JPH0860729A - Sanitary washing equipment - Google Patents

Abstract

(57) [Abstract] [Purpose] Hygiene to supply hot air equal to the set temperature by automatically compensating for errors in warm air temperature due to fluctuations in the primary voltage, variations in the resistance value of the heater, or variations in the rotation speed of the motor. A cleaning device is provided. A heater control amount is calculated by a CPU 11 from a difference between a set temperature and a room temperature and a heat amount supply capacity of a drying unit 1, and a rotation speed of a motor 1a detected by a motor rotation speed detection unit 12 and a heater current value detection unit. The resistance value of the heater 1b based on the current value of the heater 1b detected by
Also, the heater control amount is corrected based on the primary voltage value of the commercial power source 4 detected by the primary voltage value detection unit 14, and the drying heater drive unit 8 is instructed to drive and control the heater 1b based on the corrected heater control amount.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a sanitary washing device,
In particular, the present invention relates to a sanitary washing device that blows warm air having a temperature set by a user as warm air for drying a water-exposed portion of a human body.

[0002]

2. Description of the Related Art Conventionally, this type of sanitary washing device has a structure as shown in FIG. FIG. 5 is a plan view of the sanitary washing device, in which 1 is a motor 1a, a fan 1c that rotates according to the drive of the motor 1a, and a heater 1b that heats the air blown from the fan 1c, and blows warm air. Drying unit, 2 is a room temperature sensor for detecting room temperature,
3 is a switch unit having a drying switch 3a for the user to instruct start / stop of hot air blowing and a temperature setting switch 3b for the user to set the hot air temperature, and 5 is a switch unit 3 by the user. The control unit controls the motor 1a and the heater 1b according to the operation.

FIG. 6 is a block diagram of a sanitary washing device. In FIG. 6, the same parts as those described above are designated by the same reference numerals. In the control unit 5 of FIG. 6, 6 is a power supply unit that generates a DC voltage for driving the motor 1a and a DC voltage for various control circuits from the commercial power supply 4, and 7 drives the motor 1a by the DC voltage from the power supply unit 6. A drying motor drive unit, 8 is a drying heater drive unit that drives the heater 1b by the commercial power source 4, and 9 is a heater control amount calculated from the room temperature detected by the room temperature sensor 2 according to the operation of the switch unit 3 by the user. Is a CPU that controls the drying motor driving unit 7 and the drying heater driving unit 8 based on the heater control amount, and blows warm air of the set temperature from the motor 1a and the heater 1b.

When the user operates the drying switch 3a, the CPU 9 detects it and instructs the drying motor drive section 7 to start driving the motor 1a. Next, the room temperature sensor 2 detects the current room temperature TA, and the temperature setting switch 3b detects the set temperature TS of the hot air, and the heater control amount is detected from the temperature difference between these temperatures and the heat quantity supply capacity TH of the drying unit 1. To calculate. Here, when the room temperature TA = 20 ° C and the set temperature TS = 50 ° C,
The amount of supplied heat TV required to raise the temperature is TV = TS-TA = 30 deg.

The heat supply capacity TH of the drying unit 1
However, if the heat amount of 60 deg can be supplied at 100% drive, the heat supply amount TV (= 30 deg) can be supplied with half the heat amount supply capacity. Therefore, the rate at which the heat supply capacity TH of the drying unit 1 is used, that is, the heater control amount P can be expressed as P (%) = TV / TH = (TS-TA) / TH, and the heater control amount in this case P becomes P = (50-20) / 60 = 50%.

The CPU 9 outputs the calculated heater control amount P to the drying heater driving unit 8, and the drying heater driving unit 8 commercializes the heater 1b for P% of the period t based on the heater control amount P. The power supply 4 is supplied, and the supply is stopped for other periods. FIG. 7 shows the heater 1 by the dry heater driving unit 8.
3 is a timing chart showing drive control of FIG.
Is the heater control amount P = 30%, (b) is the heater control amount P = 50%, and (c) is the heater control amount P = 70%.
When the heater control amount P is 50% as described above, the heater 1b is driven by 50% (0.5t) of the cycle t to heat the air.

