TWI715231B - Full-day low-temperature solar thermal energy smart power generation system - Google Patents

Abstract

The present invention discloses an all-day low-temperature solar thermal intelligent power generation system, which includes a heat collecting plate, a plurality of thermoelectric chips, a water storage device and a plurality of water-cooled heat dissipation modules. A plurality of thermoelectric chips are arranged in an array on the back side of the heat collecting plate, and the hot ends of the plurality of thermoelectric chips contact the heat collecting plate. The water storage device includes a hot water pipe and a cold water pipe. A plurality of water-cooled heat dissipation modules are respectively arranged on the other side of each thermoelectric chip opposite to the heat collecting plate and contact the cold end of each thermoelectric chip, and respectively connect the hot water pipe and the cold water pipe corresponding to each thermoelectric chip. Wherein, when there is a temperature difference between the hot end of each thermoelectric chip connected to the heat collecting plate and the cold end connected to the water-cooled heat dissipation module, each thermoelectric chip generates electricity.

Description

All-day low-temperature solar thermal smart power generation system

The present invention relates to a power generation system, in particular to an all-day low-temperature solar thermal intelligent power generation system.

Generally speaking, common solar power generation systems need to build huge and expensive high-temperature collectors, and the initial cost of power generation is very high; on the other hand, when there is no sunlight at night, conventional solar power devices cannot generate electricity, that is, the power generation time restricted.

In view of the above-mentioned conventional problems, the purpose of the present invention is to provide an all-day low-temperature solar thermal intelligent power generation system to solve the problems faced by the conventional technology.

Based on the above objective, the present invention provides an all-day low-temperature solar thermal intelligent power generation system, which includes a heat collecting plate, a plurality of thermoelectric chips, a water storage device and a plurality of water-cooled heat dissipation modules. A plurality of thermoelectric chips are arranged in an array on the back side of the heat collecting plate, and the hot ends of the plurality of thermoelectric chips contact the heat collecting plate. The water storage device includes a hot water pipe and a cold water pipe. A plurality of water-cooled heat dissipation modules are respectively arranged on the other side of each thermoelectric chip opposite to the heat collecting plate and contact the cold end of each thermoelectric chip, and respectively connect the hot water pipe and the cold water pipe corresponding to each thermoelectric chip. Wherein, when there is a temperature difference between the hot end of each thermoelectric chip connected to the heat collecting plate and the cold end connected to the water-cooled heat dissipation module, each thermoelectric chip generates electricity.

Preferably, the all-day low-temperature solar thermal intelligent power generation system may further include a power storage device that connects each thermoelectric chip and stores the electricity generated by each thermoelectric chip.

Preferably, the all-day low-temperature solar thermal intelligent power generation system may further include a control module, which is connected to the water storage device and transmits control signals to the water storage device.

Preferably, the water storage device may include a displacement module. The displacement module moves the water storage device from a position higher than each thermoelectric chip to a position lower than each thermoelectric chip according to the control signal, or from a position lower than each thermoelectric chip Move to a position higher than each thermoelectric chip.

Preferably, the heat collecting plate, the plurality of thermoelectric chips and the water storage device can be respectively provided with temperature sensing units, each temperature sensing unit transmits sensing information to the control module, and the control module generates a control signal according to the plurality of sensing information .

Preferably, the water storage device may include a water supply motor, and the water supply motor supplies the water in the water storage device from the hot water pipe to the water-cooled heat dissipation module contacted by the cold end of each thermoelectric chip according to the control signal.

Preferably, the heat collecting plate, the plurality of thermoelectric chips and the water storage device can be respectively provided with temperature sensing units, each temperature sensing unit transmits sensing information to the control module, and the control module generates a control signal according to the plurality of sensing information .

Preferably, when the temperature of the heat collecting plate is higher than the water temperature of the water storage device, the water storage device can supply water from a cold water pipe to the water-cooled heat dissipation module contacted by the cold end of each thermoelectric chip, and the water is recovered from the hot water pipe to Water storage device.

Preferably, when the temperature of the heat collecting plate is lower than the water temperature of the water storage device, the water storage device can supply water from the hot water pipe to the water-cooled heat dissipation module contacted by the cold end of each thermoelectric chip, and the water is recovered from the cold water pipe Water storage device.

