JP2003013478A - Toilet water-pouring system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To surely detect the use conditions of a flush toilet even in the case of a water cutoff. SOLUTION: When there is no detection history of no remaining hot water in a bathtub 20 (S3: YES), the water level of a water storage tank 101 is detected by a pressure sensor at a step 4. When difference between a reference water level Hs as a water level in the case of the high water level of the water storage tank 101 obtained by a toilet water-pouring test run and a detecting water level Hx detected by the pressure sensor 107 reaches a fixed value or more (such as 60 mm or more) (S4: YES), a lever installed to the flush toilet 100 is operated, and it is decided that water stored in the water storage tank 101 is drained to a stool as pouring water.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a toilet water injection system for injecting bath water into a water storage tank of a flush toilet.

[0002]

2. Description of the Related Art Conventionally, there is known a toilet water injection system capable of saving water by supplying remaining hot water in a bathtub (tub water) to a water storage tank of a flush toilet. In such a toilet water injection system, it is necessary to determine the usage status of the flush toilet and supply the remaining hot water. Therefore, the present applicant has already proposed the following toilet water injection system disclosed in JP-A No. 11-247254 (apparatus for utilizing miscellaneous water). This toilet water injection system forms a clean water supply channel that can always supply clean water to the water storage tank of the flush toilet, and detects the presence or absence of water flow by the water flow detection means provided in this clean water supply channel. The usage status of the flush toilet is determined by the method, and the remaining hot water in the bathtub is supplied based on the determination via a bath water supply path provided separately from the clean water supply path.

[0003]

However, in the above-mentioned toilet water injection system, when the water is cut off, clean water is not supplied, so that even if a flush toilet is used, water flow cannot be detected, and the remaining hot water is stored in the water tank. Could not be supplied to. The toilet water pouring system of the present invention has an object to solve the above problems and to reliably detect the usage status of the flush toilet even when water is cut off.

[0004]

A toilet water injection system according to claim 1 of the present invention for solving the above problems is a toilet water injection system provided with a bath water supply passage for supplying bath water to a water storage tank of a flush toilet. A pressure sensor provided in the bath water supply passage for detecting the water level in the water storage tank by pressure, and the water storage tank via the bath water supply passage based on the detection of a decrease in the water level in the water storage tank by the pressure sensor. And a bathtub water supply control means for stopping the supply of bathtub water after injecting the bathtub water into the water storage tank for a predetermined time or for a predetermined flow rate.

Further, the toilet water pouring system according to claim 2 of the present invention is the toilet water pouring system according to claim 1, wherein when the water in the water storage tank is drained to the flush toilet, the water level is detected to be full. The water level difference from
The gist is to calculate the predetermined time or the predetermined flow rate based on the obtained water level difference and the rate of increase of the water level in the water storage tank.

According to a third aspect of the present invention, there is provided the toilet water pouring system according to the second aspect, wherein the rate of increase in the water level is determined by the bath water supply control means that supplies the bath water to the water storage tank. The gist is to obtain it when the water is supplied for a predetermined time or a predetermined flow rate, and to update the value each time the water is drained to the flush toilet.

[0007] The toilet water pouring system according to claim 4 of the present invention is the toilet water pouring system according to claim 2 or 3, wherein water is supplied to the water storage tank for a predetermined amount of water or for a predetermined time of water filling. Drop it to detect the water level, drop the water again for a predetermined amount of water or for a predetermined water injection time, detect the water level and compare it with the previous water level, and then drop the water until the difference between the compared water levels is below the predetermined value. And the water level comparison is repeated, and the water level when the water level difference becomes equal to or less than the predetermined value is set as the water level when the water storage tank is full.

In the toilet water pouring system according to claim 1 of the present invention having the above-mentioned configuration, the bath water supply control means is based on the detection of the water level drop in the water storage tank of the flush toilet by the pressure sensor provided in the bath water supply passage. Starts supplying bath water to the water storage tank via the bath water supply passage. Further, since the pressure sensor detects the water level in the water storage tank by detecting the water pressure, the bath water flows through the bath water supply passage and is supplied to the water storage tank while the bath water is being supplied to the bath water supply passage. Since the pressure of the unstable bath water flowing through the tank is detected, the accurate water level in the water storage tank cannot be detected. Therefore, it is difficult to supply the optimum amount of bath water to the water storage tank even if the supply of bath water is stopped based on the detection of the water level by the pressure sensor. Therefore, in order to supply an optimum amount of bath water to the water storage tank, the bath water supply control means controls the water supply to the water storage tank after pouring the water into the water storage tank for a predetermined time or a predetermined flow rate.

According to a second aspect of the present invention, in the toilet water pouring system, the bath water is supplied to the water storage tank based on the water level difference between when the water is drained to the flush toilet and when it is full and the rate of increase in the water level of the water storage tank. By calculating the predetermined time or the predetermined flow rate, the optimum amount of bath water can be supplied to the water storage tank.

