TWM562950U - Water heater heated with cooling chip - Google Patents

Abstract

A water flow heater for heating a cold wafer, comprising: a hydroelectric generating set for receiving externally input water and generating electricity, comprising a water inlet end and a water outlet end; when the water is input into the hydroelectric generating unit via the water inlet end, Driving the hydroelectric generating set to generate electricity and flowing out from the water outlet end; a heating pipe includes a water inlet and a water outlet, the water inlet of the heating pipe is connected to the water outlet of the hydroelectric generating set, and the water generating end of the hydroelectric generating set The outflowing water is input into the water inlet of the heating pipe, and then flows out from the water outlet of the heating pipe; a heating group is serially connected to the heating pipe for heating water in the heating pipe; the heating group Included in at least one heating device; each of the heating devices includes a heat exchange box through which the water flow passes; a uniform cold wafer attached to one side of the heat exchange box; The power is input to the chilled wafer via a wire; when the chilled wafer is energized, the flow of water in the heat exchange box is heated such that the temperature of the stream rises.

Description

Cooling wafer heating water heater

This creation is about water flow heaters, especially a water flow heater that heats a cold wafer.

The prior art refrigerant chip is mainly used for cooling. When the refrigerant chip is energized, the heat absorbed by one side is conducted to the other side for heat dissipation.

However, the heat energy generated by the above-mentioned conventional refrigerant wafers during use is often derived from the high temperature of the cooled wafer via other cooling mechanisms such as water cooling. Therefore, the thermal energy of the cooled wafer cannot be effectively utilized.

There are already many small heaters that can be installed on water sources (such as faucets), but these traditional heaters require an external power source to make their heating function work.

Therefore, the inventor of the present invention wishes to propose a method in which the thermal energy of the refrigerating wafer is applied to the structure of the water flow heater, and the thermal energy of the refrigerating wafer can be fully utilized to heat the water temperature, thereby achieving the effect of not requiring an external power source.

Therefore, in the present case, it is desirable to propose a new water flow heater for heating a cold wafer to solve the above-mentioned prior art defects.

Therefore, the purpose of the present invention is to solve the above-mentioned problems in the prior art. In the present invention, a water flow heater for heating a cold wafer is proposed, which combines a hydro-generator set with a heating group having a fin-forming wafer to form a heater. When external water flows into the heater, it first flows through the hydroelectric generating set to cause the hydroelectric generating set to generate electricity, and the generated electric power is input into the heating group, so that the cooled wafer generates heat energy, so when the water is from When the hydro-generator unit flows to the heating group, the heating group can apply the heat energy of the refrigerating wafer to heat the water stream, and form hot water to output outward. Therefore, the structure of the present invention can effectively utilize the thermal energy of the cooled wafer and also achieve the purpose of heating the water temperature without connecting an external power source. This is a failure of the conventional heater.

In order to achieve the above object, a water flow heater for heating a cold wafer is proposed in the present invention, comprising: a hydroelectric generating set for receiving externally input water and generating electricity, which comprises a water inlet end and a water outlet end; when the external water passes through The water inlet is input to the hydroelectric generating unit, which drives the hydroelectric generating set to generate electricity and flows out from the outlet end; wherein the hydroelectric generating set includes at least one hydroelectric generating device for receiving externally input water and generating electricity, wherein each The hydroelectric power generating device includes an inlet end and an outlet end; the inlet end receives a flow of water input from a water inlet end of the hydroelectric generating set, and the input water flow drives The hydroelectric generating device generates electricity and flows out from the outlet end to flow out from the outlet end; a heating pipe includes a water inlet and a water outlet, and the water inlet of the heating pipeline is connected to the water outlet of the hydroelectric generating unit The water flowing out from the water outlet of the hydroelectric generating unit is input into the water inlet of the heating pipe, and then flows out from the water outlet of the heating pipe; a heating group is serially connected to the heating pipe for heating the heating pipe Water in the road; the heating group includes at least one heating device for further heating water output from the water outlet end of the hydroelectric generating set; wherein each of the heating devices comprises: a heat exchange box having a hollow structure, the heating pipe The water flow passes through the heat exchange box; a uniform cold wafer is attached to one side of the heat exchange box, and the refrigerant chip is connected to each of the hydroelectric power generation devices via wires; each of the power generated by the hydraulic power generation device is via a corresponding wire Inputting the refrigerated wafer; wherein the refrigerating wafer comprises a cold end and a hot end facing the heat exchange box, and when the refrigerating wafer is energized, the hot end of the refrigerating wafer Degrees will rise, and the heat exchanger in the water tank is heated, so that the heat exchange tank the water temperature rises.

The features of the present invention and its advantages can be further understood from the description below, and please refer to the attached drawings when reading.

