JPH0127445B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to an infrared sauna bath temperature control device.

In a sauna bath that uses infrared rays, especially far infrared rays (wavelength 5 μm to 1 mm), the bathing temperature is set to a desired value in advance, the far infrared heater is energized to raise the bathroom temperature to the set temperature, and then the setting is Control the far infrared heater to maintain the temperature. Bathers were allowed to enter the bathroom only after the temperature had risen to the set temperature. However, according to such temperature control, when a bather enters the bathroom, the bathroom temperature is at the set temperature, so the far-infrared heater is not energized. If the bathroom temperature were to be energized, it would be to compensate for the drop and maintain the set temperature when the bathroom temperature falls below the set temperature due to natural heat radiation.
In this case, the bather is not irradiated with far-infrared rays, and therefore, it is not possible to fully expect the sauna bath effect due to the penetrating action of far-infrared rays into the body surface.

The object of this invention is to irradiate a bather with far-infrared rays from the moment he or she takes a bath, and to actively irradiate the bather even while taking a bath.

FIG. 1 shows a temperature control program according to the present invention. Prior to bathing, set the desired bathing temperature T (any temperature above 60°C). The far-infrared heater is then energized to raise the temperature in the bathroom. On the other hand, a bathing temperature _T1 is separately set in advance.
This temperature is lower than the bathing temperature, for example, about 40°C. This allows a naked bather to enter the bathroom and remain in the bathroom without feeling cold.

Assuming that the temperature in the bathroom is raised by energizing the far-infrared heater and reaches temperature T 1 at time t ₁ , the bathroom temperature will remain at temperature T ₁ from then on until a bather takes a bath _.
will be maintained. In other words, with temperature T ₁ as the target value,
When the bathroom temperature naturally dissipates and decreases, the far-infrared heater is energized only at that time so as to bring it back to temperature _T1 .

If the bather starts taking a bath in this state,
When this is detected, the bathroom temperature is controlled using the set temperature T as the target value. For example, if bathing is started at time _t2 , power supply to the far-infrared heater is restarted. Then, energization is continued until the set temperature T is reached at time _t3 . Therefore, the bather is irradiated with far-infrared rays due to the heat generated by the far-infrared heater immediately after starting bathing.

Next, when the bathroom temperature reaches the set temperature T, the bathroom temperature is controlled to be maintained at the temperature T from then on. That is, when the bathroom temperature reaches temperature T, power supply to the far-infrared heater is stopped, and when the bathroom temperature drops by dT, power supply to the far-infrared heater is restarted. However, in this case, in this invention, when the power supply to the far-infrared heater is stopped at time _t3 , the bathroom temperature is actively lowered by dT in a relatively short period of time. To do this, for example, you can run a ventilation fan or widen the ventilation openings to quickly dissipate hot air from the bathroom.

After the temperature is rapidly lowered by dT in this way, the far-infrared heater is energized again at time _t4 . At this time, the bather is irradiated with far-infrared rays. Therefore, even if the duration of one bath is the same, the temperature
If dT is reduced rapidly, the number of times the far-infrared heater is energized will be greater than if this temperature drop were due to natural dissipation. This means that the amount of far-infrared rays irradiated to bathers has increased.

As described above, far-infrared rays can be irradiated to the bather from the time the bather starts bathing, and even while the bather is taking a bath, a larger amount of far-infrared rays than before can be irradiated. Therefore, this kind of sauna bath effect can be fully achieved.

Next, an embodiment of the present invention will be described with reference to FIG. 1 is an infrared heater, for example a far infrared heater;
2 is its power supply, 3 is a bidirectional thyristor that turns on and off the power supply to the far infrared heater 1 from the power supply 2, 4 is a ventilation fan for dissipating the hot air in the bathroom to the outside, 5 is its power supply, 6 is a ventilation fan This is a bidirectional thyristor that turns on and off the current to thyristor 3, which is turned on and off in the opposite phase to thyristor 3. Reference numeral 7 denotes a temperature sensor for detecting the temperature of the bathroom, and as shown in FIG. 3, this uses a temperature sensor having a characteristic that as the detected temperature, that is, the bathroom temperature increases, the output voltage decreases.

Reference numeral 8 denotes a setting device for setting the bathroom temperature to bathing temperature T ₁ , and the voltage generated by this setting device 8 is V ₁ .
Reference numeral 9 denotes a setting device, such as a variable resistor, for setting the bathroom temperature to a desired bathing temperature T, and the voltage applied by this setting device 9 is V. 10 and 11 are comparators consisting of operational amplifiers; 12 is a bathing detection device that detects when a bather is taking a bath; for example, a contact that is turned on when taking a bath;
Specifically, it may be set to turn on automatically or manually when the bather sits in a predetermined position in the bathroom, or the bather may turn on the desired switch in advance using a timer before taking a bath. When setting the bathing time, it may be turned on along with the setting operation.

13 to 16 are NAND gates, 17 and 18 are not gates, and 19 and 20 are semiconductor switches such as transistors, which are inserted into the gate circuits of the thyristors 3 and 6 to turn them on and off.

