JP7182410B2 - bath equipment - Google Patents

Description

The technology disclosed in this specification relates to a bath apparatus.

Patent Document 1 discloses a heat source device that heats water, a hot water supply path that supplies the water heated by the heat source device to a bathtub, and a hot water supply path that is attached to the bathtub and supplies water from the hot water supply path to the bathtub. A bath apparatus is disclosed that includes an adapter for feeding into the interior of a bath and a controller. The adapter includes an inlet through which water flows from the hot water filling path, an outlet through which water flows out into the bathtub, and a shutoff valve capable of opening and closing a path through which water flows from the inlet to the outlet. An elastic member that biases the shutoff valve in the opening direction and a biasing mechanism that is provided near the outflow port and biases the shutoff valve in the closing direction are provided. The biasing force of the biasing mechanism changes according to the temperature of the biasing mechanism. When the temperature of the biasing mechanism is below a predetermined temperature, the biasing force of the biasing mechanism is smaller than the biasing force of the elastic member. When the temperature of the biasing mechanism is equal to or higher than the predetermined temperature, the biasing force of the biasing mechanism is greater than the biasing force of the elastic member. The control device is capable of executing a hot-water filling operation for supplying water heated by the heat source machine to the bathtub. In this bath apparatus, when water of a predetermined temperature or higher is supplied from the adapter to the bathtub during the hot-water filling operation, the temperature of the urging mechanism rises to a predetermined temperature or higher, closing the cutoff valve.

JP 2016-200332 A

When the above adapter is attached to the bathtub, when a large flow of water is supplied to the bathtub from the hot water supply path via the adapter, pressure fluctuations in the water occur inside the adapter due to turbulence. . In this case, since the temperature of the water supplied from the adapter to the bathtub is lower than the predetermined temperature, the temperature of the biasing mechanism is also lower than the predetermined temperature. An abnormal operation may occur in which the shut-off valve closes against the biasing force of the elastic member. After that, even if the hot water filling operation is resumed after the pressure fluctuation is eliminated and the shutoff valve is opened, the shutoff valve is closed again when a large flow of water is again supplied to the bathtub from the hot water filling path via the adapter. I end up repeating it. As a result, the hot water filling operation is interrupted many times, and it takes a long time until the hot water filling operation is completed. The present specification provides a technique capable of suppressing interruption of the hot water filling operation due to an abnormal operation of the adapter.

A bath apparatus disclosed in the present specification comprises a heat source machine for heating water, a hot water supply path for supplying water heated by the heat source machine to a bathtub, a hot water supply valve capable of opening and closing the hot water supply path, and a flow rate limiting means capable of limiting the flow rate of water flowing through the hot water filling path to a preset upper limit flow rate or less; a flow rate sensor detecting the flow rate of the water flowing through the hot water filling path; An adapter for sending water from the hot water supply path to the inside of the bathtub and a control device are provided. The adapter includes an inlet through which water flows from the hot water filling path, an outlet through which water flows out into the bathtub, and a shutoff valve capable of opening and closing a path through which water flows from the inlet to the outlet. An elastic member that biases the shutoff valve in the opening direction and a biasing mechanism that is provided near the outflow port and biases the shutoff valve in the closing direction are provided. The biasing force of the biasing mechanism changes according to the temperature of the biasing mechanism. When the temperature of the biasing mechanism is below a predetermined temperature, the biasing force of the biasing mechanism is smaller than the biasing force of the elastic member. When the temperature of the biasing mechanism is equal to or higher than the predetermined temperature, the biasing force of the biasing mechanism is greater than the biasing force of the elastic member. The control device is capable of executing a hot-water filling operation for supplying water heated by the heat source machine to the bathtub. The control device opens the hot water filling valve when the hot water filling operation is started. After starting the hot water filling operation, the control device closes the hot water filling valve and ends the hot water filling operation when a set amount of water is supplied to the bathtub. The control device closes the hot water filling valve to interrupt the hot water filling operation when the flow rate of water flowing through the hot water filling path falls below a predetermined flow rate during execution of the hot water filling operation, and then The hot water filling valve is opened to restart the hot water filling operation. During the execution of the hot water filling operation, the control device controls, after the hot water filling operation is interrupted, the elapsed time from when the hot water filling operation is resumed until the flow rate detected by the flow sensor becomes equal to or greater than a predetermined flow rate. is less than the predetermined time, the upper limit flow rate is reduced.

