JP2007143717A - Heated toilet seat device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a heated toilet seat device where power-saving use is possible and the responsiveness of temperature is also improved by improving mechanical strength and controlling unnecessary raising of the temperature of a toilet seat. <P>SOLUTION: A carbon fiber heater 22 arranged on the upper side of the toilet seat 20 is radiated from the side of a casing upper part 21a of a toilet seat casing 21 laid on toilet bowl 1 and formed of a material having far-infrared transmission. Radiation downward from the carbon fiber heater 22 is reflected by reflective component 23, and radiated from the side of the casing upper part 21a of the toilet seat casing 21. In this case, the carbon fiber heater 22 arranged on the upper side of the toilet seat 20 can apply radiation heat to the hips of a human body sitting directly, so that raising of temperature is not influenced by a heat capacity of the toilet seat 20 and responsiveness of the start of controlling the temperature of the toilet seat is improved. It is possible to reduce a loss for energy consumption for warming the toilet seat 20 which is always wasteful. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

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

  As a conventional example of a toilet seat having this type of heating function, there is a technique described in Patent Document 1. That is, the technique disclosed in Patent Document 1 includes a toilet seat in which a hollow portion is formed, and a radiation-type heating element configured by a lamp heater in which halogen gas is sealed in a glass tube provided in the hollow portion, By configuring the seating portion of the toilet seat with a radiant heat permeable material, the seating surface can be instantaneously heated.

  In addition, the technique disclosed in Patent Document 2 includes a toilet seat body having a cavity, radiant heat shielding means that is disposed in the cavity, moves between the toilet seat body and the radiation-type heating element, and shields radiant heat, and Toilet seat temperature detecting means for detecting the temperature of the toilet seat body, and radiant heat control means for controlling the heat generation of the radiant heating element and the moving position of the radiant heat shielding means based on the predetermined temperature detected by the toilet seat temperature detecting means The toilet seat temperature detecting means detects that the temperature of the toilet seat body has excessively increased due to the irradiation of thermal energy from the radiant heating element, and the radiant heat control means controls the heat generation of the radiant heating element and shields the radiant heat. The means moves between the toilet seat body and the radiant heating element to suppress excessive heat radiation to the toilet seat body.

The technique disclosed in Patent Document 3 is characterized in that, in a heated toilet seat device used in a portion that is in direct contact with the human body, a substance that absorbs infrared rays and converts it into heat is used on the contact surface with the human body. is there. In the technique disclosed in Patent Document 3, since the contact surface is a substance that absorbs heat, the contact surface can be immediately heated.
JP 2000-014598 A JP2005-192895 JP-A-11-299701

  However, Patent Document 1 and Patent Document 2 both use a lamp heater in which a halogen gas is sealed in a glass tube as a radiant heating element, and the lamp heater is disposed in the heating toilet seat. Are vulnerable. Therefore, the lamp heater requires a shock absorbing buffer structure, and the structure becomes complicated. In addition, Patent Document 1 and Patent Document 2 have a lamp heater structure in which halogen gas is sealed in a glass tube, so that urine or water enters during cleaning, and when these water droplets touch the glass tube, the glass tube Since it was damaged, more waterproofing than necessary was necessary.

In addition, Patent Document 1 and Patent Document 2 reflect infrared rays emitted from a radiation-type heating element by an aluminum plate, radiate infrared rays toward the inner surface of the housing, and transmit the heat to a human buttocks. It was indispensable to use a material with good thermal conductivity as the toilet seat material.
And since patent document 1 and patent document 2 use the lamp heater which enclosed the halogen gas in the glass tube, it arrange | positions on the assumption of a use condition like the conventional nichrome wire heater with respect to a toilet seat housing | casing. There is a high possibility of unevenness in the temperature rising state depending on the position.
Furthermore, since the technology disclosed in Patent Document 3 uses a substance for the toilet seat that absorbs infrared rays and converts it into heat, the responsiveness is poor, and it is necessary to always maintain a predetermined toilet seat temperature. There was a waste of energy.

  Therefore, in order to solve these problems, the present invention increases the mechanical strength and suppresses a temperature increase beyond the necessary temperature of the toilet seat, thereby enabling energy-saving use and a heated toilet seat with improved temperature responsiveness. It is an object to provide an apparatus.

In the heating toilet seat device according to claim 1, a toilet seat that is placed on a toilet bowl and at least an upper portion thereof is formed of a material having far-infrared transmittance, and a carbon fiber heater disposed on the upper side of the toilet seat. And a reflecting member that is disposed below the carbon fiber heater and reflects the far infrared rays generated by the carbon fiber heater.
Here, for example, polypropylene resin, ABS resin and the like can be used as the far infrared ray transmitting material of the toilet seat, and the far infrared ray transmission does not ask whether the resin is transparent or not.
Further, the carbon fiber heater disposed on the upper side of the toilet seat may be insert-molded on the upper portion of the toilet seat, or the center portion of the toilet seat may be hollow and joined to the upper portion or mechanically attached.
The reflecting member for reflecting the far infrared rays generated by the carbon fiber heater is not particularly intended to form a focal point at a specific position in the surface reflection direction, but to guide the far infrared rays upward in the toilet seat. It may include a flat surface and an irregular reflection surface. Simply, an aluminum tape may be insulated and joined to the lower surface side of the carbon fiber heater.

The carbon fiber heater of the heating toilet seat device according to claim 2 is arranged on the seating side upper inner surface of the toilet seat housing in a layout in consideration of heat reception of the human body part.
The layout in consideration of the heat reception of the human body buttocks means that the amount of heat generation and the heat generation surface are changed depending on the position of the buttocks and legs of the human body. Specifically, the carbon fiber heater is meandered or paralleled, It means an arrangement that changes the thermal radiation energy density.

