KR101071197B1 - Heated Toilet Seat and Toilet Device Having the Same Mounted Thereon - Google Patents

Abstract

An object of the present invention is to reduce standby power during non-use for keeping the toilet seat warm, thereby providing extremely energy saving and safe toilet seat heating.

The toilet seat 22 having the seat part 24 and the cavity part 27 inside, the radiant heating element 29 provided in the said cavity part 27, and the seat part 24 of the toilet seat 22. The temperature detecting means 44 for detecting the temperature of the radiation source, the reflector 28 reflecting the radiation of the radiation type heating element 29, and the radiation type heating element 29 are connected in series. The toilet is provided with a thermostat 30 having a bimetal 51 for receiving the radiant light and a control unit 50 for controlling the energization of the radiant heating element 29 according to the signal of the temperature detecting means 44. By detecting an abnormal excess of the surface temperature of the sheet 22 and cutting off the circuit, the toilet seat heating can be performed in a short time, and a safe heating toilet seat can be obtained.

Description

Heated Toilet Seat and Toilet Device Having the Same Mounted Thereon}

The present invention relates to a toilet seat having a heating function.

In the conventional heating toilet seat of this kind, as shown in FIG. 9, the hollow part 1 is formed inside, and the seating part of the circular toilet seat 2 used on the toilet is used ( 3) is made of a transparent polypropylene resin, and radiant heat from the lamp heater 4 provided along the entire circle of the toilet seat 2 in the cavity 1 is quickly transferred to the seating part 3, The temperature of the toilet seat 2 was prevented from rising by the thermostat 5 connected in series with the lamp heater 4, while raising the temperature of the egg surface which is a user's seating surface quickly (Example For example, see Japanese Patent Laid-Open No. 2000-210230.

Some types of heating toilet seats include a planar heater embedded in the toilet seat or attached to the back of the toilet seat (see, for example, Japanese Utility Model Publication No. 59-194897).

Fig. 36 shows a conventional heating toilet seat described in Japanese Utility Model Laid-Open No. 59-194897. As shown in FIG. 36, the cross-sectional shape of the toilet seat main body 301 swells upwards, Furthermore, the upper surface becomes a shape inclined gently toward the inner periphery and the outer periphery, and the back surface is a synthetic resin Or rubber piece 302 was provided with the clearance gap required.

In addition, on the upper surface of the toilet seat main body 301, the flexible sheet heating element 303 which has covered the conductive material with an insulating sheet from both sides is attached to the toilet seat main body 301 in a state exposed to the surface of the toilet seat main body 301. It was installed by embedding. This surface heating element 303 was comprised by forming printed wiring in a predetermined pattern, and attaching a synthetic resin sheet to the surface.

Reference numeral 304 is an insulating resin layer made of a synthetic resin such as polyamide or polyester deposited on the toilet seat main body 301 to cover the surface heating element 303 provided on the toilet seat main body 301. .

Since the insulated resin layer 304 is comprised in thin film form, the electricity is supplied to the surface heating body 303 provided in the upper surface of the toilet seat main body 301, and the main part of a human body is immediately heated without heating the toilet seat main body 301. Can be warmed at an appropriate temperature, and the heater is always energized and there is no need to warm the toilet, which is very energy saving.

However, as shown in FIG. 9, in the structure of the heating toilet seat of Unexamined-Japanese-Patent No. 2000-210230, although the thermostat 5 is installed and safety against temperature rise is aimed at, this thermostat 4 In the case of using a bimetal type thermostat that is not used in detail and is generally used, as illustrated in FIG. 10, a heat-sensitive surface that is a metal cap that receives radiant heat from the lamp heater 4 ( Since a small gap d is formed between 6) and the bimetal 7, heat transfer from the thermal surface 6 to the bimetal 7 is achieved by radiation from the thermal surface 6 and heat transfer through the air. As a result, it is considered that the temperature rise of the bimetal 7 takes time, and from this response delay, the safety surface is in jeopardy due to the delay in detecting the temperature rise.

That is, in this type of heating toilet seat, the lamp heater 4 must immediately heat the toilet seat in a short time until the user energizes immediately before sitting on the toilet seat and sits in order to save power. Rising type lamp heaters must be used. Therefore, when the thermostat of the above-described form is connected to such an electric heater circuit of the lamp heater and used as a means for preventing temperature overheating, even if the reaction delay of the thermostat is hardly a problem in the electric heater used in a normal heating mechanism, In the heating toilet seat using a lamp heater that is placed directly and the temperature rises instantaneously, it becomes hotter than the immediate temperature and gives the user an unpleasant feeling, and the situation that the user has to rise from the toilet seat when it becomes hot beyond the discomfort. I can think of it.

In addition, as is well known, the toilet seat of the past has used a low output of about 50 W as a heating element, and always keeps the desired heating temperature by energizing it, so that safety measures should be targeted at a low output heating element. In the instantaneous heating type toilet seat, the output of the radiant heating element is 1KW or more, which is much higher than that of the conventional one. Therefore, safety measures cannot be used as a conventional measure, and new safety measures are required.

Moreover, in the heating toilet seat of Unexamined-Japanese-Patent No. 59-194897, since heat transfer to the inside of an insulated resin layer, there existed a problem that it took quite a long time until the surface of a seat part became a temperature.

In addition, in the heating toilet seat of Japanese Utility Model Publication No. 59-194897, since heat is transferred to the inside of the insulating resin layer, it takes quite a long time until the surface of the seating portion becomes a temperature, and the toilet bowl is as short as possible. In order to raise the temperature of the seat surface, it is necessary to increase the capacity of the heater, and in case of failing the safety device, the user has a problem of being easily burned due to the configuration of the product that it is difficult for the user to check the surface temperature of the toilet seat. there was.

The problem to be solved by the present invention in view of the problems of the prior art is to provide a heating toilet seat that can detect the temperature change of the radiant heating element quickly and can be used safely and comfortably.

Moreover, an object of this invention is to provide the heating toilet seat which can be relieved while making the surface of a seat part cool in an extremely quick time, and a user can sit and recognize that the temperature of a toilet seat is cold.

In addition, the present invention provides a reliable heating toilet seat that allows the user to recognize the temperature of the toilet seat surface even when the safety device breaks down, while keeping the surface of the seating portion at a very fast temperature. It aims to provide.

MEANS TO SOLVE THE PROBLEM In order to solve the said subject, this invention is a toilet seat which has a seat part and a cavity part inside, the radiant heating element provided in the said cavity part, temperature detection means which detects the temperature of the seat part of the said toilet seat, and said radiation A thermostat having a reflector for reflecting the radiation of the type heating element, a bimetal connected in series with the radiation type heating element, and receiving the radiation of the radiation type heating element, and the radiation type by the signal of the temperature detecting means. It is a heating toilet seat provided with the control part which controls the electricity supply of a heat generating body.

By this configuration, the heating toilet seat receives the radiant light of the radiant heating element directly by the bimetal of the thermostat and heats it, so that the temperature change can be detected quickly, and the heating is safe and comfortable by the temperature control without response delay. Toilet seats may be used.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a schematic configuration diagram of a main section of a toilet seat of a heating toilet seat according to a first embodiment of the present invention.

Fig. 2 is a perspective view of a toilet seat in which a heating toilet seat is mounted on a toilet seat in the first embodiment.

3 is a plan view of the seating portion of the heating toilet seat in accordance with the first embodiment;

4 is an exploded perspective view of a main portion of the heating toilet seat in the first embodiment;

Fig. 5 is a seating section sectional view of the heating toilet seat in the first embodiment.

Fig. 6 is a sectional view of principal parts of the heating toilet seat in the second embodiment.

7 is a characteristic diagram of temperature control of a heating toilet seat in the first embodiment.

8 is a sectional view of principal parts of the heating toilet seat in the second embodiment;

9 is a cross-sectional view of the main portion of a conventional heating toilet seat.

10 is a cross-sectional view of a thermostat of a conventional heating toilet seat.

It is a schematic block diagram which cuts the toilet seat main part of the heating toilet seat in 3rd Example of this invention.

Fig. 12 is a perspective view of a toilet device in which a heating toilet seat is mounted on a toilet seat in the third embodiment.

The top view which removed the seating part of the heating toilet seat in the 3rd Example.

14 is an exploded perspective view of a main portion of the heating toilet seat in the third embodiment;

Fig. 15 is a seat cross-sectional view of the heating toilet seat in the third embodiment.

Fig. 16 is a sectional view of principal parts of the heating toilet seat in the third embodiment;

Fig. 17 is a sectional view of principal parts of the heating toilet seat in the third embodiment;

18 is a characteristic diagram of temperature control of a heating toilet seat in the third embodiment.

19 is a characteristic diagram of temperature control of a heating toilet seat in the third embodiment.

20 is a sectional view of principal parts of the heating toilet seat in the fourth embodiment;

Fig. 21 is a schematic sectional view of a toilet seat main section of a heating toilet seat according to a fifth embodiment of the present invention;

Fig. 22 is a perspective view of a toilet seat in which a heating toilet seat is mounted on a toilet seat in the fifth embodiment.

The top view which removed the seating part of the heating toilet seat in the 5th Example.

Fig. 24 is an exploded perspective view of a main portion of the heating toilet seat in the fifth embodiment.

Fig. 25 is a cut-away view of the radiant heating element mounting portion of the heating toilet seat in the fifth embodiment.

Fig. 26 is a seat cross-sectional view of the heating toilet seat in the fifth embodiment.

Fig. 27 is a sectional view of principal parts of the heating toilet seat in the fifth embodiment;

Fig. 27 is a sectional view of principal parts of the heating toilet seat in the fifth embodiment;

(A) is a front view of a spacer part, (b) is the same top view.

29 is a characteristic diagram of temperature control of a heating toilet seat in the fifth embodiment.

Fig. 30 is a sectional view of principal parts of the heating toilet seat in the sixth embodiment.

Fig. 31 is a perspective view of a heating toilet seat in the seventh embodiment of the present invention.

32 is a partial cutaway plan view of a heating toilet seat in a seventh embodiment of the present invention;

Fig. 33 is a sectional view of principal parts of the heating toilet seat in the seventh embodiment of the present invention;

Fig. 34 is a sectional view of principal parts of an upper body of a toilet seat in a seventh embodiment of the present invention.

Fig. 35 is a sectional view of principal parts of the upper frame of the toilet seat according to the eighth embodiment of the present invention;

36 is a sectional view of principal parts of a conventional toilet seat.

37 is a perspective view of a heating toilet seat in a ninth embodiment of the present invention;

38 is a partial cutaway plan view of a heating toilet seat in a ninth embodiment of the present invention;

Fig. 39 is a sectional view of principal parts of the heating toilet seat of the ninth embodiment of the present invention;

40 is a sectional view showing the main parts of an upper case of a heating toilet seat in a ninth embodiment of the present invention;

Fig. 41 is a perspective view of failure of the toilet seat in the heating in the ninth embodiment of the present invention.

Fig. 42 is a sectional view of principal parts of an upper case of a heating toilet seat in a tenth embodiment of the present invention.

(Explanation of drawing)

22 toilet seat

24 seats

27 joint

29 Lamp heater (radiation type heating element)

30 thermostat

41 anodized layer

42 radiation absorbing layer

43 Surface Deco Layer

44 Thermistor (temperature detection means)

48 room temperature thermistor (temperature detection means)

50 controls

51 bimetal

52 Radiant Heat Absorbers

a Distance between the radiant heating element and the toilet seat surface

b Distance between radiant heating element and thermostat

Maximum set temperature of T ₂ toilet seat

Safety limit temperature of T ₄ toilet seat

122 toilet seat

124 seats

127 joint

129 Lamp heater (radiation type heating element)

130 radiant response thermostat

131 Thermally Conductive Thermostat

141 Anodized Layer

142 Radiation Absorbing Layer

143 Surface Deco Layer

144 thermistor (temperature detection means)

148 Room temperature thermistor (temperature detection means)

150 controls

151 bimetal

152 Radiant Heat Absorbers

153 Clear Glass (Cap)

154 caps

155 Radiant Heat Absorbers

a Distance between the radiant heating element and the toilet seat surface

b Distance between radiant heating element and thermostat

Maximum set temperature of T ₂ toilet seat

Off operating temperature of T ₃ thermally conductive thermostat

Safety limit temperature of T ₄ toilet seat

201 toilet seat

203 toilet seat

207 Hartleche

208 joint

209 sitting department

210 radiant heating element

211 reflector

215 holder

215a, 215b Wedge

216 clips

217 radiation absorbing layer

218 anticorrosive layer

219 Surface Deco Layer

220 thermostat

221 temperature sensor

222 bimetal

226 spacer

232 indicator

233 radiant heat transmitting body

321 main body

322 toilet seat

325 Infrared sensor (human body detection means)

326, 342 frame

327 Hartleche

328 joint

329 radiation reflector

330 Lamp heater (radiation type heating element)

333 Thermistors (Temperature Detection Means)

334 quartz tube

336 gas

338 Radiant Heat Absorbing Layer

341 LED (Notification Means)

421 body

422 toilet seat

425 Infrared sensor (human body detection means)

426, 442 framework

427 Hartleche

428 Joint

429 copy reflector

430 Lamp Heater (Copy Heater)

438 radiation absorbing layer

441 Temperature Control Indicator

A first aspect of the invention provides a toilet seat having a seating portion and a cavity inside, a radiant heating element provided in the cavity portion, a temperature detecting means for detecting a temperature of the seating portion of the toilet seat, and a radiant light of the radiating heating element. And a thermostat having a reflector reflecting the light, a bimetal connected in series with the radiation heating element, and receiving a radiation of the radiation heating element, and controlling the energization of the radiation heating element in response to a signal from the temperature detecting means. It is a heating toilet seat provided with the control part.

A second aspect of the present invention provides a toilet seat including a seating portion provided with a radiation absorbing layer and a cavity inside, a radiant heating element provided in the cavity portion, temperature detecting means for detecting a temperature of the seating portion of the toilet seat, and the radiation. A thermostat having a reflector for reflecting the radiation of the type heating element, a bimetal connected in series with the radiation type heating element, and receiving the radiation of the radiation type heating element, and the radiation type by the signal of the temperature detecting means. It is a heating toilet seat provided with the control part which controls the electricity supply of a heat generating body.

