JP2015129603A - Gas heating device for pool facility - Google Patents

Abstract

PROBLEM TO BE SOLVED: To limit a maximum use amount of city gas and to allow a warm water pool, a shower, heating and the like to be used in a comfortable state.SOLUTION: A gas heating device for a pool facility includes: a switching valve 6 for switching pool water to one of a gas heater 3 and a bypass passage 5; a gas water heater 4 for supplying hot water to a shower 10 and a faucet 11 of a pool facility; a flow rate sensor 7 for detecting a total flow rate which the gas heater 3 and the gas water heater 4 consume; a temperature sensor 8 for detecting a pool water temperature; and a control circuit 9 for controlling the switching valve 6 by the total flow rate and the pool water temperature. The control circuit 9, in a state where the pool water temperature is lower than a preset temperature and the total flow rate is smaller than the stored maximum flow rate, switches the switching valve 6 to a position in which the pool water flows into the gas heater 3 and heats the pool water by the gas heater 3, and in a state where the pool water temperature is lower than the preset temperature but the total flow rate is larger than the maximum flow rate, bypasses the pool water to the bypass passage 5 and does not heat the pool water by the gas heater 3.

Description

  The present invention relates to a gas heating apparatus for a pool facility that heats pool water of a hot water pool and hot water consumed by a shower or faucet of the pool facility or a heater with the combustion heat of gas.

  In the hot water pool, the pool water is circulated through a heating device to maintain a constant temperature. As this type of apparatus, an apparatus for heating pool water with an electric heat pump has been developed. (See Patent Document 1)

  The heat pump of the above heating apparatus has a large calorific value with respect to power consumption as compared with an electric heater, and can heat pool water with efficiency several times that of an electric heater. However, the electric heat pump pressurizes the refrigerant with a compressor and liquefies it with a condenser to generate condensation heat. The overall structure is complicated and the cost of the apparatus increases. In particular, large electric heat pumps have the disadvantage of increasing equipment costs. Furthermore, the electric heat pump has a drawback that it is difficult to quickly heat the pool water in the winter when the outside air temperature is lowered and the calorific value is reduced.

  In order to solve the above drawbacks, an apparatus for heating pool water with combustion heat such as heavy oil or city gas is used as a warm water pool heating apparatus. City gas has clean exhaust gas and less soot compared to heavy oil, and has the feature that pool water can be heated quickly even in cold winter. Furthermore, since city gas is continuously supplied from a gas company to a pool facility via piping, it is not necessary to transport fuel like heavy oil and can be used more conveniently.

JP 2002-13838 A

  Due to the above characteristics, pool water heating devices using city gas as fuel are used in pool facilities nationwide. However, since city gas is supplied from a gas company to a pool facility via a gas pipe, if the maximum usage amount per unit time, that is, the peak usage amount increases, the gas company and the pool facility Since it is necessary to make the pipe thicker or increase the gas pressure in the pipe to reduce the pressure loss, there is a disadvantage that the gas supply cost increases.

  By the way, the pool facility of the heated pool heats the heated pool using city gas as fuel, and further warms the hot water discharged from the shower and faucet used in the facility and the heater of the facility with a gas water heater. In winter, the maximum amount of city gas is temporarily increased during peak hours when many users use it. For this reason, there is a disadvantage that a gas supply cost is increased because a special gas supply line is required, such as increasing the piping between the gas company and the pool facility, or increasing the gas pressure in the piping.

  The present invention has been developed for the purpose of solving the above-mentioned drawbacks. An important object of the present invention is to provide a gas heating device for a pool facility that allows a hot water pool, shower, heating, etc. to be used in a comfortable state while limiting the maximum amount of city gas to be used. is there.

Means and effects for solving the problems

  The gas heating apparatus for a pool facility according to the present invention is connected to a pool water circulation path 2 connected to a hot water pool 1 and heats the pool water circulated in the circulation path 2 with the combustion heat of gas. A heater 3, a bypass 5 connected to the gas heater 3 in parallel to bypass the pool water supplied to the gas heater 3, and a pool heater to be circulated through the circulation path 2. 3 and the bypass valve 5 are connected to a switching valve 6 that is circulated and a gas pipe 21 that supplies gas to the gas heater 3, and a gas provided in a pool facility provided with a hot water pool 1. A water heater 4, a gas heater 3 and a flow rate sensor 7 for detecting the flow rate of gas supplied to the gas water heater 4, a temperature sensor 8 for detecting the temperature of the pool water in the hot water pool 1, and a gas heater 3 and the gas flow rate supplied to the gas water heater 4 and the temperature sensor 8 And a control circuit 9 for controlling the switching valve 6 in the pool water temperature to.