If the shutoff valve is closed due to abnormal operation of the adapter caused by a large flow of water, when the water stops flowing inside the adapter, the water pressure fluctuation caused by turbulence disappears and the adapter Abnormal operation is quickly rectified and the isolation valve is reopened. For this reason, if the elapsed time from when the hot water filling operation is restarted after the hot water filling operation is interrupted until the flow rate detected by the flow rate sensor reaches or exceeds the predetermined flow rate is less than the predetermined time, a large flow rate may occur. It is likely that the isolation valve was closed due to abnormal operation of the adapter due to water flow. In the above bath apparatus, when a large flow of water is supplied from the hot water filling path to the bathtub through the adapter during the hot water filling operation, and the shutoff valve is closed due to the abnormal operation of the adapter, the upper limit of the hot water filling operation after that is reached. Reduce flow. By adopting such a configuration, it is possible to suppress the pressure fluctuation of the water inside the adapter caused by the flow of a large amount of water, and to suppress the adapter from operating abnormally. It is possible to suppress the interruption of the hot water filling operation due to the abnormal operation of the adapter.

Another bath apparatus disclosed in this specification includes a heat source machine that heats water, a hot water supply path that supplies the water heated by the heat source machine to a bathtub, and a hot water supply valve that can open and close the hot water supply path. a flow rate limiting means capable of limiting the flow rate of the water flowing through the hot water filling path to a preset upper limit flow rate or less; a flow rate sensor detecting the flow rate of the water flowing through the hot water filling path; It comprises a temperature sensor for detecting the temperature of water, an adapter attached to the bathtub for sending water from the hot water supply path into the bathtub, and a controller. The adapter includes an inlet through which water flows from the hot water filling path, an outlet through which water flows out into the bathtub, and a shutoff valve capable of opening and closing a path through which water flows from the inlet to the outlet. An elastic member that biases the shutoff valve in the opening direction and a biasing mechanism that is provided near the outflow port and biases the shutoff valve in the closing direction are provided. The biasing force of the biasing mechanism changes according to the temperature of the biasing mechanism. When the temperature of the biasing mechanism is below a predetermined temperature, the biasing force of the biasing mechanism is smaller than the biasing force of the elastic member. When the temperature of the biasing mechanism is equal to or higher than the predetermined temperature, the biasing force of the biasing mechanism is greater than the biasing force of the elastic member. The control device is capable of executing a hot-water filling operation for supplying water heated by the heat source machine to the bathtub. The control device opens the hot water filling valve when the hot water filling operation is started. After starting the hot water filling operation, the control device closes the hot water filling valve and ends the hot water filling operation when a set amount of water is supplied to the bathtub. The control device closes the hot water filling valve to interrupt the hot water filling operation when the flow rate of water flowing through the hot water filling path falls below a predetermined flow rate during execution of the hot water filling operation, and then The hot water filling valve is opened to restart the hot water filling operation. The control device interrupts the hot water filling operation during execution of the hot water filling operation, and if the temperature detected by the temperature sensor at the time when the hot water filling operation is interrupted is less than the predetermined temperature, reducing the upper limit flow rate;

If the shutoff valve is closed while the temperature of the water supplied from the hot water supply path to the adapter is above a predetermined temperature, the adapter is considered to be operating normally. If the cutoff valve is closed while the temperature of the supplied water is lower than the predetermined temperature, it is considered that the adapter is operating abnormally. Therefore, if the hot water filling operation is interrupted during execution of the hot water filling operation and the temperature detected by the temperature sensor at the time when the hot water filling operation is interrupted is less than the predetermined temperature, a large amount of water flows. It is highly probable that the shutoff valve was closed due to the abnormal operation of the adapter caused by this. In the above bath apparatus, when a large flow of water is supplied from the hot water filling path to the bathtub through the adapter during the hot water filling operation, and the shutoff valve is closed due to the abnormal operation of the adapter, the upper limit of the hot water filling operation after that is reached. Reduce flow. By adopting such a configuration, it is possible to suppress the pressure fluctuation of the water inside the adapter caused by the flow of a large amount of water, and to suppress the adapter from operating abnormally. It is possible to suppress the interruption of the hot water filling operation due to the abnormal operation of the adapter.

1 schematically shows the configuration of a bath water heater 2 according to an embodiment. Fig. 3 is a cross-sectional view showing the configuration of an adapter 32 of the bath water heater 2 according to the embodiment; 4 is a flowchart showing an example of processing executed by the control device 46 of the bath water heater 2 according to the embodiment; 4 is a flowchart showing an example of processing executed by the control device 46 of the bath water heater 2 according to the embodiment;

(Example)
As shown in FIG. 1, the bath water heater 2 of this embodiment heats low-temperature water supplied from a tap water supply 4, and supplies hot water to a bathtub 6 or a faucet 8 (for example, a shower or a faucet). supply.

An upstream end of the water supply route 10 is connected to the water supply 4 . A flow rate sensor 12 is provided in the water supply path 10 . The flow rate sensor 12 detects the flow rate of water flowing through the water supply path 10 . The upstream end of the heating path 14 and the upstream end of the first bypass path 16 are connected to the downstream end of the water supply path 10 .

A heat source device 18 is interposed in the heating path 14 . The heat source device 18 is, for example, a combustion heat source device that heats water with combustion heat obtained by burning fuel such as city gas. The downstream end of heating path 14 is connected to the upstream end of hot water supply path 20 .

