阅读说明：本技术 一种水滴式矿用变压器循环制冷装置 (Water-drop type mining transformer circulating refrigeration device ) 是由 李明 于 2021-08-04 设计创作，主要内容包括：本发明公开了一种水滴式矿用变压器循环制冷装置,属于变压器散热技术领域,它可以实现在变压器正常工作时,通过散热液对变压器进行降温,当变压器温度过高时,多个与受热块接触的热膨胀半球受热膨胀,使吸附海绵内部的水受到挤压后流入制冷球上,被制冷球冷却后的水不断滴落,达到制冷效果,因变压器的热量使散热液产生的部分蒸汽依附网孔膜和冷凝机构表面,同时蒸汽遇到被制冷球制冷的水滴锥筒后冷凝为大大小小的水珠,再重新沿着引导细管滴回,达到一个循环冷却的效果,当变压器温度下降时,热膨胀半球逐渐恢复形状,使其拉动吸附海绵吸附着网孔膜表面的水分,水滴停止滴落后,硝石粉末逐渐结晶,预备下一次的使用。(The invention discloses a water-drop type mine transformer circulating refrigeration device, which belongs to the technical field of transformer heat dissipation, and can realize that when a transformer works normally, the transformer is cooled by heat dissipation liquid, when the temperature of the transformer is overhigh, a plurality of thermal expansion hemispheres contacted with a heated block are heated to expand, so that water in an adsorption sponge flows onto a refrigeration ball after being extruded, the water cooled by the refrigeration ball continuously drops to achieve the refrigeration effect, part of steam generated by the heat dissipation liquid is attached to a mesh membrane and the surface of a condensation mechanism due to the heat of the transformer, meanwhile, the steam is condensed into large and small water drops after meeting a water-drop cone cooled by the refrigeration ball, and then the water drops back along a guide thin tube again to achieve the effect of circulating cooling, when the temperature of the transformer drops, the thermal expansion hemispheres gradually recover the shape to pull the water adsorbed on the surface of the mesh membrane of the adsorption sponge, after the water drops stop dripping, the saltpeter powder is gradually crystallized for the next use.)

1. The utility model provides a mining transformer circulation refrigerating plant of water droplet formula, includes casing (1) and installs transformer (101) inside casing (1), its characterized in that: the device is characterized in that a return box (2) is fixedly connected to the shell (1), a storage box (3) is fixedly connected to the lower portion of the return box (2), a plurality of connection droppers (4) and heated pipes (5) are fixedly connected between the return box (2) and the storage box (3), the connection droppers (4) and the heated pipes (5) are communicated with the return box (2) and the storage box (3), heat dissipation liquid (41) is filled in the connection droppers (4) and the heated pipes (5), heat receiving blocks (7) are fixedly connected to the upper portion of the return box (2) above the connection droppers (4), a plurality of thermal expansion hemispheres (8) are fixedly connected to the lower side wall of the heat receiving blocks (7), push-pull rods (9) are fixedly connected to the lower side wall of the thermal expansion hemispheres (8), and pressure elastic membranes (10) are fixedly connected to the upper side inner wall of the return box (2), and a plurality of push-pull rods (9) and pressure bomb membrane (10) fixed connection, the lateral wall fixedly connected with adsorbs sponge (11) under pressure bomb membrane (10), the lateral wall fixedly connected with mesh membrane (12) under adsorbing sponge (11), connect inside fixedly connected with water droplet awl section of thick bamboo (15) of burette (4), water droplet awl section of thick bamboo (15) internally mounted has refrigeration ball (14), install condensation mechanism (13) between refrigeration ball (14) and adsorption sponge (11).

2. The water drop type mining transformer circulation refrigerating device according to claim 1, characterized in that: the side wall of the transformer (101) is fixedly connected with a plurality of uniformly distributed tubes (17), and the plurality of tubes (17) are connected with the dropper (4) and the heated tube (5) in a penetrating manner.

3. The water drop type mining transformer circulation refrigerating device according to claim 1, characterized in that: the refrigeration ball (14) comprises a storage film (141), and the interior of the storage film (141) is filled with saltpeter powder (142).

4. The water drop type mining transformer circulation refrigerating device according to claim 1, characterized in that: the condensation mechanism (13) comprises a water drop guide pipe (131) fixedly connected with the refrigeration ball (14) and the mesh membrane (12), a refrigeration guide wire (132) is inserted into the water drop guide pipe (131), and the refrigeration guide wire (132) penetrates through the mesh membrane (12) and is fixedly connected with the refrigeration mesh (133).

