JP3384855B2 - Hot water heater and its hot water temperature control method - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a bypass mixing type hot water supply apparatus and a method for controlling the temperature of the discharged hot water.

[0002]

2. Description of the Related Art FIG. 10 is a schematic view showing an example of a bypass mixing type water heater. In the figure,
The burner 7, which is a combustion heating mechanism, and the heat exchanger 2 are provided in the combustion unit case 24 and housed in the instrument case 1. A gas nozzle 6 is arranged to face the gas inlet of the burner 7, and the gas nozzle 6 A proportional valve 8 that controls the gas supply amount by the valve opening amount and a solenoid valve 10 that opens and closes the pipe line are provided in the communicating gas pipe 14, and a combustion fan 13 is provided below the burner 7. It is provided.

A water supply pipe 3 functioning as a water inlet is connected to the inlet side of the heat exchanger 2, and the inlet side of the water supply pipe 3 is connected to a water supply source such as tap water via a flow sensor 9 such as a flow sensor. The flow rate sensor 9 detects the amount of water sent from the water supply source such as tap water to the heat exchanger 2 side through the water supply pipe 3. Further, the heat exchanger 2 is connected to the water supply pipe 3 through the water supply pipe 3 from the water supply source.
An incoming water temperature sensor 18 such as a thermistor that detects the temperature of the incoming water is provided.

A hot water supply pipe 11 functioning as a hot water discharge passage is connected to the outlet side of the heat exchanger 2, and the hot water supply pipe 11 is provided with a hot water discharge temperature sensor 16 such as a thermistor for detecting the hot water discharge temperature. The tip side of the hot water supply pipe 11 is a desired hot water supply location,
In this figure, piping is provided on the sink 43, and the hot water tap 12 is attached at a piping position near the sink.

Further, a bypass flow passage 44 which communicates with the water supply pipe 3 and the hot water supply pipe 11 and bypasses the heat exchanger 2 is arranged in parallel with the heat exchanger 2, and the inlet side of the bypass flow passage 44 is supplied with water. It is connected to the pipe 3 side, and the outlet end is connected to the hot water supply pipe 11 by a mixing section 19.

A controller 20 for controlling heating of the heat exchanger 2 is provided in the water heater, and the controller 20 is provided with an arithmetic circuit (not shown). Further, the controller 20 includes the water temperature sensor 18 and the flow rate sensor 9
Each of the detection signals of the hot water temperature sensor 16 is added, and a remote controller 21 having a temperature setting unit and the like is connected to the control device 20. The control device 20 controls the detection signals from the remote controller 21. Upon receiving a signal such as the set temperature,
Combustion operation of the water heater. That is, the control device 2
No. 0 is the combustion fan 1 when the hot water tap 12 is opened and the flow rate sensor 9 detects an amount of feed water that is greater than or equal to the amount of working water.
3 is rotated, it is confirmed that the rotation speed of the combustion fan 13 is in the stable rotation region, the solenoid valve 10 and the proportional valve 8 are opened, and the burner 7 is ignited.

When the burner 7 is ignited and ignited as described above and burner combustion is performed, the water passing through the heat exchanger 2 is heated to hot water, and the hot water is supplied to the hot water supply pipe 11
When the hot water reaches the mixing portion 19, the water from the bypass passage 44 is mixed and mixed (mixed) with the hot water from the heat exchanger 2 side. Hot water having a working temperature is created, and the hot water is discharged into the sink 43 for use.

Immediately after the burner 7 is ignited, the control device 20 performs feedforward control (a control method in which combustion is performed according to a preset gas amount supply pattern without detecting the discharge hot water temperature sensor 16). After that, feedback control is performed by PID calculation or the like by the arithmetic circuit (the hot water temperature sensor 16 detects the hot water temperature, and the PID calculation is performed so that the hot water temperature approaches the set temperature, that is, the proportional valve 8 is opened. The method of controlling the valve amount) is performed.

[0009]

FIG . 8 shows the hot water supply and combustion operation.
Changes in the hot water temperature, amount of hot water, and set temperature
As shown in FIG. 8 (a), hot water combustion
The characteristic line in the figure shows the flow rate of hot water produced by the water heater during operation.
As shown in characteristic line C in the figure, while keeping constant like B
When the set temperature of the remote control 21 is changed to a low temperature
The water heater controller 20 opens and closes the proportional valve 8 for gas.
Change the amount to bring the hot water temperature closer to the set temperature of the remote control 21.
The gas supply amount is throttled in the direction of opening, but the set temperature is changed.
Immediately after that, the hot water supply combustion operation before the set temperature is switched
Heat exchange due to the amount of heat retained in the heat exchanger 2 (remaining heat)
The hot water that passes through the converter 2 is used in the combustion operation before switching the set temperature.
Because it is heated with an excessive amount of heat close to
As shown by the characteristic line A in the figure, change the set temperature of the remote controller
Could not switch to a lower temperature immediately following
And gradually approaching the set temperature after the change.
After a while, the set temperature is reached. And this
As shown in the figure, after the set temperature of the remote control 21 is switched
Until the hot water temperature reaches the set temperature,
If a shoot occurs, the user will be injured as described above.
It made me feel happy and was a problem .

Further, as shown in FIG. 8B, when the flow rate of hot water discharged from the hot water supply pipe 11 is reduced, the control device 20 reduces the combustion amount of the burner 7 in the same manner as described above. However, immediately after the amount of hot water discharged from the hot water supply pipe 11 is reduced, a large amount of heat is added by the combustion control amount before the amount of hot water is reduced, and the excess heat exchanger 2 is warmed up. The heat of is transferred to the hot water having a small flow rate passing through the heat exchanger 2, so that the hot water is excessively heated and sent to the hot water supply pipe 11, and as shown by the characteristic line A in the figure, The hot water of overshoot is discharged from the hot water supply pipe 11 by that amount, which causes the user to feel very uncomfortable, which is a problem. Furthermore, in such a case, the amount of hot water discharged before the amount of hot water is very large, and when the amount of hot water is sharply reduced to a very small amount,
The overshoot of the hot water that comes out is very large,
It was dangerous because it was dangerous.

