JP2018169048A - Water heater - Google Patents

Abstract

PROBLEM TO BE SOLVED: To cool an ultraviolet light emitting part and to freely install an ultraviolet sterilizer provided with the ultraviolet light emitting part by adopting a structure in which heat generated from the ultraviolet light emitting part is radiated to a component in a hot water supply device. It is to provide a hot water supply device that improves the degree. A hot water supply device according to the present invention includes a hot water storage tank for storing heated water supplied to a bathtub and a general hot water supply destination, a bath-side circulation pipe for heating the water in the bathtub, and the like. The tank-side circulation pipe for absorbing heat from the heated water in the hot-water storage tank, the reheating heat exchanger arranged in the bath-side circulation pipe and the tank-side circulation pipe, and the water in the hot-water storage tank. It constitutes one of a hot water storage circulation pipe for heating, a heat source machine arranged in the hot water storage circulation pipe to heat water, a bath side circulation pipe, a tank side circulation pipe, and a hot water storage circulation pipe. It is provided with an ultraviolet light emitting unit that irradiates water passing through the pipe with ultraviolet rays, and a heat radiating unit that dissipates heat from the ultraviolet light emitting unit to the pipe. [Selection diagram] Fig. 2

Description

  The present invention relates to a hot water supply apparatus.

  There are two types of heat sources for a hot water supply device, gas or electricity, and a heat pump type hot water supply device is known as a method using electricity as a heat source. The heat pump hot water supply apparatus mainly includes a heat pump unit that is a hot water generator and a hot water storage tank unit that stores hot water. Carbon dioxide is circulated in the heat pump unit as a natural refrigerant (hereinafter referred to as “refrigerant”), and the refrigerant absorbs heat in the atmosphere. And in the compressor in a heat pump unit, the refrigerant | coolant which absorbed heat is compressed using electric power. Thereby, a refrigerant | coolant will be in a high voltage | pressure state and generate | occur | produces high heat.

  By the way, at present, the lower limit of the temperature of hot water supplied by the heat pump type water heater, that is, the tapping temperature is set to around 65 degrees. However, hot water as high as 65 degrees is often unnecessary during periods of low heat demand such as in summer. However, the lower limit of the hot water temperature is set to around 65 ° C., which has the purpose of preventing the propagation of bacteria, particularly Legionella, in the hot water stored in the hot water storage tank unit.

  For the above purposes, the lower limit of the hot water temperature cannot be lowered at present, and hot water is generated in order to prevent the growth of bacteria in spite of the summer season when demand for hot water is low. This is a situation where power is wasted. Therefore, in order to reduce power consumption by lowering the lower limit of the hot water temperature, it is necessary to prevent the proliferation of Legionella bacteria at a low hot water temperature.

  Silver ion, antibacterial agents, ozone, UV sterilization, etc. are known as means to suppress the growth of Legionella bacteria. Among them, UV sterilization does not produce by-products in the reaction pathway and is highly sterilizing. known. Ultraviolet rays having a wavelength of 200 to 350 nm not only act on nucleic acids that are protoplasms of bacteria to deprive them of their growth ability, but also have the action of destroying protoplasms and killing bacteria. Sterilization can be performed by irradiating with water. As such an ultraviolet light source, there is a low-pressure mercury lamp (so-called sterilization lamp) that emits light having a wavelength of 253.7 nm (mercury resonance line) generated by discharge of mercury vapor at a low pressure (about 0.1 Pa). It is common and the sterilizing lamp is widely used in various fields. In recent years, an example in which an ultraviolet light-emitting diode (hereinafter referred to as UV-LED) is used as a light source for ultraviolet rays for sterilization is increasing (see Patent Document 1).

JP, 2006-203095, A

  When using an ultraviolet sterilizer composed of UV-LEDs to sterilize hot water, heat is not collected in the UV light emitting parts such as UV-LEDs in order to exert a certain sterilizing effect and not reduce it. It is necessary to dissipate heat. In order to dissipate heat from the ultraviolet light emitting part, a heat radiating part is required. If the heat radiating part is large, there is a problem that the place where the ultraviolet sterilizer can be installed in the hot water supply apparatus in which the piping of hot water is complicated is restricted. .

