JP5641311B2 - Heating toilet seat device - Google Patents

Description

  The aspect of this invention is related with the heating toilet seat apparatus which can warm the toilet seat provided in a toilet bowl.

  Generally, the seat surface of the toilet seat is made of a resin such as PP (polypropylene), so the user may feel cold when sitting on a cold toilet seat when the temperature is low, such as in winter. is there. Therefore, there is a heated toilet seat device that can warm the toilet seat. In such a heated toilet seat device, various proposals have been made to save energy.

  For example, in patent document 1, the heating toilet seat apparatus using induction heating is disclosed. This heating toilet seat device includes an induction heating coil and an electric heater, and these are controlled by one control unit. In this heating toilet seat device, when a user enters the room, induction heating is performed to rapidly heat the toilet seat. After that, the toilet seat is kept warm by an electric heater.

  However, in the heating toilet seat device described in Patent Document 1, when an abnormality occurs in energization of the induction heating coil, there is a problem that the toilet seat reaches an abnormally high temperature in a short time.

  As a heating toilet seat device provided with a safety device against a rapid temperature rise of the toilet seat, a technique of providing a temperature fuse or a thermostat on the toilet seat is known (Patent Document 2). In the heating toilet seat device described in Patent Document 2, a temperature fuse and a thermostat are connected in series to a heater circuit. When the toilet seat reaches an abnormally high temperature, the temperature fuse and the thermostat are cut off, and the power supply to the heater is cut off.

  However, in the heating toilet seat device described in Patent Document 2, if a temperature fuse or a thermostat fails, or if a control unit for controlling the temperature of a heater or the like fails, the energization is performed even if the toilet seat reaches an abnormally high temperature. There is a risk that it cannot be blocked.

JP 2008-018114 A JP 2008-110089 A

  The present invention has been made on the basis of recognition of such a problem, and is a heating toilet seat device that uses the principle of induction heating, and is capable of forcibly turning off energization when an abnormal temperature of the toilet seat is detected. The purpose is to provide.

According to a first aspect of the present invention, there is provided an induction heating coil, a conductor that is induction-heated by a magnetic field generated by the induction heating coil, a toilet seat provided with the conductor and a heater, and an abnormal temperature of the toilet seat. A first temperature detection unit and a second temperature detection unit, a first energization control unit capable of interrupting energization to the induction heating coil, an induction heating control unit for controlling an energization amount to the induction heating coil, A control unit that controls the first energization control unit, and the induction heating control unit outputs from the first temperature detection unit when the abnormal temperature is detected by the first temperature detection unit. The control unit performs control to stop energization of the induction heating coil according to the generated signal, and the control unit outputs from the second temperature detection unit when the abnormal temperature is detected by the second temperature detection unit. The first energization control unit according to the signal Forcibly controlled to cut off the higher current supply to the induction heating coil, and a heating toilet seat apparatus characterized by controlling the power supply amount to the heater.

According to this heating toilet seat device, even if the induction heating control unit fails, the second temperature detection unit can detect the abnormal temperature of the toilet seat and the control unit can cut off the energization to the induction heating coil. .
Also, even if one of the first and second temperature detection units that monitor the temperature of the toilet seat fails, the other temperature detection unit continues monitoring, and when the toilet seat reaches an abnormal temperature, the induction heating coil is energized. Cut off.
Therefore, it is possible to provide an induction heating type heating toilet seat device with high safety.
Furthermore, since the toilet seat is provided with the heating heater, the toilet seat heated to a predetermined temperature by induction heating can be kept warm by the heating heater. In addition, since a control unit that controls the heating heater is used, it is not necessary to provide a new control unit for controlling energization when the induction heating control unit fails. Thereby, the cost increase of a heating toilet seat apparatus can be suppressed.

Further, the second invention further includes a second energization control unit capable of interrupting energization to the heater in the first invention, wherein the induction heating control unit is the first temperature detection unit. When the abnormal temperature is detected, control is performed to forcibly cut off the energization of the heater by the second energization control unit according to a signal output from the first temperature detection unit. It is a heating toilet seat device.

According to this heating toilet seat device, even if the control unit should malfunction, the first temperature detection unit can detect the abnormal temperature of the toilet seat, and the induction heating control unit can cut off the energization to the heater.
In addition, even if one of the first and second temperature detection units that monitor the temperature of the toilet seat fails, the other temperature detection unit continues monitoring, and when the toilet seat reaches an abnormal temperature, the power supply to the heater is cut off. To do.
Thereby, even if the control system of the heat generating heater breaks down, it is possible to execute a response in the case of abnormality in the induction heating control system.

In addition, according to a third aspect , in the first or second aspect , when the control unit detects an abnormality in the induction heating control unit, the first energization control unit forcibly energizes the induction heating coil. It is the heating toilet seat apparatus characterized by performing control which interrupts | blocks automatically.

According to this heating toilet seat device, when an abnormality occurs in the induction heating control unit, the control unit operates the first energization control unit to cut off the energization to the induction heating coil.
Thereby, a toilet seat does not heat up more than appropriate temperature, and a highly safe heating toilet seat apparatus can be provided.

In a fourth aspect based on the third aspect , when the induction heating control unit detects an abnormality in the control unit, the second energization control unit forcibly cuts off the power supply to the heat generating heater. It is a heating toilet seat device characterized by performing control.

According to this heating toilet seat device, when an abnormality occurs in the control unit, the induction heating control unit operates the second energization control unit to cut off the energization to the heater.
On the other hand, when an abnormality occurs in the induction heating control unit, the control unit operates the first energization control unit to cut off the energization to the induction heating coil.
That is, the induction heating control unit and the control unit are in a state of monitoring each other, and when one of the control units becomes abnormal, the energization control unit is operated to cut off the energization to the induction heating coil and the heating heater. .
Thereby, a toilet seat does not heat up more than appropriate temperature, and a highly safe heating toilet seat apparatus can be provided.