[0011] The present invention has been made to solve the conventional problems, and its object is or when changing lower setting temperature during hot water supply combustion operation, the flow rate of the hot water to be tapped from the tapping passage An object of the present invention is to provide a water heater and a hot water temperature control for the hot water that can prevent hot water from overshooting when it is decreased.

[0012]

In order to achieve the above object, the present invention is constructed as follows. That is, the first aspect of the present invention is to provide a main bypass flow passage that communicates the water inlet passage and the hot water outlet passage of the heat exchanger and bypasses the heat exchanger, and the bypass control valve that opens and closes the flow passage. Is provided
Further, the bypass flow path is provided with a sub-bypass flow path communicating between the upstream side and the downstream side of the bypass control valve and bypassing the bypass control valve. a tapping hot water temperature control method for a water heater for tapping hot water mixing water bypass flow path set temperature through the sub-bypass flow path, hot water supply combustion luck
Monitors whether the set temperature has changed during rotation, and the set temperature is low.
When the temperature is changed, it is caused by the temperature change.
Change the set temperature by predicting the magnitude of overshoot
At the same time, the bypass control valve is temporarily opened for a period of time according to the size of the overshoot, and the amount of water in the bypass flow path that mixes with the hot water from the heat exchanger is increased to suppress overshoot. Is configured as.

Further, according to the second aspect of the present invention, there is provided a main bypass passage for connecting the inlet and outlet channels of the heat exchanger to bypass the heat exchanger, and the bypass passage is opened and closed. A bypass control valve is provided, and further, a sub-bypass flow path that bypasses the bypass control valve by communicating between the upstream side and the downstream side of the bypass control valve is provided in the bypass flow path, and the bypass control valve is closed during steady hot water combustion operation. A hot water outlet temperature control method for a water heater that mixes the water in the bypass passage that passes through the sub-bypass passage with the hot water that comes out of the heat exchanger to deliver hot water at a set temperature. The amount of hot water discharged is monitored, and when the amount of hot water discharged decreases, the size of the overshoot that occurs due to the change in the amount of hot water discharged is predicted, and when the amount of hot water is changed, the bypass control valve is overrun at the same timing. Time corresponding to the magnitude of the chute only one
It is characterized by increasing the amount of water in the bypass flow path that opens temporally and mixes with the hot water discharged from the heat exchanger to suppress overshoot.

Further, according to the third aspect of the present invention, a main bypass passage is provided which communicates the water inlet passage and the hot water outlet passage of the heat exchanger and bypasses the heat exchanger, and the bypass passage is opened and closed. A water heater having a bypass control valve for bypassing the bypass control valve, which further connects the upstream side and the downstream side of the bypass control valve to bypass the bypass control valve. A set temperature monitoring unit that monitors whether or not the set temperature is changed during combustion operation, an overshoot prediction unit that predicts the magnitude of the overshoot that occurs when the set temperature is changed to a low temperature, and an overshoot When a shoot is predicted to occur, a bypass control valve on / off time determination unit that determines the bypass control valve opening / closing time according to the magnitude of the overshoot, and a bypass control valve on / off time Based on the time determined by the time determination unit, the bypass control valve on / off command unit that commands the opening and closing of the bypass control valve at the same time when changing the set temperature, and the size of the overshoot by the command of the bypass control valve on / off command unit Bypass control valve only for the appropriate time
It is characterized in that it is provided with a bypass control valve drive unit that temporarily opens and increases the amount of water in the bypass flow path that mixes with the hot water discharged from the heat exchanger.

Further, according to the fourth aspect of the present invention, there is provided a main bypass passage for connecting the water inlet passage and the hot water outlet passage of the heat exchanger to bypass the heat exchanger, and the bypass passage is opened and closed. A water heater having a bypass control valve for bypassing the bypass control valve, which further connects the upstream side and the downstream side of the bypass control valve to bypass the bypass control valve. A hot water amount monitoring unit that monitors the amount of hot water discharged from the hot water outlet during combustion operation, and an overshoot prediction unit that predicts the magnitude of the overshoot that occurs when the amount of hot water discharged changes, When a shoot is predicted to occur, the bypass control valve on / off time determination unit that determines the bypass control valve opening / closing time according to the size of the overshoot, and the bypass control valve on / off Depending on the size of the overshoot, the bypass control valve on / off command unit that commands the opening and closing of the bypass control valve at the same time when changing the amount of hot water based on the time determined by the interval determination unit and the command of the bypass control valve on / off command unit The bypass control valve drive unit is provided for temporarily opening the bypass control valve for a certain period of time to increase the amount of water in the bypass passage mixed with the hot water discharged from the heat exchanger.

[0016]

In the present invention having the above-mentioned structure, in the first and third inventions, whether or not the set temperature is changed during the hot water supply combustion operation.
Is monitored and when the set temperature is changed to a lower temperature
Of the overshoot caused by the temperature change
The size is predicted, and further, in the second and fourth inventions,
Monitor the amount of hot water discharged from the hot water outlet during hot water supply combustion operation
When the amount of hot water discharged decreases, the amount of hot water changes
Of the overshoot caused by the
As described above, the occurrence of overshoot is predicted.
If the temperature is changed, the timing may change when the set temperature is changed or the amount of hot water is changed.
The bypass control valve has a large overshoot.
It is temporarily opened for a time corresponding to the size, and the amount of water in the bypass flow path that mixes with the hot water coming out of the heat exchanger is increased to suppress overshoot.

[0017]

Embodiments of the present invention will be described below with reference to the drawings. In the description of the present embodiment, the same reference numerals will be given to the same names as those in the conventional example, and the detailed description thereof will be omitted.
Figure 1 is one embodiment of a water heater for controlling the engagement Ru out YuyuAtsushi control method of the present invention is shown. This water heater is different from the conventional water heater in that it has a main bypass passage 4 communicating with the water supply pipe 3 and the hot water supply pipe 11. The main bypass passage 4 functions as a bypass control valve. A bypass solenoid valve 15 is provided. Further, the main bypass passage 4 is connected to the upstream side 27 and the downstream side 28 of the bypass solenoid valve 15 so as to communicate with the bypass solenoid valve 1.
5, a sub-bypass flow path 26 that bypasses 5 is provided ,
Bypass solenoid valve 15 is in a state of closed during steady hot water supply combustion operation.

