TWM576617U - Thermoelectric coexisting system and hot water supply module thereof - Google Patents

Abstract

The present invention relates to a thermoelectric symbiosis system and a hot water supply module thereof, which comprises a solar battery module and a heat dissipation module, wherein the heat dissipation module is disposed on an aluminum plate added at the bottom of the solar battery module, The heat dissipation module further comprises a heat collecting tube to provide flowing cold water into the heat collecting tube and reduce the temperature of the solar panel, and the heat collecting tube can provide an external hot water supply module to provide the heat generating tube. The hot water is stored in a water heater to provide hot bath water. In addition to providing the power generation efficiency of the solar cell module, it can also achieve the purpose of general household energy conservation.

Description

Thermoelectric symbiosis system and hot water supply module

The present invention relates to a clean energy system, and more particularly to a technical field combining a solar battery module, a heat dissipation module, and a hot water supply module.

According to the issue, thermal power generation will spread the problem of global warming, and nuclear power plants will have radiation leakage problems. Therefore, countries do not vigorously promote clean energy, such as solar power, wind power, hydropower, and ocean power. ...and many more.

As disclosed in the "Newly-Effective Solar Power Generation Apparatus" of the National Patent Application No. 102202243, a solar battery module is provided with a heat dissipation module, and the heat collection tube provided by the heat dissipation module is made of an all-metal material. The heat collecting tube is welded to the bottom of the solar cell module, so that there is a problem of residual scale on the tube wall of the heat collecting tube, and the scale affects the inflow and out of the cold water, thereby reducing the overall heat dissipation efficiency of the heat dissipation module. What's more, if the heat dissipation effect is completely ineffective, the solar cell module will operate at a high temperature and cannot increase its power generation efficiency.

In addition, there is no aluminum plate on the back of the general solar cell module, only a white EVA film. If the heat collecting tube is directly fixed on the back EVA film, the EVA film will be destroyed when the calcium carbonate is removed in the future, and the solar panel is damaged.

In addition, in the above conventional solar power generation device, the temperature detector is set at the recovery temperature. If the water pipe section does not reach the preset temperature, it will flow back to a cold water tank and repeat the cycle. If the preset temperature is reached, it will flow into a warm water collecting device.

However, if the above temperature does not reach the preset temperature, it is returned to the cold water tank and mixed with the original cold water, and then the cycle is repeated until the required water temperature is reached. When the temperature is returned to the warm water collecting device, the circulation heating method will be lost. A part of the heat energy, and the production of hot water takes a long time, so that the use of heat energy is inefficient, there is a need to improve.

In view of the above problems of the conventional solar battery module, the novel creator thus creates a thermoelectric symbiosis system and a hot water supply module thereof, so the main purpose of the novel is to provide a heat collecting tube for the heat dissipation module to remove scale. A thermoelectric symbiosis system that enhances heat dissipation efficiency; the second objective of the present invention is to provide a hot water supply module that does not consume heat energy generated by the solar panel and has high water production efficiency.

In order to achieve the above objectives, the present invention employs the following technical means:

A thermal power symbiosis system has a solar battery module and a heat dissipation module, wherein the heat dissipation module is disposed on an aluminum plate added to the bottom of the solar battery module, and the heat dissipation module is further configured to include The heat collecting tube further comprises an inlet and an outlet for providing flowing cold water to enter the heat collecting tube, and the heat collecting tube system further comprises a plurality of rubber hoses and metal bending tubes, and the set is formed by a curing type thermal conductive adhesive. The heat pipe is connected to the aluminum plate added at the bottom of the solar cell module to cool the solar cell module and improve the power generation efficiency.

A hot water supply module externally connected to the above-mentioned thermoelectric symbiosis system includes an external pipe and a water heater, and the external pipe is externally connected to the heat collecting pipe of the heat dissipation module, thereby forming a circulation line and supplying heat Bath water.

The hot water supply module, wherein the external pipe is provided with a solenoid valve and a water pump, and the electromagnetic valve and the water pump are electrically connected to a temperature difference controller.

The hot water supply module, wherein the temperature difference controller further comprises a first temperature detector and a second temperature detector, and the first temperature detector is installed in the heat collecting tube, and the first The second temperature detector is installed in the water heater, and a temperature difference is formed between the two, so that the water pump and the electromagnetic valve are activated, so that the circulation pipeline can simulate the natural convection state.

The hot water supply module, wherein the temperature difference is set by the user according to the climatic condition.

Therefore, the present invention can achieve the following effects by using the above technical means:

1. The heat collecting tube of the novel heat dissipating module comprises an inlet tube, an outlet tube and a plurality of metal bending tubes, a rubber tube and the like, and the heat collecting tube is arranged at the bottom of the solar panel with the curing type thermal conductive glue, so that the heat collecting tube The heat collecting tube is easy to be combined and disassembled. In other words, if the wall of the heat collecting tube is formed with scale, the heat collecting tube can be disassembled to remove the scale, and then the bottom of the solar battery template is replaced, thereby prolonging the service life of the solar battery module. According to the maintenance cost of solar cell modules.