According to the first or second aspect of the present invention, when the thermostat is heated by the radiant light from the radiant heating element, the bimetal is heated, the temperature change of the toilet seat is foreseen quickly, and an abnormality occurs in the energization circuit of the radiant heating element. For example, before the toilet seat temperature rises abnormally, the energizing circuit can be shut off. Therefore, the radiant heating element is always energized and there is no need to warm the toilet seat, and for example, the temperature of the toilet seat is raised at a high speed to a low temperature for a few seconds until the user enters the toilet and sits on the toilet seat. The use of the radiation type heating element which can be made is possible, and a very energy-saving heating toilet seat can be used safely.

In the first invention or the second invention, the seating portion is made of aluminum having a radiation absorption layer on the inner surface, and efficiently absorbs heat radiated from the radiation type heating element in the radiation absorption layer, and the thermal conductivity Since it is high aluminum, the cracking effect which makes temperature distribution faster and more uniform is obtained. In addition, aluminum has a specific gravity of about 1/3 of steel, so that the heat capacity can be reduced while the weight can be reduced. The seating part was 0.8-1.2 mm in thickness.

4th invention WHEREIN: In a 3rd invention, when a seating part set thickness to 0.8-1.2 mm, heat capacity can be made small while ensuring the intensity | strength required for a toilet seat, and both strength and a temperature increase rate can be satisfied.

5th invention is a 3rd invention WHEREIN: A seating part has an anodized layer at least and can exhibit the anticorrosive effect effective in a toilet space.

In the sixth invention, in the second or third invention, the radiation absorbing layer of the seating portion is black, and the radiation absorbing layer can efficiently absorb heat radiated from the radiation type heating element, thereby speeding up the heating rate of the seating portion. .

According to a seventh invention, in the first invention or the second invention, a radiation heat absorber is provided on a bimetal surface of a thermostat provided opposite to a radiation heat generator, and the heat radiated from the radiation heat generator to the bimetal in the radiation heat absorber is effective. Absorbs well, increases the temperature of the bimetal more quickly, and predicts the temperature change of the toilet seat quickly, so that when an abnormality occurs in the energizing circuit of the radiant heating element, the energizing circuit can be shut off before the toilet seat temperature abnormally rises. do.

In the eighth invention, in the seventh invention, the radiant heat absorbing material is a heat resistant black paint, and the black paint effectively absorbs heat from the radiant heating element and raises the temperature of the bimetal, thus prematurely overheating the toilet seat temperature. Can be detected.

In the ninth invention, the distance between the radiant heating element and the seating portion is larger than the distance between the radiant heating element and the thermostat according to any one of the first to eighth inventions, and the temperature rise of the thermostat is increased from the toilet seat surface. By speeding up, abnormal excess of the toilet seat surface temperature can be detected early.

10th invention WHEREIN: 1st-9th invention WHEREIN: The off operation temperature of a thermostat is set to more than the maximum set temperature of a toilet seat, and below the safety limit temperature of a toilet seat, and is a thermostat in a normal use state. Even when the stat does not operate and the toilet seat surface temperature is abnormally overheated, the energizing circuit of the radiant heating element can be reliably shut off at a temperature lower than the safety limit temperature at which there is a risk of burns.

The eleventh invention has a thermostat according to any one of the first to ten inventions, wherein a plurality of radiant heating elements are provided, provided to face each of the radiant heating elements, and electrically connected in series. By connecting the thermostats in series electrically, even if abnormal radiation occurs in any of the radiating heating elements, the energizing circuit of the radiating heating element can be reliably shut off by any of the thermostats.

12th invention is any one of the 1st-11th invention, Comprising: The thermostat is equipped with the cap which let light pass so that a bimetal may receive radiant light, Therefore, the reaction rate of a thermostat can be made very high speed. Therefore, the safety of high temperature blocking is improved.

According to a twelfth invention, in the twelfth invention, the cap of the thermostat is made of transparent glass, and the thermostat can be made to have a high-speed response, and a spinning or waterproof type.

14th invention is a toilet apparatus provided with the toilet seat provided with the heating toilet seat in any one of said 1st-13th invention, The toilet apparatus which can anticipate the effect of each said invention is obtained, and can be used comfortably. .

A fifteenth invention is a toilet seat having a seating portion and a cavity inside, a radiant heating element provided in the cavity portion, a temperature detecting means for detecting a temperature of the seating portion of the toilet seat, and a radiant heating element in series. A thermostat having a bimetal that is connected to and receives the radiant light of the radiant heating element, and is connected in series with the radiant heating element, and is disposed on the front surface of the bimetal so as not to receive the radiant light of the radiant heating element directly. A heating toilet seat having a heat conduction type thermostat having a cap, and a control unit for controlling the energization of the radiation type heating element by the signal of the temperature detecting means, the radiation response type thermostat, and the heat conduction type thermostat.

According to a sixteenth aspect of the present invention, there is provided a toilet seat including a seating portion provided with a radiation absorbing layer and a cavity inside, a radiant heating element provided in the cavity portion, temperature detecting means for detecting a temperature of the seating portion of the toilet seat, and the radiation. A bimetal connected to the heating element in series and further having a bimetal for receiving the radiation of the radiation heating element, and connected in series to the radiation heating element, and not directly receiving the radiation of the radiation heating element. It is provided with a heat conductive thermostat which has a cap in the front surface, Comprising: The control part which controls the electricity supply of the said radiation type heating element by the signal of the said temperature detection means, the said radiation response thermostat, and the said heat conductive thermostat. Heating toilet seat.

According to the 15th or 16th aspect of the present invention, the radiation-responsive thermostat heats the bimetal with radiation from the radiant heating element, rapidly predicts the temperature change of the toilet seat, and causes an abnormality in the energization circuit of the radiant heating element. When it does so, the electricity supply circuit can be interrupted before the toilet seat temperature abnormally rises. Moreover, when abnormality arises in the temperature control of a toilet seat, and a toilet seat temperature rises gradually, a heat conductive thermostat rises with a rise of a toilet seat temperature, and can interrupt an electricity supply circuit before reaching a safety limit temperature. Therefore, it is possible to use a radiant heating element that can raise the seat of the toilet seat quickly and quickly to the right temperature in a very short time, for example, until the user enters the toilet and sits on the toilet seat. Heating toilet seats can be used safely. In addition, the seat portion includes a radiation absorbing layer and absorbs radiant heat emitted by the radiation heating element, thereby efficiently warming the seat portion.

The seventeenth invention is the radiation-responsive thermostat according to any one of the fifteenth or sixteenth inventions such that the toilet seat surface temperature is turned off at or above the maximum set temperature of the toilet seat and below the safety limit temperature of the toilet seat. In this case, even when there is no malfunction in which the thermostat operates in a normal use state and the toilet seat surface temperature is abnormally overheated, the energizing circuit of the radiant heating element is reliably at a temperature lower than the safety limit temperature at which there is a risk of burns. Can be blocked.

The eighteenth invention is the radiation-responsive thermostat according to any one of the fifteenth to seventeenth inventions, wherein a plurality of radiant heating elements are provided, provided to face each of the radiant heating elements, and electrically connected in series. It is equipped with a thermally conductive thermostat, and as a result of electrically connecting different types of thermostats in series to each of the radiant heating elements, even if an abnormal overheating occurs in any radiant heating element, any one thermostat is used. It is possible to cut off the energization circuit of the radiant heating element.

19th invention is any one of 15th-18th invention, Comprising: The toilet seat | sheet of a toilet seat is formed by forming the cap of a thermally conductive thermostat by the metal which is excellent in thermal conductivity, and providing a radiation heat absorber on the surface which opposes a radiant heating element. Even when the temperature control abnormality occurs and the toilet seat temperature gradually rises, the thermal conductivity to the bimetal can be improved to follow the temperature of the bimetal to the toilet seat temperature, so that the radiation is reliably radiated at a temperature lower than the safety limit temperature. The energization circuit of the type heating element can be cut off.

According to the twentieth invention, in any one of the fifteenth to nineteenth inventions, the off operation of the thermally conductive thermostat is set to be performed at or above the maximum set temperature of the toilet seat and below the safety limit temperature of the toilet seat. Even if there is no malfunction in which the thermostat operates in use and the toilet seat surface temperature is abnormally overheated, the energizing circuit of the radiant heating element can be reliably shut off at a temperature lower than the safety limit temperature at which there is a risk of burns.

In the twenty-first aspect of the present invention, the thermally conductive thermostat is a return type and the radiation-responsive thermostat is a non-return type, for example, used in an abnormal environment so that the off operating temperature is relatively low. Even when the low thermal conductivity thermostat is operated, the thermal conductivity thermostat is returned and the toilet seat can be used again by returning to an environment below a certain temperature.

A twenty-second invention is a toilet device provided with a toilet seat comprising the heating toilet seat according to any one of the fifteenth to twenty-first inventions, and a toilet device which can expect the effect of each of the above-described inventions is obtained, and can be used comfortably. have.

A twenty-third aspect of the invention provides a toilet seat main body having a seating portion made of a positive heat conducting material having a small heat capacity, and having a cavity formed therein, and a radiant heating element provided in the cavity and heating the seating portion with radiant heat. And a temperature difference between a reflecting plate that reflects the radiant heat of the radiant heating element toward the seating portion, a temperature sensor that detects temperatures of a plurality of portions of the seating portion, and a plurality of portions of the seating portion detected by these temperature sensors have a predetermined deviation or more. It is provided with the control part which stops electricity supply to a radiation type heating element, and can provide the comfortable heating toilet seat | sheet without a temperature deviation.

A twenty-fourth invention is a toilet seat main body having a seating portion made of a positive heat conducting material having a small heat capacity, and having a cavity formed therein, a radiant heating element provided in the cavity portion, and radiant heat of the radiant heating element. And a thermostat having a reflector reflecting in the seating direction and a bimetal connected in series with the radiant heating element and directly receiving the radiant heat of the radiant heating element, and providing a distance between the radiant heating element and the seating portion. a, when the distance between the radiant heating element and the thermostat is b, it is set to b <a and the distance b is secured by spaced between the thermostat and the radiant heating element by a spacer, thereby providing a comfortable heating. At the same time, it is possible to reliably stop the energization at the time of abnormality, thereby improving safety.

In the twenty-fifth aspect of the twenty-third invention, in particular, in the thermostat of the twenty-third aspect of the invention, the radiant heating element side of the bimetal is partitioned with a heat-transmitting member to improve dust and water resistance.

A twenty-sixth aspect of the present invention provides a toilet seat main body having a seating portion made of a positive heat conducting material having a small heat capacity, and having a cavity formed therein, and a radiant heating element provided in the cavity and heating the seating portion with radiant heat. And a reflecting plate for reflecting the radiant heat of the radiant heating element in a seating direction, wherein the radiating heating element is held by a pair of clamping pieces of a holder made of a leaf spring attached to the reflecting plate, and the flow of these clamping pieces By detachably attaching the clip to the end, inadvertent detachment of the radiant heating element is reduced even when an impact or the like is applied.

In a twenty-seventh aspect of the present invention, the toilet seat main body is composed of a seat made of a synthetic resin undercarriage and a positive heat conducting material having a small heat capacity. To warm up.

28th invention is any one of said 23rd, 24th, 26th, and 27th invention WHEREIN: The electrically insulating radiant heat absorption layer is provided in the inner surface of the seat part corresponding to a radiation type | mold heating element, and the heating part of a seat part is efficient, and even a radiation type heating element is provided. Even if the heat source line falls down, safety is ensured.

In the twenty-ninth invention, in any one of the twenty-third, twenty-sixth, twenty-sixth, and twenty-seventh inventions, at least one of an anticorrosive layer or a surface deco layer is provided on the outer surface of the seating portion.

In the thirtieth invention, in any one of the twenty-third, twenty-six and twenty sixth inventions, a plurality of radiant heating elements are connected in series to facilitate assembly and handling of the radiant heating elements.

In the thirty-first aspect of the present invention, any one of the twenty-third, twenty-sixth and twenty-sixth inventions is configured to display a temperature change of the seating portion from the start of energization of the radiant heating element with an indicator.

In the thirty-second aspect of the present invention, the toilet seat according to any one of the twenty-third to thirty-first aspects is provided with a toilet seat.

According to a thirty-third aspect of the present invention, a toilet seat having a cavity formed therebetween by fitting a hartle body and a frame body provided with a radiation heat absorbing layer, a temperature detecting means for detecting an inner surface temperature of the bottle body, and radiation provided in the cavity part. A heating element, a notifying means, and a human body detecting means; the radiating heating element is urged in accordance with a signal from the human body detecting means, and the notification means when at least the temperature of the frame body reaches the temperature. By operating, the user can recognize the heated state of the toilet seat, such as reaching the temperature of the toilet seat in accordance with the operation of the notification means.

In the thirty-fourth aspect of the present invention, in particular, by forming the top frame of the thirty-third invention with a high thermal conductive material and providing a radiant heat absorbing layer on the inner surface of the top frame, a general metal material such as aluminum and magnesium is used as the material of the frame, and the radiant heat Since the radiant heat generated in the absorbent layer can be rapidly transmitted to the toilet seat surface, even if the user energizes the radiant heating element after entering the toilet, the seating portion of the toilet seat can be raised to an appropriate temperature for a few seconds until the toilet seat is seated.

In the thirty-fifth aspect of the present invention, in particular, the form of the thirty-third invention is formed of a material having radiant energy transmitted light, and a radiant heat absorbing layer is provided on the outer surface of the frame to form a complicated shape such as transparent polypropylene or polycarbonate. In addition to using an injection molding material which can be molded in a mold, the radiant heat absorbing layer can be generated in the radiant heat absorbing layer on the toilet seat surface. We can raise wealth to temperature.

According to the thirty sixth aspect of the present invention, the notification means of any one of the thirty-third to thirty-fifth inventions distinguishes and notifies the toilet seat until the temperature reaches the temperature and when the temperature reaches the temperature. It can be recognized by the user visually and hearingly.

