JP4155241B2 - Water heater - Google Patents

Description

  The present invention relates to a hot water supply apparatus.

In recent years, heat pump water heaters capable of high-temperature hot water supply and high equipment efficiency have become widespread in the field of household water heaters (see, for example, Patent Document 1). In addition, products with expanded hot water capacity are also required in the commercial hot water market. Therefore, by combining a household heat source unit, it is possible to obtain a product that corresponds to the amount of hot water used in a medium-scale restaurant or the like. And there is a parallel installation example of electric water heaters as a multi-connection system of hot water storage tanks.
JP 2001-263803 A

  However, simultaneous start / stop operation of each electric water heater may be performed. In such a case, the system efficiency is lowered, the boiling temperature becomes higher than necessary, and the amount of heat released from the hot water storage tank is large. There was a problem such as.

  The present invention has been made to solve the above-described conventional drawbacks, and its object is to reduce a decrease in operating efficiency due to a start-up current and temperature fluctuation, and to reduce a tank heat dissipation loss. Is to provide.

Accordingly, a hot water supply apparatus according to claim 1 is a hot water supply apparatus used in a hot water supply circuit in which a request for high temperature hot water discharge and a request for medium temperature hot water discharge at a temperature lower than that are used, and stores a heat source and hot water heated by the heat source. hot water supply unit 1 and a hot water storage tank 3 to a, 1c and comprises a plurality, all of the above hot-water supply unit 1 a, and a high load mode to the hot water storage hot water to 1c, certain of the hot water supply unit 1 a, 1c on one of the hot water storage hot water in the hot water supply unit 1 a, the low load mode to the hot water storage low temperature medium temperature water provided than in the rest of the hot water supply unit 1 c, and can be switched in accordance with the two modes with the required load, low The hot water supply unit 1c that stores hot water in the load mode is a priority reheating unit that performs reheating in preference to the other hot water supply units 1a in the high load mode .

  In the hot water supply apparatus according to the first aspect, at the time of a heavy load such as a weekend when a large amount of hot water is used, all the hot water units 1 can be set to a high load mode in which high-temperature hot water is stored, sufficiently corresponding to the amount of hot water used. Thus, it is possible to avoid a so-called “hot water out” state where hot water runs out. In addition, when the load is low, such as on weekdays, when the amount of hot water used is low, hot water is stored in a specific hot water unit 1 of the hot water units 1, while hot water of lower temperature is stored in the remaining hot water units. Therefore, the so-called “hot water out” state in which hot water runs out can be avoided sufficiently corresponding to the amount of hot water used. In addition, in this low load mode, only a specific hot water supply unit 1 stores hot water, and the remaining hot water units store medium hot water. The hot water storage tank 3 for the intermediate hot water storage requires a hot water storage temperature. There is no need to raise it any more. Further, from the hot water supply unit 1 that can simultaneously take out the high-temperature hot water supply and the intermediate-temperature hot water supply, the high-temperature hot water supply and the intermediate-temperature hot water supply can be controlled with respect to fluctuations in the overall hot water supply load.

Further, in this hot water supply apparatus, since the specific hot water supply unit in the high load mode is a priority reheating unit that performs reheating in preference to other hot water supply units, it is possible to avoid a shortage of hot water supply. Moreover, according to hot water supply, hot water can be stored in each hot water supply unit, and the start / stop loss of the apparatus can be reduced.

  According to the hot water supply apparatus of claim 1, it is possible to avoid a so-called “hot water out” state in which hot water runs out during high loads such as weekends and low loads such as weekdays. Can accommodate the quantity. In addition, since it is not necessary to raise the hot water storage temperature in the hot water storage tank more than necessary when the load is low, such as on weekdays, energy loss can be achieved by reducing the heat dissipation loss of the tank. In addition, high temperature hot water supply and medium temperature hot water supply can be controlled with respect to fluctuations in the overall hot water supply load from a hot water supply unit that can take out high temperature hot water and medium temperature hot water simultaneously. Can do.

In addition, according to this hot water supply apparatus, it is possible to avoid a shortage of hot water supply, so that it is possible to avoid a so-called “hot water out” state in which hot water is exhausted sufficiently corresponding to the amount of hot water used by the user. . Moreover, start / stop loss can be reduced and energy saving can be achieved.

