JP2016014501A - Water heater - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a water heater having increased detection performance of detecting water leakage or a pressure relief valve being left open uncontrolled and capable of preventing fault detection.SOLUTION: A water heater comprises: a tank 7 storing hot water; a feed water flow sensor 18 detecting a flow volume of feed water fed into the tank 7; a feed hot water flow sensor 22 detecting a flow volume of feed hot water fed from within the tank 7 to a hot water supply location; and means for determining whether water flows from a detection result of the feed water flow sensor 18 and whether hot water flows from a detection result of the feed hot water flow sensor 22, and comparing determination results, thereby determining whether water leakage occurs or a pressure relief valve is left uncontrolled. A criterion for a case of determining that water flows to the feed water flow sensor 18 is set more moderate than a criterion for a case of determining that hot water flows to the feed hot water flow sensor 22.

Description

  Embodiments of the present invention relate to a water heater provided with means for detecting the occurrence of water leakage and the opening of a pressure relief valve.

  In recent years, a water heater provided with a heat pump unit provided with a heat exchanger and a tank for storing hot water boiled by the heat pump unit has become widespread. In such a water heater, tap water supplied from a water pipe is temporarily stored in a tank, and the tap water stored in the tank is boiled with a heat pump unit using inexpensive late-night power, It is stored back in the tank and the hot water in the tank is used when necessary.

  In such a water heater, it is necessary to detect the occurrence of water leakage from a tank or a pipe connected to the tank, and as an example of means for detecting the occurrence of water leakage, as described in Patent Document 1 below, There has been known one in which a water leakage tray is provided below the tank, and the water leakage collected in the water leakage tray is detected by a water leakage sensor.

Japanese Patent No. 4898539

  However, such means for detecting the occurrence of water leakage cannot detect the occurrence of water leakage when the location of the water leakage is a location other than above the water leakage tray, and has the ability to detect the occurrence of water leakage. It's not high enough.

  For this reason, in the water heater, it is required to improve the leakage detection performance. However, on the other hand, if the leakage detection performance is excessively obtained, it may be erroneously detected that water leakage has occurred although water leakage has not occurred.

  When it is erroneously detected that water leakage has occurred, it is necessary to call a service person for inspection each time, which is complicated.

  An object of an embodiment of the present invention is to provide a water heater capable of improving detection performance of leakage of water and leaving an open pressure relief valve and preventing erroneous detection thereof.

  The water heater of the embodiment includes a tank in which hot water is stored, a water supply flow rate sensor that detects a flow rate of water supplied to the tank, a hot water flow rate sensor that detects a flow rate of hot water supplied from the tank to the hot water supply location, It has a means for judging the flow of each hot water from the detection result of the flow rate sensor and the detection result of the hot water flow rate sensor, and comparing the results to determine the occurrence of water leakage or leaving the pressure relief valve open. The criterion for determining that water is flowing in the sensor is set to be slower than the criterion for determining that hot water is flowing in the hot water supply flow rate sensor.

1 is a system diagram of a water heater according to a first embodiment. It is a flowchart explaining the generation | occurrence | production of water leak or the determination of leaving open of a pressure relief valve, and the abnormality determination of a water supply flow sensor. It is a flowchart explaining abnormality determination of a feed water flow sensor.

  FIG. 1 is a system diagram of a heat pump type water heater 1, and the water heater 1 includes a heat pump unit 2, a tank unit 3, and a control unit 4. The control unit 4 includes a CPU, a ROM, a RAM, and the like, and controls each component of the water heater 1 and performs various determinations. Examples of the various determinations include determination of water leakage and determination of whether the pressure relief valve is left open. The heat pump unit 2 and the bathtub 5 are connected to the tank unit 3 through a pipe through which hot water (hot water or water) flows.

  The heat pump unit 2 has a refrigeration cycle device (not shown) in which a refrigerant circulates, and a condenser constituting a part of the refrigeration cycle device is provided as a heat exchanger 6. In this heat exchanger 6, heat exchange is performed between the refrigerant and hot water in a tank described later, so that the hot water is heated.

