JP3674185B2 - Bath drop abnormality monitoring device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a bath drop abnormality monitoring apparatus that monitors a drop abnormality such as leakage of hot water when a bathtub tap is forgotten to be closed when automatic dropping from a water heater into a bathtub.
[0002]
[Prior art]
Conventionally, when hot water or water from a water heater is automatically dropped into a bathtub, a fixed time limit, for example, a sufficiently long time of 30 minutes or more, has been adopted as a detection method for dropping abnormalities caused by forgetting to close the drain plug of the bathtub. Then, if the water level does not become more than the recirculating water level at which the water level can be detected even after the time has elapsed, it has been determined that there is an abnormality in dropping. In addition, even after reaching a water level where the water level can be detected and recirculated, if it does not reach the set water level even after a certain sufficiently long time limit, for example 30 minutes, it is determined that there is an abnormality in dropping. It was.
[0003]
[Problems to be solved by the invention]
However, in the conventional drop abnormality determination method as described above, when the drain plug is not completely closed but is slightly closed, or when the drain plug is clogged slightly and the drainage capacity is reduced, etc. Since the drop flow rate exceeds the drainage volume, the water level gradually increases as long as the drop is being carried out, the water level exceeds the water level that can be recirculated within the limit time, and reaches the set water level within the limit time. However, since it was not determined that the drainage was abnormal, there was a problem that water leakage continued even after the dropping was finished and a large amount of water was eventually wasted. And the said time limit had the problem that the capacity | capacitance of a bathtub will become a large value inevitably because it becomes the numerical value of the greatest common divisor when the kind and the amount of dropping water are considered.
[0004]
Therefore, the present invention eliminates the above-described problem of detection of dropping abnormality, reduces the amount of wasted water as much as possible, and can determine and monitor dropping abnormality due to water leakage etc. in a shorter time. An object is to provide an abnormality monitoring device.
[0005]
[Means for Solving the Problems]
  To achieve the above object, the bath drop abnormality monitoring apparatus of the present invention is, SalaryThis is a device that monitors the drop abnormality due to forgetting to close the drain tap of the bathtub when hot water or non-heated water from the water heater is automatically dropped into the bathtub and supplies hot water, and a drop flow sensor that detects the drop flow rate and the drop is the bathtub The recirculating water level determining means for determining whether or not the recirculating water level has been reached, the bathtub water level sensor for detecting the bathtub water level above the recirculating water level, and the drop reaches the recirculating water level of the bathtub. The flow value obtained by learning the drop accumulated flow value required for the bath water level to rise at a constant water level by using one or a plurality of accumulated flow values required for raising the constant water level after adding the constant flow value to the learned value And a reference flow rate value storage means for storing the calculated reference flow rate value. If, in that the integrated flow rate value in after reaching Reheating recyclable water level in the current has an abnormality determining unit darken determining abnormality darken by whether a certain level rise before the above said criterion flow valueFirstIt has the characteristics of
  Further, the bath drop abnormality monitoring device of the present invention is a device for monitoring a drop abnormality due to forgetting to close the drain plug of the bathtub when hot water or non-heated water from a water heater is automatically dropped into the bathtub to supply hot water. A drop flow sensor for detecting the water level, a circulatory water level determining means for determining whether or not the drop has reached the recirculating water level of the bathtub, a bathtub water level sensor for detecting a bathtub water level above the recirculating water level, Timer means for counting the drop time after the drop reaches the water level that can be recirculated in the bathtub, and one or more times required for the drop to reach a constant water level after the drop has reached the water level that can be recharged in the bathtub Learn how long it takes for the bath water level to rise to a certain level and add a certain amount of time to the learning value. Determination reference time calculating means for calculating the calculated time as a determination reference time, determination reference time storage means for storing the calculated determination reference time, and the accumulated drop time after reaching the water level at which the current circulation is possible A drop abnormality judging means for judging a drop abnormality depending on whether or not a certain water level has risen before the reference time or more.SecondIt has the characteristics of
  The bath drop abnormality monitoring device of the present invention isThe first or secondIn addition to the features, there is a safety command means for issuing a drop stop command and a drop error display command when a drop error is determined by the drop error determination device.ThirdIt has the characteristics of
[0006]
  According to the first aspect of the present invention, when the hot water bath starts dropping the bath with hot water or non-heated water., CirculationIt is monitored by the ringable water level determination means whether or not the bathtub water level has reached a recirculating water level.When it is determined by the circulatorable water level determination means that the bath water level has reached the circulatory water level, the accumulated flow rate is detected by the drop flow sensor, and the bathtub water level is detected by the bathtub water level sensor. Is done.The drop abnormality determination meansWater level information by bathtub water level sensorThe judgment reference flow value from the judgment reference flow value storage means is compared with the drop integrated flow value detected by the drop flow sensor, and the bathtub water level is compared.A certain level risesIf the accumulated flow rate value before dropping is equal to or higher than the judgment reference flow rate value, it is determined that the dropping is abnormal.
