JP2017042384A - Heated toilet seat device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a heated toilet seat device which secures sufficient strength with respect to a load when being seated, while reducing heat capacity in a seat part, and capable of improving heat insulation performance with a simple structure.SOLUTION: A heated toilet seat device includes: a seat part 230 having a seating surface SF and a rear surface BF on the opposite side of the seating surface; a bottom part 240 which has an opposing surface FF facing the rear surface and in which a space surrounded by the rear surface and the opposing surface is provided between the rear surface and the opposing surface; a heating part 210 provided on the rear surface in the space; and a load support part 250 provided in the space and for supporting the seat part. The load support part includes: a first plate part 251 extending in a direction parallel with the rear surface, and for partitioning one part of the space vertically; and a second plate part 252 extending in the direction perpendicular to the opposing surface, and having a lower end 252a coming into contact with the opposing surface and an upper end 252b located further upward than the first plate part. Gaps are provided between the first plate part and the rear surface, and between the second plate part and the rear surface, respectively.SELECTED DRAWING: Figure 4

Description

  Aspects of the invention generally relate to a heated toilet seat apparatus.

  There is a heated toilet seat device that warms the seating surface of the toilet seat to an appropriate temperature so that the user does not feel uncomfortable when the user sits on the toilet seat. In the heating toilet seat device, a heating unit such as a heater is built in the toilet seat, and the seating surface is warmed to a necessary temperature by controlling the amount of current supplied to the heating unit by the control unit. Recently, in order to reduce power consumption, a so-called instantaneous heating toilet seat device is also known in which a user waits at a low temperature when not in use and warms a seating surface in a short time when in use.

  In the heating toilet seat device, in order to easily transmit heat, it is desired to make the seat portion thin and to reduce the heat capacity of the seat portion. However, if the seating portion is thin, the strength of the seating portion is reduced, and it becomes difficult to support the weight of the user. Therefore, it has been proposed to provide a holding portion that supports the back surface of the seating portion in the space inside the toilet seat (Patent Document 1). Thereby, even when the seat portion is thin and the heat capacity of the seat portion is reduced, deformation of the seat portion can be suppressed.

  Moreover, in the heating toilet seat apparatus, in order to suppress the heat | fever of a seating part escaping below, providing a heat insulating material in the space inside a toilet seat is performed. At this time, as described above, if the holding portion is provided in the toilet seat, it is difficult to dispose the heat insulating material. For this reason, in the heating toilet seat device, it is desired that the heat capacity of the seating portion is reduced, sufficient strength is secured against the load at the time of seating, and the heat insulation performance is improved with a simple configuration.

JP 2001-299645 A

  The present invention has been made based on recognition of such a problem, and while ensuring a sufficient strength against a load at the time of sitting while reducing the heat capacity of the seating portion, the heat insulation performance is improved with a simple configuration. An object of the present invention is to provide a heated toilet seat device.

  1st invention has a seating surface which has a seating surface and the back surface on the opposite side of the said seating surface, and the opposing surface facing the said back surface, Between the said back surface and the said opposing surface, the said back surface And a bottom part provided with a space surrounded by the facing surface, a heating part provided on the back surface in the space, and a load support part provided in the space and supporting the seating part. The load support portion extends in a direction parallel to the back surface, extends in a direction perpendicular to the facing surface, and abuts against the facing surface, and a first plate portion that vertically partitions a part of the space A second plate portion having a lower end and an upper end positioned above the first plate portion, and between the first plate portion and the back surface, and between the second plate portion and the back surface. The heating toilet seat device is characterized in that a gap is provided between each of the heating toilet seat devices.

  According to this heating toilet seat device, since the load support portion supports the seating portion, even when the seating portion is thin and the heat capacity is reduced, sufficient strength can be ensured against the load at the time of seating. And a load support part has the 1st board part extended in the direction parallel to the back surface of a seating part, and partitions a part of interior space up and down. Thereby, it is possible to easily dissipate heat in the internal space, and it is possible to suppress the downward heat radiation of the heating part. Therefore, it is not necessary to separately provide a heat insulating material or the like, and the heat insulating performance can be improved with a simple configuration.

  Further, by providing a gap between the first plate portion and the back surface of the load support portion and between the second plate portion and the back surface, the heat of the heating portion escapes downward via the load support portion. Can be suppressed.

  A second invention is the heating toilet seat device according to the first invention, wherein the load support portion further includes a third plate portion extending downward from an end portion of the first plate portion.

  According to this heating toilet seat device, convection of air in the internal space can be further suppressed, and heat can be more easily generated in the space. That is, the heat insulation performance can be further improved.

  A third invention is the heating toilet seat device according to the second invention, wherein a gap is provided between a lower end of the third plate portion and the facing surface.

  According to this heating toilet seat device, it is possible to suppress the heat of the heating portion from escaping downward via the third plate portion. Further, when both the lower end of the second plate portion and the lower end of the third plate portion are brought into contact with the opposing surface, for example, the lower end of the second plate portion floats from the opposing surface due to a dimensional error. There is a concern that If the lower end of the second plate part floats from the opposing surface, the lower end of the second plate part abuts against the opposing surface when seated, which causes noise. Therefore, as described above, by generating the lower end of the third plate portion away from the facing surface, it is possible to suppress the generation of abnormal noise during sitting.

  In a fourth aspect based on the third aspect, the bottom portion has a fourth plate portion extending upward from the facing surface, and the fourth plate portion is disposed close to the third plate portion, A heating toilet seat device having an upper end located above the lower end of the third plate portion.

  According to this heating toilet seat device, it is possible to suppress heat from escaping from the gap between the lower end of the third plate portion and the facing surface, and to further improve the heat insulation performance.

  According to a fifth invention, in any one of the first to fourth inventions, the second plate portion extends in the vertical direction and extends along an outer edge of the facing surface, and the second portion of the space. The heating toilet seat device is characterized in that the volume of the area inside the two plate portions is less than 50% of the volume of the space.