In the toilet water pouring system according to the third aspect of the present invention, the rate of rise of the water level in the water storage tank is calculated when the bath water is supplied to the water storage tank, and the value is updated, so that a more optimal amount can be obtained at all times. The bath water can be supplied to the water storage tank.

According to a fourth aspect of the present invention, when the toilet water pouring system is installed, the water level is detected by dropping a predetermined amount of water or a predetermined pouring time into the water storage tank and detecting the water level again. The amount of water is dropped or the water is dropped for a predetermined time, the water level is detected and compared with the previous water level, and the dropping and water level comparisons are repeated until the difference in the compared water levels falls below a predetermined value. By performing a test operation in which the water level detected at the end when the difference becomes equal to or less than the predetermined value is used as the water level when the water tank is full, an accurate water level when full can be set according to the installation situation. In addition, since an overflow pipe for flowing water having a water level higher than necessary to the toilet bowl is usually provided in the water storage tank, the water level in the water storage tank does not exceed the water level determined by the overflow pipe. That is,
The water level determined by this overflow pipe is the water level when full. In addition, in general, a water tank is provided with a clean water supply channel for supplying clean water separately from the bath water supply channel, so it is possible to supply clean water without supplying the bath water from the bath water supply channel. It is possible to use a pressure sensor to detect the water level when water is supplied from the channel when the water level is full and to set it as the water level when the channel is full.In this case, air bubbles will flow into the bath water supply channel. There is a risk that the accurate water level cannot be detected. On the other hand, in the toilet water injection system of the present invention,
Since the air in the bathtub water supply passage can be purged, it is possible to accurately detect and set the water level when the water is full.

[0012]

BEST MODE FOR CARRYING OUT THE INVENTION In order to further clarify the structure and operation of the present invention described above, a preferred embodiment of the toilet water injection system of the present invention will be described below.

FIG. 1 is a schematic configuration diagram of a bath water heater 1 with a toilet water pouring function (hereinafter, simply referred to as water heater 1) according to an embodiment of the present invention. The water heater 1 is roughly classified into a circulation heating unit 4 that circulates and reheats hot water in the bathtub 20.
0 and the hot water supply unit 50 that heats tap water to be discharged
And a bathtub water supply unit 60 that supplies pouring and pouring water to the washing machine 90 and the remaining hot water in the bathtub 20 to the washing machine 90 and the flush toilet 100.

The circulation heating section 40 includes a bath heat exchanger 42 for heating the bath water, a return pipe 46 for sending the bath water to the bath heat exchanger 42, and the bath water heated by the bath heat exchanger 42 in the bath 20. A circulation heating path is formed with the outgoing pipe 47 sent to the return pipe 46 and the outgoing pipe 47 is connected to the bath heat exchanger 42.
A bath bypass pipe 34 that bypasses the This return pipe 4
In FIG. 6, a bath water thermistor 24 that detects the hot water temperature before reheating, a circulation pump 22 that circulates the bath water, and a running water switch 23 that confirms the flow of this circulating water are provided in order from the upstream side.
Is provided. On the other hand, in the outflow pipe 47, the bath heat exchanger 4
A bath hot water thermistor 25 for detecting the hot water temperature after reheating is provided in the vicinity of 2. The bath heat exchanger 42 is provided above the bath combustion chamber 49 and is heated by the bath burner 41.

The hot water supply unit 50 supplies a water supply pipe 56 connected to a water pipe, a hot water supply heat exchanger 52 for heating water supplied from the water supply pipe 56, and a flow for sending hot water heated by the hot water supply heat exchanger 52. A hot water supply heat exchanger 52 provided with a hot water outlet pipe 57 serving as a passage.
Is provided above the hot water supply combustion chamber 59 and is heated by the hot water supply burner 51. The hot water supply burner 51 is composed of three sets of burners having different combustion capacities, and burners to be burned are switched according to the amount of combustion. In the water supply pipe 56, in order from the upstream,
A flow rate sensor 26 for detecting the amount of incoming water, a hot water supply / thermistor 27 for detecting the incoming water temperature, and a motor-driven water amount control valve 28 for adjusting the flow rate of the passing water so as to obtain the set hot water temperature are provided. A hot water supply heat exchanger outlet thermistor 12 for detecting the hot water temperature after heat exchange is provided.

A hot water supply bypass pipe 36 that bypasses the hot water supply heat exchanger 52 is connected between the hot water supply pipe 56 and the hot water discharge pipe 57, and the bypass valve 14 that opens and closes the hot water supply bypass pipe 36.
Is provided. A hot water supply tapping thermistor 15 for detecting the temperature of the hot water mixed with the water passing through the hot water supply bypass pipe 36 and the hot water after heat exchange is provided in the hot water supply pipe 57 downstream of the connection point with the hot water supply bypass pipe 36. Further downstream thereof, it is connected to a general hot water supply pipe 37 that communicates with a hot water supply scallop 21 (general hot water supply tap) of a kitchen or the like. Further, a drop pipe 30 for supplying hot water to the bathtub 20 is provided so as to be branched from a hot water discharge pipe 57 downstream of the hot water discharge hot water thermistor 15. The drop pipe 30 connects the hot water supply unit 50 and the circulation heating unit 40, and detects the flow amount from the hot water supply unit 50 to the circulation heating unit 40 and the drop solenoid valve 31 that opens and closes the drop pipe 30 in order from the upstream side. A drop flow sensor 32 and two check valves 33 for preventing backflow are provided.