5. The water drop type mining transformer circulation refrigerating device according to claim 1, characterized in that: a plurality of penetration holes (151) are drilled in the water drop conical barrel (15), and the penetration holes (151) are arranged into vertical strips.

6. The water drop type mining transformer circulation refrigerating device according to claim 1, characterized in that: the side wall fixedly connected with reposition of redundant personnel dog (6) on flow back case (2), and reposition of redundant personnel dog (6) cambered surface sets up down.

7. The water drop type mining transformer circulation refrigerating device according to claim 4, wherein the water drop type mining transformer circulation refrigerating device is characterized in that: a plurality of refrigeration guide wires (134) are fixedly connected between the refrigeration guide wire (132) and the water drop guide pipe (131).

8. The water drop type mining transformer circulation refrigerating device according to claim 1, characterized in that: the transformer (101) is arranged above the storage box (3), and two side walls of the transformer (101) are respectively contacted with the connection dropper (4) and the heated tube (5).

9. The water drop type mining transformer circulation refrigerating device according to claim 1, characterized in that: the distance between the liquid level height of the heat dissipation liquid (41) and the guide thin pipe (16) is 20-30 cm.

10. The water drop type mining transformer circulation refrigerating device according to claim 1, characterized in that: the side wall fixedly connected with a plurality of heat guide wires (71) on flow-back box (2), it is a plurality of heat guide wires (71) run through flow-back box (2) and be heated piece (7) fixed connection.

Technical Field

The invention relates to the technical field of transformer heat dissipation, in particular to a water-drop type mining transformer circulating refrigeration device.

Background

A power transformer is a stationary electrical device for converting an ac voltage (current) of a certain value into another voltage (current) of the same frequency or different values, and a transformer is a stationary electrical device for converting ac voltage and current to transmit ac power. The electric energy transmission is realized according to the principle of electromagnetic induction. Transformers can be classified into power transformers, test transformers, instrument transformers, and transformers for special purposes, in terms of their use: the power transformer is necessary equipment for power transmission and distribution and power consumer distribution; the device is used for carrying out voltage withstand (boosting) test on electrical equipment by the test transformer; the instrument transformer is used for electrical measurement and relay protection (PT, CT) of a power distribution system; the transformer for special purposes comprises a furnace transformer for smelting, an electric welding transformer, a rectifier transformer for electrolysis, a small-sized regulating transformer and the like.

When the existing mining transformer runs, the loss in the winding and the iron core can generate a large amount of heat, and once the heat is not dissipated in time, the winding and other parts can be damaged,

according to the requirements of the service environment of the mining transformer, in order to avoid the phenomena that the transformer explodes to generate sparks and the like, the transformer is not required to be in direct contact with the atmosphere, so that the transformer body is required to be installed inside the shell, however, the sealed environment directly reduces the heat dissipation effect, greatly reduces the service life of the transformer, and therefore the water drop type mining transformer circulating refrigeration device is provided.

Disclosure of Invention

1. Technical problem to be solved

Aiming at the problems in the prior art, the invention aims to provide a water-drop type mining transformer circulating refrigeration device, which can guide the heat of a transformer to a heated block through a heat guide wire when the transformer generates high temperature, so that a plurality of thermal expansion hemispheres contacted with the heated block are heated and expanded, a pressure elastic membrane is extruded by expansion, water in an adsorption sponge flows into a refrigeration ball after being extruded, a refrigeration effect is generated based on the dissolution of saltpeter and water, the water cooled by the refrigeration ball continuously drops along a guide thin tube, the heat dissipation liquid is continuously cooled, partial steam generated by the heat dissipation liquid can be attached to the surfaces of a mesh membrane and a condensation mechanism due to the heat of the transformer, and the steam is condensed into large and small water drops after encountering a conical cylinder of the water drops cooled by the refrigeration ball and then drops back again along the guide thin tube, thereby achieving the effect of circulating cooling, the water after the cooling lasts the drippage, makes the temperature of radiating fluid reduce gradually, when transformer temperature descends, the thermal energy hemisphere resumes the shape gradually to draw pressure bullet membrane through the push-and-pull rod, make the absorption sponge resume the shape and produce suction, adsorb the moisture on mesh membrane surface, reach a lock water effect, after the water droplet stops dripping, the saltpeter powder crystallizes gradually, produce exothermic effect based on the saltpeter powder crystallization in-process, then can be with inside moisture evaporation, prepare next use.