[0018] The water heater of this embodiment will be described below.
The hot water temperature control method of the present embodiment
Before explaining the hot water temperature control method, the hot water temperature control of the present embodiment will be described.
Control of stabilization of the temperature of the re-outflow hot water that is used as needed according to the method
I will explain the configuration.

[0019] As we all know, stop burning the water heater
Immediately after the hot water supply has stopped burning, the
There is residual heat that has been warmed to the
The residual heat of the heat exchanger 2 is transferred to the hot water staying in the exchanger 2.
Therefore, it is known that the boiling phenomenon of hot water occurs.
However, there are various usage patterns when using the water heater.
There is, for example, the hot water discharged from the hot water supply pipe 11
After stopping, the hot water supply from the hot water supply pipe 11 is stopped for a while.
After the time has passed, the hot water supply pipe 11 should be tapped again.
Therefore, there is a wait from the stop of hot water supply combustion to the return of hot water.
When the machine time is short, when re-extracting hot water, the heat exchanger 2 side
Hot water supply pipe 1
As a result, the hot water is discharged from the tip side of the hot water supply pipe 11.
The hot water is overshoot hotter than the set temperature.
The problem that the user feels uncomfortable when the hot water is discharged
Occurs. Re-leasing hot water temperature stabilization control configuration is
Control to prevent hot water from overshooting
And the control structure is formed in the controller 20.
It

[0020] indicates to control device 20 in FIG. 2, of the re-tapping hot water temperature
It is provided with a stabilizing control configuration and has a bypass solenoid valve control unit 39 and a combustion operation control unit 40. The bypass solenoid valve control unit 39 includes a high temperature / low temperature setting determination unit 30, a bypass solenoid valve on / It has an off command unit 31, a bypass solenoid valve drive unit 32, a standby time measurement timer 33, a bypass solenoid valve on / off time calculation unit 41, and a bypass solenoid valve on / off time measurement timer 42. Further, the combustion operation control unit 40 includes a combustion capacity calculation unit 35 and a combustion amount storage unit 3
4, a proportional valve operation amount calculation unit 36, a proportional valve drive unit 37, and a temperature deviation detection unit 38.

The combustion capacity calculation section 35 has a calculation circuit, and is adapted to calculate the combustion capacity and the amount of heat of combustion of the water heater by the calculation circuit, and the temperature setting section 2 of the remote controller 21.
The set temperature signal of 9, the flow rate detection signal detected by the flow rate sensor 9, and the incoming water temperature detection signal detected by the incoming water temperature sensor 18 are constantly added to the combustion capacity calculation unit 35.

The temperature deviation detection unit 38 has a comparison circuit and an arithmetic circuit, and compares the set temperature input to the temperature setting unit 29 with the hot water temperature detection signal detected by the hot water temperature sensor 16. The temperature deviation between the hot water temperature and the set temperature is detected, and a detection signal of the temperature deviation between the hot water temperature and the set temperature is added to the combustion capacity calculator 35. Then, the combustion capacity calculation unit 35 includes signals from the temperature setting unit 29, the flow rate sensor 9, and the incoming water temperature sensor 18 and the temperature deviation detection unit 3.
In response to the signal from 8, the combustion circuit calculates the combustion capacity and the combustion heat quantity of the water heater, adds the combustion capacity calculation result to the proportional valve operation amount calculation section 36, and outputs the combustion heat quantity calculation result to the combustion quantity storage section 34. Add to.

The proportional valve operation amount calculation unit 36 has a calculation circuit, and receives the calculation result of the combustion capacity of the water heater from the combustion capacity calculation unit 35, and calculates the operation amount of the proportional valve 8 of gas by the calculation circuit. Calculation is performed and the calculation result is added to the proportional valve drive unit 37.

The proportional valve drive unit 37 receives the calculation result from the proportional valve operation amount calculation unit 36 and controls the drive of the proportional valve 8 of gas, and is calculated by the proportional valve operation amount calculation unit 36. The proportional valve 8 is opened / closed by the operation amount, thereby controlling the combustion of the water heater so that the hot water outlet temperature becomes substantially equal to the set temperature.

The combustion amount storage unit 34 is a combustion capacity calculation unit 35.
Is stored in the bypass solenoid valve on / off time calculation unit 41 of the bypass solenoid valve control unit 39.
Add the value of the amount of heat from the hot water supply combustion to the previous time.

On the other hand, the high temperature / low temperature setting determination unit 30 determines whether the set temperature of the hot water supplied to the temperature setting unit 29 of the remote controller 1 is the high temperature setting or the low temperature setting. In response to a signal from the setting unit 29, for example, when the set temperature is 60 ° C. or 70 ° C., it is determined that the set temperature is the high temperature setting, and the set temperature is, for example, 36.
When the temperature is in the range of ℃ to 48 ℃, it is judged that the set temperature is the low temperature setting, and the judgment results are added to the bypass solenoid valve on / off command section 31.

The waiting time measuring timer 33 is a waiting time from when hot water supply is once stopped to when hot water is discharged again.
That is, the combustion stop elapsed time from the hot water supply combustion stop is measured, and a signal from the flow rate sensor 9 is received,
After the hot water supply is stopped once, the detection signal detected by the flow rate sensor 9 is turned off, and then the time until the flow rate sensor 9 is turned on again is measured as the standby time, and the standby time is sequentially commanded to bypass the solenoid valve. It is added to the section 31 and the bypass solenoid valve on / off time calculation section 41.

