JP2014188295A - Toilet device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a toilet device which reliably detects a user coming closer to the front of a toilet and suppresses wasteful power consumption in a heated toilet seat function.SOLUTION: In a toilet device including: a toilet seat set above a toilet bowl; a casing which is set in the back of the toilet seat and stores at least a washing nozzle for washing hips; a radio wave sensor which is disposed inside the casing for detecting a user; and a toilet lid which covers the toilet seat and can be opened and closed, the toilet lid has an upper surface member and a lower surface member, and a radio wave within a half-value angle which is transmitted from the radio wave sensor and transmits the inside of the casing transmits only the upper surface member of the toilet lid or only the lower surface member when the toilet lid is in a closed state.

Description

  The present invention relates to a toilet device having a heating toilet seat function for detecting a user and heating a toilet seat.

  2. Description of the Related Art Conventionally, a technique for detecting the presence or absence of a user using a radio wave sensor in a toilet device is known. Specifically, a radio wave sensor is disposed in a casing of a toilet device in which a nozzle for cleaning the buttock and the like is housed, and the radio wave transmitted from the radio wave sensor is transmitted through a member of the toilet device such as a toilet lid, and the front of the toilet Is being sent to The presence or absence of the user is detected by receiving the reflected signal of the radio wave reflected by the user approaching the toilet.

  This technique can improve design because it is not necessary to use a dedicated window for the passage of light like a photoelectric sensor in the casing. In addition, since the photoelectric sensor only knows the amount of reflected light, it detects only the presence or absence of the user, but since the radio wave sensor can acquire an analog signal, it can identify the detailed operation of the user by devising signal processing. Can be detected. (For example, patent document 1).

  On the other hand, in the conventional toilet device, many toilet devices having a heating toilet seat function are widespread. In the toilet device with this heating toilet seat function, the user can prepare it in a warmed state before the user is seated on the toilet seat, so that the user can use it comfortably without feeling cold and uncomfortable. There is technology. In this technology, it is necessary to warm the toilet seat to an appropriate temperature before the user is seated. However, when the toilet device is not used such as when the user is not in use, it is desirable to save as much power as possible to warm the toilet seat. There is a request.

  Therefore, in order not to cool the toilet seat, that is, in order to keep the heat of the toilet seat as much as possible, the toilet lid covering the toilet seat has a multi-layer structure composed of a plurality of members, and a heat insulating material is disposed in the toilet lid, A technique for keeping the toilet seat warm for a long time is also known. (For example, Patent Documents 2 to 5).

  In the toilet device having the heating toilet seat function, it is conceivable to use a radio wave sensor from the viewpoint of power saving. Specifically, by identifying the detailed movements of the user by the radio wave sensor, it is possible to lengthen the time for the user to warm the toilet seat before the user is seated on the toilet seat, and as a result, to reduce the power when the toilet device is not used. It is something that can be done. In this technique, the radio wave transmitted from the radio wave sensor may pass through the multilayer structure of the toilet lid.

  Therefore, when radio waves move through different media, reflection and absorption of radio waves occur at each boundary surface, and until radio waves are transmitted from the casing through the toilet lid to the toilet, and reflected by the user. When the received radio wave is received by the sensor from the toilet lid through the casing, there is a problem that a sufficient detection signal cannot be obtained and the user cannot be detected.

JP 2001-311773 A JP 2010-178925 A JP 11-318766 A JP 2012-010834 A JP 2012-120699 A

  The present invention has been made to solve the above problem, and provides a toilet device that can reliably detect a user approaching the toilet and can suppress wasteful power consumption in the heating toilet seat function. Objective.

  According to the first invention, a toilet seat installed above the toilet bowl, a casing installed at the rear of the toilet seat and containing at least a cleaning nozzle for cleaning the buttocks, and disposed in the casing, the user And a toilet lid that covers the toilet seat and is openable and closable. The toilet lid includes an upper surface member and a lower surface member. When the toilet lid is in a closed state, The radio wave transmitted within the half-value angle transmitted through the casing transmits only the upper surface member or only the lower surface member of the toilet lid.

  According to this toilet device, the radio wave transmitted from the radio wave sensor and transmitted through the casing within the half-value angle transmits only the upper surface member or only the lower surface member of the toilet lid. In other words, the radio wave within the half-value angle passes through the one-layer structure of the toilet lid. Therefore, the reflection and absorption of radio waves on the toilet lid are reduced, and the user can be reliably detected. Therefore, the heating toilet seat function can be reliably driven. As a result, the user does not feel cold and uncomfortable when sitting on the toilet seat. Moreover, since the user approaching the toilet bowl can be detected immediately by the radio wave sensor, it is possible to suppress wasteful power consumption in the heating toilet seat function.