2. Technical scheme

In order to solve the above problems, the present invention adopts the following technical solutions.

A water drop type mining transformer circulating refrigeration device comprises a shell and a transformer installed inside the shell, wherein a backflow box is fixedly connected onto the shell, a storage box is fixedly connected below the backflow box, a plurality of connection droppers and heated tubes are fixedly connected between the backflow box and the storage box, the connection droppers and the heated tubes are communicated with the backflow box and the storage box, heat dissipation liquid is filled in the connection droppers and the heated tubes, a heated block is fixedly connected onto the inner wall of the upper side of the backflow box above the connection droppers, a plurality of thermal expansion hemispheres are fixedly connected onto the lower side wall of the heated block, a push-pull rod is fixedly connected onto the lower side wall of the thermal expansion hemispheres, a pressure elastic membrane is fixedly connected onto the inner wall of the upper side of the backflow box, the push-pull rods are fixedly connected with the pressure elastic membrane, an adsorption sponge is fixedly connected onto the lower side wall of the pressure elastic membrane, and a mesh membrane is fixedly connected onto the lower side wall of the adsorption sponge, the connection burette is internally and fixedly connected with a water drop cone cylinder, a refrigerating ball is arranged in the water drop cone cylinder, a condensing mechanism is arranged between the refrigerating ball and the adsorption sponge, the transformer can be cooled by heat dissipation liquid when the transformer works normally, when the temperature of the transformer is too high, the heat of the transformer is guided to a heated block by a heat guide wire, a plurality of thermal expansion hemispheres which are contacted with the heated block are heated and expanded, the pressure elastic membrane is extruded by expansion, water in the adsorption sponge flows into the refrigerating ball after being extruded, a refrigerating effect is generated based on the dissolution of saltpeter and water, the water cooled by the refrigerating ball continuously drops along a guide tubule, the heat dissipation liquid is cooled continuously, partial steam generated by the heat dissipation liquid due to the heat of the transformer is attached to the surface of a mesh membrane and the condensing mechanism, and a circulating cooling effect is achieved, meanwhile, steam is condensed into water drops which are small and large after meeting a water drop conical cylinder refrigerated by a refrigerating ball, and then the water drops drop back along a guide thin tube again, the cooled water continuously drops, the temperature of the cooling liquid is gradually reduced, the cooling liquid is enabled to continuously cool the shell, when the temperature of the transformer drops, the shape of the thermal expansion hemisphere is gradually restored, the pressure elastic membrane is pulled through the push-pull rod, the adsorption sponge is enabled to restore the shape and generate suction force, the moisture on the surface of the mesh membrane is adsorbed, a water locking effect is achieved, after the water drops stop dropping, the saltpeter powder is gradually crystallized, and a heat release effect is generated in the crystallization process of the saltpeter powder, so that the moisture in the interior can be automatically evaporated for next use.

Furthermore, a plurality of uniformly distributed dropper tubes and heated tubes are fixedly connected to the side wall of the transformer, so that the refrigeration effect of the cooling liquid can be enhanced, and meanwhile, when the temperature of the transformer is too high, the cooling liquid can be rapidly heated, and the steam quantity is increased.

Furthermore, the refrigeration ball includes the storage membrane, the storage membrane is inside to be filled with the saltpeter powder, can effectively avoid saltpeter powder and water to dissolve back saltpeter powder and drop to in the radiating liquid.

Further, condensation mechanism includes the drop of water guiding tube with refrigeration ball and mesh membrane fixed connection, the inside refrigeration guide wire of pegging graft of drop of water guiding tube, the refrigeration guide wire runs through mesh membrane fixed connection and refrigerates the net, can transmit the refrigeration effect of refrigeration ball to adsorbing on the sponge, makes steam and mesh membrane contact back rapid condensation depend on mesh membrane surface for the drop of water.

Furthermore, a plurality of penetration holes are dug on the water droplet awl section of thick bamboo, and the penetration hole sets up to vertical strip, water droplet awl section of thick bamboo lower extreme fixedly connected with guide tubule, the drop of water after the condensation of being convenient for drips.

Furthermore, lateral wall fixedly connected with reposition of redundant personnel dog on the flow-back box, and reposition of redundant personnel dog cambered surface sets up down, can make steam disperse to the mesh membrane in both sides after with reposition of redundant personnel dog contact.

Furthermore, fixedly connected with is a plurality of between refrigeration guide wire and the drop guide tube, can effectively improve the refrigeration effect of refrigeration guide wire to the drop guide tube, makes steam and the rapid condensation of drop guide tube back become the drop.

