JP2018053534A - Sanitary washing device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a sanitary washing device that prevents a time till reaching a prescribed temperature from becoming longer due to deterioration with time of a heater pattern, and can discharge water of a temperature suited to a user at all times.SOLUTION: A sanitary washing device discharges hot water toward a private part of a human body while heating water flowing through a water flow passage to a prescribed temperature. The sanitary washing device includes: a heating unit provided with a heater pattern that is heated by energization; a case part into which the heating unit is inserted and in which a water flow passage for supplied water is formed around the heating unit; a hot water supply temperature sensor that detects a temperature of hot water heated by the heating unit; and a control part that controls an energization quantity to the heater pattern on the basis of the temperature detected by the hot water supply temperature sensor. The control part determines whether the heater pattern has deteriorated or not on the basis of a change in the temperature detected by the hot water supply temperature sensor during start-up control time from a start of energization until a lapse of fixed time, and performs control so that the energization quantity to the heater pattern is increased when the control part determines that the heater pattern has deteriorated.SELECTED DRAWING: Figure 10A

Description

  The present invention generally relates to a sanitary washing device, and more particularly to a sanitary washing device for washing, for example, a “butt” of a user sitting on a Western-style seated toilet.

  Conventionally, there is a sanitary washing device that discharges water to a local body part while heating water flowing through a water passage to a predetermined temperature. For example, the sanitary washing apparatus disclosed in the cited document 1 discloses a configuration in which a plurality of heater patterns are combined into one heating element to stabilize the tapping temperature. Further, in Cited Document 1, a plurality of heater patterns are provided on a plurality of heating elements, and the energization time for each heater pattern is made uniform, thereby suppressing deterioration of only a specific heater pattern, and a heat exchanger. There are things that extend the life of

  However, in the above configuration, when the temperature rise performance decreases due to deterioration of the heating element over time, even if the hot water temperature is stabilized or the life of the heat exchanger is extended, the user can discharge water at an appropriate temperature. There is a problem that time is prolonged and satisfactory performance cannot be obtained.

JP 2012-67468 A

  The present invention has been made on the basis of recognition of such a problem, and prevents the time until the temperature reaches a predetermined temperature due to the deterioration of the heater pattern with time, and always discharges water at an appropriate temperature to the user. An object of the present invention is to provide a hygienic cleaning device that can be used.

  In order to achieve the above object, in the sanitary washing apparatus according to the present invention, a heater that generates heat when energized is a sanitary washing apparatus that discharges water flowing through a water passage to a local body part while heating the water to a predetermined temperature. A heating element provided with a pattern, a case part in which the heating element is inserted and a water flow path for the supplied water is formed around the heating element, and a hot water temperature for detecting the temperature of hot water heated by the heating element And a controller that controls the amount of energization to the heater pattern based on the temperature detected by the tapping temperature sensor, and the control unit performs tapping temperature sensor during start-up control until a predetermined time elapses from the start of energization. The presence or absence of deterioration of the heater pattern is determined based on the change over time of the temperature detected by the sensor, and if it is determined that there is deterioration, the amount of current supplied to the heater pattern is increased. It is characterized in that Gosuru.

According to the present invention, since the control unit determines the deterioration of the heater pattern based on the change over time of the temperature detected by the tapping temperature sensor during the start-up control, the element is used to detect the deterioration of the heater pattern. There is no need to add, and it is possible to easily detect the deterioration of the heater pattern.
If it is determined that the heater pattern is deteriorated, a decrease in the heating amount when the heater pattern is deteriorated can be suppressed by correcting the heater pattern so that the energization amount of the heater pattern is increased.
Accordingly, it is possible to prevent the time from the start of heating to reach the predetermined temperature due to the deterioration of the heater pattern during start-up control, and the time until the hot water at the predetermined temperature is discharged to the human body part. A sanitary washing apparatus that is short and easy to use can be provided.

  In the sanitary washing device according to the present invention, preferably, the heating element is provided with a plurality of heater patterns, and the control unit has a predetermined priority in order to heat the water flowing through the water passage to a predetermined temperature. Based on the ranking, the distribution of the energization amount for the plurality of heater patterns is determined. Further, the control unit determines the drive time during which the energization amount distribution amount is the largest for each of the plurality of heater patterns. Control can be performed so that the distribution amount of the energization amount for the heater pattern with the shortest drive time value is maximized so that the memory value of the drive time becomes equal at the start of water flow. To do.

