CN218094601U - Thermoelectric generation module for tap - Google Patents

Abstract

The utility model relates to a temperature difference power generation module for a faucet, which comprises a first water-cooling radiator, a second water-cooling radiator and a temperature difference power generation sheet; the first water-cooling radiator comprises a first shell and a first heat conducting plate, wherein a first water tank is formed in the first shell, and the first heat conducting plate covers the first water tank and is fixed with the first shell; the first shell is provided with a first water inlet and a first water outlet; the second water-cooling radiator comprises a second shell and a second heat-conducting plate, a second water tank is formed in the second shell, and the second heat-conducting plate covers the second water tank and is fixed with the second shell; a second water inlet and a second water outlet which are communicated with the second water tank are formed in the second shell; the water-cooling radiator and the second water-cooling radiator are fixed together, the thermoelectric generation piece is located between the second heat conduction plates on the first water-cooling radiator and the second water-cooling radiator, and two surfaces of the thermoelectric generation piece are tightly attached to the first heat conduction plate and the second heat conduction plate respectively. Through the utility model discloses, be favorable to better through thermoelectric generation.

Description

Thermoelectric generation module for tap

Technical Field

The utility model relates to a thermoelectric generation module for tap belongs to tap accessory technical field.

Background

With the improvement of living standard of people, digital display faucets and intelligent faucets gradually enter thousands of households, generally need to provide electric energy for a display for displaying water temperature or a circuit board for intelligent control for displaying water temperature or realizing intelligent control, and have the problems of short service life, troublesome replacement and the like by utilizing a battery power supply mode; the hydroelectric generation has the problems of short service life, high failure rate, high noise and large interception; therefore, the utility model discloses to these problems, provide the thermoelectric generation module that tap used, provide new power supply mode for tap through thermoelectric generation module.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a thermoelectric generation module for tap to the problem that exists among the current tap power supply technology.

The purpose of the utility model is realized like this: the utility model provides a thermoelectric generation module for tap, characterized by: the thermoelectric generation device comprises a first water-cooling radiator, a second water-cooling radiator and a thermoelectric generation sheet;

the first water-cooling radiator comprises a first shell and a first heat conducting plate, a first water tank is formed in the first shell, and the first heat conducting plate covers the first water tank and is fixed with the first shell; the first shell is provided with a first water inlet and a first water outlet which are communicated with the first water tank;

the second water-cooling radiator comprises a second shell and a second heat conducting plate, a second water tank is formed in the second shell, and the second heat conducting plate covers the second water tank and is fixed with the second shell; a second water inlet and a second water outlet which are communicated with the second water tank are formed in the second shell;

the first water-cooling radiator and the second water-cooling radiator are fixed together, the thermoelectric generation piece is located between the first heat conduction plate on the first water-cooling radiator and the second heat conduction plate on the second water-cooling radiator, and two surfaces of the thermoelectric generation piece are tightly attached to the first heat conduction plate and the second heat conduction plate respectively.

A plurality of first shell connecting seats are arranged on four sides of the first shell, and first shell connecting through holes are formed in the first shell connecting seats; the four sides of the first heat conducting plate are provided with a plurality of first heat conducting plate connecting seats corresponding to the first shell connecting seats, and the first heat conducting plate connecting seats are provided with first heat conducting plate connecting through holes;

a plurality of second shell connecting seats are arranged on four sides of the second shell, and second shell connecting through holes are formed in the second shell connecting seats; the four sides of the second heat conduction plate are provided with a plurality of second heat conduction plate connecting seats corresponding to the plurality of second shell connecting seats, and the second heat conduction plate connecting seats are provided with second heat conduction plate connecting through holes;

still be equipped with a plurality of bolts, every bolt screw in proper order corresponding first casing connecting through hole, first heat-conducting plate connecting through hole, second casing connecting through hole to back out, the nut has been revolved to the one end after the back of back out for first water-cooling radiator, second water-cooling radiator are fixed together, and thermoelectric generation piece presss from both sides the fastening and is fixed in between first heat-conducting plate, the second heat-conducting plate.

A plurality of first basin baffles which are parallel to the width direction of the first basin and are distributed at intervals are arranged in the first basin, and a first circuitous water channel is formed in the first basin through the first basin baffles which are distributed at intervals.