  The control circuit 9 stores the set temperature of the pool water for switching the switching valve 6 and the maximum flow rate of the gas, the temperature of the pool water is lower than the set temperature stored in advance, and the gas heater 3 In a state where the gas flow rate consumed by both of the gas water heaters 4 is equal to or less than the set flow rate which is smaller than the maximum flow rate stored, the switching valve is moved to a position where the pool water circulated through the circulation path 2 flows into the gas warmer 3. 6 is switched, the pool water is heated by the combustion heat of the gas heater 3, the temperature of the pool water is lower than the set temperature, and the gas flow rate consumed by both the gas heater 3 and the gas water heater 4 In a state where the flow rate exceeds a preset flow rate larger than the maximum flow rate stored in advance, the switching valve 6 is switched to a position for bypassing the pool water circulated in the circulation path 2 to the bypass path 5, and the gas heater 3 pools Warm water And there is no state.

  The above-mentioned gas heating apparatus for pool facilities has a feature that it can use a hot water pool, a shower, a heater, etc. in a comfortable state while limiting the maximum amount of fuel gas used at the peak time to a low level. Even if the temperature of the pool water is lower than the set temperature, the pool water is used when the gas flow rate consumed by both the gas heater and the gas water heater exceeds the stored maximum flow rate. This is because the gas is circulated to the bypass passage without being circulated to the gas heater. In this state, since the pool water is not circulated to the gas heater, the gas heater cannot detect that the pool water has become lower than the set temperature and does not heat it. In particular, the above gas heating apparatus circulates pool water to the gas warmer while the pool water temperature is lower than the set temperature, and the pool water in which the gas warmer is circulated is lower than the set temperature. However, it does not stop the pool water heating in a low state. In a state where the total gas flow rate exceeds the maximum flow rate, the pool water can be circulated to the gas heater, the combustion of the gas heater can be stopped, and the pool water heating can be interrupted. Because it is necessary to control the combustion of the gas heater not only with the temperature of the circulating pool water but also with the temperature of the pool water and the total flow rate of the gas, The circuit becomes complicated. Because pool facilities use off-the-shelf gas heaters that are mass-produced with almost no exceptions, it is extremely difficult to modify the control circuit, and a specially designed gas heater equipped with a special control circuit Has the disadvantage that the cost is very high. However, the gas heating device described above bypasses the pool water to the bypass passage to the gas heater 3 when the temperature of the pool water is lower than the set temperature and the total gas flow rate exceeds the maximum flow rate. Since the gas heater does not circulate, it is not necessary to control the combustion state by both the set temperature of the pool water and the total flow rate of the gas. This is because the pool water is not circulated through the gas heater when the total flow rate exceeds the maximum flow rate. In this state, the pool water is not circulated to the gas warmer and is not heated. For this reason, even if it is temporarily used by a large number of users and the gas flow rate used by both the gas heater and the gas water heater exceeds the maximum flow rate, the pool water is not heated and the gas Since the warmer is controlled so as not to consume gas, the total flow rate of gas does not exceed the maximum flow rate. In this state, the water temperature of the pool water is lower than the set temperature, but the water temperature does not drop more rapidly than the set temperature. This is because the amount of pool water is extremely large and the heat capacity is extremely large, so that the temperature change becomes very gradual. Also, the time when both the gas heater and gas water heater consume gas at peak time and the total flow rate exceeds the maximum flow rate does not continue for a long time, even if the pool water temperature is temporarily interrupted, It does not give the user of the heated pool a “cold” feeling. In particular, since the water temperature may be set somewhat lower in the hot water pool usage state, the change in the water temperature within the set temperature does not adversely affect the user.

  The gas heating device of the pool facility can supply hot water to at least one of the shower 10, the faucet 11, and the heater 12 provided in the pool facility with the gas water heater 4. The gas heating device of this pool facility is characterized by clean exhaust gas while supplying hot water to both the shower and the faucet.

  In the gas heating apparatus for a pool facility according to the present invention, the switching valve 6 that switches the circulating water to the gas heater 3 and the bypass 5 can be a three-way valve. This gas heating device can circulate the pool water by switching between the bypass path and the gas heater with one switching valve.

  The pool facility gas heating apparatus according to the present invention includes a gas water heater 4, a first gas water heater 41 that supplies warm water to the shower 10 and faucet of the pool facility, and a heater 12 of the pool facility. 2 gas water heaters 42 can be used. This gas heating device can stop the heating of the pool facility when both the shower and faucet usage is large, so the total flow rate of gas used by both the gas warmer and the gas water heater is set smaller. it can.