2. The new hot water supply module provides sensing of the water temperature in the heat collecting tube and the water heater by the first temperature detector and the second temperature detecting device of the temperature difference controller respectively, and if the temperature difference set by the user is reached, That is, if the water temperature in the heat collecting tube is higher than the water temperature in the water heater, the temperature difference controller will start the water pump and the electromagnetic valve, and immediately let the hot water in the heat collecting tube enter the water heater without loss of heat energy; then, the cold water is replenished. In the heat collecting pipe, if the water temperature in the heat collecting pipe or the water heater does not reach the temperature difference set by the user, the water pump and the electromagnetic valve are stopped, so that the cold water absorbs the heat energy of the solar panel.

3. The new heat dissipation module further comprises an aluminum plate (or other metal) as the uniform heat medium of the solar battery and the rubber hose. In addition to the rapid and uniform heat conduction, after the heat collecting tube is calcified, the aluminum plate is easier. Disassemble the heat collecting tube for replacement.

A‧‧‧Thermal symbiosis system

1‧‧‧Solar battery module

11‧‧‧Solar panels

111‧‧‧Aluminum plate

12‧‧‧Solar controller

13‧‧‧Battery

14‧‧‧Inverter

15‧‧‧A.T.S power automatic switch module

16‧‧‧I-V performance curve recorder

2‧‧‧ Thermal Module

21‧‧‧ collector tube

211‧‧‧Inlet pipe

212‧‧‧Export tube

22‧‧‧矽Hose

23‧‧‧Metal elbow

24‧‧‧Connecting tube

25‧‧‧curable thermal adhesive

B‧‧‧ hot water supply module

31‧‧‧External

311‧‧‧Water pump

312‧‧‧ solenoid valve

32‧‧‧Water heater

33‧‧‧temperature difference controller

331‧‧‧First temperature detector

332‧‧‧Second temperature detector

34‧‧‧Water Tower

c‧‧‧Circulation line

Figure 1: Schematic diagram of the novel thermoelectric symbiosis system.

Figure 2: A partial exploded view of the novel thermoelectric symbiosis system.

Figure 3: Schematic diagram of the partial combination of the solar cell module and the heat dissipation module of the present invention.

Figure 4: A partial exploded view of the novel heat dissipation module.

Figure 5: A partial combined sectional view of the novel thermoelectric symbiosis system.

First, referring to FIG. 1 , the present invention relates to a thermoelectric symbiosis system and a hot water supply module thereof, wherein a solar cell module 1 provided in the thermoelectric symbiosis system A will include a solar panel 11 , and then The solar panel 11 is electrically connected to a solar controller 12, and the solar controller 12 is electrically connected to a battery 13, an inverter 14, and an ATS power automatic switch module 15, to provide storage of the solar battery. The board 11 is subjected to electric energy generated after the sunshine, and a power supply network for supplying electric power to the household or incorporating the electric power, and an IV performance curve recorder 16 is disposed between the solar panel 11 and the solar controller 12.

Further, referring to FIG. 2 and FIG. 3, the solar panel 11 is subjected to high temperature after the sun is shining, and the high temperature has a negative influence on the power generation efficiency of the solar panel 11, that is, the temperature of the solar panel 11 itself is higher. High, the lower the power generation efficiency. Therefore, a heat dissipation module 2 is disposed at the bottom of the solar cell module 1. Usually, an aluminum plate 111 or other metal is added to the bottom of the solar cell module 1 to facilitate heat conduction of the solar cell module 1 due to sunlight. To the heat dissipation module 2, thereby lowering the temperature of the solar panel 11 to enhance the solar cell The power generation efficiency of the board 11.

In order to improve the heat dissipation efficiency of the heat collecting tube of the conventional heat dissipation module and reduce the heat dissipation efficiency, the life of the solar panel is shortened. Therefore, the heat collecting tube 21 used in the present invention is made of metal as shown in FIG. 2 and FIG. An inlet tube 211, an outlet tube 212, a plurality of metal elbows 23, a rubber tube 22 and the like are assembled into a continuous curved shape. Since the rubber tube 22 is a material having both elasticity and heat conduction, it is only required to be nested therein. The inlet tube 211, the outlet tube 212 or the metal elbow 23 can achieve the effect of sealing and leakproof.

As shown in FIG. 5, the heat collecting tube 21 is adhered to the aluminum plate 111 at the bottom of the solar cell panel 11 by a curing type thermal conductive paste 25, thereby forming a flow path of cold water. Since the silicone tube 22 and the curable thermal conductive adhesive 25 both have a heat conduction function, the heat of the solar panel 11 can be smoothly introduced into the cold water via the curable thermal conductive adhesive 25 and the silicone tube 22, and the solar panel can be sucked by the cold water. The heat of 11 achieves the purpose of lowering the temperature of the solar panel 11 to improve power generation efficiency.

In particular, as shown in FIG. 2, a connecting pipe 24 is disposed in the middle of the heat collecting pipe 21 in a middle of the rubber hose 22, and the connecting pipe 24 is reserved for providing a position for mounting a first temperature detector 331.