The first water inlet and the first water outlet are respectively arranged at two sides of the first shell, and the first water inlet and the first water outlet are communicated through a first circuitous water channel.

A plurality of second water tank clapboards which are parallel to the length direction of the second water tank and are distributed at intervals are arranged in the second water tank, and a second circuitous water channel is formed in the second water tank through the plurality of second water tank clapboards which are distributed at intervals.

The second water inlet and the second water outlet are arranged on the same side of the second shell, and the second water inlet and the second water outlet are communicated through a second circuitous water channel.

The thermoelectric generation piece is connected with a lead for outputting the electric energy generated by the thermoelectric generation piece.

The utility model discloses rational in infrastructure, convenient to use, through the utility model discloses, a pair of tap is with thermoelectric generation module is provided, during the use: cold water enters a first water tank of the first water-cooled radiator through a first water inlet and then is discharged from a first water outlet, and hot water enters a second water tank of the second water-cooled radiator through a second water inlet and then is discharged from a second water outlet; the cold water in the first basin is laminated with first heat-conducting plate, and the thermoelectric generation piece is laminated with first heat-conducting plate, and the hot water in the second basin is laminated with the second heat-conducting plate, and the thermoelectric generation piece is laminated with the second heat-conducting plate to make and form the difference in temperature between first heat-conducting plate, the second heat-conducting plate, the thermoelectric generation piece obtains the electricity generation behind the difference in temperature.

Or hot water enters a first water tank of the first water-cooled radiator through the first water inlet and then is discharged from the first water outlet, and cold water enters a second water tank of the second water-cooled radiator through the second water inlet and then is discharged from the second water outlet; the hot water in the first basin is laminated with first heat-conducting plate, and the thermoelectric generation piece is laminated with first heat-conducting plate, and the cold water in the second basin is laminated with the second heat-conducting plate, and the thermoelectric generation piece is laminated with the second heat-conducting plate to make and form the difference in temperature between first heat-conducting plate, the second heat-conducting plate, the thermoelectric generation piece generates electricity after obtaining the difference in temperature.

Particularly, in practical use, the temperature difference power generation sheet generates power after obtaining the temperature difference and can supply power for the faucet circuit, the temperature difference power generation sheet is used for displaying temperature, flow and time or realizing the functions of sound control, touch control, induction and the like, and the defects caused by the power supply of a battery and hydroelectric power generation in the past are avoided.

Through the utility model discloses, can set up a plurality of interval distribution's that are parallel with first basin width direction first basin baffle in first basin, a plurality of first basin baffles through interval distribution form first circuitous water course in first basin. And a plurality of second water tank clapboards which are parallel to the length direction of the second water tank and are distributed at intervals are arranged in the second water tank, and a second circuitous water channel is formed in the second water tank through the plurality of second water tank clapboards which are distributed at intervals. Through such circuitous water course (first circuitous water course, second circuitous water course), make the rivers that pass through fully contact with the heat-conducting plate (first heat-conducting plate, second heat-conducting plate), improve thermoelectric generation efficiency.

Through the utility model discloses, do not have water pressure just can generate electricity, still do not have wearing and tearing almost, do not damming, do not have the noise of operation, have very big market application and spreading value.

Detailed Description

Fig. 1 is a schematic view of the overall structure of the present invention;

fig. 2 is a schematic diagram of the explosion structure of the present invention;

FIG. 3 is a schematic structural view of a first water-cooled heat sink portion of the present invention;

FIG. 4 is a schematic view of a second embodiment of the present invention;

in the figure: 1 first water-cooling radiator, 1-1 first shell, 1-2 first heat conducting plate, 1-3 first shell connecting seat, 1-4 first shell connecting through hole, 1-5 first heat conducting plate connecting seat, 1-6 first heat conducting plate connecting through hole, 1-7 first water tank, 1-8 first water inlet, 1-9 first water outlet, 1-10 first water tank baffle plate, 2 second water-cooling radiator, 2-1 second shell, 2-2 second heat conducting plate, 2-3 second shell connecting seat, 2-4 second shell connecting through hole, 2-5 second heat conducting plate connecting seat, 2-6 second heat conducting plate connecting through hole, 2-7 second water tank, 2-8 second water inlet, 2-9 second water outlet, 2-10 second water tank baffle plate and 3 thermoelectric power generation sheet.

