阅读说明：本技术 借埋设式支柱管体构成内循环热传流体散热结构及应用装置 (Heat dissipation structure of internal circulation heat transfer fluid formed by embedded pillar tube and application device ) 是由 杨泰和 于 2014-06-26 设计创作，主要内容包括：本发明公开了一种借埋设式支柱管体构成内循环热传流体散热结构及应用装置,为具有支柱管体(101)及内设内管(103),支柱管体(101)内径与内管(103)外径的间具有尺寸差,在支柱管体(101)与内管(103)之间进一步设置螺旋状导流结构(2003)供构成流体流路的间隔空间,支柱管体(101)的上段管体供设置电能应用装置总成(108),而借串设于热传流体流路的流体泵(105)泵送热传流体构成封闭循环流动,而借由流经上述封闭循环的热传流体通路中支柱管体(101)及相关结构的外表露出部分,供与外部气态或固态或液态环境及/或浅层地表自然温能体的土壤或液体作均温运作。(The invention discloses an internal circulation heat transfer fluid heat dissipation structure formed by an embedded pillar tube and an application device, which comprises a pillar tube (101) and an internal inner tube (103), wherein the inner diameter of the pillar tube (101) is different from the outer diameter of the inner tube (103), a spiral flow guide structure (2003) is further arranged between the pillar pipe body (101) and the inner pipe (103) for forming an interval space of a fluid flow path, an upper section pipe body of the pillar pipe body (101) is provided with an electric energy application device assembly (108), the heat transfer fluid is pumped by a fluid pump (105) connected in series with the flow path of the heat transfer fluid to form a closed circulation flow, the exposed part of the pillar pipe body (101) and the related structure in the heat transfer fluid passage flowing through the closed circulation is used for the soil or liquid of the external gas state or solid state or liquid state environment and/or the shallow surface natural temperature energy body to carry out temperature equalization operation.)

1. An inner circulation heat transfer fluid heat dissipation structure formed by embedded type pillar pipes and an application device thereof are provided, the inner pipe (103) is arranged in the earth surface soil or liquid of a shallow earth surface natural temperature energy body in a penetrating way and performs the function of temperature equalization operation with the external gas state or solid state or liquid state environment and/or the earth or liquid of the shallow earth surface natural temperature energy body, the inner diameter of the pillar pipe (101) is larger than the outer diameter of the inner pipe (103), the interval space with different sizes is used for forming a fluid flow path, the tail section of the pillar pipe (101) is closed, the tail section of the inner pipe (103) is shorter than the tail section of the pillar pipe (101) or is provided with fluid holes, and the tail sections of the inner pipe and the pillar pipe form a flow direction turning section of the heat transfer fluid flow path;

the front section pipe orifice of the support column pipe body (101) and the front section pipe orifice of the inner pipe (103) are used for transmitting heat transfer fluid flowing through the electric energy application device assembly (108) and/or the radiator to which the electric energy application device assembly belongs, one pipe orifice is used for transmitting the heat transfer fluid so as to flow through the electric energy application device assembly (108) and/or the radiator to which the electric energy application device assembly belongs, and the other pipe orifice is used for transmitting the heat transfer fluid reflowing from the electric energy application device assembly (108) and/or the radiator to which the electric energy application device assembly belongs;

a spiral flow guide structure (2003) is further arranged between the strut pipe body (101) and the inner pipe (103) to increase the length of a flow path of the heat transfer fluid between the strut pipe body (101) and the inner pipe (103);

one or more fluid pumps (105) are arranged in series in the closed-cycle heat transfer fluid passage, and the flow direction of the fluid pumps can be switched or periodically exchanged;

the structure of the heat transfer fluid path between the heat sink and the support tube (101) and the inner tube (103) of the electrical energy application device assembly (108) comprises one or more of the following components:

one or more through heat transfer fluid passages are arranged in the electric energy application device assembly (108) in series or in parallel, and the fluid inlet end and the fluid outlet end of the electric energy application device assembly are respectively communicated with the pipe orifices of the pillar pipe body (101) and the inner pipe (103);

the second one is formed by connecting one or more through heat transfer fluid passages in parallel in an internal radiator of the electric energy application device assembly (108), and a fluid inlet end and a fluid outlet end of the heat transfer fluid passages are respectively communicated with pipe orifices of the pillar pipe body (101) and the inner pipe (103);

one or more heat transfer fluid passages are arranged in the electric energy application device assembly (108), are connected in series or in parallel with the heat transfer fluid passages in the radiator, and are respectively communicated with the pipe orifices of the support pipe body (101) and the inner pipe (103) through a fluid inlet end and a fluid outlet end;

(IV) the electric energy application device assembly (108) is provided with two or more heat transfer fluid passages, the fluid inlet end and the fluid outlet end which are connected with each other by the pipe body are reserved outside and are communicated with the pipe orifices of the pillar pipe body (101) and the inner pipe (103), or the fluid inlet end and the fluid outlet end which are bent in a U shape or an L shape inside the pipe body are respectively communicated with the pipe orifices of the pillar pipe body (101) and the inner pipe (103) by the fluid inlet end and the fluid outlet end which are on the same side or different sides;

a closed shell is additionally arranged outside the electric energy application device assembly (108), a space for heat transfer fluid circulation is arranged between the electric energy application device assembly and the closed shell, one or more heat transfer fluid passages which are connected in series or in parallel are arranged on the electric energy application device assembly (108), one end of the heat transfer fluid passage is provided with a heat transfer fluid inlet and outlet for leading to a pipe orifice of the inner pipe (103), the pipe orifice at the other end of the heat transfer fluid passage is led to the space between the shell and the electric energy application device assembly (108), and the closed shell is provided with a heat transfer fluid passage orifice for leading to a pipe orifice of the supporting pipe body (101);

(VI) the electric energy application device assembly (108) and the heat sink and the external and the shell jointly form a closed space with heat transfer fluid flowing inside, one or more heat transfer fluid passages connected in series or in parallel are arranged on the electric energy application device assembly (108) and/or the heat sink, one end of each heat transfer fluid passage is provided with a heat transfer fluid inlet and outlet for leading to a pipe orifice of the inner pipe (103), the pipe orifice at the other end of each heat transfer fluid passage is led to the space between the shell and the electric energy application device assembly (108) and/or the heat sink to which the heat transfer fluid passage is connected, and the closed shell is provided with a heat transfer fluid inlet and outlet for communicating with the pipe orifice of the support pipe body (101);

(seventh) outside the electric energy application device assembly (108) and/or affiliated radiator and form the closed body with the cooperating body together, and the electric energy application device assembly (108) and/or affiliated radiator and cooperating inside of body, have space for heat transfer fluid to flow and lead to the mouth of pipe of the pillar body (101), the electric energy application device assembly (108) and/or affiliated radiator have one or more present series or parallel heat transfer fluid access, one end has the mouth of pipe of heat transfer fluid to lead to the inner pipe (103), the mouth of pipe of another end is for leading to the space between body and electric energy application device assembly (108) and/or its affiliated radiator, and set up the mouth of pipe of heat transfer fluid in the closed body, communicate with the mouth of pipe of the pillar body (101);

the gaseous or liquid heat transfer fluid pumped by the fluid pump (105) flows through the exposed part of the pillar tube body (101) and the related structure in the closed circulation heat transfer fluid passage to be used for the temperature equalization operation of the external gaseous or solid or liquid environment and/or the soil or liquid of the shallow surface natural temperature energy body;

the electric energy application device assembly (108) comprises an electric energy-to-light energy lighting device such as a Light Emitting Diode (LED) lighting device and/or a light energy power generation Panel (photo) such as a Solar power generation Panel (Solar Panel) and/or a wind driven generator and/or a transformer and/or an electric energy driven motor, and peripheral devices, a control circuit device, an overload protection device and a temperature protection device which assist the electric energy application device assembly (108) in operation are provided according to the requirement;

wherein the pillar tube body (101) is divided into an upper section tube body, a middle section tube body and a lower section tube body,

wherein the upper section pipe body is provided with an electric energy application device assembly (108),

wherein the middle tube body is used as a support and heat energy channel,

wherein the lower tube body is arranged in the natural thermal energy body (100), and

the structural mode of the pillar pipe body (101) and the inner pipe (103) comprises one or more than one of the following modes:

the pillar tube body (101) and the inner tube (103) are coaxially or approximately parallelly arranged, a space for heat transfer fluid to pass through is formed between the periphery of the inner tube (103) and the pillar tube body (101) and between the inner tube (103) and the pillar tube body (101), the inner tube (103) arranged in the pillar tube body (101) is shorter than the pillar tube body (101), and a length difference is formed between the lower end of the inner tube and the lower bottom closed part of the pillar tube body (101) and is fixed by a support (1033) to form a space for the heat transfer fluid to pass through;

the pillar tube body (101) and the inner tube (103) are arranged in parallel, the lower end of the inner tube (103) arranged in the pillar tube body (101) is combined with the lower section bottom closed part of the pillar tube body (101), and the lower end or the lower section of the inner tube (103) is provided with a transverse hole (1031) or a notch (1032) penetrating through the inner tube body for passing through a space of heat transfer fluid;

the pillar pipe body (101) and the inner pipe (103) are eccentrically combined, the lower end of the inner pipe (103) arranged in the pillar pipe body (101) is shorter, and the lower end of the inner pipe has a length difference with the lower bottom closed part of the pillar pipe body (101) to form a space for heat transfer fluid to pass through;

the pillar pipe body (101) is arranged in parallel with two or more inner pipes (103), the lower end of the inner pipe (103) arranged in the pillar pipe body (101) is shorter, and the lower end of the inner pipe has a length difference with the lower bottom closed part of the pillar pipe body (101) to form a space for heat transfer fluid to pass through;

the pillar tube body (101) and the inner tube (103) are coaxially or approximately parallelly arranged, a space for heat transfer fluid to pass through is formed between the periphery of the inner tube (103) and the pillar tube body (101) and between the inner tube (103), the inner tube (103) arranged in the pillar tube body (101) is shorter than the pillar tube body (101), and a length difference is formed between the lower end of the inner tube and the lower bottom closed part of the pillar tube body (101) so as to form a space for heat transfer fluid to pass through.

2. The heat dissipating structure and application device for internal circulation heat transfer fluid formed by embedded pillar tube as claimed in claim 1, wherein:

the pillar tube (101) comprises a tube body made into a circular shape or other geometric shapes, and is made of a material with mechanical strength and better heat conduction characteristics or a material with heat insulation characteristics; the pillar tube (101) may be provided with heat conductive fins (2001) on the outside thereof as required;

-an inner tube (103): the heat transfer fluid channel is a tube body formed by hard materials, such as metal materials or flexible materials or soft materials, such as plastic materials or cloth materials or materials with the same properties, the outer diameter of the tube body (103) is smaller than the inner diameter of the support tube body (101), the tube body is arranged in the support tube body (101) in a straight shape, a bent shape or a curved shape or a shape which is randomly changed by the flexible materials or the soft materials without obstructing the heat transfer fluid channel, the outer diameter of the inner tube (103) and the inner diameter of the support tube body (101) have a size difference, so that a reserved space is formed to be used as the heat, the inner tube and the opening at both ends of the inner tube and the reserved space between the outer diameter of the inner tube and the inner diameter of the outer tube form a flow path for passing heat transfer fluid, one or more fluid pumps (105) are arranged in series at the selected position of the flow path, and an electric energy application device assembly (108) is arranged in the space between the upper end of the inner pipe (103) and the upper section of the strut pipe body (101);

the inner pipe (103) comprises a pipe body which is made into a circular shape or other geometric shapes, and one of the pipe body which is made of a hard material, a flexible material or a soft material with a heat insulation characteristic, or the other of the pipe body which is made of a hard material, a flexible material or a soft material with a better heat conduction characteristic, wherein the outer part of the pipe body is coated with a heat insulation material, or the other of the pipe body which is made of a hard material, a flexible material or a soft material with a better heat conduction characteristic, wherein the heat insulation material is sleeved in the pipe body, or the other of the pipe body which is made of a hard material, a flexible material or a soft material with a better heat conduction;

-a fluid pump (105): the pump is driven by an electric motor, and is used for pumping gaseous or liquid heat transfer fluid according to the flow direction and flow rate of the operation fluid driven by the pump;

-an electrical energy application device assembly (108): the device is composed of a light-emitting device driven by electric energy, a power generation device driven by external gas or liquid fluid kinetic energy, a device which is driven by light energy to generate electric energy and generates heat loss along with the electric energy, and/or a transformer and/or a motor driven by electric energy, and peripheral devices, a control circuit device, an overload protection device and a temperature protection device which assist the operation of an electric energy application device assembly (108) are provided according to the selection and the arrangement;

the heat dissipation structure and application device of the internal circulation heat transfer fluid formed by the embedded pillar tube body, wherein the pumping of the fluid pump (105) causes the gaseous or liquid heat transfer fluid to flow through the heat transfer fluid outlet at the upper end of the inner tube (103), the electric energy application device assembly (108) or the heat transfer fluid passage of the heat sink (104) associated with heat loss in operation, then flow through the heat transfer fluid passage formed by the space between the inside of the pillar tube body (101) and the inner tube (103) to lead to the lower tube body of the pillar tube body (101), and then flow back from the heat transfer fluid inlet at the lower end of the inner tube (103) to form a closed circulation heat transfer fluid loop, or the sequence and the flow direction of the heat transfer fluid pumped by the fluid pump (105) are opposite, and the closed circulation heat transfer fluid loop with the opposite flow direction and sequence is formed, so that the heat transfer fluid flows through the electric energy application device assembly (108) or the outer surface of the heat sink (104) associated with the heat transfer fluid And/or the exposed part of the outer surface of the pillar pipe body (101) and the external gaseous or liquid or solid environment are operated at the same temperature, and/or heat transfer fluid pumped by a fluid pump (105) is used for transferring temperature energy to the stratum or liquid through the embedded section of the pillar pipe body (101) arranged in the stratum or the liquid of the natural temperature energy body of the superficial layer.