  The tank unit 3 includes a tank 7 for storing hot water, a water supply pipe 9 connected between the lower part of the tank 7 and the water pipe 8 for supplying tap water into the tank 7, an upper part of the tank 7 and a hot water supply place (for example, A hot water supply pipe 10 for supplying hot water in the tank 7 to a hot water supply place and a lower part of the tank 7 and an inlet side of the heat exchanger 6. 1 pipe 11, a second pipe 12 connected between the outlet side of the heat exchanger 6 and the upper part of the tank 7, a bathtub hot water supply pipe 13 branched from the middle of the hot water supply pipe 10 and connected to the bathtub 5, The reheating tank side pipe 15 branched from the middle of the hot water supply pipe 10 and passed through the reheating heat exchanger 14 and then connected to the tank 7, and one end connected to the bathtub 5 and reheating heat exchange After passing through the vessel 14, the other end is connected to the bathtub 5 And a tank side pipe 16. A plurality of temperature sensors 17 for detecting the temperature of the hot water in the tank 7 are attached to the tank 7 along the vertical direction. These temperature sensors 17 are connected to the control unit 4 and transmit the detected temperatures to the control unit 4.

  In the middle of the water supply pipe 9, a water supply flow rate sensor 18 and a water side pressure relief valve 19 are provided. The water supply flow rate sensor 18 detects the flow of tap water supplied to the tank 7, a detection signal is transmitted to the control unit 4, and the control unit 4 obtains the water supply flow rate by calculation from the transmitted detection signal. The water-side pressure relief valve 19 is opened to allow hot water in the tank 7 to escape from the lower portion of the tank 7.

  A hot water pressure relief valve 20, a hot water mixing valve 21, and a hot water flow rate sensor 22 are provided in the middle of the hot water supply pipe 10. The hot water pressure relief valve 20 is opened so that hot water in the tank 7 is released from the upper part of the tank 7. The hot water mixing valve 21 is a part that mixes hot water taken out from the upper part of the tank 7 with tap water supplied through the water supply pipe 9 and supplies hot water to a hot water supply place (for example, a washroom or a kitchen). The temperature of the hot water is adjusted by the opening degree of the mixing valve 21 for hot water supply. Further, the hot water mixing valve 21 is connected to the control unit 4, and the opening degree is adjusted by an instruction from the control unit 4. The hot water supply flow rate sensor 22 detects the flow of hot water supplied to the hot water supply location, a detection signal is transmitted to the control unit 4, and the control unit 4 obtains the hot water supply flow rate by calculation from the transmitted detection signal.

  In the middle of the first pipe 11, a circulation pump 23 and a water channel switching valve 24 are provided. The circulation pump 23 takes out hot water in the tank 7 from the lower part of the tank 7, sends the taken hot water through the first pipe 11, the heat exchanger 6, and the second pipe 12, It is supposed to return to the top. In this case, the water channel switching valve 24 is switched to a position for guiding the hot water taken out from the lower part of the tank 7 to the heat exchanger 6.

  A bathtub mixing valve 25, a solenoid valve 26, and a bathtub flow rate sensor 27 are provided in the bathtub hot water supply pipe 13. The bathtub mixing valve 25 is a part that mixes hot water taken out from the upper part of the tank 7 and tap water supplied via the water supply pipe 9, and the temperature of the hot water supplied to the bathtub 5 is the mixing for the bathtub. It is adjusted according to the opening degree of the valve 25. Moreover, the mixing valve 25 for bathtubs is connected to the control part 4, and opening degree adjustment is performed by the instruction | indication from the control part 4. FIG. The electromagnetic valve 26 is connected to the control unit 4 and is opened and closed by an instruction from the control unit 4. The bathtub flow rate sensor 27 detects the flow of hot water supplied to the bathtub 5, a detection signal is transmitted to the control unit 4, and the control unit 4 obtains the hot water supply flow rate by calculation from the transmitted detection signal.