Preferably, the connection point between each thermoelectric chip and the hot water pipe may be higher than the connection point with the cold water pipe.

As mentioned above, the all-day low-temperature solar thermal intelligent power generation system of the present invention uses a water storage device to cool the thermoelectric chip to dissipate heat, so that the thermoelectric chip generates a temperature difference to generate electricity, and when the water temperature of the water storage device is higher than the heat collecting plate At this temperature, because there is still a temperature difference, it can achieve the effect of using thermoelectric chips to generate electricity all day.

In order to understand the features, content and advantages of the present invention and its achievable effects, the present invention is combined with the figures and described in detail in the form of an embodiment as follows. The figures used therein are merely The schematic and auxiliary instructions are not necessarily the true proportions and precise configurations after the implementation of the present invention. Therefore, the proportions and configuration relationships of the attached drawings should not be interpreted as to limit the scope of rights of the present invention in actual implementation.

Please refer to Figures 1 and 2; Figure 1 is the first schematic diagram of the all-day low-temperature solar thermal smart power generation system of the present invention; Figure 2 is the second schematic diagram of the full-day low-temperature solar thermal smart power generation system of the present invention. As shown in the figure, the all-day low-temperature solar thermal intelligent power generation system 100 of the present invention includes a heat collecting plate 110, a plurality of thermoelectric chips 120, a water storage device 150, and a plurality of water-cooled heat dissipation modules 160.

In addition, the plurality of thermoelectric chips 120 mentioned above are arranged in an array on the backside of the heat collecting plate 110, and the hot ends of the plurality of thermoelectric chips 120 contact the heat collecting plate 110. However, the water storage device 150 includes a hot water pipe 140 and a cold water pipe 130. However, a plurality of water-cooled heat dissipation modules 160 are respectively arranged on the other side of each thermoelectric chip 120 opposite to the heat collecting plate 110 and contact the cold end of each thermoelectric chip 120, and respectively connect the hot water pipe 140 and the cold water pipe 130 corresponding to each thermoelectric chip 120.

In practical applications, when there is a temperature difference between the hot end of each thermoelectric chip 120 connected to the heat collecting plate 110 and the cold end connected to the water-cooled heat dissipation module 160, each thermoelectric chip 120 generates electricity.

Please refer to Figure 3, which is the first block diagram of the all-day low-temperature solar thermal intelligent power generation system of the present invention. As shown in the figure, the all-day low-temperature solar thermal intelligent power generation system 100 of the present invention may further include an electric storage device 170 that connects the thermoelectric chips 120 and stores the electricity generated by the thermoelectric chips 120.

Please refer to Figures 4 and 5; Figure 4 is the third schematic diagram of the all-day low-temperature solar thermal intelligent power generation system of the present invention; Figure 5 is the second block diagram of the all-day low-temperature solar thermal intelligent power generation system of the present invention . As shown in the figure, the all-day low-temperature solar thermal intelligent power generation system 100 can further include a control module 180 which is connected to the water storage device 150 and transmits control signals to the water storage device 150.

Preferably, the water storage device 150 may include a displacement module 190. The displacement module 190 moves the water storage device 150 from a position higher than each thermoelectric chip 120 to a position lower than each thermoelectric chip 120, or from a lower position according to the control signal. The position of each thermoelectric chip 120 is displaced to be higher than the position of each thermoelectric chip 120.

In more detail, when the sun shines in the daytime, the temperature of the heat collecting plate 110 increases. At this time, the water entering one surface of the thermoelectric chip 120 from the cold water pipe 130 will absorb heat and the water temperature will increase, and the increased water density will decrease. As the thermal convection flows to a high place to enter the water storage device 150, the corresponding position of the water storage device 150 will be higher than the thermoelectric chip 120 (as shown in Figure 1), and the cold water in the water storage device 150 will continue to enter The pressure of the water with higher water temperature is passed through the cold water pipe 130 to one side of the thermoelectric chip 120, so as to achieve the purpose of circulating water without a pump. Conversely, when there is no sunlight at night, the temperature of the heat collecting plate 110 does not rise any more, and the water stored in the water storage device 150 is mostly water produced during the day, so the water temperature needs to be supplied by the water storage device 150 The higher water reaches the water-cooled heat dissipation module 160 contacted by the cold end of the thermoelectric chip 120 to cause a temperature difference between the two sides of the thermoelectric chip 120, so the water storage device 150 must be lowered to a position lower than the thermoelectric chip 120 (such as As shown in Fig. 4), the water with higher water temperature in the water storage device 150 is transported to the thermoelectric chip 120 by thermal convection. Of course, the above is only an example and not a limitation.