3. The heat dissipation structure and application device of claim 1 or 2, wherein the heat dissipation structure and application device of internal circulation heat transfer fluid are formed by embedded pillar pipes, which are used to install the upper pipe of the pillar pipe (101) of the power application device assembly (108), further a housing (106) is installed to protect the power application device assembly (108), and a heat transfer fluid passage (107) is formed by a space formed by the exterior of the power application device assembly (108) or the exterior of the heat sink (104) to which the power application device assembly belongs, so as to transfer heat transfer fluid, wherein:

the pillar tube (101) comprises a tube body made into a circular shape or other geometric shapes, and is made of a material with mechanical strength and better heat conduction characteristics or a material with heat insulation characteristics; the pillar tube (101) may be provided with heat conductive fins (2001) on the outside thereof as required;

inner tube (103): the heat transfer fluid channel is a tube body formed by hard materials, such as metal materials or flexible materials or soft materials, such as plastic materials or cloth materials or materials with the same properties, the outer diameter of the tube body (103) is smaller than the inner diameter of the support tube body (101), the tube body is arranged in the support tube body (101) in a straight shape, a bent shape or a curved shape or a shape which is randomly changed by the flexible materials or the soft materials without obstructing the heat transfer fluid channel, the outer diameter of the inner tube (103) and the inner diameter of the support tube body (101) have a size difference, so that a reserved space is formed to be used as the heat, the inner tube and the opening at both ends of the inner tube and the reserved space between the outer diameter of the inner tube and the inner diameter of the outer tube form a flow path for passing heat transfer fluid, one or more fluid pumps (105) are arranged in series at the selected position of the flow path, and an electric energy application device assembly (108) is arranged in the space between the upper end of the inner pipe (103) and the upper section of the strut pipe body (101);

the inner pipe (103) comprises a pipe body which is made into a circular shape or other geometric shapes, and one of the pipe body which is made of a hard material, a flexible material or a soft material with a heat insulation characteristic, or the other of the pipe body which is made of a hard material, a flexible material or a soft material with a better heat conduction characteristic, wherein the outer part of the pipe body is coated with a heat insulation material, or the other of the pipe body which is made of a hard material, a flexible material or a soft material with a better heat conduction characteristic, wherein the heat insulation material is sleeved in the pipe body, or the other of the pipe body which is made of a hard material, a flexible material or a soft material with a better heat conduction;

-a fluid pump (105): the pump is driven by an electric motor, and is used for pumping gaseous or liquid heat transfer fluid according to the flow direction and flow rate of the operation fluid driven by the pump;

-a housing (106): the heat transfer fluid is pumped by a fluid pump (105), flows to a space formed by a shell (106) and the electric energy application device assembly (108) from a heat transfer fluid outlet at the upper end of an inner pipe (103), flows to a heat transfer fluid passage formed by a space between the inner diameter of a pillar pipe body (101) and the outer diameter of the inner pipe (103) to a lower pipe body of the pillar pipe body (101), and flows back through a heat transfer fluid inlet at the lower end of the inner pipe (103) to form a closed circulation heat transfer fluid loop, or flows back in an opposite direction by the change of the flow direction of the heat transfer fluid pumped by the fluid pump (105) to form a closed circulation heat transfer fluid return;

-an electrical energy application device assembly (108): the device is composed of a light-emitting device driven by electric energy, a power generation device driven by external gas or liquid fluid kinetic energy, a device which is driven by light energy to generate electric energy and generates heat loss along with the electric energy, and/or a transformer and/or a motor driven by electric energy, and peripheral devices, a control circuit device, an overload protection device and a temperature protection device which assist the operation of an electric energy application device assembly (108) are provided according to the selection and the arrangement;

-an electronic control device (112): is composed of solid-state or electromechanical elements or chips and related operating software, and the device is optionally set or not set according to requirements;

-a temperature protection device (102) comprising an electromechanical thermal switch or thermal fuse, or a solid state temperature sensing element or solid state temperature switching element, for switching off the load or switching off part of the load or reducing the load power, either directly or by operation of an electrical control device (112), when the load is overheated, the device being optionally provided or not;

the heat transfer fluid pumped by a fluid pump (105) arranged in series in the heat transfer fluid flow path flows from a heat transfer fluid outlet at the upper end of an inner pipe (103), flows through the inner part of an electric energy application device assembly (108) and/or a space arranged between the outer part of the electric energy application device assembly (108) and a closed shell, then flows through a space of a fluid passage formed between the inner diameter of a support pipe body (101) and the outer diameter of the inner pipe (103), and then flows back through a heat transfer fluid inlet at the lower end of the inner pipe (103) to form a closed circulation flow, or flows back in a reverse flow direction to form a closed circulation flow by virtue of the change of the flow direction of the heat transfer fluid pumped by the fluid pump (105), and the surface of a closed shell (106) is exposed to the outside by virtue of the temperature energy of the gaseous or liquid heat transfer fluid pumped by the fluid pump (105), passes through the outer surface of the electric energy application device assembly (108) and/or is arranged, and/or the exposed part of the pillar body (101) is in uniform temperature operation with the external gaseous or liquid or solid environment, and/or the heat transfer fluid pumped by the fluid pump (105) is used for transferring temperature energy to the stratum or the liquid through the embedded section of the pillar body (101) arranged in the stratum or the liquid of the natural temperature energy body of the superficial layer.

4. The heat dissipation structure and application device of claim 1, comprising an electrical energy application device assembly (108) comprising an electrical energy to light energy lighting device (109), the electrical energy application device assembly (108) mainly comprises a pillar tube (101), an inner tube (103), and a fluid pump (105), and the electrical energy application device assembly (108) is an electrical energy to light energy lighting device (109) and/or a Light Emitting Diode (LED) which converts electrical energy to light energy and generates heat loss, and is selectively provided with a peripheral device, a control circuit device, an overload protection device, and a temperature protection device for assisting the operation of the electrical energy to light energy lighting device (109);

wherein: the heat transfer fluid pumped by the fluid pump (105) flows through the electric energy-to-light energy lighting device (109) or the heat transfer fluid passage (107) on the surface or inside the radiator (104), the temperature energy transmitted by the heat transfer fluid passage (107) is subjected to temperature equalization operation with the external gaseous or liquid or solid environment through the exposed part of the outer surface of the pillar tube body (101), and/or the heat transfer fluid pumped by the fluid pump (105) is used for transmitting the temperature energy to the stratum or the liquid through the embedded section of the pillar tube body (101) arranged in the stratum or the liquid of the natural temperature energy body on the superficial layer;

-an electrical to optical energy lighting device (109): the lighting device comprises various gas lamps, solid-state lighting LEDs, OLEDs and other electric energy-to-light energy lighting devices and related peripheral devices such as a light-transmitting body (1061), and further comprises a display screen, a signboard, a sign or a warning sign which operates by means of light energy of the electric energy-to-light energy lighting device (109);

-a fluid pump (105): the pump is driven by an electric motor, and is used for pumping gaseous or liquid heat transfer fluid according to the flow direction and flow rate of the operation fluid driven by the pump;

-an electronic control device (112): is composed of solid-state or electromechanical elements or chips and related operating software; the application of the present embodiment is for controlling the input voltage, current and working temperature of the lighting device (109) converting electrical energy into optical energy and controlling the operation timing of the fluid pump (105);

-a temperature protection device (102) comprising an electromechanical thermal switch or thermal fuse, or a solid-state temperature detection element or solid-state temperature switch element, for being arranged on the electrical to optical energy lighting device (109) or the associated heat sink (104), for switching off the load or part of the load or reducing the load power or operating the fluid pump (105) directly or by operation of the electrical control device (112) in case of an abnormal temperature; the device is optionally configured or not configured as desired.

5. The heat dissipation structure and application device of internal circulation heat transfer fluid formed by embedded pillar tube according to claim 1, comprising an electrical energy application device assembly (108) formed by a photo-electric energy generation plate (photo-electric) (110), which mainly comprises a pillar tube (101), an inner tube (103), and a fluid pump (105), wherein the electrical energy application device assembly (108) is formed by the photo-electric energy generation plate (photo-electric) (110) which converts photo-electric energy into electrical energy and generates heat loss, and is selectively provided with a peripheral device, a control circuit device, an overload protection device, and a temperature protection device for assisting the operation of the photo-electric energy generation plate (photo-electric) (110) according to requirements;

wherein: the heat transfer fluid pumped by the fluid pump (105) flows through a heat transfer fluid passage (107) on the back surface of the Photovoltaic panel (110) or on the surface or inside of the radiator (104), the temperature energy transmitted by the heat transfer fluid passage (107) is subjected to temperature equalization operation with the external gaseous or liquid or solid environment through the exposed part of the outer surface of the pillar tube body (101), and/or the heat transfer fluid pumped by the fluid pump (105) is further used for transmitting the temperature energy to the stratum or the liquid through the embedded section of the pillar tube body (101) arranged in the stratum or the liquid of the natural temperature energy body on the shallow surface;

-photo-electric panels (photo-voltaic) (110): the Solar Photovoltaic power generation device is composed of various Photovoltaic power generation boards (Photovoltaic) which receive light to generate electric energy and output the electric energy, such as Solar power generation boards (Solar Panel) and related peripheral devices;

-a fluid pump (105): the pump is driven by an electric motor, and is used for pumping gaseous or liquid heat transfer fluid according to the flow direction and flow rate of the operation fluid driven by the pump;

-an electronic control device (112): is composed of solid-state or electromechanical elements or chips and related operating software; the application of the present embodiment is for controlling the output voltage, current and working temperature of the Photovoltaic panel (110) and controlling the operation timing of the fluid pump (105);

a temperature protection device (102) which is composed of an electromechanical thermal switch or a thermal cut-off fuse, or a solid temperature detection element or a solid temperature switch element and is used for cutting off the load or cutting off part of the load or reducing the load power or operating the fluid pump (105) directly or through the operation of an electric control device (112) when the temperature of the photo-electric panel (110) is abnormal; the device is optionally configured or not configured as desired.

6. The heat dissipation structure and application device of internal circulation heat transfer fluid formed by embedded pillar pipes as claimed in claim 1, comprising an electric energy application device assembly (108) formed by wind power generation devices (111), which mainly comprises a pillar pipe (101) for natural temperature energy (100) installed on the shallow layer of the ground, an inner pipe (103), and a fluid pump (105), wherein the electric energy application device assembly (108) is formed by a wind power generator (222) of the wind power generation device (111), and optionally comprises peripheral devices, a control circuit device, an overload protection device, and a temperature protection device for assisting the wind power generation device (111);

wherein: the heat transfer fluid pumped by the fluid pump (105) passes through a wind power generator (222) of the wind power generation device (111) and/or a heat transfer fluid passage in a radiator of the wind power generation device, or further comprises an electric control device (112) and/or a heat transfer fluid passage in a radiator of the wind power generation device, and an inner pipe (103), an interval space between the inner pipe (103) and the inner part of the strut tube body (101) form a closed heat transfer fluid passage together, and the heat transfer fluid flows in the closed heat transfer fluid passage, and is supplied to soil or liquid of an external gaseous or solid or liquid environment and/or shallow surface natural temperature energy body for temperature equalization operation by virtue of an exposed part of the outer surface of the strut tube body (101);

-a wind power plant (111): comprises a wind turbine blade, a driven wind power generator (222) and/or an electric control device (112) and related peripheral devices, wherein the wind power generator (222) and/or the electric control device (112) are mainly used for receiving heat dissipation;

-a fluid pump (105): a pump driven by a wind power driving rotating shaft or an electric motor is used for pumping gaseous or liquid heat transfer fluid according to the controlled flow direction and flow rate;

-an electronic control device (112): the system is composed of solid-state or electromechanical elements or chips and related operation software, and is used for controlling the operation of the system in the wind power generation device (111), wherein the system comprises the output voltage, the current and the working temperature of a wind power generator (222), the direct current and alternating current conversion, the parallel control of alternating current output electric energy and a mains supply system, and the operation time of a fluid pump (105);

-a temperature protection device (102) comprising an electromechanical thermal switch or thermal fuse, or a solid-state temperature detection element or solid-state temperature switch element, for controlling the operation of the wind turbine (222) and/or the wind turbine (111) system, directly or via an electrical control device (112), and for controlling the fluid pump (105) when the wind turbine (111) is at an abnormal temperature; the device is optionally configured or not configured as desired.