10‧‧‧Hydraulic generating sets

11‧‧‧ into the water

12‧‧‧ water outlet

20‧‧‧Hydroelectric installation

21‧‧‧ entrance end

22‧‧‧export end

30‧‧‧heating line

31‧‧‧ water inlet

32‧‧‧Water outlet

35‧‧‧ circuit

50‧‧‧First water pipe

52‧‧‧Second water pipe

70‧‧‧ heating device

72‧‧‧Hot exchange box

74‧‧‧Chilled wafer

76‧‧‧ Thermal sheet

80‧‧‧vacuum cabinet

400‧‧‧heating group

741‧‧‧ wire

742‧‧‧ cold end

743‧‧‧ hot end

Figure 1 shows a schematic diagram of the component combinations of the present case.

Figure 2 shows a schematic view of the heating device of the present invention.

Figure 3 shows a schematic diagram of another component combination of the present invention.

Figure 4 shows another schematic view of the heating device of the present invention.

Figure 5 shows a schematic diagram of another component combination of the present invention.

Figure 6 shows a schematic diagram of another component combination of the present invention.

In view of the structural composition of the case, and the functions and advantages that can be produced, in conjunction with the drawings, a preferred embodiment of the present invention is described in detail below.

Referring to FIG. 1 to FIG. 6, the water flow heater of the present invention for heating the cold wafer is shown, which comprises the following components:

A hydroelectric generating set 10 is configured to receive externally input water and generate electricity, and includes a water inlet end 11 and a water outlet end 12, which can be used to connect a faucet 10 and receive water from the faucet 10. When external water is supplied to the hydroelectric generating set 10 via the water inlet end 11, the hydroelectric generating set 10 is driven to generate electricity and flows out from the water discharging end 12. The water inlet end 11 is connected to the faucet 10 via a first water pipe 50.

The faucet 10 described above is only one example of a water source connectable to the water inlet end 11, and is not intended to limit the scope of the present invention. Any water source to which the water inlet end 11 can be connected is within the scope of the present invention.

The hydroelectric generating set 10 can include at least one hydroelectric generating device 20 for receiving externally input water and generating electricity, wherein each of the hydroelectric generating devices 20 includes an inlet end 21 and an outlet end 22 (as shown in FIG. 1). . The inlet end The 21 series receives the water flow input from the water inlet end 11 of the hydroelectric generating set 10, and the input water flow drives the hydroelectric power generating device 20 to generate electricity, flows out from the outlet end 22, and flows out from the water outlet end 12.

The structure of the hydropower unit 20 is well known to those skilled in the art, so the details thereof will not be described.

A heating pipe 30 includes a water inlet port 31 and a water outlet 32. The water inlet port 31 of the heating pipe is connected to the water outlet end 12 of the hydroelectric generating set 10, and the water system input from the water outlet end 12 of the hydroelectric generating set 10 is input. The water inlet 31 of the heating pipe flows out from the water outlet 32 of the heating pipe.

A heating group 400 is connected in series to the heating line 30 for heating the water in the heating line 30. The heating group 400 includes at least one heating device 70 for further heating the water output from the water outlet end 12 of the hydro-generator set 10. Each of the heating devices 70 includes:

A heat exchange tank 72 has a hollow structure through which the water flow of the heating line 30 passes.

A uniform cold wafer 74 is attached to one side of the heat exchange tank 72, and the refrigerant wafer 74 is connected to each of the hydroelectric power generating units 20 via a wire 741. The electric power generated by each of the hydroelectric devices 20 is input to the refrigerating wafer 74 via a corresponding wire 741. As shown in FIG. 2, the refrigerating wafer 74 includes a cold end 742 and a hot end 743. The end 743 is facing the heat exchange box 72. When the refrigerant wafer 74 is energized, the temperature of the hot end 743 of the refrigerant wafer 74 rises, and the water flow in the heat exchange tank 72 is heated to cause the heat. The temperature of the water stream in the exchange tank 72 rises.

The heat exchange box 72 may be provided with a heat conducting sheet 76 on one side of the refrigerant wafer 74, as shown in FIG. The heat conductive sheet 76 serves to increase the heat transfer area of the refrigerant wafer 74 to improve the temperature increasing effect.

Wherein the portion of the heating pipe 30 located in the heat exchange box 72 can form a tortuous circuit 35 (as shown in FIG. 4), and increase the length of the portion of the heating pipe 30 located in the heat exchange box 72 to increase Heating efficiency.

When the faucet 10 is turned on, water is input to the hydro-generator set 10, and the hydro-generator set 10 is generated to output electric power to the heating group 400, so that the heating group 400 generates thermal energy to the heating pipe 30. Heating, so when water is output from the hydro-generator 10 and passes through the heating line 30, the water temperature rises to form hot water, and flows out of the water outlet 32 of the heating line 30, so that the faucet 10 can be heated. The effect of the water. In the present case, the hydro-generator set 10 is used as a power source for the heating group 400, so the heating group 400 does not need to be connected to an external power source.

The present invention may further comprise a vacuum box 80 covering the heating group 400 (as shown in FIG. 5), the vacuum box body 80 is evacuated to form a vacuum state, and This heating group 400 has a better heating effect.