A thirty-third aspect of the invention includes a toilet seat having a cavity formed therein by fitting a hartle body with a top frame body provided with a radiation heat absorbing layer, and a radiant heating element provided in the cavity, wherein the toilet seat is in contact with the human body when sitting. By installing a temperature-controlled temperature preserving material that discolors at a temperature higher than a predetermined temperature on the outer surface of the frame, a predetermined temperature is generated when the toilet seat becomes hot enough to cause burns. As the temperature-controlled Zion material discolors above the temperature, the user can recognize the temperature state of the toilet bowl before sitting so that the image can be prevented in advance.

In particular, the thirty-eighth aspect of the present invention provides the radiant heat absorbing layer of the thirty-seventh invention on the inner surface of the frame body made of a high thermally conductive material, thereby using a general metal material such as aluminum and magnesium as the material of the frame body, and radiant heat generated in the radiant heat absorbing layer. Since it can be rapidly delivered to the toilet seat surface, even if the user enters the toilet and energizes the radiant heating element, the seating portion of the toilet seat can be raised to an appropriate temperature for a few seconds until the toilet seat is seated.

In the thirty-ninth aspect of the invention, in particular, the radiation heat absorbing layer of the thirty-seventh invention is formed on an outer surface of a frame body made of a material having radiant energy permeability, thereby enabling injection molding into a complex shape such as transparent polypropylene or polycarbonate in the material of the frame body. In addition to using a molding material, radiant heat can be generated in the radiant heat absorbing layer on the toilet seat surface, so that even if the user energizes the radiant heating element after entering the toilet, the seating portion of the toilet seat is heated in a few seconds until the toilet seat is seated. You can.

40th invention makes copying by making into the letter and the form which can visually recognize that the toilet seat sheet is high temperature especially when the temperature control Zion material of any one of 37-39 invention discolors more than predetermined temperature, Even when the heater and the safety device fail and the toilet seat becomes hot enough to cause burns, the user can visually recognize the heating state of the toilet seat before sitting on the toilet seat. In the case of a form, even a child or a foreigner who cannot read a letter can recognize the warming situation visually.

The object of the present invention can be achieved by making the first to forty-fifth inventions the main parts of the embodiments, and thus, the details of the embodiments corresponding to the claims will be described below with reference to the drawings, and the best mode for carrying out the invention. Let's explain. In addition, this invention is not limited by this Example. In addition, in description of a present Example, what has the same structure and an effect is attached | subjected with the same code | symbol, and overlapping description is not carried out.

(First embodiment)

1 is a schematic configuration diagram showing a main portion of a toilet seat of a heating toilet seat according to a first embodiment of the present invention, FIG. 2 is a perspective view of a toilet seat in which the heating toilet seat is mounted, and FIG. Fig. 4 is an exploded perspective view of the heating toilet seat, and Fig. 5 is a sectional view of the main parts of the seat of the toilet seat.

In FIGS. 1-5, the heating toilet seat with the hot water washing function which wash | cleans the anus and bidet after toilet is equipped with the main body 21 which transversely extended in the rear end of the toilet bowl 20 of a toilet bowl apparatus, A part of the warm water washing function is built in the main body 21, and a circular toilet seat 22 and a toilet lid 23 mounted on the toilet 20 are provided to be rotatable. In addition, the sleeve portion of the main body 21 has a human body detection sensor 25 for detecting the presence or absence of the human body of the toilet. As shown in Fig. 1, the toilet seat 22 is formed by fixing and seating an aluminum seating portion 24 made of aluminum on the upper portion of the synthetic resin body 26 through a sheet material. It has the structure which has the spin part sealed cavities 27 which can prevent the intrusion of water.

Inside the cavity 27, the reflecting plate 28 (reflector) which finished the aluminum plate to the mirror surface facing the seating part 24 of the toilet seat 22 which a user using a toilet seat sits. And two lamp heaters 29 that are a plurality of radiant heating elements on both sides of the seating portion 24. As shown in FIG. 1, the radiation reflecting plate 28 has a bent portion 28a upward on the periphery of the inner and outer ends thereof, and the bent portion 28a is provided from the lamp heater 29. Since the radiation is deflected, it acts to increase the radiation density of the outer circumference portion and the inner circumference portion of the seating portion 24 away from the lamp heater 29, and aims at equalizing the radiation heat distribution to the seating portion 24. The thermostat 30 electrically connected in series with the lamp heater 29 is provided in the vicinity of this lamp heater 29, and the temperature rise of the seating part 24 of the toilet seat 22 is prevented in case of an unsafe situation. Act to prevent. In addition, although the radiation reflecting plate 28 was made into an aluminum plate in order to make it lightweight, you may use a stainless steel plate, a plated steel plate, etc.

The lamp heater 29 is formed by enclosing a small amount of halogen in a filament 33 made of tungsten and an inert gas 34 such as argon, inside the glass tube 32, and halogenated according to the heat generated by the filament 33. By repeating the halogen cycle reaction to form tungsten, the filament 33 is prevented from being consumed. According to this action, the filament 33 having a very small heat capacity can be used as the heat source, and the steep rise in radiant energy can be made. That is, the lamp heater 29, for example, a few seconds until the user enters the toilet and lowers the clothes and waits for the hips to sit on the seat 24 of the toilet seat 22. It is a radiant heating element capable of raising the seating portion 24 at a high temperature to an appropriate temperature. In addition, the lamp heater 29 does not necessarily need to be a halogen lamp heater according to the grade of the characteristic requested | required.

The lamp heater 29 is fixed to the radiation reflecting plate 28 by a lamp heater fixture 36 formed of a leaf spring material, and the radiation reflecting plate 28 is a boss of the resin body 26 made of resin. screwed to the boss, 37).

In FIG. 5, a part of the seating part 24 made from aluminum which comprises the toilet seat 33 is shown by the expanded cross section. In Fig. 5, the cavity 27 of the toilet seat 22, i.e., the inner surface to which the radiation of the lamp heater 29 is irradiated, has a black painted radiation absorption layer 42 which is easy to absorb the radiation. On the outer side, that is, the sitting side, an anodized layer 41 having an anticorrosive effect and a surface deco layer 43 coated thereon for a desired appearance effect are formed thereon. In addition, the alumite layer 41 and the coated surface deco layer 43 do not necessarily need to be both, and only one of the alumite layer 41 and the coated surface deco layer 43 is equivalent. Anticorrosive effects, such as chemicals, and design, such as gloss and color, can be added. However, by having both the alumite layer 41 and the coated surface deco layer 43, the anticorrosive effect can be added by using a higher anticorrosive effect, for example, using a disinfectant-containing paint. In addition, as a result of confirming the color of the radiation absorbing layer 42 with respect to various colors, it was found that black had the most endothermic efficiency and the temperature increase rate of the seated portion 24 could be increased. In addition, if it is a viewpoint that it may be practical without dwelling at the maximum speed, even if it is gray, red, blue, etc., temperature rising is possible. Also about black, it does not necessarily need to be limited to coating, and surface treatment, such as dyeing, may be sufficient. In the case of aluminum, boehmite treatment is also practical. In addition, although the surface deco layer 43 coated on the outer surface of the seating part 24 of FIG. 5 can also be made into the dyeing process, when at least the surface of the seating part is coated, not only the anticorrosive effect but also a metal toilet such as aluminum Even the sheet can dispel the cold aesthetic feeling, and can produce a soft image or a luxurious image by, for example, pearl coating such as pearls.

By using a metal and aluminum pressed product for the seating portion 24 of the toilet seat 22, the thermal conductivity is about 200 W · mK, which is very high compared to about 0.1 to 1 W · mK of the resin. The radiation absorbing layer 42 is heated up in response to the radiation of the lamp heater 29, and at the same time, heat can be transferred to the outer surface of the seating portion 24, that is, the surface deco layer 43. Moreover, since it is aluminum with high thermal conductivity, the cracking effect which makes temperature distribution more uniform is obtained. In addition, the required strength can be secured even if the sheet thickness is reduced by the work hardening by aluminum pressing. For example, in the case of resin, the thickness of about 3 mm is required in terms of strength, and 1.5 mm or less, which is half, is sufficient for the gripped workpiece of the aluminum plate. The thinner it is, the smaller the heat capacity can be, so that the amount of heat and time required for temperature increase can be reduced. As a result of the experiment, it was concluded that 0.8 to 1.2 mm is preferable for the aluminum plate thickness in terms of strength and temperature increase time.

In addition, a radiating light reflecting plate 28 is provided on an inner surface of the harness body 26 constituting the toilet seat 22, and the radiating light reflecting plate 28 is in series with a lamp heater 29 and a lamp heater 29. The connected thermostat 30 is provided. In addition, an aluminum seating portion 24 is provided on the upper portion of the harness body 26, which is a toilet seat temperature detecting means on the inner surface of the seating portion 24 in order to detect the temperature of the aluminum seating portion 24. Thermistor 44 is provided. In addition, the toilet seat 22 has an electrode 46 formed on its rotational shaft 45, and constitutes a toilet seat position detecting means 47 together with a bearing portion (not shown) of the main body 21, thereby forming a toilet seat. It is to detect whether 22 is in an upright position or in a substantially horizontal position of use on the toilet 20, which can be used for sitting.

The main body 21 acquires the detection signal of the room temperature thermistor 48 as a room temperature detection means, performs temperature control of the lamp heater 29, and heats up as it energizes the lamp heater 29 of the toilet seat 22. The control part 50 mainly having a microcomputer which has the timer part 49 which counts the elapsed time from the time of starting is provided. And the control part 50 acquires the signal of the human body detection sensor 25, the seating detection means 38, and the toilet seat position detection means 47 which detect the entrance of a person, and starts the electricity supply to the lamp heater 29. And the control of the stop and the lamp heater 29 so as to acquire signals from the thermistor 44 and the room temperature thermistor 48, so that the temperature of the seated portion 24, which is the filling surface, becomes a predetermined temperature with a constant temperature. Temperature control can be performed.

In FIG. 6, the thermostat 30 is the structure which the bimetal 51 exposed in the cavity part 27 so that the radiation of the lamp heater 29 may be received. Moreover, the heat resistant black paint is apply | coated to the light receiving surface of the bimetal 51 as a radiant heat absorber 52. As shown in FIG. The thermostat 30 is configured to efficiently absorb heat radiated from the radiant heating element toward the bimetal 51 by the radiant heat absorber 52, and to increase the temperature of the bimetal more quickly. Moreover, the thermostat 30 is set so that the distance a between the lamp heater 29 and the seating part 24 of the toilet seat 22 may become larger than the distance b between the lamp heater 29 and the bimetal 51. This distance a shows the distance to the radiation absorption layer 42 which is a light receiving surface provided in the inner surface of the seating part 24 in this embodiment.

In the above embodiment, when the user enters the bathroom, the human body detection sensor 25 detects the entrance and the signal is sent to the controller 50. At this time, when it is confirmed by the signal of the toilet seat position detecting means 47 that the toilet seat 22 is in a substantially horizontal use position, the control unit 50 starts to energize the lamp heater 29. By this initial energization, the input energy is instantaneously converted into radiant energy and radiated from the filament 33 to the seat 24 of the toilet seat 22 via the glass tube 32 and the radiation reflecting plate 28. . Moreover, the radiant energy of the lamp heater 29 heats up the radiation absorbing layer 42 and the seating part 24 which were provided in the inner surface of the seating part 24 of the toilet seat 22. As shown in FIG. As described above, in the present embodiment, when the user enters the bathroom, the lamp heater 29 is energized to warm the chaff surface of the seat 24 of the toilet seat 22 almost instantaneously, and the control unit 50 Even in case of an unstable situation due to a malfunction of the lamp heater 29, the energization of the lamp heater 29 can be interrupted by the thermostat 30 of the high speed response in which the bimetal 51 receives the radiated light of the lamp heater 29. Unlike heating toilet seats, which are generally used, they are always kept energized and have a large heating loss. Thus, there is almost no heating loss, thereby realizing an extremely energy-saving and safe heating toilet seat. In addition, the part of the hinge cover 55 shown in FIG. 3 and FIG. 4 is integrally molded with the seating part 24 in the case of the heating toilet seat (not shown) of resin generally used conventionally. In the above embodiment, the seating portion 24 shown in Figs. 3 and 4 is made of metal (aluminum material), and the hinge cover 55 is formed of propylene resin. This is because by reducing the heat capacity to be heated by minimizing the place to be heated by the lamp heater 29, it is possible to raise the seat 24 instantaneously more quickly with less power, thereby saving more power. have. That is, the aluminum material of the seating portion 24 acts to make the thermal conductivity high and the thermal conduction temperature uniform. The hinge cover 55 is a resin, and the thermal conductivity is low, so that the heat of the seating portion 24 is connected to the hinge cover 55. Almost never taken away. Thus, by constructing the member on the upper side of the toilet seat 22 with a plurality of members having different thermal conductivity, it is possible to suppress the heat loss more than necessary to the part which does not need to be warmed, and the heat loss can be reduced. As mentioned above, the toilet seat 22 which consists of the seating part 24 which is an upper structural member of the toilet seat 22, the hinge cover 55, and the harness body 26, and has the cavity part 27 inside, And a radiant heating element 29 provided in the cavity 27 and a reflector 28 provided on the side of the body 26 opposite to the radiant heating element 29, and at least the seating portion of the upper frame body. 24 is made of a metal (aluminum material), and the radiation absorbing layer 42 is provided on the inner surface of the seating portion 24 of the frame body, so that the seating portion 24 can be heated up more quickly and instantaneously with less power. Energy saving instantaneous heating toilet seat can be realized.

Moreover, the control part 50 performs calculation from the temperature difference of each temperature and each temperature based on the signal of the thermistor 44 and the room temperature thermistor 48 at the start of energization, and restricts the energization of the initial electricity supply preset and memorize | stored. When the optimum value of the time is selected and the elapsed time counted by the timer unit 49 reaches the energization limit time, the energization amount is reduced or zero, and then the toilet seat 22 is based on the signal of the thermistor 44. The amount of energization is controlled so that the seating portion 24 is in the temperature range.