By-pass solenoid valve on / off time calculation unit 41
Is the magnitude of the overshoot at the time of hot-water tapping again based on the information including after the hot water supply combustion was stopped, before the hot water supply combustion was stopped, and on the information including the combustion stop elapsed time after the hot water supply combustion was stopped. It has an overshoot prediction unit that predicts the occurrence of an overshoot, and a bypass control valve on / off time determination unit that determines the on / off time of the bypass control valve according to the size of the overshoot when hot water is re-spouted. , Standby time measurement timer 3
3 and the signal supplied from the combustion amount storage unit 34 of the combustion operation control unit 40, the previous hot water supply combustion heat amount stored in the combustion amount storage unit 34 and the hot water supply combustion stop measured by the standby time measurement timer 33. Based on the value of elapsed time of combustion stop from time to time, calculate whether overshoot occurs when re-leaving hot water after stopping hot water supply combustion, and the magnitude of overshoot when it is predicted that overshoot will occur Then, the opening time of the bypass control valve 15 (the bypass solenoid valve ON time) corresponding to the magnitude of the overshoot is calculated, and the calculation result is added to the bypass solenoid valve ON / OFF command section 31.

Whether or not an overshoot occurs in the hot water discharged at the time of re-hot water is determined by the amount of heat from the previous hot water supply combustion before the hot water supply combustion stop, the combustion stop elapsed time after the hot water supply combustion stop, the outside air temperature and the water heater. It depends on the temperature of the water entering the water and the flow velocity of the water (hot water).

FIG. 4 shows an example of the relational data between the hot water supply combustion operation, the hot water supply combustion is temporarily stopped, the standby time from the stop of the hot water supply combustion to the re-emergence of hot water, and the hot water discharge temperature at the time of re-emergence. As shown in the figure, there is a difference in the hot water supply temperature when the hot water is burned again when the previous hot water supply combustion heat quantity Q is large, when it is medium, and when it is small. It can be seen that even if the times are the same, the hot water discharge temperature is high when the previous hot water supply combustion heat amount is high, and the hot water discharge temperature is low when the previous hot water supply combustion heat amount is small.

Then, for example, as shown in the figure, if an area where hot water having a temperature higher than the set temperature by 5 ° C. or higher is predicted to be set as an overshoot determination area,
When the amount of heat of combustion for hot water supply at the previous time is large, it is predicted that overshoot will occur when the standby time is in the range from A to A'in the figure, and otherwise it will be predicted that no overshoot will occur. Similarly, when the amount of combustion heat of hot water supply last time is medium, it is predicted that overshoot will occur when the standby time is in the range shown from B to B ′ in the figure, and otherwise it will be predicted that no overshoot will occur. It is predicted that no overshoot will occur at any standby time when the heat quantity of hot water supply combustion is small last time.

Therefore, the bypass solenoid valve is used to previously obtain data on the amount of heat of combustion for hot water supply as shown in FIG. 4 and the hot water temperature when hot water is again discharged when the waiting time T has elapsed, as shown in FIG. If it is input to the on / off time calculation unit 41, it is possible to determine when the hot water is re-extracted from the previous hot water supply combustion heat amount stored in the combustion amount storage unit 34 of the combustion operation control unit 40 and the graph data as shown in FIG. It is possible to predict the occurrence of overshoot and its magnitude.

The bypass solenoid valve on / off command section 31 is
The bypass solenoid valve on / off time calculation unit functions as a bypass control valve on / off command unit for instructing opening / closing of the bypass control valve (bypass solenoid valve) based on the time determined by the bypass control valve on / off time determination unit. An instruction to turn on / off the bypass solenoid valve 15 in response to signals from the low temperature setting determination unit 30, the standby time measurement timer 33, the bypass solenoid valve on / off time calculation unit 41, and the bypass solenoid valve on / off time measurement timer 42. A signal is applied to the bypass solenoid valve drive unit 32, the high temperature / low temperature setting determination unit 30 determines that the set temperature input to the temperature setting unit 29 of the remote controller 21 is the low temperature setting, and When the hot water is again discharged when the time measured by the standby time measurement timer 33 has elapsed since the combustion operation was stopped once, When the occurrence of over-shoot is predicted by a bypass solenoid valve on-off time calculating unit 41 first adds a bypass solenoid valve ON command signal to open the bypass solenoid valve 15 to the bypass solenoid valve driving unit 32. The bypass solenoid valve on / off command unit 31 sends the bypass solenoid valve on command signal to the bypass solenoid valve drive unit 32.
At the same time, the bypass solenoid valve on / off time measuring timer 42 is supplied with a timer-on signal.

The bypass solenoid valve on / off time measuring timer 42 receives the timer-on signal from the bypass solenoid valve on / off command section 31 and the flow rate detection signal from the flow rate sensor 9, and turns on the bypass solenoid valve 15 (open state). ), And how long time has elapsed since the flow rate of the water mixed in the hot water supply pipe 11 from the main bypass passage 4 increased.

Upon receipt of the signal from the bypass solenoid valve on / off time measuring timer 42, the bypass solenoid valve on / off command section 31 causes the bypass solenoid valve on / off time measuring timer 42 to measure the bypass solenoid valve. The on time (elapsed time after the bypass solenoid valve 15 is turned on) is compared with the bypass solenoid valve on time obtained by the bypass solenoid valve on / off time calculation unit 41, and the bypass solenoid valve 15 is operated until both are equal. By applying the ON command signal to the bypass solenoid valve drive unit 32, the bypass solenoid valve 15 is commanded to open for a time corresponding to the magnitude of the overshoot predicted to occur when the hot water heater re-emerges hot water. There is.

The bypass solenoid valve drive unit 32 receives the signal from the bypass solenoid valve on / off command unit 31 and opens the bypass control valve (bypass solenoid valve) for a time corresponding to the magnitude of the overshoot at the time of re-hot water discharge. The drive of the bypass solenoid valve 15 is controlled so as to increase the bypass flow rate of water mixed with the hot water discharged from the heat exchanger.
When a bypass solenoid valve ON signal from the bypass solenoid valve ON / OFF command unit 31 is applied to the bypass solenoid valve drive unit 32, the bypass solenoid valve 15 is driven to ON (open state), and the bypass solenoid valve ON / OFF command is issued. When the bypass solenoid valve OFF signal is applied from the portion 31 to the bypass solenoid valve drive portion 32, the bypass solenoid valve 15 is driven off (closed state).