  According to this configuration, when there are a plurality of heater patterns, the driving time in the state where the distribution amount of the energization amount is the largest for each heater pattern (hereinafter referred to as the main heater) is integrated and stored. By controlling the drive time of the main heater for each heater pattern to be equal, deterioration for each heater pattern can be made uniform. In other words, by driving as the main heater the heater that is estimated to have the shortest drive time, that is, the least deteriorated as the main heater, it is possible to prevent the time from reaching the predetermined temperature from the start of heating from becoming long. Therefore, it is possible to provide a sanitary washing device that is short in time and is easy to use until the hot water of a predetermined temperature is discharged to the human body part.

  In the sanitary washing device according to the present invention, preferably, the control unit is capable of accumulating and storing the energization amount increase control number controlled to increase the energization amount for each of the plurality of heater patterns. Control is performed so that the distribution amount of the energization amount with respect to the heater pattern having the smallest stored value of the energization amount control count is maximized so that the number increase control count becomes equal.

  According to this configuration, when there are a plurality of heater patterns, the number of times the energization amount increase control is performed for each of the plurality of heater patterns is stored in order to make the deterioration for each of the plurality of heater patterns uniform. A heater pattern with a large number of energization amount increase controls is likely to have deteriorated or failed. Therefore, by driving a heater pattern with a small number of energization amount control times as a main heater, a predetermined value is set from the start of heating. It is possible to prevent the time until the temperature is reached from being increased, and it is possible to provide a sanitary washing device that is short in time and is easy to use.

  In the sanitary washing device according to the present invention, preferably, the distribution amount of the energization amount to the heater pattern is increased in preference to the small storage value of the energization amount control count over the short drive time storage value. To do.

  According to this configuration, although the driving time for driving as a main heater is short, a heater pattern that has been deteriorated is not used as a main heater, and a plurality of heater patterns are more evenly deteriorated. I can do it. Therefore, it is possible to provide a sanitary washing device that can exhibit good performance for a longer period.

Therefore, according to the aspect of the present invention, it is possible to prevent the time from the start of heating to reach the predetermined temperature due to the deterioration of the heater pattern during start-up control, and to prevent the predetermined temperature at the human body part. It is possible to provide a sanitary washing device that has a short time to discharge warm water and is easy to use.

The typical perspective view showing the toilet apparatus provided with the sanitary washing apparatus which concerns on embodiment of this invention. The block diagram which illustrates the specific example of the principal part structure of the waterway system of the sanitary washing apparatus which concerns on this Embodiment. Schematic cross-sectional view illustrating the heat exchanger according to this embodiment The typical plane which illustrates the heat generating body used with the heat exchanger which concerns on this Embodiment. The circuit block diagram which illustrates the connection structure for supplying with electricity to the heater pattern which concerns on this Embodiment. The table | surface which illustrates an example of the electricity supply pattern used for the output for every system | strain of the heater pattern which concerns on this Embodiment. The figure explaining the specific example of the energization state to a heater pattern. The figure explaining the specific example of the energization state to a heater pattern. The figure explaining the specific example of the energization state to a heater pattern. The flowchart which shows the control logic of the control part which concerns on this Embodiment. The flowchart which shows the control logic of the drive time equality control of FIG. 10A. The flowchart which shows the control logic of energization amount increase control of FIG. 10A.

  Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. In addition, in each drawing, the same code | symbol is attached | subjected to the same component and detailed description is abbreviate | omitted suitably.

  The toilet device shown in FIG. 1 includes a Western-style seat toilet 1 (hereinafter simply referred to as “toilet” for convenience of description) and a sanitary washing device 3 provided thereon. The sanitary washing device 3 includes a casing 5, a toilet seat 7, and a toilet lid 9. The toilet seat 7 and the toilet lid 9 are pivotally supported by the casing 5 so as to be openable and closable.

The casing 5 is provided with a seating detection sensor 15 that detects that the user has sat on the toilet seat 7.
Inside the casing 5, a nozzle device 10 and the like that realizes cleaning of a user sitting on the toilet seat 7 such as “wet” is incorporated. The nozzle device 10 includes a cleaning nozzle 11 that discharges water, a water discharge port 13 provided at the tip of the cleaning nozzle 11, and a control unit 200 that controls extension of the cleaning nozzle 11.
In the present specification, “water” includes not only cold water but also heated hot water.