Moreover, 5th invention is further equipped with the heat exchanger which heats the wash water which performs local cleaning in any one invention of 1st- 4th , The said control part is the energization amount to the said heat exchanger It is a heating toilet seat apparatus characterized by controlling.

  According to this heating toilet seat device, since the control unit that controls the sanitary washing device is used, it is not necessary to provide a new control unit for controlling energization when the induction heating control unit fails. Thereby, the cost increase of a heating toilet seat apparatus can be suppressed.

  According to the aspect of the present invention, there is provided a heating toilet seat device that uses the principle of induction heating, and that can forcibly cut off energization when an abnormal temperature of the toilet seat is detected.

It is a perspective schematic diagram which illustrates the toilet apparatus provided with the heating toilet seat apparatus which concerns on 1st Embodiment. It is a schematic diagram which illustrates the heating toilet seat apparatus concerning 1st Embodiment. It is a circuit diagram of the heating toilet seat device concerning a 1st embodiment. It is a control block diagram of toilet seat heating of the heating toilet seat device concerning a 1st embodiment. It is a schematic diagram which illustrates the heating toilet seat apparatus which concerns on 2nd Embodiment. It is a circuit diagram of the heating toilet seat apparatus which concerns on 2nd Embodiment. It is a control block diagram of toilet seat heating of the heating toilet seat device concerning a 2nd embodiment. It is a circuit diagram of the heating toilet seat apparatus which concerns on the other example of 2nd Embodiment. It is a control block diagram of the toilet seat heating of the heating toilet seat apparatus which concerns on the other example of 2nd Embodiment. It is a perspective schematic diagram which illustrates the toilet apparatus provided with the heating toilet seat apparatus which concerns on 3rd Embodiment. It is a circuit diagram of the heating toilet seat apparatus which concerns on 3rd Embodiment. It is a circuit diagram of the heating toilet seat apparatus which concerns on the other example of 3rd Embodiment.

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

(First embodiment)
First, an example of the heating toilet seat device according to the first embodiment will be described.
FIG. 1 is a schematic perspective view illustrating a toilet apparatus provided with the heating toilet seat apparatus according to the first embodiment.
The toilet apparatus shown in FIG. 1 includes a Western-style seat toilet 800 and a heated toilet seat apparatus 110 provided thereon. The heating toilet seat device 110 includes a casing 400, a toilet seat 200, and a toilet lid 300. The toilet seat 200 and the toilet lid 300 are pivotally supported with respect to the casing 400 so as to be freely opened and closed. The toilet lid 300 can cover the toilet seat 200 in the closed state.

  Inside the toilet seat 200, as will be described in detail later, an induction heating coil that generates a magnetic field when a high-frequency current is applied is provided. In addition, the toilet seat 200 is provided with a conductor that is induction-heated by a magnetic field generated from the induction heating coil, as will be described in detail later. More specifically, the conductor generates heat due to an eddy current induced by a magnetic field generated from the induction heating coil.

  Thereby, the heating toilet seat apparatus 110 concerning this embodiment can heat the toilet seat 200 rapidly using the principle of induction heating. Therefore, when the user is not using the toilet seat 200, the heating toilet seat device 110 does not need to keep the toilet seat 200 warm. Therefore, for example, energy saving can be achieved as compared with the case where the seating surface of the toilet seat 200 is heated by a resistance heating unit such as “seeds heater”, “halogen heater”, or “carbon heater”.

  A functional unit as a sanitary washing device may be provided inside the casing 400. That is, the casing 400 may incorporate a sanitary washing function unit having a water discharge nozzle (not shown) that ejects water toward the “butt” of the user sitting on the toilet seat 200. In the present specification, “water” includes not only cold water but also heated hot water.

  Further, inside the casing 400, a “warm air drying function”, a “deodorizing unit”, an “indoor heating unit”, etc. that blows warm air toward the “buttock” of the user sitting on the toilet seat 200 and the like are dried. Various mechanisms may be provided as appropriate. However, in the present invention, the sanitary washing function unit and other additional function units are not necessarily provided.

FIG. 2 is a schematic view illustrating the heating toilet seat device according to this embodiment.
Fig.2 (a) is a typical top view of the heating toilet seat apparatus which concerns on this embodiment, FIG.2 (b) is typical sectional drawing of the AA arrow line of Fig.2 (a).

  As shown in FIG. 2A, the control unit 410 is provided inside the casing 400. Electric power supplied from a commercial power source (hereinafter referred to as “commercial power” for convenience of explanation) is input to a control unit 410 provided in the casing 400.

  As illustrated in FIG. 2B, the toilet seat 200 includes a housing 210 that forms the outer shape of the toilet seat 200. The casing 210 is formed of an insulating material such as resin. Note that the housing 210 may be formed of a plurality of members or a single member.

  Inside the casing 210 of the toilet seat 200, an induction heating control unit 420 that converts a current supplied from the control unit 410 into a high frequency current, an induction heating coil 222 that generates a magnetic field when the high frequency current is applied, A power supply line 221 connected to the induction heating control unit 420 and the induction heating coil 222 and a support 280 that supports the induction heating coil 222 are provided. The power supply line 221 guides the high frequency current supplied from the induction heating control unit 420 to the induction heating coil 222. The power supply line 221 is, for example, a litz wire having a structure in which a plurality of insulating element wires are twisted together.