7. The heat dissipation structure and application device of claim 1, comprising an electric energy application device assembly (108) formed by a transformer (444), the electric energy application device assembly (108) mainly comprises a supporting pillar body (101), an inner tube (103) and a fluid pump (105), and the electric energy application device assembly (108) is formed by the transformer (444), and optionally provided with a peripheral device, a control circuit device, an overload protection device and a temperature protection device for assisting the transformer (444)) to operate;

wherein: the heat transfer fluid pumped by the fluid pump (105) flows through the heat transfer fluid passage (107) on the surface or inside of the transformer (444) or the radiator (104) to which the transformer belongs, the temperature energy transmitted by the heat transfer fluid passage (107) is equalized with the external gaseous or liquid or solid environment through the exposed part of the outer surface of the pillar tube body (101), and/or the heat transfer fluid pumped by the fluid pump (105) is further used for transmitting the temperature energy to the stratum or the liquid through the embedded section of the pillar tube body (101) arranged in the stratum or the liquid of the shallow natural temperature energy body on the ground surface;

-a transformer (444): the transformer is provided with a winding, a magnetic conduction magnetic circuit and a shell and is used for inputting and outputting single-phase or three-phase (including multiphase) alternating current electric energy or inputting and outputting pulse electric energy, the transformer comprises a dry type or a separation winding type transformer with a wet type structure and gas inside, and a pipeline heat dissipation structure for fluid to pass through is arranged on the surface or the outside of the transformer or a fluid inlet and outlet is arranged for the fluid to enter and exit the inner space of the transformer; the transformer is combined with the pillar tube body (101) by a transformer supporting frame (445);

-a fluid pump (105): the pump is driven by an electric motor, and is used for pumping gaseous or liquid heat transfer fluid according to the flow direction and flow rate of the operation fluid driven by the pump;

-an electronic control device (112): is composed of solid-state, or electromechanical elements, or chips and related operating software, and is applied in the present embodiment for controlling the output voltage, current and operating temperature of the transformer (444) and the operating timing of the fluid pump (105);

-temperature protection means (102) comprising an electromechanical thermal switch or thermal fuse, or a solid-state temperature detection element or solid-state temperature switching element, for disconnecting the load or part of the load or reducing the load power, directly or by operation of the electrical control means (112), in case of an abnormal temperature of the transformer (444), and for operating the fluid pump (105); the device is optionally configured or not configured as desired.

8. The heat dissipation structure and application device of claim 1, comprising an electric energy application device assembly (108) formed by an electric energy driving motor (333), the electric energy application device assembly (108) mainly comprises a support column tube (101), an inner tube (103) and a fluid pump (105), and the electric energy application device assembly (108) is formed by the electric energy driving motor (333), and is selectively provided with a peripheral device, a control circuit device, an overload protection device and a temperature protection device for assisting the operation of the motor (333) according to requirements;

wherein: the heat transfer fluid pumped by the fluid pump (105) flows through the electric energy driving motor (333) or the heat transfer fluid passage (107) on the surface or inside the radiator (104) which belongs to the electric energy driving motor, the temperature energy transmitted by the heat transfer fluid passage (107) is in uniform temperature operation with the external gaseous or liquid or solid environment through the exposed part of the outer surface of the pillar tube body (101), and/or the heat transfer fluid pumped by the fluid pump (105) is further used for transmitting the temperature energy to the stratum or the liquid through the embedded section of the pillar tube body (101) which is arranged in the stratum or the liquid of the natural temperature energy of the superficial layer;

-motor (333): comprises a rotary motor driven by an alternating current or direct current power supply to output rotary kinetic energy, and is used for driving a motor to drive a load (334);

-a fluid pump (105): the pump is driven by an electric motor, and is used for pumping gaseous or liquid heat transfer fluid according to the flow direction and flow rate of the operation fluid driven by the pump;

-an electronic control device (112): is composed of solid-state, or electromechanical elements, or chips and related operating software, and is applied in this embodiment for controlling the input voltage, current and operating temperature of the electric driving motor (333) and the operating timing of the fluid pump (105);

-temperature protection means (102) comprising an electromechanical thermal switch or thermal fuse, or a solid-state temperature detection element or solid-state temperature switching element, for disconnecting the load or part of the load or reducing the load power, directly or by operation of the electronic control means (112), in case of an abnormal temperature of the electric drive motor (333), and for operating the fluid pump (105); the device is optionally configured or not configured as desired.

9. The heat dissipating structure and application device of claim 1, wherein the upper section and the inner pipe (103) of the pillar body (101) are further formed of a multi-branch structure for installing a plurality of identical or different power application device assemblies (108) and sharing the middle and lower pillar bodies, and the structure mainly comprises the pillar body (101), the inner pipe (103), and the fluid pump (105), wherein the upper section of the pillar body (101) is formed of a multi-branch structure for installing a plurality of power application device assemblies (108) and selectively installing peripheral devices, control circuit devices, overload protection devices, and temperature protection devices for assisting the power application device assemblies (108) to operate, and sharing the middle and lower pillar bodies (101), and the same or different power application device assemblies (108), are respectively arranged on the upper sections of the pillar tube bodies (101) and are multi-branch rods, and the inner tubes (103) are oppositely arranged inside the pillar tube bodies (101);

wherein: the thermal energy transferred by the heat transfer fluid pumped by the fluid pump (105) flowing through the surface or internal heat transfer fluid passage (107) of the respective electric energy application device assembly (108) or the heat sink (104) to which the fluid pump belongs is equalized with the external gaseous or liquid or solid environment, and/or the thermal energy is further transferred to the stratum or the liquid by the heat transfer fluid pumped by the fluid pump (105) through the support column pipe body (101) embedded section arranged in the stratum or the liquid of the natural thermal energy body of the superficial layer.

10. The heat dissipation structure and application device for internal circulation heat transfer fluid formed by embedded pillar tube of claim 1, wherein the structure of the pillar tube (101) and the inner tube (103) comprises:

the pillar tube body (101) and the inner tube (103) are coaxially or approximately parallelly arranged, a space for heat transfer fluid to pass through is formed between the periphery of the inner tube (103) and the pillar tube body (101) and between the inner tube (103), the inner tube (103) arranged in the pillar tube body (101) is shorter than the pillar tube body (101) and only extends to the upper section or the middle section of the pillar tube body (101) but not to the lower section, so that the flow path length of the heat transfer fluid is shortened; or

The support column pipe body (101) and the inner pipe (103) are eccentrically combined, the lower end of the inner pipe (103) arranged in the support column pipe body (101) is shorter than the support column pipe body (101), and only extends to the upper section or the middle section of the support column pipe body (101) but not to the lower section, so that the flow path length of the heat transfer fluid is shortened; or

The pillar pipe body (101) is arranged in parallel with two or more inner pipes (103), and the lower end of the inner pipe (103) arranged inside the pillar pipe body (101) is shorter than the pillar pipe body (101), and extends only to the upper section or the middle section of the pillar pipe body (101) but not to the lower section, so as to shorten the flow path length of the heat transfer fluid.

11. The heat dissipation structure and application device of claim 1, further comprising a space between the heat sink (104) and the housing (106) of the power application device assembly (108) and a heat sink heat transfer fluid passage (1041) of the heat sink (104) to form a heat transfer fluid passage for passing a liquid or gaseous heat transfer fluid.

12. The heat dissipation structure and application device using embedded pillar tube for internal circulation heat transfer fluid as claimed in claim 1, further comprising at least two heat sink heat transfer fluid passages (1041) on the heat sink (104) of the power application device assembly (108), wherein the U-shaped connecting tube (1042) is connected in series to form a heat transfer fluid passage for passing liquid or gaseous heat transfer fluid.

13. The heat dissipation structure and application device using embedded prop tube of claim 1, further comprising a heat transfer fluid passage for passing liquid or gaseous heat transfer fluid formed by the space between the power application device assembly (108) and the housing (106) and the heat transfer fluid passage (1081) of the power application device assembly (108).

14. The heat dissipating structure and the application device using embedded pillar tube of claim 1, further comprising a space for the fluid to flow randomly inside the heat sink (104) installed with the power application device assembly (108), and a fluid inlet/outlet path is formed by the heat transfer fluid path (1081) and the heat transfer fluid path (107) between the inside of the pillar tube (101) and the outside of the heat transfer fluid path (1081).

15. The heat dissipating structure and application device of claim 1, wherein the heat dissipating structure and application device of internal circulation heat transfer fluid are formed by embedded pillar tubes, and further, a space for the fluid to flow randomly is formed inside the heat sink (104) provided with the power application device assembly (108), and a fluid inlet/outlet passage is formed by the heat transfer fluid passage (1081) and the heat transfer fluid passage (107) between the inside of the pillar tube (101) and the outside of the heat transfer fluid passage (1081) in the offset fit.

16. The heat dissipating structure and the application device using embedded pillar tube as claimed in claim 1, further comprising a heat sink (104) for installing the power application device assembly (108) having a middle flow path (570) and a ring-shaped flow path (580) and a ring-shaped flow path (590) respectively extending outward from the middle flow path to both sides, extending along the inner portion of the outer periphery of the heat sink (104) to the heat transfer fluid passage (1081), and the heat transfer fluid passage (107) between the inner portion of the pillar tube (101) and the outer portion of the nested heat transfer fluid passage (1081) forming a fluid inlet/outlet passage.

17. The heat dissipating structure and the application device using embedded pillar tube as claimed in claim 1, further comprising a heat sink (104) for installing the power application device assembly (108) having a middle flow path (570) and a ring-shaped flow path (580) and a ring-shaped flow path (590) respectively extending outward from the middle flow path to both sides, extending along the inner portion of the outer periphery of the heat sink (104) to the heat transfer fluid passage (1081), and the heat transfer fluid passage (107) between the inner portion of the pillar tube (101) and the outer portion of the offset heat transfer fluid passage (1081) forming a fluid inlet/outlet passage.

18. The heat dissipation structure and application device of claim 1, further comprising a heat sink (104) for installing the power application device assembly (108) and having a ring-shaped flow path (580) and a ring-shaped flow path (590) extending from the middle through hole (610) of the middle diversion block (600) to the outside, respectively, and extending to the heat transfer fluid passage (1081) along the inside of the periphery of the heat sink (104), wherein the heat transfer fluid passage (107) between the inside of the pillar tube (101) and the outside of the nested heat transfer fluid passage (1081) forms a fluid inlet/outlet passage.

19. The heat dissipation structure and application device of claim 1, further comprising a heat sink (104) for installing the power application device assembly (108) and having a ring-shaped flow path (580) and a ring-shaped flow path (590) extending from the middle through hole (610) of the middle diversion block (600) to the outside, respectively, and extending to the heat transfer fluid passage (1081) along the inside of the periphery of the heat sink (104), wherein the heat transfer fluid passage (107) between the inside of the pillar tube (101) and the outside of the heat transfer fluid passage (1081) in an offset manner forms a fluid inlet/outlet passage.

20. The heat dissipating structure and device using embedded pillar tube for internal circulation of heat transfer fluid as claimed in claim 1, further comprising a power application device assembly (108) disposed upward, wherein a heat transfer fluid passage (1081) leading to the power application device assembly is formed by the central axial through hole (700) and the peripheral annular holes (710), and a fluid inlet/outlet flow path is formed by the heat transfer fluid passage (107) between the pillar tube (101) and the heat transfer fluid passage (1081) of the power application device assembly.

21. The heat dissipating structure and application device for an internally circulating heat transfer fluid formed by embedded pillar tubes as claimed in claim 1, further comprising a locking type heat dissipating ring elastically attached to the exterior of the heat sink (104), wherein the locking type heat dissipating ring (800) is made of a material with good heat conducting and heat dissipating characteristics.

22. The heat dissipating structure and application device for an internally circulating heat transfer fluid formed by embedded pillar tubes as claimed in claim 1, further comprising a nested heat dissipating ring elastically attached to the outside of the heat sink (104), wherein the nested heat dissipating ring (900) is made of a material with good heat conducting and heat dissipating characteristics.

Technical Field

The invention forms the heat-transfer fluid heat-dissipating structure of inner circulation and application device by the buried pillar tube, for providing in the earth's surface soil or liquid of the natural temperature energy body of superficial earth surface, do the operation function of samming with its external gaseous state or solid state or liquid state environment and/or earth or liquid of the natural temperature energy body of superficial earth surface, the inside of the pillar tube (101) is for penetrating setting up the inner tube (103), the inner diameter of the pillar tube (101) is greater than the outer diameter of the inner tube (103), its interval space of size difference is for forming the fluid flow path, the end of the pillar tube (101) is closed, the end of the inner tube (103) is shorter than the end of the pillar tube (101) or reserves the fluid hole, the end of both forms the flow direction of the fluid flow path of heat transfer turns back the;

the front section pipe orifice of the support column pipe body (101) and the front section pipe orifice of the inner pipe (103) are used for transmitting heat transfer fluid flowing through the electric energy application device assembly (108) and/or the radiator to which the electric energy application device assembly belongs, one pipe orifice is used for transmitting the heat transfer fluid so as to flow through the electric energy application device assembly (108) and/or the radiator to which the electric energy application device assembly belongs, and the other pipe orifice is used for transmitting the heat transfer fluid reflowing from the electric energy application device assembly (108) and/or the radiator to which the electric energy application device assembly belongs;

one or more fluid pumps (105) are arranged in series in the closed-cycle heat transfer fluid passage, and the flow direction of the fluid pumps can be switched or periodically exchanged;

the gaseous or liquid heat transfer fluid pumped by the fluid pump (105) flows through the exposed part of the pillar tube (101) and the related structure in the closed circulation heat transfer fluid passage to be used for the temperature equalization operation of the external gaseous or solid or liquid environment and/or the soil or liquid of the shallow surface natural temperature energy body.