A first bypass solenoid valve 22 is provided in the first bypass path 16 . The first bypass solenoid valve 22 opens and closes the first bypass path 16 . A downstream end of the first bypass route 16 is connected to an upstream end of the hot water supply route 20 . In the bath water heater 2 of this embodiment, the flow rate of water flowing from the water supply path 10 to the heating path 14 and the first bypass path 16 and the flow rate of water flowing from the heating path 14 and the first bypass path 16 to the hot water supply path 20 are equal. Therefore, the flow rate of water flowing through hot water supply path 20 matches the flow rate of water detected by flow sensor 12 .

The hot water supply path 20 is provided with a hot water outlet thermistor 24 and a hot water outlet servo valve 26 . Hot water thermistor 24 detects the temperature of water flowing through hot water supply path 20 . Hot water supply servo valve 26 controls the flow rate of water flowing through hot water supply path 20 by adjusting the degree of opening of hot water supply path 20 . The upstream end of the first hot water outlet path 28 and the upstream end of the second hot water outlet path 30 are connected to the downstream end of the hot water supply path 20 .

A downstream end of the first hot water outlet path 28 is connected to an adapter 32 provided inside the bathtub 6 . Water flowing through first hot water outlet path 28 is supplied to bathtub 6 via adapter 32 . A hot water filling solenoid valve 34 and a first check valve 36 are provided in the first hot water outlet path 28 . The hot water filling solenoid valve 34 opens and closes the first hot water outlet path 28 . The first check valve 36 prevents reverse flow of water in the first hot water outlet path 28 .

A downstream end of the second hot water outlet path 30 is connected to the faucet 8 . Water flowing through the second hot water outlet path 30 is supplied to the faucet 8 . A second check valve 38 is provided in the second hot water outlet path 30 . The second check valve 38 prevents reverse flow of water in the second hot water outlet path 30 .

The downstream side of the second hot water outlet path 30 from the second check valve 38 and the upstream side of the water supply path 10 from the flow rate sensor 12 are connected via a second bypass path 40 . A second bypass solenoid valve 42 and a water flow switch 44 are provided in the second bypass path 40 . The second bypass electromagnetic valve 42 opens and closes the second bypass path 40 . The water flow switch 44 detects the presence or absence of water flow in the second bypass route 40 .

The controller 46 receives detection signals from the flow rate sensor 12 , hot water outlet thermistor 24 and water flow switch 44 . The control device 46 transmits control signals to the heat source machine 18, the first bypass solenoid valve 22, the hot water supply servo valve 26, the hot water filling solenoid valve 34, and the second bypass solenoid valve 42 to control their operations.

The control device 46 normally opens the first bypass solenoid valve 22 . In this case, part of the water flowing through the water supply path 10 is sent to the hot water supply path 20 via the heating path 14 and the rest is sent to the hot water supply path 20 via the first bypass path 16 . Therefore, when water is heated by the heating path 14, in the hot water supply path 20, the high temperature water from the heating path 14 and the low temperature water from the first bypass path 16 are mixed to adjust the temperature of the water. is sent to the first hot water outlet path 28 and the second hot water outlet path 30 . Note that the control device 46 closes the first bypass solenoid valve 22 when supplying hot water of a predetermined temperature (for example, 60° C.) or higher to the bathtub 6 or the faucet 8 . In this case, the entire amount of water flowing through water supply path 10 is sent to hot water supply path 20 via heating path 14 . Therefore, the hot water supply path 20 is supplied with the high temperature water from the heating path 14 as it is, and the high temperature water is sent to the first hot water outlet path 28 and the second hot water outlet path 30 .

The control device 46 normally closes the second bypass solenoid valve 42, and opens the second bypass solenoid valve 42 when performing a hot water filling operation, which will be described later. In this case, when the faucet 8 is opened during execution of the hot water filling operation, a water flow is generated in the second bypass path 40 and the water flow switch 44 is turned on. When the water flow switch 44 is turned on during the hot water filling operation, the control device 46 gives priority to the supply of water to the faucet 8, closes the hot water filling solenoid valve 34, and interrupts the hot water filling operation. 2 Bypass solenoid valve 42 is closed.

FIG. 2 shows the internal structure of the adapter 32. As shown in FIG. The adapter 32 is entirely covered by a dome-shaped casing 48 . A plurality of outflow ports 50 are formed in the lower side surface of the casing 48 . Inside the casing 48, there are provided an inlet 52 to which water is supplied from the first hot water discharge path 28, a nozzle 54 for sending the water supplied from the inlet 52 to the outlet 50, and an upstream side of the nozzle 54 that can be opened and closed. A shut-off valve 56, a compression spring 58 that biases the shut-off valve 56 in the opening direction, and a temperature sensing spring 60 that biases the shut-off valve 56 in the closing direction are provided.