  In the middle of the reheating tank side pipe 15, an intermediate mixing valve 28 and a retreat tank side pump 29 are provided. The intermediate mixing valve 28 is a part that mixes hot water taken out from the upper part of the tank 7 and hot water taken out from a part between the upper part of the tank 7 and the intermediate part in the vertical direction of the tank 7. The temperature of hot water supplied to the exchanger 14 is adjusted by the opening degree of the intermediate mixing valve 28. Further, the intermediate mixing valve 28 is connected to the control unit 4, and the opening degree is adjusted by an instruction from the control unit 4. The reheating tank side pump 29 supplies hot water taken out from the upper part of the tank 7 or hot water mixed by the intermediate mixing valve 28 to the reheating heat exchanger 14, and passes through the reheating heat exchanger 14. The hot water is returned to the tank 7.

  In the middle of the reheating tub side pipe 16, a reheating tub side pump 30 is provided. The reheating tub side pump 30 takes out hot water in the tub 5 and returns the extracted hot water to the tub 5 via the reheating heat exchanger 14. The intermediate mixing valve 28 operates also when bathing hot water or when hot water is supplied to each hot water supply place.

  Here, the control unit 4 performs determination of water leakage, determination of whether the pressure relief valves 19 and 20 are left open, and the like. These determinations are made by calculating the detection results of the respective sensors in the same manner as the determination results of whether or not hot water is determined, which is determined from the detection results of the water supply flow rate sensor 18, the hot water supply flow rate sensor 22, and the bathtub flow rate sensor 27. This is done by comparing the obtained flow rates. In this comparison, if the state where the hot water flow rate sensor 22 and the bathtub flow rate sensor 27 do not detect the flow continues for a certain period of time even though the feed water flow rate sensor 18 detects the flow, the water leakage or the pressure relief It is determined that the valves 19 and 20 are left open.

  Next, a criterion for determining that water is flowing through the feed water flow sensor 18 and a criterion for determining that hot water is flowing through the hot water flow sensor 22 will be described. The criterion for the water supply flow rate sensor 18 is set slower than the criterion for the hot water supply flow rate sensor 22. For example, when the determination that hot water is flowing through the flow rate sensors 18 and 22 is performed based on the pulse frequency count within an extremely short time (for example, 1 second) output from the flow rate sensors 18 and 22, The threshold value of the number of pulses used for the determination of the flow rate sensor 18 is set larger than the threshold number of pulses used for the determination of the hot water supply flow rate sensor 22. Thereby, even if the flow rate flowing through the flow rate sensors 18 and 22 is the same, if the flow rate is between the threshold values of the number of pulses used for both determinations, the hot water supply flow rate sensor 22 determines that hot water is being supplied. However, the water supply flow rate sensor 18 determines that water is not supplied. Moreover, the flow rate setting for determining that the water in the water supply flow rate sensor 18 is flowing may be larger than that in the hot water supply flow rate sensor 22.

  Further, the control unit 4 calculates from the detection result of the hot water flow rate sensor 22 when it is determined that the hot water flow rate sensor 18 is not supplying water and the hot water supply flow rate sensor 22 determines that hot water is being supplied as described above. When the hot water supply flow rate obtained by the above is equal to or higher than the set value and the state continues for a certain period of time, means for determining that the water supply flow rate sensor 18 is abnormal is provided.

  Furthermore, even if the hot water supply flow rate sensor 22 and the bathtub flow rate sensor 27 do not detect the hot water supply flow rate, if the amount of heat in the tank 7 decreases at a rate equal to or higher than the set value, the control unit 4 Means are provided for stopping determination of water leakage and determination of whether the pressure relief valves 19 and 20 are left open by comparing the detection result of the sensor 18 with the detection results of the hot water supply flow rate sensor 22 and the bathtub flow rate sensor 27. The determination as to whether or not the amount of heat in the tank 7 has decreased at a rate equal to or greater than the set value is made based on changes in the temperature of hot water detected by the plurality of temperature sensors 17.