  The induction heating coil 222 shown in FIG. 2B is supported by the support 280, but is not limited to this. The induction heating coil 222 may be attached to the upper surface (inner surface facing the seating surface) 210a of the toilet seat 200 without being supported by the support body 280, for example.

  The toilet seat 200 is provided with a conductor 231 that is induction-heated by a magnetic field generated from the induction heating coil 222. More specifically, the conductor 231 generates heat due to an eddy current induced by a magnetic field generated from the induction heating coil 222. The conductor 231 is attached to the upper surface (sitting surface) of the toilet seat 200.

  As the conductor 231, for example, a metal such as a ferromagnetic material such as iron or stainless steel or a paramagnetic material such as aluminum can be used. In order to make it difficult to emit a magnetic field to the outside of the toilet seat 200, it is more preferable to use a ferromagnetic material such as iron or stainless steel having a large electric resistance for the conductor 231. In the case where the conductor 231 is provided on the upper surface of the toilet seat 200, it is more preferable that the surface of the conductor 231 is coated or coated so that the human body and the conductor 231 are not in direct contact with each other. .

  Control unit 410 and induction heating control unit 420 are connected to each other by power supply line 415. The low-frequency current such as commercial power and the control signal supplied from the control unit 410 are supplied to the induction heating control unit 420 through the feeder line 415. The power supply line 415 supplies the induction heating control unit 420 with a low frequency current having a relatively lower frequency than the high frequency current output from the induction heating control unit 420. The low frequency current is, for example, a low frequency current supplied from a commercial power source. The induction heating control unit 420 converts the low frequency current supplied through the power supply line 415 into a current having a frequency higher than that frequency (hereinafter, referred to as “high frequency current” for convenience of explanation).

  The high-frequency current converted by the induction heating control unit 420 flows to the induction heating coil 222 through the power supply line 221. Then, the induction heating coil 222 generates a magnetic field. When the induction heating coil 222 generates a magnetic field, the conductor 231 generates heat due to an eddy current induced by the magnetic field. Therefore, the heating toilet seat device 110 according to the present embodiment can rapidly heat the seating surface of the toilet seat 200 by using the principle of induction heating, and can make the seating surface appropriate temperature earlier. Moreover, since the heating toilet seat device 110 according to the present embodiment can rapidly heat the seating surface of the toilet seat 200, it is not necessary to keep the toilet seat 200 warm when the user is not using the toilet seat 200. Therefore, energy saving can be achieved.

FIG. 3 is a circuit diagram of the heating toilet seat device according to the first embodiment.
For example, the casing 400 includes a control unit 410, an induction heating coil energization switch SW1 that is a first energization control unit, and a load 700. The load 700 is, for example, at least one of a hot water heater and a room heater. The hot water heater is included in a heat exchanger that heats cleaning water for performing local cleaning. The control unit 410 performs control such as energization of these loads 700.

  Control unit 410 sends control signal CT2 to induction heating coil energization switch SW1. In addition, the control unit 410 performs energization control for the load 700. The induction heating coil energization switch SW1 controls ON / OFF of energization to the induction heating coil 222 by a control signal CT2 sent from the control unit 410. A commercial power supply 10 is connected to the control unit 410, the induction heating coil energization switch SW1, and the load 700.

  In the toilet seat 200, an induction heating control unit 420, a high frequency power supply circuit 500, an induction heating coil 222, a first thermistor TH1 as a first temperature detection unit, and a second thermistor as a second temperature detection unit. TH2 is included.

  The high frequency power supply circuit 500 includes a rectifying unit 520, a smoothing unit 530, a resonance capacitor 541, and a control switch 551. The rectifying unit 520 rectifies the current supplied from the commercial power supply 10. The rectifying unit 520 rectifies the current or voltage of the commercial power supply 10 whose polarity is switched, for example, only to be positive, and makes it easy to resonate.

  The smoothing unit 530 smoothes the pulsating current included in the current rectified by the rectifying unit 520. The smoothing unit 530 includes a smoothing coil 531 and a smoothing capacitor 533, and can supply power when the induction heating coil 222 has insufficient power.

  The control switch 551 is a normally open type opening / closing switch, for example. For example, an insulated gate bipolar transistor (IGBT) is used as the control switch 551.

The induction heating control unit 420 sends a control signal CT1 to the control switch 551 to control ON / OFF of the control switch 551. The operation of the induction heating control unit 420 is as follows.
First, when the induction heating control unit 420 controls the control switch 551 to be in the ON state, the current supplied from the commercial power supply 10 is rectified by the rectifying unit 520, smoothed by the smoothing unit 530, and flows to the induction heating coil 222. Then, energy is accumulated in the induction heating coil 222. Subsequently, when the induction heating control unit 420 controls the control switch 551 to be in the OFF state, no current is supplied from the commercial power supply 10, while the energy stored in the induction heating coil 222 moves to the resonance capacitor 541 and resonates. .

  Subsequently, when the control switch 551 is again controlled to be in the ON state by the induction heating control unit 420, the energy transferred to the resonance capacitor 541 returns to the induction heating coil 222 and resonates.

  As described above, when the induction heating control unit 420 switches between the ON state and the OFF state of the control switch 551, resonance occurs in the induction heating coil 222 and the resonance capacitor 541, and a high-frequency current is generated. This high frequency current is supplied to the induction heating coil 222. The induction heating coil 222 generates a magnetic field by the supplied high frequency current. Due to this magnetic field, an eddy current is generated in the conductor 231 and the conductor 231 generates heat. Thereby, for example, when the user's entry is detected, the induction heating control unit 420 controls the energization to the induction heating coil 222 to immediately heat the toilet seat 200 and to cool when the user sits on the toilet seat 200. It is possible to make the temperature suitable so as not to feel it.