  The gas heating apparatus for a pool facility according to the present invention detects a flow rate sensor 7, a heater flow rate sensor 71 that detects a gas flow rate consumed by the gas heater 3, and a gas flow rate consumed by the gas water heater 4. It is configured by a water heater flow rate sensor 72, and the control circuit 9 adds the gas consumption flow rate detected by the heater flow rate sensor 71 and the gas consumption flow rate detected by the water heater flow rate sensor 72, thereby heating the gas. The gas flow rate used by both the water heater 3 and the gas water heater 4 can be detected. This gas heating device can calculate and detect the total flow without providing a flow sensor for detecting the total flow, and can detect the flow of both the gas water heater and the gas warmer independently. The control of the switching valve can be controlled to a more optimal state.

  The gas heating apparatus for a pool facility according to the present invention detects the flow rate of gas consumed by the gas heater 3 and the gas water heater 4 in a preset unit time by means of the control circuit 9 and switches the switching valve 6. Can be switched. This gas warming device can switch the switching valve by detecting the gas flow rate consumed by the gas warmer 3 and the gas water heater 4 in a unit time, which is 1 minute or longer and within 1 hour as a unit time. . This gas warming device can control the switching valve so that the total flow rate consumed by both the gas warmer and the gas water heater temporarily exceeds the maximum flow rate, but does not exceed the maximum flow rate per unit time. . Therefore, this gas heating device has a feature that the control of the switching valve can be made easier.

It is a block diagram of the gas heating apparatus of the pool facility concerning the Example of this invention. It is a block diagram of the gas heating apparatus concerning the other Example of this invention. It is a graph which shows the total flow volume of the gas which a gas heating apparatus consumes.

  Embodiments of the present invention will be described below with reference to the drawings. However, the embodiment shown below exemplifies a gas heating apparatus for a pool facility for embodying the technical idea of the present invention, and the present invention uses the gas heating apparatus for a pool facility as follows. Not specified.

  Further, in this specification, in order to facilitate understanding of the scope of claims, numbers corresponding to the members shown in the examples are indicated in the “claims” and “means for solving problems” sections. It is added to the members. However, the members shown in the claims are not limited to the members in the embodiments.

  The gas heating apparatus for a pool facility shown in FIG. 1 is connected to a pool water circulation path 2 connected to a hot water pool 1, and warms the pool water circulated in the circulation path 2 with the combustion heat of gas. The gas heater 3 is connected to the gas heater 3 in parallel to bypass the pool water supplied to the gas heater 3, and the pool water to be circulated through the circulation path 2 is gas-added. It is connected to a switching valve 6 for switching between the warmer 3 and the bypass path 5 and circulated, and a gas pipe for supplying gas to the gas warmer 3, and is provided in a pool facility provided with the hot water pool 1. Gas water heater 4, gas heater 3, flow sensor 7 for detecting the flow rate of gas supplied to gas water heater 4, temperature sensor 8 for detecting the temperature of pool water in hot water pool 1, and gas heating Total flow rate and temperature of gas supplied to the water heater 3 and the gas water heater 4 Capacitors 8 and a control circuit 9 for controlling the switching valve 6 in the pool water temperature detected.

  The pool facility has a 25 m or 50 m hot water pool 1 in a building equipped with a heater 12. Furthermore, the pool facility is provided with a hot water shower 10 used by a user of the hot water pool 1 and a faucet 11 for discharging the hot water. The heater 12 is heated, and the hot water supplied to the hot water shower 10 and the faucet 11 is heated by the gas water heater 4.

  The hot water pool 1 is connected to a circulation path 2 that constantly circulates the pool water. The circulation path 2 includes a filter 13 for removing foreign matter from the pool water to keep it always clear, a gas warmer 3 for maintaining a constant temperature, and a filter 13 and a gas warmer 3. A circulation pump 14 for circulating the pool water is connected in series.

  The filter 13 allows the pool water to pass through a filter medium such as sand and removes foreign matters contained in the pool water. The gas heater 3 warms the circulated pool water with the combustion heat of the gas. The gas warmer 3 in FIG. 1 includes a heat exchanger 15 that exchanges heat between pool water and heated water heated by the combustion heat of the gas warmer 3. However, the gas heater 3 can also heat pool water directly with the combustion heat of gas, without passing through a heat exchanger. The circulation pump 14 is continuously operated to circulate the pool water to the filter 13 and keep it in a clear state. Pool water passing through the filter 13 passes through either the gas warmer 3 or the bypass 5 and is circulated through the hot water pool 1 and the circulation path 2.