The said toilet seat of the heating toilet seat apparatus of Claim 3 receives heat directly or indirectly from the said carbon fiber heater to the seating side upper inner surface of the said toilet seat housing | casing, The heat-transfer material which transfers heat to a human body part by the heat conduction is provided. It is arranged.
Here, receiving heat directly or indirectly from the carbon fiber heater means that the heat directly transfers the heat of the carbon fiber heater to the upper portion of the toilet seat housing by direct heat conduction, and the indirect means the carbon fiber heater. It means that heat is transmitted to the upper part of the toilet seat housing by the heat conduction by increasing the temperature of the human body by receiving the radiation (radiation) heat of the heater. A heat transfer material refers to a material that transfers heat to the human body by heat conduction. In addition, a material having a relatively good heat conduction means a material having a good heat conduction.

A direct or indirect heat reception from the carbon fiber heater of the toilet seat of the heating toilet seat device according to claim 4, wherein a black body that absorbs radiant heat is partially applied to a seating side of the upper inner surface of the toilet seat housing, and the black body Is used to prevent the transmission of radiant heat and convert it into energy by heat conduction.
Here, the black body that absorbs radiant heat applied to the seating side of the upper inner surface of the toilet seat casing rises in temperature by absorbing the radiant heat, and heats the upper surface of the toilet seat casing by heat conduction. It is. Since the black body is partially applied, the human body is directly heated by the transmission of radiant heat from the part where the black body is not applied.

  The heat transfer material of the seating side upper inner surface of the toilet seat housing of the heating toilet seat device according to claim 5 is a material in which the ratio of radiant heat and heat conduction is determined by at least one of the material and thickness of the resin toilet seat. The temperature of the toilet seat when a person is seated and the temperature directly emitted to the human body are determined by the ratio of radiant heat and heat conduction. Therefore, the ratio of radiant heat and heat conduction can be arbitrarily set by at least one of the material and thickness of the resin toilet seat.

  The ratio of radiant heat and heat conduction to the heat transfer material on the seating side of the toilet seat housing of the heating toilet seat device according to claim 6 is such that a heat insulating member is interposed between the seating side inner surface of the toilet seat and the carbon fiber heater. Change. Here, the heat insulating member is not limited to glass fiber, and may be any material having poor heat conductivity, and preferably a material having poor heat conductivity and a material through which far infrared rays pass. Is desirable. Of course, resin etc. which can set arbitrarily the ratio of radiant heat and heat conduction may be used.

A toilet lid disposed on an upper portion of the toilet seat of the heating toilet seat device according to claim 7 is provided with a reflector that reflects infrared rays on a lower surface side thereof, and the toilet seat is heated by reflecting the emission of radiant heat. Keep warm.
Here, the toilet lid disposed in the upper part of the toilet seat is provided with a member that reflects emission of radiant heat on the lower surface or a part or all of the interior thereof, and the toilet seat is kept warm by the reflected radiant heat. Is. For this reason, it is desirable that the reflecting surface be as close to the lower surface of the toilet lid as possible.

  The temperature control of the heating toilet seat device according to claim 8 that is not in the seating state is performed by heating the seat side upper inner surface directly or indirectly by setting the carbon fiber heater to a low temperature with little radiant heat, and seating by the heat conduction. It is possible to transfer heat to the human body. Thus, the temperature control not in the seated state of the toilet seat generally reduces the emission of far-infrared rays at a low temperature by setting the carbon fiber heater to a low temperature. This is to assist in quickly raising the temperature of the toilet seat itself so as not to feel uncomfortable even when seated.

The temperature control of the seating state of the toilet seat of the heating toilet seat device according to claim 9 is determined by one or more of the temperature of the toilet seat itself and the room temperature.
The temperature control in the seated state of the toilet seat requires the temperature of the toilet seat itself to be a temperature that does not cause a sense of incongruity when seated, and it is necessary to apply thermal energy to the buttocks of a seated person by radiation. Here, when the temperature of the toilet seat itself can be maintained at a predetermined temperature, the heat dissipated is replenished. In the case where the temperature is determined by the room temperature, the radiant energy is increased. In this way, the buttocks are heated directly so that the human body does not feel cold. Of course, the use of both is most desirable.

  In the heating toilet seat device according to claim 1, the carbon fiber heater disposed on the upper side of the toilet seat is radiated from the upper side of the toilet seat formed of a far-infrared transparent material placed on the toilet. The downward radiation from the carbon fiber heater is reflected by the reflecting member and radiated from the upper side of the toilet seat. At this time, since the carbon fiber heater disposed on the upper side of the toilet seat can give radiant heat to the buttocks of the directly seated human body, the response of the toilet seat temperature control start from the detection of the human body can be improved. . And since the responsiveness at the start of toilet seat temperature control can be improved, the temperature of the toilet seat can be increased, and as a result, it is possible to reduce the loss of energy consumption required to always keep the toilet seat warm. it can. The downward radiation from the carbon fiber heater is reflected by the reflecting member, eliminates the energy loss that heats the toilet, and emits radiant heat only at the top, so that the efficiency can be increased.

  The said carbon fiber heater of the said toilet seat of the heating toilet seat apparatus concerning Claim 2 is arrange | positioned in the layout which considered the heat receiving of the human body part on the seating side upper inner surface of the said toilet seat housing | casing, Since it is 1st. In addition to the above effect, the heating region can be set ergonomically, and waste of energy can be reduced.