The hot water supply unit 50 and the circulation heating unit 40 are each provided with a common air supply duct 35 serving as a supply path for combustion air, and one fan 18 driven by a fan motor 19 causes air to flow into the bath combustion chamber. 49 and the hot water supply combustion chamber 59 are simultaneously supplied. Further, the gas flow passage is provided with an original solenoid valve 10 for opening and closing the gas flow passage and a proportional valve 11 for controlling the gas amount according to the amount of energization, in order from the upstream side, and the hot water supply side gas flow passage is provided on the downstream side thereof. And the gas flow path on the bath side. On the hot water supply side, hot water supply gas solenoid valves 55 that independently open and close the gas flow paths to the three sets of burners are provided, and independent combustion control is performed. On the other hand, on the bath side, a bath gas solenoid valve 45 for opening and closing the bath side gas flow path is provided. The bath burner 41 and the hot water supply burner 51 are provided with electrodes 43 and 53 for igniting gas by the operation of the igniter 13 and frame rods 44 and 54 for detecting combustion flames. Are connected to each other and predetermined controls such as hot water discharge and reheating are performed. The controller 9 is mainly composed of a microcomputer, and is connected to a hot water supply remote controller 58 for externally operating the hot water supply operation and a bath remote controller 48 for externally operating the bath operation.

The hot water supply remote controller 58 sets the set temperature to 38 to 48.
It can be set in the range of ° C and values such as 50 ° C and 60 ° C. Then, controller 9 performs hot water temperature control such as controlling the combustion amount of hot water supply burner 51 so that the hot water supply temperature of hot water supply unit 50 approaches the set temperature set by hot water supply remote controller 58.

Here, the operation of reheating the bath water by the circulation heating section 40 will be described. When the bath remote controller 48 gives an instruction to start the reheating operation, the circulation pump 22 is driven to start circulating the bath water. When the bath water is circulating by the running water switch 23 and the temperature of the bath water detected by the bath water thermistor 24 is equal to or lower than the set temperature in the reheating operation, the fan 18 rotates and the original solenoid valve is operated. 10 and the bath gas solenoid valve 45 open and the bath burner 41
When gas is supplied to the igniter, the igniter 13 is activated and the bath burner 41 is ignited. While circulating the bath water, the bath burner 41 heats and reheats. Then, while the running water switch 23 detects the circulation of the bath water, the combustion of the bath burner 41 is continued. On the other hand, when the return pipe 46 and the outflow pipe 47 are clogged or the bath water runs out and the running water switch 23 no longer detects the circulation of the bath water, the combustion of the bath burner 41 is stopped. When the bath water thermistor 24 detects that the temperature of the bath water being circulated and heated reaches the set temperature, the bath burner 41 is extinguished and the circulation pump 22 is stopped.

The flush toilet 100 has a structure in which a stopper (not shown) provided on the bottom surface of the water storage tank 101 is temporarily opened by operating a lever (not shown) to drain the water stored in the water storage tank 101 into a toilet bowl as flush water. A clean water supply pipe 102 for supplying clean water to 101 is connected. In the middle of the clean water supply pipe 102, the flow path area is reduced in association with the floating ball 103 that rises as the water level in the water storage tank 101 rises, and the flow path is completely raised by rising to a predetermined water level. A well-known ball tap 104 that is configured to shut off is provided. Further, in the water storage tank 101, in order to prevent the water in the water storage tank 101 from overflowing even if the water injection to the water storage tank 101 does not stop due to a failure of the ball tap 104, the water of an excessive water level is used in the toilet bowl. A flow overflow pipe 109 is provided. Also, the water storage tank 10
Toilet water injection pipe 105 for supplying the remaining hot water in the bathtub 20 to
However, the tip is provided so as to be below the water surface when the inside of the water storage tank 101 reaches the minimum water level.

The washing machine 90 is connected to a washing water injection pipe 92 via a water solenoid valve 91 that opens and closes a water supply passage, and the water solenoid valve 9 is connected.
By controlling the opening and closing of 1, the water injection operation in the washing operation and the rinsing operation is performed.

The bath water supply unit 60 is a water supply pipe 61 connected to a water supply pipe 56 downstream of the water amount control valve 28 of the hot water supply unit 50, and a hot water supply communicating with the hot water supply pipe 57 via the drop pipe 30. A pipe 62, and a water supply solenoid valve 63 and a hot water supply solenoid valve 64 for opening and closing the respective flow paths. The hot water supply pipe 62 is provided with a check valve 2 for preventing backflow. The water supply pipe 61 and the hot water supply pipe 62 join together on the downstream side of the respective solenoid valves and are connected to the main supply pipe 65. The main supply pipe 65 is provided with two check valves 3 for preventing backflow of the supplied hot water and water, and a pouring flow rate sensor 4 for detecting the pouring amount of the hot water to the washing machine 90.