The temperature sensitive spring 60 is, for example, a shape memory alloy spring. The temperature-sensing spring 60 is configured such that when the temperature is low, the force to close the shutoff valve 56 is weak, and when the temperature is high, the force to close the shutoff valve 56 is strong. In the adapter 32, when the temperature of the temperature-sensitive spring 60 is lower than a predetermined temperature (for example, 60° C.), the biasing force of the compression spring 58 is stronger than the biasing force of the temperature-sensitive spring 60, and the cutoff valve 56 is opened. . When the temperature of the temperature-sensitive spring 60 reaches or exceeds a predetermined temperature (for example, 60° C.), the biasing force of the temperature-sensitive spring 60 becomes stronger than the biasing force of the compression spring 58, and the cutoff valve 56 is closed. Thus, the shutoff valve 56 of the adapter 32 automatically opens and closes according to the temperature of the temperature sensitive spring 60 .

In the bath apparatus 32 having such an adapter 32, when water is supplied to the bathtub 6 by executing the hot water filling operation, if the temperature of the supplied water is higher than a predetermined temperature, the temperature of the water in the bathtub 6 is raised, for example. When the hot water is added to the bathtub 6, if the water level in the bathtub 6 is higher than the water level covering the adapter 32, the temperature of the temperature sensing spring 60 does not rise to a predetermined temperature or higher, so the shutoff valve 56 is closed. do not have. On the other hand, when there is no water in the bathtub 6, the water sent from the nozzle 54 to the outflow port 50 rebounds on the inner surface of the casing 48 or the like and contacts the temperature sensing spring 60, so that the temperature of the temperature sensing spring 60 rises to a predetermined value. When the temperature rises above the temperature, the cutoff valve 56 is closed and the supply of high temperature water into the bathtub 6 is stopped. As a result, it is possible to prevent the water in the bathtub 6 from reaching a predetermined temperature or higher, thereby ensuring the safety of the user.

In the adapter 32 configured as described above, when the flow rate of water supplied to the adapter 32 is large (for example, 23 L/min or more), turbulent flow occurs inside the adapter 32, and the temperature of the temperature sensing spring 60 rises. Despite being low, pressure fluctuations in the water can cause the isolation valve 56 to close. If such a malfunction of the shutoff valve 56 occurs, hot water is not supplied to the adapter 32 and there is no safety problem, but the hot water filling operation is interrupted, resulting in a loss of convenience. I will lose. Therefore, in the bath hot water supply apparatus 2 of this embodiment, when a malfunction occurs in the cutoff valve 56, the water supplied to the adapter 32 is controlled so as not to cause a similar malfunction in the subsequent hot water filling operation. Reduce flow.

3 and 4 show the processing performed by the control device 46 during the hot water filling operation of the bath water heater 2 of this embodiment.

At S<b>2 , the controller 46 opens the hot water filling solenoid valve 34 . When the hot water filling solenoid valve 34 is opened, the control device 46 controls the flow rate of the water flowing through the hot water supply path 20 until the hot water filling solenoid valve 34 is closed after that, so that the flow rate of the water flowing through the hot water supply path 20 is equal to or less than the preset maximum hot water filling flow rate Wmax. It controls the hot water supply servo valve 26 . Initially, the hot water filling maximum flow rate Wmax is set to, for example, 24 L/min.

In S4, the control device 46 determines whether or not the flow rate W detected by the flow rate sensor 12 is equal to or greater than a predetermined amount of ignition water (eg, 3 L/min). If the flow rate W is less than the ignition water amount (NO), the process proceeds to S6.

In S6, the control device 46 determines whether or not a predetermined time (for example, 60 seconds) has elapsed since the hot water filling solenoid valve 34 was opened in S2. If the predetermined time has not elapsed (NO), the process returns to S4. If the predetermined time has passed (if YES), the process proceeds to S8.

In S<b>8 , the controller 46 closes the hot water filling solenoid valve 34 .

In S10, the controller 46 notifies the user of the error and terminates the hot water filling operation.

If the flow rate W is greater than or equal to the ignition water amount in S4 (YES), the process proceeds to S12. In S<b>12 , the control device 46 starts combustion in the heat source device 18 and starts heating water by the heat source device 18 .

In S14, the control device 46 determines whether or not the flow rate W detected by the flow rate sensor 12 is equal to or less than a predetermined amount of fire extinguishing water (for example, 2 L/min). If the flow rate W exceeds the fire extinguishing water amount (NO), the process proceeds to S16.

In S16, the control device 46 determines whether or not the total amount of water supplied to the bathtub 6 after the start of the hot water filling operation (also referred to as total hot water filling amount) is equal to or greater than a predetermined hot water filling set amount (for example, 200 L). to decide. The total hot water filling amount can be obtained, for example, by integrating the flow rate of water detected by the flow sensor 12 from the start of the hot water filling operation. If the total hot water filling amount is less than the hot water filling set amount (in the case of NO), the process returns to S14. If the total hot water filling amount is greater than or equal to the hot water filling set amount (if YES), the process proceeds to S18.

At S<b>18 , the controller 46 closes the hot water filling solenoid valve 34 .

