JP4066843B2 - Water heater - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention relates to a hot water supply device that generates hot water using a heat storage unit that stores heat in a latent heat storage material.
[0002]
[Prior art]
  Conventionally, as disclosed in Patent Document 1, a heat storage unit that stores warm heat using a latent heat storage material is known. In this heat storage unit, a latent heat storage material is stored in a heat storage tank, and a heat storage heat exchanger is installed. Moreover, the heat storage heat exchanger is comprised with the heat exchanger tube and the plate-shaped fin.
[0003]
  For example, the heat storage unit described in Patent Document 1 performs the following operation. That is, when storing the heat, water heated by a heat source such as a heat pump is sent to the heat transfer tube of the heat storage heat exchanger to melt the latent heat storage material. On the other hand, when using warm heat, clean water from the water supply is sent to the heat transfer tube of the heat storage heat exchanger, and the warm water heated by the latent heat storage material is used for hot water supply or the like.
[0004]
  In the heat storage unit, the heat storage heat exchanger is in direct contact with the latent heat storage material, and its corrosion gradually proceeds. When the heat transfer tube of the heat storage heat exchanger is damaged due to corrosion, the latent heat storage material enters the heat transfer tube. And if a latent heat storage material flows in into a heat exchanger tube, it will be contaminated with the latent heat storage material to the water supply connected to the heat exchanger tube. In particular, when a hydrate such as sodium acetate hydrate having high corrosiveness to metals is used as a latent heat storage material, the necessity of preventing contamination of waterworks due to corrosion of heat transfer tubes is increased.
[0005]
  With respect to this problem, in the heat storage heat exchanger of Patent Document 1, the material of the fin is a metal having a higher ionization tendency than the material of the heat transfer tube, and corrosion of the heat transfer tube is suppressed. In other words, the corrosion of the heat transfer tube is reduced by adopting a so-called cathodic protection method and using the fin as a sacrificial anode.
[0006]
[Patent Document 1]
          JP 2001-207163 A
[0007]
[Problems to be solved by the invention]
  However, in the case of using the above heat storage heat exchanger that performs anti-corrosion, it is possible to delay the progress of corrosion of the heat transfer tube, but it is impossible to know how imminent the risk of damage to the heat transfer tube due to corrosion is. There was a problem. In order to prevent contamination of the water supply due to the latent heat storage material, the heat storage heat exchanger is used even though it is effective to shut off the heat transfer pipe and the water supply in advance according to the degree of corrosion of the heat transfer pipe. As long as it was, there was a problem that such measures could not be taken.
[0008]
  The present invention has been made in view of such a point, and an object of the present invention is to provide a heat storage unit for making it possible to detect the risk of damage to a heat transfer tube due to corrosion, and using the heat storage unit. An object of the present invention is to provide a hot water supply device that can reliably prevent contamination of waterworks by a latent heat storage material.
[0009]
[Means for Solving the Problems]
  Invention of Claim 1Water heaterIs a heat storage tank (41,51), a latent heat storage material (42,52) stored in the heat storage tank (41,51), and a latent heat storage material installed in the heat storage tank (41,51). Dipped in (42,52)And the latent heat storage material ( 42,52 ) First heat transfer tube for flowing a heat-dissipating fluid ( 45,55 ) And the latent heat storage material ( 42,52 ) The second heat transfer tube for flowing the heated fluid that absorbs heat ( 46,56 ) And are providedWith the heat storage heat exchanger (43,53)HaveHeat storage unit( 40,50 )When,TheThermal storage unit ( 40,50 ) Heat storage heat exchanger ( 43,53 ) First heat transfer tube ( 45,55 ) Connected to the refrigerant circuit ( 21,31 ) And the refrigerant circuit ( 21,31 ) As a heating fluid, the first heat transfer tube ( 45,55 ) Heat source unit ( 20,30 ) And the above heat storage unit ( 40,50 ) Heat storage heat exchanger ( 43,53 ) Second heat transfer tube ( 46,56 ) And water supply, and the above-mentioned second heat transfer pipe (with heated water as a fluid to be heated) 46,56 Hot water supply circuit () 60 ) And the refrigerant circuit ( 21,31 ) Leakage detection means that outputs a detection signal when refrigerant leakage from ( 81 ) And the above leakage detection means ( 81 ) Outputs a detection signal, the hot water supply circuit ( 60 ) And an open / close mechanism that shuts off the water supply ( 83 )The first heat transfer tube (45, 55) is made of the same material as the second heat transfer tube (46, 56) and is thinner than the second heat transfer tube (46, 56). It is.
[0010]
  Invention of Claim 2Water heaterIs a heat storage tank (41,51), a latent heat storage material (42,52) stored in the heat storage tank (41,51), and a latent heat storage material installed in the heat storage tank (41,51). Dipped in (42,52)And the latent heat storage material ( 42,52 ) First heat transfer tube for flowing a heat-dissipating fluid ( 45,55 ) And the latent heat storage material ( 42,52 ) The second heat transfer tube for flowing the heated fluid that absorbs heat ( 46,56 ) And are providedWith the heat storage heat exchanger (43,53)HaveHeat storage unit( 40,50 ) And the heat storage unit ( 40,50 ) Heat storage heat exchanger ( 43,53 ) First heat transfer tube ( 45,55 ) Connected to the refrigerant circuit ( 21,31 ) And the refrigerant circuit ( 21,31 ) As a heating fluid, the first heat transfer tube ( 45,55 ) Heat source unit ( 20,30 ) And the above heat storage unit ( 40,50 ) Heat storage heat exchanger ( 43,53 ) Second heat transfer tube ( 46,56 ) And water supply, and the above-mentioned second heat transfer pipe (with heated water as a fluid to be heated) 46,56 Hot water supply circuit () 60 ) And the refrigerant circuit ( 21,31 ) Leakage detection means that outputs a detection signal when refrigerant leakage from ( 81 ) And the leakage detection means ( 81 ) Outputs a detection signal, the hot water supply circuit ( 60 ) And an open / close mechanism that shuts off the water supply ( 83 )The first heat transfer tube (45,55)The wall thickness is the second heat transfer tube ( 46,56 )The material is a metal having a greater ionization tendency than the material of the second heat transfer tube (46, 56).