A bath water supply pipe 66 for supplying bath water to an external water supply destination such as a washing machine 90 or a water storage tank 101 of the flush toilet 100 is connected to the main supply pipe 65, and the bath water supply pipe 66 circulates. Outgoing pipe 4 of heating unit 40
Connected to 7. A switching valve 67 that switches the flow path of the bath water to either the bath 20 side or the external water supply destination side is provided at a branch portion of the outflow pipe 47 to the bath water supply pipe 66. Further, in FIG. 1, when the switching valve 67 is in the closed position, the flow path of the bath water is switched to the bath 20 side (state a), and the switching valve 67 is in the open position. The state where the flow path of the bath water is switched to the external water supply destination side (state b). The arrows a and b in FIG. 1 represent the directions of the bath water in the states a and b, respectively.
The main supply pipe 65 is connected to the external supply pipe 5 that supplies clean water and residual hot water to the external water supply destination on the downstream side of the connection portion with the bath water supply pipe 66. The pouring water flow rate sensor 4 provided in the main supply pipe 65 is provided upstream of the connection point with the bath water supply pipe 66 in order to prevent hair or the like in the bath water from being entangled. The external supply pipe 5 branches into a washing water injection pipe 92 and a toilet water injection pipe 105 on the way. In the toilet water injection pipe 105, a toilet opening / closing valve 106 that opens and closes a flow path to the water storage tank 101 in order from the upstream side, and a water storage tank 101.
A pressure sensor 107 for detecting the water level inside is provided by water pressure. The toilet opening / closing valve 106 and the pressure sensor 1
07 is formed as a separate toilet unit 108 from the water heater 1. Further, a pouring remote controller 68 for performing external operations such as switching the pouring mode to the washing machine 90 and supplying the remaining hot water to the water storage tank 101 of the flush toilet 100 is provided, and the pouring remote controller 68 is the controller 9. Connected with.

The pouring remote controller 68, as shown in FIG.
A washing mode switch 71 for selecting the pouring mode during the washing operation of the washing machine 90, a rinse mode switch 72 for selecting the pouring mode during the rinsing operation, and a display panel for displaying the selected pouring mode and the like. 73, a washing switch 74 for switching on / off the pouring operation to the washing machine 90, and a toilet switch 75 for switching on / off the operation of supplying the remaining hot water to the water storage tank 101.

As the pouring mode during the washing operation, the bathtub 2
The remaining hot water of 0 is supplied to the washing machine 90 as it is, and the remaining hot water of the bathtub 20 is set to 40 by the bath heat exchanger 42.
The remaining hot water washing mode, which is heated to ℃ and supplied, is mixed with hot water from the hot water supply pipe 62 and cold water from the water supply pipe 61.
A hot water washing mode of supplying as 0 ° C mixed hot water, a cold water washing mode of directly supplying cold water from the water supply pipe 61, a hot water from the hot water supply pipe 62 and a cold water from the water supply pipe 61 are mixed to obtain a temperature of 30 ° C. There are five types of hot water washing modes for wool supplied as mixed hot water, and in the rinse mode, there are two types of hot water (40 ° C.) rinse mode and water rinse mode.

Here, a water washing mode, a remaining hot water washing mode,
The pouring control in each of the hot water (including wool) washing modes will be described. The pouring control in the water rinsing mode and the hot water rinsing mode is the same as the pouring control in the water washing mode and the hot water rinsing mode, respectively. In the water washing mode, the hot water supply solenoid valve 64 is closed and the switching valve 67 is switched to the state a,
The water supply solenoid valve 63 is opened. Therefore, when the water solenoid valve 91 provided in the washing machine 90 is opened, the water from the water pipes causes the water supply pipe 56, the water supply pipe 61, the main supply pipe 65, the external supply pipe 5, and the washing water supply pipe 92 to flow. It flows and is supplied to the washing machine 90.

In the hot water washing (including hot water washing for wool) mode, the switching valve 67 is switched to the state a, the hot water supply solenoid valve 64 and the water supply solenoid valve 63 are simultaneously opened, and then either one is used for temperature adjustment. Open only. Such a process is defined as one cycle, and when the one cycle is completed, the temperature of the hot water poured into the washing machine is the target pouring temperature (hot water washing mode: 40 ° C,
The controller 9 controls opening / closing of the hot water supply solenoid valve 64 and the water supply solenoid valve 63 so that the hot water washing mode for wool is 30 ° C. Then, by repeating this cycle, a desired pouring amount is obtained. Here, the pouring route to the washing machine 90 when the hot water supply solenoid valve 64 is opened will be described. When the water solenoid valve 91 of the washing machine 90 is opened with the hot water supply solenoid valve 64 open, water is passed through the hot water supply unit 50 to start the burning operation of the hot water supply burner 51, and the heated hot water comes out of the hot water outlet pipe 57. ,
It is supplied to the washing machine 90 by flowing through the drop pipe 30, the hot water supply pipe 62, the main supply pipe 65, the external supply pipe 5, and the washing water injection pipe 92. Therefore, when the hot water supply solenoid valve 64 and the water supply solenoid valve 63 are simultaneously opened, hot water and water are simultaneously supplied to the main supply pipe 65 and mixed, and the mixed hot water is supplied to the external supply pipe 5 and the washing water injection pipe 9
2 to be supplied to the washing machine 90.