  When the toilet seat 200 reaches an appropriate temperature, or after the user is seated on the toilet seat 200, the control switch 551 is turned off by the induction heating control unit 420. Thereby, supply of the high frequency current to the induction heating coil 222 is stopped, and heating of the toilet seat 200 is stopped.

  The induction heating control unit 420 controls ON / OFF of the control switch 551 based on the temperature information of the toilet seat 200 detected by the first thermistor TH1. Thereby, the induction heating control unit 420 controls the heating time and heating characteristics of the toilet seat 200.

  The second thermistor TH2 detects the temperature of the toilet seat 200 in the same manner as the first thermistor TH1. Information on the temperature detected by the second thermistor TH2 is sent to the control unit 410 in the casing 400. The control unit 410 controls the induction heating coil energization switch SW1 based on the temperature information sent from the second thermistor TH2.

  Control unit 410 can also monitor the state of induction heating control unit 420. When an abnormality occurs in the state of induction heating control unit 420, control unit 410 controls induction heating coil energization switch SW1 to interrupt energization to high frequency power supply circuit 500.

  Here, temperature control of the toilet seat 200 and control when the temperature reaches an abnormal temperature will be described. In the present specification, the abnormal temperature is a temperature that is lower than a temperature that is felt hot when sitting on the toilet seat 200 and is set in advance in the control unit 410 and the induction heating control unit 420.

FIG. 4 is a control block diagram of toilet seat heating of the heating toilet seat device according to the first embodiment.
The induction heating control unit 420 obtains information on the temperature of the toilet seat 200 detected by the first thermistor TH1, sends a control signal CT1 to the control switch 551, and controls the control switch 551 to be turned ON / OFF. When the control switch 551 is controlled, energization to the high frequency power supply circuit 500 is controlled, and energization to the induction heating coil 222 is controlled.

  Here, when the abnormal temperature of the toilet seat 200 is detected by the first thermistor TH1, the induction heating control unit 420 controls the control switch 551 to be in the OFF state based on the information on the detection of the abnormal temperature by the first thermistor TH1. Thereby, the supply of the high frequency current to the induction heating coil 222 is stopped.

  On the other hand, the control unit 410 obtains information on the temperature of the toilet seat 200 detected by the second thermistor TH2. When the abnormal temperature of the toilet seat 200 is detected by the second thermistor TH2, the control unit 410 sends a control signal CT2 to the induction heating coil energization switch SW1, and controls the induction heating coil energization switch SW1 to be in an OFF state. Thereby, energization to the high frequency power supply circuit 500 is forcibly cut off, and the supply of the high frequency current to the induction heating coil 222 is stopped.

  Here, the control unit 410 obtains temperature detection information by the second thermistor TH2 independently of the induction heating control unit 420. Therefore, even if some abnormality occurs in the induction heating control unit 420 or the first thermistor TH1, the abnormal temperature of the toilet seat 200 is detected by the second thermistor TH2, and the induction heating coil energization switch is detected by the control unit 410. By controlling the SW1, the energization to the high frequency power supply circuit 500 can be forcibly cut off.

  Control unit 410 can also monitor the state of induction heating control unit 420. For example, the control unit 410 can monitor the state of the induction heating control unit 420 using a watch dog timer.

  In the watchdog timer, control unit 410 detects service pulse SP sent from induction heating control unit 420. When the control unit 410 detects that the service pulse SP is sent from the induction heating control unit 420 within a certain period, the control unit 410 determines that “no abnormality”.

  On the other hand, control unit 410 determines that “there is an abnormality” when service pulse SP is not sent from induction heating control unit 420 within a certain period of time. When it is determined that “there is abnormality”, control unit 410 controls induction heating coil energization switch SW1 to the OFF state. Thereby, energization to the high frequency power supply circuit 500 is forcibly cut off, and the supply of the high frequency current to the induction heating coil 222 is stopped.

  Therefore, when any abnormality occurs in the induction heating control unit 420, the control unit 410 controls the induction heating coil energization switch SW1, so that the toilet seat 200 does not rise to an appropriate temperature or more, and the toilet seat 200 has an abnormal temperature. The power supply to the high-frequency power supply circuit 500 can be forcibly cut off before reaching.

  As described above, according to the heating toilet seat device 110 according to the first embodiment, even if the induction heating control unit 420 or the first thermistor TH1 breaks down, the abnormal temperature of the toilet seat 200 is detected by the second thermistor TH2. The control unit 410 can forcibly cut off the energization of the high frequency power supply circuit 500. Therefore, it is possible to provide an induction heating type heating toilet seat device with higher safety. In addition, since it controls using the existing control part 410, it is not necessary to provide a separate control part for failure of the induction heating control part 420 grade | etc.,. For this reason, even if it is the heating toilet seat apparatus 110 provided with said function, the raise of production cost can be suppressed.

(Second Embodiment)
Next, an example of a heating toilet seat device according to the second embodiment will be described.
FIG. 5 is a schematic view illustrating a heated toilet seat device according to the second embodiment.
Fig.5 (a) is a typical top view of the heating toilet seat apparatus which concerns on this embodiment, FIG.5 (b) is typical sectional drawing of the BB line arrow of Fig.5 (a).

  As shown in FIGS. 5A and 5B, the heating toilet seat device 120 according to the present embodiment is provided with a heater 333 in the casing 210 of the toilet seat 200. As the heater 333, for example, a tubing heater, a sheathed heater, a halogen heater, or a carbon heater is used. In the present embodiment, an example in which a tubing heater is used as the heater 333 will be described.

