JP2019013441A - Toilet seat device - Google Patents

Abstract

To suppress decrease in a user's comfort to a temperature of a toilet seat part, even when a temperature change in a day is relatively large in a toilet seat device.SOLUTION: A controller 13 of a toilet seat device 1 includes: a target temperature setup unit 13b that sets a selection temperature Ths, a preset temperature selected by a user out of a plurality of preset temperatures, to a target temperature Tht of a seating surface S of a toilet seat part 20; and a target temperature change unit 13k that changes the target temperature Tht of the seating surface S set by the target temperature setup unit 13b according to a temperature in a room where the toilet seat device 1 is disposed, the number of times when the user uses the toilet seat part 20, and the selection temperature Ths.SELECTED DRAWING: Figure 9

Description

  The present invention relates to a toilet seat device.

  As a type of toilet seat device, one shown in Patent Document 1 is known. The toilet seat device of Patent Document 1 determines the temperature of the toilet seat based on the detection result of the room temperature detection means for detecting the room temperature in the toilet room and the detection result of the heater temperature detection means for detecting the temperature of the heater means for heating the toilet seat. A heater setting correction unit that estimates and corrects the set temperature of the heater unit so as to bring the estimated temperature of the toilet seat closer to the target temperature is provided. The toilet seat device performs control to keep the temperature of the toilet seat constant so as to become the target temperature set by the user by energizing the heater means with electric power corresponding to the set temperature corrected by the heater setting correction means.

JP 2007-312882 A

  When the season is early spring or early winter, the daily temperature change may be relatively large. In this case, specifically, the morning and evening temperatures are relatively low, and the daytime temperatures are relatively high. In such a case, the user may set the target temperature of the toilet seat relatively low according to the relatively high temperature during the day.

  However, the user feels that the temperature of the toilet seat is relatively low when the user uses the toilet seat when the target temperature of the toilet seat remains relatively low and the air temperature is relatively low in the evening of the day. Can be considered. That is, it is conceivable that the comfort of the user with respect to the temperature of the toilet seat is reduced.

  Therefore, the present invention has been made to solve the above-described problems, and in the toilet seat device, even when the daily temperature change is relatively large, the comfort of the user with respect to the temperature of the toilet seat portion is reduced. The purpose is to suppress.

  In order to solve the above-described problem, the toilet seat device according to claim 1 is disposed in the toilet seat portion having a seating surface on which the user sits when used by the user, and is energized within the toilet seat portion. A heating device that heats the seating surface, a first temperature sensor that is disposed inside the toilet seat and detects the temperature of the seating surface, a second temperature sensor that detects the temperature of the room in which the toilet seat is disposed, and the seating A toilet seat device including a seating detection device that detects a user's seating on a surface and a control device that controls at least the heating device, wherein the control device is selected by a user from a plurality of set temperatures. A selection temperature acquisition unit that acquires a set temperature as a selection temperature, a target temperature setting unit that sets the selection temperature acquired by the selection temperature acquisition unit as a target temperature of the seating surface, and a seating surface detected by the first temperature sensor The temperature of the eyes A temperature control unit that controls the energization amount of the heating device so as to be the target temperature of the seating surface set by the temperature setting unit, and divides the time of the day into a plurality of time zones, Detected by the second temperature sensor, the number-of-uses deriving unit for deriving the number of times the user is seated detected by the seating detecting device as the number of times the user has used the toilet seat for each of a plurality of time zones. The target temperature of the seating surface set by the target temperature setting unit in each of a plurality of time zones is determined according to the indoor temperature, the number of uses derived by the use number deriving unit, and the selected temperature acquired by the selected temperature acquiring unit. A target temperature changing unit to be changed.

  According to this, the toilet seat device changes the target temperature of the seating surface in accordance with the indoor temperature, the number of times of use by the user, and the selected temperature that is the set temperature selected by the user. Therefore, even when the daily temperature change is relatively large, the temperature of the seating surface can be appropriately changed. Therefore, it is possible to suppress a decrease in user comfort with respect to the temperature of the toilet seat.