  According to this heating toilet seat device, it is possible to improve the heat insulation performance of the inner portion where the user's body who is seated easily contacts.

  According to a sixth invention, in any one of the first to fifth inventions, the second plate portion is configured so that the upper end abuts on the back surface of the seat portion bent downward, and the seat portion The heating unit has a cord-like heating element, and the heating element is disposed at a position not contacting the upper end of the second plate part on the back surface. It is.

  According to this heating toilet seat device, it is possible to prevent the heating element from being sandwiched between the back surface and the upper end of the second plate portion and being disconnected when seated.

  According to the aspect of the present invention, there is provided a heating toilet seat device capable of ensuring sufficient strength against the load at the time of sitting while reducing the heat capacity of the seating portion and improving the heat insulating performance with a simple configuration. The

It is a perspective view showing the toilet apparatus provided with the heating toilet seat apparatus concerning embodiment. It is a block diagram showing the control structure of the heating toilet seat apparatus concerning embodiment. It is a disassembled perspective view showing the toilet seat concerning embodiment. It is a fragmentary sectional view showing a part of toilet seat concerning an embodiment. It is a top view showing the heating part concerning an embodiment. It is a fragmentary sectional view showing a part of heating part concerning an embodiment. It is a graph showing an example of the characteristic of the heating toilet seat device concerning an embodiment. It is a fragmentary sectional view showing the modification of the toilet seat concerning an embodiment. It is a fragmentary sectional view showing the modification of the toilet seat concerning an embodiment.

Hereinafter, embodiments will be described with reference to the drawings. In addition, in each drawing, the same code | symbol is attached | subjected to the same component and detailed description is abbreviate | omitted suitably.
Drawing 1 is a perspective view showing a toilet device provided with a heating toilet seat device concerning an embodiment.
FIG. 2 is a block diagram illustrating a control configuration of the heating toilet seat device according to the embodiment.

  The toilet apparatus 10 shown in FIG. 1 includes a Western-style seat toilet (hereinafter simply referred to as “toilet bowl”) 800 and a heated toilet seat apparatus 100 provided thereon. The heating toilet seat device 100 includes a toilet seat 200, a toilet lid 300, and a heating toilet seat function unit 400. The toilet lid 300 is provided in the heating toilet seat device 100 as necessary, and can be omitted. The toilet seat 200 and the toilet lid 300 are pivotally supported by the heating toilet seat function unit 400 so as to be freely opened and closed.

  Here, in the specification of the present application, the upper side is “upward” when viewed from the user sitting on the toilet seat 200, and the lower side is “downward” when viewed from the user sitting on the toilet seat 200. Further, the front is viewed as “front” when viewed from the user sitting on the toilet seat 200 with his back to the opened toilet lid 300, and the rear is defined as “rear” when viewed from the user sitting on the toilet seat 200. Further, the right side is “right side” as viewed from the user standing in front of the toilet bowl 800 and the left side is “left side” as viewed from the user standing in front of the toilet bowl 800.

  The toilet bowl 800 has a bowl portion 801. The bowl portion 801 has a concave shape that is recessed downward. The toilet bowl 800 receives excrement such as urine and feces of the user in the bowl portion 801.

  The toilet seat 200 has an opening 200 a that exposes the bowl 801. The toilet seat 200 is provided on the toilet bowl 800 so as to surround the outer edge of the bowl portion 801, and exposes the bowl portion 801 through the opening 200a. Thereby, the user can perform excretion into the bowl portion 801 while sitting on the toilet seat 200. In this example, a so-called O-type toilet seat 200 having a through-hole-shaped opening 200a is shown. The toilet seat 200 is not limited to the O shape, and may be a U shape. The opening 200a is not limited to a through hole shape, and may be a notch shape. The shape of the toilet seat 200 in a use state (a state in which a user can be seated) viewed from above is an annular shape or a U-shape.

  As illustrated in FIG. 2, the toilet seat 200 includes a heating unit 210 and a temperature detection sensor 220. The heating unit 210 is provided inside the toilet seat 200. The heating unit 210 heats the toilet seat 200 from the inside by generating heat in response to energization. The heating unit 210 is a so-called heater. For the heating unit 210, for example, resistance heating means, induction heating means for heating by electromagnetic induction, or the like is used.

  The temperature detection sensor 220 detects the temperature of, for example, a seating surface (surface on which a user's butt is in contact) SF of the toilet seat 200. In the embodiment, the temperature of the toilet seat 200 refers to the temperature of the seating surface SF. The temperature of the seating surface SF may be the temperature of the seating surface SF calculated from the detected temperature in addition to the temperature detected by the temperature detection sensor 220.

  The heating toilet seat function unit 400 includes a control unit 410. The control unit 410 controls the energization amount to the heating unit 210 based on the detection signal from the temperature detection sensor 220. The heated toilet seat function unit 400 further includes, for example, a seating detection sensor 420, a human body detection sensor 430, an entrance detection sensor 440, and a room temperature detection sensor 460. The seating detection sensor 420 detects the seating of the user on the toilet seat 200. The human body detection sensor 430 detects a user in front of the toilet seat 200. The entrance detection sensor 440 detects the user entering the toilet room. The room temperature detection sensor 460 detects the room temperature of the toilet room.

  The seating detection sensor 420 can detect a human body existing above the toilet seat 200 immediately before the user is seated on the toilet seat 200 or a user seated on the toilet seat 200. The seating detection sensor 420 may detect not only a user seated on the toilet seat 200 but also a user existing above the toilet seat 200. As such a seating detection sensor 420, for example, an infrared light projecting / receiving type distance measuring sensor can be used. The seating detection sensor 420 may be a switch that is turned ON / OFF by a load when the user is seated. When the seating detection sensor 420 detects the seating of the user, the seating detection sensor 420 outputs a signal SG3 indicating that the seating has been detected to the control unit 410.