  According to a second invention, in the first invention, the toilet lid has a heat insulating layer sandwiched between the upper surface member and the lower surface member, and the lower surface member of the toilet lid is a toilet seat on which a user sits in a closed state. The toilet device is formed in substantially the same range as the range, and the radio wave within the half-value angle transmitted from the radio wave sensor transmits only the upper surface member.

  According to this toilet device, since the toilet lid has the heat insulating layer sandwiched between the upper surface member and the lower surface member, the heat of the toilet seat can be kept warm. Therefore, it is not necessary to frequently operate the heating function, and more power can be saved.

  According to the third invention, the radio wave sensor transmits the radio wave transmitted horizontally or obliquely upward toward the front of the toilet, and is parallel polarized with respect to the surface of the toilet lid through which the radio wave is transmitted. It is a toilet device characterized by.

  According to this toilet device, the transmitted radio wave is transmitted horizontally or obliquely upward toward the front of the toilet, and is polarized in parallel to the surface of the toilet lid through which the radio wave is transmitted. For this reason, when radio waves are transmitted from inside the casing at the rear of the toilet seat, radio waves within the half-value angle are irradiated to the user in front of the toilet and are further reflected. Therefore, the user can be detected more reliably. As a result, it is possible to more reliably detect the user approaching the toilet bowl, so the heated toilet seat function can be driven more reliably, and when the user is seated, the toilet seat is cold and feels uncomfortable. It can be used comfortably.

  It is possible to provide a toilet device that can reliably detect a user approaching in front of a toilet and can suppress wasteful power consumption in the heating toilet seat function.

It is a figure which shows the whole toilet device of this invention, and the user before a toilet bowl. It is a figure which the electromagnetic wave within the half-value angle of this invention permeate | transmits one layer part of a toilet lid. It is a figure which shows the user currently sitting on the toilet seat of the toilet device of this invention. It is a figure which shows the incident angle which injects into a toilet lid, when the electromagnetic wave of the largest radiation direction of this invention is transmitted toward a toilet bowl toward a horizontal direction. It is a figure which shows the incident angle which injects into a toilet lid, when the electromagnetic wave of the maximum radiation direction of this invention is transmitted toward diagonally upward toward the front of a toilet bowl. It is a conceptual diagram explaining the incidence | injection of the electromagnetic wave by the polarization (excitation) direction of this invention. It is a figure which shows the reflectance in the incident angle of the electromagnetic wave by the polarization (excitation) direction of this invention.

Next, embodiments of the present invention will be described in detail with reference to the drawings.
In the present invention, the direction or angle of the strongest radio wave intensity with respect to the vertical (vertical) direction of the radio wave transmitted from the radio wave sensor is set to the maximum radiation direction, and further from the maximum radiation direction to the vertical (vertical) direction. A range or an angle at which a strong radio wave necessary for detecting a user is transmitted is a half-value angle. That is, “Radio wave within half-value angle” means “the range of radio waves transmitted between the upper and lower half-value angles determined by the maximum radiation direction, which is a strong radio wave necessary for detecting the user”. .

FIG. 1 is a diagram showing the entire toilet device of the present invention and a user in front of the toilet.
The toilet device 1 is a toilet seat 5 installed above the toilet bowl 7, a heating toilet seat device 8 installed inside the toilet seat 5, and a cleaning device installed at the back of the toilet seat 5 for cleaning at least the buttocks and the like. A casing 6 in which a nozzle is housed, a radio wave sensor 3 that is disposed in the casing 6 and detects a user, and a toilet lid 4 that covers the toilet seat 5 and is pivotally supported by the casing 6 and can be opened and closed.

  Here, when the toilet lid 4 is in the closed state, the radio wave transmitted from the radio wave sensor 3 and transmitted through the casing 6, that is, the half-value angle 11 to the half-value angle 12 determined by the maximum radiation direction 10. The radio wave transmitted in between passes through the toilet lid 4. The radio wave within the half-value angle that has passed through the toilet lid 4 is irradiated to the user 2 approaching in front of the toilet, is reflected, passes through the toilet lid 4 again, and returns to the radio wave sensor 3. The user 2 is detected by receiving the returned radio wave as a reception signal. When the user 2 is detected, power is supplied to the heating toilet seat device 8 to generate heat, and the surface of the toilet seat 5 is warmed. As a result, since the toilet seat 5 can be raised from a cold state to a warm optimum temperature before the user 2 sits on the toilet seat 5, the user 2 can comfortably use it without feeling cold and uncomfortable.