  In such a configuration, when hot water is supplied to the hot water supply place or the bathtub 5, an amount of tap water corresponding to the hot water supply flow rate is supplied into the tank 7. The hot water supply flow rate to the hot water supply place and the bathtub 5 is obtained by calculation from the detection results of the hot water supply flow rate sensor 22 and the bathtub flow rate sensor 27, and the water supply flow rate into the tank 7 is obtained by calculation from the detection result of the water supply flow rate sensor 18. Accordingly, the hot water flow rate obtained by calculation from the detection results of the hot water flow rate sensor 22 and the bathtub flow rate sensor 27 and the water supply flow rate obtained by calculation from the detection result of the water supply flow rate sensor 18 are water leakage and the pressure relief valves 19 and 20 being left open. It will be equal unless it occurs.

  On the other hand, when the hot water flow rate obtained by calculation from the detection result of the hot water flow sensor 18 is larger than the hot water flow rate obtained by calculation from the detection results of the hot water flow rate sensor 22 and the bathtub flow rate sensor 27, water leakage and pressure relief valves 19 and 20 are obtained. Is determined to have been left open.

  Here, since the solenoid valve 26 performs only a simple opening / closing operation, the bathtub flow rate sensor 27 basically detects a large flow rate or does not detect the flow rate. The flow rate of hot water flowing depending on the hot water supply state at the hot water supply place may be very small. In such a case, if the determination criterion for determining that water is flowing through the feed water flow sensor 18 and the determination criterion when determining that hot water is flowing through the hot water supply flow sensor 22 are the same, Although the water supply flow rate sensor 18 determines that water is flowing based on the individual difference in the flow rate detection accuracy of the sensors 18 and 22 and the mounting accuracy of the flow rate sensors 18 and 22, the hot water supply flow rate sensor 22 is not flowing hot water. A state of determination may occur, and the control unit 4 may erroneously determine that water leakage or the pressure relief valves 19 and 20 are left open.

  Therefore, by setting the determination criterion when determining that water is flowing through the hot water supply flow rate sensor 18 more slowly than the determination criterion when determining when hot water is flowing through the hot water supply flow rate sensor 22, When the amount of hot water supplied is small and the amount of tap water supplied to the tank 7 is also small accordingly, it is determined that no hot water is flowing through the hot water flow rate sensor 22, and water flows through the water supply flow rate sensor 18. It is possible to prevent the occurrence of the determination that there is a problem. As a result, the hot water supply flow rate sensor 22 does not detect the hot water supply flow rate and the water supply flow rate sensor 18 detects the water supply flow rate, water leakage occurs, or the pressure relief valves 19 and 20 are left open. It is possible to prevent an erroneous determination that there is.

  Next, determination of occurrence of water leakage or leaving the pressure relief valves 19 and 20 open will be described with reference to FIG. Note that a fixed timer and a clear timer, which will be described later, always measure time (step S0), initialize the time when setting (reset), and determine whether each predetermined time has elapsed since that time. Is what you do.

  First, the flow of water in the feed water flow rate sensor 18 is determined (step S1).

  If the water supply flow rate sensor 18 determines that water is flowing (YES in step S1), a clear timer is set (reset) to clear the water leakage or pressure release valve 19 and 20 open determination (step). S2).

  Next, the flow of hot water in the hot water supply flow rate sensor 22 and the bathtub flow rate sensor 27 and the rate of decrease in the amount of heat in the tank are determined (step S3).

  When it is determined that hot water is flowing in at least one of the hot water supply flow sensor 22 and the bathtub flow sensor 27, or when the heat amount drop in the tank 7 exceeds the set value (NO in step S3), water leakage or A confirmation timer for confirming whether the pressure relief valves 19 and 20 are left open is set (reset) (step S6). Thereby, even if the flow of water is detected by the water supply sensor 18, hot water is used in the bathtub 5 or a hot water supply place, or the amount of heat in the tank 7 has decreased due to additional cooking described later. It is not determined that water leaks because the volume of hot water is reduced and water is supplied.

  If it is determined that hot water does not flow through the hot water supply flow sensor 22 and the bathtub flow sensor 27 and the rate of decrease in the amount of heat in the tank 7 is equal to or less than the set value (YES in step S3), the water leakage or pressure relief valves 19, 20 The remaining time of the decision timer for determining whether to leave open is monitored (step S4).

