阅读说明：本技术 一种温差辅助发电系统 (Temperature difference auxiliary power generation system ) 是由 不公告发明人 于 2020-07-12 设计创作，主要内容包括：本发明公开了一种温差辅助发电系统,包括支撑模块、转化模块和蒸发模块,支撑模块包括底板、墙体、吸热板、导温板、外机、内机、导温块和制冷二极片。本发明通过设置蒸发模块,可以将雨水收起起来,在夏天可以利用太阳的照射,将蒸发桶内部的水蒸发,从而利用蒸汽推动涡轮进行发电,通过设置支撑模块,可以利用室内外温差的特性,使制冷二极片的两侧产生温差,从而使制冷二极片产生电流,进而实现发电的目的,通过设置转化模块,可以将制冷二极片产生的直流带你转化成所需要的交流电,从而提高了本装置在使用时的兼容性。(The invention discloses a temperature difference auxiliary power generation system which comprises a support module, a conversion module and an evaporation module, wherein the support module comprises a bottom plate, a wall body, a heat absorption plate, a temperature guide plate, an outer machine, an inner machine, a temperature guide block and two refrigeration pole pieces. The solar water heater has the advantages that the evaporation module is arranged, rainwater can be collected, the water in the evaporation barrel can be evaporated by utilizing the irradiation of the sun in summer, so that steam is utilized to push the turbine to generate electricity, the temperature difference can be generated on two sides of the two refrigeration pole pieces by utilizing the characteristic of the indoor and outdoor temperature difference by arranging the support module, so that the two refrigeration pole pieces generate current, the purpose of generating electricity is further realized, the direct current generated by the two refrigeration pole pieces can be converted into required alternating current by arranging the conversion module, and the compatibility of the solar water heater during use is improved.)

1. The utility model provides a temperature difference auxiliary power generation system, includes support module (1), conversion module (2) and evaporation module (3), support module (1) including bottom plate (101), wall body (102), absorber plate (103), lead warm board (104), outer machine (105), interior machine (106), lead warm piece (107) and two pole pieces of refrigeration (108), its characterized in that: the upper surface of the bottom plate (101) is fixedly connected with a wall body (102), two sides of the inner wall of the wall body (102) are fixedly connected with heat conducting plates (104), the opposite surfaces of the two heat conducting plates (104) are fixedly connected with a refrigerating two-pole piece (108) through a heat conducting block (107), the outer sides of the refrigerating two-pole piece (108) are fixedly connected with a heat absorbing plate (103), the top of the inner wall of the wall body (102) is fixedly connected with an inner machine (106), and the top of the outer surface of the wall body (102) is fixedly connected with an outer machine (105);

the conversion module (2) comprises a direct current motor (201), a conversion middle gear support (202), a conversion middle gear (203), a conversion side gear (204), a bidirectional gear (205), a generator (206), a generator support (207), an execution power generation gear (208), an execution power generation gear support (209), a gear ring support (210), an output gear (211), a gear ring (212), a direct current motor support (213) and an input gear (214), wherein the direct current motor (201) is arranged on the side of the wall body (102), the direct current motor (201) is fixedly connected with the upper surface of the bottom plate (101) through the direct current motor support (213), an output shaft of the direct current motor (201) is fixedly connected with the output gear (211), an outer surface gear of the output gear (211) is connected with the gear ring (212), and the side surface of the gear ring (212) is fixedly connected with the gear ring support (210), the gear ring bracket (210) is fixedly connected with the upper surface of the bottom plate (101) through an executing power generation gear bracket (209), the side surface of the executing power generation gear bracket (209) is rotatably connected with an executing power generation gear (208), the executing power generation gear (208) is fixedly connected with the executing power generation gear bracket (209) through a connecting shaft, the outer surface of the executing power generation gear (208) is in gear connection with a transformation intermediate gear (203), the transformation intermediate gear (203) is rotatably connected with the executing power generation gear bracket (209) through a transformation intermediate gear bracket (202), the lower surface of the transformation intermediate gear (203) is in gear connection with a transformation lateral gear (204), the transformation lateral gear (204) is in rotational connection with the bottom plate (101), the outer surface of the transformation lateral gear (204) is in rotational connection with a bidirectional gear (205) through the bottom plate (101), and the outer surface of the bidirectional gear (205) is in gear connection with an input, a generator (206) is arranged above the input gear (214), an output shaft of the generator (206) is fixedly connected with the input gear (214), and the generator (206) is fixedly connected with the bottom plate (101) through a generator support (207);