  The heater 333 is attached to, for example, the upper surface (inner surface facing the seating surface) 210a of the toilet seat 200. The heater 333 is connected to the control unit 410, and ON / OFF control is performed by the control unit 410. The heater 333 is routed in the housing 210 of the toilet seat 200.

FIG. 6 is a circuit diagram of the heating toilet seat device according to the second embodiment.
For example, a heater control circuit 600 is provided in the casing 400. The heater control circuit 600 includes a heater control switch 601. A heater 333 is provided in the toilet seat 200. The second thermistor TH2 of the toilet seat 200 detects the temperature of the toilet seat 200 mainly heated by the heater 333. The second thermistor TH2 detects the temperature of the toilet seat 200 even during the period when the heater 333 is not operating.

  The control unit 410 sends a control signal CT3 to the heater control switch 601 to perform ON / OFF control of the heater control switch 601. The control unit 410 controls the load 700 as well as the heater control switch 601.

FIG. 7 is a control block diagram of toilet seat heating of the heating toilet seat device according to the second embodiment.
The induction heating control unit 420 obtains information on the temperature of the toilet seat 200 detected by the first thermistor TH1, sends a control signal CT1 to the control switch 551, and controls the control switch 551 to be turned ON / OFF. When the control switch 551 is controlled, energization to the high frequency power supply circuit 500 is controlled, and energization to the induction heating coil 222 is controlled.

  The control unit 410 obtains information on the temperature of the toilet seat 200 detected by the second thermistor TH2, sends a control signal CT3 to the heater control switch 601, and performs ON / OFF control of the heater control switch 441. When the heater control switch 441 is controlled, energization to the heater 333 is controlled.

In the heating toilet seat device 120 including the induction heating coil 222 and the heater 333, for example, when the user's entry is detected, the induction heating control unit 420 controls energization of the induction heating coil 222, and the toilet seat 200 is rapidly moved by induction heating. Heat.
Thereafter, immediately before the user sits on the toilet seat 200, the induction heating control unit 420 stops energization of the induction heating coil 222, for example. And it switches to control of the control part 410, energization is started to the heater 333, and the toilet seat 200 is kept warm.

  Here, when the abnormal temperature of the toilet seat 200 is detected by the first thermistor TH1, the induction heating control unit 420 sends a control signal CT1 to the control switch 551 based on the information of the abnormal temperature detection by the first thermistor TH1. As a result, the control switch 551 is turned off. Accordingly, the supply of high-frequency current to the induction heating coil 222 is stopped.

  On the other hand, the control unit 410 obtains information on the temperature of the toilet seat 200 detected by the second thermistor TH2. When the abnormal temperature of the toilet seat 200 is detected by the second thermistor TH2, the control unit 410 sends a control signal CT2 to the induction heating coil energization switch SW1, and controls the induction heating coil energization switch SW1 to be in an OFF state. Thereby, energization to the high frequency power supply circuit 500 is forcibly cut off, and the supply of the high frequency current to the induction heating coil 222 is stopped.

  Here, the control unit 410 acquires the temperature detection information by the second thermistor TH2 independently of the control by the induction heating control unit 420 and the presence / absence of energization of the heater 333. Therefore, even if some abnormality occurs in the induction heating control unit 420 or the first thermistor TH1, the abnormal temperature of the toilet seat 200 is detected by the second thermistor TH2, and the induction heating coil energization switch is detected by the control unit 410. By controlling the SW1, the energization to the high frequency power supply circuit 500 can be forcibly cut off.

  Control unit 410 can also monitor the state of induction heating control unit 420. For example, the control unit 410 can monitor the state of the induction heating control unit 420 using a watch dog timer. When the service pulse SP is not sent from the induction heating control unit 420 within a certain period, the induction heating control unit 420 determines that “there is an abnormality”. When it is determined that “there is abnormality”, control unit 410 controls induction heating coil energization switch SW1 to the OFF state. Thereby, energization to the high frequency power supply circuit 500 is forcibly cut off, and the supply of the high frequency current to the induction heating coil 222 is stopped.

  Therefore, when any abnormality occurs in the induction heating control unit 420, the control unit 410 controls the induction heating coil energization switch SW1, so that the toilet seat 200 does not rise to an appropriate temperature or more, and the toilet seat 200 has an abnormal temperature. The power supply to the high-frequency power supply circuit 500 can be forcibly cut off before reaching.

  As described above, according to the heating toilet seat device 120 according to the second embodiment, even if the induction heating control unit 420 or the first thermistor TH1 breaks down, the abnormal temperature of the toilet seat 200 is detected by the second thermistor TH2. The control unit 410 can forcibly cut off the energization of the high frequency power supply circuit 500. Therefore, it is possible to provide an induction heating type heating toilet seat device with higher safety. In addition, since it controls using the existing control part 410, it is not necessary to provide a separate control part for failure of the induction heating control part 420 grade | etc.,. For this reason, even if it is the heating toilet seat apparatus 120 provided with said function, the raise of production cost can be suppressed.

(Another example of the second embodiment)
Next, another example of the heating toilet seat device according to the second embodiment will be described.
FIG. 8 is a circuit diagram of a heating toilet seat device according to another example of the second embodiment.
As shown in FIG. 8, in the heating toilet seat device 121 according to another example of the second embodiment, for example, a heater energization switch SW <b> 2 that is a second energization control unit is included in the casing 400.

  The heater energization switch SW2 is provided between the commercial power supply 10 and the heater control switch 601. The heater energization switch SW2 is ON / OFF controlled by a control signal CT4 output from an induction heating control unit 420 provided in the toilet seat 200.