FIG. 2 is a diagram in which radio waves within the half-value angle of the present invention are transmitted through one layer of the toilet lid 4.
The toilet lid 4 has a multilayer structure including an upper surface member 21 and a lower surface member 22. Therefore, when the toilet lid 4 is in the closed state, the heat of the toilet seat 5 heated by the heating toilet seat device 8 can be kept warm for a long time. Further, the toilet lid 4 includes a heat insulating layer 20 sandwiched between the upper surface member 21 and the lower surface member 22. Therefore, when the toilet lid 4 is in the closed state, the heat of the toilet seat 5 heated by the heating toilet seat device 8 can be kept warm for a longer time. The toilet lid 4 of the present embodiment does not need to frequently supply power to the heating toilet seat device 8, and can suppress wasteful power consumption.

  In addition, the toilet lid 4 has a single-layer structure in which the rear upper portion of the toilet seat 5 through which radio waves within the half-value angle are transmitted has only the upper surface member 21. Therefore, reflection and absorption of radio waves by the toilet lid 4 are small and a sufficient detection signal is obtained, so that the user 2 approaching the front of the toilet 7 can be detected with certainty. Furthermore, by transmitting the radio wave so that the radio wave within the half-value angle passes above the toilet seat 5 and the heating toilet seat device 8, reflection and absorption of the radio wave can be suppressed, and the user 2 can be detected more reliably.

  In the present embodiment, the radio waves in each half-value pass through only the upper surface member 21, but the toilet lid 4 may have a structure in which the radio waves in each half-value pass through only the lower surface member 22. Specifically, the rear upper portion of the toilet seat 5 has a single-layer structure including only the lower surface member 22. The lower surface member 22 extends toward the casing 6 and has a structure in which the lower surface member 22 is pivotally supported with respect to the casing 6.

FIG. 3 is a view showing a user sitting on the toilet seat 5 of the toilet device 1 of the present invention.
As described above with reference to FIG. 2, the toilet lid 4 has a multilayer structure including the upper surface member 21 and the lower surface member 22, and the heat insulating layer 20 sandwiched between the upper surface member 21 and the lower surface member 22, and transmits radio waves within a half-value angle. The rear upper portion of the toilet seat 5 is a single layer structure having only the upper surface member 21. A range where the user's 2 buttocks or the like do not touch the heated toilet seat when the user 2 sits on the toilet seat 5, that is, the range of the inclined portion of the rear portion of the toilet seat 5 where the user does not sit is defined as L <b> 1. On the other hand, the range of the toilet seat 5 which is located in front of L1 and where the user is seated is L2. At this time, the range of the lower surface member 22 of the toilet lid 4 in FIG. 2 is formed by L2 ′ which is substantially the same range as the range L2 of the toilet seat 5 on which the user is seated.

  Here, the range of L2 'is a multilayer structure including the upper surface member 21 and the lower surface member 22, and the heat insulating layer 20 sandwiched between the upper surface member 21 and the lower surface member 22 described above with reference to FIG. As a result, when the toilet lid 4 is in the closed state, the toilet lid 4 having a multilayer structure is positioned above the range of the toilet seat 5 on which the user 2 is seated. Heat can be kept warm for a long time. Therefore, it is not necessary to frequently supply power to the heating toilet seat device 8, and wasteful power consumption can be suppressed.

  The toilet lid 4 is a single layer structure having only the upper surface member 21 although the range of L1 'is behind the L2' and the range of L1 'is a portion through which radio waves within a half-value angle are transmitted. Therefore, reflection and absorption of radio waves by the toilet lid 4 are small and a sufficient detection signal is obtained, so that the user 2 approaching the front of the toilet 7 can be detected with certainty.

FIG. 4 is a diagram showing an incident angle at which the radio wave in the maximum radiation direction 10 of the present invention is incident on the toilet lid 4 when transmitted horizontally toward the front of the toilet.
The toilet lid 4 is installed with an angle of 10 degrees downward when the horizontal is 0 degrees.
The radio wave transmitted from the radio wave sensor 3 in the casing 6 to the front of the toilet bowl 7 is transmitted at 0 degree when the horizontal is 0 degree. As a result, the incident angle at which the radio wave enters the toilet lid 4 is 80 degrees when the vertical angle is 0 degree.