In S<b>20 , the control device 46 stops combustion in the heat source device 18 and stops heating water by the heat source device 18 . After S20, the hot water filling operation ends.

If the flow rate W is equal to or less than the amount of fire extinguishing water in S14 (in the case of YES), the process proceeds to S22. At S<b>22 , the controller 46 closes the hot water filling solenoid valve 34 .

In S<b>24 , the control device 46 stops combustion in the heat source device 18 and stops heating water by the heat source device 18 .

In S26 of FIG. 4, the control device 46 determines whether or not the outlet heated water temperature Th detected by the outlet heated water thermistor 24 is lower than a predetermined temperature (for example, 60° C.). If the outlet hot water temperature Th is equal to or higher than the predetermined temperature (NO), the process returns to S2. If the outlet heated water temperature Th is lower than the predetermined temperature (if YES), the process proceeds to S28.

In S28, the control device 46 determines whether or not the elapsed time T1 after opening the hot water filling solenoid valve 34 in S2 is less than a first predetermined time (for example, 30 seconds). If the elapsed time T1 is equal to or longer than the first predetermined time (NO), the process returns to S2. If the elapsed time T1 is less than the first predetermined time (YES), the process proceeds to S30.

In S<b>30 , the controller 46 opens the hot water filling solenoid valve 34 .

In S32, the control device 46 determines whether or not the flow rate W detected by the flow rate sensor 12 is equal to or greater than a predetermined amount of ignition water. If the flow rate W is less than the ignition water amount (NO), the process proceeds to S34.

In S34, the control device 46 determines whether or not a predetermined time has passed since the hot water filling solenoid valve 34 was opened in S30. If the predetermined time has not elapsed (NO), the process returns to S32. If the predetermined time has passed (YES), the process proceeds to S36.

In S<b>36 , the controller 46 closes the hot water filling solenoid valve 34 .

At S38, the controller 46 notifies the user of the error and terminates the hot water filling operation.

If the flow rate W is greater than or equal to the ignition water amount in S32 (YES), the process proceeds to S40. In S<b>40 , the control device 46 starts combustion in the heat source device 18 and starts heating water by the heat source device 18 .

In S42, the control device 46 determines whether or not the elapsed time T2 after opening the hot water filling solenoid valve 34 in S30 is less than a second predetermined time (for example, 5 seconds). If the elapsed time T2 is equal to or longer than the second predetermined time (NO), the process returns to S14. If the elapsed time T2 is less than the second predetermined time (YES), the process proceeds to S44.

In S44, the controller 46 increments the count N by one.

In S46, the control device 46 determines whether or not the count N is equal to or greater than a predetermined number of times (eg, 3 times). If the count N is less than the predetermined number (NO), the process returns to S14. If the count N is greater than or equal to the predetermined number of times (YES), the process proceeds to S48.

In S48, the controller 46 reduces the maximum hot water filling flow rate Wmax by a predetermined flow rate width (for example, 1 L/min). After S48, the process returns to S14.

When the process returns from S42, S46, S48 to S14, in S28, the elapsed time from opening the hot water filling solenoid valve 34 in S30 is T1, and the elapsed time T1 is less than the first predetermined time. or not.

According to the processes of FIGS. 3 and 4, before the hot water filling operation ends, the flow rate W becomes equal to or less than the amount of fire extinguishing water (YES in S14), the hot water filling solenoid valve 34 is closed (S22), and the heat source machine 18 is closed. When the heating of water by has stopped (S24), the count N is increased when all of the following conditions (1) to (3) are satisfied.
(1) When the flow rate W detected by the flow sensor 12 becomes equal to or less than the fire extinguishing water amount, the hot water filling solenoid valve 34 is closed, the heating of the water by the heat source device 18 is stopped, and the hot water filling operation is interrupted. The outlet hot water temperature Th detected by the thermistor 24 is lower than the predetermined temperature (YES in S26).
(2) When the flow rate W detected by the flow rate sensor 12 becomes equal to or less than the amount of fire extinguishing water, the hot water filling solenoid valve 34 is closed, the heating of the water by the heat source device 18 is stopped, and the hot water filling operation is interrupted. The elapsed time T1 from when the electromagnetic valve 34 is opened until the hot water filling operation is interrupted is less than the first predetermined time (YES in S28).
(3) When the flow rate W detected by the flow rate sensor 12 becomes equal to or less than the amount of fire extinguishing water, the hot water filling solenoid valve 34 is closed, the heating of the water by the heat source device 18 is stopped, and the hot water filling operation is interrupted, and then hot water is filled again. When the solenoid valve 34 is opened and water heating by the heat source device 18 is started, the elapsed time T2 from when the hot water filling solenoid valve 34 is opened again until the flow rate W detected by the flow rate sensor 12 becomes equal to or greater than the ignition water quantity. is less than the second predetermined time (YES in S42).