  If the time measured by the determination timer of the leakage or pressure relief valves 19 and 20 is left open (YES in step S4), the decision to leave the leakage or pressure relief valves 19 and 20 open is confirmed (step S5). .

  On the other hand, if it is determined in step S1 that water is not flowing through the feed water flow sensor 18 (NO in step S1), a confirmation timer is set (reset) for confirming whether the leakage or pressure relief valves 19 and 20 are left open. (Step S7).

  Then, the remaining time of the clear timer is monitored (step S8), and when the predetermined time has elapsed (YES in step S8), the determination of the occurrence of water leakage and the open pressure release valves 19 and 20 is cleared (step S9). ).

  After a predetermined time has elapsed since the flow of each of the flow sensors 18, 22, 27 was detected, the occurrence of water leakage or the determination of whether the pressure relief valves 19, 20 are left open or cleared can be used to more reliably prevent erroneous determination. Can be a thing.

  In addition, the predetermined time for determining whether the water leakage and the pressure relief valves 19 and 28 are left open by the confirmation timer is several minutes to several tens of minutes, and it is confirmed that the water leakage and the pressure relief valves 19 and 28 are not left open by the clear timer. The predetermined time for this is shorter than that (for example, about 5 minutes).

  Furthermore, the predetermined time for determining the leakage of the confirmation timer and leaving the pressure relief valves 19 and 28 to open is variable depending on the flow rate detected by the water supply flow rate sensor 18, so that the water leakage or pressure relief valve 19, It can be determined whether 20 is left open.

  Next, a description will be given of the control in the case of performing “chase” that raises the temperature of hot water in the bathtub 5. When the instruction of “reap” is issued from the control unit 4, the reheating tank side pump 29 and the reheating tub side pump 30 are driven.

  When the reheating tank side pump 29 is driven, the hot water in the upper part of the tank 7 or the hot water mixed in the intermediate mixing valve 28 passes through the reheating tank side pipe 15 to the reheating heat exchanger 14. After being guided through the reheating heat exchanger 14, it is returned to the tank 7. Further, when the reheating tub side pump 30 is driven, the hot water in the tub 5 is guided to the reheating heat exchanger 14 through the reheating tub side piping 16, and the reheating heat exchanger 14. After going through the inside, it is returned to the bathtub 5. Then, in the reheating heat exchanger 14, heat exchange is performed between the hot water led from the tank 7 and the hot water led from the bathtub 5, and the hot water led from the bathtub 5 is heated to increase the temperature. The hot water whose temperature has risen and the temperature has risen is returned to the bathtub 5, whereby the “hot water” of the hot water in the bathtub 5 is performed. Note that, at the time of “reaping”, hot water does not flow through the hot water supply flow rate sensor 22 and the bathtub flow rate sensor 27, and the water supply flow rate sensor 18 and the bathtub flow rate sensor 27 do not detect the flow rate.

  On the other hand, at the time of “reheating”, hot water having a high temperature is taken out from the tank 7, and the hot water whose temperature has been lowered by the heat exchanger 14 for reheating is returned to the tank 7. As a result, the temperature of the hot water in the tank 7 is lowered, and the temperature of the hot water in the tank 7 is lowered, so that the volume of the hot water in the tank 7 is lowered. Water is supplied.

  Here, the control performed by the control unit 4 when the tap water is supplied into the tank 7 as a result of “reaping” will be described with reference to FIG.

  When the reheating operation is performed and the amount of heat in the tank 7 suddenly decreases and the rate of decrease exceeds the set value, even if it is determined that the flow rate does not flow through the hot water supply flow rate sensor 22 and the bathtub flow rate sensor 27, step S3 is performed. The process proceeds to NO and sets (resets) a confirmation timer for confirming whether the water leakage or pressure relief valves 19 and 20 are left open (step S6). Whether or not the amount of heat in the tank 7 has decreased at a rate equal to or higher than the set value per unit time is determined by the control unit 4 based on changes in values detected by the plurality of temperature sensors 17.