  Next, specific embodiments of the hot water supply apparatus of the present invention will be described in detail with reference to the drawings. FIG. 1 is a simplified diagram of a hot water supply apparatus. This hot water supply apparatus includes a plurality of (in this case, three) hot water supply units 1. As shown in FIG. 2, each hot water supply unit 1 includes a first hot water storage tank 3a and a second hot water storage tank 3b as a hot water storage tank 3, and a first heat source unit 4a and a first heat source unit 4b as heat source units. And.

  Each heat source unit 4a, 4b includes a refrigerant circuit (refrigeration cycle) 5 as shown in FIG. And the refrigerating cycle 5 is comprised by connecting the compressor 6, the water heat exchanger 7, the expansion valve 8, the evaporator (air heat exchanger) 9, etc. in order. As shown in FIG. 2, the heat source units 4 a and 4 b are connected via a connecting pipe 10, and a low-temperature water supply pipe 11 connected to the bottom of the second hot water storage tank 3 b is connected to the connecting pipe 10. Has been. At this time, the connecting pipe 10 includes a first part 10a, a second part 10b, and a connecting part 10b that connects the first part 10a and the second part 10b. Connected to the unit 10b. Further, the hot water supply pipe 12 protrudes from the first heat source unit 4a, and the hot water supply pipe 13 protrudes from the second heat source unit 4b. And in the 1st heat source unit 4a, the hot water supply piping 12 and the 1st part 10a of the connection piping 10 are connected via the connection path 14, and in the 2nd heat source unit 4b, the hot water supply piping 13 and the connection piping 10 are connected. The second part 10 b is connected via the connection path 15. Under the present circumstances, the heat exchange path 16 (refer FIG. 3) comprised by each connection path 14 and 15 by the water heat exchanger 7 is interposed.

  Moreover, the upper part of the 1st hot water storage tank 3a and the bottom part of the 2nd hot water storage tank 3b are connected by the piping 17. FIG. The pipe 17 includes a first pipe 18 connected to the upper part of the first hot water storage tank 3a, a second pipe 19 connected to the bottom of the second hot water storage tank 3b, a first pipe 18 and a second pipe 19. It consists of a third pipe 20 and a fourth pipe 21 to be connected. The hot water supply pipe 12 is connected to the fourth pipe 21 via a switching valve (three-way valve) 22, and the hot water supply pipe 13 is connected to the third pipe 20 via a switching valve (three-way valve) 23. Note that water circulation pumps P and P are interposed in the first part 10a and the second part 10b of the connecting pipe 10.

  Furthermore, a hot water outlet pipe 25 is connected to the upper part (top) of the first hot water storage tank 3a, and the lower part of the first hot water storage tank 3a and the upper part of the second hot water storage tank 3b are connected via a communication pipe 26. Yes. A hot water discharge pipe 27 is connected to the upper part of the second hot water storage tank 3b. In this case, a connecting pipe 32 is connected to the hot water outlet pipe 25, and the mixing valve 30 is connected to the connecting pipe 32. The hot water pipe 27 is connected to the connection pipe 32 via a three-way valve 34. A discharge pipe 33 is connected to the lower part of the first hot water storage tank 3 a, and the discharge pipe 33 is connected to the hot water pipe 27 via a three-way valve 34. A water supply pipe 36 having a pressure reducing valve 35 is connected to the lower part of the second hot water storage tank 3b, and a water supply pipe 37 connected to the mixing valve 30 is connected to the water supply pipe 36. .

  Next, the boiling operation in the hot water supply apparatus configured as described above will be described. The compressor 6 of each heat source unit 4a, 4b is driven, and the water circulation pumps P, P of the connecting pipe 10 are driven. Then, the low temperature water at the bottom of the second hot water storage tank 3b flows into the first part 10a and the second part 10b from the low temperature water supply pipe 11 through the third part 10c of the connection pipe 10, respectively. Then, the low-temperature water (unheated water) that has entered the first part 10 a flows into the hot water supply pipe 12 through the heat exchange path 16. Further, the low temperature water (unheated water) that has entered the second part 10 b flows into the hot water supply pipe 13 through the heat exchange path 16.