  The human body detection sensor 430 can detect a user in front of the toilet bowl 800, that is, a user present in a position spaced forward from the toilet seat 200. That is, the human body detection sensor 430 can detect a user who enters the toilet room and approaches the toilet seat 200. As such a human body detection sensor 430, for example, an infrared light projecting / receiving distance measuring sensor can be used. When detecting the human body, the human body detection sensor 430 outputs a signal SG1 indicating that the human body has been detected to the control unit 410.

  The entrance detection sensor 440 can detect a user immediately after opening a toilet room door or entering a toilet room and a user existing in front of the door. That is, the entrance detection sensor 440 can detect not only the user who entered the toilet room, but also the user before entering the toilet room, that is, the user existing in front of the door outside the toilet room.

  As such a room entry detection sensor 440, a pyroelectric sensor, a microwave sensor such as a Doppler sensor, or the like can be used. When using a sensor that uses the microwave Doppler effect or a sensor that detects the object to be detected based on the amplitude (intensity) of the microwave transmitted and reflected, the user's The presence can be detected. That is, the user before entering the toilet room can be detected. When detecting the human body, the room entry detection sensor 440 outputs a signal SG2 indicating that the human body has been detected to the control unit 410.

  The room temperature detection sensor 460 detects the room temperature of the toilet room and outputs a signal SG4 including room temperature information to the control unit 410.

  In the toilet apparatus 10 shown in FIG. 1, a recessed portion 441 is formed on the upper surface of the heating toilet seat function unit 400, and an entrance detection sensor 440 and a room temperature detection sensor 460 are provided so as to be partially embedded in the recessed portion 441. It has been.

  When the toilet lid 300 is closed, the room entry detection sensor 440 detects the user's room entry through the transmission window 301 provided near the base. In addition, the seating detection sensor 420 and the human body detection sensor 430 are provided in a central portion in front of the heating toilet seat function unit 400. However, the installation forms of the seating detection sensor 420, the human body detection sensor 430, and the entrance detection sensor 440 are not limited to these, and can be changed as appropriate.

  The room temperature detection sensor 460 is not limited to the inside of the heating toilet seat function unit 400, and may be provided inside the operation unit 600 such as a remote controller provided separately from the heating toilet seat function unit 400, for example. . The room temperature detection sensor 460 only needs to detect the room temperature of the toilet room.

  The heating toilet seat function unit 400 further includes a toilet lid driving device 450 that opens and closes the toilet lid 300. For example, the toilet lid driving device 450 is installed in the vicinity of a position where the toilet lid 300 is pivotally supported with respect to the heating toilet seat function unit 400, and opens and closes the toilet lid 300 according to a signal from the control unit 410.

  The opening / closing operation of the toilet lid 300 may be operated by an operation unit 600 provided separately from the heating toilet seat function unit 400. In this case, the control unit 410 controls the driving of the toilet lid driving device 450 based on the signal transmitted from the operation unit 600, and opens and closes the toilet lid 300.

  Moreover, the heating toilet seat function part 400 may add the function part as a sanitary washing apparatus. That is, the heating toilet seat function unit 400 may appropriately include a sanitary washing function unit having a water discharge nozzle (not shown) that ejects water (hot water or cold water) toward the “butt” of the user sitting on the toilet seat 200. .

  Further, the heating toilet seat function unit 400 includes a “warm air drying function”, a “deodorizing unit”, an “indoor heating unit”, etc., which blow and dry warm air toward the “butt” of the user sitting on the toilet seat 200 These various mechanisms may be provided as appropriate. At this time, an exhaust port 443 from the deodorizing unit and an exhaust port 445 from the indoor heating unit are appropriately provided on the side surface of the heating toilet seat function unit 400. However, the sanitary washing function unit and other additional function units are not necessarily provided.

  The toilet bowl 800 and the heated toilet seat device 100 are controlled by a user instruction received by the operation unit 600. The operation unit 600 includes an opening / closing button for the toilet lid 300, a washing button for flowing washing water to the toilet bowl 800, a button for setting and changing the operation mode, and various settings (setting temperature, standby temperature, water temperature, A button BP for starting water discharge, stopping water discharge, starting water discharge, starting and stopping the drying function, and the like is provided. In addition, the operation unit 600 may be provided with a display unit DP that displays setting contents and operation status, and an output unit OP such as a speaker that notifies the state.

  Control unit 410 stops energization to heating unit 210 or reduces the energization amount when not in use to set the seating surface SF of toilet seat 200 to a lower temperature, and increases the energization amount to heating unit 210 during use. By rapidly heating the seating surface SF of the toilet seat 200, an immediate warming operation mode in which the temperature of the seating surface SF is raised to an appropriate temperature can be executed.

  The control unit 410 detects the user based on the detection result of the human body detection sensor 430 in a standby state in which the energization amount to the heating unit 210 is suppressed. When the human body detection sensor 430 detects a user, the control unit 410 increases the amount of current supplied to the heating unit 210 and heats the temperature of the seating surface SF of the toilet seat 200 to a preset temperature set in advance by the operation unit 600 or the like. .

  At this time, the time from when the user is detected by the human body detection sensor 430 until the user is seated on the toilet seat 200 is obtained in advance by statistics. The controller 410 completes the heating to the set temperature in a time shorter than this time. Thereby, it can suppress that a user sits on the toilet seat 200 with the temperature of the seating surface SF being low. It is possible to suppress the user from experiencing rapid heating from the temperature in the standby state to the set temperature.

  For example, the control unit 410 determines whether or not the temperature of the seating surface SF has increased to the set temperature based on the detection result of the temperature detection sensor 220. When the controller 410 confirms that the temperature has risen to the set temperature, the controller 410 controls the energization amount to the heating unit 210 so that the temperature of the seating surface SF becomes substantially constant at the set temperature. That is, the control unit 410 performs control to keep the temperature of the seating surface SF at the set temperature after raising the temperature of the seating surface SF to the set temperature. Thereby, the toilet seat 200 having a comfortable temperature can be provided to the user.