  The determination reference flow value is calculated by the determination reference flow value calculation means and stored in the determination reference flow value storage means..
[0007]
  SizeWhen the calculation of the determination reference flow rate value by the constant reference flow rate calculation means is not determined to be an abnormal drop (ie,,Drop is normalIt was conductedIn this case, the detected integrated flow rate value required for the rise in the constant water level in the case) can be adopted, for example, from the past one to a plurality of times and calculated from those values.
  That is, when adopting the past detected integrated flow value only once, for example, the value obtained in the trial operation when the device is installed is used as the integrated flow rate value for dropping to require a constant water level rise, for example, 2.5 cm. It is possible to learn, to use the value as a learning value, add a constant flow rate value as a margin value, for example, a flow rate value as small as about 5 liters, determine the determination reference flow rate value, and store it. . In addition, the detected integrated flow rate value until reaching the water level that can be recirculated in the previous time when it was not determined that there was a drop-in abnormality is used as a learning value, and a constant flow rate value as a margin value is added to this value as a judgment reference flow rate value. it can. The value of the constant water level rise can be appropriately determined based on experiments. Further, the constant flow rate value added as the margin value is appropriately determined based on the experimental value in accordance with the constant value of the water level rise.
  On the other hand, when adopting the past multiple detection integrated flow values, when the device is installed, a test run is performed a plurality of times, for example, three times or five times, and a constant water level at a plurality of times when the drop is normally performed. The detection integrated flow value required for the rise is adopted, and the average value of these values is used as a learning value, and a constant flow value, for example, a small flow value of about 5 liters is added as a margin value to determine the judgment reference flow value. This can be memorized. In addition, it adopts the detected integrated flow rate value required for a constant water level rise obtained in multiple operations going up in the past that have not been determined to be a drop-in abnormality, and the average value of these values is taken as the learning value. A constant flow value can be added as a margin value to obtain a determination reference flow value. In this case, it is necessary to give a plurality of temporary values as the detected integrated flow rate value required for the initial increase in the constant water level. Even if this temporary value is a large value, by repeating the dropping operation, an appropriate determination reference flow rate value is calculated for the bathtub after the plurality of normal droppings are performed. . Appropriate values can be determined in advance through experiments for the constant water level rise value, the constant flow value as the margin value, and the provisional value given as the initial value.
  the aboveFirstAccording to the above feature, after the drop has reached or exceeded the level of water that can be recirculated, it is possible to reliably determine whether or not there is a drop abnormality without further dropping.
[0008]
  Of the present inventionSecondAccording to the feature of the above, when the hot water or the non-heated water is started to drop the bath by the water heater, and the circulatorable water level determining means determines that the bathtub water level has reached the recirculating water level, The drop integrated flow rate is detected by the drop flow sensor, the bathtub water level is detected by the bathtub water level sensor, and the drop time is counted by the timer means. The drop abnormality determination means receives the water level information from the bathtub water level sensor and the drop time information from the timer means, and the determination reference time from the determination reference flow value storage means, and the drop time counted by the timer means, If the drop time becomes equal to or greater than the reference flow rate before the bath water level rises to a certain level, it is determined that the drop is abnormal.
  When the determination reference time calculation by the determination reference time calculation means is not determined to be a drop abnormality (ie,,Drop is normalIt was conductedIn this case, the drop time required for raising the constant water level in the case) can be calculated, for example, from the past one to a plurality of times.
  That is, when adopting the drop time required for a single constant water level rise in the past, for example, the drop time required for the constant water level rise obtained in the trial operation when the apparatus was installed, For example, let it learn as a drop time required to rise by 2.5 cm, set the value as a learning value, add a constant drop time as a margin value, for example, a time as small as about 1 minute, and determine the determination reference time, This can be stored. Moreover, the drop time required for the rise of the constant water level in the previous time when it was not determined that there was a drop abnormality can be used as a learning value, and a fixed time as a margin value can be added to this as the determination reference time. The constant water level in the rise of the constant water level can be appropriately determined based on experiments. Further, the fixed time added as the margin value according to the fixed value of the water level rise is also appropriately determined based on experiments.