[0011]
  Invention of Claim 3Water heaterIsThermal storage tank ( 41,51 ) And the heat storage tank ( 41,51 ) Latent heat storage material ( 42,52 ) And the above heat storage tank ( 41,51 ) In the latent heat storage material ( 42,52 ) And the latent heat storage material ( 42,52 ) First heat transfer tube for flowing a heat-dissipating fluid ( 45,55 ) And the latent heat storage material ( 42,52 ) The second heat transfer tube for flowing the heated fluid that absorbs heat ( 46,56 ) And heat storage heat exchanger ( 43,53 ) And a heat storage unit ( 40,50 )When,Connected to the first heat transfer pipe (45,55) of the heat storage heat exchanger (43,53) of the heat storage unit (40,50).The first heat transfer tube ( 45,55 ) And a heating circuit that circulates the heating fluid between the heat source ( 93 )And the second heat transfer pipe using the water as a fluid to be heated, connected to the second heat transfer pipe (46,56) of the heat storage heat exchanger (43,53) and the water supply of the heat storage unit (40,50). A hot water supply circuit (60) to be supplied to (46, 56),Heating circuit ( 93 Of heating fluid fromLeak detection means (81) that outputs a detection signal when a leak is detected,TheAn open / close mechanism (83) that shuts off the hot water supply circuit (60) and the water supply when the leak detection means (81) outputs a detection signal;The first heat transfer tube ( 45,55 ) Is made of the second heat transfer tube ( 46,56 ), The wall thickness of the second heat transfer tube ( 46,56 Is thinner thanIs.
[0012]
  The hot water supply apparatus of the invention of claim 4Thermal storage tank ( 41,51 ) And the heat storage tank ( 41,51 ) Latent heat storage material ( 42,52 ) And the above heat storage tank ( 41,51 ) In the latent heat storage material ( 42,52 ) And the latent heat storage material ( 42,52 ) First heat transfer tube for flowing a heat-dissipating fluid ( 45,55 ) And the latent heat storage material ( 42,52 ) The second heat transfer tube for flowing the heated fluid that absorbs heat ( 46,56 ) And heat storage heat exchanger ( 43,53 ) AndHeat storage unit( 40,50 )And connected to the first heat transfer pipe (45,55) of the heat storage heat exchanger (43,53) of the heat storage unit (40,50), between the first heat transfer pipe (45,55) and the heat source A heating circuit (93) for circulating the heating fluid;,
The heat storage unit (40, 50) is connected to the second heat transfer pipe (46, 56) of the heat storage heat exchanger (43, 53) and the water supply, and the second heat transfer pipe (46 , 56), a hot water supply circuit (60), a leak detection means (81) that outputs a detection signal upon detecting leakage of the heating fluid from the heating circuit (93), and the leak detection means (81) And an open / close mechanism (83) that shuts off the hot water supply circuit (60) and the water supply when a detection signal is output, The first heat transfer tube ( 45,55 ) Is the thickness of the second heat transfer tube ( 46,56 ), The material of which is the second heat transfer tube ( 46,56 ) Is a metal that has a higher ionization tendency than the materialIs.
[0013]
    -Action-
  Claim 1To claim 4In this invention, the heat storage heat exchanger (43, 53) is immersed in the latent heat storage material (42, 52) in the heat storage tank (41, 51). In the heat storage tank (41,51), the first heat transfer pipe (45,55) and the second heat transfer pipe (46,56) of the heat storage heat exchanger (43,53) are latent heat storage materials (42,52). Touching.
[0014]
  When storing heat in the heat storage unit (40, 50), the heating fluid is caused to flow through the first heat transfer tubes (45, 55). The latent heat storage material (42, 52) absorbs heat from the heating fluid flowing through the first heat transfer tubes (45, 55) and melts. And heat is stored as the heat of fusion of the latent heat storage material (42, 52). On the other hand, when using the heat stored in the heat storage unit (40, 50), the fluid to be heated is caused to flow through the second heat transfer pipe (46, 56). The latent heat storage material (42, 52) is solidified by releasing heat to the heated fluid flowing through the second heat transfer tube (46, 56). And the warm heat which a latent heat storage material (42,52) stores is provided to the to-be-heated fluid in a 2nd heat exchanger tube (46,56).
[0015]
  Claim 1And claim 3In the present invention, the material of the first heat transfer tube (45, 55) is the same as the material of the second heat transfer tube (46, 56). Further, the thickness of the first heat transfer tube (45, 55) is thinner than the thickness of the second heat transfer tube (46, 56). In other words, the first heat transfer tube (45,55) and the second heat transfer tube (46,56) that are directly touched by the latent heat storage material (42,52) are gradually corroded and may be damaged depending on the situation. It can happen. In such a case, the thin first heat transfer tube (45, 55) is broken before the second heat transfer tube (46, 56).
[0016]
  Claim 2And claim 4In the present invention, the material of the first heat transfer tube (45, 55) is a metal having a larger ionization tendency than the material of the second heat transfer tube (46, 56).The first heat transfer tube ( 45,55 The thickness of the second heat transfer tube ( 46,56 ) Is the same as the wall thickness.In other words, the first heat transfer tube (45,55) and the second heat transfer tube (46,56) that are directly touched by the latent heat storage material (42,52) are gradually corroded and may be damaged depending on the situation. It can happen. In such a case, the first heat transfer tube (45, 55) having a large ionization tendency is broken before the second heat transfer tube (46, 56).
[0017]
  Claim1 and claim 2In the invention, the refrigerant circuit (21, 31) of the heat source unit (20, 30) is connected to the first heat transfer tube (45, 55) of the heat storage heat exchanger (43, 53), and the second heat transfer tube (46 56) is connected to the hot water supply circuit (60).
[0018]
  When storing heat in the heat storage unit (40, 50), the refrigerant is circulated in the refrigerant circuit (21, 31) to perform a refrigeration cycle, and the refrigerant is used as a heating fluid in the first heat transfer pipe (45, 55). It is captured. And the refrigerant | coolant which flowed into the 1st heat exchanger tube (45,55) radiates and condenses to the latent heat storage material (42,52) in a heat storage tank (41,51). On the other hand, when using the heat stored in the heat storage unit (40, 50), the water from the water supply is sent to the second heat transfer pipe (46, 56) as the fluid to be heated. The clean water flowing into the second heat transfer pipe (46,56) absorbs heat from the latent heat storage material (42,52) in the heat storage tank (41,51) to become hot water and passes through the hot water supply circuit (60). Hot water is supplied to bathrooms.