Background

Traditional electric energy application device assemblies, such as electric energy-to-light energy lighting devices, Light Emitting Diode (LED) lighting devices, Photovoltaic panels (Photovoltaic), wind power generators, transformers, and motors, can generate heat energy during operation, and it is very important to prevent overheating or freezing in winter.

Disclosure of Invention

The invention forms the heat-transfer fluid heat-dissipating structure of inner circulation and application device by the buried pillar tube, for providing in the earth's surface soil or liquid of the natural temperature energy body of superficial earth surface, do the operation function of samming with its external gaseous state or solid state or liquid state environment and/or earth or liquid of the natural temperature energy body of superficial earth surface, the inside of the pillar tube (101) is for penetrating setting up the inner tube (103), the inner diameter of the pillar tube (101) is greater than the outer diameter of the inner tube (103), its interval space of size difference is for forming the fluid flow path, the end of the pillar tube (101) is closed, the end of the inner tube (103) is shorter than the end of the pillar tube (101) or reserves the fluid hole, the end of both forms the flow direction of the fluid flow path of heat transfer turns back the;

the front section pipe orifice of the support column pipe body (101) and the front section pipe orifice of the inner pipe (103) are used for transmitting heat transfer fluid flowing through the electric energy application device assembly (108) and/or the radiator to which the electric energy application device assembly belongs, one pipe orifice is used for transmitting the heat transfer fluid so as to flow through the electric energy application device assembly (108) and/or the radiator to which the electric energy application device assembly belongs, and the other pipe orifice is used for transmitting the heat transfer fluid reflowing from the electric energy application device assembly (108) and/or the radiator to which the electric energy application device assembly belongs;

one or more fluid pumps (105) are arranged in series in the closed-cycle heat transfer fluid passage, and the flow direction of the fluid pumps can be switched or periodically exchanged;

the structure of the heat transfer fluid path between the heat sink and the support tube (101) and the inner tube (103) of the electrical energy application device assembly (108) comprises one or more of the following components:

one or more through heat transfer fluid passages are arranged in the electric energy application device assembly (108) in series or in parallel, and the fluid inlet end and the fluid outlet end of the electric energy application device assembly are respectively communicated with the pipe orifices of the pillar pipe body (101) and the inner pipe (103);

the second one is formed by connecting one or more through heat transfer fluid passages in parallel in an internal radiator of the electric energy application device assembly (108), and a fluid inlet end and a fluid outlet end of the heat transfer fluid passages are respectively communicated with pipe orifices of the pillar pipe body (101) and the inner pipe (103);

one or more heat transfer fluid passages are arranged in the electric energy application device assembly (108), are connected in series or in parallel with the heat transfer fluid passages in the radiator, and are respectively communicated with the pipe orifices of the support pipe body (101) and the inner pipe (103) through a fluid inlet end and a fluid outlet end;

(IV) the electric energy application device assembly (108) is provided with two or more heat transfer fluid passages, the fluid inlet end and the fluid outlet end which are connected with each other by the pipe body are reserved outside and are communicated with the pipe orifices of the pillar pipe body (101) and the inner pipe (103), or the fluid inlet end and the fluid outlet end which are bent in a U shape or an L shape inside the pipe body are respectively communicated with the pipe orifices of the pillar pipe body (101) and the inner pipe (103) by the fluid inlet end and the fluid outlet end which are on the same side or different sides;

a closed shell is additionally arranged outside the electric energy application device assembly (108), a space for heat transfer fluid circulation is arranged between the electric energy application device assembly and the closed shell, one or more heat transfer fluid passages which are connected in series or in parallel are arranged on the electric energy application device assembly (108), one end of the heat transfer fluid passage is provided with a heat transfer fluid inlet and outlet for leading to a pipe orifice of the inner pipe (103), the pipe orifice at the other end of the heat transfer fluid passage is led to the space between the shell and the electric energy application device assembly (108), and the closed shell is provided with a heat transfer fluid passage orifice for leading to a pipe orifice of the supporting pipe body (101);

(VI) the electric energy application device assembly (108) and the heat sink and the external and the shell jointly form a closed space with heat transfer fluid flowing inside, one or more heat transfer fluid passages connected in series or in parallel are arranged on the electric energy application device assembly (108) and/or the heat sink, one end of each heat transfer fluid passage is provided with a heat transfer fluid inlet and outlet for leading to a pipe orifice of the inner pipe (103), the pipe orifice at the other end of each heat transfer fluid passage is led to the space between the shell and the electric energy application device assembly (108) and/or the heat sink to which the heat transfer fluid passage is connected, and the closed shell is provided with a heat transfer fluid inlet and outlet for communicating with the pipe orifice of the support pipe body (101);

(seventh) outside the electric energy application device assembly (108) and/or affiliated radiator and form the closed body with the cooperating body together, and the electric energy application device assembly (108) and/or affiliated radiator and cooperating inside of body, have space for heat transfer fluid to flow and lead to the mouth of pipe of the pillar body (101), the electric energy application device assembly (108) and/or affiliated radiator have one or more present series or parallel heat transfer fluid access, one end has the mouth of pipe of heat transfer fluid to lead to the inner pipe (103), the mouth of pipe of another end is for leading to the space between body and electric energy application device assembly (108) and/or its affiliated radiator, and set up the mouth of pipe of heat transfer fluid in the closed body, communicate with the mouth of pipe of the pillar body (101);

the gaseous or liquid heat transfer fluid pumped by the fluid pump (105) flows through the exposed part of the pillar tube (101) and the related structure in the closed circulation heat transfer fluid passage to be used for the temperature equalization operation of the external gaseous or solid or liquid environment and/or the soil or liquid of the shallow surface natural temperature energy body.

The electric energy application device assembly (108) comprises, for example, an electric energy-to-light energy lighting device such as a Light Emitting Diode (LED) lighting device and/or a light energy power generation Panel (photo) such as a Solar power generation Panel (Solar Panel) and/or a wind power generator and/or a transformer and/or an electric energy driven motor, and peripheral devices, a control circuit device, an overload protection device and a temperature protection device for assisting the electric energy application device assembly (108) in operation are selectively provided according to requirements.

Drawings

Fig. 1 is a schematic view showing the main structure constituting the present invention.

FIG. 2 is a schematic cross-sectional view taken along line X-X of FIG. 1.

Fig. 3 is a schematic view of the main structure of fig. 1 with a housing.

Fig. 4 is a schematic view of the cross-section X-X of fig. 3.

Fig. 5 is a schematic diagram of the main structure of the electrical energy application device assembly (108) formed by the electrical energy to optical energy lighting device (109) according to the present invention.

Fig. 6 is a schematic view of the cross-section X-X of fig. 5.

Fig. 7 is a schematic diagram of the main structure of the present invention applied to an electric energy application device assembly (108) formed by a photo-electric power generation plate (110).

Fig. 8 is a schematic view of the cross-section X-X of fig. 7.

Fig. 9 is a schematic view showing a main structure of the present invention applied to an electric power application device assembly (108) formed by a wind power generation device (111).

Fig. 10 is a schematic diagram showing the main structure of the present invention applied to an electric energy application device assembly (108) formed by a transformer (444).

Fig. 11 is a schematic view showing a main structure of the present invention applied to an electric power application device assembly (108) constituted by an electric power driving motor (333).

Fig. 12 is a schematic view of the main structure of the pillar body 101 with a multi-branch structure for installing a plurality of power application device assemblies 108 and sharing the middle and lower sections of the pillar body 101.

Fig. 13 shows one illustrative view of the root canal structure of the present invention.

FIG. 14 is a schematic cross-sectional view taken along line X-X of FIG. 13.

Fig. 15 shows a second illustrative view of the root canal structure of the present invention.

FIG. 16 is a schematic view of the cross-section X-X of FIG. 15.

Fig. 17 shows a third illustrative view of the root canal structure of the present invention.

FIG. 18 is a schematic cross-sectional view taken along line X-X of FIG. 17.

FIG. 19 shows a fourth illustrative view of the root canal structure of the present invention.

FIG. 20 is a schematic cross-sectional view taken along line X-X of FIG. 19.

Fig. 21 shows a fifth illustrative view of the root canal structure of the present invention.

FIG. 22 is a schematic cross-sectional view taken along line X-X of FIG. 21.

Fig. 23 is a schematic structural view of an embodiment of the present invention in which the lower end of the inner tube (103) is shortened and does not extend to the lower section of the pillar tube (101) in the examples of fig. 13 and 14.

Fig. 24 is a schematic structural view illustrating an embodiment of the present invention in which the lower end of the inner tube (103) is shortened and does not extend to the lower section of the pillar tube (101) in the examples of fig. 17 and 18.

Fig. 25 is a schematic structural view of an embodiment of the present invention in which the lower end of the inner tube (103) is shortened and does not extend to the lower section of the pillar tube (101) in the embodiment of fig. 19 and 20.

Fig. 26 is a schematic structural view showing an embodiment of the strut tubular body of the present invention, which is composed of tubular columns (301) and (302) in the form of U-shaped tubular bodies.

FIG. 27 is a schematic view of the cross-section X-X of FIG. 26.

Fig. 28 is a second structural view of the strut tubular body of the present invention constructed from tubular legs (301) and (302) in the form of a U-shaped tubular body.

FIG. 29 shows a side view of the U-shaped tube of FIG. 28.

FIG. 30 is a schematic view of the cross-section X-X of FIG. 28.

Fig. 31 is a schematic view of the heat transfer fluid path for passing the liquid or gaseous heat transfer fluid formed by the space between the heat sink (104) and the housing (106) of the electrical energy application device assembly (108) and the heat sink heat transfer fluid path (1041) of the heat sink (104).

Fig. 32 is a schematic view of an application structure of a heat transfer fluid passage for passing a liquid or gaseous heat transfer fluid, which is formed by connecting U-shaped connecting pipes (1042) in series to at least two heat transfer fluid passages (1041) of a heat sink (104) of an electric energy application device assembly (108) according to the present invention.

Fig. 33 is a schematic view showing an application structure of the heat transfer fluid passage for passing the liquid or gaseous heat transfer fluid, which is formed by the space between the power application device assembly (108) and the housing (106) and the heat transfer fluid passage (1081) of the power application device assembly (108).

Fig. 34 is a schematic view showing an application structure of the heat transfer fluid passage formed by connecting the U-shaped connecting pipe (1042) in series with at least two heat transfer fluid passages (1081) of the electric power application device assembly (108) for passing the liquid or gaseous heat transfer fluid.

Fig. 35 is a schematic view of the heat transfer fluid passage of the invention, which is formed by connecting at least one heat transfer fluid passage (1081) of the power application device assembly (108) and at least one heat sink heat transfer fluid passage (1041) of the heat sink (104) and connecting U-shaped connecting tubes (1042) in series, for passing the liquid or gaseous heat transfer fluid.

FIG. 36 is a schematic view of an embodiment of the present invention in which a space for fluid to flow randomly is formed inside the heat sink (104) provided with the power application device assembly (108), and a fluid inlet/outlet passage is formed by the heat transfer fluid passage (1081) and the heat transfer fluid passage (107) between the inside of the pillar tube (101) and the outside of the nested heat transfer fluid passage (1081).

Fig. 37 is a front view of fig. 36.

FIG. 38 is a second structural diagram of an embodiment of the present invention in which a space for a fluid to flow randomly is formed inside a heat sink (104) provided with an electrical energy application device assembly (108), and a fluid inlet/outlet passage is formed by a heat transfer fluid passage (1081) and a heat transfer fluid passage (107) between the inside of a pillar tube (101) and the outside of the heat transfer fluid passage (1081) in an offset fit.

Fig. 39 is a front view of fig. 38.

FIG. 40 is a schematic structural diagram of an embodiment of the present invention in which the heat sink (104) provided with the electrical energy application device assembly (108) has a ring-shaped flow path (580) and a ring-shaped flow path (590) extending outward from the middle flow path (570) to both sides, and extends along the inner portion of the periphery of the heat sink (104) to the heat transfer fluid passage (1081), and the heat transfer fluid passage (107) between the inner portion of the pillar tube (101) and the outer portion of the heat transfer fluid passage (1081) forms a fluid inlet/outlet passage.

Fig. 41 is a front view of fig. 40.

FIG. 42 is a second structural diagram of an embodiment of the present invention in which the heat sink (104) provided with the electrical energy application device assembly (108) has a ring-shaped flow path (580) and a ring-shaped flow path (590) extending outward from the middle flow path (570) to both sides, and extending along the inner portion of the periphery of the heat sink (104) to the heat transfer fluid passage (1081), and the heat transfer fluid passage (107) between the inner portion of the pillar tube (101) and the outer portion of the heat transfer fluid passage (1081) in an offset manner forms a fluid inlet/outlet passage.

Fig. 43 is a front view of fig. 42.

Fig. 44 is a third structural diagram of an embodiment of the present invention, in which the heat sink (104) provided with the electrical energy application device assembly (108) has a ring-shaped flow path (580) and a ring-shaped flow path (590) respectively extending outwards from the middle through hole (610) of the middle shunting block (600) to both sides, and extending along the inner portion of the periphery of the heat sink (104) to the heat transfer fluid passage (1081), and the heat transfer fluid passage (107) between the inner portion of the pillar tube (101) and the outer portion of the nested heat transfer fluid passage (1081) forms a fluid inlet/outlet passage.

Fig. 45 is a front view of fig. 44.