  The present invention has been made to solve the above-described problems, and the ultraviolet light emitting part can be cooled by adopting a structure in which heat generated from the ultraviolet light emitting part is radiated to the components in the hot water supply apparatus. In addition, an object is to obtain a hot water supply device that improves the degree of freedom of installing an ultraviolet sterilizer equipped with an ultraviolet light emitter.

  A hot water supply apparatus according to the present invention includes a hot water storage tank for storing heated water supplied to a bathtub and a general hot water supply destination, a bath-side circulation line for heating water in the bathtub, and a hot water storage tank. A tank-side circulation line for absorbing heat from the heated water, a reheating heat exchanger disposed in the bath-side circulation line and the tank-side circulation line, and for heating the water in the hot water storage tank Passes through a hot water storage circulation line, a heat source device that is placed in the hot water circulation line and heats water, and a pipe that constitutes one of the bath side circulation line, tank side circulation line, and hot water circulation line An ultraviolet light emitting unit that irradiates the water with ultraviolet rays, and a heat radiating unit that radiates heat from the ultraviolet light emitting unit to the pipe.

  The hot water supply apparatus of the present invention has an effect that it is possible to easily cool the ultraviolet light emitting unit and improve the degree of freedom of installing an ultraviolet sterilization apparatus for sterilizing hot water.

It is the schematic which shows the hot water supply apparatus of Embodiment 1 of this invention. It is sectional drawing which shows the ultraviolet sterilizer of Embodiment 1 of this invention. It is sectional drawing which shows the 1st modification in the ultraviolet sterilizer of Embodiment 1 of this invention. It is sectional drawing which shows the 2nd modification in the ultraviolet sterilizer of Embodiment 1 of this invention. It is the schematic which shows the hot water supply apparatus of Embodiment 2 of this invention. It is sectional drawing which shows the ultraviolet sterilizer of Embodiment 2 of this invention. It is the schematic which shows the hot water supply apparatus of Embodiment 3 of this invention.

  The present invention will be described in detail with reference to the accompanying drawings. In each figure, the same or corresponding parts are denoted by the same reference numerals. The overlapping description will be simplified or omitted as appropriate.

Embodiment 1 FIG.
FIG. 1 is a configuration diagram illustrating a hot water supply apparatus including the sterilization apparatus according to the first embodiment. As shown in FIG. 1, a hot water supply device 1 according to the first embodiment includes a main body 2, a heat source device 3, a control unit 4 that controls the operation of the hot water supply device 1, an instruction to the control unit 4 and a control unit 4. And a remote control unit 5 indicating the state. The main body 2 has a hot water storage tank 6, and a bathtub 7 and a general hot water supply destination 9 are connected to the other end as a destination for supplying heated water discharged from the hot water storage tank 6. The control unit 4 and the remote control unit 5 show specific configurations of the control means and the input display means, respectively.
In order to heat the hot water in the hot water storage tank 6 with the heat source unit 3, a hot water storage circulation line 8 is provided. In order to sterilize the hot water passing through the hot water storage circulation line 8, an ultraviolet sterilizer 10 is disposed. The ultraviolet sterilizer 10 generates heat when emitting ultraviolet light, and cools the ultraviolet sterilizer 10 so that heat is released to the return pipe 8b, water in the return pipe 8b, and air around the return pipe 8b. ing.

  Moreover, in order to heat the water supplied to the bathtub 7, a bath-side circulation pipe 12 that exits from the bathtub 7, passes through the reheating heat exchanger 11, and returns to the bathtub 7 again is provided. In order to circulate the hot water in the bathtub 7 through the passage 12, a bath-side water pump 13 is provided. The reheating heat exchanger 11 is also connected to a tank-side circulation line 14 that is discharged from the hot water storage tank 6 and returns to the hot water storage tank 6 again, and the heated water in the hot water storage tank 6 is supplied to the tank-side water supply pump 15. The water in the bath-side circulation conduit 12 that passes through the reheating heat exchanger 11 is heated by circulating the heat.