Further, the heat collecting plate 110, the plurality of thermoelectric chips 120 and the water storage device 150 can be respectively provided with a temperature sensing unit 101, each temperature sensing unit 101 transmits sensing information to the control module 180, and the control module 180 depends on the plurality of The sensing information generates a control signal. When the control module 180 knows that the water temperature of the water storage device 150 is higher than the temperature of the heat collecting plate 110, it can generate a corresponding control signal to lower the water storage device 150 to a position lower than the thermoelectric chip 120, and vice versa.

Please refer to Figures 6 and 7; Figure 6 is a third-party block diagram of the all-day low-temperature solar thermal intelligent power generation system of the present invention; Figure 7 is the fourth schematic diagram of the all-day low-temperature solar thermal intelligent power generation system of the present invention . As shown in the figure, the water storage device 150 may include a water supply motor 200. The water supply motor 200 supplies the water in the water storage device 150 from the hot water pipe 140 to the water-cooled heat dissipation module contacted by the cold end of each thermoelectric chip 120 according to the control signal. 160. As mentioned above, during the day or when the temperature of the heat collecting plate 110 is higher than the water temperature of the water storage device 150, the water can be automatically circulated by heat convection; however, at night or when the temperature of the heat collecting plate 110 is lower than the water storage device 150 If the position of the water storage device 150 remains unchanged, the water supply motor 200 needs to deliver the higher temperature water to the water-cooled heat dissipation module 160 contacted by the cold end of the thermoelectric chip 120.

Further, the heat collecting plate 110, the plurality of thermoelectric chips 120 and the water storage device 150 can be respectively provided with a temperature sensing unit 101, each temperature sensing unit 101 transmits sensing information to the control module 180, and the control module 180 depends on the plurality of The sensing information generates a control signal.

In view of the above, when the temperature of the heat collecting plate 110 is higher than the water temperature of the water storage device 150, the water storage device 150 can supply water from the cold water pipe 130 to the water-cooled heat dissipation module 160 contacted by the cold end of each thermoelectric chip 120, and The hot water pipe 140 recovers water to the water storage device 150.

Conversely, when the temperature of the heat collecting plate 110 is lower than the water temperature of the water storage device 150, the water storage device 150 can supply water from the hot water pipe 140 to the water-cooled heat dissipation module 160 contacted by the cold end of each thermoelectric chip 120, and the cold water The pipe 130 recovers water to the water storage device 150.

Furthermore, since the water with a higher water temperature has a lower density, it will be located at a higher level, so the connection between each thermoelectric chip 120 and the hot water pipe 140 will be higher than the connection with the cold water pipe 130.

As mentioned above, the all-day low-temperature solar thermal intelligent power generation system of the present invention uses the water storage device 150 to cool the thermoelectric chip 120 to dissipate heat, so that the thermoelectric chip 120 generates a temperature difference to generate electricity, and when the water temperature of the water storage device 150 is high At the temperature of the heat collecting plate 110, since there is still a temperature difference, the thermoelectric chip 120 can be used to generate electricity all day.

The above-mentioned embodiments are only to illustrate the technical ideas and features of the present invention, and their purpose is to enable those who are familiar with the art to understand the content of the present invention and implement them accordingly. When they cannot be used to limit the patent scope of the present invention, That is, all equal changes or modifications made in accordance with the spirit of the present invention should still be covered by the patent scope of the present invention.