Furthermore, the transformer is arranged above the storage box, and two side walls of the transformer are respectively contacted with the connection dropper and the heated tube, so that the contact surface of the transformer with the connection dropper and the heated tube is increased, and the refrigeration effect is further improved.

Furthermore, the distance between the liquid level height of the cooling liquid and the guide thin tube is 20-30cm, so that the influence of the temperature of the cooling liquid on the refrigerating effect of the refrigerating ball is avoided.

Furthermore, lateral wall fixedly connected with a plurality of heat guide wires on the flow-back box, it is a plurality of the heat guide wire runs through the flow-back box and receives hot piece fixed connection, can conduct ambient temperature to on receiving the hot piece, makes a plurality of thermal expansion hemispheres be heated the inflation.

3. Advantageous effects

Compared with the prior art, the invention has the advantages that

(1) The scheme can realize that when the transformer generates high temperature, the heat of the transformer is guided to the heated block through the heat guide wire, the plurality of thermal expansion hemispheres which are contacted with the heated block are heated and expanded, the pressure elastic membrane is extruded by utilizing the expansion, water in the adsorption sponge flows into the refrigerating ball after being extruded, a refrigerating effect is generated based on the dissolution of saltpeter and water, the water cooled by the refrigerating ball continuously drops along the guide tubule, the heat of the transformer enables partial steam generated by the heat dissipation liquid to be attached to the surfaces of the mesh membrane and the condensing mechanism, meanwhile, the steam meets the water dropping cone cooled by the refrigerating ball and is condensed into large and small water drops, and then drops back along the guide tubule again to achieve a circulating cooling effect, the cooled water continuously drops down, the temperature of the heat dissipation liquid is gradually reduced, when the temperature of the transformer drops, the thermal expansion hemisphere resumes the shape gradually to through the push-and-pull rod pulling pressure bullet membrane, make the absorption sponge resume the shape and produce suction, adsorb the moisture on mesh membrane surface, reach a lock water effect, after the water droplet stops to drip, the saltpeter powder crystallizes gradually, based on the saltpeter powder crystallization in-process produces exothermic effect, then can evaporate the moisture of inside, prepare next use.

(2) The transformer is characterized in that the plurality of uniformly distributed dropper tubes and the plurality of heated tubes are fixedly connected to the side wall of the transformer, so that the refrigerating effect of the cooling liquid can be enhanced, and meanwhile, when the temperature of the transformer is too high, the cooling liquid can be rapidly heated, and the steam quantity is increased.

(3) The refrigeration ball includes the storage membrane, and storage membrane inside is filled with the saltpeter powder, can effectively avoid saltpeter powder and water to dissolve back saltpeter powder and drop to the radiating liquid in.

(4) Condensation mechanism includes the drop of water guiding tube with refrigeration ball and mesh membrane fixed connection, and the inside grafting of drop of water guiding tube has the refrigeration to lead the silk, and the refrigeration guide silk runs through mesh membrane fixed connection has the refrigeration net, can transmit the refrigeration effect of refrigeration ball to adsorbing on the sponge, makes steam and mesh membrane contact back rapid condensation depend on mesh membrane surface for the drop of water.

(5) A plurality of penetration holes are drilled on the water drop cone, the penetration holes are arranged to be vertical strips, the lower end of the water drop cone is fixedly connected with a guide thin tube, and water drops condensed conveniently drop.

(6) Lateral wall fixedly connected with reposition of redundant personnel dog on the flow-back box, and reposition of redundant personnel dog cambered surface sets up down, can make steam disperse to the mesh membrane in both sides after with reposition of redundant personnel dog contact on.

(7) The refrigeration guide wire and the water drop guide pipe are fixedly connected in a plurality of ways, so that the refrigeration effect of the refrigeration guide wire on the water drop guide pipe can be effectively improved, and steam is rapidly condensed into water drops after being connected with the water drop guide pipe.

(8) The transformer is arranged above the storage box, and two side walls of the transformer are respectively contacted with the connection dropper and the heated tube, so that the contact surface of the transformer with the connection dropper and the heated tube is increased, and the refrigeration effect is further improved.

(9) The distance between the liquid level of the cooling liquid and the guide thin tube is 20-30cm, so that the influence of the temperature of the cooling liquid on the refrigerating effect of the refrigerating ball is avoided.