The heat collecting tube 21 of the present invention using the silicone tube 22 and the curing type thermal conductive adhesive 25 allows the heat collecting tube 21 to be easily assembled and disassembled, thereby reducing the cost of assembly and maintenance. In other words, if the solar cell module 1 and the heat dissipating module 2 of the present invention are used for a period of time, the wall of the heat collecting tube 21 is formed with scale, and the curable heat conductive adhesive 25 and the inlet tube 211 of the heat collecting tube 21 can be The outlet pipe 212 and the plurality of metal elbows 23, the rubber hose 22, the aluminum plate 111 and the like are disassembled and removed, and then reassembled to the aluminum plate 111 at the bottom of the original solar cell template 11 with a new curable thermal adhesive 25 again. Therefore, the service life of the solar cell module 1 can be prolonged, thereby saving the solar cell mode. Group 1 maintenance costs.

The hot water supply module B of the present invention can be externally connected to the above-mentioned thermoelectric symbiosis system A or other solar power generation device, as shown in FIG. 1 , wherein the hot water supply module B includes an external pipe 31 , and the outer The inlet pipe 31 is externally connected to the water inlet pipe 211 and the outlet pipe 212 of the heat collecting pipe 21 of the heat dissipation module 2, and the external pipe 31 is connected in series with a water heater 32, a water pump 311, a solenoid valve 312, and the water pump 311. A water tower 35 is connected.

Another temperature difference controller 33 is electrically connected to the water pump 311 and the electromagnetic valve 312, as shown in FIG. Further, the temperature difference controller 33 further has a first temperature detector 331 and a second temperature detector 332, and the first temperature detector 331 is connected to the connecting tube 24 of the heat collecting tube 21 (Fig. 2)), the second temperature detector 332 is installed in the interior of the water heater 32, and a temperature difference is formed between the two, so that the water pump 311 and the electromagnetic valve 312 are activated to allow the circulation line c It can simulate the natural convection state. In particular, the temperature difference is set by the user depending on the weather conditions.

The simulated natural convection mode is as shown in FIG. 1 , and the first temperature detector 331 and the second temperature detector 332 respectively sense the water temperature in the heat collecting tube 21 and the water heater 32. When the temperature difference is set, that is, the water temperature in the heat collecting tube 21 is higher than the water temperature in the water heater 32, the temperature difference controller 33 activates the water pump 311 and the electromagnetic valve 312 to allow the hot water in the heat collecting tube 21 to flow into the water temperature. The water storage tank in the water heater 32 then replenishes the cold water in the heat collecting tube 21. At this time, if the water temperature in the heat collecting tube 21 and the water heater 32 cannot reach the temperature difference set by the user, the water pump 311 and the electromagnetic valve 312 are stopped to operate. The replenished cold water absorbs the heat energy of the solar panel to raise the water temperature. After the cold water is heated to a high temperature via the solar panel 11 , the high temperature water flows into the water heater 32 again due to the operation of the temperature difference controller 33 . The water storage tank inside, such a cold water heating method does not consume solar heat energy, and rapidly produces hot water.

In summary, the present invention relates to a thermoelectric symbiosis system and a hot water supply module thereof, wherein the overall thermoelectric symbiosis technology has 50% more energy utilization efficiency than the general solar cell, and its constituent structure has not been seen in books or Public use, in line with the requirements of the new patent application, please ask the Bureau to express the patent, as soon as the patent is granted, to the pray; to be clear, the above is the specific embodiment of the new model and the technical principles used, if Changes in the concept of the new type, if the functional role produced by the new concept has not exceeded the spirit of the specification and the drawings, shall be within the scope of this new model and shall be combined with Chen Ming.

Claims (6)

A thermoelectric symbiosis system has a solar battery module and a heat dissipation module, wherein the heat dissipation module is disposed at the bottom of the solar battery module, and the heat dissipation module is further configured to include a heat collecting tube. The heat collecting tube is provided with an inlet tube and an outlet tube for supplying flowing cold water into the heat collecting tube, and the heat collecting tube system further comprises a plurality of rubber tubes and metal bending tubes, and the heat collecting tube is formed by the curing type thermal conductive glue. Connected to the bottom of the solar cell module to cool the solar cell module and improve its power generation efficiency. The thermoelectric symbiosis system of claim 1, wherein an aluminum plate is added to the bottom of the solar cell module. A hot water supply module externally connected to the thermoelectric symbiosis system of claim 1, comprising an external pipe and a water heater, wherein the external pipe is externally connected to the heat collecting pipe of the heat dissipation module, thereby forming a circulation line and Supply hot bath water. The hot water supply module of claim 3, wherein the external pipe is provided with a solenoid valve and a water pump, and the electromagnetic valve and the water pump are electrically connected to a temperature difference controller. The hot water supply module of claim 4, wherein the temperature difference controller further comprises a first temperature detector and a second temperature detector, and the first temperature detector is installed in the heat collecting tube. And the second temperature detector is installed in the water heater, and a temperature difference is formed between the two, so that the water pump and the electromagnetic valve are activated, so that the circulation pipeline can simulate the natural convection state. The hot water supply module of claim 5, wherein the temperature difference is set by the user according to the climatic condition.