KR20190057545A - Water receiving apparatus capable of displaying temperature through thermoelectric power generation - Google Patents

Abstract

According to the present invention, a faucet apparatus capable of displaying a temperature by thermoelectric power generation comprises: a cold water supply unit connected to a cold water pipe to supply cold water from the cold water pipe to the outside; and a hot water supply unit to receive cold water from the cold water pipe to heat the cold water, and then supply heated water to the outside through a hot water pipe. The faucet apparatus further comprises: a thermoelectric module arranged between the cold water supply unit and the hot water supply unit to convert heat energy by a temperature difference between the cold water supply unit and the hot water supply unit into electric energy; an energy storage unit to store electric energy provided from the thermoelectric module; a lighting control unit to sense the intensity of electric energy supplied to the energy storage unit to check the temperature of cold water or hot water, and transfer a signal of the checked temperature; and a temperature display unit to receive a signal from the lighting control unit to display the temperature of cold water or hot water. Accordingly, thermoelectric power generation is performed by using a temperature difference of cold water and hot water, and electric energy obtained by thermoelectric power generation can be used in driving the temperature display unit to eliminate a need for supply of separate power.

Description

[0001] The present invention relates to a water receiving apparatus capable of displaying a temperature through a thermoelectric power generation,

The present invention relates to a water receiving apparatus capable of displaying a temperature through a thermoelectric generator, more particularly, to a thermoelectric generator using a temperature difference between cold water and hot water, and to use the electric energy obtained through the thermoelectric generator for driving a temperature display unit To a water receiving apparatus capable of displaying a temperature through a thermoelectric generator which does not require a separate electric supply.

Currently, faucets are sold as household goods with very high added value by various functions and designs. In recent years, LED technology has been combined with faucet to realize various lighting corresponding to the temperature of water supply, so that expensive faucets capable of preventing burns due to hot water or sensing the temperature of the used water are emerge. Until now, however, there are no faucet products that can be developed by themselves, but faucets that indicate the temperature of the faucet are supplied at high prices. Therefore, it is possible to connect self-power generation technology to faucet, and it is possible to generate thermoelectric power by typical self-power generation.

Thermoelectric generation is a technology that converts heat energy directly into electric energy. It is a concept that heat generated by the temperature difference between the high temperature part and the low temperature part is converted into electric energy to move. Technology that converts heat energy to electrical energy when temperature difference exists between p and n semiconductor devices by using Seebeck effet which generates electromotive force when temperature difference is given to both ends of two kinds of metal connected devices. to be. Since the thermoelectric power generation uses a solid-state electronic circuit, there is no operation part, and the structure is simple, and various heat sources are available, and it is attracting attention as a new alternative energy technology. In recent years, heat from industrial facilities, exhaust gas from automobiles, and solar heat have been used as power generation sources for thermoelectric power generation.

However, even in the case of non-industrial facilities or special facilities, high-temperature heat generated for thermoelectric power generation is not utilized properly. In particular, a considerable amount of heat is generated in hot water used in general households or hotels, but it is not applied to thermoelectric power generation properly.

Korea Patent Office Registration No. 10-0977403 Korean Patent Application Publication No. 10-2014-0043197

SUMMARY OF THE INVENTION It is therefore an object of the present invention to provide a thermoelectric generator which can perform thermoelectric generation using the temperature difference between cold water and hot water and can utilize the electric energy obtained through the thermoelectric generator for driving the temperature display unit, A water receiving device capable of displaying a temperature is provided.

The above-mentioned object is achieved by a cold water supply system comprising: a cold water supply unit connected to a cold water pipe to supply cold water from the cold water pipe to the outside; And a hot water supply unit for supplying hot water to the outside through a hot water pipe after receiving cold water from the cold water pipe, the water receiving apparatus comprising: a cold water supply unit A thermoelectric module for converting thermal energy due to a temperature difference between the cold water supply unit and the hot water supply unit into electric energy; An energy storage unit for storing electric energy provided from the thermoelectric module; A lighting controller for sensing the intensity of the electric energy provided to the energy storage unit to confirm the temperature of the cold water or the temperature and transmitting the sensed temperature; And a temperature display unit for receiving the signal from the illumination control unit and displaying the temperature of the cold water or the hot water.