  FIG. 2 is a block diagram illustrating a specific example of the main configuration of the water channel system of the sanitary washing device 3 according to this embodiment.

  As shown in FIG. 2, in the sanitary washing device 3 according to this embodiment, water supplied from a water supply source (not shown) such as a water supply or a water storage tank is first guided to the branch fitting 19. The water guided to the branch fitting 19 is distributed to a connecting hose (not shown) and a toilet bowl cleaning valve unit 21. However, the toilet 1 provided with the sanitary washing device 3 according to this embodiment is not limited to the so-called “water direct pressure type”, and may be a so-called “low tank type”. Therefore, when the toilet bowl 1 is a “low tank type”, the water guided to the branch fitting 19 is guided to a low tank (not shown) instead of the valve unit 21 for cleaning the toilet bowl.

Subsequently, the water guided to the connecting hose (not shown) is guided to the valve unit 21. The valve unit 21 includes a water supply valve 23, a water inlet thermistor, and 25.
The water supply valve 23 is an electromagnetic valve that can be opened and closed, and controls the supply of water to the heat exchanger 101 based on a command from the control unit 200 provided in the casing 5. A water thermistor 25 is provided on the downstream side of the water supply valve 23. The incoming water thermistor 25 detects the temperature of the water guided to the heat exchanger 101 and outputs information on the water temperature to the control unit 200.

  Subsequently, the water supplied to the valve unit 21 is guided to the heat exchanger 101. The heat exchanger 101 includes a heating element 103 and a hot water thermistor 27. The hot water thermistor 27 detects the temperature of the water heated by the heat exchanger 101 and outputs information on the water temperature to the control unit 200.

Subsequently, the water heated by the heat exchanger 101 is guided to the nozzle device 10. The nozzle device 10 includes a cleaning nozzle 11, one or a plurality of nozzle channels 12 provided in the cleaning nozzle 11, and one or a plurality of water discharge ports 13 provided at the tip of the cleaning nozzle 11.
The water supplied to the nozzle device 10 is passed through each nozzle flow path 12 corresponding to, for example, “wet washing”, “soft washing”, “bidet washing”, and the like by a flow path switching valve (not shown). . Then, the water passed through the nozzle flow path 12 was discharged from the respective spouts 13 corresponding to, for example, “wet washing”, “soft washing”, “bidet washing”, etc., and sat on the toilet seat 7. Wash the user's “buttock”.

FIG. 3 is a schematic cross-sectional view illustrating the heat exchanger 101 according to this embodiment.
FIG. 4 is a schematic plan view illustrating the heating element 103 used in the heat exchanger 101 according to this embodiment.
FIG. 5 is a circuit configuration diagram illustrating a connection configuration for energizing the heater pattern 105 according to the present embodiment.

  As shown in FIG. 3, the heat exchanger 101 according to the present embodiment is an instantaneous heating (instantaneous) heat exchanger 101 using, for example, a ceramic heater, and includes a heating element 103 having a cylindrical portion 102. And a case portion 107 that houses the heating element 103.

  In addition, the heat exchanger 101 according to the present embodiment includes a water inlet A formed by the heating element 103 and a water outlet B formed by the case portion 107.

  The one end 102 a side of the cylindrical portion 102 is inserted into the case portion 107. As a result, water flow paths 104 a and 104 b heated by the heating element 103 are formed around the cylindrical portion 102. Further, the cylindrical portion 102 is provided with a flange portion 106. The other end 102 b side of the cylindrical portion 102 extends from the flange portion 106 to the outside of the case portion 107.

  The heating element 103 is fixed to the case portion 107 by a flange 106 and a fastener such as a screw. An O-ring R <b> 1 is provided between the flange portion 106 and the case portion 107 to ensure the sealing property between the flange portion 106 and the case portion 107.

The tubular portion 102 is provided with a belt-like heater pattern 105 made of one or a plurality of tungsten or the like.
In the present embodiment, a case where three heater patterns 105a, 105b, and 105c are provided will be described as an example.

  As shown in FIG. 4, the cylindrical portion 102 of the heating element 103 includes an inner portion PA and an outer portion PB. The inner part PA and the outer part PB are made of, for example, ceramics. Further, an intermediate part PC is sandwiched between the inner part PA and the outer part PB. A heater pattern 105 is formed in the intermediate portion PC. The intermediate portion PC includes, for example, an insulating film material and a conductive heater pattern 105 provided on the film material.