Next, the stabilization operation of the re-outflow hot water temperature is shown in FIG.
A specific description will be given based on the flowchart shown in FIG. First, in step 101 of FIG. 3, the remote controller 21 of the water heater is turned on. At this time, as shown in step 102, the bypass solenoid valve 15 is in the off state. Next, in step 103, it is confirmed whether or not the flow rate sensor 9 is turned on. When it is confirmed that the flow rate sensor 9 is turned on, the combustion operation is started in step 104.

Next, at step 105, it is determined whether the set temperature input to the temperature setting section 29 of the remote controller 21 and the hot water temperature detected by the hot water temperature sensor 16 are substantially equal to each other. The combustion control is performed until the set temperature is substantially equal to the hot water discharge temperature detected by the unit 38, and the hot water supply combustion operation is continued while sequentially storing the combustion amount in the combustion amount storage unit 34 in step 107. At this time, it is determined in step 108 whether or not the flow rate sensor 9 is off. If the flow rate sensor 9 is not off, the combustion operation is continued,
The operations from step 105 to step 108 are repeated.

When it is confirmed in step 108 that the flow sensor 9 is turned off, step 10
It is determined in step 9 that the hot water supply combustion has been stopped, and step 110
Then, measurement of the waiting time T by the waiting time measuring timer 33 is started. Then, in step 111, it is determined whether or not the flow rate sensor 9 is turned on, and when it is confirmed that the flow rate sensor 9 is turned on, in step 112, the bypass solenoid valve on / off time calculation section 41 performs re-hot water. Predict whether an overshoot will occur, and if the overshoot is predicted, calculate the on-time of the bypass solenoid valve according to the magnitude of the overshoot that is expected to occur when tapping hot water again. 1
Turn 5 on.

When the occurrence of overshoot is predicted, by opening the bypass solenoid valve 15,
Sending water from the main bypass channel 4 to the mixing section 19 side, and thus combining and mixing water from both the main bypass channel 4 and the sub bypass channel 26 with water from the heat exchanger 2 side. Allows more heat than usual to be used in the heat exchanger 2
It is mixed with hot water from the side to prevent overshoot of hot water discharged from the hot water supply pipe 11. At the same time when the bypass solenoid valve 15 is turned on, the standby time measurement timer 33 is cleared at step 113, and the bypass solenoid valve on / off time measurement timer 42 is started at step 114.

Next, in step 115, the combustion is restarted, and in step 116, the bypass solenoid valve on / off command section 31 determines the bypass solenoid valve on / off time calculation value T _B obtained by the bypass solenoid valve on / off time calculation section 41. And the bypass solenoid valve on-time measurement value T ₀ measured by the bypass solenoid valve on / off time measurement timer 42 are compared, and the bypass solenoid valve on-time measurement value T ₀ reaches the bypass solenoid valve on-time calculation value T _B. If not, the combustion operation is continued with the bypass solenoid valve 15 turned on in step 117. When it is determined in step 116 that the measurement time T ₀ has reached the calculation time T _B , the bypass solenoid valve 15 is turned off in step 118, and the bypass solenoid valve on / off time measurement timer 42 is set in step 119. After clearing, the routine returns to step 105 to continue the normal combustion operation operation.

[0042] The above Symbol operation, the combustion operation control unit 40 of the control device 20 together with the combustion operation operation of the water heater is controlled, heat of combustion at that time is stored in the combustion storage unit 34, on the other hand, hot water combustion When the hot water supply is stopped, the standby time measuring timer 33 measures the standby time T from the combustion stop to the re-hot water discharge after the hot water supply combustion is stopped.
And the magnitude of the overshoot at the time of re-hot water is predicted by the bypass solenoid valve on / off time calculation unit 41 based on the information including the previous hot water supply heat of combustion before the hot water combustion stop. When it is predicted that a chute will occur, the bypass solenoid valve 15 will be opened during re-hot water for a time period corresponding to the size of the overshoot, and the amount of water in the main bypass flow path 4 to be mixed with the hot water discharged from the heat exchanger 2 will increase. In order to be done, that much hot water supply pipe 1
It is possible to suppress the overshoot of the hot water discharged from No. 1.

In the water heater of this embodiment shown in FIG. 1, the bypass control valve and the like are not provided in the sub bypass flow passage 26, and the water from the sub bypass flow passage 26 comes from the heat exchanger 2 side. Since the hot water is always mixed in the mixing section 19, for example, when the hot water from the heat exchanger 2 side is cooled down and the hot water is again discharged, the hot water supply and combustion are restarted from the start of the hot water discharge again. Although there is a slight delay until the hot water is warmed up, the water from the sub-bypass flow path 26 is mixed with the hot water from the heat exchanger 2 side at this time as well, so that the hot water temperature at the hot water outlet is local. Undershoot will occur.

In order to mitigate such undershoot, for example, it is usually necessary to set a large amount of water passed through the heat exchanger 2 side with respect to the total amount of water entering the water heater. The temperature of the hot water heated on the side of the heat exchanger 2 (the temperature of the hot water before being mixed in the mixing section 19) is also low, but the hot water is warmed by the start of hot water supply and the start of hot water combustion. Until the sub-bypass flow path 26
Due to the small amount of water mixed from the side, local undershoot of the hot water temperature can be mitigated.

[0045] Figure 5 shows a YuyuAtsushi control how out of the present invention examples of row <br/> Nau control mechanism. Also in the control mechanism of the present embodiment , the control device 20 has the bypass solenoid valve control unit 39 and the combustion operation control unit 40, as in the control device 20 shown in FIG. 2, and is shown in FIG. In the control device 20 of the present embodiment , the bypass solenoid valve control unit 39
Does not have the standby time measurement timer 33, the combustion operation control unit 40 does not have the combustion amount storage unit 34, and the other components are the control device 20 shown in FIG. Is the same as.