FIG. 46 is a fourth embodiment of the present invention, in which the heat sink (104) for installing the power application device assembly (108) has a ring-shaped flow path (580) and a ring-shaped flow path (590) outwardly from the middle through hole (610) of the middle diversion block (600) to both sides, and extends along the inner portion of the periphery of the heat sink (104) to the heat transfer fluid passage (1081), and the heat transfer fluid passage (107) between the inner portion of the pillar tube (101) and the outer portion of the heat transfer fluid passage (1081) in an offset manner forms a fluid inlet/outlet passage.

Fig. 47 is a front view of fig. 46.

FIG. 48 is a schematic view of an embodiment of the present invention in which the power application device assembly (108) is disposed upward, and a heat transfer fluid passage (1081) leading to the power application device assembly is formed by the central axial through hole (700) and the peripheral annular holes (710), and a fluid inlet/outlet flow path is formed by the heat transfer fluid passage (107) between the pillar tube (101) and the heat transfer fluid passage (1081) of the power application device assembly.

Fig. 49 is a front view of fig. 48.

FIG. 50 is a schematic view of a locking type heat dissipating ring (800) elastically installed on the exterior of the heat sink (104) according to the present invention.

Fig. 51 is a schematic structural diagram of a shrink-fit heat dissipation ring (900) elastically added to the exterior of the heat sink (104) according to the present invention.

Description of the reference numerals

100: natural temperature energy body for superficial layer of earth surface

101: pillar tube

102 temperature protection device

103 inner tube

1031 transverse hole

1032: a gap

1033 supporting frame

104: heat radiator

1041: heat transfer fluid passage of heat sink

1042: u-shaped connecting pipe

105: fluid pump

106: shell body

1061: light transmitting body

107: heat transfer fluid passage

108: electric energy application device assembly

1081: heat transfer fluid passage of electric energy application device assembly

109: lighting device capable of converting electric energy into light energy

110: light energy power generation board

111: wind power generator

222: wind power generator

112: electric control device

200 bending section of U-shaped pipe body

201. 202: tubular column of U type body

301. 302: tubular column of U type body

333: motor with a stator having a stator core

334: motor-driven load

444: transformer device

445: transformer support frame

570: intermediate flow path

580. 590: circular flow path

600: middle shunting block

610: middle through hole

700: middle axial through hole

710: circular cloth hole

800: locking type heat dissipation ring

900: sleeved heat dissipation ring

2001: heat conduction fin

2002: heat-conducting cladding body

2003: a spiral flow guide structure.

Detailed Description

Traditional electric energy application device assemblies, such as electric energy-to-light energy lighting devices, Light Emitting Diode (LED) lighting devices, Photovoltaic panels (Photovoltaic), wind power generators, transformers, and motors, can generate heat energy during operation, and it is very important to prevent overheating or freezing in winter.

The invention forms the heat-transfer fluid heat-dissipating structure of inner circulation and application device by the buried pillar tube, for providing in the earth's surface soil or liquid of the natural temperature energy body of superficial earth surface, do the operation function of samming with its external gaseous state or solid state or liquid state environment and/or earth or liquid of the natural temperature energy body of superficial earth surface, the inside of the pillar tube (101) is for penetrating setting up the inner tube (103), the inner diameter of the pillar tube (101) is greater than the outer diameter of the inner tube (103), its interval space of size difference is for forming the fluid flow path, the end of the pillar tube (101) is closed, the end of the inner tube (103) is shorter than the end of the pillar tube (101) or reserves the fluid hole, the end of both forms the flow direction of the fluid flow path of heat transfer turns back the; .

The front section pipe orifice of the support column pipe body (101) and the front section pipe orifice of the inner pipe (103) are used for transmitting heat transfer fluid flowing through the electric energy application device assembly (108) and/or the radiator to which the electric energy application device assembly belongs, one pipe orifice is used for transmitting the heat transfer fluid so as to flow through the electric energy application device assembly (108) and/or the radiator to which the electric energy application device assembly belongs, and the other pipe orifice is used for transmitting the heat transfer fluid reflowing from the electric energy application device assembly (108) and/or the radiator to which the electric energy application device assembly belongs;

one or more fluid pumps (105) are connected in series in the closed-cycle heat transfer fluid path, and the flow direction of the fluid pumps can be selected to be switchable or periodically exchanged.

The structure of the heat transfer fluid path between the heat sink and the support tube (101) and the inner tube (103) of the electrical energy application device assembly (108) comprises one or more of the following components:

one or more through heat transfer fluid passages are arranged in the electric energy application device assembly (108) in series or in parallel, and the fluid inlet end and the fluid outlet end of the electric energy application device assembly are respectively communicated with the pipe orifices of the pillar pipe body (101) and the inner pipe (103);

the second one is formed by connecting one or more through heat transfer fluid passages in parallel in an internal radiator of the electric energy application device assembly (108), and a fluid inlet end and a fluid outlet end of the heat transfer fluid passages are respectively communicated with pipe orifices of the pillar pipe body (101) and the inner pipe (103);

one or more heat transfer fluid passages are arranged in the electric energy application device assembly (108), are connected in series or in parallel with the heat transfer fluid passages in the radiator, and are respectively communicated with the pipe orifices of the support pipe body (101) and the inner pipe (103) through a fluid inlet end and a fluid outlet end;

(IV) the electric energy application device assembly (108) is provided with two or more heat transfer fluid passages, the fluid inlet end and the fluid outlet end which are connected with each other by the pipe body are reserved outside and are communicated with the pipe orifices of the pillar pipe body (101) and the inner pipe (103), or the fluid inlet end and the fluid outlet end which are bent in a U shape or an L shape inside the pipe body are respectively communicated with the pipe orifices of the pillar pipe body (101) and the inner pipe (103) by the fluid inlet end and the fluid outlet end which are on the same side or different sides;

a closed shell is additionally arranged outside the electric energy application device assembly (108), a space for heat transfer fluid circulation is arranged between the electric energy application device assembly and the closed shell, one or more heat transfer fluid passages which are connected in series or in parallel are arranged on the electric energy application device assembly (108), one end of the heat transfer fluid passage is provided with a heat transfer fluid inlet and outlet for leading to a pipe orifice of the inner pipe (103), the pipe orifice at the other end of the heat transfer fluid passage is led to the space between the shell and the electric energy application device assembly (108), and the closed shell is provided with a heat transfer fluid passage orifice for leading to a pipe orifice of the supporting pipe body (101);

(VI) the electric energy application device assembly (108) and the heat sink and the external and the shell jointly form a closed space with heat transfer fluid flowing inside, one or more heat transfer fluid passages connected in series or in parallel are arranged on the electric energy application device assembly (108) and/or the heat sink, one end of each heat transfer fluid passage is provided with a heat transfer fluid inlet and outlet for leading to a pipe orifice of the inner pipe (103), the pipe orifice at the other end of each heat transfer fluid passage is led to the space between the shell and the electric energy application device assembly (108) and/or the heat sink to which the heat transfer fluid passage is connected, and the closed shell is provided with a heat transfer fluid inlet and outlet for communicating with the pipe orifice of the support pipe body (101);

and (seventh) a closed shell is formed by the outer part of the electric energy application device assembly (108), the radiator and the matched shell, the electric energy application device assembly (108) and/or the radiator and the matched shell are provided with a pipe orifice which is provided with a space for heat transfer fluid to flow and leads to the support pipe body (101), the electric energy application device assembly (108) and/or the radiator is provided with one or more heat transfer fluid passages which are connected in series or in parallel, one end of the electric energy application device assembly is provided with a heat transfer fluid passage mouth for leading to the pipe orifice of the inner pipe (103), the pipe orifice at the other end of the electric energy application device assembly is provided with a pipe orifice which leads to the space between the shell and the electric energy application device assembly (108) and/or the radiator, and the closed shell is provided with a heat transfer fluid passage mouth for leading to the pipe orifice of the support pipe body (101.

The gaseous or liquid heat transfer fluid pumped by the fluid pump (105) flows through the exposed part of the pillar tube (101) and the related structure in the closed circulation heat transfer fluid passage to be used for the temperature equalization operation of the external gaseous or solid or liquid environment and/or the soil or liquid of the shallow surface natural temperature energy body.

The electric energy application device assembly (108) comprises, for example, an electric energy-to-light energy lighting device such as a Light Emitting Diode (LED) lighting device and/or a light energy power generation Panel (photo) such as a Solar power generation Panel (Solar Panel) and/or a wind power generator and/or a transformer and/or an electric energy driven motor, and peripheral devices, a control circuit device, an overload protection device and a temperature protection device for assisting the electric energy application device assembly (108) in operation are selectively provided according to requirements.

The main components of the heat dissipation structure and the application device of the internal circulation heat transfer fluid formed by the embedded pillar tube are described as follows:

fig. 1 is a schematic view showing the main structure constituting the present invention.

FIG. 2 is a schematic cross-sectional view taken along line X-X of FIG. 1.

As shown in fig. 1 and 2, it mainly consists of:

-a prop tube (101): for the hollow pipe body structure that constitutes by the material that has mechanical strength, the body has upper segment body, middle section body, hypomere body, wherein:

the upper section of the pipe body is mainly used for arranging an electric energy application device assembly (108);

the middle pipe body is used for forming a supporting function and conducting heat energy between the inside and the outside of the pipe;

the lower pipe body is arranged in the stratum or liquid of the natural temperature energy body of the superficial layer of the earth surface for transmitting heat energy.

The pillar tube (101) comprises a tube body made into a circular shape or other geometric shapes, and is made of a material with mechanical strength and better heat conduction characteristics or a material with heat insulation characteristics; the pillar tube (101) may be provided with heat conductive fins (2001) on the outside of the tube as required.

-an inner tube (103): the heat transfer fluid passage is a pipe body which is composed of hard materials, such as metal materials or flexible materials or soft materials, such as plastic materials or cloth materials or materials with the same property, the outer diameter of which is smaller than the inner diameter of the pillar pipe body (101), the heat transfer fluid passage is arranged in the pillar pipe body (101) in a straight shape, a bent shape or a curved shape or a shape which is randomly changed by the flexible materials or the soft materials without obstructing the heat transfer fluid passage, the upper end of the heat transfer fluid passage is provided for leading to an electric energy application device assembly (108) arranged at the upper section of the pillar pipe body (101) or a radiator (104) which the heat transfer fluid passage belongs to, the lower end of the heat transfer fluid passage is provided for leading to the middle section or extending to the lower section of the pillar pipe body (101), the size difference is formed between the outer diameter of the inner pipe (103) and the inner diameter of the pillar pipe body (101) so as to form a reserved, one or more fluid pumps (105) are arranged in series at selected positions of the flow path, and an electric energy application device assembly (108) is arranged in a space between the upper end of the inner pipe (103) and the upper section of the strut pipe body (101).

The inner pipe (103) comprises a pipe body which is made into a circular shape or other geometric shapes, and one of the pipe body which is made of a hard material, a flexible material or a soft material with a heat insulation characteristic, or the other of the pipe body which is made of a hard material, a flexible material or a soft material with a better heat conduction characteristic, wherein the outer part of the pipe body is coated with a heat insulation material, or the other of the pipe body which is made of a hard material, a flexible material or a soft material with a better heat conduction characteristic, wherein the heat insulation material is sleeved in the pipe body, or the other of the pipe body which is made of a hard material, a flexible material or a soft material with a better heat conduction.

-a fluid pump (105): the pump driven by the electric motor is used for pumping gaseous or liquid heat transfer fluid according to the flow direction and flow rate of the operation fluid driven by the pump.

-an electrical energy application device assembly (108): the device is composed of a light-emitting device driven by electric energy, a power generation device driven by external gas or liquid fluid kinetic energy, a device which is driven by light energy to generate electric energy and generates heat loss along with the electric energy, and/or a transformer and/or a motor driven by electric energy, and peripheral devices, a control circuit device, an overload protection device and a temperature protection device which assist the operation of an electric energy application device assembly (108) are provided according to the selection and arrangement of requirements.

The heat dissipation structure and application device of the internal circulation heat transfer fluid formed by the embedded pillar tube body, wherein the pumping of the fluid pump (105) causes the gaseous or liquid heat transfer fluid to flow through the heat transfer fluid outlet at the upper end of the inner tube (103), the electric energy application device assembly (108) or the heat transfer fluid passage of the heat sink (104) associated with heat loss in operation, then flow through the heat transfer fluid passage formed by the space between the inside of the pillar tube body (101) and the inner tube (103) to lead to the lower tube body of the pillar tube body (101), and then flow back from the heat transfer fluid inlet at the lower end of the inner tube (103) to form a closed circulation heat transfer fluid loop, or the sequence and the flow direction of the heat transfer fluid pumped by the fluid pump (105) are opposite, and the closed circulation heat transfer fluid loop with the opposite flow direction and sequence is formed, so that the heat transfer fluid flows through the electric energy application device assembly (108) or the outer surface of the heat sink (104) associated with the heat transfer fluid And/or the exposed part of the outer surface of the pillar pipe body (101) and the external gaseous or liquid or solid environment are operated at the same temperature, and/or heat transfer fluid pumped by a fluid pump (105) is used for transferring temperature energy to the stratum or liquid through the embedded section of the pillar pipe body (101) arranged in the stratum or the liquid of the natural temperature energy body of the superficial layer.