As a result, the thermistor 44 actually detects the temperature in the vicinity of the seating portion 24 in contact with the user, and the control unit 50 raises and maintains the temperature precisely to an appropriate temperature, so that the use of the toilet seat 22 is comfortable. Since the input amount of the radiant energy is controlled in accordance with the load based on the signals of the thermistor 44 and the room temperature thermistor 48, it is possible to heat the temperature more precisely and safely.

In addition, since the initial energization time control is first performed, the energization amount is reduced and the temperature increase rate is reduced after the energization limit time, so that the toilet seat can be safely warmed even if the response speed of the toilet seat temperature detection means is slow. Sheet temperature detection means can also be used. Usually, in a general heater, the temperature is controlled by reducing the applied voltage, but the lamp heater 29 repeats the halogen cycle reaction of forming tungsten halide in accordance with the heat generation of the filament 33, thereby Since the consumption is prevented, the halogen cycle becomes uneven when the temperature of the glass tube is 200 ° C. or lower. Therefore, in order to keep the seating part 24 at a temperature with the lamp heater 29, it performs by changing an energization cycle in the output range in which a halogen cycle is effective.

On the other hand, when the toilet seat 22 is in a standing state or when the male user stands up in the toilet seat 22 for urine after entering the toilet, the control unit (based on the signal of the toilet seat position detecting means 47) ( 50 stops energizing the lamp heater 29. As a result, heating of the toilet seat 22 can be reduced in vain, and energy saving can be further reduced, and gravity is applied in the energized state and in the longitudinal direction, which is the tension direction of the filament 33, to reach a disconnection. Therefore, the life can be prevented from being shortened.

In addition, even if the user opens and closes the toilet seat 22 in an upright position and in a substantially horizontal state in accordance with the purpose, the impact of the lamp heater fixture 36 of the leaf spring member which is an elastic material is alleviated, so that the glass tube or the filament Can be damaged.

Next, when the user sits for defecation, the amount of current supplied to the lamp heater 29 is controlled by changing the current amount to zero or the point where the toilet seat temperature does not rise in accordance with the signal of the seat detecting means 38. Accordingly, the toilet seat temperature does not rise during use, and it is safe to use without fear of burns.

In particular, since the heating toilet seat sits in direct contact with the skin of the toilet seat incorporating a lamp heater, sufficient consideration is required for safety. In a normal use state, it can be used safely and comfortably as described above. If, for some reason, a problem occurs in the control unit 50 such as a microcomputer (not shown), the electricity to the lamp heater 29 is continuously performed. It is necessary to operate safely on the back.

In the thermostat, as shown in FIG. 10, a bimetal 7 is enclosed in a metal cap 6 to block light. In this configuration, the cap 6 is first heated, and the bimetal is heated. Is performed by radiation from the cap 6, so it takes time for the bimetal to reach a predetermined temperature, and therefore, when the temperature of the toilet seat 22 changes in a short time, a delay may occur in the interruption of the circuit. there was.

By the way, in this embodiment, in order to solve this, the thermostat 30 exposes the bimetal 51, and apply | coats the heat resistant black coating material as the radiant heat absorber 52 on the surface of the bimetal 51. As shown in FIG. Accordingly, since the bimetal 51 directly receives the radiation of the lamp heater 29, the bimetal 51 is directly heated by the radiation from the lamp heater 29, and in addition, the radiation heat absorbing material 52 is formed on the surface of the bimetal 51. Since a heat resistant black paint was applied, almost all of the radiant heat reaching the bimetal 51 from the lamp heater 29 is absorbed by the bimetal 51 to quickly follow a sudden change in the temperature of the toilet seat 22, Since the thermostat 30 is electrically connected in series with the lamp heater 29, the electricity supply of the lamp heater 29 can be interrupted at the time of overheating.

The thermostat 30 is set at a position where the distance a between the surface of the lamp heater 29 and the toilet seat 22 becomes larger than the distance b between the lamp heater 29 and the thermostat 30. As a result, the temperature of the bimetal 51 is increased faster than the temperature of the toilet seat 22 surface is increased. Therefore, when the toilet seat 22 surface temperature rises in an abnormal condition and becomes a dangerous state such as burns, The circuit can be cut off to make it safe.

In addition, in this embodiment, if the temperature of the bimetal 51 can be raised quickly, malfunction of the thermostat 30 can also be prevented. That is, if the temperature of the bimetal 51 can be raised quickly, the operating temperature of the thermostat 30 off (opening the energization circuit of the lamp heater 29) can be set higher than the normal use temperature of the toilet seat 22. Therefore, it is possible to avoid the risk that the thermostat 30 is operated in normal use to disable the heating function of the toilet seat.

That is, FIG. 7 shows the temperature near the bimetal 51 in the case where the lamp heater 29 is energized with the distance b = 7 mm and the distance a = 15 mm in the thermostat 30 having the configuration shown in FIG. 6. It is the result of having measured the surface temperature of the seating part 24. In Figure 7, curve (A) is capable of temperature rise of the surface temperature and in the seating unit 24, the temperature 5 ℃, at about 7.5 seconds (t ₁₎ to a normal toilet seat control temperature (T _1). On the other hand, the temperature of the bimetal 51, the thermostat 30 is raised to the curve as shown by (B), the seating portion 24 quickly t toilet seat temperature control in the _second time than (T _1). The temperature of the bimetal 51 when the seat portion 24 is the maximum set temperature (T ₂₎ over the toilet seat 22 has reached the off (open) operating temperature (T ₃₎ of the thermostat 29, the lamp The energization circuit of the heater 29 is cut off.

In addition, if a problem occurs in the thermostat 30 and the energization circuit of the lamp heater 29 cannot be shut off, the non-return thermostat 31 before reaching the safety limit temperature T ₄ . Or a thermal fuse) operates to cut off the energization circuit of the lamp heater 29. At this time, the toilet seat 22 surface temperature does not reach the safety limit temperature T ₄ .

In addition, by setting the operating temperature T ₃ of the thermostat 30 to be equal to or higher than the maximum set temperature T ₂ of the toilet seat 22 and the safety limit temperature T ₄ , the non-returnable thermostat 31 is easy. Or the thermal fuse may cause the interruption of the energization circuit of the lamp heater 29 so that the heating function of the toilet seat 22 cannot be used. That is, the first stage of the initial energization time is the temperature control by the timer 49 and thermistor 44 of the controller 50, and the second stage is the energization circuit of the lamp heater 29 by the thermostat 30 being turned off. Of the lamp heater 29 by the non-returning thermostat 31 or the thermal fuse (the circuit cannot be restored). And by setting the safety function of each step, it can use for a long time safely and comfortably.

In addition, in this embodiment, as shown in FIG. 3, the lamp heater 29 of the front side, and the lamp heater 29b of the back side are arrange | positioned before and behind the toilet seat 22, and are installed in multiple numbers, and each lamp heater 29 And 29b), thermostats 30 and 30b are provided, and each of the thermostats 30 and 30b is electrically connected in series. In addition, the return-type thermostat (30, 30b) is cut off at a somewhat lower temperature, the non-return type thermostat (31, 31b) is operated to cut off at a higher temperature than the return type thermostat (30, 30b) By setting it as temperature, higher multiple safety | security and long term, safety can also be used comfortably.

That is, by connecting the thermostats 30 and 30b to each lamp heater 29 and 29b in series, and connecting them in series to configure the energization circuit of the lamp heaters 29 and 29b, any one lamp heater ( When abnormality occurs in 29 and 29b, the energization circuits of the lamp heaters 29 and 29b are cut off by the thermostats 30 and 30b, so that power supply to both lamp heaters 29 and 29b is safely stopped. Since the thermostats 30 and 30b use different off operating temperatures, if a problem occurs in one of the thermostats 30, the energization circuit of the lamp heaters 29 and 29b cannot be cut off. In addition, since the energization circuit of the lamp heaters 29 and 29b is interrupted by another thermostat 30b, it is safe. In addition, since the lamp heaters 29 and 29b are divided into a plurality, in the conventional circular toilet seat 2 shown in Fig. 9, one circular lamp heater 4 is disposed in the cavity of the toilet seat 2. The problem that stress is directly applied to the lamp heater 4 due to the warpage of the toilet seat 2 and the installation error of the lamp heater 4 is eliminated by disposing it in approximately the entirety of (1). The risk of damage to the lamp heater 29 due to warpage or the like can be eliminated.

(2nd Example)

Fig. 8 is a sectional view of the main parts of the heating toilet seat in the second embodiment of the present invention, and particularly shows a partial sectional view of the thermostat. The present embodiment has the same basic configuration as the invention of the first embodiment, and the other is an improvement in the structure of the thermostat connected in series with the lamp heater, and therefore only the structure of the other thermostat will be described.

In FIG. 8, the thermostat 30c has a cap 53 made of transparent glass so that the bimetal 51 receives the radiation of the lamp heater 29. Moreover, by providing the cap 53 of the transparent glass, it can be set as the spinning or waterproofing type | mold which water droplets and dust do not invade inside the thermostat 30c, and even if the cavity part 27 is flooded in one bay, It is possible to prevent the immersion of the stat (30c) to the energized portion can maintain electrical insulation can prevent the electric shock. In addition, in the thermostat 30c, the heat resistant black paint is applied to the light-receiving surface of the bimetal 51 as the radiation heat absorber 52 as in FIG. The thermostat 30 is configured to efficiently absorb heat radiated from the radiant heating element toward the bimetal 51 by the radiant heat absorber 52 and to raise the temperature of the bimetal more quickly. In addition, the thermostat 30c is set so that the distance a between the surface of the lamp heater 29 and the toilet seat 22 may become larger than the distance b between the lamp heater 29 and the bimetal 51. Accordingly, since the bimetal 51 directly receives the radiation of the lamp heater 29, the bimetal 51 is directly heated by the radiation from the lamp heater 29, and in addition, the radiation heat absorbing material 52 is formed on the surface of the bimetal 51. Since the heat resistant black paint was applied, almost all of the radiant heat reaching the bimetal 51 from the lamp heater 29 was absorbed by the bimetal 51 and quickly followed the sudden fluctuation of the temperature of the toilet seat 22. Since the thermostat 30 is electrically connected in series with the lamp heater 29, it is possible to block the energization of the lamp heater 29 when the temperature rises.

In addition, the transparent glass of the cap 53 is excellent in the transmission characteristic of the radiant light of the lamp heater 29 by using quartz glass, and it can be made into a faster response, and can improve the interruption | blocking safety. Of course, it goes without saying that even the other glass becomes practical depending on the required degree. If the plate pressure of the transparent glass 53 is too thick, the permeation performance is lowered. Therefore, the plate thickness is preferably 1.5 mm or less, and preferably 1.2 mm or less. In addition, in each said embodiment, although the seating material was made into the press-formed product of an aluminum plate, the same effect can be acquired also by other processing methods, such as aluminum die-casting. The type of metal may be copper plate or steel sheet.

(Third Embodiment)

Fig. 11 is a schematic configuration diagram showing a main portion of a toilet seat of a heating toilet seat according to a third embodiment of the present invention, Fig. 12 is a perspective view of a toilet seat in which the toilet seat is mounted, and Fig. 13 is a toilet seat. Fig. 14 is an exploded perspective view of the heating toilet seat, and Fig. 15 is a sectional view of the main parts of the seat of the heating toilet seat.

In FIGS. 11-15, the toilet seat with the warm water washing function which wash | cleans the anus and bidet after a toilet is provided with the main body 121 extended horizontally in the rear end of the toilet bowl 120 of a toilet bowl apparatus, A part of the hot water cleaning function is built in the main body 121, and a circular toilet seat 122 and a toilet lid 123 mounted on the toilet 120 are rotatably installed. In addition, the sleeve of the main body 121 has a human body detection sensor 125 for detecting the presence of the human body of the toilet. As shown in FIG. 11, the toilet seat 122 is formed by fixedly coupling an aluminum seating portion 124 to the upper portion of the synthetic resin body 126 through a seal material, and penetrating water droplets therein. It is configured to have a spin-sealed cavity 127 that can prevent the.

Inside the cavity 127, a light reflecting plate 128 (reflector) in which an aluminum plate is mirror-finished is opposed to the seating portion 124 of the toilet seat 122 where a user using the toilet seat sits. And the front lamp heater 129 and the rear lamp heater 129b (shown as lamp heaters 129 when there is no need for distinguishing thereafter) are provided on both sides of the seating portion 124. As shown in FIG. 1, the radiation reflecting plate 128 has a bent portion 128a upward on the entire circumference of the inner and outer ends thereof, and from the lamp heater 129 by the bent portion 128a. Radiant light is deflected, so that the radiation density of the outer circumference and the inner circumference of the seating portion 124 away from the lamp heater 129 is increased, and the radiation heat distribution to the seating portion 124 is made uniform. . In the vicinity of the lamp heater 129, a radiation-responsive thermostat 130 electrically connected in series with the lamp heater 129 is provided, and the seating portion 124 of the toilet seat 122 is protected against an unsafe situation. It acts to prevent the temperature rise. In addition, although the radiation reflecting plate 128 was made into an aluminum plate in order to make it lightweight, you may use a stainless steel plate, a plated steel plate, etc.

The lamp heater 129 is formed by enclosing a small amount of halogen in a filament 133 made of tungsten and an inert gas 134 such as argon, inside the glass tube 132, and halogenating according to the heat generated by the filament 133. By repeating the halogen cycle reaction to form tungsten, the filament 133 is prevented from being consumed. According to this action, the filament 133 having a very small heat capacity can be used as a heat source, and the steepest increase in radiant energy can be performed. That is, the lamp heater 129 enters the toilet seat 122 in a very short time, for example, a few seconds until the user enters the toilet and lowers the clothes and waits for the hip to the seating portion 124 of the toilet seat 122. ) Is a radiant heating element capable of raising the seating portion 124 at a high temperature to a high temperature. In addition, the lamp heater 129 does not necessarily need to be a halogen lamp heater according to the grade of characteristic requested | required.

The lamp heater 129 is fixed to the radiation reflecting plate 128 by a lamp heater fixture 136 formed of a leaf spring member, and the radiation reflecting plate 128 is a boss of the resin body 126 made of resin. It is screwed to (137).