  At this time, in each of the heat source units 4a and 4b, the refrigerant discharged from the compressor 6 sequentially passes through the water heat exchanger 7, the expansion valve 8, the air heat exchanger (evaporator) 9 and the like to the compressor 6. And return. Therefore, unheated water flowing through the heat exchange path 16 is heated by the water heat exchanger 7. The heated water heated by the first heat source unit 4a enters the first pipe 18 from the hot water supply pipe 12 via the three-way valve 22, and flows into the first hot water storage tank 3a from the first pipe 18. Also, the heated water heated by the second heat source unit 4b enters the first pipe 18 from the third pipe 20 through the three-way valve 23 from the hot water supply pipe 13, and the first hot water storage tank 3a from the first pipe 18. Flow into. That is, the low-temperature water in the second hot water storage tank 3a flows out from the low-temperature water supply pipe 11, and accordingly, the hot water in the first hot water storage tank 3a passes from the lower part to the upper part of the second hot water storage tank 3b via the connection pipe 26. As a result, the hot water in the first hot water storage tank 3a accumulates sequentially from the top.

Incidentally, a temperature detector (temperature thermistor) 38 is attached to the lower side of the first hot water storage tank 3a, and a temperature detector (temperature thermistor) 39 is attached to the upper side of the second hot water storage tank 3b. That is, by switching the three-way valve 34 based on the temperatures of the temperature detectors 38 and 39, the hot water can be discharged from the first hot water storage tank 3a or the second hot water storage tank 3b. Further, in addition to the medium hot water hot water, high temperature hot water from the hot water hot water discharge pipe 25 can be discharged. Here, the high temperature hot water is, for example, about 80 ° C., and the medium temperature hot water is, for example, about 50 ° C. hot water.
When the heating source unit 4a, 4b is not sufficiently heated at the start of boiling operation, the three-way valves 22, 23 are switched so that low temperature hot water is not supplied to the upper part of the first hot water storage tank 3a. This low temperature hot water is returned to the second hot water storage tank 3b via the third pipe of the pipe 17.

  In this manner, each hot water supply unit 1 (that is, the first hot water supply unit 1a, the second hot water supply unit 1b, and the third hot water supply unit 1c) can store hot water and hot water. That is, this hot water supply device is a hot water supply device used in a hot water supply circuit in which a request for hot hot water hot water and a request for medium hot water hot water lower in temperature are mixed, and includes a heat source (heat source unit) and hot water heated by the heat source. A plurality of hot water supply units 1 having hot water storage tanks 3 for storing hot water are provided. Therefore, in this hot water supply apparatus, as shown in FIG. 1, a high temperature hot water supply pipe 40 and an intermediate hot water supply pipe 41 are provided, and the first hot water supply unit 1 a and the second hot water supply unit 1 b are provided in the high temperature hot water supply pipe 40. Are connected to the hot water outlet pipes 25 of the third hot water supply unit 1c, and the intermediate hot water supply pipes 41 are connected to the hot water hot water supply pipes 42 of the first hot water supply unit 1a, the second hot water supply unit 1b, and the third hot water supply unit 1c. Is connected. In addition, an electromagnetic valve 43 is interposed in the medium hot water outlet pipe 42 of the first hot water supply unit 1a and the second hot water supply unit 1b, and an electromagnetic valve 44 is interposed in the hot water outlet pipe 25 of the third hot water supply unit 1c. ing. That is, in each hot water supply unit 1a, 1b, the supply of the medium temperature hot water from the medium temperature hot water tap pipe 42 to the medium temperature hot water supply pipe 41 can be stopped by each electromagnetic valve 43. In the hot water supply unit 1c, the supply of the high temperature hot water from the high temperature hot water tap pipe 25 to the high temperature hot water supply pipe 40 can be stopped.