In the remaining hot water washing mode, the water supply solenoid valve 63,
The hot water supply solenoid valve 64 is closed, the switching valve 67 is switched to the state b, and the circulation pump 22 is driven. Therefore, the washing machine 9
When the water solenoid valve 91 provided at 0 is opened, the remaining hot water in the bath 20 returns to the return pipe 46, the going pipe 47, and the bath water supply pipe 6
6, it flows through the main supply pipe 65, the external supply pipe 5, and the washing water injection pipe 92, and is supplied to the washing machine 90. In the residual hot water heating and washing mode, the residual hot water is heated and supplied by the bath burner 41 while passing through the bath heat exchanger 42 while the residual hot water is being supplied to the washing machine 90 as described above. . still,
The temperature after mixing the remaining hot water that has passed through the bath heat exchanger 42 and the hot water that has passed through the bath bypass pipe 34 is 4
The controller 9 controls the combustion of the bath burner 41 and the capacity of the circulation pump 22 so that the temperature becomes 0 ° C.

Next, in order to set the water level when the water storage tank 101 is full, the control process performed by the controller 9 during the toilet water injection test operation performed when the water heater 1 is installed is shown in the flowchart of FIG. It demonstrates using. The pressure sensor 107 includes the pressure sensor 107 and the water storage tank 101.
The water level difference between the pressure sensor 107 and the water surface of the water storage tank 101 varies depending on the installation condition. Therefore, the water level when the water storage tank 101 is full is determined by such a water heater. It cannot be uniquely determined as a value unique to 1. For this purpose, the following control is performed. When the toilet switch 75 is pressed when the water level when the water tank 101 is full is not set (S
1) This routine is started, and first, the switching valve 67 is switched to the state a and the toilet opening / closing valve 106 is opened (S2). Then, the water supply solenoid valve 63 is opened (S3), and the clean water is supplied to the water storage tank 101 until the pouring flow rate sensor 4 detects that a predetermined amount (for example, 10 liters) of clean water has been supplied. Supply. When a predetermined amount of clean water is supplied (S4: YE
S), the water supply solenoid valve 63 is closed (S5), the supply of clean water is stopped, and after waiting for 5 seconds for the water in the water storage tank 101 to settle down, the water level in the water storage tank 101 is measured by the pressure sensor 107.
Is detected and stored as H0 (S6). Subsequently, the water supply solenoid valve 63 is opened (S7), and the water storage tank 101 is again opened.
A predetermined amount (for example, 10 liters) of clean water is supplied to.
When a predetermined amount of clean water is supplied (S8: YES), the water supply solenoid valve 63 is closed (S9), the clean water supply is stopped, and after waiting for 5 seconds for the water in the water storage tank 101 to settle down, the water storage tank 101 The water level inside is detected by the pressure sensor 107 and stored as H1 (S10). Then, in step 11, the water level H1 detected in step 10 is compared with the water level H0 detected in step 6, and if the difference is 30 mm or more (S
11: NO), after H1 detected in step 10 is replaced by H0 by rewriting (S12), the process returns to step 7 and the above-described control is repeated. That is, the water level detected immediately before is compared with the water level detected this time. And H1
And the difference between H0 and H0 is less than 30mm (S11: YE
S), H1 at that time is stored in the water storage tank 101 in step 13.
The standard water level Hs is set as the water level when the
7 is switched to the state b and the toilet opening / closing valve 106 is closed (S
14) and the control ends (S15). In addition, water tank 1
01 is provided with an overflow pipe 109 for flowing water of an excessive water level to the toilet bowl, so that the water storage tank 101
The water level inside rises only up to a certain level. This water level is the water level at the time of full water set as the reference water level Hs.
Further, at the time of this toilet water injection test operation, the main plug of the clean water supply pipe 102 is closed so that clean water is not supplied. Further, as a method of setting the water level when the water is full, the pressure sensor 107 measures the water level when the water is full by supplying the clean water from the clean water supply pipe 102 without supplying the bath water from the toilet water injection pipe 105. However, in this case, bubbles may flow into the toilet water injection pipe 105 and an accurate water level may not be detected.