In FIG. 15, a part of the seating part 124 made of aluminum which comprises the toilet seat 122 was shown by the expanded cross section. In FIG. 15, the inner surface to which the cavity 127 of the toilet seat 122 is irradiated, that is, the inner surface to which the radiant light of the lamp heater 129 is irradiated, has a black-painted radiant absorbing layer 142 which is easy to absorb the radiant light. On the outer side, that is, the sitting side, an anodized layer 141 having an anticorrosive effect and a surface deco layer 143 coated thereon for a desired appearance effect are formed. In addition, the alumite layer 141 and the coated surface deco layer 143 do not necessarily need to be both, and only one of the alumite layer 141 or the coated surface deco layer 143 is equivalent. Anticorrosive effects, such as chemicals, and design, such as gloss and color, can be added. However, by having both the alumite layer 141 and the coated surface deco layer 143, the anticorrosive effect can be added by using a higher anticorrosive effect, for example, using a disinfectant-containing paint. In addition, as a result of confirming the color of the radiation absorbing layer 142 with respect to various colors, black has the most endothermic efficiency and results in that the temperature increase rate of the seating portion 124 can be increased. In addition, if it is a viewpoint that it may be practical without dwelling at the maximum speed, even if it is gray, red, blue, etc., temperature rising is possible. Also about black, it does not necessarily need to be limited to coating, and surface treatment, such as dyeing, may be sufficient. In the case of aluminum, boehmite treatment is also practical. In addition, although the surface deco layer 143 coated on the outer surface of the seating portion 124 of FIG. 15 may be dyed, at least when the coating is applied to the seating surface, not only the anticorrosive effect but also a metal toilet seat such as aluminum is cold. The beauty of the aesthetics can be eliminated, so a soft or luxurious image can be produced by, for example, pearl coating such as pearls.

By using a metal and aluminum pressed product for the seating portion 124 of the toilet seat 122, the thermal conductivity is about 200 W mK, which is very high compared to about 0.1 to 1 W mK of resin. The radiation absorbing layer 142 is heated up in response to the radiant light of the lamp heater 129, and at the same time, heat can be quickly transferred to the outer surface of the seating portion 124, that is, the surface deco layer 143. Moreover, since it is aluminum with high thermal conductivity, the cracking effect which makes temperature distribution more uniform is obtained. In addition, the required strength can be secured even if the sheet thickness is reduced by the work hardening by aluminum pressing. For example, in the case of resin, the thickness of about 3 mm is required in terms of strength, and 1.5 mm or less, which is half, is sufficient for the gripped workpiece of the aluminum plate. The thinner it is, the smaller the heat capacity can be, so that the amount of heat and time required for temperature increase can be reduced. As a result of the experiment, it was concluded that the thickness of the aluminum sheet is preferably 0.8 to 1.2 mm in terms of strength and temperature increase time.

In addition, a radiation light reflecting plate 128 is provided on an inner surface of the heart body 126 constituting the toilet seat 122, and the front lamp heater 129 and the rear lamp heater 129b are provided on the radiation reflecting plate 128. And a radiation responsive thermostat 130 and a heat conduction thermostat 131 connected in series with each other are provided. In addition, an aluminum seating portion 124 is provided on the upper portion of the hartle body 126, and a toilet seat temperature detecting means is provided on the inner surface of the seating portion 124 in order to detect the temperature of the aluminum seating portion 124. Thermistor 144 is provided. In the toilet seat 122, an electrode 146 is formed on the pivot shaft 145, and the toilet seat position detecting means 147 is formed together with a bearing portion (not shown) of the main body 121 to form a toilet seat. It is to detect whether the seat 122 is in an upright position or in a substantially horizontal position of use on the toilet 120, which can be used for sitting.

The main body 121 acquires the detection signal of the room temperature thermistor 148 as a room temperature detection means, performs temperature control of the lamp heater 129, and heats up as it energizes the lamp heater 129 of the toilet seat 122. The control part 150 mainly having a microcomputer which has the timer part 149 which counts the elapsed time from the time of starting is provided. Then, the controller 150 acquires signals from the human body detecting sensor 125, the seat detecting means 138, and the toilet seat position detecting means 147, which detects the entrance of a person, and starts the energization of the lamp heater 129. And the control of the stop and the lamp heater 129 to acquire signals from the thermistor 144 and the room temperature thermistor 148, so that the temperature of the seating portion 124, which is the filling surface, becomes a predetermined temperature with a constant temperature. Temperature control can be performed.

In FIG. 16, the radiation-responsive thermostat 130 is a configuration in which the bimetal 151 is exposed in the cavity 127 to receive the radiation of the lamp heater 129, and the bimetal 151 is exposed to the lamp heater 129. ) Installed facing each other. A heat resistant black paint is applied to the light receiving surface of the bimetal 151 as the radiant heat absorbing material 152. In addition, the radiation-responsive thermostat 130 efficiently absorbs the heat radiated from the radiant heating element to the bimetal 151 by the radiant heat absorber 152, and is configured to increase the temperature of the bimetal more quickly. In addition, the radiation-responsive thermostat 130 is set such that the distance a between the lamp heater 129 and the seating portion 124 of the toilet seat 122 is greater than the distance b between the lamp heater 129 and the bimetal 151. It is. This distance a shows the distance to the radiation absorption layer 142 which is a light receiving surface provided in the inner surface of the seating part 124 in this embodiment.

In FIG. 17, the thermally conductive thermostat 131 has a cap 154 on the front surface of the bimetal 151 so that the bimetal 151 does not directly receive the radiation of the lamp heater 129. It is set to face the heater 129. The cap 154 is formed of a metal having good thermal conductivity, here, an aluminum alloy, and a radiant heat absorber made of black paint is provided on the surface thereof.

The radiation-responsive thermostat 130 and the thermally conductive thermostat 131 are connected in series to two lamp heaters 129 and 129b.

In the above embodiment, when the user enters the bathroom, the human body detection sensor 125 detects the entrance of the room, and a signal is sent to the controller 150. At this time, when it is confirmed by the signal of the toilet seat position detection means 147 that the toilet seat 122 is in a substantially horizontal use position, the control part 150 starts electric power supply to the lamp heater 129. By this initial energization, the input energy is instantaneously converted into radiant energy and radiated from the filament 133 to the seat 124 of the toilet seat 122 via the glass tube 132 and the radiation reflecting plate 128. . In addition, the radiant energy of the lamp heater 129 heats up the radiation absorbing layer 142 and the seating portion 124 provided on the inner surface of the seating portion 124 of the toilet seat 122. As described above, in the present embodiment, when the user enters the bathroom, the lamp heater 129 is energized to warm the chaff surface of the seat 124 of the toilet seat 122 almost instantaneously, and the control unit 150 Even in case of an unstable situation due to a failure of), the energization of the lamp heater 129 is blocked by the high speed response radiation response thermostat 130 in which the bimetal 151 receives the radiation of the lamp heater 129. Therefore, unlike the heating toilet seat which is generally used in the past, it is always kept energized, and the heating loss is large, unlike the heating loss, which realizes an extremely energy-saving and safe heating toilet seat. In addition, the part of the hinge cover 156 shown in FIG. 13 and FIG. 14 is integrally molded with the seating part 124 in the case of the heating toilet seat (not shown) of resin generally used conventionally. In the above embodiment, the seating portion 124 shown in Figs. 13 and 14 is made of metal (aluminum material), and the hinge cover 156 is formed of propylene resin. This is because by reducing the heat capacity to be heated by minimizing the place to be heated by the lamp heater 129, it is possible to raise the seat 124 instantaneously and more quickly with less power, thereby saving more power. . That is, the aluminum material of the seating portion 124 has a high thermal conductivity and thermal conduction so that the temperature is uniform. Since the hinge cover 156 is made of resin and has a low thermal conductivity, the heat of the seating portion 124 is provided in the hinge cover 156. Almost never taken away. Thus, by constructing the member on the upper side of the toilet seat 122 with a plurality of members having different thermal conductivity, it is possible to suppress the loss of heat more than necessary to the part which does not need to be warmed, so that the loss of heat can be reduced. As described above, the toilet seat 122 having the seat 124, the hinge cover 156, and the bottle body 126, which is an upper constituent member of the toilet seat 122, and having a cavity 127 therein and And a radiant heating element 129 provided in the cavity portion 127 and a reflector 128 provided on the hearth body 126 side to face the radiant heating element 129. The portion 124 is made of a metal (aluminum material), and the radiation absorbing layer 142 is provided on the inner surface of the seating portion 124 of the frame, thereby enabling the seating portion 124 to be quickly and instantaneously with less power. Energy saving instantaneous heating toilet seat can be realized.

Moreover, the control part 150 performs calculation from both the temperature difference and each temperature based on the signal of the thermistor 144 and the room temperature thermistor 148 at the start of energization, and restricts the energization of the initial electricity supply which is preset and memorize | stored. When the optimum value of the time is selected and the elapsed time counted by the timer unit 149 reaches the energization limit time, the energization amount is reduced or zero, and then the toilet seat 122 is based on the signal of the thermistor 144. Controls the amount of energization so that the seating portion 124 of the temperature.

Accordingly, the thermistor 144 actually detects the temperature in the vicinity of the seating portion 124 that the user contacts, and the controller 150 raises and maintains the temperature precisely to an appropriate temperature, so that the use of the toilet seat 122 is comfortable. Since the input amount of the radiant energy is controlled in accordance with the load based on the signals of the thermistor 144 and the room temperature thermistor 148, it is possible to heat the temperature more precisely and safely.

In addition, since the initial energization time control is first performed, the energization amount is reduced and the temperature increase rate is reduced after the energization limit time, so that the toilet seat can be safely warmed even if the response speed of the toilet seat temperature detection means is slow. Sheet temperature detection means can also be used. In general, in the common heater, the temperature is controlled by reducing the applied voltage, but the lamp heater 129 repeats the halogen cycle reaction of forming tungsten halide according to the heat generated by the filament 133, thereby consuming the filament 133. Since the temperature of the glass tube is 200 ° C. or lower, the halogen cycle becomes uneven. Therefore, in order to make the seating part 124 warm with the lamp heater 129, it performs by changing an energization cycle in the output range in which a halogen cycle is effective.

On the other hand, when the toilet seat 122 is in a standing state or when the male user stands up in the toilet seat 122 for urine after entering the toilet, the control unit (based on the signal of the toilet seat position detecting means 147) ( 150 stops energizing the lamp heater 129. As a result, the heating of the toilet seat 122 can be reduced in vain, and energy saving can be further reduced. In addition, in the energized state, gravity is applied in the longitudinal direction, which is the tension direction of the filament 133, leading to disconnection. Therefore, the life can be prevented from being shortened.

In addition, even if the user opens and closes the toilet seat 122 in an upright state and in a substantially horizontal state in accordance with the purpose, the impact of the lamp heater fixture 136 of the leaf spring member which is an elastic material is alleviated, so that the glass tube or the filament Can be damaged.

Next, when the user sits down for defecation, the amount of energization to the lamp heater 129 is controlled by changing the amount of energization to zero or the point where the toilet seat temperature does not rise in accordance with the signal of the seat detecting means 138. Accordingly, the toilet seat temperature does not rise during use, and it is safe to use without fear of burns.

In particular, since the toilet seat is seated in contact with the skin directly to the toilet seat incorporating a lamp heater, sufficient consideration for safety is necessary. In the normal use state, it can be used safely and comfortably as described above. However, if a problem occurs in the control unit 150 such as a microcomputer (not shown) for some reason, the electricity to the lamp heater 129 is continuously performed. It is also necessary for the safety device to operate reliably. As a case where the toilet seat temperature rises during use, the following cases can be considered. That is, when a problem occurs in the control unit 150 such as a microcomputer (not shown) and the current is supplied to the lamp heater 129 continuously, or when a problem occurs in the thermistor 144, the toilet seat temperature gradually rises. .

In the thermostat, as shown in FIG. 10, a bimetal 7 is enclosed in a metal cap 6 to block light. In this configuration, the cap 6 is first heated, and the bimetal is heated. Is performed by radiation from the cap 6, and therefore, it takes time for the bimetal to reach a predetermined temperature. Therefore, when the temperature of the toilet seat 122 changes in a short time, there may be a delay in breaking the circuit. there was. In this embodiment, in order to solve the problem, the radiation-responsive thermostat 130 and the thermally conductive thermostat 131 are provided in correspondence with the plurality of lamp heaters 129, and they are configured to be connected in series.

First, the radiation response thermostat will be described. The radiation responsive thermostat 130 exposes the bimetal 151 and applies a heat resistant black paint as a radiant heat absorber 152 on the surface of the bimetal 151. Accordingly, since the bimetal 151 receives the radiation of the lamp heater 129 directly, the bimetal 151 is directly heated by the radiation from the lamp heater 129, and thus the radiant heat absorbing material 152 is formed on the surface of the bimetal 151. Since a heat resistant black paint was applied, almost all of the radiant heat that reaches the bimetal 151 from the lamp heater 129 is absorbed by the bimetal 151 to quickly follow a sudden change in the temperature of the toilet seat 122, Since the radiation-responsive thermostat 130 is electrically connected in series with the lamp heater 129, it is possible to block the energization of the lamp heater 129 when the temperature rises.

In addition, the radiation response thermostat 130 is set at a position where the distance a between the lamp heater 129 and the toilet seat 122 surface is larger than the distance b between the lamp heater 129 and the radiation response thermostat 130. . As a result, the temperature of the bimetal 151 is raised faster than the temperature of the toilet seat 122 surface is increased. Thus, when an abnormality occurs, the surface of the lamp heater 129 is increased before the toilet seat 122 surface temperature rises and becomes a dangerous state such as a burn. The circuit can be cut off to make it safe.

In addition, in the present embodiment, if the temperature of the bimetal 151 can be quickly increased, malfunction of the radiation-responsive thermostat 130 can be prevented. That is, if the temperature of the bimetal 151 can be raised quickly, the operating temperature of the off-response thermostat 130 (opening the energization circuit of the lamp heater 129) is higher than the normal use temperature of the toilet seat 122. Since it can be set high, the radiation responsive thermostat 130 can operate in normal use, and can avoid the danger of being unable to use the heating function of a toilet seat.