Detailed Description

The technical solution of the present invention will be described clearly and completely with reference to the following embodiments, and it should be understood that the described embodiments are some, but not all embodiments of the present invention. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts all belong to the protection scope of the present invention.

A temperature difference power generation module for a faucet comprises a first water-cooling radiator 1, a second water-cooling radiator 2 and a temperature difference power generation sheet 3. The first water-cooling radiator 1 comprises a first shell 1-1 and a first heat conduction plate 1-2, a first water tank 1-7 is arranged on the first shell 1-1, and the first heat conduction plate 1-2 covers the first water tank 1-7 and is fixed with the first shell 1-1; the first shell 1-1 is provided with a first water inlet 1-8 and a first water outlet 1-9 which are communicated with the first water tank 1-7. The second water-cooling radiator 2 comprises a second shell 2-1 and a second heat conduction plate 2-2, a second water tank is arranged on the second shell 2-1, and the second heat conduction plate 2-2 covers the second water tank and is fixed with the second shell 2-1; a second water inlet 2-8 and a second water outlet 2-9 which are communicated with the second water tank 2-7 are arranged on the second shell 2-1.

The first water-cooling radiator 1 and the second water-cooling radiator 2 are fixed together, the thermoelectric generation piece 3 is positioned between the first heat conduction plate 1-2 on the first water-cooling radiator 1 and the second heat conduction plate 2-2 on the second water-cooling radiator 2, and two surfaces of the thermoelectric generation piece 3 are respectively clung to the first heat conduction plate 1-2 and the second heat conduction plate 2-2.

Furthermore, a plurality of first shell connecting seats 1-3 are arranged on four sides of the first shell 1-1, and first shell connecting through holes 1-4 are formed in the first shell connecting seats 1-3; a plurality of first heat conduction plate connecting seats 1-5 corresponding to the first shell connecting seats 1-3 are arranged on the four sides of the first heat conduction plate 1-2, and first heat conduction plate connecting holes 1-6 are formed in the first heat conduction plate connecting seats 1-5.

A plurality of second shell connecting seats 2-3 are arranged on the four sides of the second shell 2-1, and second shell connecting through holes 2-4 are arranged on the second shell connecting seats 2-3; the four sides of the second heat conduction plate 2-2 are provided with a plurality of second heat conduction plate connecting seats 2-5 corresponding to the plurality of second shell connecting seats 2-3, and the second heat conduction plate connecting seats 2-5 are provided with second heat conduction plate connecting through holes 2-6.

And a plurality of bolts are further arranged, each screw is sequentially screwed into the corresponding first shell connecting through hole 1-4, first heat conducting plate connecting through hole 1-6, second heat conducting plate connecting through hole 2-6 and second shell connecting through hole 2-4 and screwed out, a nut is screwed at one screwed-out end, so that the first water-cooled radiator 1 and the second water-cooled radiator 2 are fixed together, and the thermoelectric generation piece 3 is clamped and fixed between the first heat conducting plate 1-2 and the second heat conducting plate 2-2.

Furthermore, a plurality of first water tank partition plates 1-10 which are distributed at intervals and are parallel to the width direction of the first water tank 1-7 are arranged in the first water tank 1-7, and a first circuitous water channel is formed in the first water tank 1-7 through the plurality of first water tank partition plates 1-10 which are distributed at intervals. The first water inlet 1-8 and the first water outlet 1-9 are respectively arranged at two sides of the first shell 1-1, and the first water inlet 1-8 and the first water outlet 1-9 are communicated through a first circuitous water channel.

A plurality of second water tank clapboards 2-10 which are distributed at intervals and are parallel to the length direction of the second water tank 2-7 are arranged in the second water tank 2-7, and a second circuitous water channel is formed in the second water tank 2-7 through the plurality of second water tank clapboards 2-10 which are distributed at intervals. The second water inlet 2-8 and the second water outlet 2-9 are arranged at the same side of the second shell 2-1, and the second water inlet 2-8 and the second water outlet 2-9 are communicated through a second circuitous water channel.

The thermoelectric generation piece 3 is connected with a lead for outputting the electricity generated by the thermoelectric generation piece.