  As shown in FIG. 5, based on the water temperature information output from the incoming water thermistor 25 and the hot water thermistor 27, the control unit 200 energizes the three heater patterns 105a, 105b, and 105c. At that time, the control unit 200 controls the energization by controlling the voltage supplied from the power supply 109 by turning on / off the plurality of switch units 111a, 111b, and 111c corresponding to the plurality of heater patterns 105a, 105b, and 105c. Do.

  As energization control to the heater pattern 105, pattern control or the like is used. In the specification of the present application, the “pattern control method” means that a half wave with respect to the sine wave of the power supply 109 is set as one unit, and energization and non-energization to the heater pattern 105 are controlled in this half wave unit. A method of controlling the total power by combining a plurality of the above. Details of the pattern control will be described later.

  Next, pattern control which is energization control to the plurality of heater patterns 105a, 105b and 105c will be described.

The control unit 200 controls energization to the plurality of heater patterns 105a, 105b, and 105c of the heat exchanger 101, and heats the water supplied to the heat exchanger 101 to a predetermined temperature when the heater pattern 105 generates heat. To do.
The energization control to the plurality of heater patterns 105a, 105b, and 105c is performed between the temperature of water entering the heat exchanger 101 detected by the water thermistor 25 and the temperature of heated water detected by the hot water thermistor 27. When the control part 200 takes in information, it is performed by the combination of feedforward control and feedback control.

  The control unit 200 controls ON / OFF of energization by dividing one set into a plurality of waves (for example, 16 waves) for one of the heater patterns 105a, 105b, and 105c. A plurality of sets (for example, 4 sets) is set as a control unit.

  The control unit 200 is driven as the heater pattern 105 that is energized with the largest distribution amount of the energization amount among the plurality of heater patterns 105a, 105b, and 105c (hereinafter referred to as “main heater” for convenience of explanation). The time is accumulated and memorized.

The main heater will be described more specifically. For example, when there is a power distribution table to a plurality of heater patterns 105 as shown in FIG. 6, the control unit 200 outputs 500 watts to the heater pattern 105. Suppose you request. At that time, if the control unit 200 requests the heater pattern 105a to output 400 watts and the heater pattern 105b requests 100 watts of output, the heater pattern 105a is the main heater.
In addition, even when it is necessary to request each heater pattern 105 to output the same amount as when an output from 800 watts to 1200 watts is requested, the heater pattern 105 that preferentially distributes the output first. The heater pattern 105 used when an output of 400 watts or less shown in FIG. 6 is requested is the main heater.

  In the heat exchanger 101 according to the present embodiment, in such energization control by the control unit 200, a plurality of heater patterns 105a, 105b, and 105c are driven as main heaters based on the stored driving time of the main heater. Control is performed so as to equalize the time to be performed (hereinafter referred to as “driving time uniform control” for convenience of explanation).

  By performing the drive time equalization control, for example, when obtaining a desired output, if only the heater pattern 105a is used as the main heater, only the heater pattern 105a deteriorates faster than the other heater patterns 105b and 105c. Can be suppressed. Therefore, by uniformly degrading all the heater patterns 105, it is possible to provide a sanitary washing device having a stable performance for a long period of time by the user.

  The control unit 200 performs heating detected by the hot water thermistor 27 during start-up control from when energization to the plurality of heater patterns 105a, 105b, and 105c starts until a predetermined time elapses, in other words, during feedforward control. When the difference between the temperature of the generated water and the predetermined temperature determined by the control unit 200 is greater than or equal to a certain level, it is determined that the heater pattern 105 used as the main heater has deteriorated, and the heater Control is performed so as to increase the energization amount for the pattern 105 (hereinafter referred to as “energization amount increase control” for convenience of explanation).

  The control unit 200 accumulates and stores the number of times that the plurality of heater patterns 105a, 105b, and 105c have been subjected to energization amount increase control (the number of energization amount increase control times) for each of the plurality of heater patterns 105.

  In the heat exchanger 101 according to the present embodiment, the heater pattern 105 to be driven as the main heater is determined based on the number of times the stored energization amount increase control is performed in the energization control by the control unit 200. Take control.