Next, the water storage tank 10 of the flush toilet 100
The control process performed by the controller 9 when supplying the remaining hot water to 1 will be described with reference to the flowchart of FIG. Even when the remaining hot water is supplied to the water storage tank 101, the clean water is supplied from the clean water supply pipe 102. When the toilet switch 75 is pressed to supply the remaining hot water to the water storage tank 101 of the flush toilet 100 (S1), this routine is started, and the switching valve 67 is first switched to the state b (S).
2). If there is no detection history that there is no remaining hot water in the bathtub 20 (S3: YES), the pressure sensor 10 is determined in step 4.
7 detects the water level of the water storage tank 101, and the difference between the reference water level Hs, which is the water level when the water storage tank 101 is full and is set by the toilet water injection test operation, and the detected water level Hx detected here is a predetermined value or more (for example, 60 mm or more. ) Becomes (S
4: YES), it is determined that the lever provided in the flush toilet 100 has been operated and the water stored in the water storage tank 101 has been drained to the toilet bowl as running water. After that, in order to wait for the water in the water storage tank 101 to settle down, wait for 3 seconds to pass (S5: YES), detect the water level after settling and store it as H1, and then drive the circulation pump 22. Then, the toilet opening / closing valve 106 is opened (S6). At this time, at the same time, the supply time T for supplying the remaining hot water to the water storage tank 101 is calculated. The method of calculating the supply time T will be described later. The first supply time T when this routine is started
Is an initial value (for example, 10 seconds), and the supply time T used from the second time is obtained by the calculation here. Then, it is judged whether the running water switch 23 for checking the flow of the circulating water is in the ON state (S
7) It is determined whether or not there is remaining hot water in the bathtub 20.

If the running water switch 23 is on (S
7: YES), in step 8, the remaining hot water is stored in the water storage tank 10
The circulation pump 22 is continuously driven until it is determined that the predetermined supply time T for supplying water to the toilet 1 has passed, and the toilet water injection pipe 1
The remaining hot water is supplied to the water storage tank 101 from 05. At this time, clean water from the clean water supply pipe 102 is also supplied to the water storage tank 101. Supply time T from start of supply of remaining hot water
When (S8: YES), the toilet on-off valve 106 is closed to stop the operation of the circulation pump 22 (S9), the supply of the remaining hot water to the water storage tank 101 is stopped, and the water storage tank 101 for calculating T is calculated. The water level is detected and stored as H2 (S10). After that, if the water level change in the water storage tank 101 is no longer detected (S11: YES), the water storage tank 1
It is determined that 01 is full and the supply of clean water is stopped, and the process proceeds to step 12. The pressure sensor 10 when it is determined in step 12 that the change in water level from the reference water level Hs has disappeared
When the difference from the detected water level Hx detected in 7 is equal to or more than a predetermined value (for example, 60 mm or more) (S12: YES), clean water is not supplied due to water cutoff or the like, and thus a predetermined amount or more of water is supplied to the water storage tank 101. If it is determined that the hot water has not been formed, the process returns to step 6 to further supply the remaining hot water. If the difference between Hs and Hx is less than or equal to the predetermined value (S12: NO), it is determined that the remaining hot water and tap water have been sufficiently supplied to the water storage tank 101, and the water level in the water storage tank 101 at this time is determined by the pressure sensor. The detected water level is detected by 107 and is stored and updated by replacing the detected water level with the reference water level Hs as the water level when the water storage tank 101 is full (S13). Subsequently, the rate of increase K of the water level in the water storage tank 101 when the remaining hot water and the clean water required to calculate the supply time T are supplied together is calculated, and after the memory is updated (S19), the process proceeds to step 3. Returning to step 4, it waits until the flush toilet 100 is used again. The method of calculating the rate of increase K will be described later. The water storage tank 10
The standard water level Hs, which is the water level when the water level is full, is set to the initial value set in the toilet water injection trial run when the toilet switch 75 is turned on, but is constantly updated in step 13 by repeating such processing. Go.

On the other hand, in step 7, when the running water switch 23 is continuously off for 1 minute (S7: NO),
Toilet opening / closing valve 1 when it is determined that there is no remaining hot water in the bathtub 20
06 is closed to stop the operation of the circulation pump 22 (S1
4) Return to step 3. In this case, there is a detection history that there is no remaining hot water in step 3 (S3:
NO), the process proceeds to step 15 and the bathtub 2 for automatic bath operation etc.
It waits until the operation of dropping hot water to 0 is performed (S15: NO). When hot water is supplied to the bathtub 20 (S
15: YES), the supplied bath water is stored in the water storage tank 1
01, but before that, the switching valve 67 is switched to the state a, the toilet opening / closing valve 106 is opened, the water supply solenoid valve 63 is opened (S16), and clean water is stored in the water storage tank 101. Supply. This is to prevent the water in the toilet water injection pipe 105 from being extruded and emptied when the circulation pump 22 is driven, even though there is no remaining hot water, and the pressure sensor 107 cannot accurately detect the water level. This is done to fill the toilet water injection pipe 105 with water for cleaning.
When the pouring water flow sensor 4 detects that a predetermined amount (for example, 5 liters) of clean water has been supplied (S17: YES),
The water supply solenoid valve 63 is closed, the toilet opening / closing valve 106 is closed, the switching valve 67 is switched to the state b (S18), the process returns to step 4, and waits until the flush toilet 100 is used. When the flush toilet 100 is used, the bath water is supplied to the water storage tank 101 together with the clean water from the clean water supply pipe 102 according to the control described above.

