JPH0820108B2 - Hot water filling device for bath equipment - Google Patents

Description

Description: [Field of Use] The present invention reduces the water hammer effect at the end of the filling operation by reducing the amount of hot water supplied before stopping the filling operation, especially in the bath apparatus. The present invention relates to such a water filling device.

[Prior Art and Problems Thereof] In recent bath equipment, hot water is directly supplied (water filling) from a water heater to a bathtub, and when the supplied hot water reaches a predetermined value, the water filling operation is stopped. .

Therefore, an electromagnetic on-off valve is inserted in the water filling circuit from the water heater to the bathtub, and the output of the detection means for detecting the water level in the bathtub or the total amount of water filling is input to the water filling controller.
The on-off valve is controlled by the output of this control device.

In this case, the water filling circuit is suddenly cut off at the time of completion of the water filling, so that a water hammer effect occurs in the water filling circuit, which causes noise. Also, if it is used for a long period of time, the water hammer effect may damage the piping.

Therefore, in order to solve such problems,
There is a proposal of No. 765, in which the flow control valve inserted in the water filling circuit is used to throttle the flow from the water filling circuit from the normal flow rate state to the throttle state at the stage of shutting off the water filling circuit when the water filling is stopped. I have to.

When this method is adopted, the water hammer effect is alleviated because the supply flow rate from the water filling circuit is small when the water filling is stopped, that is, when the water filling circuit is cut off, and the above problem can be solved.

However, with this prior art, there is the inconvenience that the water level in the bathtub exceeds the set water level. In this prior art, when the amount of water filling reaches the set value, the amount of water filling from the water filling circuit is squeezed, and then the water filling operation is stopped for a certain period of time, and then the water filling operation is stopped. As a result, the amount of hot water stored in the bathtub increases accordingly. Recently, since various complicated controls have been performed for the filling water level, the above-mentioned variations in the filling water level cannot be ignored.

The present invention is provided with the detection means (3) for detecting the amount of water filling by filling the bathtub (B) with water through the water filling circuit (2) from the water heater (1). The output of the means (3) is input to the control device (4), and this control device (4)
The water filling circuit (2) is shut off by the output of the water filling circuit (2) to stop the water filling operation, and it is inserted into the water filling circuit (2) and switches between a normal flow state and a throttle state of a smaller flow rate ( 22) is operated at a predetermined timing to stop the filling of water in the bath device, in which the expansion device (22) reduces the amount of supply from the filling circuit (2) before the completion of the filling. It is a technical subject to prevent the water hammer effect at the time and to reduce the error between the amount of water filling and the set value.

* Regarding the invention of claim 1 [Technical means] The technical means of the present invention taken to solve the above-mentioned problem is "setting means (31) for setting the output from the detecting means (3) and the amount of water filling. And the output from the control device (4) is input to the control device (4), and the detection means (3)
Throttle control circuit (41) which outputs a signal for changing the throttle device (22) from the normal flow rate state to the throttle state when the output from the controller reaches a value smaller than the set value of the setting means (31) by a certain amount. It was equipped with ”. (See FIG. 1) [Operation] The operation of the above technical means will be described with reference to the flowchart of FIG.

When the filling operation is performed, the control content of the control device (4) shifts from step (80) to step (81) to start the filling operation. That is, the output of the control device (4) causes the expansion device (22) to be in a normal flow rate state and the water filling circuit (2) to be in an open state, so that the water filling operation proceeds as in the conventional case and the water heater (1 ) The hot water from the circuit is filled with water (2)
Is supplied to the bathtub (B) via.

When this supply amount is increased to a value smaller than the set value by the setting means (31) by a certain amount, the control content of the control device (4) shifts from step (82) to step (83) to control the throttle operation. The output of the circuit (41) causes the expansion device (22) to switch from the normal flow rate state to the throttle state, so that the water filling progresses with a small flow rate. Then, in step (84), the amount of hot water supplied and the set value of the setting means (31) are compared, and if both are equal, the output of the control device (4) shuts off the water filling circuit (2) in step (85). Water filling is completed.