If the above condition (1) is not satisfied, it is considered that the shutoff valve 56 is closed because the adapter 32 is supplied with water having a temperature equal to or higher than the predetermined temperature. In this case, the adapter 32 is operating normally, and it is unlikely that the adapter 32 malfunctioned due to the large flow rate of water being supplied.

If the above condition (2) is not satisfied, after a certain amount of time has passed since the start of the hot water filling operation, the flow rate W is less than or equal to the fire extinguishing water amount due to, for example, a water outage or water supply to another faucet. As a result, it is thought that the hot water filling operation was interrupted. If a large flow rate of water is supplied to the adapter 32 and the cutoff valve 56 is closed, it is considered that the cutoff valve 56 closes immediately after the hot water filling operation is started and the hot water filling operation is interrupted. Therefore, in this case as well, it is unlikely that the adapter 32 malfunctioned due to the supply of a large amount of water.

If the above condition (3) is not satisfied, it is considered that the hot water filling operation was interrupted and the flow rate W became equal to or greater than the ignition water quantity after a certain amount of time had passed since the hot water filling operation was resumed. In this case as well, it is considered that the flow rate W fell below the amount of fire extinguishing water due to a water outage or water supply to other faucets, and the hot water filling operation was interrupted. Therefore, in this case as well, it is unlikely that the adapter 32 malfunctioned due to the supply of a large amount of water.

If all of the above conditions (1) to (3) are satisfied, it is considered that shutoff valve 56 was closed due to malfunction of adapter 32 due to the supply of a large flow of water. In the processes of FIGS. 3 and 4, when an event that satisfies all of the conditions (1) to (3) occurs a predetermined number of times (YES in S46), the maximum hot water filling flow rate Wmax is set lower than the previous set value. value. As a result, it is possible to suppress malfunction of the adapter 32 due to a large flow of water being supplied in the subsequent hot water filling operation.

It should be noted that, in the case of a simpler determination, the control device 46 does not need to determine all of the above conditions (1) to (3). The process of S48 may be executed when the number of times that any one or two of the conditions is satisfied reaches a predetermined number of times.

Regarding the above condition (3), when the flow rate W detected by the flow rate sensor 12 is equal to or greater than the ignition water amount, it is determined that the hot water filling operation has been restarted. Even if not, it may be determined that the hot water filling operation has been restarted when the flow rate (for example, 2 L/min to 10 L/min) at which it can be determined that the hot water filling operation has been restarted is reached.

As described above, the bath hot water supply apparatus 2 (an example of a bath apparatus) of this embodiment includes the heat source device 18 that heats water, the hot water supply path 20 that supplies the water heated by the heat source device 18 to the bathtub 6, and the first It is equipped with a hot water outlet path 28 (an example of a hot water filling path), an adapter 32 attached to the bathtub 6 for sending water from the first hot water outlet path 28 into the bathtub 6, and a control device 46. The adapter 32 can open and close an inlet 52 through which water flows from the first hot water outlet path 28, an outlet 50 through which water flows out into the bathtub 6, and a path through which water flows from the inlet 52 to the outlet 50. A valve 56, a compression spring 58 (an example of an elastic member) that biases the shutoff valve 56 in the opening direction, and a temperature sensing spring 60 that is provided near the outflow port 50 and biases the shutoff valve 56 in the closing direction. (example of biasing mechanism). The biasing force of the temperature-sensitive spring 60 changes according to the temperature of the temperature-sensitive spring 60 . When the temperature of the temperature-sensitive spring 60 is lower than the predetermined temperature, the biasing force of the temperature-sensitive spring 60 becomes smaller than the biasing force of the compression spring 58 . When the temperature of the temperature-sensitive spring 60 is equal to or higher than the predetermined temperature, the biasing force of the temperature-sensitive spring 60 is greater than the biasing force of the compression spring 58 . The control device 46 can perform a hot water filling operation in which the water heated by the heat source device 18 is supplied to the bathtub 6 at a flow rate equal to or lower than a preset maximum hot water filling flow rate Wmax (an example of the upper limit flow rate). When the control device 46 determines that the cutoff valve 56 is closed due to the abnormal operation of the adapter 32 during the hot water filling operation, the control device 46 reduces the hot water filling maximum flow rate Wmax.

In the bath water heater 2 described above, when a large flow of water is supplied from the first hot water outlet path 28 to the bathtub 6 through the adapter 32 during the hot water filling operation, and the shutoff valve 56 is closed due to the abnormal operation of the adapter 32, , to reduce the maximum hot water filling flow rate Wmax in the subsequent hot water filling operation. By adopting such a configuration, it is possible to suppress the pressure fluctuation of the water inside the adapter 32 caused by the flow of a large amount of water, and to suppress the adapter 32 from operating abnormally. It is possible to suppress interruption of the hot water filling operation due to an abnormal operation of the adapter 32. - 特許庁

The bath water heater 2 described above further includes a flow rate sensor 12 that detects the flow rate of water flowing through the hot water supply path 20 . The control device 46 interrupts the hot water filling operation during execution of the hot water filling operation, and then restarts the hot water filling operation. If the elapsed time T2 until is less than the second predetermined time (an example of the predetermined time), it is determined that the shutoff valve 56 has been closed due to the abnormal operation of the adapter 32 .