[0019]
  In the heat storage heat exchanger (43,53), when the first heat transfer tube (45,55) is damaged by corrosion by the latent heat storage material (42,52), the second heat transfer tube (46,56) will soon be There is an increased risk of damage due to corrosion. On the other hand, the water heater (10) is provided with a leakage detection means (81). When the first heat transfer tube (45, 55) is broken and the refrigerant leaks, the leak detection means (81) detects the refrigerant leak and outputs a detection signal. When the detection signal is output from the leak detection means (81), the opening / closing mechanism (83) is closed. That is, when the breakage of the second heat transfer tube (46,56) is imminent, the opening / closing mechanism (83) is closed in advance to shut off the second heat transfer tube (46,56) and the water supply.
[0020]
  Claim3 and claim 4In the invention, the heating circuit (93) is connected to the first heat transfer tube (45,55) of the heat storage heat exchanger (43,53), and the hot water supply circuit (60) is connected to the second heat transfer tube (46,56). Is connected.
[0021]
  When storing heat in the heat storage unit (40, 50), the heating fluid circulates in the heating circuit (93) and is sent to the first heat transfer tubes (45, 55). And the heating fluid which flowed into the 1st heat exchanger tube (45,55) radiates heat to the latent heat storage material (42,52) in the heat storage tank (41,51). On the other hand, when using the heat stored in the heat storage unit (40, 50), the water from the water supply is sent to the second heat transfer pipe (46, 56) as the fluid to be heated. The clean water flowing into the second heat transfer pipe (46,56) absorbs heat from the latent heat storage material (42,52) in the heat storage tank (41,51) to become hot water and passes through the hot water supply circuit (60). Hot water is supplied to bathrooms.
[0022]
  In the heat storage heat exchanger (43,53), when the first heat transfer tube (45,55) is damaged by corrosion by the latent heat storage material (42,52), the second heat transfer tube (46,56) will soon be There is an increased risk of damage due to corrosion. On the other hand, the water heater (10) is provided with a leakage detection means (81). When the first heat transfer tube (45, 55) is broken and the heating fluid leaks, the leak detection means (81) detects the leakage of the heating fluid and outputs a detection signal. When the detection signal is output from the leak detection means (81), the opening / closing mechanism (83) is closed. That is, when the breakage of the second heat transfer tube (46,56) is imminent, the opening / closing mechanism (83) is closed in advance to shut off the second heat transfer tube (46,56) and the water supply.
[0023]
DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiment 1
  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
[0024]
  As shown in FIG. 1, the hot water supply device (10) of this embodiment includes two heating units (11, 12). The first heating unit (11) includes a first heat source unit (20) and a first heat storage unit (40). On the other hand, the second heating unit (12) includes a second heat source unit (30) and a second heat storage unit (50). The hot water supply device (10) includes a hot water supply circuit (60), a reheating circuit (66), and a controller (80).
[0025]
  Each of the first and second heat source units (20, 30) includes a heat source circuit (22, 32) and constitutes a heat pump.
[0026]
  In the heat source circuit (22) of the first heat source unit (20), the receiver (23), the electric expansion valve (24), the outdoor heat exchanger (25), and the accumulator (26) are arranged in the refrigerant circulation direction. The compressor (27) is connected to the pipe in order. On the other hand, in the heat source circuit (32) of the second heat source unit (30), the receiver (33), the electric expansion valve (34), the outdoor heat exchanger (35), and the accumulator (36) are arranged in the refrigerant circulation direction. ) And the compressor (37) are connected in order by piping.
[0027]
  One end of the heat source circuit (22, 32) of the first and second heat source units (20, 30) is one end of the heat transfer tube (45, 55), and the other end is the heat transfer tube (45, 55). Is connected to the other end. The closed circuit refrigerant circuit (21, 31) is configured by connecting the heat source circuit (22, 32) to the heating heat transfer tube (45, 55). The refrigerant circuit (21, 31) is filled with HCFC refrigerant, HFC refrigerant such as R410A, HC refrigerant such as propane, carbon dioxide gas, or the like as the refrigerant.
[0028]
  The compressor (27, 37) of each heat source circuit (22, 32) is a so-called hermetic compressor (27, 37), and although not shown, the compression mechanism and the electric motor are housed in a sealed casing. It is configured. Electric power is supplied to the electric motors of the compressors (27, 37) via an inverter (not shown). When the output frequency of this inverter is changed, the rotational speed of each electric motor changes, and the capacity of the compressors (27, 37) changes.
[0029]
  The outdoor heat exchanger (25, 35) of each heat source circuit (22, 32) is for exchanging heat between the refrigerant and the outdoor air, and is a so-called cross fin type fin-and-tube heat exchanger. It is configured.
[0030]
  The hot water supply circuit (60) has a start end connected to the water supply via an electromagnetic valve (83) that is an open / close mechanism, and a terminal end connected to the hot water tap (61). By opening and closing the electromagnetic valve (83), the supply of tap water from the tap water is interrupted.
[0031]
  Connected to the hot water supply circuit (60) are the hot water transfer pipes (46, 56) of the heat storage units (40, 50). In the hot water supply circuit (60), the hot water transfer pipe (56) of the second heat storage unit (50) is connected to the downstream side of the hot water transfer pipe (46) of the first heat storage unit (40).
[0032]
  The hot water supply circuit (60) is provided with a bypass pipe (62). One end of the bypass pipe (62) is connected to the upstream side of the heat transfer heat transfer pipe (46) of the first heat storage unit (40), and the other end is a heat transfer heat transfer pipe (56) of the second heat storage unit (50). Is connected via a mixing valve (63) to the downstream side. When this mixing valve (63) is operated, the mixing ratio of warm water from the second heat storage unit (50) and clean water from the bypass pipe (62) changes.
[0033]
  Furthermore, a bath pouring pipe (64) is connected to the hot water supply circuit (60). The bath pouring pipe (64) has its start end connected between the mixing valve (63) and the hot water tap (61) in the hot water supply circuit (60), and its end via the reheating circuit (66). Connected to the bathtub (15). The bath pouring pipe (64) is provided with a bath pouring valve (65).