100: All-day low-temperature solar thermal smart power generation system 101: temperature sensing unit 110: Collector plate 120: Thermoelectric chip 130: cold water pipe 140: hot water pipe 150: water storage device 160: Water cooling module 170: Power storage device 180: control module 190: Displacement module 200: Water supply motor

Figure 1 is the first schematic diagram of the all-day low temperature solar thermal intelligent power generation system of the present invention. Figure 2 is the second schematic diagram of the all-day low-temperature solar thermal intelligent power generation system of the present invention. Figure 3 is the first block diagram of the all-day low temperature solar thermal intelligent power generation system of the present invention. Figure 4 is the third schematic diagram of the all-day low temperature solar thermal intelligent power generation system of the present invention. Figure 5 is the second block diagram of the all-day low temperature solar thermal intelligent power generation system of the present invention. Figure 6 is a third-party block diagram of the all-day low-temperature solar thermal intelligent power generation system of the present invention. Figure 7 is the fourth schematic diagram of the all-day low temperature solar thermal intelligent power generation system of the present invention.

100: All-day low-temperature solar thermal smart power generation system

110: Collector plate

120: Thermoelectric chip

130: cold water pipe

140: hot water pipe

150: water storage device

160: Water cooling module

Claims (8)

An all-day low-temperature solar thermal intelligent power generation system, comprising: a heat collecting plate; a plurality of thermoelectric chips arranged in an array on the back side of the heat collecting plate, and the hot ends of the plurality of thermoelectric chips contact the heat collecting plate A water storage device includes a hot water pipe and a cold water pipe; and a plurality of water-cooled heat dissipation modules are respectively arranged on the other side of each thermoelectric chip relative to the heat collecting plate and contact the cold end of each thermoelectric chip, And respectively connect the hot water pipe and the cold water pipe; a control module is connected to the water storage device and transmits a control signal to the water storage device; wherein, when each thermoelectric chip is connected to the hot end of the heat collecting plate and the connection When there is a temperature difference between the cold ends of the water-cooled heat dissipation module, each thermoelectric chip generates electricity; wherein the water storage device includes a displacement module, and the displacement module shifts the water storage device from high to high according to the control signal Displace the position of each thermoelectric chip to a position lower than the position of each thermoelectric chip, or from a position lower than the position of each thermoelectric chip to a position higher than that of each thermoelectric chip. For example, the all-day low-temperature solar thermal intelligent power generation system described in the first item of the scope of patent application further includes a power storage device that connects each thermoelectric chip and stores the electricity generated by each thermoelectric chip. For example, the all-day low-temperature solar thermal intelligent power generation system described in item 1 of the scope of patent application, wherein the heat collecting plate, the plurality of thermoelectric chips, and the water storage device are respectively provided with a temperature sensing unit, and each temperature sensing unit Sensor information To the control module, the control module generates the control signal according to the plurality of sensing information. For example, the all-day low-temperature solar thermal intelligent power generation system described in the scope of patent application, wherein the water storage device includes a water supply motor, and the water supply motor supplies water in the water storage device from the hot water pipe according to the control signal To the water-cooled heat dissipation module contacted by the cold end of each thermoelectric chip. For example, the all-day low-temperature solar thermal intelligent power generation system described in item 4 of the scope of patent application, wherein the heat collecting plate, the plurality of thermoelectric chips, and the water storage device are respectively provided with a temperature sensing unit, and each temperature sensing unit A sensing information is sent to the control module, and the control module generates the control signal according to the plurality of sensing information. For example, the all-day low-temperature solar thermal intelligent power generation system described in item 1 of the scope of patent application, wherein when the temperature of the heat collecting plate is higher than the water temperature of the water storage device, the water storage device is supplied by a cold water pipe to each thermoelectric chip The water-cooled heat dissipation module touched by the cold end, and the water is recovered from the hot water pipe to the water storage device. For example, the all-day low-temperature solar thermal intelligent power generation system described in item 1 of the scope of patent application, wherein when the temperature of the heat collecting plate is lower than the water temperature of the water storage device, the water storage device is supplied by a hot water pipe to each of the thermoelectric chips The water-cooled heat dissipation module touched by the cold end of the cold end recovers water from the cold water pipe to the water storage device. For the all-day low-temperature solar thermal intelligent power generation system described in item 1 of the scope of patent application, the connection point between each thermoelectric chip and the hot water pipe is higher than the connection point with the cold water pipe.

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