Here, the temperature display unit may include a first temperature display unit displayed when the temperature is 0 to 20 캜; A second temperature display portion displayed when the temperature is between 21 and 40 캜; And a third temperature display portion which is displayed when the temperature is 41 DEG C or higher, and is preferably made of an LED.

The thermoelectric module may further include: a first conductor in contact with the cold water supply unit; A second conductor contacting the hot water supply unit; And an n-type and a p-type semiconductor interposed between the first conductor and the second conductor and converting thermal energy due to a temperature difference between the first conductor and the second conductor into electric energy Do.

And a temperature sensor for measuring the temperature of the cold water or hot water supplied from the cold water supply unit and the hot water supply unit and transmitting a signal to the lighting control unit.

According to the present invention, the thermoelectric power generation can be performed by using the temperature difference between the cold water and the hot water, and the electric energy obtained through the thermoelectric power generation can be used for driving the temperature display unit.

1 is a front view of a water receiving apparatus according to an embodiment of the present invention,
Figure 2 is an interior view of Figure 1;

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a water receiving apparatus 100 capable of displaying a temperature through a thermoelectric generator according to an embodiment of the present invention will be described in detail with reference to the drawings.

As shown in FIGS. 1 and 2, the water receiving apparatus 100 includes a handle 110 provided to allow a user to receive water, a cold water supply unit 120 for supplying cold water to the outside, a hot water supply unit 120 for supplying hot water, A thermoelectric module 140 interposed between the supply part 130, the cold water supply part 120 and the hot water supply part 130, an energy storage part 150 receiving electric energy from the thermoelectric module 140, A lighting control unit 160 and a temperature display unit 170 for displaying the temperature of the hot water.

The cold water supply unit 120 is connected to the cold water pipe, and receives cold water from the cold water pipe and then supplies the cold water to the outside. The hot water supply unit 130 receives cold water from the cold water pipe and heats the cold water using oil or gas to form hot water, and then supplies the hot water to the outside through the hot water pipe. The temperature of the water is determined according to the amount of cold water or hot water supplied from the cold water supply unit 120 and the hot water supply unit 130. Here, cold water is supplied from a water source or an already stored water tank.

 The thermoelectric module 140 intervenes between the cold water supply unit 120 and the hot water supply unit 130 to convert the thermal energy due to the temperature difference between the cold water supply unit 120 and the hot water supply unit 130 into electrical energy. In the case of the cold water supply unit 120, cold water is supplied, and in the case of the hot water supply unit 130, hot water having a temperature higher than that of cold water is supplied, so that a temperature difference occurs between cold water and hot water. Due to the temperature difference, the thermoelectric module 140 converts the thermal energy due to the temperature difference into electric energy through the Seebeck effect. At this time, when the temperature difference between the cold water and the hot water is large, a larger thermal energy is generated and thus a high capacity electric energy can be obtained.

The cold water supply unit 120 and the hot water supply unit 130 are made of a material having a high thermal conductivity so that the thermoelectric module 140 can be driven through the temperature difference between the cold water supply unit 120 and the hot water supply unit 130, . For example, aluminum, copper, or an alloy thereof having a high thermal conductivity among metals may be used as the material having a high thermal conductivity.

The thermoelectric module 140 includes a first conductor 141 in contact with the cold water supply unit 120, a second conductor 142 in contact with the hot water supply unit 130, a first conductor 141, 2 conductors 142 between the n-type and p-type semiconductors 143. The n- The n-type and p-type semiconductors 143 have a structure in which the n-type semiconductor and the p-type semiconductor are alternately arranged on the same plane and spaced apart by an arbitrary interval. The first conductor 141 and the second conductor 142) to the electric energy. That is, the DC voltage is generated by the temperature difference between the cold water and the hot water, so that the electric energy can be obtained.

The energy storing unit 150 serves to store the electric energy supplied from the thermoelectric module 140. Conventionally, only a technique of directly supplying electric energy to the outside even if electric energy is produced using the temperature difference between the cold water supply unit 120 and the hot water supply unit 130 in the water receiving apparatus has been known. However, in the present invention, an energy storing unit for storing electric energy is additionally provided, so that the water receiving apparatus 100 can be easily installed and semi-permanent operation of the water receiving apparatus 100 becomes possible. Further, there is an advantage that management of the water receiving apparatus 100 is facilitated since a separate energy supplying apparatus is not required.