It is a perspective view which shows the toilet seat apparatus which concerns on one Embodiment by this invention. It is a top view of the toilet seat part of the toilet seat apparatus shown in FIG. It is sectional drawing of the toilet seat part of the toilet seat apparatus along the III-III line | wire shown in FIG. It is a block diagram of the toilet seat apparatus shown in FIG. It is the table | surface (Table 1) showing the frequency | count that the user used the toilet seat for every time slot | zone in the learning period for the control apparatus shown in FIG. It is the table | surface (Table 2) showing the frequency | count of use which the control apparatus shown in FIG. 1 derived | led-out. It is a flowchart performed by the control apparatus shown in FIG. It is a figure which shows the daily change of indoor temperature, Comprising: The time slot | zone used as a 1st state is shown. It is a time chart which shows operation | movement of the toilet seat apparatus when the flowchart shown in FIG. 7 is performed when the indoor temperature changes as shown in FIG. It is a figure which shows the daily change of indoor temperature, Comprising: The time slot | zone used as a 2nd state is shown. It is a time chart which shows operation | movement of the toilet seat apparatus when the flowchart shown in FIG. 7 is performed when indoor temperature changes as shown in FIG.

  Hereinafter, an embodiment of a toilet seat device according to the present invention will be described with reference to the drawings. In the present specification, for convenience of explanation, the upper and lower sides in FIG. 1 are the upper and lower sides of the toilet seat device 1, respectively, the lower right side and the upper left side are respectively the front and rear of the toilet seat device 1, and the lower left side. The upper right side will be described as the left side and the right side of the toilet seat device 1, respectively.

  The toilet seat apparatus 1 is a warm water washing toilet seat in this embodiment. As shown in FIG. 1, the toilet seat device 1 is attached to a seat-type toilet 3 installed in a toilet room 2 (corresponding to a room of the present invention). The toilet seat device 1 includes a toilet seat device body 10, a toilet seat 20, a toilet lid 30 that covers the toilet seat 20, and a remote control device 40.

  The toilet seat device main body 10 includes a casing 10a, a cleaning device (not shown) for cleaning a local part of the human body, a seating detection device 11, an indoor temperature sensor 12 (corresponding to the second temperature sensor of the present invention), and a control device 13. ing.

  The casing 10a is formed in a hollow box shape. The casing 10 a is attached to the seat-type toilet 3. The casing 10a holds the toilet seat 20 and the toilet lid 30 so as to be rotatable. The casing 10a accommodates a cleaning device, a seating detection device 11, a room temperature sensor 12, and a control device 13 for controlling at least a heating device 22 described later.

  The seating detection device 11 detects the seating of the user on the seating surface S. The seating surface S is a part where the user is seated when the toilet seat 20 is used by the user (see FIG. 2). The seating detection device 11 is arranged at the upper part inside the casing 10a. The seating detection device 11 is an infrared distance sensor that detects the distance to the object. The seating detection device 11 outputs an on signal when the user is seated on the seating surface S, and outputs an off signal when the user is not seated on the seating surface S.

  When the user is seated on the seating surface S, the distance between the user and the seating detection device 11 is relatively short. Thereby, when the detection result of the seating detection device 11 is not more than the predetermined distance, the seating detection device 11 outputs an ON signal. On the other hand, when the detection result of the seating detection device 11 is longer than a predetermined distance because the user is not seated on the toilet seat portion 20, the seating detection device 11 outputs an off signal. The predetermined distance is actually derived by experiments and the like. The detection result of the seating detection device 11 is output to the control device 13.

  The room temperature sensor 12 detects the temperature in the toilet room 2 in which the toilet seat 20 is disposed (hereinafter referred to as room temperature). The indoor temperature sensor 12 is disposed in a portion where the indoor temperature can be detected in the casing 10a. The room detected temperature that is the room temperature detected by the room temperature sensor 12 is output to the control device 13.

  The toilet seat 20 has a seating surface S on which the user sits when used by the user. As shown in FIGS. 2 and 3, the toilet seat 20 includes a toilet seat body 21, a heating device 22, and a toilet seat temperature sensor 23 (corresponding to the first temperature sensor of the present invention).

  The toilet seat body 21 is formed in an annular shape in plan view of the toilet seat 20 (see FIG. 2). The toilet seat body 21 is formed in a hollow shape having a substantially constant wall thickness (see FIG. 3). The wall thickness is the thickness of the side wall that forms the toilet seat body 21. The toilet seat body 21 is made of a thermoplastic resin.

  Further, the toilet seat body 21 has a seating surface S. The seating surface S is a portion of the outer surface of the toilet seat main body 21 where the user is seated from above. The seating surface S is an upper part on the outer surface of the toilet seat body 21. The seating surface S is set in a range where the user's human body can contact when the user is seated from above.