  On the other hand, when adopting the drop time required for a certain number of rises in the past in the past, when the device is installed, the test run is performed several times, for example, 3 times or 5 times, and the drop is normally performed. The drop time required for the rise of the constant water level at the time is adopted, the average value of these is taken as the learning value, and the learning value is a marginal value for a certain time, for example, about 1 minute.timeIn addition, the determination reference time is determined and stored. In addition, the drop time required for the rise of a constant water level obtained in multiple operations that went back in the past that were not determined to be drop abnormalities was adopted, the average value of these was taken as the learning value, and a margin value was added to this learning value. As a reference time by adding a certain time. In this case, it is necessary to give a plurality of temporary values as the drop time required for raising the constant water level at the beginning. Even if this temporary value is a large value, by repeating the dropping operation, an appropriate determination reference time is calculated for the bathtub after the plurality of normal dropping operations. Appropriate values can be determined in advance by experiments for the value of the constant water level in the rise of the constant water level, the fixed time as the margin value, and the provisional value given as the initial value.
  the aboveSecondAccording to the above feature, after the drop has reached or exceeded the level of water that can be recirculated, it is possible to reliably determine whether there is a drop abnormality before a large amount of drop due to the elapse of a longer drop time.
[0009]
  the aboveThirdAccording to the features above1st or 2ndIn addition to the functions and effects of the above feature, when the drop abnormality determining means determines that there is a drop abnormality, the safety command means issues a drop stop instruction and a drop abnormality display instruction. Therefore, when there is a drop abnormality, the drop can be stopped automatically and the drop abnormality display can be immediately known, and the cause of the drop abnormality can be repaired.
[0010]
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 is an overall configuration diagram of a hot water supply apparatus using the bath drop abnormality monitoring apparatus of the present invention. FIG. 2 is a block diagram showing a control configuration in the controller according to the first embodiment of the bath drop abnormality monitoring apparatus of the present invention. FIG. 3 is a flowchart showing a control example according to the first embodiment of the bath drop abnormality monitoring apparatus of the present invention. FIG. 4 is a block diagram showing a control configuration in the controller according to the second embodiment of the bath drop abnormality monitoring apparatus of the present invention. FIG. 5 is a flowchart showing a control example according to the second embodiment of the bath drop abnormality monitoring apparatus of the present invention. FIG. 6 is a block diagram showing a control configuration in the controller according to the third embodiment of the bath drop abnormality monitoring apparatus of the present invention. FIG. 7 is a flowchart showing a control example according to the third embodiment of the bath drop abnormality monitoring apparatus of the present invention.
[0011]
First, the whole hot water supply apparatus of FIG. 1 will be described. 10 is a bathtub, 20 is a water heater, and 30 is a bath.
The bathtub 10 is provided with a drain plug 11, and a circulation fitting 12 for reheating circulation is provided at a position slightly below the middle of the side wall of the bathtub 10. Bath automatic hot water supply through the circulation fitting 12 is also performed.
The bath pot 30 is provided with a reheating burner 31 and a reheating heat exchanger 32. A reheating circulation path 33 is provided between the reheating heat exchanger 32 and the circulation fitting 12 of the bathtub 10, and the reheating circulation path 33 includes a bathtub water level sensor 34 including a water pressure sensor, a circulation A pump 35, a water flow switch 36, a bathtub temperature sensor 37, and the like are provided.
The water heater 20 is provided with a hot water burner 21 and a hot water heat exchanger 22. A water inlet 23 is connected to the hot water heat exchanger 22, and a water inlet flow rate sensor 24 and a water inlet temperature sensor 25 are provided in the water inlet 23. A hot water supply passage 26 is connected to the hot water supply heat exchanger 22, and a hot water supply temperature sensor 27 is provided in the hot water supply passage 26. A bypass 28 having a mixed water regulator 29 is connected to the hot water outlet 26 from the water inlet 23, and hot water and non-heated water are mixed by the flow regulator 29 at the junction, and the hot water supply passage 40 is downstream from the junction. It has been. The hot water supply passage 40 is provided with a water amount regulator 41 and a hot water supply temperature sensor 42. The hot water supply path 40 is branched into a general hot water supply path 43 and an automatic bath dropping hot water supply path 44 on the way.
The bath automatic drop hot water supply path 44 is connected in the middle of the recirculation circulation path 33, and a drop flow sensor 45, a vacuum breaker 46, a drop electromagnetic valve 47, and a check valve 48 are provided in the middle.