  By performing the energization amount increase control, for example, when obtaining a desired output, even if the heater pattern 105a used as the main heater deteriorates and the time from the start of heating until reaching a predetermined temperature is increased, By controlling so that the energization amount larger than the energization amount to be applied to the heater pattern 105a can be controlled, it is possible to prevent the heating time from becoming long. Therefore, even if the heater pattern 105a deteriorates over time, the time until water of a predetermined temperature is discharged to the human body part does not become long, and a sanitary washing device having stable performance for a long period of time can be provided to the user.

7-9 is a figure explaining the specific example of the electricity supply state to a heater pattern. In each figure, (a) illustrates the energization state to the heater pattern 105a, (b) illustrates the energization state to the heater pattern 105b, and (c) illustrates the energization state to the heater pattern 105c. .
In this control example, one control unit is four sets, and energization control is performed with 16 waves per set. The output of each of the plurality of heater patterns 105a, 105b, and 105c is 400W.

The specific examples shown in FIGS. 7 to 9 show the energized state when an output of 25 W is obtained in one control unit. Here, in order to obtain an output of 25 W, energization for four waves may be performed in one set for one of the three heater patterns 105a, 105b, and 105c. That is, for one heater pattern 105, a 400 W output is energized by 4 out of 16 waves in one set, that is, 4/16 energization. This gives a 4/16 100W output of 400W per set. Further, the other two heater patterns 105 are not energized.
Further, among the four sets of one control unit, the other three sets are not energized to any of the heater patterns 105a, 105b and 105c. That is, 0 W.
Therefore, in one control unit, only one set out of the four sets has an output of 100 W, so an output of 25 W, which is 1/4 of 100 W, can be obtained.

  In FIG. 7, energization for 4/16 waves is performed to obtain 100 W only for the first set set1 of the heater pattern 105a among the three heater patterns 105a, 105b, and 105c in one control unit. On the other hand, the other two heater patterns 105b and 105c are not energized in any set.

As in this specific example, when the output of 25 W is continued, if energization is performed using only the specific heater pattern 105a as the main heater, the deterioration of the heater pattern 105a is more likely to proceed than the other two heater patterns 105b and 105c.
Therefore, in the present embodiment, the time for energizing the three heater patterns 105a, 105b, and 105c as main heaters is made equal by the drive time equalization control.

For example, in this specific example, as shown in FIG. 7, for one control unit, the heater pattern 105a is used as the main heater and only the first set set1 is energized to obtain 100 W. In the next one control unit, As shown in FIG. 8, only the first set set1 of the heater pattern 105b is energized to obtain 100W.
Further, in the next one control unit, as shown in FIG. 9, energization is performed to obtain 100 W only for the first set set 1 using the heater pattern 105 c as the main heater.
In this way, by switching the heater pattern 105 serving as the main heater in order, the time during which the plurality of heater patterns 105a, 105b, and 105c are energized as the main heater becomes equal.

Thereby, the plurality of heater patterns 105a, 105b and 105c are not used unevenly, and the life of the entire heat exchanger 101 can be extended.
Note that switching of the heater pattern 105 serving as the main heater is not limited to one control unit. For example, the heater pattern 105 serving as the main heater may be switched every time the user sits or when the energization becomes zero. That is, it is only necessary to switch the heater patterns 105a, 105b, and 105c so that the time for energization as the main heater becomes equal during a predetermined use period.

  As in this specific example, when 25 W is output, only the specific heater pattern 105 a is energized as the main heater, and the temperature of the heated water detected by the hot water thermistor 27 is determined by the control unit 200. When the difference between the predetermined temperature and the predetermined temperature is equal to or greater than a certain value, the energization amount increase control is performed on the specific heater pattern 105 to control the gain in units of one wave, in other words, the control to increase the output for 25 W. I do.

Thereby, even if the several heater patterns 105a, 105b, and 105c deteriorate, the heat exchanger 101 can always exhibit the stable performance.
The gain control in the energization amount increase control is not limited to one wave unit. For example, it may be performed in units of 2 waves or in units of 3 waves. That is, if the energization amount is controlled so that the temperature of the water supplied to the heat exchanger 101 can be raised to a predetermined temperature determined by the control unit 200 by the energization amount given to the heater pattern 105 within a predetermined time. Good.

  10A, 10B, and 10C are flowcharts illustrating the control logic of the control unit 200 according to an embodiment of the present invention. The control unit 200 executes the following control logic.

  First, in step S2, it is determined whether or not the user has received a cleaning start instruction from an operation unit such as a remote controller of the sanitary cleaning device 3 (S2). When the cleaning start instruction has not been received (S2, NO), the process of step S2 is repeated until the cleaning start instruction is received.