  The heating device 22 is disposed inside the toilet seat 20 (toilet seat body 21) and heats the seating surface S when energized. As shown in FIG. 3, the heating device 22 is disposed on the inner side surface of the upper side wall 21 a of the toilet seat body 21. That is, the heating device 22 is disposed on the opposite surface of the seating surface S. The heating device 22 heats the seating surface S by heating the upper side wall 21 a of the toilet seat body 21. The heating device 22 includes a sheet portion 22a and a heating element 22b.

  The sheet portion 22a is formed in a sheet shape. The seat portion 22a diffuses heat from the heating element 22b to the inner side surface of the upper side wall 21a and transmits the heat to the seating surface S through the upper side wall 21a. The sheet part 22a is, for example, an aluminum foil. The sheet portion 22a is disposed such that one surface (upper surface) is in contact with the inner surface of the upper side wall 21a. One surface of the sheet portion 22a and the inner surface of the upper side wall 21a are fixed by, for example, an adhesive.

  The heating element 22b heats the seating surface S. The heating element 22b is a cord heater configured by a cord-like heating element. The heating element 22b generates heat when electric power is supplied from a power supply unit (not shown) via the control device 13. The power supply unit is an AC system power supply.

  Specifically, the heating element 22b includes a heating part 22b1 and an insulating coating 22b2. The heat generating portion 22b1 is formed by spirally winding an electric heating alloy wire (not shown) around a wire core (not shown) made of glass fiber, for example. The insulating coating 22b2 has insulating properties and covers the outer periphery of the heat generating portion 22b1. The insulating coating 22b2 is provided by, for example, polyvinyl chloride.

  The heating element 22b is disposed on the other surface (lower surface) of the sheet portion 22a. The heating element 22b is fixed by welding the insulating coating 22b2 to the sheet portion 22a. The heating device 22 configured by the sheet portion 22a and the heating element 22b is a planar heating element.

  The toilet seat temperature sensor 23 is disposed inside the toilet seat 20 (toilet seat body 21) and detects the temperature of the seating surface S. The toilet seat temperature sensor 23 is disposed on the other surface of the seat portion 22a. The toilet seat temperature sensor 23 indirectly detects the temperature of the seating surface S by detecting the temperature of the inner surface of the upper side wall 21a. The toilet seat detection temperature, which is the temperature detected by the toilet seat temperature sensor 23, is output to the control device 13.

  The remote control device 40 is for remotely operating the toilet seat device 1. The remote control device 40 and the control device 13 are provided so that they can communicate with each other wirelessly or by wire. As shown in FIG. 1, the remote control device 40 includes a plurality of switches for operating the toilet seat device 1. The switch includes at least a cleaning switch SW1 that operates the cleaning device, and a selection switch SW2 that is a switch that selects the temperature of the seating surface S from a plurality of set temperatures described later.

  The remote control device 40 has a clock function. The remote control device 40 displays the current time on a display unit (not shown). The remote control device 40 is clocked by the user. Note that the time of the control device 13 is synchronized with the time measured by the remote control device 40.

  Further, as shown in FIG. 4, the control device 13 includes a selection temperature acquisition unit 13a, a target temperature setting unit 13b, a temperature control unit 13c, a first state detection unit 13d, a second state detection unit 13e, a storage unit 13f, and a use unit. A number deriving unit 13g, a first time detecting unit 13h, a second time detecting unit 13i, a third time detecting unit 13j, and a target temperature changing unit 13k are provided.

  The selected temperature acquisition unit 13a acquires a set temperature selected by the user from among a plurality of set temperatures as the selected temperature Ths. The set temperature is a temperature set in advance as a temperature for setting the target temperature Tht of the seating surface S. Six set temperatures are set from the first set temperature to the sixth set temperature (see FIGS. 9 and 11). The temperature is set to increase as it goes from the first set temperature to the sixth set temperature in order. The first set temperature to the sixth set temperature are set by measuring the temperature of the seating surface S in advance by experiments or the like at a predetermined environmental temperature (for example, 5 ° C.) that is a relatively low environmental temperature. The environmental temperature is a temperature around the toilet seat device 1 when an experiment is performed on the toilet seat device 1.

  The selected temperature Ths is a set temperature selected by the user from a plurality of set temperatures. The selection temperature Ths is selected by pressing the selection switch SW2 by the user.

  The target temperature setting unit 13b sets the selection temperature Ths acquired by the selection temperature acquisition unit 13a to the target temperature Tht of the seating surface S.