[0034]
  Both ends of the chasing circuit (66) are connected to the bathtub (15). In this reheating circuit (66), the reheating pump (67) and the reheating heat transfer pipe (59) of the second heat storage unit (50) are connected in order.
[0035]
  As shown in FIG. 2, each of the first and second heat storage units (40, 50) includes one heat storage tank (41, 51) and one heat storage heat exchanger (43, 53). Moreover, the latent heat storage material (42, 52) is stored in each heat storage tank (41, 51). Specifically, in the heat storage tank (41) of the first heat storage unit (40), sodium sulfate decahydrate (Na₂SO₄・ 10H₂O) is stored as a latent heat storage material (42). On the other hand, in the heat storage tank (51) of the second heat storage unit (50), sodium acetate trihydrate (CH₃COONa ・ 3H₂O) is stored as a latent heat storage material (52). In addition, all of the substances constituting these latent heat storage materials (42, 52) are merely examples.
[0036]
  The heat storage heat exchanger (43, 53) is a so-called cross fin type fin-and-tube heat exchanger, and is immersed in the latent heat storage material (42, 52). Specifically, the heat storage heat exchanger (43, 53) includes a large number of fins (44, 54), a heat transfer tube for heating (45, 55), and a heat transfer tube for hot water (46, 56). Yes. The fins (44, 54) are plate-like and are erected at regular intervals in the heat storage tank (41, 51). On the other hand, the heating heat transfer tubes (45, 55) and the tapping heat transfer tubes (46, 56) penetrate the fins (44, 54) provided in the horizontal direction. Moreover, the heat transfer tubes (45, 55) for heating and the heat transfer tubes (46, 56) for hot water are alternately arranged in the vertical direction.
[0037]
  In the heat storage heat exchanger (43) of the first heat storage unit (40), the heat transfer tube (45) is connected to the heat source circuit (22) of the first heat source unit (20) via a pair of headers (47). The hot water transfer pipe (46) is connected to the hot water supply circuit (60) through a pair of headers (48). On the other hand, in the heat storage heat exchanger (53) of the second heat storage unit (50), the heat transfer tube (55) is connected to the heat source circuit (32) of the second heat source unit (30) via a pair of headers (57). The hot water transfer pipe (56) is connected to the hot water supply circuit (60) through a pair of headers (58).
[0038]
  The heating heat transfer tubes (45, 55) of the respective heat storage heat exchangers (43, 53) constitute a first heat transfer tube through which a refrigerant as a heating fluid flows. On the other hand, the heat transfer pipe (46, 56) for hot water of the heat storage heat exchanger (43, 53) constitutes a second heat transfer pipe through which clean water as a fluid to be heated flows. The heating heat transfer tubes (45, 55) and the hot water heat transfer tubes (46, 56) are both made of copper. Further, the thickness of the heating heat transfer tube (45, 55) is thinner than the thickness of the tapping heat transfer tube (46, 56).
[0039]
  The outdoor heat exchanger (25) of the first heat source unit (20) is provided with a first outdoor heat exchanger temperature sensor (71) for detecting the refrigerant temperature. The outdoor heat exchanger (35) of the second heat source unit (30) is provided with a second outdoor heat exchanger temperature sensor (72) for detecting the refrigerant temperature. The first heat source unit (20) has a first outdoor temperature sensor (73) for detecting the temperature of outdoor air, and the second heat source unit (30) has a second temperature for detecting the temperature of outdoor air. An outdoor temperature sensor (74) is provided.
[0040]
  On the other hand, the heat storage heat exchanger (43) of the first heat storage unit (40) is provided with a first heat storage heat exchanger temperature sensor (75) for detecting the condensation temperature of the refrigerant. The heat storage heat exchanger (53) of the second heat storage unit (50) is provided with a second heat storage heat exchanger temperature sensor (76) for detecting the condensation temperature of the refrigerant.
[0041]
  The first heat storage unit (40) is provided with a first latent heat storage material temperature sensor (73) for detecting the temperature of the latent heat storage material (42), and the second heat storage unit (50) A second latent heat storage material temperature sensor (78) for detecting the temperature of the latent heat storage material (52) is provided.
[0042]
  The controller (80) includes a leak detection unit (81) and a control unit (82).
[0043]
  The leakage detection unit (81) is leakage detection means, and the detection temperature of the temperature sensor is input. In addition, the output frequency of the inverter is input to the leakage detection unit (81) as the operating capacity of each compressor (27, 37). This leakage detection unit (81) analyzes the detection value of the temperature sensor and the capacity of each compressor (27, 37) and determines whether or not the amount of refrigerant circulating in each refrigerant circuit (21, 31) is insufficient. to decide. When the leakage detection unit (81) determines that the amount of refrigerant is insufficient, it outputs a detection signal.
[0044]
  On the other hand, the control unit (82) can receive the detection signal from the leakage detection unit (81). When the control unit (82) receives the detection signal from the leakage detection unit (81), the control unit (82) stops the compressors (27, 37) of the first and second heat source units (20, 30) and the solenoid valve ( 83) is closed to shut off the supply of clean water from the water supply to the hot water supply circuit (60).
[0045]
        -Driving action-
  The operation of the hot water supply device (10) will be described. As with the so-called instant water heater, this hot water supply device (10) continuously heats the water supplied from the water supply to generate hot water, and the obtained hot water is used for the hot water tap (61) and the bathtub (15 ) Sequentially.
[0046]
    <Hot-water supply operation of hot-water supply device>
  Here, the first and second heat storage units (40, 50) are fully stored, that is, the latent heat storage materials (42, 52) of both heat storage units (40, 50) are melted and become liquid. The explanation starts from.
[0047]
  When the hot-water tap (61) or the bath pouring valve (65) is opened, clean water begins to circulate in the hot-water supply circuit (60). Accordingly, the first and second heat source units (40, 50) are operated, and the refrigerant circulates in each refrigerant circuit (21, 31) to perform a vapor compression refrigeration cycle. At that time, the opening degree of each electric expansion valve (24, 34) of each heat source circuit (22, 32) is adjusted as appropriate.