  Further, for example, the control unit 410 detects that the user has left the toilet seat 200 based on the detection result of the seating detection sensor 420, and in response to this detection, the controller 410 waits for the temperature of the seating surface SF from the set temperature. Reduce to the temperature of.

  The control unit 410 is not limited to the immediate warming operation mode, and may perform a warming operation mode in which, for example, the temperature of the seating surface SF is always kept at a set temperature. For example, the controller 410 may be configured to switch between a plurality of operation modes such as an immediate warm operation mode and a heat retention operation mode.

FIG. 3 is an exploded perspective view illustrating the toilet seat according to the embodiment.
FIG. 4 is a partial cross-sectional view illustrating a part of the toilet seat according to the embodiment.
4 shows a cross section taken along line A1-A2 of FIG.
As illustrated in FIGS. 3 and 4, the toilet seat 200 includes a seating portion 230, a bottom portion 240, and a load support portion 250.

  The seating part 230 has a seating surface SF and a back surface BF on the opposite side of the seating surface SF. The bottom part 240 has the opposing surface FF which opposes the back surface BF. A space surrounded by the back surface BF and the counter surface FF is provided between the back surface BF and the counter surface FF. That is, the bottom portion 240 covers the back surface BF with the facing surface FF, thereby forming a space (hereinafter referred to as an internal space SP) surrounded by the back surface BF and the facing surface FF. In other words, the seating portion 230 and the bottom portion 240 constitute a toilet seat body. The toilet seat body has a seating portion 230 and a bottom portion 240, and has an internal space SP surrounded by a back surface BF and a facing surface FF. The load support portion 250 is provided in the internal space SP and supports the seating portion 230.

  As described above, the toilet seat 200 includes the heating unit 210. The heating unit 210 is provided on the back surface BF of the seating unit 230 in the internal space SP. The heating unit 210 has, for example, a sheet shape and is attached to the back surface BF. For example, the heating unit 210 is provided on substantially the entire back surface BF, and warms the entire seating unit 230 from the inside.

  Each of the seating portion 230, the bottom portion 240, and the load support portion 250 has openings 230a, 240a, and 250a. The shape of the seating portion 230 and the bottom portion 240 viewed from above is substantially the same as the shape of the toilet seat 200 viewed from above. That is, the shape of the seating portion 230 and the bottom portion 240 viewed from above is an annular shape or a U shape. The opening 200 a of the toilet seat 200 is formed by the opening 230 a of the seating portion 230 and the opening 240 a of the bottom portion 240.

  In this example, the shape of the load support portion 250 as viewed from above is annular, like the seating portion 230 and the bottom portion 240. For example, the load support portion 250 may be formed in a U shape with respect to the annular seat portion 230 and the bottom portion 240. Further, in this example, one load support portion 250 that is continuous along the outer edges of the seating portion 230 and the bottom portion 240 is provided. Without being limited to this, the load support portion 250 may be divided into a plurality of parts. In other words, the toilet seat 200 may have a plurality of load support portions 250.

  The seating portion 230 has an open box shape that opens downward. The cross-sectional shape of the seating portion 230 is a substantially arc shape. The seating portion 230 has a plate shape curved in an arc shape. The bottom part 240 closes the opening end of the seating part 230. Thereby, the interior space SP is formed by the seating portion 230 and the bottom portion 240. On the contrary, the bottom 240 may be formed in an open box shape opened upward, and the opening end of the bottom 240 may be closed by the seating portion 230. That is, at least one of the seating part 230 and the bottom part 240 is formed in an open box shape, and the other end is closed. As a result, the internal space SP can be formed.

  The seating portion 230 and the bottom portion 240 are joined to each other by, for example, vibration welding. For the seating portion 230 and the bottom portion 240, for example, thermoplastic resin such as polypropylene (PP), ABS (copolymer synthetic resin of acrylonitrile, butadiene and styrene), or polycarbonate (PC) is used. Thereby, vibration welding of the seating part 230 and the bottom part 240 becomes possible. For example, PP is used for the seating portion 230 and the bottom portion 240. Thereby, the manufacturing cost of the toilet seat 200 can be suppressed. Moreover, the material of the bottom part 240 is the same as the material of the seating part 230, for example. Thereby, the seating part 230 and the bottom part 240 can be easily joined by vibration welding. The material of the bottom portion 240 may be different from the material of the seating portion 230.

  The joining of the seating portion 230 and the bottom portion 240 is not limited to vibration welding, but may be another welding method, or adhesion using an adhesive. Or you may attach using holding members, such as a screw, and you may attach by engaging an engaging claw etc. mutually. However, when the bottom portion 240 is attached to the seating portion 230 using screws, engaging claws, etc., the joint surface between the seating portion 230 and the bottom portion 240 is filled with a sealing material or the like, and water or the like does not enter the internal space SP. It is preferable to do so. The internal space SP is preferably sealed.

  The seating portion 230 includes, for example, an annular or U-shaped upper plate portion 231, an outer edge portion 232 that extends downward from the outer edge of the upper plate portion 231, and an inner edge portion 233 that extends downward from the inner edge of the upper plate portion 231. Have.

  The thickness t1 of the upper plate portion 231 is, for example, 1 mm or more and 3 mm or less. More preferably, it is 1.5 mm. Accordingly, it is possible to obtain an appropriate strength in the upper plate portion 231, reduce the heat capacity of the upper plate portion 231, and suppress power consumption accompanying heating of the seating portion 230. In particular, when the seating section 230 is heated in the immediate warming operation mode, by setting the thickness t1 within the above range, the power consumption during rapid heating is suppressed and the time required for temperature rise is shortened. can do.