The lighting control unit 160 senses the intensity of the electric energy supplied from the thermoelectric module 140 to the energy storage unit 150 to check the temperature of the cold or hot water and transmits the signal of the determined temperature difference. Since the electric energy intensity of the thermoelectric module 140 varies depending on the temperature difference between the cold water and the hot water, the temperature of the cold water or the hot water can be confirmed through the strength of the electric energy. Accordingly, the illumination controller 160 can sense the intensity of the electric energy stored in the energy storage unit 150 and measure the temperature of the cold water or the hot water.

 In addition, the temperature sensor 180 may be additionally installed. The temperature sensor 180 directly measures the temperature of the cold or hot water supplied from the cold water supply unit 120 and the hot water supply unit 130 and transmits the signal to the lighting control unit 160. Therefore, when both the illumination control unit 160 and the temperature sensor 180 are installed in the water receiving apparatus 100, the temperature of cold water or hot water can be detected more accurately.

The temperature display unit 170 receives a signal from the illumination controller 160 and displays the temperature of the cold water or hot water. There is a possibility that a user who uses the water receiving apparatus 100 may be burnt by an extremely high temperature when water is poured into the water receiving apparatus 100. In order to prevent such a problem in advance and to supply water of a desired temperature to the user, A separate temperature display unit 170 is provided. The temperature display unit 170 is preferably formed of LEDs consuming less electric energy, but is not limited thereto.

The temperature display unit 170 may include a first temperature display unit 171, a second temperature display unit 172, and a third temperature display unit 173 which are formed of a plurality of units and are displayed according to a temperature range. The illumination is turned on in the first temperature indicator 171 when the temperature is in the range of 0 to 20 degrees Celsius and in the second temperature indicator 172 in the range of 21 to 40 degrees Celsius, The user can turn on the water to determine the temperature, turn the water or adjust the temperature.

As described above, according to the present invention, the thermoelectric power generation is performed using the temperature difference between the cold water and the hot water, and the electric energy obtained through the thermoelectric power generation can be used for driving the temperature display unit 170, It is possible to obtain the water receiving apparatus 100 capable of displaying the temperature through the water receiving apparatus. In addition, since the hot water temperature display is made on the water receiving device, it is possible to grasp the temperature before the user turns on the water and to rotate the water by appropriately adjusting the desired temperature.

100: water receiving device 110: handle portion
120: cold water supply unit 130: hot water supply unit
140: thermoelectric module 141: first conductor
142: second conductor 143: n-type and p-type semiconductors
150: Energy storage unit 160: Lighting control unit
170: temperature display section 171: first temperature display section
172: second temperature display section 173: third temperature display section
180: Temperature sensor

Claims (5)

A cold water supply unit connected to the cold water pipe to supply cold water from the cold water pipe to the outside; And a hot water supply unit for supplying hot water to the outside through a hot water pipe after receiving cold water from the cold water pipe and heating the hot water pipe,
A thermoelectric module interposed between the cold water supply unit and the hot water supply unit to convert thermal energy due to a temperature difference between the cold water supply unit and the hot water supply unit into electrical energy;
An energy storage unit for storing electric energy provided from the thermoelectric module;
A lighting controller for sensing the intensity of the electric energy provided to the energy storage unit to confirm the temperature of the cold water or the temperature and transmitting the sensed temperature;
And a temperature display unit that receives a signal from the illumination control unit and displays a temperature of the cold water or the hot water. The method according to claim 1,
The temperature display unit includes:
0 > C to 20 < 0 >C;
A second temperature display portion displayed when the temperature is between 21 and 40 캜;
And a third temperature display unit which is displayed when the temperature is higher than or equal to 41 ° C. The method according to claim 1,
The temperature display unit includes:
Wherein the thermoelectric generator is a thermoelectric generator. The method according to claim 1,
The thermoelectric module includes:
A first conductor in contact with the cold water supply;
A second conductor contacting the hot water supply unit;
And an n-type and a p-type semiconductor interposed between the first conductor and the second conductor and converting thermal energy due to a temperature difference between the first conductor and the second conductor into electric energy Which can display the temperature through the thermoelectric power generation. The method according to claim 1,
And a temperature sensor for measuring a temperature of cold water or hot water supplied from the cold water supply unit and the hot water supply unit and transmitting a signal to the lighting control unit.

Images