  The heat source unit 3 includes a compressor 20 that compresses a refrigerant, a heating heat exchanger 21 that corresponds to a radiator, an expansion valve 22, an evaporator 23, and a circulation pipe 24 that connects these in an annular shape. The refrigeration cycle unit 25 is provided. In the refrigeration cycle unit 25, a refrigerant such as carbon dioxide is compressed by the compressor 20 to become high temperature and high pressure and then radiated by the boiling heat exchanger 21, depressurized by the expansion valve 22, and absorbed by the evaporator 23. The gas is then drawn into the compressor 20. When carbon dioxide is used as the refrigerant, it is preferable to operate on the high pressure side under conditions that exceed the critical pressure of the carbon dioxide.

  The boiling heat exchanger 21 is connected to the hot water storage circulation line 8 that is discharged from the hot water storage tank 6 and returns to the hot water storage tank 6 again. The amount of heat obtained in the heat source unit 3 is heated through the boiling heat exchanger 21 to heat the water circulating in the hot water storage circulation line 8. A hot water storage water pump 26 is provided to circulate the water in the hot water storage circulation line 8.

  On the other hand, the main body 2 includes a hot water storage tank 6, a hot water storage circulation line 8, a reheating heat exchanger 11, a bath side circulation line 12, a tank side circulation line 14, a water supply line 30, and a first hot water supply line 31. The bath side hot water / water mixing valve 32a, the general side hot water / water mixing valve 32b, the second hot water supply pipe 33, the third hot water supply pipe 34, and the like.

  The hot water storage tank 6 is a stacked tank that stores water supplied from the water supply pipe 30 and stores hot water boiled by the heat source unit 3. Below the hot water storage tank 6, there are provided a water inlet 6 a to which the water supply pipe 30 is connected and a water outlet 6 b to which the forward pipe 8 a of the hot water circulation pipe 8 is connected. At the upper part of the hot water storage tank 6, a hot water inlet 6 c to which the return pipe 8 b of the hot water storage circulation line 8 is connected and a hot water outlet 6 d to which the first hot water supply pipe 31 is connected are provided. The hot water storage tank 6 is always kept in a full state by supplying water from the water supply pipe 30.

  Although not shown, a temperature sensor for detecting the temperature of hot water flowing from the hot water storage tank 6 into the tank side circulation line 14 and the first hot water supply line 31 is attached to the upper part of the hot water storage tank 6. Yes. A plurality of temperature sensors for detecting the temperature of hot water in the hot water storage tank 6 are attached to the peripheral surface portion of the hot water storage tank 6 with different mounting heights.

  The water supply pipe 30 is a pipe for supplying water such as city water to the hot water storage tank 6, the bath-side hot / cold water mixing valve 32 a, the general hot-water mixing valve 32 b, and the general hot water supply destination 9. It has 3rd water supply pipe parts 30a-30c. The pressure reducing valve 35 is provided in the middle of the 1st water supply pipe part 30a, and reduces the water pressure from water sources, such as a water supply, to a predetermined value. The first water supply pipe section 30a connects the water source and the water introduction port 6a of the hot water storage tank 6, and the second water supply pipe section 30b is branched from the first water supply pipe section 30a by the pressure reducing valve 35. 30a is connected to the bath-side hot / cold water mixing valve 32a and the general-side hot / cold water mixing valve 32b, and the third water supply pipe portion 30c is branched from the first water supply pipe portion 30a upstream of the pressure reducing valve 35. 30a and general hot water supply destination 9 are connected. Although not shown, the second water supply pipe portion 30b is provided with a temperature sensor for detecting the temperature of the water in the second water supply pipe portion 30b.

  The general hot water supply destination 9 is a hot water supply destination that is opened by a user's direct operation by hand (including the case where the sensor is opened in response to a sensor), for example, a washbasin, a sink faucet, a bathroom shower, etc. It is.