  By doing so, the process does not proceed to the step of confirming whether the water leakage or the pressure relief valves 19 and 20 are left open. Therefore, it is determined that water is flowing through the water supply flow rate sensor 18 when the “catch-up” is performed. Even if it is determined that hot water is not flowing in the hot water supply flow sensor 22 and the bathtub flow sensor 27, it is possible to prevent erroneous determination of occurrence of water leakage or leaving the pressure relief valves 19 and 20 open.

  Next, abnormality determination of the water supply flow rate sensor 18 will be described with reference to FIG. The following description relates to the determination based on the relationship with the hot water supply flow rate sensor 22, and a determination condition having the same content and not setting the flow rate threshold value can be used for the determination based on the relationship with the bathtub flow rate sensor 27.

  First, it is determined whether hot water is flowing through the hot water supply flow rate sensor 22 (step S10).

  Next, it is determined whether water is flowing through the water supply flow rate sensor 18 (step S11).

  In the case of determination that water is not flowing, it is determined whether or not the hot water flow rate obtained by calculation from the detection result of the hot water flow rate sensor 22 is greater than or equal to a set value (step S12).

  If the hot water supply flow rate exceeds the set value (YES in step S12), it is monitored whether a predetermined timer for determining an abnormality in the water supply flow rate sensor 18 has passed a predetermined time (step S13).

  If the confirmation timer has expired (YES in step S13), the abnormality of the water supply flow rate sensor 18 is confirmed (S14).

  If it is determined that water is flowing in the feed water flow sensor 18 (NO in step S11), it is in a normal state. Therefore, a confirmation timer for confirming the abnormality of the feed water flow sensor 18 is set, and the feed water flow sensor 18 is set. If the abnormality is confirmed, the confirmation is cleared (step S15).

  FIG. 3 is a diagram in the case where the time until the abnormality of the feed water flow sensor 18 is confirmed is monitored by integration time. A step is added to set a timer for determining the abnormality.

  As described above, in the present invention, the hot water flow rate sensor 18 and the hot water flow rate sensor 22 are configured such that the hot water flow rate sensor 22 determines that the hot water is flowing first. If the hot water supply operation is performed at a flow rate between the determination thresholds that the hot water is flowing in the flow sensor 22, an erroneous determination of abnormality of the water supply flow rate sensor 18 may occur, but depending on the hot water supply flow rate in step S12 of FIG. By adding a determination, it can be avoided.

  As mentioned above, although embodiment of this invention was described, this embodiment is shown as an example and is not intending limiting the range of invention. These embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. These embodiments and their modifications are included in the scope and gist of the invention, and are also included in the invention described in the claims and the equivalents thereof.

DESCRIPTION OF SYMBOLS 1 ... Hot water supply machine, 7 ... Tank, 18 ... Feed water flow sensor, 19, 20 ... Pressure relief valve

Claims (3)

A tank for storing hot water,
A water supply flow rate sensor for detecting a water supply flow rate of water supplied into the tank;
A hot water supply flow rate sensor for detecting a flow rate of hot water supplied from the tank to a hot water supply location;
Means for determining the flow of each hot water from the detection result of the water supply flow rate sensor and the detection result of the hot water flow rate sensor, and comparing the results to determine whether water leakage has occurred or the pressure relief valve is left open. ,
A water heater according to claim 1, wherein a criterion for determining that water is flowing in the water supply flow rate sensor is set slower than a criterion for determining that hot water is flowing in the hot water flow rate sensor.   When determining that hot water is flowing through the hot water flow rate sensor and determining that water is not flowing through the hot water flow rate sensor, the hot water flow rate obtained by calculation from the detection result of the hot water flow rate sensor is a set value or more, The hot water heater according to claim 1, further comprising means for determining that the water supply flow rate sensor is abnormal when the state continues for a predetermined time. Even if the hot water supply flow sensor does not detect the hot water supply flow rate, if the amount of heat in the tank has decreased at a rate equal to or higher than a set value, the respective values obtained by calculation from the detection results of the water supply flow rate sensor and the hot water supply flow rate sensor, respectively. The hot water heater according to claim 1 or 2, further comprising means for stopping the determination of occurrence of water leakage or leaving the pressure relief valve open by comparing the flow rate of the water.