  The said toilet seat of the heating toilet seat apparatus concerning Claim 3 receives heat directly or indirectly from the said carbon fiber heater to the seating side upper inner surface of the said toilet seat housing | casing, and heat-transfer material which transfers heat to a human body part by the heat conduction Therefore, in addition to the effect according to claim 1 or 2, the temperature of the toilet seat itself can be set to a low temperature so that a person does not feel uncomfortable, and the warming of the useless toilet seat is possible. Loss for energy consumption required can be reduced.

  To directly or indirectly receive heat from the carbon fiber heater of the toilet seat of the heating toilet seat according to claim 4, a black body that absorbs radiant heat is applied to a seating side of the upper inner surface of the toilet seat casing to prevent transmission of radiant heat. Therefore, in addition to the effect described in any one of claims 1 to 3, the radiant heat applied to the seating side of the upper inner surface of the toilet seat housing is absorbed. The black body absorbs radiant heat, raises the temperature of the black body itself, and heats the upper surface of the toilet seat by its heat conduction. Since the black body is partially applied, the human body can be directly warmed by transmission of radiant heat from an unapplied portion. Therefore, the toilet seat can be maintained at an appropriate temperature.

  Since the heat transfer material of the seating side upper inner surface of the toilet seat housing of the heating toilet seat device according to claim 5 is a ratio of radiant heat and heat conduction determined by one or more of the material and thickness of the resin toilet seat, In addition to the effect described in Item 3, it is possible to rationally warm the human body directly and to warm the toilet seat to an appropriate temperature.

  The ratio of radiant heat and heat conduction to the heat transfer material on the seating side of the toilet seat housing of the heating toilet seat device according to claim 6 is such that a heat insulating member is interposed between the seating side inner surface of the toilet seat and the carbon fiber heater. Therefore, in addition to the effect of claim 3, the ratio of radiant heat and heat conduction can be arbitrarily set to resin, glass fiber, etc. In particular, the heat conduction can be easily cut off and the degree of design freedom can be increased without significantly suppressing radiant heat.

  A toilet lid disposed on an upper portion of the toilet seat of the heating toilet seat device according to claim 7 is provided with a reflector that reflects infrared rays on the back surface thereof, and the toilet seat is heated by reflecting the emission of radiant heat. In addition to the effect according to any one of claims 1 to 6, since the heat is retained, the emission of radiant heat when the carbon fiber heater is at a low temperature does not cause radiant heat without causing energy loss. By reflecting the emission of, the heating energy of the toilet seat can be obtained, and its efficiency can be increased.

  The temperature control that is not in the seating state of the toilet seat of the heating toilet seat device according to claim 8 is such that the carbon fiber heater is set to a low temperature with little radiant heat, directly or indirectly heating the seating side upper inner surface, Since it is possible to transfer heat to the seated human body part, in addition to the effect described in any one of claims 1 to 7, it is possible to perform heat insulation of only the toilet seat with high efficiency. And radiant heat energy loss can be minimized.

  The temperature control of the seating state of the toilet seat of the heating toilet seat device according to claim 9 is determined by one or more of the temperature of the toilet seat itself and the room temperature, and therefore any one of claims 1 to 8 In addition to the effect described above, the temperature control of the seating state of the toilet seat is performed so that the temperature of the toilet seat itself is not uncomfortable when seated, and thermal energy is also applied to the buttocks of a seated person. Since it is given by radiation, it is possible to perform warming with good responsiveness. When the temperature of the toilet seat itself can be maintained at a predetermined temperature, the heat dissipated is replenished. In the case of entering into temperature control depending on the room temperature, when the room temperature is lowered, the radiant energy can be raised to directly heat the buttocks so that the human body does not feel cold.

Next, the heating toilet seat apparatus of embodiment of this invention is demonstrated using figures. In the second and subsequent embodiments, since the same symbols or the same reference numerals as those in the first embodiment indicate the same or corresponding components as those in the first embodiment, detailed description thereof is omitted. Only the differences will be described.
[Embodiment 1]

  FIG. 1 is a side view of a heating toilet seat apparatus according to Embodiment 1 of the present invention, and FIG. 2 is a plan view of the same. FIG. 3 is a plan view of the toilet seat of the heating toilet seat device according to the first embodiment, and FIG. 4 is a side view of FIG. 5 is a cross-sectional view of the heating toilet seat device according to the first embodiment taken along the line AA shown in FIG.

  In FIG. 1 to FIG. 4, reference numeral 1 is a toilet bowl having a known form, and 2 is a heated toilet seat apparatus that is placed on the toilet bowl 1. 4 is a rear device storage portion of the human body local cleaning device 3, 4 a is an upper cover of the rear device storage portion 4, 4 b is a base member of the rear device storage portion 4, 5 is a toilet lid, 20 is a toilet seat, The storage unit 4 is rotatably attached.

  In FIG. 3, the base member 4 b of the rear device housing portion 4 includes an electric control board unit 7 including electric control constituting heater energization control means of the toilet seat 20 constituting the human body local washing device 3, hot water washing not shown. Nozzle 8, hot water supply system unit 9 for supplying hot water to the hot water cleaning nozzle 8, a proximity switch having a detecting means such as a toilet seat human body detection sensor 56 comprising an infrared detection sensor or a pressure sensor, a toilet seat temperature sensor 55, and other hot water cleaning related A seating detection means 10 comprising a switch 57 is provided. Except for the heater energization control means, all have a known configuration, and thus detailed description thereof is omitted.