  The thickness t2 of the outer edge portion 232 is, for example, not less than 4 mm and not more than 8 mm. A thickness t3 of the inner edge portion 233 is, for example, not less than 4 mm and not more than 8 mm. The thicknesses t2 and t3 are more preferably 6 mm. The thickness t2 of the outer edge portion 232 and the thickness t3 of the inner edge portion 233 are set to be thicker than the thickness t1 of the upper plate portion 231. Thereby, for example, when the seating portion 230 and the bottom portion 240 are vibration welded, an appropriate joint surface can be obtained. The seating part 230 and the bottom part 240 can be joined appropriately. Further, by setting the thicknesses t2 and t3 in the above range, an increase in the heat capacity of the seating portion 230 can be suppressed.

  A plurality of attachment portions 240 b for attaching the load support portion 250 are provided on the facing surface FF of the bottom portion 240. Each attachment portion 240b is, for example, a substantially cylindrical boss protruding upward from the facing surface FF. Each attachment part 240b has a screw hole, for example.

  The load support portion 250 has a plurality of attached portions 250 b provided corresponding to the attachment portions 240 b of the bottom portion 240. Each attached portion 250b is, for example, a through hole for inserting a screw. The load support part 250 is attached to the bottom part 240 by, for example, placing it on the facing surface FF and screwing it from above via the attachment parts 240b and the attachment parts 250b.

  Thus, the load support part 250 is attached to the bottom part 240. Therefore, when performing vibration welding between the seating portion 230 and the bottom portion 240, the load support portion 250 moves integrally with the bottom portion 240. In addition, the attachment method of the load support part 250 is not restricted to screwing, and may be any method that can attach the load support part 250 to the bottom part 240.

  For the load support portion 250, for example, a resin material such as PP is used. The material of the load support portion 250 is substantially the same as the material of the bottom portion 240, for example. The material of the load support portion 250 may be different from the material of the bottom portion 240.

  The load support portion 250 includes a first plate portion 251 and a plurality of second plate portions 252. The first plate portion 251 extends in a direction parallel to the back surface BF of the seating portion 230, and partitions a part of the internal space SP up and down. Each second plate portion 252 extends in a direction perpendicular to the facing surface FF of the bottom portion 240. Each of the second plate portions 252 has a lower end 252a that contacts the facing surface FF of the bottom portion 240 and an upper end 252b that is positioned above the first plate portion 251. The upper end 252b of each second plate portion 252 is disposed close to the back surface BF. Each second plate portion 252 partitions, for example, a part of the internal space SP in the horizontal direction.

  A gap is provided between the first plate portion 251 and the back surface BF. Similarly, a gap is provided between each second plate portion 252 and the back surface BF. That is, the 1st board part 251 and each 2nd board part 252 are spaced apart from the back surface BF. The load support part 250 is separated from the back surface BF.

  As described above, a resin material such as a thermoplastic resin is used for the seating portion 230. The seating portion 230 has elasticity and bends downward when the user is seated. Each of the second plate portions 252 abuts the upper end 252b against the back surface BF of the seating portion 230 bent downward. As described above, the load support portion 250 supports the seating portion 230 by the second plate portions 252.

  Here, in the present specification, “extending in the direction” is not limited to the case where it completely coincides with the direction, but includes the case where it has a component extending in the direction. That is, the 1st board part 251 should just have the component extended in the direction parallel to the back surface BF at least. The extending direction of the first plate portion 251 may be inclined with respect to the back surface BF. Each second plate portion 252 only needs to have a component extending in a direction perpendicular to at least the facing surface FF. The extending direction of each second plate portion 252 may be inclined with respect to the direction perpendicular to the facing surface FF. In addition, the extending direction of each second plate portion 252 may be different. In other words, each second plate portion 252 may be parallel or non-parallel.

  Further, in the present specification, “contact” is not limited to direct contact, but also includes mechanical contact via another member. For example, the lower end 252a of the second plate portion 252 may contact the facing surface FF via a sheet-like member (for example, a label) attached to the facing surface FF.

  The first plate portion 251 extends in a direction parallel to the back surface BF and extends along the outer edge of the facing surface FF. The first plate portion 251 is, for example, an annular shape that extends along the outer edge of the facing surface FF. The opening part 250a of the load support part 250 is formed by, for example, the inner edge of the first plate part 251.

  The load support part 250 includes, for example, two second plate parts 252 arranged in the width direction. Here, more specifically, the “width direction” refers to a direction extending along the outer edges of the seating portion 230 and the bottom portion 240 of the first plate portion 251 (a direction perpendicular to the paper surface in FIG. 4) and the vertical direction. It is a vertical direction (the left-right direction in FIG. 4).

  The two second plate portions 252 arranged in the width direction extend along the outer edge of the facing surface FF. Thereby, the internal space SP of the toilet seat 200 is divided into approximately three regions by these two second plate portions 252. That is, the internal space SP includes the first region R1 inside the second plate portion 252 located inside, the second region R2 between the two second plate portions 252 and the second plate portion located outside. And the third region R3 outside the region 252.

  The first region R1 is a region on the inner side of the second plate portion 252 located on the innermost side in the internal space SP. In other words, the first region R1 is the innermost region among the plurality of regions of the inner space SP divided by the plurality of second plate portions 252. The volume of the first region R1 is less than 50% of the volume of the entire internal space SP. In this example, the volume of the first region R1 is less than 30% of the total volume of the internal space SP. The volume of the first region R1 is smaller than the volume of the second region R2 and the volume of the third region R3. The volume of the first region R1 is the smallest among the plurality of regions of the internal space SP divided by the plurality of second plate portions 252. The volume of the inner area of the internal space SP is smaller than the volume of the outer area.

  The load support portion 250 further includes a third plate portion 253 that extends downward from the end portion of the first plate portion 251. The load support portion 250 includes, for example, a pair of third plate portions 253 provided at both ends in the width direction of the first plate portion 251. Both end portions in the width direction of the first plate portion 251 and the respective third plate portions 253 are arranged close to the back surface BF.