In this way, the amount of hot water supplied from the water heater (1) is throttled at the constant flow rate supply stage until the completion of the filling, and then the filling circuit (2) is cut off. The impact is mitigated. Further, when the hot water filling circuit is cut off, the amount of hot water supplied to the bathtub (B) matches the set value.

[Effects] The present invention having the above-described configuration has the following unique effects.

The amount of hot water is squeezed before the completion of filling, and the filling circuit is cut off when the final supply amount in this state reaches the set value, so the water hammer effect at this time is alleviated and the amount of filling is reduced. It will exactly match the set value.

* Regarding the invention of claim 2 This invention is the diaphragm device (22) according to the invention of claim 1.
In this case, the specified configuration is "to make the diaphragm device (22) finally operate to the front closed state in the diaphragm state". The control contents of the control device (4) are as shown in FIG. That is, when it is confirmed that the amount of hot water supplied to the bathtub (B) has reached the set value of the setting means (31) by the same control as in the invention of claim 1 (steps (80) to (84)), The throttle device (22) is maintained in the fully closed state by the control of step (850), whereby the filling operation is completed. Therefore, in the invention of claim 2, the expansion device (22) also has a flow path blocking function of the water filling circuit (2), and it is not necessary to separately prepare a flow path blocking means such as the on-off valve (20). , The configuration can be simplified.

[Embodiment] An embodiment of the present invention will be described below with reference to FIGS. 2 to 5.

In the embodiment shown in FIG. 2, the flow meter (32) inserted into the water filling circuit (2) detects the amount of water filling, and the water filling circuit (2) from the water heater (1) is detected. The flow meter (32) is inserted downstream of the on-off valve (20) inserted in the. This flow meter (32) functions as the above-mentioned detection means (3).

The water heater (1) in the figure has a hot water supply circuit (2) downstream of the heat exchanger (10) and a hot water supply circuit (2) for other locations.
1) and branch into the hot water filling circuit (2).
2) and the on-off valve (20) are inserted, and the flow meter (32) is inserted on the downstream side. Then, the output from the flow meter (32) is input to the control device (4). The throttle device (22) adjusts the opening degree according to a signal input, and its operation is controlled by the output of the throttle operation control circuit (41) provided in the control device (4). The amount of water filling can be set arbitrarily, and the setting means (31) is built in the remote operation panel (5) connected to the extension cord from the appliance and is provided on this remote operation panel (5). The flow rate setting knob (51) allows the setting means (3
The output value of 1) is adjusted. Further, the remote operation panel (5) is provided with a water filling operation switch (52), and by operating this, the water heater (1) is brought into an operating state and the water filling operation automatically proceeds.

Here, a circuit as shown in FIG. 3 is adopted as the control device (4), and the output value from the flow meter (32) is a voltage corresponding to the integrated value of the flow rate. Voltage and the reference voltage setting circuit (3
The output voltage from 3) is input to the first comparator (42).

The reference voltage setting circuit (33) includes a variable resistor (R)
And a fixed resistor (R ₁ ) (R ₂ ) connected in series with this, and the combination of the variable resistor (R) and the fixed resistor (R ₁ ) functions as the setting means (31). The voltage applied to the series circuit of the variable resistor (R) and the fixed resistor (R ₁ ) is input to the first comparator (42). In addition, in order to set the timing of the diaphragm operation of the diaphragm device (22),
A second comparator (43) is provided, and an output voltage from the flowmeter (32) and a voltage applied to the variable resistor (R) are input to the second comparator (43). There is.