  The temperature control unit 13c is configured so that the temperature of the seating surface S (toilet seat detection temperature) detected by the toilet seat temperature sensor 23 becomes the target temperature Tht of the seating surface S set by the target temperature setting unit 13b. Control the energization amount. Specifically, the temperature control unit 13c uses the toilet seat detection temperature to turn on and off the heating device 22 (heating element 22b), thereby adjusting the temperature of the seating surface S to the target temperature Tht of the seating surface S. .

  The first state detection unit 13d is configured such that the selected temperature Ths is equal to or lower than a first predetermined set temperature Thp1, and the indoor temperature detected by the indoor temperature sensor 12 (indoor detected temperature) is equal to or lower than the predetermined temperature Thps. The state S1 is detected. In the present embodiment, the first predetermined set temperature Thp1 is set to a third set temperature, which is a set temperature having a lower temperature among a plurality of set temperatures. The first predetermined set temperature Thp1 (third set temperature) is a temperature at which the user feels that the user does not want to cool the seating surface S when the user sits on the seating surface S when the environmental temperature is the predetermined environment temperature ( For example, it is set to 28 ° C.

  The predetermined temperature Thps is set to a temperature that the user feels chilly. The predetermined temperature Thps is set to a temperature equal to or higher than the predetermined environmental temperature. The predetermined temperature Thps is, for example, 10 ° C. The first state detection unit 13d detects the first state S1 using the selection temperature Ths and the indoor detection temperature acquired by the selection temperature acquisition unit 13a.

  The second state detection unit 13e detects the second state S2 in which the selected temperature Ths is higher than the first predetermined set temperature Thp1 and the indoor temperature detected by the indoor temperature sensor 12 is higher than the predetermined temperature Thps. is there. The second state detection unit 13e detects the second state S2 using the selection temperature Ths and the indoor detection temperature acquired by the selection temperature acquisition unit 13a.

  The storage unit 13f stores the user's seating detected by the seating detection device 11 in time series. When the on signal is output from the seating detection device 11, the storage unit 13f stores that the user has been seated.

  The use frequency deriving unit 13g divides the time of the day into a plurality of time zones, and the number of times the user is seated detected by the seating detection device 11 in each of the plurality of time zones (the number of times the ON signal is output). ) Is derived for each of a plurality of time zones as the number of uses, which is the number of times the user has used the toilet seat section 20.

  In the present embodiment, the plurality of time zones are provided by equally dividing the time of one day (24 hours) into sixteen. Specifically, as shown in Table 1 of FIG. 5, the plurality of time zones are divided into 24 hours from midnight into time zones i to xvi. That is, the time of one time zone is thirty minutes for one hour.

  The number-of-uses deriving unit 13g calculates the number of times the user has been seated (the number of times the ON signal has been output) stored in the storage unit 13f from the first midnight when the toilet seat device 1 is turned on. Count in order. Further, the use number deriving unit 13g executes this count for 14 days (24 hours × 14; two weeks) as a learning period for deriving the use number. For example, the number of times the ON signal is output in each time zone on the third day of the learning period is 0 times, 0 times, 0 times, 1 time, 3 times, 4 times, 1 time in the order of time zones i to xvi. 0 times, 1 time, 0 times, 1 time, 1 time, 3 times, 1 time, 4 times and 1 time.

  Further, the usage number deriving unit 13g derives the average value of the number of times the ON signal is output in the learning period as the number of times that the user has used the toilet seat unit 20 for each time period. Specifically, as shown in Table 2 in FIG. 6, the average value of the number of times the ON signal is output in the learning period of the first day and the eighth day is the number of times of use in the first combination P1 for each time period. To be derived.

  Further, an average value of the number of times the ON signal is output in the learning period of the second day and the ninth day is derived for each time period as the number of times of use in the second combination P2. Similarly, the average value of the number of times the ON signal is output in the learning period of the third day and the tenth day is derived for each time period as the number of times of use in the third combination P3. Similarly, the average value of the number of times the ON signal is output in each time zone of the fourth and eleventh learning periods is derived for each time zone as the number of uses in the fourth combination P4. Similarly, the average value of the number of times the ON signal is output in the fifth and twelfth learning periods is derived for each time period as the number of times of use in the fifth combination P5. Similarly, the average value of the number of times the ON signal is output in the sixth and thirteenth learning periods is derived for each time period as the number of times of use in the sixth combination P6. Similarly, the average value of the number of times the ON signal is output in the seventh and fourteenth learning periods is derived for each time period as the number of times of use in the seventh combination P7.