the evaporation module (3) comprises an evaporation barrel (301), a primary reflector (302), an inner side ratchet wheel (303), a transmission belt (304), an output belt wheel (305), a belt wheel transmission shaft (306), an output belt wheel support (307), an outer side ratchet wheel (308), a turbine support (309), a turbine (310), an input belt wheel (311), a middle transmission shaft (312), an input belt wheel support (313), an input belt wheel support fixing plate (314), an evaporation connecting plate (315) and an outer side reflector (316), wherein the evaporation barrel (301) is fixedly connected with the upper surface of the bottom plate (101), the primary reflector (302) is arranged on the outer side of the bottom of the evaporation barrel (301), the primary reflector (302) is fixedly connected with the bottom plate (101), the turbine (310) is arranged at the top end inside the evaporation barrel (301), and the turbine support (309) is rotatably connected with the upper surface of the turbine (310), the turbine support (309) is fixedly connected with the bottom plate (101), the upper surface of the turbine support (309) is rotatably connected with an outer side ratchet wheel (308), the outer side ratchet wheel (308) is fixedly connected with the turbine (310) through a connecting shaft, an inner ring of the outer side ratchet wheel (308) is clamped with an inner side ratchet wheel (303), the upper surface of the inner side ratchet wheel (303) is fixedly connected with a belt wheel transmission shaft (306), the upper surface of the belt wheel transmission shaft (306) is rotatably connected with the turbine support (309) through an evaporation connecting plate (315) and an output belt wheel support (307), the upper surface of the output belt wheel support (307) is rotatably connected with an output belt wheel (305), the output belt wheel (305) is fixedly connected with the inner side ratchet wheel (303), the upper part of the bidirectional gear (205) is fixedly connected with an input belt wheel (311) through a middle connecting shaft (312), and the input belt wheel (311) is rotatably connected, the top end of the outer surface of the middle transmission shaft (312) is rotatably connected with an input belt wheel support (313), the input belt wheel support (313) is fixedly connected with the generator support (207) through an input belt wheel support fixing plate (314), an outer side reflecting cover (316) is arranged on the outer side of the primary reflecting cover (302), and the outer side reflecting cover (316) is fixedly connected with the bottom plate (101).

2. A thermoelectric assisted power generation system of claim 1, wherein: the number of the heat conducting blocks (107) and the number of the refrigerating two pole pieces (108) are twenty-eight respectively, and the twenty-eight heat conducting blocks (107) and the refrigerating two pole pieces (18) are respectively arranged on the opposite surfaces of the two heat conducting plates (104) in a rectangular shape.

3. A thermoelectric assisted power generation system of claim 1, wherein: and heat-conducting silicone grease is smeared between the opposite surfaces of the heat-conducting block (107) and the two refrigerating pole pieces (108).

4. A thermoelectric assisted power generation system of claim 1, wherein: and heat-conducting silicone grease is smeared between the opposite surfaces of the two refrigerating pole pieces (108) and the heat absorbing plate (103).

5. A thermoelectric assisted power generation system of claim 1, wherein: the positive and negative electrodes of the twenty-eight refrigerating two-pole piece (108) are connected in series.

6. A thermoelectric assisted power generation system of claim 1, wherein: the transition intermediate gear bracket (202) is rotationally connected with a transition intermediate gear (203), and the transition intermediate gear bracket (202) is fixedly connected with an execution power generation gear bracket (209).

7. A thermoelectric assisted power generation system of claim 1, wherein: the bottom of the outer surface of the primary reflector (302) is provided with a through hole.

8. A thermoelectric assisted power generation system of claim 1, wherein: the evaporation connecting plate (315) is fixedly connected with the upper surface of the turbine support (309), the output belt wheel support (307) is fixedly connected with the evaporation connecting plate (315), and the belt wheel transmission shaft (306) is rotatably connected with the output belt wheel support (307).

Technical Field

The invention relates to the technical field of environmental protection, in particular to a temperature difference auxiliary power generation system.

Background

In the power generation, the power generation power device is used to convert water energy, heat energy of fossil fuel (coal, oil, natural gas, etc.), nuclear energy, solar energy, wind energy, geothermal energy, ocean energy, etc. into electric energy. The power generation is performed by using fossil fuels in the end of the 20 th century, but the fossil fuels are few in resources and are exhausted day by day, so that people generate power by using renewable energy sources (water energy, solar energy, wind energy, geothermal energy, ocean energy and the like) more and more, and in hot summer, most people need to use an air conditioner, so that the air conditioner needs electricity, and the cost of a user in using the air conditioner is increased.