  The hot water storage circulation line 8 is a pipe line that reaches from the water outlet 6b at the lower part of the hot water storage tank 6 to the hot water inlet 6c at the upper part of the hot water storage tank 6 via the heat exchanger 21 for boiling of the heat source unit 3. It has the forward pipe 8a provided with the water supply pump 26, and the return pipe 8b. The forward pipe 8a connects the water outlet 6b and the boiling heat exchanger 21, and the return pipe 8b connects the boiling heat exchanger 21 and the hot water inlet 6c.

  The tank-side circulation pipe 14 is a pipe that reaches the lower part of the hot water storage tank 6 from the hot water outlet 6d at the upper part of the hot water storage tank 6 via the reheating heat exchanger 11, and includes the forward pipe 14a and the tank side water supply pump 15 And a return pipe 14b. The forward pipe 14 a connects the hot water outlet 6 d and the hot water inlet 11 a at the top of the reheating heat exchanger 11, and the return pipe 14 b connects the hot water outlet 11 b at the bottom of the reheating heat exchanger 11 and the lower part of the hot water storage tank 6. Connect.

  The bath-side circulation line 12 (bath circulation line) is a line that returns from the bathtub 7 to the bathtub 7 via the reheating heat exchanger 11, and includes an outward pipe 12a and a return pipe 12b. The forward pipe 12 a connects the bathtub 7 and the bath water introduction port 11 c below the reheating heat exchanger 11, and the return pipe 12 b connects the bath water outlet 11 d above the reheating heat exchanger 11 and the bathtub 7. The forward switch 12a is provided with a flow switch 36, a water level sensor 37, and a bath-side water supply pump 13 in this order from the reheating heat exchanger 11 side to the upstream side (tub 7 side). Although not shown, the forward pipe 12a is also provided with a temperature sensor for detecting the temperature of hot water in the forward pipe 12a.

  The flow switch 36 detects the presence or absence of a water flow in the forward pipe 12a. The water level sensor 37 detects the water level of the bath water in the bathtub 7 from the water pressure in the forward pipe 12 a based on the mounting position of the water level sensor 37. The bath-side water pump 13 extracts bath water from the bathtub 7, circulates it in the bath-side circulation conduit 12, and returns it to the bathtub 7. The temperature sensor (not shown) detects the temperature of the bath water in the forward pipe 12a. A bathtub adapter 38 is provided at a connecting portion between the forward pipe 12 a and the return pipe 12 b and the bathtub 7.

  In the bathtub adapter 38, two pipe connections are provided so that the forward pipe 12a and the return pipe 12b can be connected.

  The bath water heater 1 further includes a control unit 4 and a remote control unit 5 installed on a bathroom or kitchen wall. The user can set the hot water supply temperature, various operation modes, and the like using the remote controller 5. Based on the information detected by each sensor described above and the information transmitted from the remote control unit 5, the control unit 4 is based on the heat source unit 3, the ultraviolet sterilizer 10, the bath-side water pump 13, the tank-side water pump 15, Various operation control of the bath hot water supply apparatus 1 is performed by controlling the hot water storage water supply pump 26, the bath side hot water / water mixing valve 32a, and the general side hot water / water mixing valve 32b.

  When hot water is supplied to the bathtub 7, the hot water supplied from the hot water storage tank 6 and the water supplied from the water supply pipe 30 are mixed at the bath-side hot water / water mixing valve 32 a so as to have a set temperature, and the mixing is performed. The hot water is sent through the second hot water supply pipe 33 and the bath-side circulation pipe 12 and supplied into the bathtub 7 via the bathtub adapter 38.

  When hot water is supplied to the general hot water supply destination 9, the hot water supplied from the hot water storage tank 6 and the water supplied from the water supply pipe 30 are mixed at the general hot water mixing valve 32b so as to reach a set temperature, The mixed hot water is sent through the third hot water supply pipe 34 and supplied to the general hot water supply destination 9.

  Moreover, the control part 4 may control operation | movement of the other heating apparatus etc. which the hot water supply apparatus 1 with which it does not show. The remote control unit 5 is connected to the control unit 4 so as to be capable of bidirectional data communication, and may further include a user interface such as an operation unit operated by the user, a display unit for notifying the user of information, and a voice announcement device. The remote control unit 5 may be installed in a bathroom.

