JP4764435B2 - Water heater - Google Patents

Description

  The present invention relates to a hot water supply apparatus.

  Conventionally, for example, a hot water supply apparatus disclosed in Japanese Patent Application Laid-Open No. 2007-12084 (hereinafter referred to as a conventional example) has been proposed.

  This conventional example includes a heating unit including a boiler and a heat pump, and a hot water storage tank for storing hot water heated by the heating unit. The boiler and the heat pump in the heating unit are appropriately switched and controlled. The hot water storage tank is heated.

  That is, in the conventional example, the heat pump is operated at night when the amount of hot water used is relatively small and the electricity bill is low, and the water in the hot water storage tank is heated over time. When the temperature of the hot water used is low (the hot water tank is replenished with the amount of hot water extracted, so the hot water temperature of the hot water tank decreases). This is a structure that compensates for this by operating a boiler with high heating capacity. The heat pump and the boiler are controlled to be switched based on information from a temperature sensor provided in the hot water storage tank.

  Therefore, the conventional example has a lower running cost than a boiler-only structure, is a structure that is good for an environment that uses electric power as clean energy, and in a situation where a heat pump cannot maintain a temperature higher than a predetermined temperature. Since it is a structure corresponding to a boiler, hot water having an optimum temperature can always be obtained.

JP 2007-12084 A

  However, in the conventional example, the heat pump may not operate well in winter when the air (outside air) is cold.

  Specifically, the heat pump uses a compressor that compresses the refrigerant, a refrigerant heat exchanger that exchanges heat between the compressed refrigerant and the heated medium, an expansion valve (decompression unit), and air as a heat source. It has a refrigerant circuit consisting of an air heat exchanger (takes heat from the air), but when heat is exchanged by sucking air with a fan in this air heat exchanger, frost adheres if the air is cold As a result, the air heat exchanger does not function well, and thus the heat pump must be stopped while frost is attached to the air heat exchanger. The heat pump is provided with a function (defrost function) for automatically stopping the entire apparatus when the frost adheres to the air heat exchanger and removing the frost.

  The present invention provides an epoch-making hot water supply apparatus that solves the above-described problems and exhibits an unprecedented effect.

  The gist of the present invention will be described with reference to the accompanying drawings.

In a hot water supply apparatus having a heating unit 4 including a boiler 2 and a heat pump 3, the heat pump 3 has an air heat exchanger 5 using air as a heat source, and the heating unit 4 is provided in a chamber 6 having a heat insulating wall structure. The air heat exchanger 5 is disposed in the proximity of the boiler 2, and the hot water storage tank 1 for storing hot water heated by the heating unit 4 is disposed in the chamber 6. the air heat exchanger 5 is all SANYO to heat source air heated by the heat radiation to the surroundings from the boiler 2 and the hot water storage tank 1, the water storage tank 1 inside the central position and a lower position respectively are Thermostats 10A and 10B for measuring hot water temperature are provided, and the boiler 2 is controlled to operate or stop based on the hot water temperature measurement in the upper thermostat 10A, and the heat pump 3 It relates to a hot water supply device according to claim being configured to be controlled to operate or stop based on the measurement of the hot water temperature in the serial bottom of the thermostat 10B.

The hot water supply apparatus according to claim 1, wherein the hot water storage tank 1 has a vertically long shape .

Further, in the hot water supply apparatus according to any one of claims 1 and 2, the hot water storage tank 1 is provided with a hot water circulation section 7, and the hot water circulation section 7 is connected to the hot water storage tank 1 and connected to the hot water use section. This is a hot water supply apparatus characterized in that a pump device 7 b is provided in a circulation path 7 a having 8 .

  Since the present invention is configured as described above, unlike the conventional example described above, for example, the heat pump does not stop in winter when the air is cold, and an unprecedented effect such as that a good operating state can always be obtained. It becomes an epoch-making hot water supply device that demonstrates.

  Embodiments of the present invention considered to be suitable will be briefly described with reference to the drawings.

  Water in the apparatus according to the present invention is heated by a heating unit 4 including a boiler 2 and a heat pump 3 to form hot water.

  By the way, in the present invention, the heat pump 3 has an air heat exchanger 5 using air as a heat source, and air heated by heat radiation to the surroundings in the boiler 2 is used as a heat source of the air heat exchanger 5.