In FIG. 5, the toilet seat 20 has a toilet seat housing 21 that is generally hollow. The toilet seat housing 21 includes a housing upper portion 21a and a housing lower portion 21b, and mechanically and integrally joins both. The housing upper part 21a is made of a polypropylene resin, an ABS resin, or the like, and at least the upper side thereof is formed of a material having far-infrared transmittance. Here, “at least” means that although a material having infrared transparency is preferable, it is not always necessary to use a transparent member from the viewpoint of design, and it is only necessary to have far infrared transparency. The casing lower part 21b may have a heat insulating property, and does not ask for the far infrared transmission. Therefore, the thickness and strength of the upper housing portion 21a and the lower housing portion 21b are determined by the mechanical strength.
In general, the housing upper portion 21a and the housing lower portion 21b are formed of the same material.

  A carbon fiber heater 22 having a covering material made of a material having far-infrared transmissivity such as polypropylene resin or ABS resin is disposed on the inner upper side of the upper portion 21a of the toilet seat housing 21. The carbon fiber heater 22 is bonded or attached to the inner upper surface of the housing upper portion 21a with a predetermined interval. A reflective member 23 such as an aluminum foil tape is joined to the lower surface. The reflecting member 23 is joined by a synthetic adhesive between the carbon fiber heater 22 and the inner upper surface of the housing upper part 21a. This synthetic adhesive is made of a material having far-infrared transparency. However, if the casing upper portion 21a of the toilet seat 20 is heated due to heat transfer characteristics, it can be made of a material that absorbs far-infrared transmittance.

  In the heated toilet seat device 2 according to the first embodiment, the toilet seat 20 is placed on the toilet 1 and has a housing upper portion 21a in which at least an upper portion thereof is formed only or entirely from a material having far-infrared transmittance. The carbon fiber heater 22 disposed on the upper side of the upper portion 21a of the toilet seat 20 and the aluminum foil tape disposed on the lower portion of the carbon fiber heater 22 to reflect far infrared rays generated by the carbon fiber heater 22 The reflecting member 23 is made of.

The heating toilet seat device of the first embodiment configured as described above can operate as follows.
The carbon fiber heater 22 disposed on the upper side of the toilet seat 20 is a case upper portion 21a side, that is, an upper portion of the toilet seat housing 21 that is formed on the toilet bowl 1 and is made of a material having far-infrared transmittance. Radiated from the side. Further, the downward radiation from the carbon fiber heater 22 is reflected by the aluminum foil tape as the reflecting member 23 and is radiated from the housing upper portion 21a side of the toilet seat housing 21. At this time, the carbon fiber heater 22 disposed on the upper side of the toilet seat 20 can directly apply radiant heat to the buttocks of the human body seated on the toilet seat 20, and the temperature increase sensed by the buttocks of the human body increases the heat capacity of the toilet seat 20. Since it is not influenced, it is possible to improve the response of the toilet seat temperature control start from the detection of the human body. And since the responsiveness at the start of toilet seat temperature control can be improved, the temperature of the toilet seat 20 can be increased, and as a result, the energy consumption required to always keep the toilet seat 20 warm can be reduced. . The downward radiation from the carbon fiber heater 22 is reflected by the reflecting member 23, eliminates the energy loss that heats the toilet 1, and emits radiant heat only to the upper portion 21a of the toilet seat housing 21 or only to the upper portion thereof. Because of this, the efficiency can be increased.

FIG. 6 is a control circuit diagram for controlling the temperature of the toilet seat of the heating toilet seat device according to the first embodiment of the present invention.
In FIG. 6, the microcomputer 50 includes an indoor human body detection sensor 53 including an infrared detection sensor or an ultrasonic sensor for detecting the presence of a person in a private room (toilet), and a temperature sensor for detecting the indoor temperature of the private room. A room temperature sensor 54, a toilet seat temperature sensor 55 for measuring the temperature of the toilet seat 20, an infrared detection sensor for detecting the seating state of the toilet seat 20, or a human body detection sensor 56 including a pressure sensor, and other hot water washing related switches 57 are connected. ing.
Further, as the output, the driver 51 is driven and controlled, and the driver 51 performs on / off control, that is, PWM control, of the current of the carbon fiber heater 22. The temperature control map 52 is configured to turn off the current of the carbon fiber heater 22 based on the output of the room temperature sensor for detecting the room temperature and / or the toilet seat temperature sensor 55 for detecting the temperature of the upper surface of the housing upper part 21a of the toilet seat 20. The time is set, and the PWM control mode is changed using the temperature of the toilet seat 20, the temperature of the room, and the usage time as parameters.

FIG. 7 is a flowchart for controlling the temperature of the toilet seat of the heating toilet seat device according to the first embodiment of the present invention.
The routine shown in FIG. 7 is called during execution of another main program. When this routine is called, first, the presence of a person in the room of the private room is detected by the indoor human body detection sensor 53 in step S1, and when the presence of a human body is not detected in the room, the memory S described later is cleared in step S2. In step S3, it is determined whether or not M minutes have elapsed since the previous process. If not, it is not necessary to check the temperature of the toilet seat 20, and the routine is exited. If it is determined in step S3 that M minutes have passed since the previous process, the temperature T ° C. of the toilet seat 20 is detected in step S4, and the temperature T ° C. of the toilet seat 20 is less than a predetermined threshold temperature T _H ° C in step S5. If the temperature T ° C of the toilet seat 20 is equal to or higher than a predetermined threshold temperature T _H ° C, it means that the temperature T ° C of the toilet seat 20 is equal to or higher than the threshold temperature T _H ° C. To do. However, when the temperature T ° C of the toilet seat 20 is lower than the predetermined threshold temperature T _H ° C in step S5, the temperature T ° C of the toilet seat 20 is set to the threshold temperature in step S6 in order to set the temperature T of the toilet seat 20 to the threshold temperature T _H ° C. The ON time T _ON of the current of the carbon fiber heater 22 necessary for setting to T _H ° C is determined, and a predetermined energized state is output for the _ON time T _ON in Step S7 and Step S8. If it is determined in step S8 that the on-time T _ON has elapsed, the output is shut off in step S9, and this routine is exited.