Next, the configuration of the ultraviolet sterilizer 10 will be described.
FIG. 2 shows a cross-sectional view of the ultraviolet sterilizer in the first embodiment. In FIG. 2, (a) is a cross section in the direction parallel to the water flow of hot water passing through the return pipe 8b, and shows a cross-sectional view of section BB of (b), (b) is hot water passing through the return pipe 8b. It is a cross section perpendicular to the water flow, and shows a cross-sectional view of the AA portion of (a).

  The ultraviolet sterilizer 10 includes a UV-LED 40 that is a specific configuration of the ultraviolet light emitting unit, an LED substrate 41 for installing the UV-LED 40, and a heat radiating unit 42 for radiating heat generated from the UV-LED 40. It has. The UV-LED 40 and the LED substrate 41 are incorporated within the thickness of the return tube 8b, and the inside of the return tube 8b is a reflecting portion 43 that reflects ultraviolet rays, so that the return tube 8b can be irradiated in a wide range. The sterilization efficiency against hot water can be increased. The UV-LED 40 is controlled by a constant current supplied from a power source (not shown). In addition, the arrow in FIG. 2 shows the water flow of hot water typically.

  The heat dissipating part 42 has the same external shape as the return pipe 8b, and has a structure in which the heat dissipating part 42 is cooled by heat dissipation to the hot water passing through the return pipe 8b, the return pipe 8b, and the outside air. The heat radiation part 42 and the return pipe 8b may be an integral structure or a detachable structure. When the ultraviolet sterilizer 10 including the heat radiation part 42 is detachable, the return pipe 8b is connected to the heat radiation part 42. And an attaching / detaching portion (not shown) for attaching and detaching.

The UV-LED 40 is cooled by the heat radiating unit 42, thereby extending the life of the UV-LED 40 and preventing the sterilization effect from being lowered due to the decrease in the ultraviolet intensity. Moreover, it becomes possible to arrange | position the ultraviolet sterilizer 10 in the hot water supply apparatus 1 easily, and the freedom degree which installs the ultraviolet sterilizer 10 improves.
In addition, the ultraviolet sterilizer 10 is not limited to the structure arrange | positioned at the return pipe 8b, The structure arrange | positioned at the bath side circulation line 12, the tank side circulation line 14, the 1st hot water supply pipe 31, etc. may be sufficient.
Moreover, the ultraviolet sterilizer 10 may be arrange | positioned in the position which can radiate | emit heat to the components which have the material with high heat conductivity in the hot water supply apparatus 1. FIG.

  Components having high thermal conductivity in the hot water supply device 1 that radiates heat from the heat radiating unit 42 accommodate at least the main body 2, the hot water storage tank 6, the tank side circulation line 14, the hot water circulation line 8, and the bath side circulation line 12. It may be a hot water supply device housing, and a configuration in which the heat radiating portion 42 is disposed at a position where heat is radiated to at least one of these components. The UV-LED 40 can be cooled by absorbing heat generated from the heat radiating unit 42 by a component having high thermal conductivity.

Moreover, it is preferable that the material to which the ultraviolet sterilizer 10 is attached and the heat radiating part 42 is a component having high thermal conductivity. For example, copper, aluminum, copper tungsten alloy, copper molybdenum alloy, nitriding It may be made of one or a plurality of materials such as aluminum, Al—SiC, Mg—SiC ceramics / metal alloys, and diamond. Each material of the piping to which the ultraviolet sterilizer 10 is attached and the heat radiation part 42 may be made of the same or different materials.
In the above-described component having high thermal conductivity, the material having high thermal conductivity may be a component having high thermal conductivity, or the entire component may be coated on the surface, and the material may be bonded and welded.

  In the case where the heat radiating unit 42 is air-cooled, a structure in which the heat radiating unit 42 is cooled by heat exchange and heat radiation by air touching piping such as the hot water supply device housing, the water supply conduit 30 and the bath circulation conduit 12. It may be. Moreover, you may make it the structure attached to the piping in the hot water supply apparatus 1 which does not have adjacent piping and can perform heat exchange with air efficiently.