FIG. 5 is a view showing an incident angle incident on the toilet lid 4 when the radio wave in the maximum radiation direction 10 of the present invention is transmitted obliquely upward toward the front of the toilet bowl.
The toilet lid 4 is installed with an angle of 10 degrees downward when the horizontal is 0 degrees.
The radio wave transmitted from the radio wave sensor 3 in the casing 6 to the front of the toilet 7 is transmitted at 30 degrees when the horizontal is 0 degrees. As a result, the incident angle at which the radio wave enters the toilet lid 4 is 50 degrees when the vertical angle is 0 degree.

Here, FIG. 6 is a conceptual diagram for explaining the incidence of radio waves according to the polarization (excitation) direction of the present invention.
The relationship in which the electric field component of the radio wave is incident on the surface of the toilet lid 4 in parallel with the incident surface 9 as shown in FIG. The radio wave transmitted from the radio wave sensor 3 is incident on the toilet lid 4 with parallel polarization. FIG. 7 is a diagram showing the reflectance at the incident angle of the radio wave according to the polarization (excitation) direction of the present invention.
The radio wave transmitted from the radio wave sensor 3 enters the toilet lid 4 made of a resin such as polypropylene or polyethylene from the air layer. The refractive index n1 of the air layer is about 1, and the refractive index n2 of a resin such as polypropylene or polyethylene is about 1.5.

  Comparing the reflectance of parallel polarization (electric field component parallel to the incident surface) and vertical polarization (electric field component perpendicular to the incident surface) with respect to the incident angle, the incident angle of the radio wave to the toilet lid 4 in FIG. In this case, the parallel polarization is about 0.237, and the vertical polarization is about 0.539. The parallel polarization greatly reduces the reflectance when radio waves are incident on the toilet lid 4. . Also, in the case where the incident angle of the radio wave with respect to the toilet lid 4 in FIG. 5 is 50 degrees, the parallel polarization is about 0.003, and the vertical polarization is about 0.112. The reflectance when the radio wave enters the toilet lid 4 is greatly reduced.

  Therefore, as shown in FIGS. 4 and 5, the radio wave transmitted from the radio wave sensor 3 is transmitted horizontally or obliquely upward toward the front of the toilet, and is parallel polarized with respect to the surface of the toilet lid 4 through which the radio wave is transmitted. Since the reflectance when the radio wave enters the toilet lid 4 is reduced by entering the signal, a detection signal for sufficiently detecting the user can be obtained, and the user 2 approaching the front of the toilet 7 surely can be obtained. It can be detected.

  In the present invention, the configuration of the embodiment is merely an example. If the effects of the present invention can be satisfied, the distribution of the single-layer configuration and the multi-layer configuration of the toilet lid 4 may be freely set within the scope of the present invention. Absent. In addition, the angle of the toilet lid 4 and the irradiation angle of the radio wave and the incident angle of the radio wave incident on the toilet lid 4 can be freely set as long as a detection signal that can sufficiently detect the user 2 such as the user can be obtained. You can set it.

DESCRIPTION OF SYMBOLS 1 ... Toilet device 2 ... User 3 ... Radio wave sensor 4 ... Toilet lid 5 ... Toilet seat 6 ... Casing 7 ... Toilet bowl 8 ... Heating toilet seat device 9 ... Incident surface 10 ... Maximum radiation direction 11, 12 ... Half value angle 20 ... Heat insulation layer 21 ... Upper surface member 22 ... Lower surface member

Claims (3)

A toilet seat installed above the toilet bowl, a casing installed at the rear of the toilet seat and containing a cleaning nozzle for cleaning at least the buttocks, a radio wave sensor disposed in the casing and detecting a user; Covering the toilet seat and opening and closing the toilet lid;
In a toilet device comprising:
The toilet lid includes an upper surface member and a lower surface member,
Have
When the toilet lid is in a closed state, radio waves transmitted from the radio wave sensor and transmitted through the casing within a half-value angle are transmitted only through the upper surface member or only the lower surface member of the toilet lid. Toilet bowl device. The toilet lid has a heat insulating layer sandwiched between the upper surface member and the lower surface member,
The lower surface member of the toilet lid is formed in a range substantially the same as the range of the toilet seat on which a user sits in the closed state,
The toilet device according to claim 1, wherein a radio wave within a half-value angle transmitted from the radio wave sensor transmits only the upper surface member. The radio wave sensor is
The transmitted radio wave is transmitted horizontally or obliquely upward toward the front of the toilet and is parallel polarized with respect to the surface of the toilet lid through which the radio wave is transmitted.
The toilet device according to claim 1 or 2, characterized in that.