(10) Lateral wall fixedly connected with a plurality of heat guide wires on the flow-back box, a plurality of heat guide wires run through the flow-back box and are heated piece fixed connection, can make a plurality of thermal expansion hemispheres be heated the inflation on conducting to the piece that receives heat with ambient temperature.

Drawings

FIG. 1 is an external view of the present invention;

FIG. 2 is a schematic view of the structure of the connection dropper portion of the present invention;

FIG. 3 is a front cross-sectional view of the present invention;

FIG. 4 is an enlarged view taken at A in FIG. 3;

FIG. 5 is an enlarged view at B in FIG. 4;

FIG. 6 is an enlarged view at C of FIG. 5;

FIG. 7 is a schematic view of the structure of the bead guide tube of the present invention;

FIG. 8 is a schematic structural view of a refrigeration ball of the present invention;

FIG. 9 is a schematic structural diagram of a water dropping cone of the present invention;

the reference numbers in the figures illustrate:

the device comprises a shell 1, a transformer 101, a reflux box 2, a storage box 3, a connection dropper 4, a heat dissipation liquid 41, a heated tube 5, a diversion stop block 6, a heated block 7, a heat guiding wire 71, a thermal expansion hemisphere 8, a push-pull rod 9, a pressure elastic membrane 10, an adsorption sponge 11, a mesh membrane 12, a condensation mechanism 13, a water droplet guiding tube 131, a refrigeration guiding wire 132, a refrigeration net 133, a refrigeration ball 14, a storage membrane 141, saltpeter powder 142, a water droplet conical cylinder 15, a penetration hole 151 and a guide thin tube 16.

Detailed Description

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention; it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all embodiments, and all other embodiments obtained by those skilled in the art without any inventive work are within the scope of the present invention.

In the description of the present invention, it should be noted that the terms "upper", "lower", "inner", "outer", "top/bottom", and the like indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus should not be construed as limiting the present invention. Furthermore, the terms "first" and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "disposed," "sleeved/connected," "connected," and the like are to be construed broadly, e.g., "connected," which may be fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Example 1:

referring to fig. 1-5, a water-drop type mining transformer circulating refrigeration device comprises a shell 1 and a transformer 101 installed inside the shell 1, wherein a return tank 2 is fixedly connected to the shell 1, a storage tank 3 is fixedly connected to the lower portion of the return tank 2, a plurality of connection droppers 4 and heated pipes 5 are fixedly connected between the return tank 2 and the storage tank 3, the connection droppers 4 and the heated pipes 5 are both communicated with the return tank 2 and the storage tank 3, the connection droppers 4 and the heated pipes 5 are both filled with cooling liquid 41, a heated block 7 is fixedly connected to the upper inner wall of the return tank 2 above the connection droppers 4, a plurality of thermal expansion hemispheres 8 are fixedly connected to the lower side wall of the heated block 7, push-pull rods 9 are fixedly connected to the lower side walls of the thermal expansion hemispheres 8, a pressure elastic membrane 10 is fixedly connected to the upper inner wall of the return tank 2, and the push-pull rods 9 are fixedly connected to the pressure elastic membrane 10, the device is characterized in that an adsorption sponge 11 is fixedly connected to the lower side wall of a pressure elastic membrane 10, a mesh membrane 12 is fixedly connected to the lower side wall of the adsorption sponge 11, a water drop cone 15 is fixedly connected to the inside of a connection dropper 4, a refrigeration ball 14 is installed inside the water drop cone 15, a condensation mechanism 13 is installed between the refrigeration ball 14 and the adsorption sponge 11, a plurality of heat guiding wires 71 are fixedly connected to the upper side wall of a backflow box 2, the plurality of heat guiding wires 71 penetrate through the backflow box 2 and are fixedly connected with a heated block 7, the ambient temperature can be conducted to the heated block 7 through the heat guiding wires 71, a plurality of thermal expansion hemispheres 8 are heated and expanded, the pressure elastic membrane 10 is pushed through a push-pull rod 9 when the thermal expansion hemispheres 8 are expanded, the pressure elastic membrane 10 is enabled to extrude and adsorb moisture inside the sponge 11, and the pressurized water flows to the refrigeration ball 14 through a water drop guiding pipe 131, and the device can realize that the temperature of the transformer is reduced through a heat dissipation liquid 41 when the transformer normally works, when the temperature of the transformer is too high, the heat of the transformer is guided to the heated block 7 through the heat guiding wire 71, so that the plurality of thermal expansion hemispheres 8 which are in contact with the heated block 7 are heated and expanded, the pressure elastic membrane 10 is extruded by expansion, water in the adsorption sponge 11 flows onto the refrigerating ball 14 after being pressed, a refrigerating effect is generated based on dissolution of saltpeter and water, the water cooled by the refrigerating ball 14 continuously drops along the guiding tubule 16, the cooling liquid 41 is continuously cooled, partial steam generated by the cooling liquid 41 is attached to the surfaces of the mesh membrane 12 and the condensing mechanism 13 due to the heat of the transformer, a circulating cooling effect is achieved, meanwhile, the steam meets the water dropping cone 15 refrigerated by the refrigerating ball 14 and is condensed into large and small water drops, then the steam drops back along the guiding tubule 16 again, the cooled water continuously drops, and the temperature of the cooling liquid 41 is gradually reduced, make heat dissipation liquid 41 continue to cool down casing 1, when the transformer temperature descends, thermal expansion hemisphere 8 resumes the shape gradually, and through push-and-pull rod 9 pulling pressure bullet membrane 10, make absorption sponge 11 resume the shape and produce suction, adsorb the moisture on mesh membrane 12 surface, reach a lock water effect, after the water droplet stops dripping, saltpeter powder 142 crystallizes gradually, produce exothermic effect based on saltpeter powder 142 crystallization process, then can evaporate the moisture of inside automatically, prepare next use.