That is, FIG. 18 shows the bimetal 151 in the case of energizing the lamp heater 129 with the distance b = 7 mm and the distance a = 15 mm in the radiation responsive thermostat 130 having the configuration shown in FIG. 16. It is the result of having measured the vicinity temperature and the surface temperature of the seating part 124. FIG. In FIG. 18, the curve A is the surface temperature of the seating portion 124, and at a room temperature of 5 ° C., the temperature can be raised from about 7.5 seconds (t ₁ ) to the normal toilet seat control temperature T ₁ . On the other hand, the temperature of the bimetal 151 of the radiation-responsive thermostat 130 rises to the toilet seat control temperature T ₁ at t ₂ times faster than the seating portion 124, as indicated by the curve (B). When the seating portion 124 is equal to or higher than the maximum set temperature T ₂ of the toilet seat 122, the temperature of the bimetal 151 is adjusted to the off operating temperature T ₃ of the radiation-responsive thermostat 130. And the energization circuit of the lamp heater 129 is cut off.

Therefore, when a problem occurs in a microcomputer or the like and the state in which the power supply circuit of the lamp heater 129 is not blocked, the radiation-responsive thermostat 130 operates to reach the lamp heater 129 before the safety limit temperature is reached. Shut off the power supply circuit. At this time, the toilet seat 122 surface temperature does not reach the safety limit temperature T ₄ . In addition, since the radiation responsive thermostat 130 is made non-returnable, when the radiation responsive thermostat 130 is operated, the toilet seat temperature does not rise afterwards.

Next, the thermally conductive thermostat 131 will be described. As shown in FIG. 17, the thermally conductive thermostat 131 has the same configuration as that of the conventional thermostat 5 illustrated in FIG. 10, such that the bimetal 151 is enclosed in the metal cap 154. It is the structure which interrupts the radiation from the lamp heater 129. In this configuration, since the cap 154 is first heated and conducted by heat conduction and radiation from the cap 154, it takes time for the bimetal to reach a predetermined temperature. However, when the user sits on the toilet seat 122 and the lamp heater 122 is kept warm at low power, the thermally conductive thermostat 131 is at the same temperature as the toilet seat temperature.

19 shows a problem in the thermistor 144, and the temperature of the toilet seat 122 cannot be accurately detected, and thus the temperature (curve C) and the thermal conductivity of the toilet seat 122 when the toilet seat temperature gradually rises. The temperature (curve D) of the bimetal 151 of the thermostat 131 is shown. The toilet seat temperature gradually rises, but the temperature of the bimetal 151 rises in the same manner so that the seating portion 124 becomes equal to or higher than the maximum set temperature T ₂ of the toilet seat 122, and the temperature of the bimetal 151 increases. When the off (opening) operating temperature T _{5 of the} heat conductive thermostat 131 is reached, the energization circuit of the lamp heater 129 is cut off. Since the temperatures of the bimetal 151 and the toilet seat 122 are equal to those, the energizing circuit of the lamp heater 129 is reliably shut off before the toilet seat reaches the safety limit temperature T ₄ .

Since the off operating temperature T ₅ of the thermally conductive thermostat 131 is low with respect to the radiation response type thermostat 130 off operating temperature T ₃ , an abnormality may occur in the toilet seat, for example, depending on the use environment. If it doesn't exist, it can work. Therefore, the thermally conductive thermostat 131 is a return type, and the bimetal 151 temperature returns to a temperature lower than the off operation temperature T ₅ , and can be used again.

In addition, the radiation-responsive thermostat 130 allows the toilet seat surface temperature to be turned off above the maximum set temperature T ₂ of the toilet seat 122 and below the safety limit temperature T ₄ . Since the off operation temperature T _{3 of the} radiation response thermostat 130 can be set to a temperature higher than the safety limit temperature T ₄ of the toilet seat, the lamp heater 129 by the radiation response thermostat 130 is easy. The risk that the heating function of the toilet seat 122 becomes unusable by the interruption of the energization circuit of (circle) is eliminated. That is, the first stage of the initial energization time is the temperature control by the timer unit 149 and thermistor 144 of the controller 150, the second stage is the lamp heater 129 by the off of the thermally conductive thermostat 131 Of the power supply circuit of the lamp heater 129 by the non-returning radiation-responsive thermostat 130 Impurity) and safety functions at each stage, so that the device can be used for a long time, safely and comfortably.

That is, as shown in Fig. 13, the front lamp heater 129 and the rear lamp heater 129b are arranged in front of and behind the toilet seat 122, and a plurality of lamp heaters 129 and 129b are provided. On the opposite side, radiant response thermostats 130 and 130b and thermally conductive thermostats 131 and 131b are provided, and each is electrically connected in series. In addition, the return type thermally conductive thermostats 131 and 131b are blocked at a low temperature, and the non-returned type thermostats 130 and 130b are blocked at a higher temperature than the return type thermally conductive thermostats 131 and 131b. By operating operating temperature, higher multiple safety and long term, safety can also be used comfortably.

In addition, in the present embodiment, each of the lamp heaters is installed to face the radiation-responsive and thermally conductive thermostats. However, when a plurality of lamp heaters are provided, the thermostats may be opposed to each other at any one position of the series of lamp heaters. By providing it, the same safe operation can be performed. Moreover, when there exist two or more types of thermostats, even if one of the same types of thermostats becomes abnormal, a safe operation can be performed reliably by another.

In addition, since the lamp heaters 129 and 129b are divided into plural, in the conventional circular toilet seat 2 shown in Fig. 9, one circular lamp heater 4 is disposed in the cavity of the toilet seat 2. The problem that stress is directly applied to the lamp heater 4 due to the warpage of the toilet seat 2 and the installation error of the lamp heater 4 is eliminated by disposing it in approximately the entirety of (1). The risk of damage to the lamp heater 129 due to warpage can be eliminated.

(Example 4)

20 is a sectional view of principal parts of the heating toilet seat in the fourth embodiment of the present invention, in particular showing a partial sectional view of the thermostat. The present embodiment has the same basic configuration as the invention of the third embodiment, and the other is an improvement in the structure of the thermostat connected in series with the lamp heater, and therefore only the structure of the other thermostat will be described.

In FIG. 18, the radiation-responsive thermostat 130c has a cap 153 made of transparent glass such that the bimetal 151 receives the radiation of the lamp heater 129. In addition, by providing the cap 153 of the transparent glass, it can be a waterproof or waterproof type that does not penetrate the water droplets and dust inside the radiation-responsive thermostat (130c). Even when the radiation-responsive thermostat (130c) can be prevented inundation to the energized part can maintain electrical insulation can prevent the electric shock. In addition, the radiation-responsive thermostat 130c is coated with a heat resistant black paint as a radiation heat absorber 152 on the light receiving surface of the bimetal 151 as in FIG. The radiation responsive thermostat 130 is configured to efficiently absorb heat radiated from the radiant heating element to the bimetal 151 by the radiant heat absorber 152, and to increase the temperature of the bimetal more quickly. In addition, the radiation response thermostat 130c is set so that the distance a between the surface of the lamp heater 129 and the toilet seat 122 becomes larger than the distance b between the lamp heater 129 and the bimetal 151. Accordingly, since the bimetal 151 receives the radiation of the lamp heater 129 directly, the bimetal 151 is directly heated by the radiation from the lamp heater 129, and thus the radiant heat absorbing material 152 is formed on the surface of the bimetal 151. Since a heat resistant black paint was applied, almost all of the radiant heat that reaches the bimetal 151 from the lamp heater 129 is absorbed by the bimetal 151 and quickly follows a sudden change in the temperature of the toilet seat 122. , The radiation-responsive thermostat 130 is electrically connected in series with the lamp heater 129, so that the electric current of the lamp heater 129 may be cut off when the temperature rises.

In addition, the transparent glass of the cap 153 is excellent in the transmission characteristic of the radiant light of the lamp heater 129 by using quartz glass, and it can be made into a faster response, and can improve the interruption | blocking safety. Of course, it goes without saying that even the other glass becomes practical depending on the required degree. In addition, when the plate pressure of the transparent glass 153 is too thick, permeation | transmission performance will fall, 1.5 mm or less of plate | board thickness is good, Preferably 1.2 mm or less is preferable. In addition, in each said embodiment, although the seating material was made into the press-formed product of an aluminum plate, the same effect can be acquired also by other processing methods, such as aluminum die-casting. The type of metal may be copper plate or steel sheet.

(Fifth Embodiment)

21 to 25, the toilet seat of the present embodiment provided on the toilet 201 of the toilet seat is a toilet seat main body which is hingedly coupled to the main body 202 which is horizontally long and which can be erected or laid down in front of it. 203 and the lid 204.

The main body 202 has a built-in part of the hot water washing function, and various control functions are built in. In addition, the human body detection sensor 205 is provided integrally or independently of the main body 202, and detects the entrance of a person into the toilet to open the lid 204, or to control various functions of the main body 202. To start.

By the way, the toilet seat main body 203 fits the sealing body 207 made of the synthetic resin which protruded the leg 206 which becomes the hinge part to the main body 202 from both sides, and this sealing body 207. It is watertightly joined, and is formed by the seating part 209 which consists of heat | fever positive conductive materials, such as aluminum which comprises the cavity part 208 inside.

In the cavity portion 208, there are two front and rear radiation heating elements 210 arranged to be substantially circular, and the reflecting plate 211 is located at the distribution of the radiation type heating elements 210, that is, at the heart body 207 side. Is installed.

The front and rear radiation type heating elements 210 are electrically connected in series, and each inert gas such as argon in which trace amounts of halogen are mixed is enclosed in the heat transmitting tube 212 made of crystallized glass, and the like. The filament 213 is disposed, and the exhaust cycle of the filament 213 is prevented by repeating the halogen cycle reaction of forming tungsten halide in accordance with the heat generation of the filament 213.

By the above operation, the filament 213 having a very small heat capacity can be used as a heat source, thereby making it possible to make an extremely steep rise in radiant energy. That is, the radiation type heating element 210 is the seating portion 208 at a moment, for example, a few seconds until the user enters the toilet and sits on the seating portion 208 of the toilet seat main body 203. The temperature is raised to high temperature at high speed.

In addition, the radiant heating element 210 does not necessarily use halogen depending on the degree of required properties.

As long as light weight is important, the reflecting plate 211 is preferably an aluminum plate. Otherwise, a stainless steel plate, a plated steel sheet, or the like may be used. As shown in FIG. 211a), the radiant heat from the radiant heating element 210 is deflected by the bent portion 211a, so that the seating portion 209 is effectively and evenly heated.

Moreover, the said reflecting plate 211 is fixed to the protrusion 214 formed in the hartle body 207 with a screw, etc., The clearance gap which exhibits a heat insulation effect between both is set according to the height of these protrusion 214. .

The radiation type heating element 210 is held by a holder 215 made of a leaf spring member having a lower end fixed to the reflecting plate 211 by means of welding or the like. More specifically, as shown in Fig. 25, the holder 215 sandwiches the outer circumferential surface of the radiant heating element 210 at the arc portion of the flow end side in the pair of holding pieces 215a and 215b. In addition, inadvertent enlargement of the clamping pieces 215a and 215b is prevented by fitting the clips 216 at their flow ends.

The clip 216 is detachable. Needless to say, the clip 216 can be detachably installed and detached from the radiant heating element 210 with respect to the sandwich pieces 215a and 215b.

As shown in FIG. 26, the inner surface side of the seating part 209, ie, the site | part to which the radiant heat of the radiant heating element 210 is irradiated, is black which should absorb the radiant heat well, and also the electrically insulating radiant heat absorbing layer 217 ), The outer side, that is, the sitting side, is provided with an anticorrosive layer 218 such as an alumite layer and a surface deco layer 219 coated thereon for a desired appearance effect.

In addition, the anticorrosive layer 218 and the surface deco layer 219 do not necessarily need to have both, and any of them can add anticorrosive effects such as chemical resistance and design such as gloss and color. have.

However, by having both the anticorrosive layer 218 and the surface deco layer 219, a higher anticorrosive effect and the antimicrobial effect can be added, for example by using the antimicrobial containing paint.

In addition, as a result of confirming the color of the radiant heat absorbing layer 217 with respect to various colors, it was found that black had the most endothermic efficiency and the temperature increase rate of the seating portion 209 could be increased.

In view of the fact that it is not necessary to dwell at the maximum speed but may be practical, the temperature can be raised even in gray, red, and blue.

When the aluminum press (squeezed) workpiece is used for the seating portion 209, the thermal conductivity is about 200 W · mK, which is very high compared to about 0.1 to 1 W · mK of the resin. Upon receiving the radiant heat, the radiation absorbing layer 217 is heated, and at the same time, heat can be transferred to the surface deco layer 219 of the seating portion 209. Moreover, since it is aluminum with high thermal conductivity, the cracking effect which makes temperature distribution more uniform is obtained. In addition, the required strength can be secured even if the sheet thickness is reduced by the work hardening by aluminum pressing.

For example, in the case of resin, the thickness of about 3 mm is required in terms of strength, and 1.5 mm or less, which is half, is sufficient for the gripped workpiece of the aluminum plate. The thinner it is, the smaller the heat capacity can be. Therefore, the amount of heat and time required for temperature increase can be reduced.

As a result of the experiment, it was concluded that the thickness of the aluminum sheet is preferably 0.8 to 1.2 mm in terms of strength and temperature increase time.

Two thermostats 220 are electrically connected in series on both sides of each of the front and rear radiant heat generating elements 210, and one and two of each of the two thermostats 220 are electrically connected in series. A temperature sensor 221 such as a thermostat is provided, and acts to prevent the temperature rise of the seating portion 209 against an unsafe situation in case of emergency.

First, as shown in FIG. 27, the thermostat 220 employ | adopts the structure which arrange | positioned the bimetal 222 in the case 223 so that the radiant heat from the radiation type heating body 210 may be directly irradiated. The bimetal 222 has a plate spring shape, and is alternatively inverted at two stable positions depending on the temperature at the dead point.