Claims (7)

1. The utility model provides a thermoelectric generation module for tap, characterized by: comprises a first water-cooling radiator (1), a second water-cooling radiator (2) and a thermoelectric generation sheet (3);

the first water-cooling radiator (1) comprises a first shell (1-1) and a first heat conducting plate (1-2), a first water tank (1-7) is formed in the first shell (1-1), and the first heat conducting plate (1-2) covers the first water tank (1-7) and is fixed with the first shell (1-1); a first water inlet (1-8) and a first water outlet (1-9) which are communicated with the first water tank (1-7) are formed in the first shell (1-1);

the second water-cooling radiator (2) comprises a second shell (2-1) and a second heat conducting plate (2-2), a second water tank is formed in the second shell (2-1), and the second heat conducting plate (2-2) covers the second water tank and is fixed with the second shell (2-1); a second water inlet (2-8) and a second water outlet (2-9) which are communicated with the second water tank (2-7) are formed in the second shell (2-1);

first water-cooling radiator (1), second water-cooling radiator (2) are together fixed, just thermoelectric generation piece (3) are located on first water-cooling radiator (1) first heat-conducting plate (1-2), second water-cooling radiator (2) go up between second heat-conducting plate (2-2), and the two sides of thermoelectric generation piece (3) are hugged closely respectively in first heat-conducting plate (1-2), second heat-conducting plate (2-2).

2. The thermoelectric generation module for the faucet of claim 1, wherein: a plurality of first shell connecting seats (1-3) are arranged on the four sides of the first shell (1-1), and first shell connecting through holes (1-4) are formed in the first shell connecting seats (1-3); the four sides of the first heat conduction plate (1-2) are provided with a plurality of first heat conduction plate connecting seats (1-5) corresponding to the first shell connecting seats (1-3), and the first heat conduction plate connecting seats (1-5) are provided with first heat conduction plate connecting through holes (1-6);

a plurality of second shell connecting seats (2-3) are arranged on the four sides of the second shell (2-1), and second shell connecting through holes (2-4) are formed in the second shell connecting seats (2-3); a plurality of second heat conduction plate connecting seats (2-5) corresponding to the second shell connecting seats (2-3) are arranged on the four sides of the second heat conduction plate (2-2), and second heat conduction plate connecting through holes (2-6) are formed in the second heat conduction plate connecting seats (2-5);

the thermoelectric generation device is characterized by further comprising a plurality of bolts, each bolt is sequentially screwed into the corresponding first shell connecting through hole (1-4), the corresponding first heat conduction plate connecting through hole (1-6), the corresponding second heat conduction plate connecting through hole (2-6) and the corresponding second shell connecting through hole (2-4) and screwed out of the second shell connecting through hole (2-4), a nut is screwed at one screwed-out end, so that the first water-cooled radiator (1) and the second water-cooled radiator (2) are fixed together, and the thermoelectric generation sheet (3) is clamped and fixed between the first heat conduction plate (1-2) and the second heat conduction plate (2-2).

3. The thermoelectric generation module for the faucet of claim 1, wherein: a plurality of first water tank clapboards (1-10) which are distributed at intervals and are parallel to the width direction of the first water tank (1-7) are arranged in the first water tank (1-7), and a first circuitous water channel is formed in the first water tank (1-7) through the plurality of first water tank clapboards (1-10) which are distributed at intervals.

4. The thermoelectric generation module for the faucet of claim 3, wherein: the first water inlet (1-8) and the first water outlet (1-9) are respectively arranged at two sides of the first shell (1-1), and the first water inlet (1-8) and the first water outlet (1-9) are communicated through a first roundabout water channel.

5. The thermoelectric generation module for the faucet of claim 1, wherein: a plurality of second water tank clapboards (2-10) which are distributed at intervals and are parallel to the length direction of the second water tank (2-7) are arranged in the second water tank (2-7), and a second circuitous water channel is formed in the second water tank (2-7) through the plurality of second water tank clapboards (2-10) which are distributed at intervals.

6. The thermoelectric generation module for the faucet of claim 5, wherein: the second water inlet (2-8) and the second water outlet (2-9) are arranged on the same side of the second shell (2-1), and the second water inlet (2-8) and the second water outlet (2-9) are communicated through a second circuitous water channel.

7. The thermoelectric generation module for the faucet of claim 5, wherein: the thermoelectric generation piece (3) is connected with a lead for outputting electricity generated by the thermoelectric generation piece.

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