  The gas heater 3 in FIG. 1 includes a heat exchanger 15 that heats pool water, and a heater main body 16 that heats heated water circulated through the heat exchanger 15. In the illustrated heat exchanger 15, in order to heat the pool water with the heating water of the heater main body 16, a heat exchange pipe 18 is arranged in the sealed case 17, and the heated water is circulated in the sealed case 17. Then, the pool water is circulated through the heat exchange pipe 18. In order to circulate heated water from the warmer body 16 into the sealed case 17 of the heat exchanger 15, the gas warmer 3 includes an in-machine pump 19. Further, the warmer body 16 includes a gas burner (not shown) for heating the heated water circulated by the in-machine pump 19 with the combustion heat of the gas.

  The gas heater 3 described above detects the pool water temperature in the heat exchanger 15 and controls the ignition state, that is, the combustion state, of the gas burner of the heater body 16. In order to detect the pool water temperature in the heat exchanger 15, the gas warmer 3 includes an ignition control temperature sensor 20, and an ignition temperature for igniting the gas burner is detected by the detected temperature of the ignition control temperature sensor 20. I remember it. The gas warmer 3 operates the in-machine pump 19 when the detected temperature of the ignition control temperature sensor 20 is lower than the stored ignition temperature, and supplies heated water to the heat exchanger 15 and the warmer body 16. And igniting the gas burner to heat the heated water. In this state, the heated water circulated to the heat exchanger 15 heats the pool water via the heat exchanger 15. When the detected temperature of the ignition control temperature sensor 20 becomes higher than the ignition temperature, that is, when the pool water temperature in the heat exchanger 15 becomes higher than the ignition temperature, the gas burner is not burned, that is, the gas burner is not ignited. Stop pump operation. In this state, the heated water is not heated by the gas burner, and the heated water does not heat the pool water.

  Furthermore, the heating device of FIG. 1 connects the bypass path 5 in parallel with the gas warmer 3 and switches whether the bypass water is bypassed to the bypass path 5 by the switching valve 6. In a state where the pool water is circulated to the gas heater 3, the gas heater 3 warms the pool water with combustion heat, and the pool water is heated by the gas heater 3. In a state where the pool water is bypassed to the bypass passage 5, the pool water is not circulated to the gas heater 3, and the gas heater 3 does not heat the pool water. The control circuit 9 controls the switching valve 6 to switch whether the pool water is circulated through the gas heater 3 or the bypass passage 5.

  In a state where the pool water is bypassed to the bypass passage 5 and is not circulated to the gas heater 3, the gas heater 3 does not heat the pool water. In this state, the pool water temperature in the heat exchanger 15 becomes higher than the ignition temperature. This is because the gas heater 3 detects the temperature of the pool water in the heat exchanger 15 and controls the ignition of the gas burner. Therefore, the control circuit 9 switches the switching valve 6 so that the pool water is circulated to the bypass path 5 when the temperature of the pool water circulated through the circulation path 2 is higher than the set temperature. When the switching valve 6 is in this position, the pool water is not circulated to the gas heater 3 and the gas heater 3 does not heat the pool water. Therefore, in a state where the temperature of the circulated pool water is higher than the set temperature and the pool water is not heated, that is, in a non-warm state, the control circuit 9 causes the bypass valve 5 to bypass the pool water. Control. However, in a non-warming state where the pool water temperature is higher than the set temperature, the control circuit 9 can also switch the switching valve 6 so that the pool water is circulated to the gas heater 3. This is because, in this state, the pool water temperature circulated through the gas warmer 3 is higher than the set temperature, so that the gas burner of the gas warmer 3 is not ignited.

  The pool water is circulated to either the gas heater 3 or the bypass 5 by the switching valve 6 controlled by the control circuit 9. When the pool water is heated by the gas heater 3, the control circuit 9 switches the switching valve 6 so that the pool water is circulated through the gas heater 3. The pool water is heated when the pool water temperature is lower than the set temperature. However, even if the pool water temperature is lower than the set temperature, when the gas flow rate consumed by both the gas heater 3 and the gas water heater 4 exceeds the maximum flow rate, the pool water is bypassed to the bypass 5. Then, heating of the pool water by the gas heater 3 is interrupted. Therefore, in the state where the temperature of the pool water is lower than the preset temperature stored in advance, the control circuit 9 has a gas flow rate consumed by both the gas warmer 3 and the gas water heater 4 smaller than the maximum flow rate stored. After confirming that the flow rate is not more than the set flow rate, the switching valve 6 is switched to a position where the pool water is circulated through the gas heater 3. When the pool water is circulated to the gas heater 3 in this state, the gas heater 3 is ignited by the gas burner because the pool water temperature in the heat exchanger 15 becomes lower than the set temperature, and the combustion heat of the gas. The heated water is heated by the heating water, and the heated water heats the pool water through the heat exchanger 15.