  Therefore, unlike the above-described conventional example, frost adheres to the air heat exchanger 5 that uses air heated by heat radiation to the surroundings of the boiler 2 as a heat source even in the winter when the air gets cold. Therefore, the heat pump 3 does not stop due to the above-described adhesion of frost, and a good operating state is always obtained (this point has been confirmed by experiments conducted by the present inventor).

  Moreover, since the structure which prevents this frost adhesion uses the air heated by the thermal radiation to the periphery in the essential boiler 2 which comprises the heating part 4, this invention prevents the frost adhesion. Therefore, the structure becomes extremely efficient without using a special heating device or the like separately.

  A specific embodiment of the present invention will be described with reference to the drawings.

  In this embodiment, a heating unit 4 including a boiler 2 and a heat pump 3 and a hot water storage tank 1 for storing hot water HW heated by the heating unit 4 are provided. In this specification, water having a temperature that needs to be heated by the heating unit 4 is water W, and water having a temperature that is heated by the heating unit 4 and is suitable for use is hot water HW.

  Specifically, the hot water storage tank 1 is a vertically long tank as shown in FIG. 1, and the hot water storage tank 1 is provided with a hot water circulation section 7.

  As shown in FIGS. 1 to 3, the hot water circulation section 7 has a configuration in which a pump device 7 b is provided in a circulation path 7 a provided continuously with the hot water storage tank 1 and provided with a hot water use section 8 (faucet). 7 a is connected to a hot water feed portion 1 a provided at the upper part of the hot water storage tank 1 and a hot water return portion 1 b provided at the center of the hot water storage tank 1.

  The hot water HW heated by the heating unit 4 is easily stored in the upper part of the hot water storage tank 1 due to the nature of the heat. Therefore, the hot water HW stored in the upper part of the hot water storage tank 1 is preferentially used from the hot water feeding part 1a. It is configured to send to the unit 8.

  Further, a hot water introduction part 1c is provided at the upper part of the hot water storage tank 1, and this hot water introduction part 1c is extended from a boiler 2 and a heat pump 3 associated with the heating part 4 described later, and a pipe member 13 for sending hot water HW. , 19 are connected.

  Further, thermostats 10A and 10B are provided at the center and the lower part of the hot water storage tank 1, respectively.

  Each of the thermostats 10A and 10B measures the temperature of the hot water in the vicinity of the center and the lower part of the hot water storage tank 1, and the boiler 2 associated with the heating unit 4 to be described later based on the measurement data of the thermostats 10A and 10B. The operation of the heat pump 3 is switched and controlled.

  Specifically, the upper thermostat 10A is set to operate the boiler 2 when the temperature near the center of the hot water storage tank 1 is 60 ° C. or lower, and to stop the operation of the boiler 2 when the temperature is 65 ° C. or higher. The temperature setting of the thermostat 10A can be changed as appropriate.

  The lower thermostat 10B is set to operate the heat pump 3 when the temperature near the lower side of the hot water storage tank 1 is 35 ° C. or lower, and to stop the operation of the heat pump 3 when the temperature is 50 ° C. or higher. The temperature setting of the thermostat 10B can be changed as appropriate.

  As shown in FIG. 1, the heating unit 4 includes a boiler 2 and a heat pump 3 connected to the hot water storage tank 1 described above.

  The boiler 2 has a known structure that is operated by a fuel such as gas or oil (petroleum), and the boiler 2 is used to heat the water W drawn from the hot water storage tank 1 and to heat the water W. It is configured to return the hot water HW to the hot water storage tank 1.

  Specifically, as shown in FIGS. 1 to 3, the boiler 2 includes a pipe member 12 connected to a water outlet 1 d provided at the lower part of the hot water storage tank 1, and a hot water introduction part provided at the upper part of the hot water storage tank 1. And a pipe member 13 connected to 1c, and draws and heats water W in the lower part of the hot water storage tank 1 and supplies the hot water HW produced by the heating in the upper part of the hot water storage tank 1 Configured to send to.

  Reference numeral 14 is a pump device, and 20 is a backflow prevention valve.

  The heat pump 3 has a known structure that is operated by electric power, and includes a compressor that compresses a refrigerant (not shown), a refrigerant heat exchanger 15 that exchanges heat between the compressed and temperature-increased refrigerant, and a heat medium, and a heater that is not shown. And a refrigerant circuit comprising an air heat exchanger 5 that uses air as a heat source (takes heat away from the air).