On the radiant heat-heating surface of the bimetal 222, a radiant heat absorbing layer 224 is formed by applying a heat resistant black paint, so as to efficiently absorb radiant heat from the radiant heating element 210, so that the temperature is increased more quickly. It is configured to increase.

In addition, the thermostat 220 is set so that the distance b between the radiation type heating element 210 and the bimetal 222 may be smaller than the distance a between the radiation type heating element 210 and the seating portion 209. For reference, this distance a indicates the distance to the radiation absorbing layer 217 provided on the inner surface of the seating portion 209 in this embodiment.

A distance b of a predetermined value must be secured between the radiation type heating element 210 and the bimetal 222, and the mounting body 225 for installing the thermostat 220 on the reflecting plate 211 is shown in FIG. Similarly, the spacer 226 is integrally provided. In other words, the arc-shaped recess formed at the tip of the spacer 226 is coupled to the circumferential wall of the radiation type heating element 210 to determine the distance b.

The main body 202 acquires the detection signal of the room temperature sensor 227 as the room temperature detection means to perform energization control of the radiation type heating element 210, and the elapsed time of energization from the timer unit 228 to the radiation type heating element 210. The control part 229 which mainly uses the microcomputer which made the count to count is provided.

The control unit 229 acquires a signal of the seat detecting means 230 or the toilet seat position detecting means 231 which detects that the user sits on the human body detecting sensor 205 or the seating portion 209 described above, and copies the signals. Control of the start and stop of energization to the type heating element 210, and the signals from the two temperature sensors 221 and the room temperature sensor 227 for detecting the temperature of the seating section 209, Temperature control of the radiation type heating element 210 is performed so that the temperature of the seating portion 209, which is a surface), becomes a predetermined value that is an appropriate temperature.

In addition, the control unit 229 starts the energization of the radiation type heating element 210, and when the seating unit 209 has not yet reached the predetermined temperature, the indicator (such as a pilot lamp) turns on continuously when the flashing state reaches the predetermined temperature ( 232) lighting control.

This indicator 232 is arrange | positioned in the site | parts, such as the front upper surface of the main body 202, which can be confirmed irrespective of the state which the lid 204 opens and closes.

In addition, although two temperature sensors 221 are provided to detect the temperature of the seating part 209, the control part 229 of the radiation type heating element 210 when there is no deviation in the temperature detection result of these temperature sensors 221 is carried out. Temperature control is performed, and when the deviation of the predetermined range or more has occurred, the electricity supply to the radiation type heating element 210 is stopped.

This is because, in contrast to the purpose of uniform heating in the seating section 209, a safety problem is expected when there is a temperature deviation of a predetermined value or more.

In the above embodiment, when the user enters the bathroom, the human body detecting sensor 205 detects it, and a signal is sent to the control unit 229. At this time, when it is confirmed by the signal of the toilet seat position detecting means 231 that the toilet seat main body 203 is in a substantially horizontal use position, the control unit 229 starts energizing the radiant heating element 210.

By this initial energization, the input energy is instantaneously converted into radiant heat, reflected directly and by the reflecting plate 211, and radiated in the direction of the seating portion 209 of the toilet seat main body 203.

Radiant heat radiated in the direction of the seating portion 209 is efficiently absorbed by the radiation absorbing layer 217, and as a result, the seating portion 209 is quickly heated up.

As described above, in the present embodiment, when the user enters the bathroom, the radiant heating element 210 is energized to warm the seat 209 of the toilet seat main body 203 almost instantaneously, and the control unit 229 Even in the event of an unstable situation due to a failure, the bimetal 222 of the thermostat 220 directly radiates the radiant heat of the radiant heating element 210, so that energization can be cut off at a high speed in response to this, and thus has been commonly used. Unlike heating toilet seats, which are always energized to maintain a large heating loss, there is little heating loss, thereby realizing an extremely energy-saving and safe heating toilet seat.

In the toilet seat main body 203, the heart body 207 is formed of a synthetic resin, and the leg 206 serving as a hinge portion to the main body 202 is integrally formed with the heart body 207. Since the place where the radiant heating element 210 heats is minimized, only the seat 209 needs to be minimized, and the heat loss through the legs 206 is suppressed as much as possible, so that the seat 209 can be used quickly and with less power. ) Can be raised.

In addition, the control unit 229 calculates from the temperature difference between the two and the respective temperatures based on the signals of the temperature sensor 221 and the room temperature sensor 227 at the start of energization, and determines the initial energization that is set and stored in advance. When the elapsed time counted by the timer unit 228 reaches the energization limit time, the electrification amount is reduced or set to 0, and then the seating unit (244) is selected based on the signal of the thermistor 244. The amount of energization is controlled so that the temperature of 209 is kept at an appropriate temperature.

Accordingly, the temperature sensor 221 detects the temperature near the seating portion 209 that the user actually touches, and increases and maintains the temperature at a high temperature with good accuracy through the control unit 229, so that the use of the toilet seat is comfortable. In addition, since the input amount of the radiant energy is controlled in accordance with the load based on the signals of the temperature sensor 221 and the room temperature sensor 227, it is possible to heat the temperature more precisely and safely.

In addition, since the initial energization time control is first performed, the energization amount is reduced and the temperature increase rate is reduced after the energization limit time, so that the toilet seat can be safely warmed even if the response speed of the toilet seat temperature detection means is slow. Sheet temperature detection means can also be used.

In general, in general heaters, the applied voltage is reduced to control the temperature, but the halogen radiant heating element 210 repeats the halogen cycle reaction of forming tungsten halide in accordance with the exothermic heat of the filament 213. Since the consumption is prevented, when the temperature of the heat transmitting tube 212 is 200 ° C or less, the halogen cycle becomes uneven. Therefore, in order to make the seating section 209 in the radiant heat generating element 210 temperature-correct, it performs by changing an energization cycle in the output range in which a halogen cycle is effective.

On the other hand, when the toilet seat main body 203 is in a standing state or when the male user enters the toilet seat main body 203 for standing urine after entering the toilet, the toilet seat position detecting means 231 is based on the signal. The control unit 229 stops energization to the radiation type heating element 210. Accordingly, it is possible to prevent the toilet seat main body 203 from warming up, and to further save energy, and at the same time, gravity is applied in the longitudinal direction, which is the tension direction of the filament 213, in the energized state. Can shorten the life span.

In addition, even if the user opens and closes the toilet seat main body 203 in an upright state and in a substantially horizontal state, such as standing up or down, the radiant heating element 210 is held by the holder 215 made of leaf spring material. (Iii) Since impact protection is aimed at, damage to the heat transmitting tube 212 and the filament 213 can be prevented.

Next, when the user sits for defecation, the amount of current supplied to the radiant heating element 210 is controlled by changing the amount of current supplied to the radiant heating element 210 to a point where the toilet seat temperature does not rise according to the signal of the seat detecting means 230. Accordingly, the toilet seat temperature does not rise during use, and it is safe to use without fear of burns.

In particular, since the heating toilet seat makes direct contact with the seating portion 209 of the skin, sufficient consideration is required for safety. In the normal use state, it can be used safely and comfortably as described above, but if for some reason a problem occurs in the control unit 229 such as a microcomputer (not shown), the energization of the radiant heating element 210 is continued. It is necessary to operate safely even in cases.

In general, a thermostat is one in which a bimetal is enclosed in a metal cap to block radiant heat. In this configuration, the cap is first heated, and since the bimetal is heated by radiation from the cap, the bimetal reaches a predetermined temperature. It takes time until now, and when the temperature of a toilet seat changes in a short time, a delay may arise in interruption | disconnection of a circuit.

However, in this embodiment, in order to solve the problem, the thermostat 220 is coated with a heat resistant black paint on the surface as the radiant heat absorbing layer 224 while allowing the bimetal 222 to directly heat.

Therefore, almost all of the radiant heat arriving from the radiant heating element 210 to the bimetal 222 is absorbed by the bimetal 222 and quickly follows a sudden change in the temperature of the seating portion 209. The energization of 210 can be cut off.

In addition, the thermostat 220, more specifically, the distance b between the bimetal 222 and the radiant heating element 210 is set to be shorter than the distance a between the radiant heating element 210 and the seating portion 209. Therefore, the temperature of the bimetal 222 is raised faster than the surface temperature of the seating part 209, and the safe operation at the time of abnormality is performed correctly.

As such, if the temperature of the bimetal 222 can be quickly increased, malfunction of the thermostat 220 can be prevented. That is, if the temperature of the bimetal 222 can be raised quickly, the operating temperature of the thermostat 220 (opening the energizing circuit) can be set higher than the normal use temperature of the toilet seat, and thus the thermostat 220 at the time of normal use. ) Can be activated to disable the heating function.

That is, FIG. 29 shows the temperature near the bimetal 222 when the thermostat 220 having the configuration shown in FIG. 27 is energized by the radiant heating element 210 at a distance b = 7 mm and a distance a = 15 mm. And the surface temperature of the seating part 209 are measured.

In FIG. 28, the curve A is the surface temperature of the seating portion 209, and at a room temperature of 5 ° C., the temperature can be raised from about 7.5 seconds t1 to the normal toilet seat control temperature T1. On the other hand, the temperature of the bimetal 222 of the thermostat 220 rises up to toilet seat control temperature T1 in t2 time earlier than seating part 209, as shown by curve (B). When the seating portion 209 becomes equal to or higher than the maximum set temperature T2 of the toilet seat, the temperature of the bimetal 222 reaches the off operating temperature T3 of the thermostat 220, and the energization circuit of the radiant heating element 210 is applied. To block.

As described above, since the distance b between the thermostat 220 and the radiant heating element 210 has a significant significance for safety, it will be required to have a high precision for its dimensional management.

Thus, as shown in Fig. 28, the spacer 226 is integrally provided from the mounting body 225 in which the thermostat 220 is attached to the reflecting plate 211, and an arc-shaped recess formed at the tip of the spacer 226. The portion is coupled to the circumferential wall of the radiation type heating element 210. As a result, the distance b between the thermostat 220 and the radiation type heating element 210 is accurate, and the above safety operation is performed correctly.

In addition, in the present embodiment, two of the plurality of thermostats 220 (for example, two arranged on the right side in FIG. 23) are returned, and two (for example, two arranged on the left side in FIG. 23). The non-return type, if the problem occurs in the return-type thermostat 220 and the state in which the energizing circuit of the radiation type heating element 210 cannot be interrupted, reaching the safety limit temperature T4. Before the non-return thermostat 220 is operated to cut off the energization circuit. As a result, the toilet seat surface temperature does not reach the safety limit temperature T4.

Further, by setting the operating temperature T3 of the thermostat 220 to be equal to or higher than the maximum set temperature T2 of the toilet seat and the safety limit temperature T4, the radiation type heating element by the non-returnable thermostat 220 is easily The interruption of the electricity supply circuit of 210 occurs, and the problem which becomes impossible to use the heating function of a toilet seat can be eliminated.

That is, the first stage of the initial energization time is the temperature control by the timer unit 228 and the temperature sensor 221 of the control unit 229, the second stage is the radiation type heating element 210 by the off of the thermostat 220 (3) The third step is to cut off the power supply circuit of the non-return thermostat 220 (it is impossible to return the circuit) and to set the multi-level safety function. As a result, it can be used for a long time, safely and comfortably.

In addition, the return type thermostat 220 is cut off at a slightly lower temperature, and the non-return thermostat 220 is set at an operating temperature that cuts off at a higher temperature, thereby providing higher multiple safety and longer term, safety. Also, it can be used comfortably.

In addition, since the heating source is constituted by the plurality of radiant heating elements 210, the stress is directly applied to the radiant heating element 210 due to the warpage of the toilet seat main body 203 and the installation error of the radiant heating element 210. This applied problem can be solved, and the risk of damage can be eliminated. Of course, the arrangement itself of the radiation type heating element 210 also becomes simple.

By the way, the radiant heat absorption layer 217 is formed in the inner surface side of the seating part 209 to which the radiant heat of the radiant heat generating body 210 is irradiated. The radiation heat absorbing layer 217 is also set to be electrically insulating.

Therefore, even if the filament 213 is struck on the seating portion 209 side when the radiation type heating element 210 causes damage, there is no fear of electric shock or the like.

In addition, the radiant heating element 210 has an outer circumferential surface sandwiched between the arc portions of the flow end side in the pair of sandwich pieces 215a and 215b made of leaf spring material, and the clips 216 are fitted to the flow ends thereof. This prevents inadvertent expansion.

Therefore, even if an impact is applied when the toilet seat main body 203 is erected or laid down, for example, inadvertent detachment of the radiant heating element 210 and the resulting damage can be prevented.

(Sixth Embodiment)

30 shows the sixth embodiment, the basic configuration of which is the same as that of the fifth embodiment, except that improvements have been made to the structure of the thermostat.

That is, the difference from the fifth embodiment is that the radiation type heating element 210 side of the bimetal 222 in the thermostat 220 is partitioned with a heat transmitting element 233 such as quartz glass.

Thus, by partitioning with the heat-transmitting body 233, it can be a waterproof or waterproof type that does not intrude water droplets and dust inside the thermostat 220, even if the cavity 208 is submerged in one bay Inundation into the energizing portion of 220 can be prevented, and electrical insulation can be maintained, thereby preventing electric shock.

If the heat permeable body 233 is too thick, heat permeation performance will fall, so plate | board thickness 1.5 mm or less is preferable, Preferably it is 1.2 mm or less.

In addition, in each said embodiment, although the seating material was made into the press-formed product of an aluminum plate, the same effect can be acquired also by other processing methods, such as aluminum die-casting. The type of metal may be a copper plate or a steel sheet.

(Seventh Embodiment)

FIG. 7: shows the perspective view of the heating toilet seat with a warm water washing function in 7th Example of this invention.

In FIG. 31, the main body 321 is provided in the toilet 320, and the toilet seat 322 and the toilet lid 323 are provided in this main body 321 so that rotation movement is possible.

In addition, an infrared ray transmitting portion is provided in the sleeve 324 of the main body 321, and an infrared sensor 325 for detecting the presence or absence of a human body in the toilet space is built therein.