  In step S1, the presence of a person in the room of the private room is detected. When the presence of a human body is detected in the room, the room temperature t ° C is measured in step S10, and the temperature T ° C of the toilet seat 20 is measured in step S11. To do. Then, in step S12, a PWM signal mode indicating how much radiant energy should be supplied as an initial value to the seated person's buttocks based on the room temperature t ° C and the temperature T ° C of the toilet seat 20 from the temperature control map of the memory Select. That is, the on-time and off-time of the current of the carbon fiber heater 22 are determined and output in step S13 in a predetermined PWM control mode. The output continues for a predetermined time S seconds monitored in step S14. When the predetermined time S seconds elapses, the predetermined time S seconds to be monitored is added to the storage of the memory S in step S15, and the toilet seat human body detection sensor detects whether the human body's buttocks are on the toilet seat 20 in step S16. 56, the routine from step S11 to step S16 is repeated, and when it is no longer possible to detect the presence of the human body in the toilet seat 20 in step S16, the output is shut off in step S17. Leave this routine.

Note that the temperature control map used in step S6 of the present embodiment is intended to heat the temperature T ° C. of the toilet seat 20 to the threshold temperature T _H ° C. Therefore, a predetermined temperature range from the threshold temperature T _H ° C. When the person is seated on the toilet seat 20, it can be heated quickly so as not to feel uncomfortable when seated.
In particular, in the temperature control routine of the toilet seat 20, by reducing the current value of the carbon fiber heater 22 and generating heat while keeping the temperature of the carbon fiber heater 22 low, heat transfer efficiency by heat conduction outside the far-infrared rays is achieved. Can be raised.

  The temperature control map used in step S12 of the present embodiment is based on the indoor temperature t ° C. and the temperature T ° C. of the toilet seat 20 so that a person does not feel uncomfortable when sitting on the toilet seat 20. It enables rapid heating with far infrared rays. At this time, in this embodiment, the carbon fiber heater 22 is on / off controlled by PWM control. However, when the present invention is implemented, the present invention is not limited to the on / off control, and can be a current control for increasing / decreasing the current, or can be a signal obtained by smoothing the PWM control signal. You can also

Furthermore, since the indoor temperature t ° C becomes seasonal information and the temperature T ° C of the toilet seat 20 becomes usage frequency or time information, only one of the indoor temperature t ° C and the temperature T ° C of the toilet seat 20 can be obtained from the carbon fiber heater 22. Far-infrared radiation can also be set.
[Embodiment 2]

FIG. 8 is a cross-sectional view of the heating toilet seat device according to the second embodiment, corresponding to a cross-sectional view taken along line AA shown in FIG.
The difference from the first embodiment is that the housing upper part 21a is made of polypropylene resin, ABS resin, or the like, and at least the upper part is formed of a material having far-infrared transmittance. However, a black body layer 24 in which a black body such as carbon is partially applied is provided inside the housing upper portion 21a. This black body layer 24 absorbs far-infrared rays radiated from the carbon fiber heater 22 and raises its own temperature. This heat is thermally conducted from the inner surface side to the outer surface side of the housing upper portion 21a. The buttocks of the human body can be heated by the temperature of the toilet seat housing 21.

  Further, the black body layer 24 applied to the inside of the housing upper portion 21a is formed partially or entirely, and by adjusting the thickness thereof, the black body layer 24 formed partially or entirely is At least a part of the external infrared rays is transmitted. Therefore, if the far-infrared rays are only radiated from the carbon fiber heater 22, a part of the far-infrared rays can be absorbed, and the buttock of the human body can be heated by the temperature of the toilet seat housing 21. The remainder of the far-infrared rays is formed from a material having far-infrared transparency on the upper side of the upper portion 21a of the casing, so that the buttock of the human body can be directly heated by the radiation energy.

That is, in the second embodiment, the heat transfer method includes radiation and heat conduction, and both are actively used. Therefore, the black body layer 24 can be replaced with a synthetic resin that absorbs infrared rays or far infrared rays to generate heat and transfers the heat to the toilet seat 20 by conduction.
[Embodiment 3]

9 is a cross-sectional view corresponding to the AA cross-sectional view of the heating toilet seat device according to the third embodiment, taken along line AA shown in FIG.
The difference from the first embodiment is that the housing upper part 21a is made of polypropylene resin, ABS resin, or the like, and at least the upper part is formed of a material having far-infrared transmittance. A glass fiber 25 that blocks heat conduction is partially or wholly joined to the inside of the housing upper part 21a, and a carbon fiber heater 22 is disposed below the glass fiber 25. Since the glass fiber 25 has a function of blocking heat conduction, only the far-infrared radiation radiated from the carbon fiber heater 22 is radiated from the inner surface side to the outer surface side of the housing upper portion 21a, and the radiant energy directly radiates the buttocks of the human body. Can be warmed.

  Moreover, the glass fiber 25 arrange | positioned inside the housing | casing upper part 21a interrupts | blocks the heat conduction from the carbon fiber heater 22 to the toilet seat housing | casing 21, and permeate | transmits only a far infrared ray or infrared rays. Therefore, if the far-infrared rays are only radiated from the carbon fiber heater 22, the far-infrared rays are directly formed by the radiation energy because the upper side of the housing upper portion 21a is formed of a material having far-infrared transparency. Can heat the buttocks of the human body.