  The outer third plate portion 253 of the pair of third plate portions 253 faces a part of the outer edge portion 232 of the seating portion 230. The inner third plate portion 253 faces a part of the inner edge portion 233 of the seating portion 230. The outer third plate portion 253 faces a portion of the heating unit 210 that is attached to the outer edge portion 232. The inner third plate portion 253 faces a portion of the heating unit 210 that is attached to the inner edge 233.

  In addition, a gap is provided between the lower end 253 a of each third plate portion 253 and the facing surface FF of the bottom portion 240. In other words, each third plate portion 253 is separated from the facing surface FF.

  The bottom part 240 has the 4th board part 241 extended upwards from the opposing surface FF. The fourth plate portion 241 is disposed in the vicinity of the third plate portion 253. In this example, a pair of fourth plate portions 241 corresponding to each of the pair of third plate portions 253 is provided on the bottom portion 240. Each fourth plate portion 241 has an upper end 241a located above the lower end 253a of each third plate portion 253. The upper end 241a of the fourth plate part 241 is positioned above at least the lower end 253a of the third plate part 253 that is close thereto.

  Each 3rd board part 253 is provided in the load support part 250 as needed, and can be abbreviate | omitted. Similarly, each 4th board part 241 is provided in the bottom part 240 as needed, and can be abbreviate | omitted. For example, only one of the pair of third plate portions 253 may be provided on the load support portion 250. For example, you may provide the 3rd board part 253 only in the inner part with a large area facing the heating part 210. FIG.

  In this example, a pair of fourth plate portions 241 is provided between the pair of third plate portions 253. On the contrary, a pair of third plate portions 253 may be provided between the pair of fourth plate portions 241. For example, when the first plate portion 251 is U-shaped, the third plate portion 253 and the fourth plate portion 241 may be one continuous member along the edge of the first plate portion 251.

  The distance d1 in the width direction in the orthogonal cross section between the load support portion 250 and the outer edge portion 232 of the seating portion 230 is, for example, 1 mm or more and 5 mm or less. The distance d1 is a distance in the width direction between the third plate portion 253 and the outer edge portion 232, for example. When the third plate portion 253 is omitted, the distance d1 is the distance in the width direction between the end portion in the width direction of the first plate portion 251 and the outer edge portion 232. In other words, the distance d1 is the length of the gap provided between the first plate portion 251 and the back surface BF. By setting the distance d1 to 1 mm or more, for example, contact between the load support portion 250 and the seating portion 230 during vibration welding can be suppressed. By setting the distance d1 to 5 mm or less, for example, air convection in the internal space SP can be suppressed.

  The distance d2 in the width direction in the orthogonal cross section between the load support portion 250 and the inner edge portion 233 of the seating portion 230 is, for example, not less than 1 mm and not more than 5 mm, similarly to the distance d1.

  The vertical distance d3 between the upper end 252b of the second plate portion 252 and the back surface BF is, for example, not less than 1 mm and not more than 3 mm. In other words, the distance d3 is the length of the gap provided between the upper end 252b of the second plate portion 252 and the back surface BF. By setting the distance d3 to be 1 mm or more, for example, contact between the load support portion 250 and the seating portion 230 during vibration welding can be suppressed. By setting the distance d3 to 3 mm or less, for example, excessive bending of the seating portion 230 can be suppressed. For example, breakage of the seating portion 230 can be suppressed.

  The vertical distance d4 between the lower end 253a of the third plate portion 253 and the facing surface FF is, for example, not less than 1 mm and not more than 3 mm. In other words, the distance d4 is the length of the gap provided between the lower end 253a of the third plate portion 253 and the facing surface FF. By setting the distance d4 to be 1 mm or more, for example, contact between the lower end 253a of the third plate portion 253 and the facing surface FF can be suppressed. Moreover, it can suppress that the heat of the heating part 210 escapes downward via the 3rd board part 253. FIG. By setting the distance d4 to 3 mm or less, for example, convection of air in the internal space SP can be suppressed.

  The distance d5 in the width direction between the third plate portion 253 and the fourth plate portion 241 is, for example, 1 mm or more and 3 mm or less. By setting the distance d5 to be 1 mm or more, for example, the heat of the heating unit 210 can be prevented from escaping downward via the third plate portion 253 and the fourth plate portion 241. By setting the distance d5 to 3 mm or less, for example, air convection in the internal space SP can be suppressed.

FIG. 5 is a plan view illustrating a heating unit according to the embodiment.
FIG. 6 is a partial cross-sectional view illustrating a part of the heating unit according to the embodiment.
As illustrated in FIGS. 5 and 6, the heating unit 210 includes a first foil body 211, a second foil body 212, and a cord-shaped heating element 214. The heating element 214 is provided between the first foil body 211 and the second foil body 212. The heating element 214 generates heat when an electric current flows. The heating element 214 is, for example, a heating wire.

  A first adhesive 216 is provided between the second foil body 212 and the heating element 214 and between the first foil body 211 and the second foil body 212. The first adhesive 216 joins the second foil body 212 and the heating element 214. The first adhesive 216 joins the first foil body 211 and the second foil body 212. As described above, the heating element 214 is bonded and sandwiched between the first foil body 211 and the second foil body 212.

  A second adhesive 217 is provided between the first foil body 211 and the back surface BF of the seating portion 230. The second adhesive 217 joins the first foil body 211 and the back surface BF of the seating portion 230. Thereby, the heating unit 210 is provided on the back surface BF of the seating unit 230.

  Each of the first foil body 211 and the second foil body 212 is a metal foil. The thermal conductivity of the metal foil is higher than the thermal conductivity of the seating portion 230. Examples of the first foil body 211 and the second foil body 212 include aluminum foil and copper foil.

  As shown in FIG. 5, the heating element 214 meanders between the first foil body 211 and the second foil body 212, and extends over substantially the entire first foil body 211 and the second foil body 212. Be placed. Further, as illustrated in FIG. 4, the heating unit 210 is provided over substantially the entire back surface BF of the seating unit 230. The heating element 214 meanders under the seating portion 230 and is disposed over substantially the entire back surface BF.