Now, a method of calculating the predetermined supply time T for supplying the remaining hot water to the water storage tank 101 and a method of calculating the rate of increase K of the water level of the water storage tank 101 required for obtaining the supply time T will be described. When the toilet switch 75 is turned on, T has an initial value T ₁ (for example, 10 seconds). And
The value T _n of the nth (n ≧ 2) times when the above control is repeated is calculated by the equation (1). _{T n = (Hs-H1)} / K n-1 ······ (1) where K _{is, K n-1 = (H2} -H1) / T n-1 ······ (2 ) Is. Hs is the reference water level, H1 is the water level detected in step 6, and H2 is the water level detected in step 10. K
Is the rate of increase in the water level of the water storage tank 101 when both the remaining hot water and the clean water are being supplied to the water storage tank 101. By dividing the difference from the water level H1 at that time, it is possible to find the supply time T at which the water storage tank 101 is full when the supply of the remaining hot water is stopped. In this way
It is possible to constantly correct the supply time T for supplying the remaining hot water to the water storage tank 101 to obtain the optimum time for supplying the remaining hot water to the water storage tank 101. In addition, until step 10, that is, while the remaining hot water is being supplied, the water storage tank 101
If the water inside overflows from the overflow pipe 109, an accurate rate of rise K of the water level cannot be obtained. Therefore, in order to prevent the water from overflowing the overflow pipe 109, the initial value T ₁ of the supply time T is set to a certain level. It is necessary to keep it small enough.

As described above, in the toilet water pouring bath water heater 1 according to the present embodiment, the flush toilet 100 is used based on the detection of the water level in the water storage tank 101 by the pressure sensor 107 provided in the toilet water injection pipe 105. Since the situation is determined, it is possible to determine the use situation of the flush toilet 100 without any problem even when the water is cut off. Further, in comparison with the fact that the user of the flush toilet 100 has to manually supply the water stored in the bathtub 20 or the like with a bucket or the like to the water storage tank 101 at the time of normal water interruption, this embodiment The bath water heater 1 with a toilet water injection function is very comfortable because it can automatically supply bathtub water.

The water level H when the water storage tank 101 is full
s and the water level H1 when the flush toilet 100 is used are divided by the rate of rise K of the water level in the water storage tank 101 when both the clean water and the bath water are supplied to the water storage tank 101 to supply the bath water. By determining the time T, the amount of clean water used can be minimized and the water in the bathtub can be maximized, which improves the economy. That is, the bath water is stopped before the water storage tank 101 is full, or the bath water is not supplied further even though the water storage tank 101 is full. Water injection control can be performed so that the supply is stopped at the same time. Further, the water level increase rate K is calculated during the control processing performed by the controller 9 when the toilet water is injected, and the updating of the value is repeated, so that a more optimal amount of bath water can be supplied. Further, by constantly calculating and updating the rate of rise K of the water level in this way, even when the conditions change suddenly, for example, when water is cut off,
An appropriate amount of bath water can be supplied. Since the water level (standard water level Hs) of the water storage tank 101 when it is full is obtained by the toilet water injection test operation, the water storage tank 101 and the pressure sensor 107 can be installed without worrying about the height relationship and the workability is improved. improves. Further, during this toilet water injection test operation, air purging inside the toilet water injection pipe 105 can be performed, so that an accurate water level at the time of full water can be detected and set. In addition, a bathtub water supply unit 60 that supplies pouring water and pouring water to the washing machine and the remaining hot water in the bathtub to the washing machine and the flush toilet.
By incorporating the bath water supply unit 60, workability such as mounting can be further improved, compared with a conventional appliance formed as a unit separate from the water heater with bath. Furthermore, the water storage tank 101 set by the toilet water injection trial run
A more accurate full water level can be set by constantly correcting the full water level (reference water level Hs) during the control process performed by the controller 9 during the toilet water injection. As a result, the supply time T becomes even more optimal.