  In the third embodiment, the toilet lid 30 that opens and closes the upper surface of the toilet seat 20 has a design surface layer 31 made of a known synthetic resin, and nickel, aluminum, or the like is formed on the lower surface of the reflector 32 by sputtering. As a result, a metal thin film is formed. The metal thin film as the reflector 32 reflects far infrared rays radiated from the upper side of the upper portion 21a of the casing. The far infrared rays radiated from the carbon fiber heater 22 are consumed by the toilet lid 30 or the toilet lid. 30 so as not to pass through. Usually, the reflector 32 is formed on the lower surface of the toilet lid 30, but may be embedded in a synthetic resin constituting the toilet lid 30. The synthetic resin at this time is preferably a material having far-infrared transparency such as polypropylene resin or ABS resin. In particular, when aluminum or the like is adopted as the material of the reflector 32, it is preferable to insert it into a part of the synthetic resin.

  Thus, by forming the reflective film 32 on the lower surface of the design surface layer 31 of the toilet lid 30, far infrared rays radiated from the carbon fiber heater 22 are reflected by the toilet lid 30, and far infrared rays are transmitted to the toilet seat 20 side. The reflected far infrared rays are reflected again by the carbon fiber heater 22 side and the aluminum foil tape as the reflecting member 23, and the far infrared rays reflected repeatedly are reflected between the reflector 32 and the reflecting member 23. As a result, the housing upper part 21a of the toilet seat 20 absorbs the heat energy and heats the toilet seat 20.

That is, in the third embodiment, since the heat transfer method includes radiation and heat conduction, only one of the radiation is used. Therefore, instead of the glass fiber 25, infrared rays or far-infrared rays are absorbed to generate heat, and a synthetic resin that transmits the heat by conduction is not interposed, so that the heating control is led by radiant heat.
Further, if energy is consumed by repeating reflection between the reflector 32 and the reflecting member 23, at least the material only for radiation or heat conduction does not exist. Can be warmed.
[Embodiment 4]

FIG. 10 is a plan view showing an arrangement state of carbon fiber heaters in the toilet seat of the heating toilet seat device according to the fourth embodiment.
In FIG. 10, the carbon fiber heater 22 is a meandering carbon fiber so that a large amount of radiant heat energy is generated in a portion sensitive to the temperature of the hip and leg of the human body and a small amount is generated in a non-sensitive portion. The heater 22 is formed with coarse and dense thermal energy consisting of a coarse portion 22a and a dense portion 22b.
Note that the density due to the meandering can be in a direction perpendicular to the meandering of FIG. 10, or the carbon fiber heaters 22 can be connected in parallel so as to correspond to the diversion. Of course, when connected in parallel, the resistance becomes low and the amount of heat generation decreases, so it is necessary to decrease the wire diameter or increase the specific resistance accordingly.

As shown in FIG. 10, the carbon fiber heater 22 of the heating toilet seat device according to the above embodiment is arranged on the inner surface of the seating-side casing upper portion 21 a of the toilet seat casing 21 in a layout in consideration of the heat reception of the human body. . Here, the layout in consideration of the heat reception of the human buttocks means that the amount of heat generation and the heat generation surface are changed depending on the position of the hips and legs of the human body and the position sensitive to temperature, and specifically, meandering or parallel This is done by disposing a carbon fiber heater 22 on the surface.
The carbon fiber heater 22 of the heating toilet seat device according to the above embodiment is arranged on the inner surface of the seat-side casing upper portion 21a of the toilet seat casing 21 in a layout that takes into consideration the heat reception of the human body part. Can be set, energy waste can be reduced, and a natural feeling of use can be obtained.

The toilet seat 20 of the heating toilet seat device of the above embodiment receives heat directly or indirectly from the carbon fiber heater 22 on the inner surface 21a of the seat side housing 21 of the toilet seat housing 21, and transfers heat to the human body by heat conduction. Heat transfer material is arranged.
Here, the heat of the carbon fiber heater 22 is directly transmitted to the upper part of the toilet seat housing 21 by direct heat conduction, and once the heat conduction of the carbon fiber heater 22 is interrupted, only the far-infrared radiation is received. Thus, heat can be transferred to the upper portion of the toilet seat casing 21 indirectly. The heat transfer material may be any material that conducts heat to the human body by heat conduction, and may be any material that has relatively good heat conduction. In addition, the material having relatively good heat conduction may be any material that is not thermally blocked. In particular, considering not only the problem of heat conduction from the carbon fiber heater 22 side but also the way of heat dissipation when the seated collar is used as a heat source, it is preferable that the material not have good heat conduction.

  As described above, the toilet seat 20 of the heating toilet seat device of the above embodiment receives the heat directly or indirectly from the carbon fiber heater 22 on the inner surface 21a of the seating side housing 21 of the toilet seat housing 21, and the human body part by the heat conduction. Since the heat transfer material for transferring heat is disposed on the toilet seat 20, the temperature of the toilet seat 20 itself can be set to a low temperature so that a person does not feel uncomfortable, and energy consumption required to keep the waste toilet seat 20 warm is reduced. be able to. In particular, since it is not necessary to raise the temperature of the toilet seat 20, the temperature gradient with the room temperature can be reduced, and energy loss can be reduced. Specifically, if the temperature of the toilet seat 20 is initially maintained at about 20 ° C., the human body can be rapidly transferred to the human body by the far-infrared radiant heat of the carbon fiber heater 22 and used without any sense of incongruity. State.