50 is a controller for controlling the entire water heater, and 60 is a remote controller. The controller 50 has a built-in microcomputer, receives commands from the remote controller 60, inputs information from sensors in each part of the water heater, performs calculations, judgments, and storages according to the specified software, and commands the operation to each part of the water heater Put out.
The automatic bath dropping is performed when the set water level of the bathtub is set by the remote controller 60 or the like and the automatic dropping operation switch is turned on by the remote controller or the like. When the drop solenoid valve 47 is opened, hot water or non-heated water that has passed through the hot water supply path 26 and the automatic bath drop hot water supply path 44 from the water heater 20 enters the recirculation circulation path 33 and enters the recirculation circulation path 33. It passes through the circulation fitting 12 and is introduced into the bathtub 10.
[0012]
In the bath automatic dropping operation, when hot water or non-heated water is smoothly dropped into the bathtub 10 and reaches the set water level, the automatic bath dropping ends. On the other hand, forgetting to set the drain plug 11 of the bathtub 10, the setting method is bad, or there is a case where water leaks from the bathtub 10, and these dropping abnormalities are monitored by the controller 50.
[0013]
A first embodiment of the bath drop abnormality monitoring apparatus of the present invention will be described with reference to FIGS. FIG. 2 is a block diagram showing a configuration related to the bath drop abnormality monitoring device in the internal configuration of the controller 50. The circulating water level determination means 51, the determination reference flow value calculation means 52, the determination reference flow value storage means 53, the drop An abnormality determination unit 54 and a safety command unit 55 are internally configured.
The circulating water level determining means 51 is a means for determining whether or not the bathtub water level has become a water level that can be detected by the bathtub water level sensor 34 provided in a part of the recirculation circulation path 33. If the water level becomes equal to or higher than the circulating water level, the water level can be detected by the bathtub water level sensor 34. On the other hand, the water level of the bathtub cannot be detected below the circulating water level. The circulatorable water level can be said to be a water level at which the circulation fitting 12 of the bathtub 10 is immersed in water.
The determination by the circulatorable water level determination means 51 is performed by a method of determining by detecting the inflection point of the detection value by the bathtub water level sensor 34, and by periodically driving the circulation pump 35 so that the bathtub water is actually replenished. There is a circulation determination method for determining whether to circulate.
The method of capturing the inflection point of the detection value of the bathtub water level sensor 34 is that the detection value by the bathtub water level sensor 34 is taken into the circulatorable water level determination means 51 simultaneously with the start of dropping into the bathtub 10, and the detection value has a certain inflection. This is a method for determining that the bathtub water level has reached the circulatorable water level at the time point occurs. The detection value of the bathtub water level sensor 34 in the recirculation circulation path 33 is that the water gradually enters the recirculation circulation path 33 when the bathtub water level reaches the circulation fitting 12. A large change is started from the detected value in the state where the use circuit 33 is empty, and an inflection point is indicated. Then, when the water level of the bathtub becomes a state in which the circulating metal fitting 12 is submerged, a stable change is again exhibited. Therefore, by catching the inflection point by the circulating water level determining means 51, it is possible to determine whether or not the bathtub water level has reached the recyclable water level.
On the other hand, in the circulation determination method, after the dropping into the bathtub 10 is started, the dropping is periodically stopped and the circulation pump 35 is driven to check whether the bathtub water circulates in the recirculation circuit 33 or not. The circulatorable water level determination means 51 determines the signal from
[0014]
The determination reference flow rate value calculating means 52 is a means for calculating a determination reference flow rate value for determining whether or not the bath drop is abnormal, and when it is not determined that the drop is abnormal (that is, the drop is normal). In this case, the detected integrated flow value until reaching the recirculating water level is dropped from the flow sensor 45, and the detected integrated flow value until reaching the recirculating water level is reversed from the latest to the past. Adopt multiple times, for example, 5 times, and use these average values as learning values, add a constant flow rate value as a margin value to this learning value, for example, an appropriate small flow rate value from 30 to 40 liters, etc. It is what. In this case, since there is no detected integrated flow rate value to be adopted at the beginning, it is necessary to give a plurality of temporary values instead, for example, 200 liters which is a general bathtub capacity. Even if this temporary value is a large value, it is suitable for the bathtub after the normal dropping has been carried out several times, for example, five times for the adoption of the five times, by repeating the dropping operation. Therefore, a correct judgment flow rate value is calculated.
When the determination reference flow value is calculated, the determination reference flow value is stored in the determination reference flow value storage means 53.