  The switching valve 6 in the figure is a three-way valve that circulates pool water to either the gas warmer 3 or the bypass 5. However, the switching valve 6 is composed of a first on-off valve 6A connected to the bypass 5 and a second on-off valve 6B connected to the gas heater 3, as shown in FIG. You can also. These switching valves 6A and 6B open any one of the first switching valve 6A and the second switching valve 6B and close the other, and the pool water is supplied to either the bypass passage 5 or the gas warmer 3. It can be circulated.

  The pool facility includes a gas water heater 4 that supplies hot water in addition to the hot water pool 1 of the pool facility, in addition to the gas heater 3 that heats the pool water. The gas water heater 4 supplies hot water to at least one of the shower 10, the faucet 11, and the heater 12 provided in the pool facility. 1 includes a first gas water heater 41 that supplies hot water to the shower 10 and the faucet 11 of the pool facility, and a second gas water heater 42 that heats the heater 12 of the pool facility. I have.

  The gas water heater 4 is connected to the gas pipe 21 of the gas warmer 3. The gas pipe 21 supplies gas to both the gas water heater 4 and the gas heater 3. A gas flow rate consumed by the gas water heater 4 and the gas warmer 3 is detected by a flow rate sensor 7. The apparatus shown in FIG. 1 and FIG. 2 includes a heater flow rate sensor 71 that detects the gas flow rate consumed by the gas warmer 3 and a water heater flow rate sensor 72 that detects the gas flow rate consumed by the gas water heater 4. Prepare. 1 and FIG. 2 includes a first water heater flow sensor 72 that detects the gas flow rate of the first gas water heater 4 that supplies hot water to the shower 10 and the faucet 11 of the pool facility, A second water heater flow rate sensor 72 for detecting the gas flow rate of the second gas water heater 4 for heating the heater 12 of the facility is provided.

  The control circuit 9 detects the total flow rate consumed by the gas heater 3 and the gas water heater 4 and switches the switching valve 6 or switches the switching valve 6 based on both the total gas flow rate and the pool water temperature. The control circuit 9 stores the maximum gas flow rate for switching the switching valve 6 or stores both the maximum gas flow rate and the set temperature of the pool water.

  The control circuit 9 that controls the switching valve 6 by both the pool water temperature and the gas flow rate is such that the temperature of the pool water is lower than the preset temperature stored in advance, and both the gas heater 3 and the gas water heater 4 are The switching valve 6 is switched to a position where the pool water flows into the gas warmer 3 and the bypass passage 5 is not bypassed in a state where the total flow rate of the consumed gas is less than the set flow rate smaller than the stored maximum flow rate. . In this state, the pool water is circulated to the heat exchanger 15 of the gas heater 3. When pool water is circulated through the heat exchanger 15 of the gas warmer 3, the pool water decreases the temperature of the heated water of the heat exchanger 15. When the temperature of the heated water decreases and becomes lower than the ignition temperature, the gas burner is ignited, the heated water is heated by the combustion heat of the gas, and the heated water warms the pool water. The ignition temperature of the gas burner is set lower than the set temperature of the pool water so that the gas warmer 3 heats the pool water in a state where the pool water is circulated through the heat exchanger 15.

  The control circuit 9 is set so that the total flow rate of the gas consumed by both the gas heater 3 and the gas water heater 4 is larger than the maximum flow rate stored in advance even if the temperature of the pool water is lower than the set temperature. In a state where the flow rate is exceeded, the pool water is bypassed to the bypass path 5 and is not circulated through the gas heater 3. In this state, although the temperature of the pool water is lower than the set temperature, the pool water is not heated by the gas heater 3. Pool water that is not heated gradually decreases in temperature. However, since pool water has an extremely large amount of water, the temperature gradient at which the temperature decreases is extremely small. Therefore, even if the pool water is not heated for a predetermined time, the pool user hardly feels that the water temperature has decreased.