  When the cleaning start instruction is received from the operation unit (S2, YES), the control unit 200 proceeds to step S3 and starts the drive time equalization control illustrated in FIG. 10B. That is, it progresses to step S31 of FIG. 10B, and the object heater pattern 105 for determining whether it is the heater pattern 105 which should be used as a main heater is determined (S31). Every time this control is performed, the efficiency is improved when the heater pattern 105 determined first is changed in order. Therefore, the following determination is performed after the main heater target heater pattern 105 is changed.

Subsequently, the process proceeds to step S <b> 32, where the control unit 200 determines whether or not the driving time as the main heater of the target heater pattern 105 is longer than the average driving time as the main heater of all the heater patterns 105. Determine (S32).
At this time, when the driving time as the main heater of the target heater pattern 105 is longer than the driving time as the main heater of all the heater patterns 105 (S32, NO), the process proceeds to step S33, and when the driving time is the same or shorter (S32, YES) The process proceeds to step S34.

When the process proceeds to step S33 (S32, NO), the control unit 200 compares the energization amount increase control count of the target heater pattern 105 with the maximum energization amount increase control count of all the heater patterns 105, It is determined whether or not the number is small (S33).
At this time, if the energization amount increase control count of the target heater pattern 105 is small (S33, YES), the process proceeds to step S35, and if it is the same or longer (S33, NO), the process returns to step S31, and the target heater pattern 105 is set. To change.

When the process proceeds to step S34 (S32, YES), the control unit 200 has more energization amount increase control counts of the target heater pattern 105 than the maximum value of energization amount increase control counts of all the heater patterns 105. It is determined whether or not (S34).
At this time, when the energization amount increase control count of the target heater pattern 105 is large (S34, NO), the process returns to step S31, and the target heater pattern 105 is changed to be the same or short (S34, YES). Proceed to S35.

  The heater pattern 105 that has proceeded to step S35 is determined as the main heater (S35). Returning to FIG. 10A, the process proceeds to step S4.

  In step S4, the incoming thermistor 25 detects the temperature of the water led to the heat exchanger 101 in the initial state before energizing the heater pattern, and the temperature of the water before being heated by the heat exchanger 101 is determined by the hot water thermistor 27. Is detected (S4). Next, the process proceeds to step S5.

  In step S5, the output wattage requested by the control unit 200 for the heater pattern 105 is determined based on the temperature information of the water detected by the incoming water thermistor 25 and the hot water thermistor 27 in step S4 (S5). . Then, it progresses to step S6.

  In step S6, energization of the heater pattern 105 is started so as to correspond to the output wattage calculated in step S5 (S6). More specifically, energization is started according to the power distribution table corresponding to each heater pattern 105 as the main heater shown in FIG.

  After energization of the heater pattern 105 is started, the process proceeds to FIG. 10C and energization amount increase control is performed (S7). Based on the temperature detection in the initial state in step S4, the controller 200 energizes according to the determined output wattage and simultaneously starts the rising temperature determination timer (S71). The control unit 200 continues to operate the rising temperature determination timer until the rising temperature determination timer ends (S72, NO) (S72). When the predetermined time has elapsed and the rising temperature determination timer has ended (S72, YES), the controller 200 detects the temperature of the water heated by the heat exchanger 101 (S73).

  Subsequently, the process proceeds to step S74, where a temperature gradient that rises for a predetermined time, in other words, a temperature gradient obtained by dividing the difference between the temperature detected by the hot water thermistor in step S73 and the temperature detected by the hot water thermistor in step S4 by the predetermined time. When it is higher than the threshold value (S74, NO), the energization amount increase control is terminated and the process returns to FIG. 10A and proceeds to step S8. When the temperature gradient is equal to or lower than the threshold value (S74, YES), the process proceeds to step S75. Control (S75) is performed to increase the energization amount to the heater pattern 105 used as the main heater.

  The control to increase the energization amount to the heater pattern 105 used as the main heater in step S75 is to control the gain to increase the output for one wave, in other words, 25 W. More specifically, for example, when there is a power distribution table to a plurality of heater patterns 105 as shown in FIG. 6, energization control is performed so as to move to the power distribution in the next lower row. .

  In step S76, the control part 200 memorize | stores the frequency | count which performed the control which increases the energizing amount in step S75 for every several heater pattern 105 (S76). Next, it returns to FIG. 10A and progresses to step S8.