[0015]
The drop abnormality determination means 54 receives the determination information as to whether or not the tub water level has reached the recirculating water level by the circulatorable water level determination means 51, and the determination reference flow value from the determination reference flow value storage means 53. Is compared with the drop integrated flow value detected by the drop flow sensor 45, and the drop integrated flow value becomes equal to or higher than the judgment reference flow value before the bathtub water level reaches the recirculating water level. It is determined that the drop is abnormal.
Upon receipt of the drop abnormality determination by the drop abnormality determining means 54, the safety command means 55 instructs the display unit 61 of the remote controller 60 to indicate that there is a drop abnormality, and also issues a command to close the drop solenoid valve 47. Out and stop automatic hot water supply.
[0016]
A control example of the bath drop abnormality monitoring apparatus according to the first embodiment of the present invention will be described with reference to the flowchart of FIG.
Now, when the automatic dropping operation (not shown) of the remote controller 60 is turned on to start the automatic dropping operation, the dropping solenoid valve 47 is opened by the command of the controller 50 and dropping hot water supply is started. At the same time, the dropping flow sensor The counting of the drop flow rate by 45 is started (step S1).
When the dropped hot water supply operation is started, the integrated flow rate value detected by the dropped flow rate sensor 45 is compared with the determination reference flow rate value from the determination reference flow rate storage means 53 by the drop abnormality determining means 54 (step S2), or The determination by the circulatorable water level determining means 51 is taken into the drop abnormality determining means 54, and it is determined whether or not the bathtub water level is equal to or higher than the recyclable water level (step S3). The drop abnormality judging means 54 compares the integrated flow rate value with the judgment reference flow rate value, and takes in whether or not the bathtub water level is higher than the recirculating water level, so that the bathtub water level is higher than the recirculating water level. However, if the integrated flow rate value is equal to or higher than the determination reference flow rate value (Yes in S2, No in S3), it is determined that there is a drop abnormality. If it is determined that there is a dropping abnormality, the safety command means 55 issues a closing command to the dropping solenoid valve 47 and a remote control 60 issues a dropping abnormality display command, so that the dropped hot water supply is stopped and a dropping abnormality display is made ( Step S4).
On the other hand, if the drop abnormality determining means 54 does not determine that there is a drop abnormality (No in S2, Yes in S3), the judgment reference flow rate value calculating means 52 determines the water level that can be replenished by the drop. The integrated flow rate value is newly taken in, the determination reference flow value is calculated, and the value is stored in the determination reference flow value storage means 53 (step S5).
Thereafter, separately from the calculation and storage procedure of the judgment reference flow rate value, it is monitored whether or not the bathtub water level sensor 34 detects the set water level or higher (step S6). The hot water supply operation is terminated (step S7).
[0017]
A second embodiment of the bath drop abnormality monitoring apparatus of the present invention will be described with reference to FIGS. FIG. 4 is a block diagram showing a configuration related to the bath drop abnormality monitoring device among the internal configurations of the controller 50. The circulating water level determination means 51a, the determination reference flow value calculation means 52a, the determination reference flow value storage means 53a, the drop The abnormality determination means 54a, the safety command means 55a, and the integrated flow count reset means 56a are internally configured.
The mechanism, action, etc. of the circulatorable water level determination means 51a are the same as those of the circulatory water level determination means 51 described in the first embodiment.
The determination reference flow value calculation means 52a is a means for calculating a determination reference flow value for determining whether or not bath dropping is abnormal, and the calculation of the determination reference flow value by the determination reference flow value calculation means 52a is: When it is not determined that the drop is abnormal (that is, when the drop is performed normally), the detected integrated flow rate required to rise by a certain level, for example, 2.5 cm, is reversed from the latest to the past. A plurality of times, for example, 5 times, are adopted, and an average value of these values is used as a learning value, and a constant flow rate value, for example, a flow rate value as small as about 5 liters is added as a margin value to calculate a determination reference flow rate value. The rise in the constant water level can be obtained from information from the bathtub water level sensor 34, and the detected integrated flow value required for the rise in the constant water level can be obtained from information from the drop flow sensor 45.
The calculated determination reference flow value is stored in the determination reference flow value storage means 53a.
In the second embodiment, it is necessary to give a plurality of provisional values as the detected integrated flow value required for raising the constant water level in the calculation of the judgment reference flow value at the beginning. Even if this temporary value is a large value, an appropriate judgment reference flow rate value is calculated for the bathtub after the normal dropping is repeated a plurality of times by repeating the dropping operation. Will be. Appropriate values can be determined in advance by experiments for the constant water level rise value, the constant flow value as the margin value, and the provisional value given as the initial value.