  The reflection part 43 may be the reflection part 43 only inside the pipe through which hot water near the UV-LED 40 is disposed, or all the surface inside the pipe.

  Next, the operation of the hot water supply apparatus 1 will be described. Tap water is supplied into the hot water storage tank 6 from the water supply line 30. When the hot water storage tank 6 is filled, the hot water storage water pump 26 is operated and circulates in the hot water storage circulation line 8. When the circulating water is warmed by the amount of heat obtained by the heat source unit 3 through the heating heat exchanger 21 and the water in the hot water storage tank 6 reaches a predetermined temperature or more, the hot water storage water supply pump 26 is stopped. The boiling is completed. The hot water boiled in the hot water storage tank 6 is supplied to the bathtub 7 or the general hot water supply destination 9 according to the operation of the user. With respect to the decrease in hot water in the hot water storage tank 6 due to the supply to the bathtub 7 or the general hot water supply destination 9, the hot water storage tank 6 is additionally replenished from the water supply line 30. While the above operation is repeated, the hot water temperature in the hot water storage tank 6 decreases, so that when the temperature falls below a predetermined temperature, the boiling operation is performed again.

  When the hot water temperature in the hot water storage tank 6 decreases, the bacterial propagation in the hot water storage tank 6 increases. For this reason, when the hot water temperature in the hot water storage tank 6 is lowered, the ultraviolet sterilization apparatus 10 is periodically connected after a predetermined time has elapsed since the temperature decreased or when the hot water storage tank 6 becomes lower than the predetermined hot water temperature. The hot water storage water supply pump 26 disposed in the hot water storage circulation line 8 is operated and the power is input to the ultraviolet sterilizer 10 to cause the UV-LED 40 to emit light. Sterilize the hot water inside.

  The ultraviolet sterilizer 10 may periodically perform an operation of irradiating ultraviolet rays when the hot water storage water supply pump 26 disposed in the hot water circulation path 10 is operating. By sterilizing the hot water with the ultraviolet rays, the temperature of the hot water in the hot water storage tank 6 can be set lower than before.

Next, a modified example of the ultraviolet sterilizer 10 will be described.
FIG. 3 is a schematic diagram illustrating a first modification of the ultraviolet sterilizer according to the first embodiment. In FIG. 3, the heat radiating part 32 is configured to be disposed in a partial region with respect to the outer shape of the return pipe 8b.
FIG. 4 is a schematic diagram illustrating a second modification of the ultraviolet sterilizer according to the first embodiment. In FIG. 4, the return pipe 8b is provided with a window portion 44 that transmits ultraviolet rays. The UV-LED 40, the LED substrate 41, and the heat radiating unit 42 are disposed outside the window 44, and the ultraviolet light from the UV-LED 40 passes through the window 44 and is irradiated onto the hot water.
When the ultraviolet sterilizer 10 shown in FIGS. 2 to 4 is arranged on the return pipe 8b, there is no restriction on the direction of gravity, and for example, the UV-LED 40 is arranged on the upper side of the return pipe 8b to sterilize hot water. You may make it the structure to do.

Embodiment 2. FIG.
The hot water supply apparatus shown in the present embodiment is different from the first embodiment in the arrangement of the forward pipe 8a adjacent to the ultraviolet sterilizer 10. In addition, the same number is attached | subjected to the same structure as Embodiment 1, and description is abbreviate | omitted.
FIG. 5 is a schematic diagram showing a hot water supply apparatus according to Embodiment 2 of the present invention. In FIG. 5, the ultraviolet sterilizer 10 is disposed in the hot water storage circulation line 8. When hot water circulates in the return pipe 8b of the hot water storage circulation line 8, the hot water is sterilized by irradiating the hot water with ultraviolet rays. The forward tube 8a is disposed adjacent to the ultraviolet sterilizer 10 and has a structure for cooling the ultraviolet sterilizer 10.