The controller 20 of this embodiment shown in FIG. 5 is provided in the water heater shown in FIG. 1. In the controller 20 of FIG. 5, the combustion capacity calculator 35 is shown. It has an unset temperature monitoring unit, a hot water discharge amount monitoring unit, and an overshoot prediction unit. The set temperature monitoring unit monitors the set temperature of the temperature setting unit 29 of the remote controller 21, and the set temperature is changed to a low temperature. Occasionally, the size of the overshoot generated by the temperature change is predicted by the overshoot prediction unit, and the result is turned on / off by the bypass solenoid valve.
It is added to the off-time calculation unit 41. Further, the hot water discharge amount monitoring unit receives a signal from the flow rate sensor 9 to monitor whether or not there is a change in the amount of hot water discharged from the hot water supply pipe 11, and when the amount of hot water discharged decreases, the overshoot prediction unit detects the change. The size of the overshoot caused by the change of the amount of hot water discharged is predicted, and the result is added to the bypass solenoid valve on / off time calculation unit 41.

By-pass solenoid valve on / off time calculation unit 41
Has a bypass control valve on / off time determination unit that determines a bypass control valve (bypass electromagnetic valve) opening / closing time according to the magnitude of the overshoot when the occurrence of overshoot is predicted. When the set temperature is changed in response to the value of the magnitude of the overshoot predicted in step 1, the ON time of the bypass solenoid valve 15 is calculated according to the magnitude of the overshoot, and when the amount of hot water is changed. , The on-time of the bypass solenoid valve 15 is calculated according to the magnitude of the overshoot, and these calculation results are obtained.
Add to.

The bypass solenoid valve on / off command section 31 is
The functions as a bypass control valve on-off command unit, measurement and on-time of the bypass solenoid valve 15 obtained by the bypass solenoid valve on-off time calculating unit 41, the bypass solenoid valve on and off time measuring timer 42 The bypass solenoid valve 15 is opened for the ON time of the bypass solenoid valve 15 calculated by the bypass solenoid valve ON / OFF time calculation unit 41 by comparing the time with the set temperature and adjusting the timing when changing the set temperature or changing the amount of hot water. Thus, a command signal is applied to the bypass solenoid valve drive unit 32 to control the opening time of the bypass solenoid valve 15.

The present embodiment is constructed as described above,
The characteristic of the present embodiment is to monitor whether or not the set temperature of the remote controller 21 is changed during the hot water supply combustion operation of the water heater, and when the set temperature is changed to a low temperature, the overshoot caused by the temperature change is detected. Predict the size of the bypass solenoid valve 15 by adjusting the timing when changing the set temperature.
Is opened for a period of time according to the size of the overshoot, and the amount of hot water discharged from the hot water outlet is monitored during hot water supply combustion operation, and when the amount of hot water discharged decreases, the amount of hot water discharged changes. The size of the overshoot is predicted, and the bypass solenoid valve is opened for a time corresponding to the size of the overshoot at the same timing when changing the amount of hot water.

Next, the operation of this embodiment will be specifically described with reference to the flowcharts of FIGS. 5 and 6.
First, in step 201 of FIG. 6, the combustion operation operation of the water heater is performed. At this time, as shown in step 202, the bypass solenoid valve 15 is off, it is determined in step 203 whether the flow sensor 9 is on, and when the flow sensor 9 is on, in step 204. The combustion operation is started, and in step 205, the hot water supply combustion operation is continued so that the set temperature becomes substantially equal to the hot water discharge temperature.

Then, in step 207, when the set temperature of the remote controller 21 is changed to a low temperature during the hot water supply combustion operation, in step 208 the magnitude of the overshoot caused by the temperature change is calculated by the combustion capacity calculation part 35. The bypass solenoid valve on / off time calculation unit 41 calculates the on-time of the bypass solenoid valve 15 according to the predicted magnitude of the overshoot, and calculates the bypass solenoid valve on-time calculation value T _B by the bypass solenoid valve on / Off command unit 3
Add to 1. At the same time, the bypass solenoid valve on / off time measurement timer 42 is started in step 209, and in step 210, the bypass solenoid valve on-time calculation value T _B is compared with the bypass solenoid valve on-time measurement value T ₀ .

Then, the bypass solenoid valve on-time measured value T
_The bypass solenoid valve 15 is turned on (open state) in step 211 until ₀ reaches the bypass solenoid valve on-time calculated value T _B , and the bypass solenoid valve on-time measured value T ₀ reaches the bypass solenoid valve on-time calculated value T _B. If yes, step 21
In step 2, the bypass solenoid valve 15 is turned off, in step 213, the bypass solenoid valve on / off time measuring timer 42 is cleared, and the process proceeds to step 215.

When it is determined in step 207 that the set temperature of the remote controller 21 has not been changed to a low temperature, it is determined in step 214 whether or not the flow rate of the hot water discharged from the hot water supply pipe 11 has decreased, and the temperature decreases. If not, the process proceeds to step 215, and when it is determined that the flow rate of hot water discharged from the hot water supply pipe 11 has decreased, step 208 is performed.
Proceed to step 208 to step 21 as before.
The operation up to 3 is repeated.

Then, in step 215, it is judged whether or not the flow rate sensor 9 is turned off. When the flow rate sensor 9 is turned off, the combustion operation operation of the water heater is stopped in step 216, and the process returns to step 202. Also, step 2
When the flow sensor 9 is not turned off at 15, the process returns to step 205 and the same operation as described above is repeated.