The drop abnormality determining means 54a receives the water level information from the bathtub water level sensor 34, and determines the judgment reference flow value from the judgment reference flow value storage means 53a and the drop integrated flow value detected by the drop flow sensor 45. Compare the size, and if the accumulated water flow rate value is equal to or higher than the judgment reference flow rate value before the bathtub water level rises to a certain level, it is determined that there is a dropping abnormality.
The safety command means 55a performs the same function and operation as the safety command means 55 in the first embodiment.
The integrated flow count reset means 56a is means for resetting the integrated flow rate detected by the drop flow sensor 45.
[0018]
A control example of the bath drop abnormality monitoring apparatus according to the second embodiment of the present invention will be described with reference to the flowchart of FIG.
In FIG. 5, the conventional bath drop abnormality monitoring method is employed in steps S11 to S14, but this may be replaced with steps S1 to S4 in FIG. The important points for monitoring the bath drop abnormality according to the second embodiment are steps S15 to S18.
Now, when the automatic dropping operation switch (not shown) of the remote controller 60 is turned on to start the automatic dropping operation, the dropping electromagnetic valve 47 is opened by the command of the controller 50, the dropping hot water supply is started, and the controller 50 is not shown. A timer is started (step S11).
The controller 50 determines whether the water level in the bathtub reaches the recirculating water level or more before the predetermined fixed time limit, for example, 30 minutes elapses, based on the accumulated time from the timer and the determination by the circulating water level determining means 51a. (Step S12, S13). If the water level does not exceed the recyclable water level even after the time limit has elapsed (yes in step S12, no in step S13), it is determined that the drop is abnormal. And dropping hot water supply is stopped and dropping abnormality is displayed (step S14).
The above is the same as the conventional method and is repeated, but it may be replaced with the flow of steps S1 to S4 in FIG.
Next, when the bath water level becomes equal to or higher than the water level that can be recirculated before the time limit has elapsed (No in step S12, yes in step S13), the controller 50 controls the flow rate by the integrated flow rate count resetting means 56a. Integration is newly started and water level detection by the bathtub water level sensor 34 is started (step S15). Then, whether or not the integrated flow rate value detected by the drop flow rate sensor 45 is equal to or greater than the determination reference flow rate value is determined by the drop failure determination means 54a (step S16). It is determined whether or not the bathtub water level has risen above a predetermined water level (step S17). That is, the drop abnormality determination means 54a determines whether or not the integrated flow rate value is equal to or higher than the determination reference flow rate value, determines whether or not the bathtub water level has risen above a predetermined level, and the bathtub water level is further determined. If the integrated flow rate value is greater than or equal to the determination reference flow rate value even though it has not risen above a certain level (yes in step S16, no in S17), it is determined that there is a drop abnormality. If it is determined that there is a dropping abnormality, the safety command means 55a issues a closing command to the dropping solenoid valve 47 and a remote control 60 issues a dropping abnormality display command, so that the dropped hot water supply is stopped and a dropping abnormality display is made ( Step S14).
On the other hand, if the drop abnormality determination means 54a does not determine that there is a drop abnormality (No in S16, Yes in S17), the integration required until the water level rises by the reference flow rate calculation means 52a. The flow rate value is newly taken in, the determination reference flow rate value is calculated, and the value is stored in the determination reference flow rate value storage means 53a (step S18).
Thereafter, separately from the calculation and storage procedure of the judgment reference flow rate value, it is monitored whether or not the bathtub water level sensor 34 detects the set water level or higher (step S19). The hot water supply operation is terminated (step S20).
[0019]
A third embodiment of the bath drop abnormality monitoring device of the present invention will be described with reference to FIGS. FIG. 6 is a block diagram showing the configuration related to the bath drop abnormality monitoring device among the internal configurations of the controller 50. The circulating water level determination means 51b, the determination reference time calculation means 52b, the determination reference time storage means 53b, the drop abnormality determination Means 54b, safety command means 55b, integrated flow count reset means 56b, and timer means 57b are internally configured.
The mechanism, action, etc. of the circulatorable water level determination means 51b are the same as those of the circulatorable water level determination means 51 described in the first embodiment.
The determination reference time calculation means 52b is a means for calculating a determination reference time for determining whether or not the bath drop is abnormal, and the calculation of the determination reference time by the determination reference time calculation means 52b is a drop abnormality. The detection time required for a certain water level rise, for example, 2.5 cm rise when the drop is not determined (ie, when the drop is normally performed), for example, 5 times, for example, going up from the latest to the past The average value of these values is taken as a learning value, and a fixed time value, for example, a time as short as about 1 minute, is added as a margin value to the learning value to calculate the determination reference time. The rise in the constant water level can be obtained from information from the bathtub water level sensor 34, and the time required for the rise in the constant water level can be obtained from information from the timer means 57b.