Disclosure of Invention

Aiming at the defects of the prior art, the invention provides a temperature difference auxiliary power generation system, which solves the problem that the use cost of an air conditioner is high when the air conditioner is used in summer.

In order to achieve the purpose, the invention provides the following technical scheme: the utility model provides a temperature difference auxiliary power generation system, includes support module, conversion module and evaporation module, the support module include bottom plate, wall body, absorber plate, lead the temperature board, outer machine, interior machine, lead the temperature piece and two pole pieces of refrigeration, the last fixed surface of bottom plate is connected with the wall body, and the equal fixedly connected with in both sides of wall body inner wall leads the temperature board, two lead the looks back of temperature board all through leading temperature piece fixedly connected with two pole pieces of refrigeration, the outside fixedly connected with absorber plate of two pole pieces of refrigeration, the top fixedly connected with interior machine of wall body inner wall, the top fixedly connected with outer machine of wall body surface.

The conversion module comprises a direct current motor, a conversion middle gear bracket, a conversion middle gear, a conversion lateral gear, a bidirectional gear, a generator bracket, an execution power generation gear bracket, a gear ring bracket, an output gear, a gear ring, a direct current motor bracket and an input gear, wherein the direct current motor is arranged on the lateral side of the wall body, the direct current motor is fixedly connected with the upper surface of the bottom plate through the direct current motor bracket, the output shaft of the direct current motor is fixedly connected with the output gear, the outer surface gear of the output gear is connected with the gear ring, the lateral side of the gear ring is fixedly connected with the gear ring bracket, the gear ring bracket is fixedly connected with the upper surface of the bottom plate through the execution power generation gear bracket, the lateral side of the execution power generation gear bracket is rotatably connected with the execution power generation gear, and the execution power, the gear transmission device comprises an execution power generation gear, a transmission side gear, a bottom plate, a transmission side gear, a bidirectional gear, a generator support and a transmission side gear, wherein the transmission side gear is connected with the transmission side gear, the transmission side gear is connected with the transmission side.

The evaporation module comprises an evaporation barrel, a primary reflector, an inner ratchet wheel, a transmission belt, an output belt wheel, a belt wheel transmission shaft, an output belt wheel support, an outer ratchet wheel, a turbine support, a turbine, an input belt wheel, a middle transmission shaft, an input belt wheel support fixing plate, an evaporation connecting plate and an outer reflector, wherein the evaporation barrel is fixedly connected with the upper surface of the bottom plate, the primary reflector is arranged on the outer side of the bottom of the evaporation barrel and fixedly connected with the bottom plate, the turbine is arranged at the top end inside the evaporation barrel, the upper surface of the turbine is rotatably connected with the turbine support, the turbine support is fixedly connected with the bottom plate, the upper surface of the turbine support is rotatably connected with the outer ratchet wheel, the outer ratchet wheel is fixedly connected with the turbine through a connecting shaft, the inner ring of the outer ratchet wheel is clamped with, the upper surface of band pulley transmission shaft passes through the evaporation connecting plate with the turbine support and is connected with output pulley support rotation, output pulley support's upper surface rotation is connected with output pulley, and output pulley passes through connecting axle fixed connection with inboard ratchet, intermediate drive axle fixedly connected with input pulley is passed through to the top of two-way gear, and input pulley passes through the drive belt rotation with output pulley and is connected, the top of intermediate drive axle surface rotates and is connected with input pulley support, and input pulley support passes through input pulley support fixed plate fixed connection with the generator support, the outside of elementary reflector is provided with the outside reflector, outside reflector and bottom plate fixed connection.

Preferably, the number of the heat conducting blocks and the number of the refrigerating two pole pieces are twenty-eight respectively, and the twenty-eight heat conducting blocks and the refrigerating two pole pieces are respectively arranged on the opposite surfaces of the two heat conducting plates in a rectangular shape.

Preferably, heat-conducting silicone grease is smeared between the opposite surfaces of the temperature conduction block and the two refrigerating pole pieces.

Preferably, heat-conducting silicone grease is smeared between the opposite surfaces of the two refrigeration pole pieces and the heat absorption plate.

Preferably, the positive and negative electrodes of the twenty-eight refrigeration two-pole pieces are connected in series.

Preferably, the transition intermediate gear bracket is rotationally connected with the transition intermediate gear, and the transition intermediate gear bracket is fixedly connected with the execution power generation gear bracket.

Preferably, the bottom of the outer surface of the primary reflector is provided with a through hole.