[0007]

Therefore, in such a conventional sanitary washing device, the warm air of the temperature set by the user is caused by the fluctuation of the commercial power supply, the variation of the heater resistance value, the variation of the motor rotation speed, and the like. There was a problem that it could not be supplied accurately. The amount of heat supplied from the heater 1b is determined by the power consumption W in the heater 1b, where the primary voltage of the commercial power source 4 is V, the resistance value of the heater 1b is R, and the current flowing through the heater 1b is I. , The power consumption W is W = V ² / R = V · I.

Here, it is generally assumed that the primary voltage V of the commercial power source 4 has a certain degree of fluctuation, for example, about ± 10% with respect to 100 V. From the above equation, the primary voltage V is compared. When the target voltage is high, the power consumption W also increases, the amount of heat supplied from the heater 1b increases, and hot air having a temperature higher than the set temperature is supplied, and when the primary voltage V is relatively low, the power consumption increases. Since the electric power W also decreases, the amount of heat supplied from the heater 1b decreases, and the hot air having a temperature lower than the set temperature is supplied. Therefore, even if the set temperature is constant, the warm air is changed due to the fluctuation of the primary voltage V. There is a problem in that the temperature changes and the user feels uncomfortable.

Similarly, the resistance value R of the heater 1b is also
In the heater 1b, which has a variation in production, for example, a variation of about ± 5%, and the resistance value R is relatively low, the power consumption W increases due to the increase in the current I, and the amount of heat supplied from the heater 1b is large. In the heater 1b having a relatively high resistance value R, the power consumption W is also reduced due to the decrease in the current I and the amount of heat supplied from the heater 1b is also reduced. Since hot air having a temperature lower than the set temperature is supplied, even if the set temperature is constant, the hot air temperature changes due to the variation in the resistance value R of the heater 1b, which gives the user discomfort. There was a problem.

Further, when a DC motor is used as the motor 1a, variations in the number of revolutions with respect to a predetermined voltage,
For example, if the motor 1a has a variation of about ± 10% and the rotation speed is relatively low with respect to the supplied voltage, the fan 1c
As a result, the amount of air supplied to the heater 1b is reduced, and hot air having a temperature higher than the set temperature is supplied. Further, in the motor 1a having a relatively high rotation speed with respect to the supplied voltage, the fan 1c supplies the heater 1b to the heater 1b. Since the amount of supplied air increases and hot air having a temperature lower than the set temperature is supplied, the hot air temperature changes due to the variation in the rotation speed of the motor 1a even if the set temperature is constant, and the user There was a problem in that it was uncomfortable with.

When an AC motor is used as the motor 1a, its rotation speed is almost constant because it depends on the frequency of the commercial power source 4, but it is expensive as compared with the DC motor, and the AC motor is drive-controlled. Therefore, there is a problem in that the circuit components forming the drying motor driving unit 7 are also expensive. The present invention is for solving such a problem, and automatically corrects the error of the warm air temperature due to the fluctuation of the primary voltage, the fluctuation of the resistance value of the heater or the fluctuation of the rotation speed of the motor, and the set temperature is adjusted. It is an object of the present invention to provide a sanitary washing device that supplies equal hot air.

[0012]