The calculated determination reference time is stored in the determination reference time storage means 53b.
In the third embodiment, in the initial determination reference time calculation, it is necessary to give a plurality of provisional values as the detection time required for raising the constant water level. Even if this temporary value is a large value, an appropriate determination reference time is calculated for the bathtub after the normal dropping is performed a plurality of times by repeating the dropping operation. It will be. Appropriate values can be determined in advance by experiments for the constant water level rise value, a fixed time as a margin value, and a temporary value given as an initial value.
The drop abnormality determination unit 54b receives the water level information from the bathtub water level sensor 34, and the determination reference time from the determination reference time storage unit 53b, and the accumulated drop time after the bathtub water level reaches the recyclable water level. Are compared, and if the accumulated drop time exceeds the reference time before the water level rises to a certain level, it is determined that the drop is abnormal. The accumulated dropping time after the bathtub water level reaches the water level that allows recirculation is counted by the timer means 57b.
The safety command means 55b performs the same function and operation as the safety command means 55 in the first embodiment.
The integrated flow count resetting means 56b is the same as the integrated flow count resetting means 56a in the second embodiment, and is a means for resetting the integration of the flow detected by the drop flow sensor 45.
The timer means 57b is a means for accumulating the dropping time from the start of operation until the bathtub water level reaches the recirculating water level, and newly adding the dropping time after the bath water level reaches the recirculating water level. is there.
[0020]
A control example of the bath drop abnormality monitoring apparatus according to the third embodiment of the present invention will be described with reference to the flowchart of FIG.
In FIG. 7, steps S31 to S34 employ a conventional bath drop abnormality monitoring method, but this may be replaced with steps S1 to S4 in FIG. 3. The important points in monitoring the bath drop abnormality according to the third embodiment are steps S35 to S38.
When the automatic dropping operation switch (not shown) of the remote controller 60 is turned on to start automatic dropping operation, the dropping electromagnetic valve 47 is opened by the command of the controller 50, dropping hot water supply is started, and the timer means of the controller 50 A timer for integrating the dropping time by 57b is started (step S31).
Based on the accumulated time from the timer means 57b and the determination by the circulatorable water level determination means 51b, the controller 50 determines that the bath water level is more than the circulatory water level at which the bath water level is replenished before a predetermined time limit, e.g. (Steps S32, S33), and if the water level does not exceed the recyclable water level even after the time limit has elapsed (Yes in Step S32, No in Step S33), it is determined that the drop is abnormal. . And dropping hot water supply is stopped and dropping abnormality is displayed (step S34).
The above is the same as the conventional method and is repeated, but it may be replaced with the flow of steps S1 to S4 in FIG.
Next, when the water level of the bathtub becomes equal to or higher than the water level that can be recirculated before the time limit elapses (No in step S32, Yes in step S33), the controller 50 sets a new drop time by the timer means 57b. Accumulation is started, and the accumulated flow count resetting means 56b newly starts counting the accumulated flow, and starts water level detection by the bathtub water level sensor 34 (step S35). Then, whether or not the accumulated drop time counted by the timer means 57b is equal to or longer than the determination reference time is determined by the drop abnormality determination means 54b (step S36). It is determined whether or not has risen above a predetermined water level (step S37). That is, the drop abnormality determination unit 54b determines whether or not the accumulated drop time is equal to or greater than the determination reference time, determines whether or not the bathtub water level has risen above a predetermined level, and further determines whether the bathtub water level is higher. If the integrated flow rate value is greater than or equal to the determination reference flow rate value even though it has not risen above a certain level (Yes in step S36, No in S37), it is determined that there is a drop abnormality. If it is determined that there is a dropping abnormality, the safety command means 55b issues a closing command to the dropping solenoid valve 47 and a remote control 60 issues a dropping abnormality display command, so that dropping hot water supply is stopped and a dropping abnormality display is made ( Step S34).
On the other hand, if the drop abnormality determining means 54b does not determine that there is a drop abnormality (No in S36, Yes in S37), the integration time required until the constant water level rises by the determination reference time calculating means 52b. A new reference time is taken in to calculate the determination reference time, and the value is stored in the determination reference time storage means 53b (step S38).
Thereafter, separately from the calculation of the judgment reference time and the storage procedure, it is monitored whether or not the bathtub water level sensor 34 detects the set water level or higher (step S39). The operation is terminated (step S40).