  The direct or indirect heat reception from the carbon fiber heater 22 of the toilet seat 20 of the heating toilet seat device according to the above-described embodiment is performed partially or entirely by a black body such as carbon that absorbs radiant heat on the seating side of the inner surface of the seating-side housing upper part 21a. The black body layer 24 is applied to prevent the transmission of radiant heat and converted into energy by heat conduction. The black body layer 24 rises in temperature by absorbing radiant heat, and heats the upper surface of the toilet seat housing 21 by heat conduction. Since the black body is partially applied, the human body is directly heated by the transmission of radiant heat from the part where the black body is not applied.

  Thus, the direct or indirect heat reception from the carbon fiber heater 22 of the toilet seat 20 of the heating toilet seat device of the above embodiment applies a black body that absorbs radiant heat to the seating side of the inner surface of the seating-side housing upper part 21a, The black body that absorbs radiant heat applied to the seating side of the inner surface of the seating side housing upper part 21a absorbs the radiant heat, and the black body itself rises in temperature because the transmission of radiant heat is blocked and converted into energy by heat conduction. The upper surface of the toilet seat 20 is heated by the heat conduction. Although the black body layer 24 may be partially formed, the human body can be directly heated by transmitting radiant heat from a portion where the black body layer 24 is not formed. Therefore, the toilet seat 20 can be maintained at an appropriate temperature.

  The direct and indirect heat reception from the carbon fiber heater 22 of the toilet seat 20 of the heating toilet seat device of the above embodiment has been described in the case where the black body layer 24 is formed. It is good also as a molding material of synthetic resin. However, since the synthetic resin becomes black at this time, it is desirable to have a multilayer structure of two or more layers.

As for the heat transfer material on the inner surface of the seat-side casing upper portion 21a of the toilet seat casing 21 of the heating toilet seat device of the above embodiment, the ratio of radiant heat and heat conduction can be determined by at least one of the material and thickness of the resin toilet seat. . Depending on the ratio of radiant heat and heat conduction, the temperature of the toilet seat 20 when a person is seated and the radiation temperature of far-infrared rays radiated directly to the human body are determined. Therefore, the ratio of radiant heat and heat conduction can be arbitrarily set according to at least one of the material and thickness of the toilet seat 20 made of synthetic resin.
As described above, the heat transfer material on the inner surface of the seating-side casing upper portion 21a of the toilet seat casing 21 of the heating toilet seat device of the above embodiment is determined by determining the ratio of radiant heat and heat conduction by the material and thickness of the resin toilet seat. Reasonably, the human body can be heated directly and rapidly, and the toilet seat 20 can also be heated to an appropriate temperature.

  The toilet lid 30 disposed in the upper part of the toilet seat 20 of the heating toilet seat device of the above embodiment is provided with a reflector 32 that reflects infrared rays on the back surface thereof, and the toilet seat 20 is heated by reflecting the emission of radiant heat. The toilet seat 20 can be kept warm. Here, the toilet lid 30 disposed on the upper part of the toilet seat 20 is provided with a member that reflects the emission of radiant heat on the lower surface or a part or all of the interior thereof, and the toilet seat 20 is kept warm by the reflected radiant heat. Therefore, it is desirable that the reflecting surface be as close to the lower surface of the toilet lid 30 as possible.

  As described above, the toilet lid 30 disposed in the upper part of the toilet seat 20 of the heating toilet seat device of the above-described embodiment is provided with the reflector 32 that reflects infrared rays on the back surface thereof, and reflects the emission of radiant heat to reflect the toilet seat. 20 is heated, and the toilet seat 20 is kept warm, so that the release of the radiant heat when the carbon fiber heater 22 is at a low temperature is reflected without reflecting the radiant heat, thereby heating the toilet seat 20. It can be energy and its efficiency can be increased.

In the toilet seat 20 of the heating toilet seat device of the above embodiment, the ratio of radiant heat and heat conduction and the total amount of energy discharged outside the toilet seat 20 can be determined by one or more of the material and thickness of the toilet seat 20 made of synthetic resin. . Here, the temperature of the toilet seat 20 when a person is seated and the temperature directly emitted to the human body are determined by the ratio of radiant heat and heat conduction. And the ratio of radiant heat and heat conduction is arbitrarily set by at least one or more of the material and thickness of the toilet seat 20 made of synthetic resin, and the total amount can be determined, so that the user who sits for a long time also feels uncomfortable. Can form no use condition.
Thus, the toilet seat of the heating toilet seat device of the above embodiment can determine the ratio of radiant heat and heat conduction and the total amount of energy discharged outside the toilet seat 20 by the material and thickness of the toilet seat 20 made of synthetic resin. Even if a person who sits down sits for a long time, a natural sitting state can be continued.

  The temperature control that is not in the seating state of the toilet seat 20 of the heating toilet seat device of the above-described embodiment is to directly or indirectly heat the inner surface of the seat-side casing upper portion 21a by setting the carbon fiber heater 22 to a low temperature with little radiant heat, It is possible to transfer heat to the human buttock seated by heat conduction. In the temperature control when the toilet seat 20 is not in the seated state, the emission of far infrared rays is generally reduced at a low temperature by setting the carbon fiber heater 22 to a low temperature. The temperature of itself can be heated so that there is no sense of incongruity even when seated.

  As described above, temperature control that is not in the seating state of the toilet seat 20 of the heating toilet seat device of the above-described embodiment is performed by setting the carbon fiber heater 22 to a low temperature with little radiant heat, and directly or indirectly the inner surface of the seating-side housing upper portion 21a. Since it is possible to heat and transmit heat to the human body part seated by the heat conduction, it is possible to keep only the toilet seat 20 warm with high efficiency and to minimize loss of radiant heat energy. it can.