FIG. 9 is a control block diagram of toilet seat heating of a heating toilet seat device according to another example of the second embodiment.
The induction heating control unit 420 obtains information on the temperature of the toilet seat 200 detected by the first thermistor TH1, sends a control signal CT1 to the control switch 551, and controls the control switch 551 to be turned ON / OFF.
For example, when the user enters the room, the induction heating control unit 420 controls energization of the induction heating coil 222 to rapidly heat the toilet seat 200 by induction heating.

The control unit 410 obtains information on the temperature of the toilet seat 200 detected by the second thermistor TH2, sends a control signal CT3 to the heater control switch 601, and performs ON / OFF control of the heater control switch 441. When the heater control switch 441 is controlled, energization to the heater 333 is controlled.
For example, immediately before the user sits on the toilet seat 200, the induction heating control unit 420 stops energizing the induction heating coil 222. And it switches to control of the control part 410, energization is started to the heater 333, and the toilet seat 200 is kept warm.

In the heating toilet seat device 121 according to another example of the second embodiment, when the toilet seat 200 reaches an abnormal temperature, the control unit 410 and the induction heating control unit 420 perform control to interpolate each other.
That is, when the abnormal temperature of the toilet seat 200 is detected by the first thermistor TH1, the induction heating control unit 420 sends the control signal CT1 to the control switch 551 based on the information of the abnormal temperature detection by the first thermistor TH1, and the control switch 551 is controlled to be in an OFF state. Thereby, the supply of the high frequency current to the induction heating coil 222 is stopped.

  Further, the induction heating control unit 420 sends a control signal CT4 to the heater energization switch SW2 based on the information on the detection of the abnormal temperature by the first thermistor TH1, turns off the heater energization switch SW2, and energizes the heater 333. Control to forcibly shut off.

  On the other hand, when the abnormal temperature of the toilet seat 200 is detected by the second thermistor TH2, the control unit 410 sends a control signal CT3 to the heater control switch 601 based on the information on the detection of the abnormal temperature by the second thermistor TH2, and the heater control switch 601 is controlled to be in an OFF state. Thereby, the energization to the heater 333 is stopped.

  Furthermore, the control unit 410 sends a control signal CT2 to the induction heating coil energization switch SW1 based on information on detection of abnormal temperature by the second thermistor TH2, and controls the induction heating coil energization switch SW1 to be in an OFF state. Thereby, energization to the high frequency power supply circuit 500 is forcibly cut off, and the supply of the high frequency current to the induction heating coil 222 is stopped.

By such control, even if some abnormality occurs in the induction heating control unit 420 or the first thermistor TH1 and the control becomes impossible, the abnormal temperature of the toilet seat 200 is detected by the second thermistor TH2 and is guided by the control unit 410. By controlling the heating coil energization switch SW1, energization to the high frequency power supply circuit 500 can be forcibly cut off.
On the other hand, even if some abnormality occurs in the control unit 410 or the second thermistor TH2, the abnormal temperature of the toilet seat 200 is detected by the first thermistor TH1, and the heater heating switch SW2 is set by the induction heating control unit 420. By controlling, it becomes possible to forcibly cut off the power supply to the heater 333.

Control unit 410 can also monitor the state of induction heating control unit 420. For example, the control unit 410 can monitor the state of the induction heating control unit 420 using a watch dog timer.
On the other hand, the induction heating control unit 420 monitors the state of the control unit 410. The induction heating control unit 420 monitors the state of the control unit 410 using, for example, a watch dog timer.

  Thereby, when an abnormality occurs in one of the control unit 410 and the induction heating control unit 420, the control unit 410 or the induction heating control unit 420 that detects the other party's abnormality causes the toilet seat 200 to rise in temperature to an appropriate temperature or higher. Therefore, before the toilet seat 200 reaches the abnormal temperature, the energization of the induction heating coil 222 and the energization of the heater 333 can be forcibly stopped.

It should be noted that when the abnormal temperature of the toilet seat 200 is detected, or when the abnormality occurs in one of the control unit 410 and the induction heating control unit 420, at least energization to the induction heating coil 222 is forcibly stopped. Control is preferred.
That is, the heater 333 is usually connected with a temperature fuse or a thermostat. Therefore, there is a high possibility that the thermal fuse and the thermostat function before the abnormal temperature is reached, and the power supply to the heater 333 can be cut off.
On the other hand, in the induction heating by the induction heating coil 222, the temperature of the toilet seat 200 may exceed the abnormal temperature before the temperature fuse or the thermostat functions. Therefore, when an abnormal temperature is detected, it is desirable to immediately stop energization of the induction heating coil 222.

  As described above, according to the heating toilet seat device 121 according to another example of the second embodiment, even if the induction heating control unit 420, the first thermistor TH1, the control unit 410, and the second thermistor TH2 malfunction, The power supply to the power supply circuit 500 can be forcibly cut off. Therefore, it is possible to provide an induction heating type heating toilet seat device with higher safety. In addition, since the control part 410 and the induction heating control part 420 mutually perform the other party's interpolation, it is not necessary to provide a separate control part for a failure. For this reason, even if it is the heating toilet seat apparatus 121 provided with said function, the raise of production cost can be suppressed.

(Third embodiment)
Next, an example of a heating toilet seat device according to the third embodiment will be described.
FIG. 10 is a schematic perspective view illustrating a toilet device provided with the heating toilet seat device according to the third embodiment.
The toilet device shown in FIG. 10 includes a Western-style seat toilet 800 and a heated toilet seat device 130 provided thereon. The heating toilet seat device 130 includes a casing 400, a toilet seat 200, and a toilet lid 300.
In the heating toilet seat device 130 according to the present embodiment, a heater 333 is provided in the toilet seat 200.
The toilet lid 300 is provided with an induction heating coil 222. The conductor 231 that is induction-heated by the induction heating coil 222 is provided on the toilet seat 200.