If the shut-off valve 56 is closed due to abnormal operation of the adapter 32 caused by a large flow of water, the water pressure fluctuation caused by the turbulent flow disappears when the water stops flowing inside the adapter 32. , the abnormal operation of the adapter 32 is quickly resolved and the isolation valve 56 is opened again. Therefore, if the elapsed time T2 from when the hot water filling operation is restarted after the hot water filling operation is interrupted until the flow rate detected by the flow sensor 12 becomes equal to or greater than the ignition water quantity is less than the second predetermined time. , it is highly probable that the shut-off valve 56 was closed due to abnormal operation of the adapter 32 caused by a large flow of water. According to the above configuration, it is possible to appropriately determine whether or not the shutoff valve 56 has been closed due to the abnormal operation of the adapter 32 .

The bath water heater 2 described above further includes a hot water outlet thermistor 24 (an example of a temperature sensor) that detects the temperature of water flowing through the hot water supply path 20 . The control device 46 interrupts the hot water filling operation during execution of the hot water filling operation, and if the temperature detected by the hot water discharge thermistor 24 at the time when the hot water filling operation is interrupted is less than a predetermined temperature, the adapter 32 is abnormal. It is determined that the shut-off valve 56 is closed by such operation.

When the temperature of the water supplied to the adapter 32 from the first hot water outlet path 28 is equal to or higher than the predetermined temperature and the cutoff valve 56 is closed, it is considered that the adapter 32 is operating normally. If the shut-off valve 56 is closed while the temperature of the water supplied to the adapter 32 from the hot water supply path 28 is below the predetermined temperature, the adapter 32 is considered to be operating abnormally. Therefore, if the hot water filling operation is interrupted during execution of the hot water filling operation and the temperature detected by the hot water discharge thermistor 24 at the time when the hot water filling operation is interrupted is less than the predetermined temperature, a large flow rate of water will be supplied. It is likely that the shutoff valve 56 was closed due to abnormal operation of the adapter 32 due to flow. According to the above configuration, it is possible to appropriately determine whether or not the shutoff valve 56 has been closed due to the abnormal operation of the adapter 32 .

In the above embodiment, the case where the heat source device 18 is a combustion heat source device that heats water with the combustion heat of burning fuel has been described, but the heat source device 18 may be a heat pump, an electric heater, or another method. It may be a heat source machine that heats water.

In the above embodiment, the configuration in which the biasing mechanism of the adapter 32 is the temperature-sensitive spring 60 made of shape memory alloy has been described. Unlike this, the urging mechanism of the adapter 32 includes, for example, a temperature sensor that detects the water temperature of the outflow port 50 and an actuator that urges the shutoff valve 56 in the closing direction according to the temperature detected by the temperature sensor. may be Also in this case, when the water temperature at the outlet 50 is lower than a predetermined temperature (eg, 60° C.), the biasing force of the actuator is weaker than the biasing force of the compression spring 58, and the water temperature at the outlet 50 is lower than the predetermined temperature (eg, 60° C.). ), by controlling the operation of the actuator so that the biasing force of the actuator becomes stronger than the biasing force of the compression spring 58, the cutoff valve 56 of the adapter 32 is automatically closed according to the water temperature of the outlet 50. Can be opened and closed.

In the above embodiment, adapter 32 may be provided with a mechanism for detecting whether isolation valve 56 is open or closed. In this case, in the hot water filling operation, if the detected temperature Th of the hot water supply thermistor 24 at the time when it is detected that the shutoff valve 56 is closed is less than the predetermined temperature, the adapter 32 abnormally operates to close the shutoff valve. 56 may be determined to be closed, and the hot water filling maximum flow rate Wmax may be reduced.

In the above embodiment, the start and end times of the elapsed time T1 used in the determination of S28 and the start and end times of the elapsed time T2 used in the determination of S42 can be various timings. The starting time of the elapsed time T1 may be, for example, the time when the flow rate W becomes equal to or greater than the ignition water quantity (YES) in S4. The end point of the elapsed time T1 may be any point at which it can be determined that the hot water filling operation has been interrupted. It may be the time when beam electromagnetic valve 34 is closed. The starting time point of the elapsed time T2 may be, for example, the time point when the flow rate W becomes equal to or greater than the ignition water amount (YES) in S32.

Although specific examples of the present invention have been described in detail above, these are merely examples and do not limit the scope of the claims. The technology described in the claims includes various modifications and changes of the specific examples illustrated above. In addition, the technical elements described in this specification or the drawings exhibit technical usefulness alone or in various combinations, and are not limited to the combinations described in the claims as of the filing. In addition, the techniques exemplified in this specification or drawings achieve multiple purposes at the same time, and achieving one of them has technical utility in itself.