  The flow rate of the gas consumed by the gas water heater 4 changes with time. This is because the amount of hot water used by the user of the pool facility in the shower 10 and the faucet 11 and the amount of heat used in the heater 12 change. As time passes, the gas flow rate consumed by the gas water heater 4 decreases, the gas flow rate consumed by both the gas water heater 4 and the gas warmer 3 becomes lower than the maximum flow rate, and the pool water temperature Is lower than the set temperature, the control circuit 9 switches the switching valve 6 to circulate the pool water to the gas heater 3. The control circuit 9 stores the gas flow rate of the gas warmer 3 in the ignition state of the gas burner, detects only the flow rate of the gas water heater 4 without igniting the gas warmer 3, and the gas warmer 3 and the gas water heater 4 can detect the total flow rate of gas consumed. Therefore, the gas warmer 3 that makes the consumed gas flow rate constant can store the consumed gas flow rate in the control circuit 9 and detect the gas flow rate of the gas warmer 3 in the ignition state. This apparatus can detect the flow rate of the gas heater 3 without providing the heater flow rate sensor 7 that detects the gas flow rate of the gas heater 3. However, the gas heater 3 having a constant gas consumption flow rate can also be provided with the heater flow rate sensor 7 to detect the gas flow rate to be consumed more accurately. This device can control the switching valve 6 by more accurately detecting the gas flow rate consumed by the gas warmer 3. In particular, the apparatus of the present invention can be controlled so that the gas flow rate consumed per unit time does not exceed the maximum flow rate even if the peak value of the total gas flow rate exceeds the maximum flow rate. Therefore, the gas flow burner of both the gas warmer 3 and the gas water heater 4 is temporarily ignited, and both are used. The total flow rate is detected, and the total flow rate exceeds the maximum flow rate. The valve 6 can be switched to circulate the pool water to the bypass 5. This device can detect the total flow rate of the fluctuating gas and control the switching valve 6 so that the total flow rate does not exceed the maximum flow rate per unit time.

  In the non-warming state where the temperature of the pool water is higher than the set temperature, it is not necessary to heat the pool water with the gas warmer 3. Therefore, in the non-warming state, the control circuit 9 switches the switching valve 6 to a position where the pool water circulated in the circulation path 2 is bypassed to the bypass path 5 so that the gas can be supplied only to the gas water heater 4. To do. However, in a state where the pool water temperature is higher than the set temperature, the pool water can be circulated through the gas heater 3. However, this apparatus sets the ignition temperature so that the gas burner is not ignited in a state where pool water having a temperature higher than the set temperature is circulated.

  The control circuit 9 detects the total gas flow rate by adding the gas consumption flow rate detected by the heater flow rate sensor 71 and the gas consumption flow rate detected by the water heater flow rate sensor 72. The control circuit 9 that stores the gas flow rate when the gas warmer 3 is in the gas burner ignition state can detect only the gas flow rate of the gas water heater 4 to detect the total flow rate. However, as shown in FIGS. 1 and 2, a total flow rate sensor 75 for detecting the total flow rate may be provided to detect the total flow rate.

  The heating apparatus of FIG. 1 includes a first water heater flow rate sensor 73 that detects a gas flow rate of a first gas water heater 41 that supplies hot water to the shower 10 and the faucet 11 of the pool facility, and the heater 12 of the pool facility. A second water heater flow rate sensor 74 for detecting the gas flow rate of the second gas water heater 42 for heating the gas. In this heating device, the first gas water heater 41 can be set to be used in preference to the second gas water heater 42, and the maximum gas flow rate can be set smaller. This is because when the gas consumption flow rate of the first gas water heater 41 is large, the gas supply of the second gas water heater 42 can be interrupted to stop the heating of the heater 12.

  Even if the heater 12 is not temporarily heated, the temperature of the building of the pool facility does not rapidly decrease. In particular, as shown in FIGS. 1 and 2, the structure in which warm water is stored in the warm water tank 23 and supplied from the warm water tank 23 to the heater 12 can further reduce the decrease in room temperature. In the heating device, when the total flow rate of the first gas water heater 41 and the second gas water heater 42 exceeds the maximum flow rate, the control circuit 9 supplies gas only to the first gas water heater 41, The switching valve 6 is switched to a position where no gas is supplied to the second gas water heater 42 and the pool water is bypassed to the bypass passage 5.

  The structure for temporarily interrupting the operation of the second gas water heater 42 can be the same as the structure for stopping the operation of the gas heater 3. The heating apparatus of FIG. 1 includes a heating heat exchanger 22 that heats heating water circulated through the heater 12. The heat exchanger 22 for heating arranges the hot water pipe 24 in the hot water tank 23 having a watertight structure, and circulates the hot water for heating through the hot water pipe 24. The hot water tank 23 is connected to the second gas water heater 42 to circulate the heated water. Further, a sub bypass path 26 is connected in parallel to the hot water pipe 24 via a sub switching valve 25. The sub switching valve 25 is switched by the control circuit 9. The control circuit 9 switches the sub switching valve 25 and the switching valve 6 so that the total flow rate of the gas consumed by both the gas warmer 3 and the gas water heater 4 does not exceed the maximum flow rate. When both the first gas water heater 41 and the second gas water heater 42 are operated without operating the gas heater 3, when the gas consumption flow rate exceeds the maximum flow rate, the control circuit 9 The sub switching valve 25 is switched so as to bypass the hot water circulated to the sub bypass path 26, and the switching valve 6 is switched so as to bypass the pool water to the bypass path 5. In this state, the hot water tank 23 connected to the heater 12 is not circulated in the hot water circulated through the heater 12. For this reason, the temperature of the hot water for heating stored in the hot water tank 23 does not decrease, and is kept higher than the ignition temperature at which the gas burner of the second gas water heater 42 is ignited. Therefore, the gas is supplied only to the first gas water heater 41, and the total flow rate of the gas does not exceed the maximum flow rate.