  At this time, when there is a lot of hot water to be used on weekends (Saturday and Sunday) (when the load is high), all the hot water supply units 1a, 1b, 1c are set to a high load mode in which hot water is stored, and on weekdays. When less hot water is used (low load), hot water is stored in the specific hot water supply units 1a, 1b of the hot water supply units 1a, 1b, 1c, while the remaining hot water supply units 1c are more than that. A low-load mode is provided to store hot water at low temperature. Both modes can be switched according to the required load.

  That is, at the time of high load, the hot water from the hot water hot water supply pipes 25 of each of the hot water supply units 1a, 1b and 1c is supplied to the high temperature hot water supply pipe 40 and the hot water hot water discharge pipes of the hot water supply units 1a and 1b are supplied. The hot water from 42 is supplied to the hot water supply pipe 41. Thereby, sufficient hot water supply amount of high temperature hot water and medium hot water can be ensured, and the user can use it stably. Moreover, when there is little hot water to use like a weekday (at the time of low load), from the hot water outlet pipes 25 and 25 of the hot water supply units 1a and 1b, as described as the time of low load in FIG. The hot water is supplied to the hot water supply pipe 40, and the hot water from the hot water outlet pipe 42 of the hot water supply unit 1c is supplied to the hot water supply pipe 41. As described above, the amount of high-temperature hot water that can be supplied to the high-temperature hot water supply pipe 40 and the amount of high-temperature hot water that can be supplied to the medium-temperature hot-water supply pipe 41 are smaller than those at the time of the high load. Since it is a load time, it can fully respond to the amount of use.

  In the above hot water supply device, during a heavy load such as a weekend when a large amount of hot water is used, all the hot water units 1 can be set to a high load mode in which high temperature hot water is stored. It is possible to avoid a so-called “hot water out” state where there is no water. In addition, when the load is low, such as on weekdays, when the amount of hot water used is low, hot water is stored in a specific hot water unit 1 of the hot water units 1, while hot water of lower temperature is stored in the remaining hot water units. Therefore, the so-called “hot water out” state in which hot water runs out can be avoided sufficiently corresponding to the amount of hot water used. That is, since the so-called “hot water out” state where hot water runs out can be avoided during high loads such as weekends and low loads such as weekdays, it is possible to deal with the amount of hot water used in medium-scale restaurants and the like. In addition, in this low load mode, only a specific hot water supply unit 1 stores hot water, and the remaining hot water units 1 store medium hot water. The hot water storage tank 3 of the medium hot water stores the hot water temperature. There is no need to raise it more than necessary. For this reason, energy saving can be achieved by reducing tank heat dissipation loss. In addition, from the hot water supply unit 1 that can take out high temperature hot water and medium temperature hot water simultaneously, it is possible to control high temperature hot water and medium temperature hot water in response to fluctuations in the overall hot water supply load, reducing the decrease in operating efficiency due to startup current and temperature fluctuations. can do.

  By the way, although the said hot-water supply apparatus is provided with three hot-water supply units 1a, 1b, 1c, when it boils up using only two hot-water supply units 1a, 1b in a high load mode, heating capacity is insufficient. (Insufficient hot water supply) may occur. In such a case, the hot water supply unit 1c can be used for replenishment in order to compensate for the shortage of hot water storage amount (shortage of hot water supply amount) of the two hot water supply units. That is, as shown by the solid line in FIG. 4, when the first hot water storage unit 1a and the second hot water storage unit 1b are first used to boil, the amount of hot water supply is insufficient (when the heating capacity is insufficient as indicated by the solid line). In addition to the first hot water storage unit 1a and the second hot water storage unit 1b, the third hot water storage unit 1c is used to eliminate the shortage of hot water supply. Then, when the amount of hot water supply due to the boiling of the three hot water storage units 1a, 1b, and 1c becomes excessive (in the heating capacity surplus line indicated by the solid line), the operation of the third hot water storage unit 1c is stopped. Thereafter, if the amount of hot water supply becomes insufficient again, the third hot water storage unit 1c is operated.

  If controlled as described above, in the high load mode, the specific hot water supply unit (in this case, the third hot water supply unit 1c) is changed to the other hot water supply units (in this case, the first hot water supply unit 1a and the second hot water supply unit 1b). A priority tracking unit that performs a heating operation (tracking operation) with priority is provided.