Preferably, the evaporation connecting plate is fixedly connected with the upper surface of the turbine support, the output belt wheel support is fixedly connected with the evaporation connecting plate, and the belt wheel transmission shaft is rotatably connected with the output belt wheel support.

Compared with the prior art, the invention provides a temperature difference auxiliary power generation system, which has the following beneficial effects: the solar water heater has the advantages that the evaporation module is arranged, rainwater can be collected, the water in the evaporation barrel can be evaporated by utilizing the irradiation of the sun in summer, so that steam is utilized to push the turbine to generate electricity, the temperature difference can be generated on two sides of the two refrigeration pole pieces by utilizing the characteristic of the indoor and outdoor temperature difference by arranging the support module, so that the two refrigeration pole pieces generate current, the purpose of generating electricity is further realized, the direct current generated by the two refrigeration pole pieces can be converted into required alternating current by arranging the conversion module, and the compatibility of the solar water heater during use is improved.

Drawings

FIG. 1 is a schematic view of the structure of the present invention.

FIG. 2 is a schematic structural diagram of a thermal block according to the present invention.

FIG. 3 is a schematic structural diagram of a conversion module according to the present invention.

FIG. 4 is a schematic view of the present invention.

Fig. 5 is a schematic structural diagram of the generator according to the present invention.

FIG. 6 is a schematic view of the present invention.

Fig. 7 is a schematic structural view of the pulley transmission shaft of the present invention.

In the figure: 1-a support module; 101-a base plate; 102-a wall body; 103-a heat absorbing plate; 104-a temperature conducting plate; 105-an outdoor unit; 106-inner machine; 107-temperature conducting block; 108-two refrigeration pole pieces; 2-a transformation module; 201-a direct current motor; 202-transition intermediate gear holder; 203-transition intermediate gear; 204-shifting the side gear; 205-bidirectional gear; 206-a generator; 207-generator support; 208-executing the power generation gear; 209-executing the power generation gear bracket; 210-gear ring holder; 211-output gear; 212-gear ring; 213-dc motor support; 214-input gear; 3-an evaporation module; 301-an evaporation barrel; 302-primary reflector; 303-inner ratchet wheel; 304-a drive belt; 305-an output pulley; 306-a pulley driveshaft; 307-output pulley carrier; 308-outer ratchet; 309-turbine support; 310-a turbine; 311-input pulley; 312-an intermediate drive shaft; 313-input pulley carrier; 314-input pulley carrier fixed plate; 315-evaporation connection plate; 316-outside reflector.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1, 2, 3, 4, 5, 6, and 7, the auxiliary thermoelectric power generation system includes a support module 1, a conversion module 2, and an evaporation module 3, as shown in fig. 1 and 2, wherein the support module 1 includes a bottom plate 101, a wall 102, a heat absorbing plate 103, a heat conducting plate 104, an external unit 105, an internal unit 106, a heat conducting block 107, and two refrigeration pole pieces 108, the wall 102 is fixedly connected to an upper surface of the bottom plate 101, the heat conducting plates 104 are fixedly connected to both sides of an inner wall of the wall 102, two opposite sides of the two heat conducting plates 104 are fixedly connected to two refrigeration pole pieces 108 through the heat conducting block 107, the heat absorbing plate 103 is fixedly connected to an outer side of the two refrigeration pole pieces 108, the internal unit 106 is fixedly connected to a top of the inner wall 102, and the external unit 105 is fixedly connected to a top of an outer surface.

Referring to fig. 3 and 5, the conversion module 2 includes a dc motor 201, a conversion middle gear bracket 202, a conversion middle gear 203, a conversion side gear 204, a bidirectional gear 205, a generator 206, a generator bracket 207, an execution power generation gear 208, an execution power generation gear bracket 209, a gear ring bracket 210, an output gear 211, a gear ring 212, a dc motor bracket 213 and an input gear 214, the dc motor 201 is disposed at a side of the wall 102, the dc motor 201 is fixedly connected with the upper surface of the base plate 101 through the dc motor bracket 213, the output shaft of the dc motor 201 is fixedly connected with the output gear 211, the outer surface of the output gear 211 is gear-connected with the gear ring 212, the side of the gear ring 212 is fixedly connected with the gear ring bracket 210, the gear ring bracket 210 is fixedly connected with the upper surface of the base plate 101 through the execution power generation gear bracket 209, the side of the execution power generation gear bracket 209 is rotatably connected with the execution power, the executing power generation gear 208 is fixedly connected with an executing power generation gear bracket 209 through a connecting shaft, the outer surface of the executing power generation gear 208 is in gear connection with a transformation intermediate gear 203, the transformation intermediate gear 203 is in rotational connection with the executing power generation gear bracket 209 through a transformation intermediate gear bracket 202, the lower surface of the transformation intermediate gear 203 is in gear connection with a transformation lateral gear 204, the transformation lateral gear 204 is in rotational connection with the bottom plate 101, the outer surface of the transformation lateral gear 204 is in rotational connection with a bidirectional gear 205 through the bottom plate 101, the outer surface of the bidirectional gear 205 is in gear connection with an input gear 214, a power generator 206 is arranged above the input gear 214, the output shaft of the power generator 206 is fixedly connected with the input gear 214, and the power generator 206 is.