[0021]
【The invention's effect】
  The present invention comprises the above configuration, and according to the bath drop abnormality monitoring device according to claim 1,FallEven after the water drop reaches the recirculating water level, it is possible to reliably determine whether there is a drop abnormality without further dropping.
  AlsoClaim 2According to the bath drop abnormality monitoring device described in, it is ensured that there is a drop abnormality even after the drop has exceeded the water level that can be recirculated, and before a large amount of drop due to the longer drop time. Can be determined.
  AlsoClaim 3According to the bath drop abnormality monitoring device described in the above,Claim 1 or 2In addition to the effects and effects of the configuration described in (1), if a drop abnormality is determined by the drop abnormality determination means, the drop can be stopped immediately by the safety command means, so that further unnecessary drop is automatically performed. Can be eliminated. Moreover, since the drop abnormality display is made immediately, the user can immediately know the drop abnormality and can quickly take countermeasures against it.
[Brief description of the drawings]
FIG. 1 is an overall configuration diagram of a hot water supply apparatus using a bath drop abnormality monitoring apparatus of the present invention.
FIG. 2 is a block diagram showing a control configuration in the controller according to the first embodiment of the bath drop abnormality monitoring apparatus of the present invention.
FIG. 3 is a flowchart showing a control example according to the first embodiment of the bath drop abnormality monitoring apparatus of the present invention;
FIG. 4 is a block diagram showing a control configuration in a controller according to a second embodiment of the bath drop abnormality monitoring apparatus of the present invention.
FIG. 5 is a flowchart showing a control example according to the second embodiment of the bath drop abnormality monitoring apparatus of the present invention;
FIG. 6 is a block diagram showing a control configuration in a controller according to a third embodiment of the bath drop abnormality monitoring apparatus of the present invention.
FIG. 7 is a flowchart showing a control example according to the third embodiment of the bath drop abnormality monitoring apparatus of the present invention;
[Explanation of symbols]
10 Bathtub
11 Drain valve
12 Circulation bracket
20 Water heater
30 bath
33 Circulation circuit
34 Bathtub water level sensor
44 Bath automatic hot water supply path
45 Drop flow sensor
47 Drop solenoid valve
50 controller
60 Remote control

Claims (3)

When dropping hot water or non-heated water from a water heater into a bathtub and supplying hot water, it is a device that monitors the drop abnormality due to forgetting to close the drain tap of the bathtub, etc., and a drop flow sensor that detects the drop flow rate, and the drop is a bathtub The recirculating water level determining means for determining whether or not the recirculating water level has been reached, the bathtub water level sensor for detecting the bathtub water level above the recirculating water level, and the drop reaches the recirculating water level of the bathtub. The flow value obtained by learning the drop accumulated flow value required for the bath water level to rise at a constant level using one or more accumulated flow values required for the rise in the constant water level, and adding the constant flow value to the learned value As a determination reference flow value, a determination reference flow value calculation means, and a determination reference flow value storage for storing the calculated determination reference flow value It has a stage, and an abnormality determination unit darken determining abnormality darken by whether a certain level rise before the integrated flow rate value is equal to or greater than the determination reference flow rate value in after reaching Reheating recyclable water level in the current Bath drop abnormality monitoring device characterized by. When dropping hot water or non-heated water from a water heater into a bathtub and supplying hot water, it is a device that monitors the drop abnormality due to forgetting to close the drain tap of the bathtub, etc., and a drop flow sensor that detects the drop flow rate, and the drop is a bathtub The recirculating water level determining means for determining whether or not the recirculating water level has been reached, the bathtub water level sensor for detecting the bathtub water level above the recirculating water level, and the drop reaches the recirculating water level of the bathtub. The water level of the bathtub rises to a certain level using one or a plurality of timers for counting the time of dropping after the dropping, and the time required for the rising of the constant water level after the dropping reaches the water level where the bathtub can be recirculated. Learning to calculate the time required to calculate as a criterion time by adding a certain time to the learning value And quasi time calculation means, and the reference time storage means for storing the computed reference time, a certain level rise before the darken time integrated in after reaching Reheating recyclable water level in the current becomes equal to or higher than the determination reference time A bath drop abnormality monitoring apparatus, comprising: drop abnormality determining means for determining drop abnormality depending on whether or not The bath drop abnormality monitoring apparatus according to claim 1 or 2, further comprising safety command means for issuing a drop stop command and a drop abnormality display command when the drop abnormality determination unit determines that there is a drop abnormality.

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