In order to achieve such an object, the sanitary washing device according to the present invention is driven by a motor for driving a fan that blows air, and a fan that is driven by a predetermined power supply voltage. A heater for heating air, a hot air drying means having a heat quantity supplying ability for supplying a predetermined quantity of heat when a rated voltage is supplied as a power supply voltage, and a heater voltage value detecting means for detecting a voltage supplied to the heater. And a heater control amount indicating the ratio of the energization time of the heater from the difference between the predetermined set temperature and room temperature and the heat quantity supply capacity, and the heater based on the voltage value and the rated voltage detected by the heater voltage value detection means. The control means for correcting the control amount and the heater driving means for driving the heater based on the corrected heater control amount are provided.
Further, it is composed of a motor that drives a fan that blows air, and a heater that heats the air that is blown by the fan. When the heater has a rated resistance value as a resistance value, it has a heat quantity supply capacity that supplies a predetermined amount of heat. The air drying means, the heater current value detecting means for detecting the current supplied to the heater, and the heater control amount indicating the ratio of the energization time of the heater from the difference between the predetermined set temperature and the room temperature and the heat quantity supply capacity. A control means for correcting the heater control amount based on the heater resistance value and the rated resistance value calculated from the current value detected by the heater current value detection means, and a heater driving means for driving the heater based on the corrected heater control amount And with. It also consists of a motor that drives a fan that blows air, and a heater that heats the air that is blown by the fan, and has a heat supply capacity that supplies a predetermined amount of heat when the rated rotation speed is obtained as the rotation speed of the motor. While having a warm air drying means, a motor rotation speed detection means for detecting the rotation speed of the motor, and a heater control amount indicating the ratio of the energization time of the heater from the difference between the predetermined set temperature and room temperature and the heat quantity supply capacity. A control means for correcting the heater control amount based on the rotation speed detected by the motor rotation speed detection means and the rated rotation speed, and a heater driving means for driving the heater based on the corrected heater control quantity. .

[0013]

Therefore, the control means calculates the heater control amount indicating the ratio of the energization time of the heater from the difference between the predetermined set temperature and the room temperature and the heat quantity supply capacity, and the voltage detected by the heater voltage value detecting means. The heater control amount is corrected based on the value and the rated voltage, and the heater is driven based on the corrected heater control amount. Also, by the control means,
The heater control amount indicating the ratio of the energization time of the heater is calculated from the difference between the predetermined set temperature and the room temperature and the heat quantity supply capacity, and the heater resistance value and the rating calculated from the current value detected by the heater current value detecting means. The heater control amount is corrected based on the resistance value, and the heater is driven based on the corrected heater control amount. Further, the control means calculates the heater control amount indicating the ratio of the energization time of the heater from the difference between the predetermined set temperature and the room temperature and the heat quantity supply capacity, and the rotation speed and the rating detected by the motor rotation speed detection means. The heater control amount is corrected based on the rotation speed, and the heater is driven based on the corrected heater control amount.

[0014]

Next, the present invention will be described with reference to the drawings. FIG. 1 is a block diagram of a sanitary washing device according to an embodiment of the present invention, in which the same or equivalent parts as those described above are designated by the same reference numerals. In the control unit 5, 12 is a motor rotation speed detection unit (motor rotation speed detection unit) that detects the rotation speed of the motor 1a in the drying unit 1 (warm air drying unit), and 13 is a heater 1b in the drying unit 1.
A heater current value detection unit (heater current value detection unit) that detects a current flowing through the device, 14 is a primary voltage value detection unit (heater voltage value detection unit) that detects a primary voltage supplied from the commercial power supply 4 to the heater 1b, 11 Is the rotation speed of the motor 1a detected by the motor rotation speed detection unit 12, the current value flowing through the heater 1b detected by the heater current value detection unit 13, and the primary of the commercial power supply 4 detected by the primary voltage value detection unit 14. The heater control amount is corrected based on the voltage value, and the heater 1 is applied to the drying heater driving unit 8 based on the corrected heater control amount.
It is a CPU (control means) for instructing drive control of b.

FIG. 2 is a circuit diagram showing the primary voltage detector 14, where FIG. 2A shows a case where the commercial power source 4 and the controller 5 are insulated from each other by using a transformer (current transformer) CT, and FIG.
Shows the case where the photocoupler PC is used for insulation. In FIG. 2A, RP is a fixed resistance,
A current IP corresponding to the primary voltage V of the commercial power source 4 flows through the transformer CT. Assuming that the conversion rate of the transformer CT is n, the secondary side current IS of the transformer CT is: IS = nIP = n (V / Rp)

A secondary voltage VS, VS = RS.multidot.IS = RS.multidot.n.multidot. (V / RP), is generated across the secondary side fixed resistor RS and is rectified by the diode D, and then rectified by the capacitor C. A / which is stabilized and is one of the input ports of the CPU 11
The primary voltage V is calculated from the secondary voltage VS input to the D input port, that is, the port provided with means for converting an analog signal into a digital value.