[0048]
  Specifically, in each refrigerant circuit (21, 31), the refrigerant discharged from the compressor (27, 37) dissipates heat in the heat transfer tubes (45, 55) and condenses. The condensed refrigerant passes through the receiver (23, 33) and is reduced in pressure when passing through the electric expansion valve (24, 34), and then absorbs heat from the outdoor air and evaporates in the outdoor heat exchanger (25, 35). . The refrigerant evaporated in the outdoor heat exchanger (25, 35) passes through the accumulator (26, 36), is sucked into the compressor (27, 37), is compressed, and then discharged again from the compressor (27, 37). Is done.
[0049]
  The operating conditions of the refrigeration cycle are different between the first heat source unit (20) and the second heat source unit (30). In the first heat source unit (20), the high pressure of the refrigeration cycle is set such that the refrigerant condensing temperature in the heating heat transfer tube (45) of the first heat storage unit (40) is about 40 ° C. On the other hand, in the second heat source unit (30), the high pressure of the refrigeration cycle is set so that the condensation temperature of the refrigerant in the heating heat transfer tube (55) of the second heat storage unit (50) is about 65 ° C.
[0050]
  The clean water flowing through the hot water supply circuit (60) first flows into the hot water transfer pipe (46) of the first heat storage unit (40). While flowing through the heat transfer pipe (46) for hot water, clean water absorbs heat from both the latent heat storage material (42) of the first heat storage unit (40) and the refrigerant flowing through the heat transfer pipe (45), and the temperature is The temperature rises to about 35 ° C. At that time, the latent heat storage material (42) of the first heat storage unit (40) dissipates heat to the clean water flowing through the heat transfer pipe (46) for hot water, and a part thereof is solidified.
[0051]
  The hot water heated by the latent heat storage material (42) of the first heat storage unit (40) and the heat transfer pipe (46) for hot water subsequently flows into the heat transfer pipe (56) for hot water supply of the second heat storage unit (50). . While flowing through the heat transfer pipe (56) for hot water, the clean water absorbs heat from both the latent heat storage material (52) of the second heat storage unit (50) and the refrigerant flowing through the heat transfer pipe (55). The temperature rises to about 60 ° C. At that time, the latent heat storage material (52) of the second heat storage unit (50) dissipates heat to the clean water flowing through the heat transfer pipe (56) for hot water, and a part thereof is solidified.
[0052]
  The hot water sent out from the heat transfer pipe (56) for hot water of the second heat storage unit (50) is sent to the mixing valve (63). In the mixing valve (63), clean water from the bypass pipe (62), that is, cold water is mixed into the hot water. Further, the mixing ratio of hot water and cold water is adjusted by operating the mixing valve (63). And hot water is set to predetermined temperature, when passing a mixing valve (63), and is supplied to a hot-water tap (61) and a bathtub (15) after that.
[0053]
  As described above, the amount of heat stored in the first and second heat storage units (40, 50) decreases during hot water supply. When the heat storage amount of the first and second heat storage units (40, 50) falls below a predetermined value, the first and second heat source units (20, 30) are operated while hot water is not being supplied. Heat is stored in the unit (40, 50).
[0054]
  Moreover, when it becomes necessary to reheat the hot water in the bathtub (15), the reheating pump (67) and the second heat source unit (30) are operated. When the reheating pump (67) is operated, hot water is taken from the bathtub (15) into the reheating circuit (66) and introduced into the reheating heat transfer tube (59) of the second heat storage unit (50). . On the other hand, when the second heat source unit (30) is operated, the refrigerant radiates heat to the latent heat storage material (52) and condenses in the heating heat transfer tube (55) of the second heat storage unit (50). The hot water absorbs heat from both the refrigerant in the heating heat transfer tube (55) and the latent heat storage material (52) while flowing through the reheating heat transfer tube (59), and is sent back to the bathtub (15) after the temperature rises. It is.
[0055]
    <Controller operation>
  The operation of the controller (80) will be described.
[0056]
  The hot water supply device (10) always has a refrigerant circuit (when the device is energized, regardless of whether the compressors (27, 37) of the first and second heat source units (20, 30) are stopped or in operation). 21,31) is configured to detect refrigerant leakage.
[0057]
  First, while the compressor (27, 37) is stopped, the leak detection unit (81) of the controller (80) is based on the detected temperature of the first and second outdoor heat exchanger temperature sensors (71, 72). Determine whether there is a refrigerant leak. The operation of the leak detection unit (81) will be described.
[0058]
  While the compressor (27, 37) is stopped, the refrigerant does not circulate in the refrigerant circuit (21, 31). Therefore, normally, the temperature of the first and second outdoor heat exchangers (25, 35) remains constant and does not change. However, if the refrigerant leaks from the refrigerant circuit (21, 31), the internal pressure of the refrigerant circuit (21, 31) gradually decreases accordingly, and the refrigerant accumulated in the outdoor heat exchanger (25, 35) evaporates. As a result, the temperature of the outdoor heat exchanger (25, 35) decreases.
[0059]
  Therefore, the leak detection unit (81) monitors changes in the detected temperature of the first and second outdoor heat exchanger temperature sensors (71, 72). Then, the leakage detection unit (81) causes the refrigerant circuit (21, 31) when the decrease per unit time of the detected temperature exceeds a predetermined value for at least one of the outdoor heat exchanger temperature sensors (71, 72). It is determined that the refrigerant is leaking from the sensor, and a detection signal is output.
[0060]
  When the leak detection unit (81) outputs a detection signal, the control unit (82) receives the detection signal and closes the solenoid valve (83). In other words, when the leakage detection unit (81) detects refrigerant leakage from the refrigerant circuit (21, 31), the control unit (82) closes the solenoid valve (83) and connects the hot water supply circuit (60) to the water supply. Cut off.
[0061]
  Next, during the operation of the compressor (27, 37), the leak detection unit (81) of the controller (80) includes the outdoor heat exchanger temperature sensors (71, 72) and the outdoor temperature sensors (73, 74). Based on the detected temperatures of the heat storage heat exchanger temperature sensors (75, 76) and the latent heat storage material temperature sensors (77, 78), the presence or absence of refrigerant leakage is determined. The operation of the leak detection unit (81) will be described. Here, the operation for detecting refrigerant leakage from the refrigerant circuit (21) of the first heat storage unit (40) will be described, but this operation is similarly performed for the refrigerant circuit (31) of the second heat storage unit (50). Is called.