  Subsequently, in step S8, the incoming thermistor 25 detects the temperature of the water led to the heat exchanger 101 in the energized state after the heater pattern is energized, and the temperature of the water heated by the heat exchanger 101 is heated. The thermistor 27 detects (S8). Then, it progresses to step S9.

  In step S9, the output wattage required by the control unit 200 for the heater pattern 105 is determined based on the temperature information of the water detected by the incoming water thermistor 25 and the hot water thermistor 27 in step S8 (S9). . Then, it progresses to step S10.

  In step S10, energization to the heater pattern 105 is controlled so as to correspond to the output wattage calculated in step S9 (S10). More specifically, energization is controlled according to a power distribution table corresponding to each heater pattern 105 as the main heater shown in FIG.

  In step S11, it is determined whether or not the user has received a cleaning end instruction from an operation unit such as a remote controller of the sanitary cleaning device 3 (S11). If the cleaning end instruction has not been received (S11, NO), the process returns to step S8 until the cleaning end instruction is received, and the above-described control is repeated. When the control unit 200 receives a cleaning end instruction from the operation unit (S11, YES), the process proceeds to step S12, and energization of the heater pattern 105 is ended (S12).

  When energization of the heater pattern 105 is completed, the control unit 200 stores the drive time of the heater pattern 105 determined as the main heater in step S3 (S13).

  By controlling the cleaning operation by the sanitary cleaning device according to the control flow as described above, the heater pattern 105 that is not least deteriorated can be used as the main heater, and when the heater pattern 105 deteriorates, the energization amount Can be increased. Accordingly, it is possible to suppress the deterioration variation of all the heater patterns 105, and even if the heater pattern 105 is deteriorated, it is possible to prevent the time from the start of heating to reaching the predetermined temperature from becoming long.

DESCRIPTION OF SYMBOLS 1 Toilet bowl 3 Sanitary washing apparatus 5 Casing 7 Toilet seat 9 Toilet lid 10 Nozzle apparatus 11 Washing nozzle 12 Nozzle flow path 13 Water outlet 15 Seating detection sensor 17 Bowl 19 Branch metal fitting 21 Valve unit 23 Water supply valve 25 Incoming thermistor 27 Hot water thermistor 101 Heat exchange Vessel 102 cylindrical portion 103 heating element 104a water flow path 104b water flow path 105 heater pattern 105a heater pattern a
105b Heater pattern b
105c Heater pattern c
106 Flange portion 107 Case portion 109 Power supply 111 Switch means 111a Switch means a
111b Switch means b
111c switch means c

Claims (4)

A sanitary washing device that discharges water to a local human body while heating water flowing through a water passage to a predetermined temperature,
A heating element provided with a heater pattern that generates heat when energized;
A case portion in which the heating element is inserted and a water flow path of the supplied water is formed around the heating element;
A hot water temperature sensor for detecting the temperature of hot water heated by the heating element;
A control unit that controls an energization amount for the heater pattern based on a temperature detected by the tapping temperature sensor, and the control unit at the time of start-up control until a predetermined time elapses from the start of energization,
It is determined whether or not the heater pattern is deteriorated based on a change with time of the temperature detected by the hot water temperature sensor, and when it is determined that there is deterioration, control is performed so as to increase an energization amount to the heater pattern. Cleaning device. The heating element is provided with a plurality of the heater patterns,
The controller determines distribution of energization amounts for the plurality of heater patterns based on a predetermined priority order to heat the water flowing through the water flow path to a predetermined temperature.
Furthermore, the control unit can accumulate and store the drive time energized in the state where the distribution amount of the energization amount is the largest for each of the plurality of heater patterns. The sanitary washing device according to claim 1, wherein control is performed so that a distribution amount of the energization amount for the heater pattern having the shortest storage value of the driving time is maximized so that the storage values are uniform. The control unit is capable of accumulating and storing the number of energization amount control controlled to increase the energization amount for each of the plurality of heater patterns,
The sanitary washing according to claim 2, wherein control is performed so that the distribution amount of the energization amount for the heater pattern having the smallest stored value of the energization amount increase control count is maximized so that the energization amount increase control count is equalized. apparatus. 4. In the priority order, the distribution amount of the energization amount for the heater pattern is increased in preference to the fact that the stored value of the energization amount increase control count is smaller than the short storage value of the drive time. The sanitary washing device described.

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