  In a state where the total flow rate of the first gas water heater 41 and the second gas water heater 42 does not exceed the maximum flow rate, the control circuit 9 bypasses the heating hot water circulated to the heater 12 to the sub-bypass path 26. Without switching, the hot water for heating is circulated to the hot water tank 23 by switching to the hot water pipe 24 of the heat exchanger 22 for heating. In this state, when the gas is supplied to both the gas water heater 4 and the gas heater 3 and the total gas flow rate does not exceed the maximum flow rate, the control circuit 9 supplies the pool water to the gas heater 3. When the total flow rate of the gas water heater 4 and the gas warmer 3 exceeds the maximum flow rate, the switch valve 6 is switched so as to bypass the pool water to the bypass passage 5.

  FIG. 3 shows the total flow rate of gas consumed by both the gas heater 3 and the gas water heater 4 in the pool facility. The pool facility shown in this graph heats pool water and heats the building of the pool facility in the pre-opening time zone several hours before opening the pool. In this pre-opening time zone, the gas heater 3 that heats the pool water consumes a substantially constant amount of gas, but the gas water heater 4 that supplies hot water for heating has a gas consumption amount that increases as the room temperature rises. It gradually decreases. Therefore, in the time zone before opening, the total flow rate of the gas consumed by both the gas heater 3 and the gas water heater 4 gradually decreases. Since the user uses the shower 10 and the faucet 11 in the open time zone when the pool is opened, the total flow rate of gas consumed by the gas water heater 4 increases or decreases. Since the pool water is kept at a constant temperature during this open time zone, the gas warmer 3 intermittently warms the pool water. Therefore, when both the gas heater 3 and the gas water heater 4 consume gas in the open time period, the total gas flow rate exceeds the preset maximum flow rate as shown by the curve A. There is.

  A curve A shows a gas flow rate of a device which is not an embodiment of the present invention and uses the gas warmer 3 and the gas water heater 4 without limiting the heating of the pool water with the total gas flow rate. In this apparatus, when the pool water temperature falls below the set temperature, the gas heater 3 warms the pool water with the combustion heat of the gas, and when the user uses the hot water in the shower 10 or the faucet 11, the gas water heater 4 is used. Hot water is consumed by the heat of combustion and gas is consumed. Therefore, when the amount of hot water used in the shower 10 or the faucet 11 increases and the temperature of the pool water decreases, the total gas flow rate temporarily exceeds the maximum flow rate.

  Curve B shows the gas flow rate consumed by the gas heating apparatus of the embodiment of the present invention. In this apparatus, the control circuit 9 switches the switching valve so that the total flow rate does not exceed the maximum flow rate in the time zone when the total flow rate of the gas consumed by both the gas warmer 3 and the gas water heater 4 exceeds the maximum flow rate. 6 is switched so that the pool water is bypassed to the bypass passage 5 and is not circulated through the gas heater 3. In this state, the gas heater 3 is in a state where the pool water is not heated. Therefore, the gas warmer 3 does not consume the gas, and the flow rate of the gas consumed by the gas warmer 3 is subtracted from the total flow rate of the gas shown in the curve A. When the gas warmer 3 does not consume gas, as shown by the curve B, the total flow rate of the gas decreases and does not exceed the maximum flow rate.

  Thereafter, both the gas heater 3 and the gas water heater 4 consume gas, and the total flow rate does not exceed the maximum flow rate, that is, the gas consumption is below the set flow rate. When the temperature becomes lower than the set temperature, the control circuit 9 switches the switching valve 6 so that the pool water is circulated from the bypass passage 5 to the gas warmer 3. In this state, the gas heater 3 warms the pool water to the set temperature. When the pool water reaches the set temperature, the control circuit 9 switches the switching valve 6 to bypass the pool water to the bypass 5 without circulating it to the gas heater 3. In this state, the pool water is circulated through the gas warmer 3 so that the gas burner of the gas warmer 3 is not ignited, and the pool water warming is stopped.

  The gas warming device for a pool facility of the present invention maintains a warm water pool at a comfortable temperature while reducing the total flow rate of gas consumed by the gas warmer and the gas water heater to less than the maximum flow rate. Hot water can be supplied to showers, faucets, etc. to create economically comfortable pool facilities.