In the above configuration, the bathroom temperature is set to a desired value T by the setting device 9 prior to bathing. Also, at this time, the bathroom temperature is lower than the set temperature T ₁ , T.
The output voltage of the temperature sensor 7 is higher than the voltage V ₁ ,V.
Therefore, the outputs of comparators 10 and 11 are both H. Also, since bathing has not yet started, contact 12 remains off. As a result, the outputs of NAND gate 13 and not gate 17 become L, and the output of NAND gate 14 becomes H, so NAND gate 1
5 becomes H, the transistor 19 is turned on, and the thyristor 3 is turned on, so that the far-infrared heater 1 is energized and the temperature of the bathroom is raised. On the other hand, since the output of the NAND gate 16 becomes H, the transistor 20 is turned off and the ventilation fan 4 does not operate at all.

Next, when the bathroom temperature reaches the bathing temperature T ₁ ,
Since the output voltage of the temperature sensor 7 is _V1 , the output of the comparator 10 is L. Therefore, the outputs of NAND gates 13 and 15 are inverted, and transistor 19 is turned off. Therefore, at this point, the supply of electricity to the far-infrared heater 1 is stopped. This state continues until the bather starts taking a bath. However, the bathroom temperature is
When the temperature decreases from T ₁ due to natural dissipation, the output of the comparator 10 is reversed, so that the far-infrared heater 1 is energized again. That is, the bathroom temperature is the temperature T ₁
It is controlled to maintain the

Assume that the bather starts taking a bath in this state. Then, since the contact 12 is turned on, the output of the not gate 17 is inverted and becomes H. Therefore, the outputs of the NAND gates 14 and 15 are also inverted, the transistor 19 is turned on again, and the far-infrared heater 1 is energized. As a result, the bather is irradiated with far-infrared rays from the beginning of bathing. When the bathroom temperature reaches the set temperature T by energizing the far-infrared heater 1, the output of the temperature sensor 7 becomes V, and the output of the comparator 11 is inverted and becomes L. As a result, the outputs of the NAND gates 14 and 15 are inverted, the transistor 19 is turned off, and the supply of electricity to the far-infrared heater 1 is stopped. Thereafter, when the bathroom temperature decreases by dT, the output of the comparator 11 is inverted and energized.

On the other hand, when the output of the comparator 11 is inverted to L as described above, the output of the NAND gate 16 is inverted to L. At this point, the transistor 20 is turned on,
The thyristor 6 is turned on and the ventilation fan 4 starts operating. Due to this operation, hot air in the bathroom is rapidly dissipated to the outside. This radiation causes the bathroom temperature to increase.
When the voltage decreases by dT, the output of the comparator 11 is inverted again, the far-infrared heater 1 is energized, and the ventilation fan is stopped. The above action is then repeated during the bathing period of the bather.

In the example shown in the figure, the bathroom temperature is T, T ₁
When the temperature reaches that temperature, the power to the far infrared heater is stopped, but instead of this, we prepare multiple far infrared heaters, and when the temperature rises, we turn on all of them, and when each temperature is reached, Only one or several of them may be energized. Alternatively, the power supplied to the far-infrared heater may be reduced.

As detailed above, according to the present invention, it is possible to irradiate infrared rays immediately after a bather starts bathing, and also to actively lower the bathroom temperature in a short time even during bathing. In addition, since the temperature is raised to maintain the set temperature, more infrared rays can be irradiated to the bather, and this type of sauna bath effect can be sufficiently enhanced.

[Brief explanation of drawings]

FIG. 1 is a control characteristic diagram according to an embodiment of the present invention.
FIG. 2 is a circuit diagram showing an embodiment of the present invention, and FIG. 3 is a characteristic diagram of a temperature sensor. 1... Far infrared heater, 2... Power source, 3... Thyristor, 4... Ventilation fan, 5... Power source, 6... Thyristor, 7... Temperature sensor, 8, 9... Setting device, 10, 11... ... Comparator, 13-16 ... NAND gate, 17, 18 ... Not gate, 19,
20...Semiconductor switch.

Claims (1)

[Claims] 1. An infrared heater installed in the bathroom, a temperature sensor that outputs an output corresponding to the temperature of the bathroom, a bathing detection device that detects bathing in the bathroom and outputs a signal, and presets the temperature of the bathroom. a first temperature control device that controls the heat generation of the infrared heater based on the output of the temperature sensor so as to maintain the bathing temperature at a certain bathing temperature; a second temperature control device that controls heat generation of the infrared heater to raise and maintain the temperature of the bathroom to a desired set temperature higher than the bathing temperature based on the output of the sensor; After the bathroom temperature reaches the set temperature, the amount of ventilation in the bathroom is increased so as to accelerate the rate of decrease in the bathroom temperature while the second temperature control device is suppressing the heat generation of the infrared heater. An infrared sauna bath temperature control device consisting of a ventilation amount control device and a ventilation amount control device.