The output of each of these comparators is configured to control the corresponding output device via the drive circuit, and the output of the first comparator (42) is connected to the switching valve (20) in series with the switch circuit (44). ) And the output of the other second comparator (43) is input to the drive circuit (45) of the diaphragm device (22).
The first comparator (42) is in the output “H” state under the condition that the output level of the flow meter (32) is higher than the output level of the setting means (31), and if the two output levels match. , Output “L” state. The switch circuit (44) makes the circuit conductive only in the output "H" state. Further, the output of the second comparator (43) changes from "H" to "L" after the time when the input from the flowmeter (32) becomes equal to or higher than the other input, as with the first comparator (42). The driving circuit (45) sets the diaphragm device (22) in the diaphragm state under the condition that the input is at "L" level.
Therefore, in this embodiment, the combination of the second comparator (43) and the drive circuit (45) is the above-mentioned diaphragm operation control circuit (41).
Function as

The operation switch (52) is connected to a set input terminal of a flip-flop circuit (hereinafter referred to as FF circuit (F)), and the output of the first comparator (42) is the FF circuit (F).
Feedback is input to the reset input terminal of. Further, the set resistance of the variable resistor (R) is adjusted by the hot water amount setting knob (51).

In the embodiment described above, the controller (4) is operated by operating the operation switch (52) after operating the hot water amount setting knob (51) provided on the remote control panel (5) to set the hot water filling amount.
The respective parts of FIG. 6 become conductive (this operation corresponds to the control branching from steps (80) to (81) in FIG. 6 for explaining the operation of the invention of claim 1). At this time, since the output of the first comparator (42) is in the “H” state, the switch circuit (44) is turned on to open the on-off valve (20), which causes the water heater (1) to operate. It becomes a state. At this time, since the output of the second comparator (43) is also in the "H" state, the drive circuit (45) is in the non-throttled state, that is, the throttle device (22) is set in the normal flow rate state. Therefore, the filling operation proceeds in the normal flow rate state. Incidentally, the control in which the opening / closing valve (20) is opened and the throttle device (22) is maintained in the normal flow rate state is the step (81) in FIG. 6 (the explanatory view of the operation of the invention of claim 1).
It corresponds to the control operation of.

At this time, the amount of water filling is measured by the flow meter (32), but when the state of filling water is approached, the output level from the flow meter (32) first reaches the level set by the variable resistor (R), After that, when the filling is completed, the voltage level finally set by the series circuit of the variable resistor (R) and the fixed resistor (R ₁ ) is reached.

Therefore, when the measured value of the flow meter (32) is smaller than the value set by the setting means (31) by a certain amount, the output of the second comparator (43) becomes "L" and the drive circuit (45). Output state changes and the aperture device (22) is set to the aperture state. The operation of setting the throttle device (22) in the throttled state when the measured value of the flowmeter (32) is in the fixed amount state smaller than the set value is shown in FIG. ) Corresponding to the control operation of steps (82) and (83).

After that, when an additional amount corresponding to the voltage level set by the fixed resistance (R ₁ ) is supplied, the flow meter (32)
And the set value by the setting means (31) match, the output circuit of the first comparator (42) causes the switch circuit (44) to operate and the on-off valve (20) to close. That is, the filling operation is completed. The operation of closing the on-off valve (20) when the measured value of the flow meter (32) matches the set value is the step (84) (8) of FIG. 6 (the explanatory view of the operation of the invention of claim 1).
It corresponds to the control operation of 5).

At this time, since the output level of the first comparator (42) is in the “L” state, this output is input to the reset terminal of the FF circuit (F) via the converter.
The FF circuit (F) is reset and each part of the control device (4) becomes non-conductive.

As described above, in the above embodiment, the flow rate is throttled in a certain section before the completion of the filling and the water hammer action is prevented, and the final filling amount is set by the setting means (31). It will be an exact match.

In this embodiment, the flow meter (32) is used as the detecting means (3), but the water level sensor (37) for detecting the water level in the bathtub (B) is used as the detecting means (3) as shown in FIG. It is also possible to employ it. In this case, as the control device (4), the one in which the flow meter (32) in FIG. 3 is replaced by the water level sensor (37) may be adopted. However, the variable resistor (R) and the fixed resistors (R ₁ ) (R ₂ ) must be set according to the signal level of the water level sensor (37).