In addition, an LED 341 serving as a notification means is provided in the main body 321.

32 is a partial cutaway plan view of the toilet seat 322 in the seventh embodiment of the present invention, and FIG. 33 is a cross-sectional view of the main parts of the toilet seat 322 in the seventh embodiment of the present invention.

The toilet seat 322 is formed by joining and fixing the inner circumference and the outer circumference of each of the metal frame 326 and the heart 327 which have a high thermal conductivity, such as aluminum, to form a cavity 328 therein. The branch has a structure.

Inside the cavity 328, a radiating reflecting plate 329 having an aluminum plate mirrored and a lamp heater 330 which is a radiating heating element are provided to face the seating portion of the toilet seat 322. have. The end of the radiation reflecting plate 329 has a bent upward portion over the entire circumference, and since the heat radiation is deflected from the lamp heater 330 by the bent portion, an outer periphery separated from the lamp heater 330. It acts to raise the radiation density of the circumference part and the inner circumference part, and aims at equalizing the radiation distribution to the frame 326. As shown in FIG.

In the vicinity of the lamp heater 330, a thermostat 331 and a room temperature fuse 332 electrically connected in series with the lamp heater 330 are provided, and act to prevent a temperature rise in case of an unsafe situation.

In addition, a thermistor 333 is disposed on the inner surface of the frame 326, and a controller for controlling the energization to the lamp heater 330 so that the temperature of the filling surface becomes a predetermined temperature based on the signal of the thermistor 333 ( Not shown) is provided in the main body 321.

The lamp heater 330 is formed by enclosing a gas 336 containing argon and nitrogen as a main component by penetrating the tungsten filament 335 inside the quartz tube 334, and consumes the tungsten filament 335. It is working to prevent.

By further applying the halogen gas to the gas 336, the halogen cycle reaction of forming tungsten halide with the heat generation of the tungsten filament 335 is repeated, which serves to further prevent the consumption of the tungsten filament 335.

According to this action, the tungsten filament 335 having a small heat capacity can be used as a heat source, and an extremely steep increase in radiant energy can be performed.

Fig. 34 is a sectional view of principal parts of the frame body 326 in the seventh embodiment of the present invention, wherein the frame body 326 is formed of carbon black on the inner surface of the frame body 337 formed using a metal material such as aluminum. The radiation absorbing layer 338 containing a large amount is coated, and the surface deco layer 339 is coated on the outer surface of the main body 337 in consideration of surface hardness, chemical resistance, glossiness, and the like.

The upper frame body 337 is formed by forming a metal material with an average thickness of 1.2 mm to increase the thermal conductivity and to function as a structural structure of the toilet seat due to its rigidity.

In addition, the thickness of the radiant heat absorbing layer 338 coated on the inner surface is 0.1 mm, so that the radiant heat is completely absorbed and the heat capacity is very small.

In addition, the thickness of the surface deco layer 339 coated on the outer surface is 0.2 mm, and since this layer also has a very small heat capacity, the temperature is temporarily raised by heat conducting the body body 337.

According to the above configuration, when the user enters the bathroom, the infrared sensor 325 detects it, and the lamp heater 330 is urged according to the signal. As a result, the input energy is instantaneously converted into radiant energy and radiated in the direction of the frame body 337 via the quartz tube 334 and the radiation reflecting plate 329.

The operation | movement and an action | movement are demonstrated below about the heating toilet seat comprised as mentioned above.

By the above configuration, when the user enters the toilet and approaches the heating toilet seat, the infrared sensor 325 detects the human body, and power supply to the lamp heater 330 is started in response to the signal. As a result, the input energy is instantaneously converted into radiant energy and transmitted through the quartz tube 334 and radiated toward all directions inside the toilet seat. Radiant energy is irradiated to the frame body 326 directly and via the radiation reflecting plate 329.

Radiant energy that reaches the frame 326 is absorbed by the radiant heat absorbing layer 338 and converted into thermal energy. The metal frame 326 is heated in a short time by the heat energy, and when the frame 326 reaches a predetermined temperature, the thermistor 333 detects and controls the electricity supply to the lamp heater 330, and the frame body 326 is heated. Maintain 326 at a constant temperature.

In addition, the LED 341 provided in the main body 321 turns on when the toilet seat becomes warm by energization of the lamp heater 330 controlled by the temperature signal from the thermistor 333, and the lamp heater until reaching the temperature. 330 flashes during energization, and the user can visually check the heating state of the toilet seat.

As described above, the heating toilet seat of the present embodiment detects the human body and can warm up the frame which becomes the seating part almost instantaneously, so that the toilet seat does not need to be preheated in advance, and is automatically energized when used. Since a warm state can be recognized beforehand, the effect of energy saving and a comfortable and convenient heating toilet seat can be provided.

In the present embodiment, the LED is distinguished by the lighting and the flashing of the temperature from the time of reaching the temperature to the temperature reaching the temperature, but even if the LEDs of different colors are used, the effect does not change even if the voice acts on the hearing.

(Example 8)

Fig. 34 is a sectional view of principal parts of the frame body in the eighth embodiment of the present invention.

This embodiment differs from the seventh embodiment in that the upper body 342 shown in FIG. 34 is coated with a radiant heat absorbing layer 338 on the upper surface of the upper body body 343 formed by injection molding using a transparent polypropylene resin material. In addition, the surface deco layer 339 is coated thereon.

In addition, the same code | symbol as 7th Example has the same structure, and it abbreviate | omits description again.

By adopting the frame body 342 having the above-described configuration, the radiant energy irradiated to the frame body 342 is partially absorbed or reflected in the inside of the frame body 343, most of which is transmitted through the radiant heat absorbing layer 338 and the surface. Contributes to the temperature increase of the decor layer 339. Since the radiant heat absorbing layer 338 and the surface deco layer 339 are extremely small in heat capacity, they can be warmed in a very short time and sit in a short time, thereby providing a greater energy saving effect and providing a comfortable and convenient heating toilet seat. have.

(Example 9)

Fig. 37 shows a perspective view of a heating toilet seat with a hot water cleaning function in a ninth embodiment of the present invention.

In FIG. 37, the main body 421 is provided in the toilet bowl 420, and the toilet seat 422 and the toilet lid 423 are provided in this main body 421 so that rotation movement is possible.

In addition, an infrared ray transmitting portion is provided in the sleeve portion 424 of the main body 421, and an infrared sensor 425 that detects the presence or absence of a human body in the toilet space is embedded therein.

38 is a partially cutaway plan view of the toilet seat 422 in the ninth embodiment of the present invention, and FIG. 39 is a cross-sectional view of the main parts of the toilet seat 422 in the ninth embodiment of the present invention.

The toilet seat 422 is formed by joining and fixing the inner circumference and the outer circumference of each of the metal frame 426 and the heart 427 having a high thermal conductivity, such as aluminum, to thereby form the cavity 428 therein. The branch has a structure.

Inside the cavity 428, a radiating reflecting plate 429 in which an aluminum plate is mirror-finished with a seating surface of the toilet seat 422 and a lamp heater 430 which is a radiating heating element are provided. . An end portion of the radiation reflecting plate 429 has a bent upward portion over the entire circumference, and since the heat radiation is deflected from the lamp heater 430 by the bent portion, an outer periphery separated from the lamp heater 430. It acts to raise the radiation density of the circumference part and the inner circumference part, and aims at equalizing the radiation distribution to the upper case 426.

In the vicinity of the lamp heater 330, a thermostat 431 and a room temperature fuse 432 electrically connected in series with the lamp heater 330 are provided, and act to prevent a temperature rise in case of an unsafe situation.

In addition, a thermistor 433 is disposed on the inner surface of the frame 426, and a controller for controlling energization to the lamp heater 430 so that the temperature of the filled surface becomes a predetermined temperature based on the signal of the thermistor 433 ( Not shown) is provided in the main body 421.

The lamp heater 430 is formed by enclosing a gas 436 containing argon and nitrogen as a main component through the tungsten filament 435 inside the quartz tube 434. It is working to prevent.

By further applying a halogen gas to the gas 436, the halogen cycle reaction of forming tungsten halide with the heat of the tungsten filament 435 is repeated, thereby acting to further prevent the consumption of the tungsten filament 435.

According to this action, the tungsten filament 435 having a small heat capacity can be used as a heat source, and an extremely steep rise in radiant energy can be performed.

40 is a cross-sectional view of main parts of the upper case 426 according to the ninth embodiment of the present invention, wherein the upper case 426 is formed of carbon black on the inner surface of the main body 437 molded using a metal material such as aluminum. After coating a large amount of radiant heat absorbing layer 438, and coating the surface deco layer 439 in consideration of the surface hardness, chemical resistance, gloss, etc. on the outer surface of the main body 437, discoloring at a predetermined temperature or more The temperature control indicator 441 having the characteristics is coated.

The upper case main body 437 forms a metallic material with an average thickness of 1.2 mm to increase the thermal conductivity and to function as a structural sphere of the toilet seat due to its rigidity.

In addition, the thickness of the radiant heat absorbing layer 438 coated on the inner surface is 0.1 mm, so that the radiant energy is completely absorbed and the heat capacity is so small that the temperature rises instantaneously.

In addition, the thickness of the surface deco layer 439 coated on the outer surface is 0.2 mm, and since this layer also has a very small heat capacity, the temperature is temporarily raised by heat conducting the upper case body 437.

Fig. 41 is a perspective view at the time of failure of the heating toilet seat, showing a state in which the toilet seat temperature becomes high at the time of failure. By coating the temperature control indicator 441 with the letter 'high temperature', it is an example that the character of the high temperature in the toilet seat can be recognized in a state where the toilet seat temperature exceeds 50 ° C. If the form of the coating of the temperature control instruction material 441 is felt to be in a state of discomfort when the user looks at the toilet seat, even if it is a letter or a shape, it is not limited to the form.

The operation | movement and an action | movement are demonstrated below about the heating toilet seat comprised as mentioned above.

By the above configuration, when the user enters the toilet and approaches the heating toilet seat, the infrared sensor 425 detects the human body, and power supply to the lamp heater 430 is started in response to the signal. As a result, the input energy is instantaneously converted into radiant energy, and is transmitted through the quartz tube 434 and radiated toward all directions inside the toilet seat. Radiant energy is irradiated to the frame body 426 directly and via the radiation reflector 429.

Radiant energy that reaches the frame 426 is absorbed by the radiant heat absorbing layer 438 and converted into thermal energy. The metal frame 426 is heated in a short time by the heat energy. When the frame 426 reaches a predetermined temperature, the thermistor 433 detects and controls the energization to the lamp heater 430. Maintain 426 at a constant temperature.

However, when the controller (not shown) which controls the electricity supply to the lamp heater 430 breaks down and the short failure of the thermostat 431 and the thermal fuse 432 occurs simultaneously, the temperature control of the toilet seat is performed. When the temperature of the seating surface does not work and reaches a temperature which causes burns when seating, but the color change temperature of the temperature management indicator 441 is assumed to change color at a temperature assumed to be an image area, for example, 50 ° C, the toilet seat When the temperature reaches 50 ° C., letters or shapes appear on the toilet seat.

(Example 10)

Fig. 42 is a sectional view of principal parts of the frame body in the tenth embodiment of the present invention.

This embodiment differs from the ninth embodiment in that the upper body 442 shown in FIG. 42 is coated with a radiant heat absorbing layer 438 on the upper surface of the upper body body 443 formed by injection molding using a transparent polypropylene resin material. The surface decoration layer 439 is coated thereon, and the temperature control indicator 441 having the characteristic of discoloring at a predetermined temperature or more is coated.

In addition, the same code | symbol as 9th Example has the same structure, and it abbreviate | omits description again.

By adopting the frame body 442 having the above-described configuration, the radiant energy irradiated to the frame body 442 is partially absorbed or reflected in the inside of the frame body 443, most of which is transmitted through the radiant heat absorbing layer 438 and the surface. Contributes to the temperature increase of the decor layer 439. Since the radiant heat absorbing layer 438 and the surface deco layer 439 are extremely small in heat capacity, they can be warmed in a very short time and sit in a short time, thereby providing a greater energy saving effect and providing a comfortable and convenient heating toilet seat. have.

The temperature management indicating member 441 has the same effects and effects as the ninth embodiment.

Although this invention was detailed also demonstrated with reference to the specific Example, it is clear for those skilled in the art that various changes and correction can be added without deviating from the mind and range of this invention.

This application is a Japanese patent application and application number 2005-131973 of an application on April 28, 2005, a Japanese patent application and application number 2005-131974 of an application on April 28, 2005, and a Japanese patent of an application on July 15, 2005. Application and Application No. 2005-206419, Japanese Patent Application and Application No. 2005-238151 of August 19, 2005, Japanese Patent Application and Application No. 2005-251180 of August 31, 2005 The contents are as follows: It is incorporated herein by reference.

In the heating toilet seat of the present invention, the bimetal of the thermostat is directly heated by the radiant light from the radiant heating element, so that the temperature change can be detected quickly, and the temperature change of the toilet seat can be quickly controlled.

As described above, in the heating toilet seat of the present invention, the bimetal of the thermostat is heated by the radiant light from the radiant heating element, so that the temperature change can be detected quickly, and a heating toilet seat which can be used safely is obtained. It can be applied as a heating technique of sitting equipment.

In addition, even in the event of a failure, dangerous conditions such as burns on the toilet seat can be recognized, so that the present invention can be applied to other heating appliances.

Claims (14)

A toilet seat having a seat and a cavity therein, a radiant heating element provided in the cavity, a temperature detecting means for detecting a temperature of the seat of the toilet seat, and the radiation type A thermostat having a bimetal that is connected in series to the heating element and heated by radiation from the radiation type heating element, and controls the energization of the radiation type heating element by a signal of the temperature detecting means. A heating toilet seat having a control unit, The thermostat is a heating toilet seat having a cap (cap) for passing the light so that the bimetal receives the radiation. The method according to claim 1, The cap is a heating toilet seat made of transparent glass. The toilet seat apparatus provided with the toilet seat of the heating toilet seat of Claim 1 or 2. delete delete delete delete delete delete delete delete delete delete delete

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