In the application example of the present application, the at least one heating device 70 may be a plurality of heating devices 70, and the plurality of heating devices 70 are serially connected in the heating pipe 30 (as shown in FIG. 3).

As shown in FIG. 6, the at least one hydropower generating device 20 may be a plurality of hydroelectric generating devices 20, wherein the water inlet end 11 of the hydroelectric generating set 10 is the inlet end 21 of the hydroelectric generating device 20 closest to the faucet 10; The water outlet end 12 of the hydroelectric generating set 10 is the outlet end 22 of the hydroelectric generating device 20 farthest from the faucet 10; wherein the adjacent different hydroelectric generating devices 20 are connected to each other via a second water pipe 52, each of which is second One end of the water pipe 52 is connected to the outlet end 22 of the hydroelectric power unit 20 of the upper stage, and the other end is connected to the inlet end 21 of the hydroelectric power unit 20 of the next stage.

The advantage of the present invention is that a hydro-generator set is combined with a heating group having a refrigerating wafer to form a heater. When external water flows into the heater, it will first flow through the hydro-generator set to cause the hydro-generator unit to generate electricity. And inputting the generated electric power into the heating group, so that the refrigerating wafer generates thermal energy, so when water flows from the hydroelectric generating set to the heating group, the heating group can apply the thermal energy of the refrigerating wafer to heat the water stream, and The hot water is formed to be output to the outside. Therefore, the structure of the present invention can effectively utilize the thermal energy of the cooled wafer and also achieve the purpose of heating the water temperature without connecting an external power source. This is a failure of the conventional heater.

In summary, the humanized design of this case is quite in line with actual needs. The specific improvement of the existing defects is obviously a breakthrough improvement advantage compared with the prior art, and it has an improvement in efficacy and is not easy to achieve. The case has not been disclosed or disclosed in domestic and foreign literature and market, and has complied with the provisions of the Patent Law.

The detailed description above is a detailed description of one of the possible embodiments of the present invention, and the embodiment is not intended to limit the scope of the patents, and the equivalent implementations or modifications that are not included in the spirit of the present invention should be included in The patent scope of this case.

Claims (7)

A water flow heater for heating a cold wafer, comprising: a hydroelectric generating set for receiving externally input water and generating electricity, comprising a water inlet end and a water outlet end; when external water is input into the hydroelectric generating unit via the water inlet end The hydroelectric generating set is driven to generate electricity and flows out from the water outlet end; wherein the hydroelectric generating set includes at least one hydroelectric generating device for receiving externally input water and generating electricity, wherein each of the hydroelectric generating devices includes an inlet end And an outlet end; the inlet end receives the water flow input from the water inlet end of the hydroelectric generating set, and the input water flow drives the hydroelectric generating device to generate electricity, and flows out from the outlet end, and flows out from the water outlet end; a heating pipe includes a water inlet and a water outlet, wherein the water inlet of the heating pipeline is connected to the water outlet of the hydroelectric generating unit, and the water flowing out of the water outlet of the hydroelectric generating unit is input into the water inlet of the heating pipeline. And flowing out from the water outlet of the heating pipeline; a heating group is connected in series in the heating pipeline for heating water in the heating pipeline; The heating group includes at least one heating device for further heating water outputted from the water outlet end of the hydroelectric generating set; wherein each of the heating devices comprises: a heat exchange box having a hollow structure, the water flow of the heating pipe passing through the heat Exchange box A uniform cold wafer is attached to one side of the heat exchange box, and the refrigerant chip is connected to each of the hydroelectric power generating devices via wires; the power generated by each of the hydroelectric power generating devices is input to the refrigerating wafer via a corresponding wire; The cold wafer includes a cold end and a hot end facing the heat exchange box. When the cold wafer is energized, the temperature of the hot end of the refrigerating wafer rises, and the water flow in the heat exchange box Heating causes the temperature of the water stream in the heat exchange box to rise. A water flow heater for heating a cold wafer as described in claim 1, wherein the heat exchange box is provided with a heat conductive sheet on one side of the refrigerant wafer; the heat conductive sheet is used to increase a heat transfer area of the cold wafer And improve the heating effect. The water flow heater for heating a cold wafer according to claim 1, wherein the at least one heating device is a plurality of heating devices, and the plurality of heating devices are serially connected in the heating pipe in series. . A water flow heater for heating a cold wafer as described in claim 1 wherein the at least one hydroelectric power generating device is a plurality of hydroelectric power generating devices. A water flow heater for heating a cold wafer as described in claim 1 wherein the water inlet end is used to connect a water tap; the water inlet end is connected to the water tap via a first water pipe. The water flow of the cold wafer heating as described in item 1 of the patent application scope The heater, wherein the portion of the heating pipe located in the heat exchange box forms a tortuous circuit, and increases the length of the portion of the heating pipe located in the heat exchange box to increase heating efficiency. The water flow heater for heating the cold wafer according to the first aspect of the patent application, further comprising a vacuum box covering the heating group, wherein the vacuum box is evacuated to form a vacuum state, so that the heating group Has a better heating effect.