The embedded pillar tube forms an internal circulation heat transfer fluid heat dissipation structure and an application device, which is provided with an upper section tube of a pillar tube (101) of an electric energy application device assembly (108), a shell (106) can be further additionally arranged to protect the electric energy application device assembly (108), and a heat transfer fluid passage (107) is formed by a space formed by the outer surface of the electric energy application device assembly (108) or the outer surface of a radiator (104) of the electric energy application device assembly to transfer heat transfer fluid.

Fig. 3 is a schematic view of the main structure of fig. 1 with a housing.

Fig. 4 is a schematic view of the cross-section X-X of fig. 3.

As shown in fig. 3 and 4, it mainly consists of:

-a prop tube (101): for the hollow pipe body structure that constitutes by the material that has mechanical strength, the body has upper segment body, middle section body, hypomere body, wherein:

the upper section of the pipe body is mainly used for arranging an electric energy application device assembly (108) and a shell (106);

the middle pipe body is used for forming a supporting function and conducting heat energy between the inside and the outside of the pipe;

the lower pipe body is arranged in the stratum or liquid of the natural temperature energy body of the superficial layer of the earth surface for transmitting heat energy.

The pillar tube (101) comprises a tube body made into a circular shape or other geometric shapes, and is made of a material with mechanical strength and better heat conduction characteristics or a material with heat insulation characteristics; the pillar tube (101) may be provided with heat conductive fins (2001) on the outside of the tube as required.

-an inner tube (103): the heat transfer fluid passage is a pipe body which is composed of hard materials, such as metal materials or flexible materials or soft materials, such as plastic materials or cloth materials or materials with the same property, the outer diameter of which is smaller than the inner diameter of the pillar pipe body (101), the heat transfer fluid passage is arranged in the pillar pipe body (101) in a straight shape, a bent shape or a curved shape or a shape which is randomly changed by the flexible materials or the soft materials without obstructing the heat transfer fluid passage, the upper end of the heat transfer fluid passage is provided for leading to an electric energy application device assembly (108) arranged at the upper section of the pillar pipe body (101) or a radiator (104) which the heat transfer fluid passage belongs to, the lower end of the heat transfer fluid passage is provided for leading to the middle section or extending to the lower section of the pillar pipe body (101), the size difference is formed between the outer diameter of the inner pipe (103) and the inner diameter of the pillar pipe body (101) so as to form a reserved, one or more fluid pumps (105) are arranged in series at selected positions of the flow path, and an electric energy application device assembly (108) is arranged in a space between the upper end of the inner pipe (103) and the upper section of the strut pipe body (101).

The inner pipe (103) comprises a pipe body which is made into a circular shape or other geometric shapes, and one of the pipe body which is made of a hard material, a flexible material or a soft material with a heat insulation characteristic, or the other of the pipe body which is made of a hard material, a flexible material or a soft material with a better heat conduction characteristic, wherein the outer part of the pipe body is coated with a heat insulation material, or the other of the pipe body which is made of a hard material, a flexible material or a soft material with a better heat conduction characteristic, wherein the heat insulation material is sleeved in the pipe body, or the other of the pipe body which is made of a hard material, a flexible material or a soft material with a better heat conduction.

-a fluid pump (105): the pump driven by the electric motor is used for pumping gaseous or liquid heat transfer fluid according to the flow direction and flow rate of the operation fluid driven by the pump.

-a housing (106): the heat transfer fluid is pumped by a fluid pump (105), flows to a space formed by a shell (106) and the electric energy application device assembly (108) from a heat transfer fluid outlet at the upper end of an inner pipe (103), flows to a heat transfer fluid passage formed by a space between the inner diameter of a pillar pipe body (101) and the outer diameter of the inner pipe (103) to a lower pipe body of the pillar pipe body (101), and flows back through a heat transfer fluid inlet at the lower end of the inner pipe (103) to form a closed circulation heat transfer fluid loop, or flows back in an opposite direction by changing the flow direction of the heat transfer fluid pumped by the fluid pump (105) to form closed circulation heat transfer fluid.

-an electrical energy application device assembly (108): the device is composed of a light-emitting device driven by electric energy, a power generation device driven by external gas or liquid fluid kinetic energy, a device which is driven by light energy to generate electric energy and generates heat loss along with the electric energy, and/or a transformer and/or a motor driven by electric energy, and peripheral devices, a control circuit device, an overload protection device and a temperature protection device which assist the operation of an electric energy application device assembly (108) are provided according to the selection and arrangement of requirements.

-an electronic control device (112): is made up of solid-state or electromechanical components or chips and associated operating software, with or without the devices being selectively configured as desired.

-a temperature protection device (102) comprising an electromechanical thermal switch or thermal fuse, or a solid state temperature sensing element or solid state temperature switching element, for switching off the load or for switching off part of the load or reducing the power of the load, either directly or by operation of an electrical control device (112), when the load is overheated, this device being optionally provided or not.

The heat transfer fluid pumped by a fluid pump (105) arranged in series in the heat transfer fluid flow path flows from a heat transfer fluid outlet at the upper end of an inner pipe (103), flows through the inner part of an electric energy application device assembly (108) and/or a space arranged between the outer part of the electric energy application device assembly (108) and a closed shell, then flows through a space of a fluid passage formed between the inner diameter of a support pipe body (101) and the outer diameter of the inner pipe (103), and then flows back through a heat transfer fluid inlet at the lower end of the inner pipe (103) to form a closed circulation flow, or flows back in a reverse flow direction to form a closed circulation flow by virtue of the change of the flow direction of the heat transfer fluid pumped by the fluid pump (105), and the surface of a closed shell (106) is exposed to the outside by virtue of the temperature energy of the gaseous or liquid heat transfer fluid pumped by the fluid pump (105), passes through the outer surface of the electric energy application device assembly (108) and/or is arranged, and/or the exposed part of the pillar body (101) is in uniform temperature operation with the external gaseous or liquid or solid environment, and/or the heat transfer fluid pumped by the fluid pump (105) is used for transferring temperature energy to the stratum or the liquid through the embedded section of the pillar body (101) arranged in the stratum or the liquid of the natural temperature energy body of the superficial layer.

The electric energy application device assembly (108) in the internal circulation heat transfer fluid heat dissipation structure and application device formed by the embedded pillar tube comprises, for example, an electric energy-to-light energy illumination device (109), such as a Light Emitting Diode (LED) illumination device and/or a photo-electric Panel (110), such as a Solar Panel and/or a wind power generation device (111) and/or a transformer (444), and/or an electric energy driven motor (333), and peripheral devices, a control circuit device, an overload protection device and a temperature protection device for assisting the operation of the electric energy application device assembly (108) are selectively provided according to requirements, and various embodiments thereof are described below.

Fig. 5 is a schematic diagram of the main structure of the electrical energy application device assembly (108) formed by the electrical energy to optical energy lighting device (109) according to the present invention.

Fig. 6 is a schematic view of the cross-section X-X of fig. 5.

As shown in fig. 5 and fig. 6, the main structure of the device includes a pillar tube (101), an inner tube (103), and a fluid pump (105), and the power application device assembly (108) is a power to light lighting device (109) and/or Light Emitting Diode (LED) that converts power to light with heat loss, and optionally provides peripheral devices, control circuit devices, overload protection devices, and temperature protection devices for assisting the power to light lighting device (109).

Wherein: the heat transfer fluid pumped by the fluid pump (105) flows through the electric energy-to-light energy lighting device (109) or the heat transfer fluid passage (107) on the surface or inside the radiator (104), the temperature energy transmitted by the heat transfer fluid passage (107) is subjected to temperature equalization operation with the external gaseous or liquid or solid environment through the exposed part of the outer surface of the pillar tube body (101), and/or the heat transfer fluid pumped by the fluid pump (105) is used for transmitting the temperature energy to the stratum or the liquid through the embedded section of the pillar tube body (101) arranged in the stratum or the liquid of the natural temperature energy body on the superficial layer;

-an electrical to optical energy lighting device (109): the lighting device comprises various gas lamps, solid-state lighting LEDs, OLEDs and other electric energy-to-light energy lighting devices and related peripheral devices such as a light-transmitting body (1061), and further comprises a display screen, a signboard, a sign or a warning sign which operates by means of light energy of the electric energy-to-light energy lighting device (109);

-a fluid pump (105): the pump is driven by an electric motor, and is used for pumping gaseous or liquid heat transfer fluid according to the flow direction and flow rate of the operation fluid driven by the pump;

-an electronic control device (112): is composed of solid-state or electromechanical elements or chips and related operating software; the application of the present embodiment is for controlling the input voltage, current and working temperature of the lighting device (109) converting electrical energy into optical energy and controlling the operation timing of the fluid pump (105);

-a temperature protection device (102) comprising an electromechanical thermal switch or thermal fuse, or a solid-state temperature detection element or solid-state temperature switch element, for being arranged on the electrical to optical energy lighting device (109) or the associated heat sink (104), for switching off the load or part of the load or reducing the load power or operating the fluid pump (105) directly or by operation of the electrical control device (112) in case of an abnormal temperature; the device is optionally configured or not configured as desired.

Fig. 7 is a schematic diagram of the main structure of the present invention applied to an electric energy application device assembly (108) formed by a photo-electric power generation plate (110).

Fig. 8 is a schematic view of the cross-section X-X of fig. 7.

As shown in fig. 7 and 8, the main structure of the device includes a pillar tube (101), an inner tube (103), and a fluid pump (105), and the power application device assembly (108) is formed by a Photovoltaic panel (110) that converts light energy into electric energy and generates heat, and optionally provides a peripheral device, a control circuit device, an overload protection device, and a temperature protection device for assisting the operation of the Photovoltaic panel (110).

Wherein: the heat transfer fluid pumped by the fluid pump (105) flows through a heat transfer fluid passage (107) on the back surface of the Photovoltaic panel (110) or on the surface or inside of the radiator (104), the temperature energy transmitted by the heat transfer fluid passage (107) is subjected to temperature equalization operation with the external gaseous or liquid or solid environment through the exposed part of the outer surface of the pillar tube body (101), and/or the heat transfer fluid pumped by the fluid pump (105) is further used for transmitting the temperature energy to the stratum or the liquid through the embedded section of the pillar tube body (101) arranged in the stratum or the liquid of the natural temperature energy body on the shallow surface;

-photo-electric panels (photo-voltaic) (110): the Solar Photovoltaic power generation device is composed of various Photovoltaic power generation boards (Photovoltaic) which receive light to generate electric energy and output the electric energy, such as Solar power generation boards (Solar Panel) and related peripheral devices;

-a fluid pump (105): the pump is driven by an electric motor, and is used for pumping gaseous or liquid heat transfer fluid according to the flow direction and flow rate of the operation fluid driven by the pump;

-an electronic control device (112): is composed of solid-state or electromechanical elements or chips and related operating software; the application of the present embodiment is for controlling the output voltage, current and working temperature of the Photovoltaic panel (110) and controlling the operation timing of the fluid pump (105);

a temperature protection device (102) which is composed of an electromechanical thermal switch or a thermal cut-off fuse, or a solid temperature detection element or a solid temperature switch element and is used for cutting off the load or cutting off part of the load or reducing the load power or operating the fluid pump (105) directly or through the operation of an electric control device (112) when the temperature of the photo-electric panel (110) is abnormal; the device is optionally configured or not configured as desired.

Fig. 9 is a schematic view showing a main structure of the present invention applied to an electric power application device assembly (108) formed by a wind power generation device (111).

As shown in fig. 9, the main structure of the device includes a pillar pipe (101) for installing on the natural temperature energy body (100) on the shallow layer of the earth surface, an inner pipe (103), and a fluid pump (105), and the power application device assembly (108) is composed of a wind power generator (222) of a wind power generation device (111), and is selectively installed with a peripheral device, a control circuit device, an overload protection device, and a temperature protection device for assisting the operation of the wind power generation device (111) according to the requirement.

Wherein: the heat transfer fluid pumped by the fluid pump (105) passes through a wind power generator (222) of the wind power generation device (111) and/or a heat transfer fluid passage in a radiator of the wind power generation device, or further comprises an electric control device (112) and/or a heat transfer fluid passage in a radiator of the wind power generation device, and an inner pipe (103), an interval space between the inner pipe (103) and the inner part of the strut tube body (101) form a closed heat transfer fluid passage together, and the heat transfer fluid flows in the closed heat transfer fluid passage, and is supplied to soil or liquid of an external gaseous or solid or liquid environment and/or shallow surface natural temperature energy body for temperature equalization operation by virtue of an exposed part of the outer surface of the strut tube body (101);

-a wind power plant (111): comprises a wind turbine blade, a driven wind power generator (222) and/or an electric control device (112) and related peripheral devices, wherein the wind power generator (222) and/or the electric control device (112) are mainly used for receiving heat dissipation;

-a fluid pump (105): a pump driven by a wind power driving rotating shaft or an electric motor is used for pumping gaseous or liquid heat transfer fluid according to the controlled flow direction and flow rate;

-an electronic control device (112): the system is composed of solid-state or electromechanical elements or chips and related operation software, and is used for controlling the operation of the system in the wind power generation device (111), wherein the system comprises the output voltage, the current and the working temperature of a wind power generator (222), the direct current and alternating current conversion, the parallel control of alternating current output electric energy and a mains supply system, and the operation time of a fluid pump (105);

-a temperature protection device (102) comprising an electromechanical thermal switch or thermal fuse, or a solid-state temperature detection element or solid-state temperature switch element, for controlling the operation of the wind turbine (222) and/or the wind turbine (111) system, directly or via an electrical control device (112), and for controlling the fluid pump (105) when the wind turbine (111) is at an abnormal temperature; the device is optionally configured or not configured as desired.