  The heat pump 3 is used to heat the water W drawn from the hot water storage tank 1 and the water pipe 16 and return the hot water HW generated by the heating to the hot water storage tank 1.

  Specifically, as shown in FIGS. 1 to 3, the heat pump 3 is provided at the upper part of the hot water storage tank 1 and the water lead-in / in part 1 e provided at the lower part of the hot water storage tank 1 and the pipe member 18 connected to the water pipe 16. The hot water produced by drawing and heating the water W supplied from the lower part of the hot water storage tank 1 and the water pipe 16 is provided. The HW is configured to be sent to a hot water introduction part 1 c provided at the upper part of the hot water storage tank 1.

  Reference numeral 21 is a pump device, and 22 is a backflow prevention valve.

  In this embodiment, as shown in FIG. 1, the hot water storage tank 1 and the heating unit 4 (boiler 2 and heat pump 3) are disposed in a chamber 6 (so-called boiler chamber) having an appropriate space.

  The chamber 6 has a heat insulating wall structure, and heat generated in the chamber 6 is difficult to escape to the outside, and a good heat retaining effect is obtained.

  From this structure, the air heated by the heat radiation to the surroundings in each part (equipment equipment, piping, and electrical equipment equipment arranged in the chamber 6) of the boiler 2 and the hot water storage tank 1, and this embodiment is the chamber 6 The heated air becomes a heat source of the air heat exchanger 5 related to the heat pump 3.

  As a result of an actual trial, the inventor of the present invention has significantly reduced the adhesion of frost to the air heat exchanger 5 of the heat pump 3 as compared with the above-described conventional example, and a good operating state of the heat pump 3 can be continuously obtained. It was confirmed that The configuration in which the heated air in the chamber 6 is used as a heat source for the air heat exchanger 5 is not only effective for use in winter, but also extremely effective for use in summer when the interior of the chamber 6 is hot. is there.

  That is, in the summer when the temperature of the outside air becomes high, the inside of the chamber 6 in which the boiler 2 and the like are disposed becomes high temperature, and this heat causes trouble in the operation of various equipment devices disposed in the chamber 6. In this embodiment, since the heated air in the chamber 6 is positively used as the heat source of the air heat exchanger 5, heat is taken from the heated air in the chamber 6. As a result, the inside of the chamber 6 is cooled, so that various equipments are always operated normally.

  In this embodiment, the air heat exchanger 5 is disposed in the chamber 6 in which the boiler 2 is disposed, so that the air heated by the heat radiation to the surroundings in the boiler 2 is converted into a heat source for the air heat exchanger 5. However, a heat source composed of heated air may be secured by disposing it in the proximity of the boiler 2 even outdoors.

  The operation of the present embodiment having the above configuration will be described.

  When the hot water HW is not used and the thermostat 10B detects that the temperature is 50 ° C. or higher, the heat pump 3 is in an operation stopped state.

  When the thermostat 10B detects that the temperature is 35 ° C. or lower when the hot water HW is not used, the water W in the hot water storage tank 1 is sent to the heat pump 3 and heated as shown in FIG. The hot water HW thus produced is returned to the hot water storage tank 1, and the hot water boundary line L between the hot water HW and the water W divided into the upper layer and the lower layer in the hot water storage tank 1 is operated to be maintained at a position below the thermostat 10A. That is, only the heat pump 3 operates so that the boiler 2 does not operate (a state where the thermostat 10A detects 65 ° C. or higher).

  When hot water HW is used, when the hot water HW in the hot water storage tank 1 is led out of the tank, the water W is replenished from the water pipe 16 to the water storage tank 1.

  At this time, for example, hot water HW is used and water W is replenished to the hot water storage tank 1 until the hot water boundary L in the hot water storage tank 1 rises and reaches the thermostat 10A as shown in FIG. While water 10B is detected as 35 ° C or lower and the thermostat 10A is detected as 65 ° C or higher), the water W in the water pipe 16 is sent to the heat pump 3 and heated, and the hot water HW produced by the heat pump 3 is heated. Is returned to the hot water storage tank 1 and operates so as to maintain the hot water boundary line L between the hot water HW and the water W divided into the upper layer and the lower layer in the hot water storage tank 1 at a position below the thermostat 10A. That is, only the heat pump 3 operates so that the boiler 2 does not operate (a state where the thermostat 10A detects 65 ° C. or higher).