  In addition, arrangement | positioning of the ultraviolet sterilizer 10 is not limited to the hot water storage circulation line 8, One of the bath side circulation line 12 or the tank side circulation line 14, or all of these circulation lines It may also be configured to be incorporated in. The heat dissipating part 42 of the ultraviolet sterilizer 10 has the same structure as the outer shape of the return pipe 8b, and the heat dissipating part 42 is cooled by exchanging heat with the forward pipe 8a in contact with the heat dissipating part 42.

  FIG. 6 is a cross-sectional view showing a sterilizer according to Embodiment 2 of the present invention. In FIG. 6, (a) is a cross-section in the direction parallel to the water flow of hot water passing through the return pipe 8b, and shows a cross-sectional view of section BB in (b), (b) is hot water passing through the return pipe 8b. It is a cross section perpendicular to the water flow, and shows a cross-sectional view of the AA portion of (a).

  The ultraviolet sterilizer 10 includes a UV-LED 40, an LED substrate 41, and a heat dissipation part 42. The UV-LED 40 and the LED substrate 41 are incorporated within the thickness of the return tube 8b, and the inside of the return tube 8b is a reflecting portion 43 that reflects ultraviolet rays, so that the return tube 8b can be irradiated in a wide range. , Sterilization efficiency can be increased. The UV-LED 40 is controlled by a constant current supplied from a power source (not shown).

The heat dissipating part 42 has the same outer shape as the return pipe 8b, the outer part is in contact with the forward pipe 8a, and the heat dissipating part 42 is cooled by hot water passing through the forward pipe 8a. . The heat dissipating part 42 may be arranged in a partial region with respect to the outer shape of the return pipe 8b shown in FIG.
In addition, the arrow in FIG. 6 shows the water flow of hot water typically. Further, the forward pipe 8a shows a specific configuration of the cooling means for the heat radiating section 42.

The ultraviolet sterilizer 10 is not limited to the configuration adjacent to the forward pipe 8a, and may be a structure adjacent to the water supply pipe 30 through which tap water passes or the circulation pipe 24 through which refrigerant passes.
Further, it may be arranged at a position where heat can be radiated to a component having a material with high thermal conductivity of the hot water supply device 1.

  Components having high thermal conductivity in the hot water supply device 1 that radiates heat from the heat radiating unit 42 accommodate at least the main body 2, the hot water storage tank 6, the hot water storage circulation line 8, the bath side circulation line 12, the tank side circulation line 14. It is a hot-water supply apparatus housing | casing, and the thermal radiation part 42 may be arrange | positioned in the position which contacts at least 1 component among these components. The UV-LED 40 can be cooled by absorbing heat generated from the heat radiating unit 42 by a component having high thermal conductivity.

  Moreover, you may make it the structure used in order to heat the heat from the thermal radiation part 42 of the ultraviolet sterilizer 10 to heat the water which passes through the circulation pipeline 8 for hot water storage.

Embodiment 3 FIG.
The hot water supply apparatus shown in the present embodiment is different from the first embodiment in the arrangement of the ultraviolet sterilizer 10 and the hot water storage tank 6. The same components as those in the first embodiment are denoted by the same reference numerals and description thereof is omitted.
FIG. 7 is a schematic diagram showing a hot water supply apparatus according to Embodiment 3 of the present invention. In FIG. 7, the ultraviolet sterilizer 10 is disposed in a pipe branched from the return pipe 8 b and is disposed in the hot water storage tank 6 at a position where heat is radiated from the heat radiation portion 42. The heat radiating unit 42 may be in contact with the hot water storage tank 6. The ultraviolet sterilizer 10 is not limited to being disposed in the hot water storage circulation line 8, and may be configured to be disposed in the tank side circulation line 14 or the first hot water supply line 31.

  When the heat dissipating part 42 is disposed at a position where heat is dissipated to the hot water storage tank 6, the heat generated from the ultraviolet sterilizer 10 can be returned to the hot water storage tank 6. It becomes possible to suppress a drop in hot water temperature.

  As described above, it is possible to realize a hot water supply device that can easily cool the ultraviolet light emitting unit and improve the degree of freedom of installing an ultraviolet sterilizer for sterilizing hot water.