Further, in FIG. 2B, a photocoupler PC
The primary side (LED) is a commercial power source 4 via a fixed resistor RP.
, And a primary current IP corresponding to the primary voltage V of the commercial power supply 4 flows. Assuming that the current-voltage conversion rate of the photocoupler PC is A, the secondary voltage VS of the photocoupler PC (phototransistor) is VS = A.IP = A. (V / RP), and the capacitor C After stabilization, CPU11
Secondary voltage V input to the A / D input port of
The primary voltage V is calculated from S.

FIG. 3 is a circuit diagram showing the heater current value detection unit 13, in which the primary side of the transformer CT (current transformer) is connected via the heater 1b having a resistance value R and the drying heater driving unit 8. It is connected to the commercial power supply 4.
Since the drying heater driving unit 8 controls ON / OFF of the current supply to the heater 1b, the resistance component in the drying heater driving unit 8 can be ignored, and the primary current IP flowing in the primary side of the transformer CT can be ignored. Becomes IP = R · V.

Here, assuming that the conversion rate of the transformer CT is n, the secondary side current IS and the secondary voltage VS are: IS = n.multidot.IP = n.multidot.R.V as in the case of FIG. VS = RS.multidot.IS = RS.multidot.n.multidot.R.multidot.V, rectified by the diode D, stabilized by the capacitor C, and input to the A / D input port of the CPU
The resistance value R of the heater 1b is calculated from the input secondary voltage VS. The primary current IP supplied to the heater 1b
Is supplied for a predetermined period according to the heater control amount, and the CPU 11 detects a signal from the heater current value detection unit 13 during the period when the primary current is supplied.

FIG. 4 is a circuit diagram showing the motor rotation speed detection unit 12. Reference numeral 41 is a disk portion provided with a slit portion for passing light from the primary side (LED) of the photointerrupter PI to rotate the motor 1a. Disk member that rotates according to PI
Is a photo interrupter, and a rotary encoder is constituted by both. LE of photo interrupter PI
A predetermined current is constantly supplied to D through the fixed resistor RP, and light is emitted to the phototransistor on the secondary side. A disc member 41 is provided between the LED of the photointerrupter PI and the phototransistor, and the disc member 41 rotates in response to the rotation of the motor 1a, and the light passing through the slit portion is detected by the phototransistor.
A pulse corresponding to the rotation speed of the motor 1a is input to the input port of the CPU 11 that is pulled up by the fixed resistance RS, and the rotation speed of the motor 1a is calculated from the input pulse number.

Next, the operation of the present invention will be described with reference to FIG. First, in response to the user's operation of the drying switch 3a, the CPU 11 instructs the drying motor drive unit 7 to start driving the motor 1a, and the drying motor drive unit 7 supplies the DC voltage from the power supply unit 6 to the motor 1a. To start driving. Next, the CPU 11 detects the current room temperature TA by the room temperature sensor 2 and the set temperature TS of the hot air by the temperature setting switch 3b, and detects the heater from the temperature difference between these temperatures and the heat supply capacity TH of the drying unit 1. The control amount is calculated, and the heater control amount P is calculated as described above. P (%) = TV / TH = (TS-TA) / TH

Next, the CPU 11 causes the primary voltage value detector 14 to
The primary voltage Vb supplied from the commercial power supply 4 to the heater 1b via the heater is detected, and the rated primary voltage Va serving as a reference when the heater 1b supplies the amount of heat according to the amount of heat supply capacity TH.
The calculated heater control amount P is corrected based on (for example, 100 V). Here, since the amount of heat supplied from the heater 1b is proportional to the power consumption W in the heater 1b, that is, to the square of the primary voltage supplied to the heater 1b, P = P. (Va ² / Vb ² ) · XV corrected. XV is a correction coefficient at the time of correction based on the primary voltage, and is the square ratio (Va ² / Vb ² ) of the primary voltage.
It may be calculated on the basis of the correction based on and the actual measurement value, and may be used if necessary.