  Then, a large amount of hot water HW is used to replenish the hot water storage tank 1 with a lot of water W, and when the hot water boundary line L in the hot water storage tank 1 rises and reaches the thermostat 10A as shown in FIG. 4 (thermostat 10A When the water temperature is detected to be 60 ° C. or lower), the water W in the hot water storage tank 1 is sent to the boiler 2 and heated, and the hot water HW produced by the boiler 2 is returned to the hot water storage tank 1 and the hot water boundary in the hot water storage tank 1 It operates to maintain line L at a position below thermostat 10A. That is, the boiler 2 is also operated together with the heat pump 3 until the thermostat 10A is detected to be 65 ° C. or higher in a state that cannot be handled by the heat pump 3.

  During the heating operation by the boiler 2 and the heat pump 3, the air heated by the heat radiation to the surroundings in the boiler 2 and the hot water storage tank 1 operating in the chamber 6 is filled in the chamber 6, and the heated air is used as the air. By using the heat exchanger 5 as a heat source, frost is prevented from adhering to the air heat exchanger 5.

  As described above, in the present embodiment, the hot water HW is used so that the heat pump 3 is actuated first, and when the heat pump 3 cannot cope with it, the boiler 2 is actuated to compensate for this. . The heat in the room 6 including the heat pump 3 and the boiler 2 causes heat generated in the room 6 to keep the air in the room 6 at a certain temperature or higher. As a heat source of the air heat exchanger 5 related to the heat pump 3, a good operating state of the heat pump 3 can always be obtained. This point has been confirmed by a test conducted by the present inventor.

  Since the present embodiment is configured as described above, unlike the above-described conventional example, the heat pump 3 does not stop, for example, in winter when the air is cold, and a good operating state is always obtained.

  Moreover, since the hot water storage tank 1 was arrange | positioned in the chamber 6 in the present Example, the air heated by the thermal radiation to the circumference | surroundings in the hot water storage tank 1 with the boiler 2 can be used as the heat source of the air heat exchanger 5, An even better operating state of the heat pump 3 can be obtained.

  Further, in this embodiment, since the chamber 6 having the heat insulating wall structure is adopted as the chamber 6, the heat generated from the boiler 2 and the hot water storage tank 1 is well maintained, and an optimum heat source in the air heat exchanger 5 is obtained. Can be secured.

  Note that the present invention is not limited to this embodiment, and the specific configuration of each component can be designed as appropriate.

It is a schematic explanatory drawing which shows a present Example. It is operation | movement explanatory drawing of the principal part which concerns on a present Example. It is operation | movement explanatory drawing of the principal part which concerns on a present Example. It is operation | movement explanatory drawing of the principal part which concerns on a present Example.

DESCRIPTION OF SYMBOLS 1 Hot water storage tank 2 Boiler 3 Heat pump 4 Heating part 5 Air heat exchanger 6 Room
7 hot water circulation section
7a circuit
7b pump equipment
8 hot water use part
10A thermostat
10B thermostat

Claims (3)

In the hot water supply apparatus including a heating unit including a boiler and a heat pump, the heat pump includes an air heat exchanger using air as a heat source, and the heating unit is disposed in a room including a heat insulating wall structure, and the air heat exchange The hot water storage tank for storing hot water heated by the heating unit is disposed in the room, and the air heat exchanger is connected to the boiler and the hot water storage tank . all SANYO to heat source air heated by the heat dissipation to the surroundings, the thermostat for measuring the water temperature are provided in the hot water storage inside the central position and a lower position respectively of the tank s, the boiler, the upper part of the thermostat The heat pump is controlled based on the measurement of the hot water temperature in the lower thermostat. Hot water supply apparatus characterized by being configured to be controlled to operate or stop. The hot water supply apparatus according to claim 1, wherein the hot water storage tank has a vertically long shape. The hot water supply device according to any one of claims 1 and 2, wherein the hot water storage tank is provided with a hot water circulation section, and the hot water circulation section is connected to the hot water storage tank and is provided in a circulation path having a hot water use section. A hot water supply device having a configuration provided with a pump device.

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