As shown in fig. 6 and 7, the evaporation module 3 includes an evaporation barrel 301, a primary reflector 302, an inner ratchet 303, a transmission belt 304, an output pulley 305, a pulley transmission shaft 306, an output pulley support 307, an outer ratchet 308, a turbine support 309, a turbine 310, an input pulley 311, an intermediate transmission shaft 312, an input pulley support 313, an input pulley support fixing plate 314, an evaporation connecting plate 315 and an outer reflector 316, the evaporation barrel 301 is fixedly connected with the upper surface of the base plate 101, the primary reflector 302 is arranged on the outer side of the bottom of the evaporation barrel 301, the primary reflector 302 is fixedly connected with the base plate 101, the turbine 310 is arranged at the top end inside the evaporation barrel 301, the turbine support 309 is rotatably connected with the upper surface of the turbine 310, the turbine support 309 is fixedly connected with the base plate 101, the outer ratchet 308 is rotatably connected with the upper surface of the turbine support 309, and the outer ratchet 308 is fixedly, an inner ratchet wheel 303 is clamped on the inner ring of the outer ratchet wheel 308, a belt wheel transmission shaft 306 is fixedly connected to the upper surface of the inner ratchet wheel 303, the upper surface of the belt wheel transmission shaft 306 is rotatably connected with a turbine support 309 through an evaporation connecting plate 315 and an output belt wheel support 307, an output belt wheel 305 is rotatably connected to the upper surface of the output belt wheel support 307, the output belt wheel 305 is fixedly connected with the inner ratchet wheel 303 through a connecting shaft, an input belt wheel 311 is fixedly connected to the upper portion of the double-direction gear 205 through a middle transmission shaft 312, the input belt wheel 311 is rotatably connected with the output belt wheel 305 through a transmission belt 304, an input belt wheel support 313 is rotatably connected to the top end of the outer surface of the middle transmission shaft 312, the input belt wheel support 313 is fixedly connected with the generator support 207 through an input belt wheel support fixing plate 314.

When the refrigerator is used, the temperature inside the wall 102 is reduced after a user opens the inner machine 106, the temperature on the surface of the temperature guide plate 104 is also reduced, temperature difference is generated on two sides of the two refrigeration pole pieces 108, current is generated inside the two refrigeration pole pieces 108, because the direct current motor 201 is electrically connected with the two refrigeration pole pieces 108, the output shaft of the two refrigeration pole pieces 108 drives the output gear 211 to rotate, the output gear 211 rotates to drive the gear ring 212 to rotate, the gear ring 212 rotates to drive the execution power generation gear 208 to rotate, the execution power generation gear 208 rotates to drive the conversion intermediate gear 203 to rotate, the conversion intermediate gear 203 rotates to drive the conversion lateral gear 204 to rotate, the conversion lateral gear 204 rotates to drive the two-way gear 205 to rotate, the two-way gear 205 rotates to drive the generator 206 to rotate, and the current is generated inside the generator 206, when the outside air temperature is too high, the water in the evaporation barrel 301 will boil under the action of the outer reflector 316 and the primary reflector 302, at this time, the steam will push the turbine 310 to rotate, the rotation of the turbine 310 will drive the outer ratchet 308 to rotate, the rotation of the outer ratchet 308 will drive the inner ratchet 303 to rotate, the rotation of the inner ratchet 303 will drive the output pulley 305 to rotate, the rotation of the output pulley 305 will drive the input pulley 311 to rotate through the transmission belt 304, the rotation of the input pulley 311 will drive the bidirectional gear 205 to rotate through the intermediate transmission shaft 312, the rotation of the bidirectional gear 205 will drive the input gear 214 to rotate, the rotation of the input gear 214 will drive the output shaft of the generator 206 to rotate, and at this time, the inside of the.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.