Referring to fig. 5-9, the refrigeration ball 14 includes a storage film 141, the storage film 141 is filled with the saltpeter powder 142, the saltpeter powder 142 can be effectively prevented from dropping into the heat dissipation liquid 41 after being dissolved by water, a refrigeration effect is generated based on the saltpeter and the water, a plurality of penetration holes 151 are drilled in the water-drop cone 15, the penetration holes 151 are arranged in a vertical strip shape, the lower end of the water-drop cone 15 is fixedly connected with the guide tubule 16, and the water cooled by the refrigeration ball 14 continuously drops along the guide tubule 16, so that the heat dissipation liquid 41 can be cooled.

Referring to fig. 3, a plurality of uniformly distributed 17 are fixedly connected to the side wall of the transformer 101, and the plurality of 17 are disposed by penetrating and connecting the dropper 4 and the heated tube 5, so that the cooling effect of the heat dissipation liquid 41 can be enhanced, and when the temperature of the transformer is too high, the heat dissipation liquid 41 can be rapidly heated, and thus the generated steam floats upwards.

Referring to fig. 3-4, a diversion block 6 is fixedly connected to the upper side wall of the return box 2, and the diversion block 6 is disposed with its arc surface facing downward, so that the steam can be dispersed to the mesh membranes 12 on both sides after contacting the diversion block 6.

Referring to fig. 6, the condensing mechanism 13 includes a water drop guiding tube 131 fixedly connected to the refrigeration ball 14 and the mesh membrane 12, a refrigeration guiding wire 132 is inserted into the water drop guiding tube 131, the refrigeration guiding wire 132 penetrates through the mesh membrane 12 and is fixedly connected to a refrigeration net 133, so as to transmit the refrigeration effect of the refrigeration ball 14 to the adsorption sponge 11, a plurality of wires 134 are fixedly connected between the refrigeration guiding wire 132 and the water drop guiding tube 131, so as to effectively improve the refrigeration effect of the refrigeration guiding wire 132 on the water drop guiding tube 131, so that the steam is rapidly condensed into water drops after contacting the water drop guiding tube 131, after the steam is dispersed through the cambered surface of the diversion baffle 6, the steam is contacted with the mesh membrane 12 and is rapidly condensed into water drops attached to the surface of the mesh membrane 12, and drops along the condensing mechanism 13 onto the refrigeration ball 14, and finally drops into the heat dissipation liquid 41 again through the guide tubule 16, so as to achieve a circulating cooling effect.

Referring to fig. 3, the transformer 101 is disposed above the storage box 3, and two side walls of the transformer 101 are respectively in contact with the connection dropper 4 and the heated tube 5, so as to increase the contact area between the transformer 101 and the connection dropper 4 and the heated tube 5, and further improve the cooling effect.

Referring to fig. 3, the distance between the liquid level of the heat dissipating liquid 41 and the guiding tubule 1620-30cm avoids the temperature of the heat dissipating liquid 41 directly affecting the cooling effect of the cooling ball 14.

The foregoing is only a preferred embodiment of the present invention; the scope of the invention is not limited thereto. Any person skilled in the art should be able to cover the technical scope of the present invention by equivalent or modified solutions and modifications within the technical scope of the present invention.