[0062]
  During the operation of the compressor (27, 37), the refrigerant circulates in the refrigerant circuit (21, 31) to perform a refrigeration cycle. Therefore, normally, there is a certain difference between the refrigerant evaporation temperature detected by the first outdoor heat exchanger temperature sensor (71) and the outside air temperature detected by the first outdoor temperature sensor (73). . There is also a certain difference between the refrigerant condensing temperature detected by the first heat storage heat exchanger temperature sensor (75) and the heat storage material temperature detected by the first latent heat storage material temperature sensor (77).
[0063]
  However, if the refrigerant leaks from the refrigerant circuit (21, 31), the refrigerant circulation amount in the refrigerant circuit (21, 31) remains low even if the compressor (27, 37) is operated at a certain capacity. Thus, the difference between the high and low pressures of the refrigeration cycle is not sufficient. For this reason, the refrigerant temperature detected by the first outdoor heat exchanger temperature sensor (71) is higher than that during normal operation, and is detected by the first outdoor heat exchanger temperature sensor (71) and the first outdoor temperature sensor (73). The temperature difference becomes smaller. The refrigerant temperature detected by the first heat storage heat exchanger temperature sensor (75) is lower than that during normal operation, and the first heat storage heat exchanger temperature sensor (75) and the first latent heat storage material temperature sensor (77) The detected temperature difference becomes smaller.
[0064]
  Therefore, the leakage detection unit (81) includes the detected temperature difference between the first outdoor heat exchanger temperature sensor (71) and the first outdoor temperature sensor (73), the first heat storage heat exchanger temperature sensor (75), and the first The temperature difference detected by the latent heat storage material temperature sensor (77) is monitored. In addition, the leakage detection unit (81) includes a difference between detected temperatures of the second outdoor heat exchanger temperature sensor (72) and the second outdoor temperature sensor (74), a second heat storage heat exchanger temperature sensor (76), and a second Monitoring with the temperature difference detected by the latent heat storage material temperature sensor (78) is also performed. The leakage detector (81) causes the refrigerant to leak from the refrigerant circuit (21, 31) when the detected temperature difference for both of the refrigerant circuits (21, 31) is less than a predetermined reference value. A detection signal is output.
[0065]
  When the leak detection unit (81) outputs a detection signal, the control unit (82) receives the detection signal, stops the compressor (27, 37), and closes the electromagnetic valve (83). In other words, when the leakage detection unit (81) detects refrigerant leakage from the refrigerant circuit (21, 31), the control unit (82) closes the solenoid valve (83) and connects the hot water supply circuit (60) to the water supply. Cut off.
[0066]
    -Effect of Embodiment 1-
  In the heat storage unit (40, 50) of Embodiment 1, the thickness of the heating heat transfer tube (45, 55) is thinner than the thickness of the tapping heat transfer tube (46, 56). The heat pipe (45, 55) is damaged by corrosion before the heat transfer pipe (46, 56) for hot water. If it is detected that the heating heat transfer tube (45, 55) is broken by means such as detecting refrigerant leakage, the hot water heat transfer tube (46, 56) is likely to break soon. It can be judged that
[0067]
  Therefore, according to the present embodiment, the heat storage unit (40, 50) is provided that makes it possible to determine that the risk of breakage is imminent with respect to the heat transfer pipe (46, 56) for hot water, which causes great damage if broken. it can.
[0068]
  Further, in the hot water supply device (10) using the heat storage unit (40, 50), when the refrigerant leaks due to breakage of the heating heat transfer tube (45, 55), the leakage detection unit (81) outputs a detection signal. The control unit (82) receives the detection signal from the leakage detection unit (81), stops the compressor (27, 37), and closes the electromagnetic valve (83). For this reason, if the heat transfer pipe for heating (45,55) has already been damaged and it can be determined that the heat transfer pipe for hot water (46,56) is close, the heat transfer pipe for hot water (46,56) will be damaged. Before the operation, the solenoid valve (83) can be closed to shut off the heat transfer pipe (46, 56) and the water supply. Therefore, according to this embodiment, it is possible to reliably prevent contamination of the waterworks due to the leaked latent heat storage material (42, 52).
[0069]
  Furthermore, in this embodiment, the hot water supply device (10) to which the above leakage detection function is newly added can be made using an existing temperature sensor, and the cost of the device can be reduced.
[0070]
Second Embodiment of the Invention
  Embodiment 2 of the present invention is obtained by changing the configuration of the first and second heat storage units (40, 50) in the hot water supply device (10) of Embodiment 1 described above. Here, the difference between the present embodiment and the first embodiment will be described.
[0071]
  In the heat storage heat exchanger (43, 53) of the present embodiment, the materials of the heat transfer tubes (45, 55) for heating and the heat transfer tubes (46, 56) for hot water are different. Specifically, in this heat storage heat exchanger (43, 53), the heat transfer tubes (45, 55) for heating are made of aluminum, whereas the heat transfer tubes for hot water (46, 56) are made of copper. That is, the heat transfer tubes (45, 55) for heating are made of a metal having a higher ionization tendency than the heat transfer tubes (46, 56) for hot water. The wall thickness of the heat transfer tube for heating (45,55) is the same as the wall thickness of the heat transfer tube for hot water (46,56) or thinner than the wall thickness of the heat transfer tube for hot water (46,56). Yes.
[0072]
  In the heat storage heat exchanger (43, 53), the hot water heat transfer tube (46, 56) is in conduction with the heating heat transfer tube (45, 55) via the fin (44, 54). For this reason, the anticorrosion effect | action which uses the heat exchanger tube (45,55) for heating as a sacrificial anode is acquired. Therefore, according to the present embodiment, it is possible to delay the progress of the corrosion of the hot water transfer pipe (46, 56).
[0073]
Embodiment 3 of the Invention
  In the third embodiment of the present invention, instead of using the heat pump as a heat source for applying heat to the first and second heat storage units (40, 50) in the first embodiment, a power generation gas engine (90) is used. The exhaust heat is used as a heat source. Here, the difference between the present embodiment and the first embodiment will be described.
[0074]
  As shown in FIG. 3, the hot water supply device (10) of this embodiment includes a heating circuit (93). The heating circuit (93) is provided with an exhaust heat exchanger (92). The exhaust heat exchanger (92) is attached to a gas engine (90) for driving the generator (91).