According to this embodiment, as described above, the presence / absence of a change in the set temperature and the amount of hot water discharged are monitored individually during the hot water supply combustion operation, and the characteristic line C in FIG. When the set temperature of the remote controller 21 is changed to a low temperature as shown in FIG. 5, the bypass solenoid valve 15 is turned on (open state) at the same timing as the set temperature is changed as shown in D of FIG. Only the time corresponding to the size of the chute, that is, the bypass solenoid valve on / off time calculation unit 4
1, the bypass solenoid valve 15 is opened by the bypass solenoid valve on-time calculated value T _B, and the amount of water from the main bypass passage 4 that joins and mixes with the hot water from the heat exchanger 2 side is increased to suppress overshoot, after the bypass solenoid valve on-time calculated value T _B has elapsed, the bypass solenoid valve 15
As shown by the characteristic line A in the figure, the hot water temperature of the hot water discharged from the hot water supply pipe 11 is low in accordance with the change in the set temperature shown in the characteristic line C in the figure in order to close the valve and return to the normal state. Changed to temperature. Therefore, as in the conventional case, the hot water discharge temperature does not follow the change of the set temperature as shown by the dotted line A ′ in FIG. It is possible to prevent the user from feeling uncomfortable due to the hot water being discharged.

Further, as shown by the characteristic line B in FIG. 7B, when the amount of hot water discharged from the hot water supply pipe 11 decreases, the size of the overshoot caused by the change in the amount of hot water discharged is predicted, As shown in D of the figure, when the amount of hot water is changed, the bypass solenoid valve 15 is turned on at the same timing, and the bypass solenoid valve on-time calculated value T _{B is} set in the same manner as above.
Reach to turn on the bypass solenoid valve 15, in order to return to the normal state the bypass solenoid valve 15 as off when it reaches the bypass solenoid valve on-time calculated value T _B, overshoot generated by a change of tapping hot water The temperature of the hot water that is suppressed and discharged from the hot water supply pipe 11 is maintained in a stable state with a substantially constant value as shown by the characteristic line A in the figure. A '
As shown in FIG. 5, the amount of hot water does not suddenly increase and overshoot of hot water does not come out with respect to the set temperature, thereby preventing the user from feeling uncomfortable.

The present invention is not limited to the above-mentioned embodiments, and various embodiments can be adopted. For example, in the above embodiment, the high temperature / low temperature setting determination unit 3 of the control device 20.
0 determined that it was a high temperature setting when the set temperature of hot water supply was 60 ° C or 70 ° C, and determined that it was a low temperature setting when the set temperature was 36 to 48 ° C, but the high temperature / low temperature setting determination unit 30 , It is always judged that the high temperature is set when the set temperature is 60 ° C or 70 ° C, and the set temperature is 36 to 48 ° C.
In this case, it is not always determined that the temperature is the low temperature setting, and the value for determining that the set temperature is the high temperature setting or the value for determining the low temperature setting is not particularly limited, and the high temperature / low temperature setting determination unit 30 Is not necessarily provided in the control device 20, and the control device 20 may be configured without the high temperature / low temperature setting determination unit 30.

[0058] Further, in the above you施例, and when hot water burning and whether the presence and pouring hot water changes the change set temperatures individually monitored during operation, is changed to a lower temperature setting temperature, tapping hot water When the amount decreases, the size of the overshoot caused by the temperature change or the change in the amount of hot water is predicted, and when the set temperature is changed or the amount of hot water is changed, the bypass solenoid valve 15 is turned on for a time corresponding to the amount of the overshoot. Although it was configured to open, only one of the change of the set temperature and the change of the amount of discharged hot water is monitored during the hot water combustion operation, and when either the change of the set temperature or the change of the discharged hot water occurs. The bypass solenoid valve 15 may be configured to be opened only for a time period corresponding to the magnitude of the overshoot. However, if it is configured to monitor both the change in the set temperature and the change in the amount of hot water discharged as in the above embodiment, it is possible to suppress overshoot when either the set temperature or the amount of hot water discharged changes. Is more desirable because

[0059] Further, the upper in you施例, and Changes in presence and pouring hot water changes the set temperature during the hot water supply combustion operation individually monitored, the overshoot caused by change or hot water changes the set temperature predicting the size has been configured to open for a time corresponding bypass solenoid valve 15 to the magnitude of the overshoot timed at the time and quantity of water changes change the set temperature, the present invention is, above you施例To the configuration of
2 is added to the configuration for stabilizing the temperature of the hot water supplied again to suppress the overshoot due to the change of the set temperature during the hot water supply combustion operation and the change in the amount of hot water, and when the hot water supply is restarted after the hot water supply combustion is stopped. It may be configured so that overshoot can be suppressed together. With such a configuration, it is possible to suppress the overshoot both during the hot water supply combustion operation and during the re-hot water discharge after the hot water supply combustion is stopped. Therefore, it is more preferable to have such a configuration.

Further, in the above embodiment, the bypass solenoid valve 15 functioning as a bypass control valve is provided in the main bypass passage 4, but the bypass control valve is not limited to the bypass solenoid valve 15, and the bypass solenoid valve is not necessarily used. Instead of 15, a water amount control valve of variable water amount (flow rate) may be used. At this time, the water amount control valve may be a solenoid valve and may be a water amount control valve of a type in which the solenoid valve is repeatedly turned on and off.

[0061]

According to the present invention, when the presence or tapping hot water changes the set temperature was monitored during hot water supply combustion operation, are or tapping hot water when the set temperature is changed to a lower temperature decreases,
By predicting the magnitude of the overshoot caused by these changes, when the overshoot is predicted to occur, the bypass control valve is temporarily opened for a time corresponding to the magnitude of the overshoot, and the heat exchanger is by increasing the amount of water in the bypass passage for mixing the hot water exiting to suppress overshooting, it is possible to suppress an overshoot generated by a decrease in change or pouring hot water into the lower temperature in the hot water supply combustion operation It will be possible.

[0062] Then, in this way, it so as not to the uncomfortable by the sheet for hot water tapping of hot water overshoots during combustion operation is inhibited, tapping the user of the hot water overshoots the water heater .

[Brief description of drawings]

1 is a schematic diagram showing an embodiment of a water heater for controlling the engagement Ru out YuyuAtsushi control method of the present invention.

FIG. 2 is an essential part of the control configuration of the method for controlling the temperature of discharged hot water according to the present invention.
FIG. 6 is a block diagram showing a control mechanism for stabilizing the temperature of redeposited hot water that can be added if necessary .