The CPU 11 also includes a motor rotation speed detector 1
The rotation speed rb of the motor 1a is detected via the
The calculated heater control amount P is corrected based on the rated rotational speed ra of the motor 1a, which serves as a reference when b supplies a heat amount corresponding to the heat amount supply capacity TH. Here, since the amount of heat supplied from the heater 1b changes according to the ratio of the number of rotations of the motor 1a, it is corrected by P = P. (Rb / ra) .Xr. It should be noted that Xr is a correction coefficient at the time of correction based on the motor rotation speed, and may be calculated based on the correction based on the rotation speed ratio (rb / ra) and the actually measured value, and may be used as necessary.

Further, the CPU 11 determines from the value of the current flowing through the heater 1b via the heater current value detector 13 to the heater 1b.
The resistance value Rb of the
Rated resistance value R, which is the standard when supplying the amount of heat according to
The calculated heater control amount P is corrected based on a. Here, the amount of heat supplied from the heater 1b is proportional to the power consumption W in the heater 1b, that is, the heater 1b.
Since it is inversely proportional to the resistance value of P, it is corrected by P = P. (Rb / Ra) .XR.

It should be noted that XR is a correction coefficient at the time of correction based on the heater resistance value, and may be calculated based on the correction by the resistance ratio (Rb / Ra) and the actually measured value, and may be used as necessary. Further, by using the value detected through the primary voltage value detection unit 14 as the primary voltage V of the commercial power source 4 used when calculating the resistance value Rb of the heater 1b, the resistance value Rb of the heater 1b can be more accurately measured. Can be calculated,
The heater control amount P can be corrected with higher accuracy.

In this way, the CPU 11 corrects the calculated heater control amount P and then outputs it to the drying heater driving unit 8, which, as shown in FIG.
Based on the heater control amount P, the commercial power source 4 is supplied to the heater 1b only during the period P% of the cycle t, and the supply is stopped during the other periods, whereby the heater 1b is driven and controlled.

Therefore, a motor rotation detector 12 for detecting the number of rotations of the motor 1a, a heater current value detector 13 for detecting the current flowing through the heater 1b, and a primary voltage value detector 14 for detecting the primary voltage of the commercial power supply 4 are provided. The motor 1 that is provided and detected by the motor rotation speed detection unit 12 by the CPU 11
A heater based on the rotation speed of a, the resistance value of the heater 1b based on the current value flowing through the heater 1b detected by the heater current value detection unit 13, and the primary voltage value of the commercial power source 4 detected by the primary voltage value detection unit 14. Since the control amount is corrected and the driving control of the heater 1b is instructed to the drying heater driving unit 8 by the corrected heater control amount, the fluctuation of the primary voltage, the variation of the resistance value of the heater, or the rotation speed of the motor is reduced. The error of the hot air temperature due to the variation is automatically corrected, and the hot air equal to the set temperature is supplied.

In the above description, as the correction for the heater control amount P obtained from the room temperature and the set temperature, the fluctuation of the primary voltage of the commercial power source 4, the variation of the resistance value of the heater 1b and the variation of the rotation speed of the motor 1a. Although the correction is performed based on the above, any one of them or any combination thereof may be used for the correction, and the heater control amount can be corrected by a simpler configuration. This makes it possible to accurately supply hot air having a temperature desired by the user.

[0029]

As described above, according to the present invention, the heater voltage value detecting means for detecting the voltage value supplied to the heater is provided, and the control means causes the difference between the predetermined set temperature and the room temperature and the heat quantity to be supplied. The heater control amount indicating the ratio of the energization time of the heater is calculated from the capacity, the heater control amount is corrected based on the voltage value detected by the heater voltage value detection means and the rated voltage, and based on the corrected heater control amount. Since the heater is driven, it is possible to stably supply hot air having a temperature equal to the set temperature set by the user even when the commercial power supply or the like supplied to the heater changes.

Further, a heater current value detection means for detecting the current supplied to the heater is provided, and the control means indicates the ratio of the energization time of the heater from the difference between the predetermined set temperature and the room temperature and the heat quantity supply capacity. The control amount is calculated, the heater control amount is corrected based on the heater resistance value and the rated resistance value calculated from the current value detected by the heater current value detection means, and the heater is driven based on the corrected heater control amount. As a result, even if the resistance value of the heater itself varies, it is possible to stably supply hot air having a temperature equal to the set temperature set by the user.