Although the embodiments of the present invention have been described above, the present invention is not limited to these embodiments, and it is needless to say that the present invention can be implemented in various modes without departing from the scope of the present invention. is there. For example, in the bathroom water heater 1 with a toilet water pouring function of the present embodiment, when the pressure sensor 107 detects that the water level in the water storage tank 101 has decreased, and the use of the flush toilet 100 is detected, a predetermined supply time T Only the bath water for the water storage tank 101
However, the control may be performed so as to drop by a predetermined supply amount Q. In this case,
The control process performed by the controller 9 is different from the control process in which the supply time T is dropped, in that the determination that the supply time T has elapsed in step 8 is changed to determine that the supply amount Q has been dropped. Then, in step 6, Q is calculated, and in step 19, the rate of rise K ′ of the water level of the water storage tank 101 per flow rate is calculated. The method of calculating the supply amount Q performed in step 6 is the same as the method of calculating the supply time T, and the method of calculating the rate of increase K ′ of the water level per flow rate performed in step 19 is the same as the method of calculating the water level per hour. The method of calculating the rate of increase K is similar to the method of calculating the rate of increase K, and is calculated as follows. Toilet switch 7
When 5 is turned on, Q takes an initial value Q ₁ (for example, 4 liters), and n (n
The value _{Q n} of ≧ 2) th is calculated by the equation (3). _{Q n = (Hs-H1)} / K 'n-1 ······ (3) where K' _{is, K 'n-1 = (} H2-H1) / Q n-1 ·····・ It is (4). In this case, it is necessary to detect the amount of bath water dropped in the water storage tank 101. Therefore, the pouring flow rate sensor 4 is provided in the main supply pipe 65 on the downstream side of the connection point with the bath water supply pipe 66.
Is used to detect the supply amount Q.

Further, in the toilet water filling test operation for setting the reference water level Hs which is the water level when the water storage tank 101 is full, a control for dropping a predetermined amount (for example, 10 liters) of clean water into the water storage tank 101 in step 4 and step 8. However, the control may be such that the clean water is dropped for a predetermined time (for example, 1 minute).

[0038]

As described in detail above, the first aspect of the present invention
According to the toilet water injection system described above, even when the water is cut off, it is possible to determine the usage status of the flush toilet without any problem and supply the bath water to the water storage tank through the bath water supply passage.
In addition, it is possible to automatically supply the bath water without the problem that the user of the flush toilet has to manually supply the water to the water storage tank using a bucket etc. It is a comfortable one.

Further, according to the toilet water pouring system of the second aspect of the present invention, the bath water supplied to the water storage tank does not unnecessarily overflow or become too small, and an optimum amount of bath water is stored in the water storage tank. It can be supplied and is very economical.

Further, according to the toilet water pouring system of the third aspect of the present invention, the rate of rise of the water level in the water storage tank is calculated every time the water is drained to the flush toilet, and the value is constantly updated. As a result, an optimum amount of bath water can be supplied to the water storage tank, which makes it even more economical.

Further, according to the toilet water pouring system of claim 4 of the present invention, since the water level when the water tank is full can be set according to the installation condition, the position with the water tank when the toilet water pouring system is installed. The workability is improved without considering the relationship.

[Brief description of drawings]

FIG. 1 is a schematic configuration diagram of a bath water heater with a toilet water injection function according to the present embodiment.

FIG. 2 is an external view of a pouring remote controller.

FIG. 3 is a flowchart showing a control process performed by a controller in a toilet water filling test operation.

FIG. 4 is a flowchart showing a control process performed by the controller when supplying the remaining hot water in the bathtub to the water storage tank of the flush toilet.

[Explanation of symbols]

1 ... Bath water heater with toilet water injection function, 5 ... External supply pipe, 9
... controller, 20 ... bathtub, 22 ... circulation pump, 46
... Return pipe, 47 ... Outgoing pipe, 65 ... Main supply pipe, 66 ... Bath water supply pipe, 100 ... Flush toilet, 101 ... Water tank,
105 ... Toilet water injection pipe, 107 ... Pressure sensor, 108 ...
Toilet unit.

Claims (4)

[Claims] 1. A toilet water injection system having a bath water supply passage for supplying bath water to a water storage tank of a flush toilet, wherein a pressure sensor is provided in the bath water supply passage and detects the water level in the water storage tank by pressure. And, starting the supply of bath water to the water storage tank via the bath water supply path based on the detection of the water level drop in the water storage tank by the pressure sensor, after pouring water into the water storage tank for a predetermined time or a predetermined flow rate. A toilet water injection system, comprising: bath water supply control means for stopping the supply of bath water. 2. The water level when the water in the water storage tank is drained to the flush toilet is detected to obtain a water level difference from the water level when the water is full, and the obtained water level difference and the rate of increase of the water level in the water storage tank. The toilet water pouring system according to claim 1, wherein the predetermined time or the predetermined flow rate is calculated based on 3. The rate of rise of the water level is obtained when the bath water supply control means supplies bath water to the water storage tank for a predetermined time or a predetermined flow rate, and the value is updated each time the flush toilet is drained. The toilet water injection system according to claim 2. 4. The water level is detected by dropping water into the water storage tank for a predetermined amount of water or for a predetermined time of water injection to detect the water level, and then again dropping water for a predetermined amount of water or for a predetermined time of water injection to detect the water level. Compared with the previous water level,
The dropping and the water level comparison are repeated until the compared water level difference becomes a predetermined value or less, and the water level when the water level difference becomes the predetermined value or less is set as the water level when the water storage tank is full. The toilet water injection system according to claim 2 or 3.