FIG. 3 is a flowchart showing an operation of stabilizing the temperature of the re-outflow hot water .

FIG. 4 is a graph showing an example of a difference in the amount of heat from the previous hot-water supply combustion before the hot-water supply combustion is stopped, and a difference in the hot-water supply temperature at the time of re-hot-water discharge based on the standby time after the hot-water supply combustion is stopped.

FIG. 5 is a real control mechanism that performs YuyuAtsushi control how out of the present invention
It is a block block diagram which shows an Example .

6 is a flowchart showing the operation of the real施例.

7 is a graph showing the relationship between the operation and the hot water hot water Metropolitan bypass solenoid valve 15 when performing hot water hot water temperature control method for a water heater by the upper you施例.

FIG. 8 is a graph showing the occurrence of an overshoot of the hot water discharge temperature due to a change in the set temperature of the conventional water heater and a change in the hot water discharge amount.

FIG. 9 is an explanatory diagram of post-boiling generation due to residual heat of the heat exchanger 2 after the hot water supply combustion is stopped.

FIG. 10 is a schematic view showing an example of a conventional bypass mixing type hot water supply device.

[Explanation of symbols]

2 heat exchanger 4 main bypass channels 11 Hot water supply pipe 15 Bypass solenoid valve 30 High / Low temperature setting judgment unit 31 Bypass solenoid valve on / off command section 33 Standby time measurement timer 34 Combustion amount storage unit 41 By-pass solenoid valve on / off time calculator

─────────────────────────────────────────────────── --- Continuation of the front page (56) References JP-A-5-118656 (JP, A) JP-A-3-191254 (JP, A) JP-A-5-203261 (JP, A) Actual development Sho-59- 80651 (JP, U) (58) Fields surveyed (Int.Cl. ⁷ , DB name) F24H 1/10 302 F24H 1/10 303

Claims (4)

(57) [Claims] 1. A main bypass passage for connecting the inlet and outlet channels of the heat exchanger to bypass the heat exchanger, and a bypass control valve for opening and closing the passage is provided in the bypass passage.
Further, the bypass flow path is provided with a sub-bypass flow path communicating between the upstream side and the downstream side of the bypass control valve and bypassing the bypass control valve. It is a hot water temperature control method for a water heater that mixes the water in the bypass flow path that passes through the sub bypass flow path to discharge hot water at the set temperature, and monitors whether the set temperature has changed during hot water combustion operation. When the set temperature is changed to a low temperature, the size of the overshoot that occurs due to the temperature change is predicted, and when the set temperature is changed, the bypass control valve is temporarily turned on for the time corresponding to the size of the overshoot. to open, tapping hot water temperature control method for suppressing water heater overshoots by increasing the amount of water in the bypass passage for mixing the hot water leaving the heat exchanger. 2. A main bypass passage for connecting the inlet and outlet channels of the heat exchanger to bypass the heat exchanger, and a bypass control valve for opening and closing the passage is provided in the bypass passage.
Further, the bypass flow path is provided with a sub-bypass flow path communicating between the upstream side and the downstream side of the bypass control valve and bypassing the bypass control valve. A hot water supply temperature control method for a water heater that mixes the water in the bypass flow path that passes through the sub bypass flow path to generate hot water at a set temperature, and monitors the amount of hot water discharged from the hot water supply channel during hot water combustion operation. When the amount of hot water to be discharged decreases, the size of the overshoot caused by the change in the amount of hot water to be discharged is predicted, and the bypass control valve is temporarily operated for the time corresponding to the size of the overshoot by adjusting the timing when changing the amount of hot water. A method for controlling the hot water temperature of a hot water supply device, which suppresses overshoot by increasing the amount of water in a bypass flow path that mixes with hot water discharged from a heat exchanger. 3. A main bypass passage for connecting the water inlet and outlet channels of the heat exchanger and bypassing the heat exchanger is provided, and a bypass control valve for opening and closing the passage is provided in the bypass passage. In addition, the bypass flow passage is a water heater provided with a sub-bypass flow passage that communicates the upstream side and the downstream side of the bypass control valve and bypasses the bypass control valve. A set temperature monitoring unit that monitors whether there is a change, an overshoot prediction unit that predicts the magnitude of overshoot that occurs when the set temperature is changed to a low temperature, and the occurrence of overshoot is predicted Sometimes it is determined by the bypass control valve on / off time determination unit and the bypass control valve on / off time determination unit that determines the bypass control valve opening / closing time according to the magnitude of overshoot. The bypass control valve on / off command section that commands the opening and closing of the bypass control valve at the same time when the set temperature is changed based on time, and the bypass control valve for the time corresponding to the size of the overshoot by the command of the bypass control valve on / off command section The water heater, which is provided with a bypass control valve drive unit that temporarily opens the valve to increase the amount of water in the bypass flow path that mixes with the hot water discharged from the heat exchanger. 4. A main bypass flow passage, which communicates the inlet and outlet channels of the heat exchanger and bypasses the heat exchanger, is provided with a bypass control valve for opening and closing the flow passage. In addition, the bypass water passage is provided with a sub-bypass flow passage that connects the upstream side and the downstream side of the bypass control valve and bypasses the bypass control valve. A hot water amount monitoring unit that monitors the amount of hot water discharged, an overshoot prediction unit that predicts the amount of overshoot that occurs when the amount of hot water discharged decreases, and the occurrence of overshoot is predicted. Sometimes it is determined by the bypass control valve on / off time determination unit that determines the bypass control valve opening / closing time according to the size of the overshoot and the bypass control valve on / off time determination unit. The bypass control valve ON / OFF command section that commands the opening and closing of the bypass control valve at the same time when changing the amount of hot water based on the interval, and the bypass control valve for the time corresponding to the size of the overshoot by the command of the bypass control valve ON / OFF command section A water heater characterized by being provided with a bypass control valve drive section for temporarily increasing the amount of water in a bypass flow path that mixes with hot water coming out of a heat exchanger.