[0075]
  The heating circuit (93) is a closed circuit filled with heat transfer water that is a heating fluid. In this heating circuit (93), an exhaust heat exchanger (92), a pump (94), a heat transfer pipe (45) for heating of the first heat storage unit (40), and a heater for heating the second heat storage unit (50) The heat transfer tube (55) is connected in order. When the pump (94) is driven in the heating circuit (93), the heat transfer water circulates between the exhaust heat exchanger (92) and the heat transfer tubes (45, 55). In the exhaust heat exchanger (92), the heat transfer water is heated by exchanging heat with the exhaust gas of the gas engine (90). The heated heat transfer water dissipates heat to the latent heat storage material (42,52) when passing through the heat transfer tubes (45,55), and then is sent back to the exhaust heat exchanger (92) where it is heated again. The
[0076]
  In addition, a pressure gauge (95) is connected to the heating circuit (93) between the pump (94) and the heat transfer pipe (45) of the first heat storage unit (40). The pressure gauge (95) detects the internal pressure of the heating circuit (93).
[0077]
  The detection value of the pressure gauge (95) is input to the leak detection unit (81) of the present embodiment. And this leak detection part (81) judges the presence or absence of the leakage of the heat transfer water in a heating circuit (93) based on the detected value of a pressure gauge (95). This point will be described.
[0078]
  The heat transfer water circulating through the heating circuit (93) is pressurized and discharged from the pump (94). And when the heat transfer pipe for heating (45,55) is damaged and the heat transfer water leaks, the pressure of the heat transfer water discharged from the pump (94) is higher than that of the heat transfer water leaking. Become lower. Therefore, the leakage detection unit (81) of the present embodiment uses the pressure on the discharge side of the pump (94) in a normal state as a reference value, and compares this reference value with the detection value of the pressure gauge (95). When the difference between the detected value of the pressure gauge (95) and the reference value exceeds a predetermined value, the leak detection unit (81) determines that the heat transfer water is leaking from the heating circuit (93) and detects the detection signal. Is output.
[0079]
  When the leak detection unit (81) outputs a detection signal, the control unit (82) receives the detection signal, stops the pump (94), and closes the electromagnetic valve (83). In other words, when the leak detection unit (81) detects the leakage of the heat transfer water from the heating circuit (93), the control unit (82) closes the solenoid valve (83) and connects the hot water supply circuit (60) and the water supply. Block the gap.
[0080]
  In this embodiment, the exhaust heat of the gas engine (90) is used as the heat source. However, the present invention is not limited to this, and for example, the exhaust heat of the fuel cell may be used as the heat source.
[0081]
【The invention's effect】
  Claim 1And 3In the present invention, since the thickness of the first heat transfer tube (45, 55) is thinner than the thickness of the second heat transfer tube (46, 56), the first heat transfer tube (45, 55) is the first one. 2 Damaged by corrosion before the heat transfer tubes (46,56).
[0082]
  Claim 2And 4In the present invention, since the material of the first heat transfer tube (45, 55) is a metal having a higher ionization tendency than the second heat transfer tube (46, 56), the first heat transfer tube (45, 55) is the first one. 2 Damaged by corrosion before the heat transfer tubes (46,56).
[0083]
  in this way,BookIn the invention, the first heat transfer tube (45, 55) is damaged by corrosion before the second heat transfer tube (46, 56). And if it detects that the 1st heat exchanger tube (45,55) was damaged by means, such as detecting the leakage of the heating fluid, for example, the 2nd heat exchanger tube (46,56) will also be damaged soon. It can be judged that the possibility is high. As the fluid to be heated flowing through the second heat transfer pipe (46, 56), there are many cases in which a fluid having a high necessity for preventing contamination such as tap water from a water supply is used. Therefore,BookAccording to the present invention, it is possible to provide the heat storage unit (40, 50) that makes it possible to determine that the risk of breakage is imminent with respect to the second heat transfer tube (46, 56), which causes a great adverse effect when broken.
[0084]
  Claim1 and 2In this invention, when the refrigerant leaks due to breakage of the first heat transfer tube (45, 55), the leak detection means (81) outputs a detection signal, and the open / close mechanism (83) is closed accordingly. For this reason, when it can be judged that the first heat transfer tube (45,55) has already been damaged and the second heat transfer tube (46,56) is also about to be damaged, the second heat transfer tube (46,56) is damaged. Before the opening / closing mechanism (83) is closed, the second heat transfer pipe (46, 56) and the water supply can be shut off. Therefore, according to this invention, contamination of the water supply by the leaked latent heat storage material (42, 52) can be reliably prevented.
[0085]
  Claim3 and 4In this invention, when the heating fluid leaks due to the breakage of the first heat transfer tube (45, 55), the leak detection means (81) outputs a detection signal, and the open / close mechanism (83) is closed accordingly. Yes. For this reason, when it can be judged that the first heat transfer tube (45,55) has already been damaged and the second heat transfer tube (46,56) is also about to be damaged, the second heat transfer tube (46,56) is damaged. Before the opening / closing mechanism (83) is closed, the second heat transfer pipe (46, 56) and the water supply can be shut off. Therefore, according to this invention, contamination of the water supply by the leaked latent heat storage material (42, 52) can be reliably prevented.
[Brief description of the drawings]
FIG. 1 is a schematic configuration diagram of a hot water supply apparatus according to a first embodiment.
FIG. 2 is a schematic configuration diagram of a heat storage unit according to the first embodiment.
FIG. 3 is a schematic configuration diagram of a hot water supply apparatus according to a third embodiment.