DESCRIPTION OF SYMBOLS 1 ... Warm water pool 2 ... Circulation path 3 ... Gas warmer 4 ... Gas water heater 41 ... 1st gas water heater 42 ... 2nd gas water heater 5 ... Bypass path 6 ... Switching valve 6A ... 1st on-off valve 6B ... 2nd on-off valve 7 ... Flow sensor 8 ... Temperature sensor 9 ... Control circuit 10 ... Shower 11 ... Faucet 12 ... Heater 13 ... Filter 14 ... Circulation pump 15 ... Heat exchanger 16 ... Heater body 17 ... Sealed case 18 ... Heat exchange pipe 19 ... In-machine pump 20 ... Ignition control temperature sensor 21 ... Gas pipe 22 ... Heat exchanger 23 for heating 23 ... Warm water tank 24 ... Warm water pipe 25 ... Sub switching valve 26 ... Sub bypass path 71 ... Heating Heater flow sensor 72 ... Hot water heater flow sensor 73 ... First hot water heater flow sensor 74 ... Second hot water heater flow sensor 75 ... Total flow sensor

Claims (7)

Gas that is connected to the pool water circulation path (2) connected to the hot water pool (1) provided in the pool facility and heats the pool water circulated through the circulation path (2) with the combustion heat of the gas A heater (3),
A bypass path (5) connected in parallel with the gas heater (3) and bypassing pool water supplied to the gas heater (3);
A switching valve (6) for switching and circulating the pool water to be circulated in the circulation path (2) to either the gas heater (3) or the bypass path (5);
A gas water heater (4) connected to a gas pipe (21) for supplying gas to the gas heater (3) and provided in a pool facility provided with the hot water pool (1),
A flow rate sensor (7) for detecting a flow rate of gas supplied to the gas warmer (3) and the gas water heater (4);
A temperature sensor (8) for detecting the temperature of the pool water of the warm water pool (1);
A control circuit for controlling the switching valve (6) by the gas flow rate supplied to the gas heater (3) and the gas water heater (4) and the pool water temperature detected by the temperature sensor (8) ( 9)
The control circuit (9) stores the set temperature of the pool water for switching the switching valve (6) and the maximum flow rate of gas,
The pool water temperature is lower than the preset temperature stored in advance, and the gas flow rate consumed by both the gas heater (3) and the gas water heater (4) is smaller than the maximum flow rate stored. In the following state, the switching valve (6) is switched to a position where the pool water circulated through the circulation path (2) is introduced into the gas heater (3), and the combustion of the gas heater (3) is performed. Heat the pool water with heat,
Furthermore, the pool water temperature is lower than the set temperature, and the gas flow rate consumed by both the gas heater (3) and the gas water heater (4) exceeds the preset flow rate that is greater than the maximum flow rate stored in advance. Then, the switching valve (6) is switched to a position for bypassing the pool water circulated through the circulation path (2) to the bypass path (5), and the pool water is heated by the gas heater (3). A gas heating device for pool facilities that is not in use.   The gas for a pool facility according to claim 1, wherein the gas water heater (4) supplies hot water to at least one of a shower (10), a faucet (11) and a heater (12) provided in the pool facility. Heating device.   The gas heating apparatus for a pool facility according to claim 1 or 2, wherein the switching valve (6) is a three-way valve.   The gas water heater (4) heats the first gas water heater (41) for supplying hot water to the shower (10) and the faucet (11) of the pool facility and the heater (12) of the pool facility. The gas heating apparatus for a pool facility according to any one of claims 1 to 3, comprising two gas water heaters (42). The flow rate sensor (7) is a heater flow rate sensor (71) for detecting a gas flow rate consumed by the gas heater (3), and a hot water supply for detecting a gas flow rate consumed by the gas water heater (4). Meter flow sensor (72),
The control circuit (9) detects the gas flow rate by adding the gas consumption flow rate detected by the heater flow rate sensor (71) and the gas consumption flow rate detected by the water heater flow rate sensor (72). Item 5. A gas heating apparatus for a pool facility according to any one of Items 1 to 4.   The control circuit (9) detects a gas flow rate consumed by the gas warmer (3) and the gas water heater (4) in a preset unit time, and switches the switching valve (6). The gas heating apparatus for a pool facility according to any one of claims 1 to 5, wherein switching is performed.   The control circuit (9) detects the gas flow rate consumed by the gas warmer (3) and the gas water heater (4) per unit time with a unit time of 1 minute or longer and within one hour, and The gas heating apparatus for a pool facility according to claim 6, wherein the switching valve is switched.

Images