Fig. 10 is a schematic diagram showing the main structure of the present invention applied to an electric energy application device assembly (108) formed by a transformer (444).

As shown in fig. 10, the main components of the device include a pillar body (101), an inner tube (103), and a fluid pump (105), and the power application assembly (108) is composed of a transformer (444), and optionally provides a peripheral device, a control circuit device, an overload protection device, and a temperature protection device for assisting the transformer (444)) in operation.

Wherein: the heat transfer fluid pumped by the fluid pump (105) flows through the heat transfer fluid passage (107) on the surface or inside of the transformer (444) or the radiator (104) to which the transformer belongs, the temperature energy transmitted by the heat transfer fluid passage (107) is equalized with the external gaseous or liquid or solid environment through the exposed part of the outer surface of the pillar tube body (101), and/or the heat transfer fluid pumped by the fluid pump (105) is further used for transmitting the temperature energy to the stratum or the liquid through the embedded section of the pillar tube body (101) arranged in the stratum or the liquid of the shallow natural temperature energy body on the ground surface;

-a transformer (444): the transformer is provided with a winding, a magnetic conduction magnetic circuit and a shell and is used for inputting and outputting single-phase or three-phase (including multiphase) alternating current electric energy or inputting and outputting pulse electric energy, the transformer comprises a dry type or a separation winding type transformer with a wet type structure and gas inside, and a pipeline heat dissipation structure for fluid to pass through is arranged on the surface or the outside of the transformer or a fluid inlet and outlet is arranged for the fluid to enter and exit the inner space of the transformer; the transformer is combined with the pillar tube body (101) by a transformer supporting frame (445);

-a fluid pump (105): the pump is driven by an electric motor, and is used for pumping gaseous or liquid heat transfer fluid according to the flow direction and flow rate of the operation fluid driven by the pump;

-an electronic control device (112): is composed of solid-state, or electromechanical elements, or chips and related operating software, and is applied in the present embodiment for controlling the output voltage, current and operating temperature of the transformer (444) and the operating timing of the fluid pump (105);

-temperature protection means (102) comprising an electromechanical thermal switch or thermal fuse, or a solid-state temperature detection element or solid-state temperature switching element, for disconnecting the load or part of the load or reducing the load power, directly or by operation of the electrical control means (112), in case of an abnormal temperature of the transformer (444), and for operating the fluid pump (105); the device is optionally configured or not configured as desired.

Fig. 11 is a schematic view showing a main structure of the present invention applied to an electric power application device assembly (108) constituted by an electric power driving motor (333).

As shown in fig. 11, the main components of the device include a pillar tube (101), an inner tube (103), and a fluid pump (105), and the power application device assembly (108) is composed of a power driving motor (333), and optionally includes a peripheral device, a control circuit device, an overload protection device, and a temperature protection device for assisting the motor (333) in operation.

Wherein: the heat transfer fluid pumped by the fluid pump (105) flows through the electric energy driving motor (333) or the heat transfer fluid passage (107) on the surface or inside the radiator (104) of the electric energy driving motor, the temperature energy transmitted by the heat transfer fluid passage (107) is equalized with the external gaseous or liquid or solid environment through the exposed part of the outer surface of the pillar tube body (101), and/or the heat transfer fluid pumped by the fluid pump (105) is used for transmitting the temperature energy to the stratum or the liquid through the embedded section of the pillar tube body (101) arranged in the stratum or the liquid of the natural temperature energy of the shallow layer of the ground.

-motor (333): comprises a rotary motor driven by an AC or DC power supply to output rotary kinetic energy, for driving a motor to drive a load (334).

-a fluid pump (105): the pump driven by the electric motor is used for pumping gaseous or liquid heat transfer fluid according to the flow direction and flow rate of the operation fluid driven by the pump.

-an electronic control device (112): the device is composed of a solid state, or electromechanical device, or a chip and related operation software, and is applied to control the input voltage, current and working temperature of the electric driving motor (333) and the operation timing of the fluid pump (105).

-temperature protection means (102) comprising an electromechanical thermal switch or thermal fuse, or a solid-state temperature detection element or solid-state temperature switching element, for disconnecting the load or part of the load or reducing the load power, directly or by operation of the electronic control means (112), in case of an abnormal temperature of the electric drive motor (333), and for operating the fluid pump (105); the device is optionally configured or not configured as desired.

The inner circulation heat transfer fluid heat dissipation structure and the application device are formed by the embedded pillar body, the upper section and the inner pipe (103) of the pillar body (101) are further formed by a multi-branch rod structure, so that a plurality of same or different electric energy application device assemblies (108) can be arranged, and the middle section and the lower section of the pillar body are shared.

Fig. 12 is a schematic view of the main structure of the pillar body 101 with a multi-branch structure for installing a plurality of power application device assemblies 108 and sharing the middle and lower sections of the pillar body 101.

As shown in fig. 12, the main structure of the device includes the pillar body (101), the inner tube (103), and the fluid pump (105), wherein the upper section of the pillar body (101) is a multi-branch structure for providing a plurality of power application device assemblies (108), and optionally providing peripheral devices, control circuit devices, overload protection devices, and temperature protection devices for assisting the power application device assemblies (108) to operate according to the requirements, and the middle section and the lower section of the pillar body (101) are shared, and the same or different power application device assemblies (108) are respectively disposed on the upper section of the pillar body (101) to be multi-branch, and the inner tube (103) is disposed inside the pillar body (101) relatively.

Wherein: the thermal energy transferred by the heat transfer fluid pumped by the fluid pump (105) flowing through the surface or internal heat transfer fluid passage (107) of the respective electric energy application device assembly (108) or the heat sink (104) to which the fluid pump belongs is equalized with the external gaseous or liquid or solid environment, and/or the thermal energy is further transferred to the stratum or the liquid by the heat transfer fluid pumped by the fluid pump (105) through the support column pipe body (101) embedded section arranged in the stratum or the liquid of the natural thermal energy body of the superficial layer.

The present invention relates to a heat dissipation structure and application device of internal circulation heat transfer fluid formed by embedded pillar tube, wherein the structure of the heat transfer fluid flow path formed by the lower section of the pillar tube (101) and the inner tube (103) has many ways, and the following examples are given to illustrate the feasibility, but not to limit, and still belong to the scope of the present invention under the same function operation; the structural modes of the strut pipe body (101) and the inner pipe (103) comprise one or more of the following.

Fig. 13 shows one illustrative view of the root canal structure of the present invention.

FIG. 14 is a schematic cross-sectional view taken along line X-X of FIG. 13.

As shown in fig. 13 and 14, the column tube body (101) and the inner tube (103) are arranged coaxially or approximately in parallel, and a space for passing a heat transfer fluid is provided around the inner tube (103) and between the column tube body (101) and the inner tube (103), and the inner tube (103) disposed inside the column tube body (101) is shorter than the column tube body (101), and a space for passing a heat transfer fluid is formed by fixing the lower end thereof to a lower bottom closed portion of the column tube body (101) by a bracket (1033) with a difference in length.

Fig. 15 shows a second illustrative view of the root canal structure of the present invention.

FIG. 16 is a schematic view of the cross-section X-X of FIG. 15.

As shown in fig. 15 and 16, the pillar tube body (101) and the inner tube (103) are arranged in parallel, the lower end of the inner tube (103) arranged inside the pillar tube body (101) is connected to the lower bottom closed part of the pillar tube body (101), and the lower end or the lower section of the inner tube (103) has a space for passing a heat transfer fluid, which is provided with a transverse hole (1031) or a notch (1032) penetrating through the inner tube body.

Fig. 17 shows a third illustrative view of the root canal structure of the present invention.

FIG. 18 is a schematic cross-sectional view taken along line X-X of FIG. 17.

As shown in fig. 17 and 18, the column pipe body (101) is eccentrically coupled to the inner pipe (103), and the lower end of the inner pipe (103) disposed inside the column pipe body (101) is short and has a length difference from the lower bottom closed portion of the column pipe body (101) to form a space through which a heat transfer fluid passes.

FIG. 19 shows a fourth illustrative view of the root canal structure of the present invention.

FIG. 20 is a schematic cross-sectional view taken along line X-X of FIG. 19.

As shown in fig. 19 and 20, the column tube body (101) is arranged in parallel with two or more inner tubes (103), and the lower end of the inner tube (103) arranged inside the column tube body (101) is short and has a length difference with the lower bottom closed part of the column tube body (101) to form a space for passing a heat transfer fluid.

Fig. 21 shows a fifth illustrative view of the root canal structure of the present invention.

FIG. 22 is a schematic cross-sectional view taken along line X-X of FIG. 21.

As shown in fig. 21 and 22, the structure is mainly that a pillar tube (101) and an inner tube (103) are coaxially or approximately parallel to each other, a space for passing a heat transfer fluid is provided between the periphery of the inner tube (103) and the pillar tube (101) and the inner tube (103), the inner tube (103) disposed inside the pillar tube (101) is shorter than the pillar tube (101), a length difference is provided between the lower end of the inner tube and the lower bottom closed portion of the pillar tube (101) to form a space for passing the heat transfer fluid, and a spiral flow guide structure (2003) is further provided between the pillar tube (101) and the inner tube (103) to increase the length of a flow path of the heat transfer fluid between the pillar tube (101) and the inner tube (103).

The heat dissipation structure and application device of the inner circulation heat transfer fluid formed by the embedded pillar tube can also shorten the inner tube (103) arranged inside the pillar tube (101) and extend from the upper end to the upper section or the middle section of the pillar tube (101) without extending to the lower section, comprising:

fig. 23 is a schematic structural view of an embodiment of the present invention in which the lower end of the inner tube (103) is shortened and does not extend to the lower section of the pillar tube (101) in the examples of fig. 13 and 14.

As shown in fig. 23, the column tube body (101) and the inner tube (103) are arranged coaxially or approximately in parallel, and a space for passing a heat transfer fluid is provided around the inner tube (103) and between the column tube body (101) and the inner tube (103), and the inner tube (103) arranged inside the column tube body (101) is shorter than the column tube body (101), and extends only to the upper or middle section of the column tube body (101) without extending to the lower section, thereby shortening the flow path length of the heat transfer fluid.

Fig. 24 is a schematic structural view illustrating an embodiment of the present invention in which the lower end of the inner tube (103) is shortened and does not extend to the lower section of the pillar tube (101) in the examples of fig. 17 and 18.

As shown in fig. 24, the inner pipe 103 is eccentrically coupled to the pillar tube 101, and the lower end of the inner pipe 103 disposed inside the pillar tube 101 is shorter than the pillar tube 101, and extends only to the upper or middle section of the pillar tube 101 without extending to the lower section, thereby shortening the flow path length of the heat transfer fluid.

Fig. 25 is a schematic structural view of an embodiment of the present invention in which the lower end of the inner tube (103) is shortened and does not extend to the lower section of the pillar tube (101) in the embodiment of fig. 19 and 20.

As shown in fig. 25, the column tube body (101) is arranged in parallel with two or more inner tubes (103), and the lower end of the inner tube (103) arranged inside the column tube body (101) is shorter than the column tube body (101), and extends only to the upper or middle section of the column tube body (101) without extending to the lower section, thereby shortening the flow path length of the heat transfer fluid.

The embedded pillar tube forms an internal circulation heat transfer fluid heat dissipation structure and an application device, wherein the pillar tube for transmitting the internal circulation heat transfer fluid can further be formed by a U-shaped tube, which is described as follows:

fig. 26 is a schematic structural view showing an embodiment of the strut tubular body of the present invention, which is composed of tubular columns (301) and (302) in the form of U-shaped tubular bodies.

FIG. 27 is a schematic view of the cross-section X-X of FIG. 26.

As shown in fig. 26 and 27, it is mainly constituted by the structure that the columns (201), (202) of the U-shaped pipe body are higher and lower to the electric energy application device assembly (108), the columns (201), (202) of the U-shaped pipe body are used for respectively leading to the inlet and the outlet of the heat transfer fluid passage formed in the electric energy application device assembly (108) and/or the internal space formed by the external surface of the heat sink (104) and the shell (106), wherein the column (201) of the U-shaped pipe body is used for leading to the inlet, the column (202) of the U-shaped pipe body is used for leading to the outlet, the lower section of the U-shaped pipe body is used for forming the U-shaped pipe body bending section (200) to form the loop of the heat transfer fluid, and by means of more than one fluid pump (105) arranged in the heat transfer fluid passage, the U-shaped pipe body bending section (200) and the adjacent lower section are directly buried in the natural temperature energy body (100) on the shallow layer of the ground surface; or further bending the U-shaped pipe body back section (200) and the adjacent lower section to be coated in a columnar heat conduction coating body (2002), wherein the heat conduction coating body (2002) is arranged in the natural temperature energy body (100) on the shallow layer of the ground surface.

The pipe columns (201), (202) of the U-shaped pipe body, wherein the pipe column (202) of the U-shaped pipe body comprises a pipe body which is made into a round shape or other geometric shapes, and is made of a material with mechanical strength and better heat conduction characteristics or a material with heat insulation characteristics; the pipe column (201) of the U-shaped pipe body comprises a pipe body which is made into a circular shape or other geometric shapes, and one of the pipe body which is made of a hard material, a flexible material or a soft material with a heat insulation characteristic, or the other of the pipe body which is made of a hard material, a flexible material or a soft material with a better heat conduction characteristic, wherein the outside of the pipe body is coated with a heat insulation material, or the other of the pipe body which is made of a hard material, a flexible material or a soft material with a better heat conduction characteristic, and the inside of the pipe body is sleeved with a heat insulation material, or the other of the pipe body which is made of a hard material, a flexible material or a soft material.