  In the first to third embodiments described above, the configuration in which the ultraviolet sterilizer is disposed in the hot water supply device has been described. However, the present invention may be applied to other electrical devices that need to be sterilized by ultraviolet rays. It is also possible to apply to sterilizing air.

  In addition, the component shown in each said embodiment, the connection form of a component, etc. are examples, and do not limit this invention. In other words, the constituent elements and their connection forms can be expanded to other devices without departing from the spirit of the present invention, various modifications can be made to the constituent elements and their connection forms, and the like can be combined. is there.

DESCRIPTION OF SYMBOLS 1 Hot water supply apparatus, 2 Main body, 3 Heat source machine, 4 Control part 5 Remote control part 6 Hot water storage tank, 6a Water inlet, 6b Water outlet, 6c Hot water inlet, 6d Hot water outlet, 7 Bathtub, 8 Circulation pipe for hot water storage 8a Outward pipe, 8b Return pipe, 9 General hot water supply destination, 10 UV sterilizer, 11 Heat exchanger for reheating, 11a Hot water inlet, 11b Hot water outlet, 11c Bath water inlet, 11d Bath water outlet, 12 Bath side circulation pipe, 12a Outward pipe, 12b Return pipe, 13 Bath side water supply pump, 14 Tank side circulation pipe, 14a Outward pipe, 14b Return pipe, 15 Tank side water supply pump, 20 Compressor, 21 Heat for heating Exchanger, 22 Expansion valve, 23 Evaporator, 24 Circulation piping, 25 Refrigeration cycle section, 26 Water supply pump for hot water storage, 30 Water supply pipe line, 30a First water supply pipe section, 30b Second water supply pipe section 30c 3rd water supply pipe part, 31 1st hot water supply pipe, 32a Bath side hot water mixing valve, 32b General side hot water mixing valve, 33 2nd hot water supply pipe, 34 3rd hot water supply pipe, 35 Pressure reducing valve, 36 Flow switch, 37 Water level sensor, 38 Bathtub adapter, 40 UV-LED, 41 LED substrate, 42 Heat radiation part, 43 Reflection part, 44 Window part

Claims (7)

A hot water storage tank for storing heated water supplied to a bathtub and a general hot water supply destination;
A bath-side circulation conduit for heating the water in the bathtub;
A tank side circulation line for absorbing heat from the heated water in the hot water storage tank;
A reheating heat exchanger disposed in the bath-side circulation line and the tank-side circulation line;
A hot water storage circulation line for heating the water in the hot water storage tank;
A heat source device that is disposed in the hot water circulation conduit and heats the water;
An ultraviolet light emitting unit for irradiating the water passing through the pipe constituting either the bath side circulation line, the tank side circulation line or the hot water circulation line;
A hot water supply apparatus comprising: a heat radiating part that radiates heat of the ultraviolet light emitting part to the pipe. The hot water supply apparatus according to claim 1, further comprising: a reflecting portion that reflects the ultraviolet light in the pipe in which the ultraviolet light emitting unit is installed. Control means for controlling the reheating heat exchanger, the heat source unit and the ultraviolet light emitting unit;
The hot water supply apparatus according to claim 1, further comprising: an input display unit that indicates an instruction to the control unit and a state of the control unit. The hot water supply apparatus according to any one of claims 1 to 3, further comprising a cooling unit that cools the heat radiating unit. A water supply line for supplying the water to the hot water storage tank;
The water supply pipe, the bath-side circulation pipe, the tank-side circulation pipe, the hot water storage circulation pipe, and a hot water storage device housing the hot water storage tank, and the heat radiating section,
At least one of the pipe for the water supply pipe, the pipe for the bath side circulation pipe, the pipe for the tank side circulation pipe, the pipe for the circulation pipe for hot water storage, the hot water storage tank, and the case of the hot water supply device The hot water supply device according to any one of claims 1 to 4, wherein heat of the ultraviolet light emitting unit is radiated. The hot water supply device according to any one of claims 1 to 5, wherein the heat radiating portion has a structure through which the water passes. The hot water supply device according to any one of claims 1 to 6, wherein the heat dissipating unit is in contact with a lower portion of the hot water storage tank.

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