  That is, in the heating toilet seat device 130, the induction heating coil 222 provided on the toilet lid 300 and the conductor 231 provided on the toilet seat 200 face each other by closing the toilet lid 300. Accordingly, when the induction heating coil 222 is energized with the toilet lid 300 closed, the conductor 231 is induction heated and the toilet seat 200 is rapidly heated.

  On the other hand, when the toilet lid 300 is opened, the space between the induction heating coil 222 of the toilet lid 300 and the conductor 231 of the toilet seat 200 is opened, and the induction heating of the conductor 231 by the induction heating coil 222 is not performed. When the toilet lid 300 is opened, it is desirable to stop energization of the induction heating coil 222.

FIG. 11 is a circuit diagram of the heating toilet seat device according to the third embodiment.
For example, in the casing 400, a control unit 410, an induction heating coil energization switch SW1, which is a first energization control unit, a heater control circuit 600, and a load 700 such as a hot water heater or a heater for room heating are provided. It has been. The heater control circuit 600 includes a heater control switch 601.

  In the toilet seat 200, a heater 333, a first thermistor TH1 that is a first temperature detection unit, and a second thermistor TH2 that is a second temperature detection unit are provided.

In the toilet lid 300, an induction heating control unit 420, a high frequency power supply circuit 500, and an induction heating coil 222 are provided. The high frequency power supply circuit 500 includes a rectifying unit 520, a smoothing unit 530, a resonance capacitor 541, and a control switch 551.
The output line of the first thermistor TH1 provided in the toilet seat 200 is routed to the induction heating control unit 420 provided in the toilet lid 300.

The control block diagram of the toilet seat heating of the heating toilet seat device 130 according to the third embodiment is the same as the control block diagram of the toilet seat heating of the heating toilet seat device 120 according to the second embodiment shown in FIG.
That is, the induction heating control unit 420 obtains information on the temperature of the toilet seat 200 detected by the first thermistor TH1, sends the control signal CT1 to the control switch 551, and controls the control switch 551 to be turned ON / OFF. When the control switch 551 is controlled, energization to the high frequency power supply circuit 500 is controlled, and energization to the induction heating coil 222 is controlled.

  The control unit 410 obtains information on the temperature of the toilet seat 200 detected by the second thermistor TH2, sends a control signal CT3 to the heater control switch 601, and performs ON / OFF control of the heater control switch 441. When the heater control switch 441 is controlled, energization to the heater 333 is controlled.

  When the abnormal temperature of the toilet seat 200 is detected by the first thermistor TH1, the induction heating control unit 420 sends a control signal CT1 to the control switch 551 and controls the control switch 551 to be in an OFF state. Thereby, the supply of the high frequency current to the induction heating coil 222 is stopped.

  On the other hand, when the abnormal temperature of the toilet seat 200 is detected by the second thermistor TH2, the control unit 410 sends a control signal CT2 to the induction heating coil energization switch SW1, and controls the induction heating coil energization switch SW1 to be in an OFF state. Thereby, energization to the high frequency power supply circuit 500 is forcibly cut off, and the supply of the high frequency current to the induction heating coil 222 is stopped.

  Control unit 410 can also monitor the state of induction heating control unit 420. For example, the control unit 410 can monitor the state of the induction heating control unit 420 using a watch dog timer. When determining that the state of the induction heating control unit 420 is “abnormal”, the control unit 410 controls the induction heating coil energization switch SW1 to be in an OFF state. As a result, the energization of the high frequency power supply circuit 500 is forcibly cut off, the toilet seat 200 does not rise above the appropriate temperature, and the high frequency current is supplied to the induction heating coil 222 before the toilet seat 200 reaches the abnormal temperature. Is stopped.

  Thus, according to the heating toilet seat device 130 according to the third embodiment, even if the induction heating control unit 420 or the first thermistor TH1 breaks down, the abnormal temperature of the toilet seat 200 is detected by the second thermistor TH2. The control unit 410 can forcibly cut off the energization of the high frequency power supply circuit 500. Therefore, it is possible to provide an induction heating type heating toilet seat device with higher safety. In addition, since it controls using the existing control part 410, it is not necessary to provide a separate control part for failure of the induction heating control part 420 grade | etc.,. For this reason, even if it is the heating toilet seat apparatus 130 provided with said function, the raise of production cost can be suppressed.

(Another example of the third embodiment)
Next, another example of the heating toilet seat device according to the third embodiment will be described.
FIG. 12 is a circuit diagram of a heating toilet seat device according to another example of the third embodiment.
As illustrated in FIG. 12, in the heating toilet seat device 131 according to another example of the third embodiment, for example, a heater energization switch SW <b> 2 that is a second energization control unit is included in the casing 400.

  The heater energization switch SW2 is provided between the commercial power supply 10 and the heater control switch 601. The heater energization switch SW2 is ON / OFF controlled by a control signal CT4 output from an induction heating control unit 420 provided in the toilet seat 200.

The control block diagram of the toilet seat heating of the heating toilet seat device 131 according to another example of the third embodiment is a control block of the toilet seat heating of the heating toilet seat device 121 according to another example of the second embodiment illustrated in FIG. It is the same as the figure.
That is, the induction heating control unit 420 obtains information on the temperature of the toilet seat 200 detected by the first thermistor TH1, sends the control signal CT1 to the control switch 551, and controls the control switch 551 to be turned ON / OFF.
For example, when the user enters the room, the induction heating control unit 420 controls energization of the induction heating coil 222 to rapidly heat the toilet seat 200 by induction heating.