The columns (201), (202) of the U-shaped pipe body can be provided with heat conduction fins (2001) between the pipe bodies or outside the pipe bodies as required.

Fig. 28 is a second structural view of the strut tubular body of the present invention constructed from tubular legs (301) and (302) in the form of a U-shaped tubular body.

FIG. 29 shows a side view of the U-shaped tube of FIG. 28.

FIG. 30 is a schematic view of the cross-section X-X of FIG. 28.

As shown in fig. 28, 29 and 30, it is mainly constituted by the structure that the columns (301), (302) of the U-shaped pipe body are connected to the electric energy application device assembly (108) at the left and right sides, the columns (301), (302) of the U-shaped pipe body are respectively connected to the inlet and the outlet of the heat transfer fluid passage formed in the electric energy application device assembly (108) and/or the heat sink (104) belonging thereto, or the inlet and the outlet of the heat transfer fluid passage formed by the internal space formed by the exterior of the electric energy application device assembly (108) and/or the heat sink (104) belonging thereto and the shell (106), wherein the column (301) of the U-shaped pipe body is connected to the inlet, the column (302) of the U-shaped pipe body is connected to the outlet, and the lower section of the U-shaped pipe body forms the U-shaped bent section (200) to form the loop of the heat transfer fluid, and the pumping of the selected pumping flow direction is carried out by more than one fluid pump (105) which is arranged in the heat transfer fluid passage in series, and the U-shaped pipe body bending section (200) and the adjacent lower section are used for being directly buried in the natural temperature energy body (100) of the shallow layer of the ground surface; or further bending the U-shaped pipe body back section (200) and the adjacent lower section to be wrapped in the columnar heat conduction wrapping body (2002), wherein the heat conduction wrapping body (2002) is arranged in the natural temperature energy body (100) on the shallow layer of the ground surface.

The pipe columns (301) and (302) of the U-shaped pipe body, wherein the pipe column (302) of the U-shaped pipe body comprises a pipe body which is made into a round shape or other geometric shapes, and is made of a material with mechanical strength and better heat conduction characteristics or a material with heat insulation characteristics; the pipe column (301) of the U-shaped pipe body comprises a pipe body which is made into a circular shape or other geometric shapes, and one of the pipe body which is made of a hard material, a flexible material or a soft material with a heat insulation characteristic, or the other of the pipe body which is made of a hard material, a flexible material or a soft material with a better heat conduction characteristic, wherein the outside of the pipe body is coated with a heat insulation material, or the other of the pipe body which is made of a hard material, a flexible material or a soft material with a better heat conduction characteristic, and the inside of the pipe body is sleeved with a heat insulation material, or the other of the pipe body which is made of a hard material, a flexible material or a soft material.

The columns (301), (302) of the U-shaped pipe body can be provided with heat conduction fins (2001) between the pipe bodies or outside the pipe bodies as required.

Fig. 31 is a schematic view of the heat transfer fluid path for passing the liquid or gaseous heat transfer fluid formed by the space between the heat sink (104) and the housing (106) of the electrical energy application device assembly (108) and the heat sink heat transfer fluid path (1041) of the heat sink (104).

As shown in fig. 31, it is mainly configured that a heat transfer fluid passage for passing a liquid or gaseous heat transfer fluid is formed by a space between the heat sink (104) and the housing (106) of the power application device assembly (108) and a heat sink heat transfer fluid passage (1041) of the heat sink (104).

Fig. 32 is a schematic view of an application structure of a heat transfer fluid passage for passing a liquid or gaseous heat transfer fluid, which is formed by connecting U-shaped connecting pipes (1042) in series to at least two heat transfer fluid passages (1041) of a heat sink (104) of an electric energy application device assembly (108) according to the present invention.

As shown in fig. 32, it is mainly configured that the heat sink (104) of the power application device assembly (108) has at least two heat sink heat transfer fluid passages (1041), and the U-shaped connecting pipe (1042) is connected in series to form a heat transfer fluid passage for passing the liquid or gaseous heat transfer fluid.

Fig. 33 is a schematic view showing an application structure of the heat transfer fluid passage for passing the liquid or gaseous heat transfer fluid, which is formed by the space between the power application device assembly (108) and the housing (106) and the heat transfer fluid passage (1081) of the power application device assembly (108).

As shown in fig. 33, it is mainly configured to form a heat transfer fluid passage for passing a liquid or gaseous heat transfer fluid by a space between the power application device assembly (108) and the housing (106) and a heat transfer fluid passage (1081) provided in the power application device assembly (108).

Fig. 34 is a schematic view showing an application structure of the heat transfer fluid passage formed by connecting the U-shaped connecting pipe (1042) in series with at least two heat transfer fluid passages (1081) of the electric power application device assembly (108) for passing the liquid or gaseous heat transfer fluid.

As shown in fig. 34, it is mainly configured that the electric energy application device assembly (108) has at least two heat transfer fluid passages (1081) for connecting U-shaped connecting pipes (1042) in series to form a heat transfer fluid passage for passing liquid or gaseous heat transfer fluid.

Fig. 35 is a schematic view of the heat transfer fluid passage of the invention, which is formed by connecting at least one heat transfer fluid passage (1081) of the power application device assembly (108) and at least one heat sink heat transfer fluid passage (1041) of the heat sink (104) and connecting U-shaped connecting tubes (1042) in series, for passing the liquid or gaseous heat transfer fluid.

As shown in fig. 35, it is mainly configured that a heat transfer fluid passage for passing liquid or gaseous heat transfer fluid is formed by connecting a U-shaped connection pipe (1042) between at least one heat transfer fluid passage (1081) of the power application device assembly (108) and at least one heat sink heat transfer fluid passage (1041) of the heat sink (104).

FIG. 36 is a schematic view of an embodiment of the present invention in which a space for fluid to flow randomly is formed inside the heat sink (104) provided with the power application device assembly (108), and a fluid inlet/outlet passage is formed by the heat transfer fluid passage (1081) and the heat transfer fluid passage (107) between the inside of the pillar tube (101) and the outside of the nested heat transfer fluid passage (1081).

Fig. 37 is a front view of fig. 36.

As shown in fig. 36 and 37, in order to provide a space for the fluid to flow randomly inside the heat sink (104) provided with the power application device assembly (108), a fluid inlet/outlet passage is formed through the heat transfer fluid passage (1081) and the heat transfer fluid passage (107) between the inside of the pillar tube (101) and the outside of the nested heat transfer fluid passage (1081).

FIG. 38 is a second structural diagram of an embodiment of the present invention in which a space for a fluid to flow randomly is formed inside a heat sink (104) provided with an electrical energy application device assembly (108), and a fluid inlet/outlet passage is formed by a heat transfer fluid passage (1081) and a heat transfer fluid passage (107) between the inside of a pillar tube (101) and the outside of the heat transfer fluid passage (1081) in an offset fit.

Fig. 39 is a front view of fig. 38.

As shown in fig. 38 and 39, in order to provide a space for the fluid to flow randomly inside the heat sink (104) provided with the power application device assembly (108), a fluid inlet/outlet passage is formed through the heat transfer fluid passage (1081) and the heat transfer fluid passage (107) between the inside of the pillar tube (101) and the outside of the heat transfer fluid passage (1081) in the offset fitting.

FIG. 40 is a schematic structural diagram of an embodiment of the present invention in which the heat sink (104) provided with the electrical energy application device assembly (108) has a ring-shaped flow path (580) and a ring-shaped flow path (590) extending outward from the middle flow path (570) to both sides, and extends along the inner portion of the periphery of the heat sink (104) to the heat transfer fluid passage (1081), and the heat transfer fluid passage (107) between the inner portion of the pillar tube (101) and the outer portion of the heat transfer fluid passage (1081) forms a fluid inlet/outlet passage.

Fig. 41 is a front view of fig. 40.

As shown in fig. 40 and 41, the heat sink (104) for installing the power application device assembly (108) has a ring-shaped flow path (580) and a ring-shaped flow path (590) outwardly from the middle flow path (570) to both sides, and extends along the inner portion of the periphery of the heat sink (104) to the heat transfer fluid passage (1081), and the heat transfer fluid passage (107) between the inner portion of the pillar tube (101) and the outer portion of the nested heat transfer fluid passage (1081) forms a fluid inlet/outlet passage.

FIG. 42 is a second structural diagram of an embodiment of the present invention in which the heat sink (104) provided with the electrical energy application device assembly (108) has a ring-shaped flow path (580) and a ring-shaped flow path (590) extending outward from the middle flow path (570) to both sides, and extending along the inner portion of the periphery of the heat sink (104) to the heat transfer fluid passage (1081), and the heat transfer fluid passage (107) between the inner portion of the pillar tube (101) and the outer portion of the heat transfer fluid passage (1081) in an offset manner forms a fluid inlet/outlet passage.

Fig. 43 is a front view of fig. 42.

As shown in FIG. 42 and FIG. 43, the heat sink (104) for installing the power application device assembly (108) has a ring-shaped flow path (580) and a ring-shaped flow path (590) outwardly from the middle flow path (570) to both sides, and extends along the inner portion of the periphery of the heat sink (104) to the heat transfer fluid passage (1081), and the heat transfer fluid passage (107) between the inner portion of the pillar tube (101) and the outer portion of the heat transfer fluid passage (1081) in an offset fit forms a fluid inlet and outlet passage.

Fig. 44 is a third structural diagram of an embodiment of the present invention, in which the heat sink (104) provided with the electrical energy application device assembly (108) has a ring-shaped flow path (580) and a ring-shaped flow path (590) respectively extending outwards from the middle through hole (610) of the middle shunting block (600) to both sides, and extending along the inner portion of the periphery of the heat sink (104) to the heat transfer fluid passage (1081), and the heat transfer fluid passage (107) between the inner portion of the pillar tube (101) and the outer portion of the nested heat transfer fluid passage (1081) forms a fluid inlet/outlet passage.

Fig. 45 is a front view of fig. 44.

As shown in fig. 44 and 45, the heat sink (104) for installing the electrical energy application device assembly (108) has a ring-shaped flow path (580) and a ring-shaped flow path (590) outwardly from the middle through hole (610) of the middle flow dividing block (600) to both sides, extending along the inner portion of the periphery of the heat sink (104) to the heat transfer fluid passage (1081), and the heat transfer fluid passage (107) between the inner portion of the pillar tube (101) and the outer portion of the nested heat transfer fluid passage (1081) forms a fluid inlet/outlet passage.

FIG. 46 is a fourth embodiment of the present invention, in which the heat sink (104) for installing the power application device assembly (108) has a ring-shaped flow path (580) and a ring-shaped flow path (590) outwardly from the middle through hole (610) of the middle diversion block (600) to both sides, and extends along the inner portion of the periphery of the heat sink (104) to the heat transfer fluid passage (1081), and the heat transfer fluid passage (107) between the inner portion of the pillar tube (101) and the outer portion of the heat transfer fluid passage (1081) in an offset manner forms a fluid inlet/outlet passage.

Fig. 47 is a front view of fig. 46.

As shown in fig. 46 and 47, the heat sink (104) for installing the power application device assembly (108) has a ring-shaped flow path (580) and a ring-shaped flow path (590) outwardly from the middle through hole (610) of the middle diversion block (600) to both sides, respectively, extending along the inner portion of the periphery of the heat sink (104) to the heat transfer fluid passage (1081), and the heat transfer fluid passage (107) between the inner portion of the pillar tube (101) and the outer portion of the heat transfer fluid passage (1081) in the offset fit constitutes a fluid inlet and outlet passage.

FIG. 48 is a schematic view of an embodiment of the present invention in which the power application device assembly (108) is disposed upward, and a heat transfer fluid passage (1081) leading to the power application device assembly is formed by the central axial through hole (700) and the peripheral annular holes (710), and a fluid inlet/outlet flow path is formed by the heat transfer fluid passage (107) between the pillar tube (101) and the heat transfer fluid passage (1081) of the power application device assembly.

Fig. 49 is a front view of fig. 48.

As shown in fig. 48 and 49, for disposing the power application device assembly (108) upward, a heat transfer fluid passage (1081) leading to the power application device assembly is formed by the central axial through hole (700) and the peripheral annular hole (710), and a heat transfer fluid passage (107) between the pillar tube (101) and the heat transfer fluid passage (1081) of the power application device assembly constitutes a fluid inlet/outlet flow path.

FIG. 50 is a schematic view of a locking type heat dissipating ring (800) elastically installed on the exterior of the heat sink (104) according to the present invention.

As shown in fig. 50, the heat sink ring (800) is made of a material with good thermal conductivity and radiation heat dissipation characteristics for providing a heat sink ring with elasticity on the outside of the heat sink (104).

Fig. 51 is a schematic structural diagram of a shrink-fit heat dissipation ring (900) elastically added to the exterior of the heat sink (104) according to the present invention.

As shown in fig. 51, the shrink-fit heat dissipation ring (900) is made of a material with good heat conduction and radiation heat dissipation characteristics for a shrink-fit heat dissipation ring elastically added to the outside of the heat sink (104).

The above description is only a preferred embodiment of the present invention, and is not intended to limit the scope of the present invention.