  Further, as illustrated in FIG. 5, the heating element 214 is disposed on the back surface BF at a position where it does not contact the upper end 252 b of each second plate portion 252. In other words, the heating element 214 is disposed at a position that does not overlap the second plate portions 252 in the vertical direction. The arrangement pattern of the heating elements 214 is not limited to the example shown in FIG. 5, and can be any pattern that can be arranged over substantially the entire back surface BF of the seating portion 230 and does not contact the upper end 252 b of each second plate portion 252. It's okay. In other words, the shape and arrangement of each second plate portion 252 may be any shape and arrangement that can appropriately support the seating portion 230 and that do not contact the heating element 214. The heating unit 210 is not limited to the one having the cord-like heating element 214, and may be any configuration that is provided on the back surface BF and can heat substantially the entire back surface BF.

  The heating unit 210 includes a central portion 210a, an outer portion 210b, and an inner portion 210c. The central portion 210a faces the upper plate portion 231 of the seating portion 230 in a state where it is bonded to the back surface BF. The outer portion 210b faces the outer edge portion 232 of the seating portion 230 in a state where it is adhered to the back surface BF. The inner portion 210c faces the inner edge portion 233 of the seating portion 230 in a state where it is adhered to the back surface BF.

  The density of the heating element 214 provided in the outer portion 210b is higher than the density of the heating element 214 provided in the central portion 210a. The density of the heating element 214 provided in the inner portion 210c is higher than the density of the heating element 214 provided in the central portion 210a.

  As described above, the thickness t2 of the outer edge portion 232 and the thickness t3 of the inner edge portion 233 are thicker than the thickness t1 of the upper plate portion 231. Therefore, the uniformity of the temperature of the seating portion 230 can be increased by increasing the density of the heating elements 214 of the outer portion 210b and the inner portion 210c than the density of the heating elements 214 of the central portion 210a. For example, it can be heated substantially uniformly over substantially the entire seating portion 230.

  As described above, in the heating toilet seat device 100 according to the present embodiment, the load support portion 250 supports the seating portion 230. Therefore, even when the seating portion 230 is thin and the heat capacity is reduced, the load at the time of sitting is reduced. Sufficient strength can be ensured. And the load support part 250 has the 1st board part 251 extended in the direction parallel to the back surface BF of the seating part 230, and partitions off a part of internal space SP up and down. Thereby, it is possible to easily generate heat in the internal space SP, and it is possible to suppress the downward heat dissipation of the heat of the heating unit 210. Therefore, it is not necessary to separately provide a heat insulating material or the like, and the heat insulating performance can be improved with a simple configuration.

  Further, by providing gaps between the first plate portion 251 and the back surface BF of the load support portion 250 and between the second plate portions 252 and the back surface BF, the heat of the heating unit 210 is increased. Escape to the bottom via 250 can be suppressed.

  Further, by providing a gap as described above and separating the load support part 250 from the seating part 230, the seating part 230 and the bottom part 240 can be appropriately joined by vibration welding.

  Further, by providing the third plate portion 253 in the load support portion 250, it is possible to further suppress the convection of the air in the internal space SP and to easily heat the internal space SP. That is, the heat insulation performance can be further improved.

  Further, by providing a gap between the lower end 253a of the third plate portion 253 and the facing surface FF, it is possible to suppress the heat of the heating portion from escaping downward via the third plate portion 253. Further, when both the lower end 252a of the second plate portion 252 and the lower end 253a of the third plate portion 253 are brought into contact with the facing surface FF, for example, the lower end of the second plate portion 252 due to a dimensional error. There is a concern that 252a may float from the facing surface FF. When the lower end 252a of the second plate portion 252 floats from the facing surface FF, the lower end 252a of the second plate portion 252 abuts against the facing surface FF when seated, which causes noise. Therefore, as described above, by separating the lower end 253a of the third plate portion 253 from the facing surface FF, it is possible to suppress the generation of abnormal noise during sitting.

  Moreover, by providing the 4th board part 241 in the bottom part 240, it can suppress that a heat | fever escapes from the clearance gap between the lower end 253a of the 3rd board part 253, and the opposing surface FF, and can improve heat insulation performance more. .

  Further, by setting the volume of the first region R1 to less than 50% of the total volume of the internal space SP, it is possible to further improve the heat insulation performance of the inner part where the body of the user who is seated is easy to contact.

  Further, by arranging the heating element 214 of the heating unit 210 at a position that does not contact the upper end 252b of the second plate part 252, the heating element 214 is sandwiched between the back surface BF and the upper end 252b of the second plate part 252 when seated. It is possible to prevent the heating element 214 from being disconnected.

Drawing 7 is a graph showing an example of the characteristic of the heating toilet seat device concerning an embodiment.
The horizontal axis in FIG. 7 is the vertical distance D _SL (see FIG. 4) between the first plate portion 251 and the seating portion 230. The vertical axis in FIG. 7 represents the power consumption when the heating unit 210 is operated. That is, FIG. 7 is a graph showing the relationship between the distance _DSL and the power consumption of the heating unit 210.

As shown in FIG. 7, the power consumption of the heating unit 210 is lowest when the vertical distance D _SL between the first plate unit 251 and the seating unit 230 is set to about 10 mm. This is because if the distance _DSL is too far away, the effect of suppressing the convection of air due to the provision of the first plate portion 251 is weakened. This is thought to be due to running away.

Thus, the distance D _SL in the vertical direction between the seat 230 and the first plate portion 251, decreases the heat insulating performance is too far or too close. Therefore, the distance _DSL is set to 5 mm or more and 15 mm or less. More preferably, it is set to 8 mm or more and 10 mm or less. Thereby, appropriate heat insulation performance can be obtained by providing the first plate portion 251.