2: Bath water heater 4: Water supply 6: Bathtub 8: Faucet 10: Water supply path 12: Flow rate sensor 14: Heating path 16: First bypass path 18: Heat source device 20: Hot water supply path 22: First bypass solenoid valve 24: hot water outlet thermistor 26: hot water outlet servo valve 28: first hot water outlet path 30: second hot water outlet path 32: adapter 34: hot water filling solenoid valve 36: first check valve 38: second check valve 40: second bypass path 42: Second bypass solenoid valve 44 : Water flow switch 46 : Controller 48 : Casing 50 : Outlet 52 : Inlet 54 : Nozzle 56 : Shutoff valve 58 : Compression spring 60 : Temperature sensitive spring

Claims (2)

a heat source machine for heating water;
a hot water supply path for supplying the water heated by the heat source machine to the bathtub;
a hot water filling valve capable of opening and closing the hot water filling path;
a flow rate limiting means capable of limiting the flow rate of water flowing through the hot water filling path to a preset upper limit flow rate or less;
a flow rate sensor for detecting the flow rate of water flowing through the hot water filling path;
an adapter attached to the bathtub for sending water from the hot water supply path to the inside of the bathtub;
equipped with a controller,
The adapter is
an inflow port into which water flows from the hot water filling path;
an outlet through which water flows out into the bathtub;
a shutoff valve capable of opening and closing a path through which water flows from the inflow port to the outflow port;
an elastic member that biases the shutoff valve in a direction to open it;
A biasing mechanism is provided near the outflow port and biases the shutoff valve in a closing direction,
The biasing force of the biasing mechanism changes according to the temperature of the biasing mechanism,
when the temperature of the biasing mechanism is below a predetermined temperature, the biasing force of the biasing mechanism becomes smaller than the biasing force of the elastic member;
when the temperature of the biasing mechanism is equal to or higher than the predetermined temperature, the biasing force of the biasing mechanism becomes larger than the biasing force of the elastic member;
The control device is capable of executing a hot-water filling operation for supplying water heated by the heat source machine to the bathtub,
When the hot water filling operation is started, the control device opens the hot water filling valve,
After starting the hot water filling operation, when a set amount of water is supplied to the bathtub, the control device closes the hot water filling valve to end the hot water filling operation,
The control device closes the hot water filling valve to interrupt the hot water filling operation when the flow rate of water flowing through the hot water filling path falls below a predetermined flow rate during execution of the hot water filling operation, and then opening the hot water filling valve to restart the hot water filling operation;
During the execution of the hot water filling operation, the control device controls, after the hot water filling operation is interrupted, the elapsed time from when the hot water filling operation is resumed until the flow rate detected by the flow sensor becomes equal to or greater than a predetermined flow rate. is less than a predetermined time, the bath apparatus reduces the upper limit flow rate. a heat source machine for heating water;
a hot water supply path for supplying the water heated by the heat source machine to the bathtub;
a hot water filling valve capable of opening and closing the hot water filling path;
a flow rate limiting means capable of limiting the flow rate of water flowing through the hot water filling path to a preset upper limit flow rate or less;
a flow rate sensor for detecting the flow rate of water flowing through the hot water filling path;
a temperature sensor that detects the temperature of water flowing through the hot water filling path;
an adapter attached to the bathtub for sending water from the hot water supply path to the inside of the bathtub;
equipped with a controller,
The adapter is
an inflow port into which water flows from the hot water filling path;
an outlet through which water flows out into the bathtub;
a shutoff valve capable of opening and closing a path through which water flows from the inflow port to the outflow port;
an elastic member that biases the shutoff valve in a direction to open it;
A biasing mechanism is provided near the outflow port and biases the shutoff valve in a closing direction,
The biasing force of the biasing mechanism changes according to the temperature of the biasing mechanism,
when the temperature of the biasing mechanism is below a predetermined temperature, the biasing force of the biasing mechanism becomes smaller than the biasing force of the elastic member;
when the temperature of the biasing mechanism is equal to or higher than the predetermined temperature, the biasing force of the biasing mechanism becomes larger than the biasing force of the elastic member;
The control device is capable of executing a hot-water filling operation for supplying water heated by the heat source machine to the bathtub,
When the hot water filling operation is started, the control device opens the hot water filling valve,
After starting the hot water filling operation, when a set amount of water is supplied to the bathtub, the control device closes the hot water filling valve to end the hot water filling operation,
The control device closes the hot water filling valve to interrupt the hot water filling operation when the flow rate of water flowing through the hot water filling path falls below a predetermined flow rate during execution of the hot water filling operation, and then opening the hot water filling valve to restart the hot water filling operation;
The control device interrupts the hot water filling operation during execution of the hot water filling operation, and if the temperature detected by the temperature sensor at the time when the hot water filling operation is interrupted is less than the predetermined temperature, A bath apparatus that reduces the upper limit flow rate .

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