Further, in the embodiment described above, the expansion device (22) is configured to be changed in two steps between the normal flow rate state and the throttle state, but it may be changed in three or more steps. A structure such as a rotary valve driven by a servo motor, which is capable of continuously adjusting the flow rate, and which gradually reduces the output from the drive circuit (45) corresponding to the change in the opening of the expansion device (22). It is also possible to do so. In this case, the output from the drive circuit (45) gradually decreases at the time when the flow rate becomes a certain amount less than the set flow rate, and the throttle device (22) having the above configuration operates according to the output. The opening gradually becomes smaller. That is, the flow rate is gradually reduced, and the water hammer effect is further alleviated. In addition, since the total flow rate in this throttle operation section is set to a constant value in advance,
The operation is started by the output of the second comparator (43) at the time when the flow rate value obtained by subtracting the total flow rate in the throttle section from the set amount of water filling is reached.

The diaphragm device (22) of the above type may be provided with a function of fully closing the circuit. In this case, the expansion device (22) functions as an on-off valve, and the water filling circuit (2) can be configured as shown in FIG. In this case, the expansion device (22) also functions as the opening / closing valve (20) (see the control of step (850) in FIG. 7 which is an explanatory view of the operation of the invention of claim 2). Also, as shown by the broken line in the figure, the on-off valve (2
It is also possible to use 0) together so as to close the opening / closing valve (20) after the time when the expansion device (22) of the above type is fully closed. In the latter case, in relation to the invention of claim 1, the filling operation section is a section from the start of filling to the closing of the on-off valve (20).

Furthermore, in the embodiment of FIG. 2, the flow meter (32) may be inserted upstream of the heat exchanger (10).

Note that the timing for stopping the filling operation after the squeezed state is set by comparing the measured value of the flow meter (32) with the set value of the amount of filling as in the first embodiment, and If the amount of supply in the state is set to a predetermined value in advance, a method of setting the timing of stopping the filling operation by the time set to this value, or the interval until the expansion device (22) stops filling In the case of the type of continuously reducing the flow rate with, the method of setting the time when the degree of reduction of the expansion device reaches the set value as the stop time of the water filling operation can also be adopted.

[Brief description of drawings]

1 is an explanatory view of the principle of the present invention, FIG. 2 is a schematic view of the first embodiment, FIG. 3 is an explanatory view of a control device (4), and FIG.
FIG. 5 is a schematic explanatory view of the embodiment, FIG. 5 is a schematic explanatory view of the third embodiment, FIG. 6 is a flow chart explaining the operation of the invention of claim 1, and FIG. 7 is an operation of the invention of claim 2. It is a flow chart, and in the figure, (1) …… Hot water heater (2) …… Hot water filling circuit (B) …… Bathtub (3) …… Detecting means (4) …… Control device (20) …… Opening / closing valve ( 22) …… Throttle device (31) …… Setting means (41) …… Throttle operation control circuit

Claims (2)

[Claims] 1. A detector (3) for detecting the amount of water filling is provided by filling the bathtub (B) with water from a water heater (1) through a water filling circuit (2). The output is input to the control device (4), and the water filling circuit (2) is shut off by the output of the control device (4) to stop the water filling operation and to insert the water into the water filling circuit (2). Moreover, the throttle device (22) for switching between the normal flow state and the throttle state of a smaller flow rate is operated at a predetermined timing, and the supply amount from the water filling circuit (2) is completed by this throttle device (22) before the completion of the water filling. In the water filling device of the bath device that is squeezed, the output from the detection means (3) and the output from the setting means (31) for setting the amount of water filling are input to the control device (4), and the control is performed. The device (4) receives the output from the detection means (3). A throttle operation control circuit (41) is provided for outputting a signal for changing the throttle device (22) from the normal flow rate state to the throttle state when it reaches a value smaller than the set value of the constant means (31) by a certain amount. Water filling device for bath equipment. 2. The diaphragm device (22) is so designed that, in the diaphragm state, the diaphragm device is finally operated to a front closed state.
A bath filling device in the bath device according to.