[Explanation of symbols]
   (20), (30) Heat source unit
   (21), (31) Refrigerant circuit
  (40), (50) Thermal storage unit
  (41), (51) Thermal storage tank
  (42), (52) Latent heat storage material
  (43), (53) Heat storage heat exchanger
  (45), (55) Heat transfer tube (first heat transfer tube)
  (46), (56) Heat transfer pipe for hot water (second heat transfer pipe)
   (60) Hot water supply circuit
   (81) Leakage detection unit (leakage detection means)
   (83) Solenoid valve (open / close mechanism)
  (93) Heating circuit

Claims (4)

A heat storage tank (41,51), a latent heat storage material (42,52) stored in the heat storage tank (41,51), and a latent heat storage material (42) installed in the heat storage tank (41,51). a first heat transfer tube (45, 55) for flow of heating fluid to heat radiation to be immersed in 52) Rutotomoni the latent heat storage material (42, 52), absorbs heat from the latent heat storage material (42, 52) A heat storage unit ( 40,50 ) having a heat storage heat exchanger (43,53) provided with a second heat transfer tube ( 46,56 ) for flowing a fluid to be heated ;
A refrigerant circuit ( 21, 31 ) is formed by being connected to the first heat transfer pipe ( 45, 55 ) of the heat storage heat exchanger ( 43, 53 ) of the heat storage unit ( 40, 50 ) , and the refrigerant in the refrigeration cycle. heat source unit (20, 30) for supplying the refrigerant circulating into the first heat transfer pipe as a heating fluid (45, 55) in the circuit (21, 31),
Said heat storage unit (40, 50) and the second heat transfer tube (46, 56) and water supply and to the connected to the second heat transfer pipe clean water as the heated fluid of the heat storage heat exchanger (43, 53) having (46 , 56 ) and a hot water supply circuit ( 60 )
A leakage detection means ( 81 ) for outputting a detection signal when refrigerant leakage from the refrigerant circuit ( 21, 31 ) is detected ;
An open / close mechanism ( 83 ) that shuts off the hot water supply circuit ( 60 ) and the water supply when the leak detection means ( 81 ) outputs a detection signal ;
The first heat transfer pipe (45, 55), the material is the same as the second heat transfer tube (46, 56), hot water whose thickness is thinner than the second heat transfer tube (46, 56) Equipment . A heat storage tank (41,51), a latent heat storage material (42,52) stored in the heat storage tank (41,51), and a latent heat storage material (42) installed in the heat storage tank (41,51). a first heat transfer tube (45, 55) for flow of heating fluid to heat radiation to be immersed in 52) Rutotomoni the latent heat storage material (42, 52), absorbs heat from the latent heat storage material (42, 52) A heat storage unit ( 40,50 ) having a heat storage heat exchanger (43,53) provided with a second heat transfer tube ( 46,56 ) for flowing a fluid to be heated ;
A refrigerant circuit ( 21, 31 ) is formed by being connected to the first heat transfer pipe ( 45, 55 ) of the heat storage heat exchanger ( 43, 53 ) of the heat storage unit ( 40, 50 ) , and the refrigerant in the refrigeration cycle. heat source unit (20, 30) for supplying the refrigerant circulating into the first heat transfer pipe as a heating fluid (45, 55) in the circuit (21, 31),
Said heat storage unit (40, 50) and the second heat transfer tube (46, 56) and water supply and to the connected to the second heat transfer pipe clean water as the heated fluid of the heat storage heat exchanger (43, 53) having (46 , 56 ) and a hot water supply circuit ( 60 )
A leakage detection means ( 81 ) for outputting a detection signal when refrigerant leakage from the refrigerant circuit ( 21, 31 ) is detected ;
An open / close mechanism ( 83 ) that shuts off the hot water supply circuit ( 60 ) and the water supply when the leak detection means ( 81 ) outputs a detection signal ;
The thickness of the first heat transfer tube ( 45,55 ) is the same as that of the second heat transfer tube (46,56), and the material is more ionized than the material of the second heat transfer tube (46,56). A water heater that is a large metal. Heat storage tank and (41, 51), the heat storage tank (41, 51) latent heat storage material is stored in a (42, 52), is installed in the heat storage tank (41, 51) in the latent heat storage material (42 a first heat transfer tube (45, 55) for flow of heating fluid to heat radiation to the latent heat storage material (42, 52) while being immersed in 52), absorbs heat from the latent heat storage material (42, 52) A heat storage unit ( 40,50 ) having a heat storage heat exchanger ( 43,53 ) provided with a second heat transfer tube ( 46,56 ) for flowing a fluid to be heated ;
Connected to the first heat transfer tube (45,55) of the heat storage heat exchanger (43,53) of the heat storage unit ( 40,50 ) and for heating between the first heat transfer tube ( 45,55 ) and the heat source A heating circuit ( 93 ) for circulating the fluid ;
The heat storage unit (40, 50) is connected to the second heat transfer pipe (46, 56) of the heat storage heat exchanger (43, 53) and the water supply, and the second heat transfer pipe (46 , 56) a hot water supply circuit (60),
Leakage detection means (81) for outputting a detection signal upon detecting leakage of the heating fluid from the heating circuit ( 93 ) ,
An open / close mechanism (83) that shuts off the hot water supply circuit (60) and the water supply when the leak detection means (81) outputs a detection signal ;
The first heat transfer tube ( 45,55 ) is made of the same material as the second heat transfer tube ( 46,56 ), and its wall thickness is thinner than that of the second heat transfer tube ( 46,56 ). Equipment . Heat storage tank and (41, 51), the heat storage tank (41, 51) latent heat storage material is stored in a (42, 52), is installed in the heat storage tank (41, 51) in the latent heat storage material (42 a first heat transfer tube (45, 55) for flow of heating fluid to heat radiation to the latent heat storage material (42, 52) while being immersed in 52), absorbs heat from the latent heat storage material (42, 52) A heat storage unit ( 40,50 ) having a heat storage heat exchanger ( 43,53 ) provided with a second heat transfer tube ( 46,56 ) for flowing a fluid to be heated ;
Connected to the first heat transfer tube (45,55) of the heat storage heat exchanger (43,53) of the heat storage unit (40,50) and for heating between the first heat transfer tube (45,55) and the heat source A heating circuit (93) for circulating the fluid ;
The heat storage unit (40, 50) is connected to the second heat transfer pipe (46, 56) of the heat storage heat exchanger (43, 53) and the water supply, and the second heat transfer pipe (46 , 56) a hot water supply circuit (60),
Leakage detection means (81) for outputting a detection signal upon detecting leakage of the heating fluid from the heating circuit (93),
An open / close mechanism (83) that shuts off the hot water supply circuit (60) and the water supply when the leak detection means (81) outputs a detection signal ;
The first heat transfer pipe (45, 55), the wall thickness the same as the second heat transfer tube (46, 56), the material of ionization tendency than the material of said second heat transfer tube (46, 56) A water heater that is a large metal .

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