  For this reason, in the priority tracking unit 1c, the shortage of hot water supply between the first hot water supply unit 1a and the second hot water supply unit 1b is compensated, so that the shortage of hot water supply can be avoided. Thereby, it is possible to avoid a so-called “hot water out” state in which hot water runs out sufficiently corresponding to the amount of hot water used by the user. Moreover, according to hot water supply, each hot water storage unit 1a, 1b, 1c will be drive | operated, start / stop loss can be reduced, and energy saving can be achieved.

  Moreover, it is also possible to control as follows in the thing provided with the three hot-water supply units 1a, 1b, and 1c. First, when three units are operated at the same time and the amount of hot water supply due to the boiling of these three hot water supply units 1a, 1b, 1c becomes excessive (in the heating capacity surplus line indicated by the broken line), the hot water supply units 1a, 1b, 1c Stop driving. Thereafter, if the amount of hot water supply again becomes insufficient (in the case of the heating capacity shortage line indicated by the broken line), the three hot water supply units 1a, 1b, 1c are operated.

  As described above, when the priority tracking unit 1c compensates for the shortage of the hot water supply amount of the other hot water supply units 1a, 1b, the hot water storage units 1a, 1b, 1c do not necessarily have a plurality of hot water storage tanks 3. Alternatively, a single hot water storage tank 3 may be provided. In this case, for example, as shown in FIG. 5, the hot water storage tank 3 is provided with a discrimination level 45 for night boiling and a discrimination level 46 for day boiling, and the remaining hot water is a discrimination level 45 for night boiling. Between the hot water supply units 1a and 1b, and if the remaining hot water is above the daytime boiling determination level 46, each hot water supply unit is operated. Three units 1a, 1b and 1c can be operated. The discrimination levels 45 and 46 can be determined by temperature detectors (temperature thermistors) 47 and 48 attached to the hot water storage tank 3.

  Although specific embodiments of the present invention have been described above, the present invention is not limited to the above embodiments, and various modifications can be made within the scope of the present invention. For example, in the embodiment shown in FIG. 1, each of the hot water supply units 1a, 1b, 1c includes two hot water storage tanks 3a, 3b. In this case, in each of the hot water supply units 1a, 1b, 1c, If medium temperature hot water supply is possible, the number of hot water storage tanks may be one or three or more. Furthermore, the heat source units 4a and 4b may be one. In addition, the number of hot water supply units can be increased or decreased. In the above embodiment, a heat pump is used as a heating source, but other heat sources such as an electric heater may be used. Moreover, as a refrigerant of a refrigeration cycle when using a heat pump, dichlorodifluoromethane (R-12), chlorodifluoromethane (R-22), 1,1,1,2-tetrafluoroethane (R-134a), etc. Even such a refrigerant may be a natural refrigerant such as carbon dioxide, ethylene, ethane, or nitric oxide.

It is a simplified diagram showing an embodiment of a hot water supply apparatus of the present invention. It is a simplified view of a hot water supply unit of the hot water supply apparatus. It is a simplified diagram of the heat source unit of the hot water supply apparatus. It is a schematic diagram which shows the control method of other embodiment of the hot water supply apparatus of this invention. It is a simplified diagram showing a hot water storage tank of the hot water supply apparatus.

Explanation of symbols

  1. Hot water supply unit 3. Hot water storage tank

Claims (1)

A hot water supply apparatus for use in a hot water supply circuit in which high-temperature hot-water demand and low-temperature medium-temperature hot-water demand are mixed, and includes a heat source and a hot water storage tank (3) for storing hot water heated by the heat source. hot water supply units (1 a · 1c) has a plurality, and a high load mode to the hot water storage hot water to the all of the hot water supply unit (1 a · 1c), the hot water supply unit certain of (1 a · 1c) The hot water supply unit (1 a ) stores hot water while the remaining hot water supply unit (1 c ) has a low load mode for storing hot water at a lower temperature, and the two modes can be switched according to the required load. The hot water supply unit (1c) that stores hot water in the low load mode is a priority reheating unit that performs reheating in preference to the other hot water supply units (1a) in the high load mode. Hot water equipment.