  The temperature control of the seating state of the toilet seat 20 of the heating toilet seat device of the above embodiment can be determined by one or more of the temperature of the toilet seat 20 itself and the room temperature. The temperature control in the seated state of the toilet seat 20 is such that the temperature of the toilet seat 20 itself is not uncomfortable when seated, and heat energy is also given to the buttocks of a seated person by radiation. Here, when the temperature of the toilet seat 20 itself can be maintained at a predetermined temperature, the heat dissipated is supplemented. In the case where the temperature is determined by the room temperature, the radiant energy is increased. In this way, the buttocks are heated directly so that the human body does not feel cold. Of course, simultaneous use of both is most desirable.

  Thus, since the temperature control of the seating state of the toilet seat 20 of the heating toilet seat device of the above embodiment is determined by one or more of the temperature of the toilet seat 20 itself and the room temperature, the seating state of the toilet seat 20 is determined. In the temperature control, the temperature of the toilet seat 20 itself is set to a temperature that does not cause a sense of incongruity, and heat energy is also given to the buttocks of a seated person by radiation, so that responsive heating is performed. Can do. When the temperature of the toilet seat 20 itself can be maintained at a predetermined temperature, the heat dissipated is supplemented. In the case of entering into temperature control depending on the room temperature, when the room temperature is lowered, the radiant energy can be raised to directly heat the buttocks so that the human body does not feel cold.

In the heating toilet seat device of the above-described embodiment, the case where the carbon fiber heater 22 is disposed on the toilet seat 20 has been described, but it can also be used for the hot water supply system unit 9 that supplies hot water to the hot water cleaning nozzle 8.
Further, since the carbon fiber heater 22 is a material having a high flexibility, it can be formed integrally with a synthetic resin molding for various uses, and can be widely used for heating and heating.

FIG. 1 is a side view of a heating toilet seat apparatus according to Embodiment 1 of the present invention, and FIG. 2 is a plan view of the same. FIG. 2 is a plan view of the heating toilet seat device according to the first embodiment of the present invention. FIG. 3 is a plan view of the toilet seat of the heating toilet seat device according to the first embodiment of the present invention. FIG. 4 is a side view of FIG. 5 is a cross-sectional view of the heating toilet seat device according to the first embodiment taken along the line AA shown in FIG. FIG. 6 is a control circuit diagram for controlling the temperature of the toilet seat of the heating toilet seat device according to the first embodiment of the present invention. FIG. 7 is a flowchart for controlling the temperature of the toilet seat of the heating toilet seat device according to the first embodiment of the present invention. FIG. 8 is a cross-sectional view of the heating toilet seat device according to the second embodiment, corresponding to a cross-sectional view taken along line AA shown in FIG. 9 is a cross-sectional view corresponding to the AA cross-sectional view of the heating toilet seat device according to the third embodiment, taken along line AA shown in FIG. FIG. 10 is a plan view showing an arrangement state of carbon fiber heaters in the toilet seat of the heating toilet seat device according to the fourth embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Toilet 20 Toilet seat 21 Toilet seat housing | casing 21a Case upper part 22 Carbon fiber heater 23 Reflective member 24 Black body layer 25 Glass fiber 50 Microcomputer 22a Coarse part 22b of a carbon fiber heater Dense part of a carbon fiber heater

Claims (9)

A toilet seat mounted on a toilet bowl, at least the upper side of which is formed from a material having far-infrared transparency;
A carbon fiber heater disposed on the upper side of the toilet seat;
A heating toilet seat device, comprising: a reflecting member disposed on a lower side of the carbon fiber heater and configured to reflect far infrared rays generated by the carbon fiber heater.   2. The heating toilet seat device according to claim 1, wherein the carbon fiber heater is disposed on a seating-side upper inner surface of the toilet seat housing in a layout that takes into account heat reception of a human body part.   The toilet seat is provided with a heat transfer material that receives heat directly or indirectly from the carbon fiber heater on the seating side upper inner surface of the toilet seat housing, and transfers heat to the human body by heat conduction. The heating toilet seat apparatus of Claim 1 or Claim 2.   Direct or indirect heat reception from the carbon fiber heater of the toilet seat is a partial application of a black body that absorbs radiant heat on the seating side of the upper inner surface of the toilet seat housing, and blocking the transmission of radiant heat by the black body, The heating toilet seat device according to any one of claims 1 to 3, wherein the heating toilet seat device is converted into energy by heat conduction.   The heating toilet seat device according to claim 3, wherein the heat transfer material on the seating side of the toilet seat housing has a ratio of radiant heat and heat conduction determined by at least one of a material and a thickness of the resin toilet seat.   In order to change the ratio of radiant heat and heat conduction to the heat transfer material on the seating side of the toilet seat housing, a heat insulating member is interposed between the seating side inner surface of the toilet seat and the carbon fiber heater. The heating toilet seat device according to claim 3.   The toilet lid disposed in the upper part of the toilet seat is provided with a reflector that reflects infrared rays on the lower surface side thereof, and the toilet seat is heated by reflecting the emission of radiant heat to keep the toilet seat warm. The heating toilet seat device according to any one of claims 1 to 6.   The temperature control not in the seating state of the toilet seat is such that the carbon fiber heater is set to a low temperature with little radiant heat, and the upper inner surface of the seating side is directly or indirectly heated, and the heat is transferred to the seated human body by the heat conduction. The heating toilet seat device according to any one of claims 1 to 7, characterized in that:   The heating toilet seat device according to any one of claims 1 to 8, wherein the temperature control of the seating state of the toilet seat is determined by at least one of a temperature of the toilet seat itself and a room temperature.

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