Further, a motor rotation speed detection means for detecting the rotation speed of the motor is provided, and the control means controls the heater control amount indicating the ratio of the energization time of the heater from the difference between a predetermined set temperature and room temperature and the heat supply capacity. Is calculated, the heater control amount is corrected based on the rotation speed detected by the motor rotation speed detection means and the rated rotation speed, and the heater is driven based on the corrected heater control amount. Even if there is a variation in the number, it becomes possible to stably supply hot air having a temperature equal to the set temperature set by the user.

[Brief description of drawings]

FIG. 1 is a block diagram of a sanitary washing device according to an embodiment of the present invention.

FIG. 2 is a circuit diagram of the primary voltage value detection unit of FIG.

FIG. 3 is a circuit diagram of a heater current value detection unit in FIG.

FIG. 4 is a circuit diagram of a motor rotation speed detection unit in FIG.

FIG. 5 is a plan view of a general sanitary washing device.

FIG. 6 is a circuit diagram of a conventional sanitary washing device.

FIG. 7 is a timing chart showing heater drive control based on a heater control amount.

[Explanation of symbols]

1 ... Drying unit (warm air drying means), 1a motor, 1b
Heater, 2 room temperature sensor, 3 switch section, 3a drying switch, 3b temperature setting switch, 4 commercial power source, 5 control section, 6
Power supply unit, 7 drying motor drive unit, 8 drying heater drive unit (heater drive unit), 11 CPU (control unit), 12 motor rotation speed detection unit (motor rotation speed detection unit), 13 heater current value detection unit (heater current value) Detection unit), 14 primary voltage value detection unit (heater voltage value detection unit).

Claims (3)

[Claims] 1. A sanitary washing device for drying a human body wet part by blowing warm air, comprising: a motor that drives a fan that blows air, and air that is blown by the fan that is driven by a predetermined power supply voltage. A warm air drying unit that includes a heater that heats and has a heat amount supply capability that supplies a predetermined amount of heat when a rated voltage is supplied as the power supply voltage, and a heater voltage value detection unit that detects the voltage supplied to the heater. And a heater control amount indicating the ratio of the energization time of the heater from the difference between the predetermined set temperature and room temperature and the heat quantity supply capacity, and the voltage value detected by the heater voltage value detection means and the rated voltage. And a heater driving unit that drives the heater based on the corrected heater control amount. Sanitary washing device, characterized in that it comprises. 2. A sanitary washing device for drying a human body submerged part by blowing warm air, comprising: a motor for driving a fan for blowing air, and a heater for heating air blown by the fan,
When the heater has a rated resistance value as a resistance value, a warm air drying means having a heat quantity supplying ability for supplying a predetermined heat quantity, a heater current value detecting means for detecting a current supplied to the heater, and a predetermined setting. A heater resistance value calculated from the current value detected by the heater current value detection means and the rated value are calculated from the difference between the temperature and the room temperature, and the heater control amount indicating the ratio of the energization time of the heater from the heat supply capacity. A sanitary washing device comprising: a control unit that corrects the heater control amount based on a resistance value; and a heater driving unit that drives the heater based on the corrected heater control amount. 3. A sanitary washing device for drying a water-exposed part of a human body by blowing warm air, comprising: a motor for driving a fan for blowing air, and a heater for heating the air blown by the fan,
A warm air drying means having a heat quantity supply capacity for supplying a predetermined quantity of heat when a rated rotation speed is obtained as the rotation speed of the motor, a motor rotation speed detection means for detecting the rotation speed of the motor, and a predetermined setting. The heater control amount indicating the ratio of the energization time of the heater is calculated from the difference between the temperature and the room temperature and the heat amount supply capacity, and based on the rotation speed detected by the motor rotation speed detection means and the rated rotation speed, A sanitary washing device comprising: a control unit that corrects a heater control amount; and a heater driving unit that drives the heater based on the corrected heater control amount.