The control unit 410 obtains information on the temperature of the toilet seat 200 detected by the second thermistor TH2, sends a control signal CT3 to the heater control switch 601, and performs ON / OFF control of the heater control switch 441. When the heater control switch 441 is controlled, energization to the heater 333 is controlled.
For example, immediately before the user sits on the toilet seat 200, the induction heating control unit 420 stops energizing the induction heating coil 222. And it switches to control of the control part 410, energization is started to the heater 333, and the toilet seat 200 is kept warm.

  In the heating toilet seat device 131, as in the heating toilet seat device 121, when the toilet seat 200 reaches an abnormal temperature, the control unit 410 and the induction heating control unit 420 perform control to interpolate each other.

As a result, even if some abnormality occurs in the induction heating control unit 420 or the first thermistor TH1, the abnormal temperature of the toilet seat 200 is detected by the second thermistor TH2, and the induction heating coil energization is performed by the control unit 410. By controlling the switch SW1, the energization to the high frequency power supply circuit 500 can be forcibly cut off.
On the other hand, even if some abnormality occurs in the control unit 410 or the second thermistor TH2, the abnormal temperature of the toilet seat 200 is detected by the first thermistor TH1, and the heater heating switch SW2 is set by the induction heating control unit 420. By controlling, it becomes possible to forcibly cut off the power supply to the heater 333.

  Moreover, in the heating toilet seat apparatus 131, similarly to the heating toilet seat apparatus 121, the control unit 410 and the induction heating control unit 420 can also monitor each other's state. As a result, when an abnormality occurs in one of the control unit 410 and the induction heating control unit 420, the control unit 410 or the induction heating control unit 420 that has detected the abnormality of the other party supplies power to the induction heating coil 222 and the heater 333. Among the energizations, the energization to at least the induction heating coil 222 can be forcibly stopped.

  Thus, according to the heating toilet seat device 131 according to another example of the third embodiment, even if the induction heating control unit 420, the first thermistor TH1, the control unit 410, and the second thermistor TH2 fail, The power supply to the power supply circuit 500 can be forcibly cut off. Therefore, it is possible to provide the induction heating type heating toilet seat device 131 with higher safety. In addition, since the control part 410 and the induction heating control part 420 mutually perform the other party's interpolation, it is not necessary to provide a separate control part for a failure. For this reason, even if it is the heating toilet seat apparatus 131 provided with said function, the raise of production cost can be suppressed.

  As described above, according to the present embodiment, the heating toilet seat devices 110, 120, 121, 130, and 131 using the principle of induction heating are forced to energize when an abnormal temperature of the toilet seat 200 is detected. Therefore, a safer heating toilet seat device 110, 120, 121, 130 and 131 can be provided. In addition, such an excellent function can be realized by the existing control unit 410, the induction heating control unit 420, and the like, and an increase in cost can be suppressed.

The embodiment of the present invention has been described above. However, the present invention is not limited to these descriptions. As long as the features of the present invention are provided, those skilled in the art appropriately modified the design of the above-described embodiments are also included in the scope of the present invention.
Moreover, each element with which each embodiment mentioned above is provided can be combined as long as technically possible, and the combination of these is also included in the scope of the present invention as long as it includes the features of the present invention.

  10 Commercial power supply, 110, 120, 121, 130, 131 Heating toilet seat device, 200 Toilet seat, 210 Case, 210a Top surface inside 222, Induction heating coil, 231 Conductor, 300 Toilet lid, 333 Heater, 400 Casing, 410 Control Part, 415 power supply line, 420 induction heating control part, 500 high frequency power supply circuit, 530 smoothing part, 531 smoothing coil, 533 smoothing capacitor, 541 resonance capacitor, 551 control switch, 600 heater control circuit, 601 heater control switch, 700 load , 800 Western-style sitting toilet, TH1 first thermistor, TH2 second thermistor, SW1 induction heating coil energization switch, SW2 heater energization switch

Claims (5)

An induction heating coil;
A conductor that is induction-heated by the magnetic field generated by the induction heating coil;
A toilet seat provided with the conductor and a heater ;
A first temperature detection unit and a second temperature detection unit for detecting an abnormal temperature of the toilet seat;
A first energization control unit capable of interrupting energization to the induction heating coil;
An induction heating control unit for controlling an energization amount to the induction heating coil;
A control unit for controlling the first energization control unit;
With
The induction heating control unit performs control to stop energization of the induction heating coil according to a signal output from the first temperature detection unit when the abnormal temperature is detected by the first temperature detection unit. Done
When the abnormal temperature is detected by the second temperature detection unit, the control unit outputs a signal to the induction heating coil by the first energization control unit according to a signal output from the second temperature detection unit. A heating toilet seat device that performs control to forcibly cut off energization and control of the energization amount to the heater . A second energization control unit capable of interrupting energization of the heater;
The induction heating control unit is supplied to the heating heater by the second energization control unit according to a signal output from the first temperature detection unit when the abnormal temperature is detected by the first temperature detection unit. Heating toilet seat apparatus according to claim 1, characterized in that the forced control to cut off the energization. The control unit, when detecting an abnormality of the induction heating control unit, the first power supply controller by claim 1 or 2, characterized in that the control for forcibly interrupting the power supply to the induction heating coil The heating toilet seat device according to 1. The induction heating control unit, when detecting an abnormality of the controller, heating according to claim 3, characterized in that the forced control to cut off the energization of the second said heater by energizing the control unit of the Toilet seat device. It further includes a heat exchanger that heats wash water for performing local cleaning,
The heating toilet seat device according to any one of claims 1 to 4 , wherein the control unit controls an energization amount to the heat exchanger.

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