FIG. 8 is a partial cross-sectional view illustrating a modification of the toilet seat according to the embodiment.
As illustrated in FIG. 8, the number of the second plate portions 252 provided in the load support portion 250 may be one. For example, the load supporting portion 250 is provided with one second plate portion 252 that extends in a direction perpendicular to the facing surface FF and extends along the outer edge of the facing surface FF. In this case, it is preferable that the second plate portion 252 is disposed near the center in the width direction of the seating portion 230 and the bottom portion 240. Thereby, in the one 2nd board part 252, the intensity | strength with respect to the load at the time of seating can be raised.

  Thus, the number of the second plate portions 252 provided in the load support portion 250 may be one, or two or more. The number of the second plate portions 252 may be appropriately set according to the strength against the load, the arrangement pattern of the heating elements 214, and the like.

FIG. 9 is a partial cross-sectional view illustrating a modified example of the toilet seat according to the embodiment.
As shown in FIG. 9, in this example, the toilet seat 200 further includes elastic bodies 271 and 272. The elastic bodies 271 and 272 are provided in the load support portion 250 and close the gap in the width direction between the first plate portion 251 and the seating portion 230.

  The elastic body 271 closes the gap between the first plate portion 251 and the outer edge portion 232. One end 271 a in the width direction of the elastic body 271 contacts the outer edge portion 232. Further, the other end 271 b of the elastic body 271 engages with the upper end 252 b of the second plate portion 252 disposed on the outside, and closes the gap between the upper end 252 b and the seating portion 230.

  The elastic body 272 closes the gap between the first plate portion 251 and the inner edge portion 233. One end 272a in the width direction of the elastic body 272 contacts the inner edge portion 233. The other end 272 b of the elastic body 272 engages with the upper end 252 b of the second plate portion 252 disposed on the inner side, and closes the gap between the upper end 252 b and the seating portion 230.

  A resin material such as rubber is used for the elastic bodies 271 and 272. The rigidity of the elastic bodies 271 and 272 is lower than the rigidity of the load support portion 250. In addition, the thermal conductivity of the elastic bodies 271 and 272 is lower than the thermal conductivity of the load support portion 250.

  As described above, the elastic bodies 271 and 272 close a gap that is vacant between the seating portion 230 and the load support portion 250. Thereby, the convection of the air in internal space SP can be suppressed more, and heat insulation performance can be improved more. Further, the elastic bodies 271 and 272 suppress the movement of the seating portion 230 and the bottom portion 240 together by elastic deformation during vibration welding.

  As described above, the elastic bodies 271 and 272 can more appropriately partition the internal space SP in the vertical direction and the horizontal direction without hindering vibration welding between the seating portion 230 and the bottom portion 240. Heat insulation performance can be further improved without inhibiting vibration welding.

The embodiment of the present invention has been described above. However, the present invention is not limited to these descriptions. As long as the features of the present invention are provided, those skilled in the art appropriately modified the design of the above-described embodiments are also included in the scope of the present invention. For example, the shape, size, material, arrangement, and the like of each element included in the heating toilet seat device 100 and the like are not limited to those illustrated, and can be changed as appropriate.
Moreover, each element with which each embodiment mentioned above is provided can be combined as long as technically possible, and the combination of these is also included in the scope of the present invention as long as it includes the features of the present invention.

  DESCRIPTION OF SYMBOLS 10 Toilet apparatus, 100 Heating toilet seat apparatus, 200 Toilet seat, 210 Heating part, 211 1st foil body, 212 2nd foil body, 214 Heat generating body, 216 1st adhesive agent, 217 2nd adhesive agent, 220 Temperature Detection sensor, 230 seating portion, 231 upper plate portion, 232 outer edge portion, 233 inner edge portion, 240 bottom portion, 241 fourth plate portion, 250 load support portion, 251 first plate portion, 252 second plate portion, 253 third plate Part, 271, 272 elastic body, 300 toilet lid, 301 transmission window, 400 heating toilet seat function part, 410 control part, 420 seating detection sensor, 430 human body detection sensor, 440 entrance detection sensor, 441 recessed part, 443 exhaust port, 445 discharge port, 460 room temperature detection sensor, 600 operation unit, 800 Western-style toilet, 801 bowl, BF back , FF facing surface, SF seating surface, SP internal space

Claims (6)

A seating portion having a seating surface and a back surface opposite to the seating surface;
A bottom portion having a facing surface facing the back surface, and a space surrounded by the back surface and the facing surface provided between the back surface and the facing surface;
A heating unit provided on the back surface in the space;
A load support portion provided in the space and supporting the seating portion;
With
The load support portion is
A first plate part extending in a direction parallel to the back surface and partitioning a part of the space up and down;
A second plate portion extending in a direction perpendicular to the facing surface and having a lower end contacting the facing surface and an upper end positioned above the first plate portion;
Have
A heating toilet seat device, wherein a gap is provided between each of the first plate portion and the back surface and between the second plate portion and the back surface.   The heating toilet seat device according to claim 1, wherein the load support portion further includes a third plate portion extending downward from an end portion of the first plate portion.   The heating toilet seat device according to claim 2, wherein a gap is provided between a lower end of the third plate portion and the facing surface. The bottom portion has a fourth plate portion extending upward from the facing surface,
The heating toilet seat device according to claim 3, wherein the fourth plate portion is disposed in proximity to the third plate portion and has an upper end located above the lower end of the third plate portion. The second plate portion extends in the vertical direction and extends along an outer edge of the facing surface,
The heating toilet seat device according to any one of claims 1 to 4, wherein the volume of the area inside the second plate portion of the space is less than 50% of the volume of the space. The second plate portion supports the seating portion by bringing the upper end into contact with the back surface of the seating portion bent downward,
The heating unit has a cord-like heating element,
The heating toilet seat device according to any one of claims 1 to 5, wherein the heating element is disposed at a position on the back surface that does not contact the upper end of the second plate portion.

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