  That is, the number of times of use is derived for each time period as an average value of the number of times the ON signal is output in each combination. For example, the number of times of use in the third combination P3 is 0 times, 0 times, 0 times, 1 time, 3 times, 4 times, 1 time, 1 time, 1 time, 1 time, in the order of time zones i to xvi. 1 time, 1 time, 3 times, 1 time, 4 times and 1 time. Further, the usage number deriving unit 13g sequentially updates the number of times the ON signal is output in each time slot in Table 1 of FIG. 5 and the number of uses of Table 2 in FIG. 6 with the passage of time. Since there are seven combinations, each combination corresponds to each day of the week.

Returning to FIG. 4, the description will be continued.
The first time detection unit 13h detects, as the first time Tm1, a time zone in which the number of uses derived by the use number deriving unit 13g is equal to or more than the first predetermined number among the plurality of time zones. The first predetermined number of times is set to a number of times (for example, three times) that the number of times that the toilet seat 20 is used (number of times the ON signal is output) is relatively large in one time zone.

  For example, in the third combination P3, the time when the fifth time zone v, the sixth time zone vi, the thirteenth time zone xiii, and the fifteenth time zone xv are equal to or more than the first predetermined number of times. Since it corresponds to a belt, it is detected as the first time Tm1 by the first time detector 13h.

  The second time detection unit 13i detects a time zone in which the number of uses derived by the use number deriving unit 13g is less than the first predetermined number among the plurality of time zones as the second time Tm2. In the present embodiment, the second time Tm2 is a second predetermined number of times that is less than the first predetermined number and less than the first predetermined number of times, the number of times of use derived by the use number deriving unit 13g being a plurality of time zones. It is a time zone. The second predetermined number of times is set to a relatively small number of times (for example, once) that the user uses the toilet seat 20 (the number of times the ON signal is output) in one time zone.

  For example, in the third combination P3, the fourth time zone iv, the seventh time zone vii to the twelfth time zone xii, the fourteenth time zone xiv, and the sixteenth time zone xvi are Since this corresponds to a time period that is equal to or greater than two predetermined times and less than the first predetermined number of times, the second time detection unit 13i detects the second time Tm2.

  The third time detection unit 13j detects, as the third time Tm3, a time zone in which the number of uses derived by the use number deriving unit 13g is less than the second predetermined number of times than the first predetermined number among the plurality of time zones. To do. For example, in the third combination P3, since the first time zone i to the third time zone iii correspond to the time zone that is less than the second predetermined number of times, the third time detection unit 13j performs the third time. Detected as Tm3.

  The target temperature changing unit 13k corresponds to the indoor temperature (room detected temperature) detected by the indoor temperature sensor 12, the number of uses derived by the use number deriving unit 13g, and the selected temperature Ths acquired by the selected temperature acquiring unit 13a. Thus, the target temperature Tht of the seating surface S set by the target temperature setting unit 13b in each of a plurality of time zones is changed.

  Specifically, when the first state S1 is detected by the first state detection unit 13d within the first time Tm1 detected by the first time detection unit 13h, the target temperature changing unit 13k is the first time Tm1. The target temperature Tht of the seating surface S set by the target temperature setting unit 13b is changed to a second predetermined set temperature Thp2 that is higher than the first predetermined set temperature Thp1 among the plurality of set temperatures. The second predetermined set temperature Thp2 is the fourth set temperature in the present embodiment.

  For example, when the user selects a set temperature that is equal to or lower than the first predetermined set temperature Thp1 because the daytime air temperature is relatively high, the temperature falls in the evening, and the detected indoor temperature is equal to or lower than the predetermined temperature Thps. Thus, when the first state S1 is detected, when the user is seated on the seating surface S, the user may feel that the temperature of the seating surface S is low.

  Therefore, when the first state S1 in which the indoor temperature is relatively low is detected within the first time Tm1 where the number of uses is equal to or more than the first predetermined number, the seating surface S is given priority to the user's comfort. The target temperature Tht is changed to the second predetermined set temperature Thp2, which is higher than the first predetermined set temperature Thp1, thereby preventing the user from feeling that the temperature of the seating surface S is low.

  The target temperature changing unit 13k also sets the target temperature at the second time Tm2 when the second state detecting unit 13e detects the second state S2 within the second time Tm2 detected by the second time detecting unit 13i. The target temperature Tht of the seating surface S set by the part 13b is changed to the first predetermined set temperature Thp1.

  For example, when the user selects a set temperature that is higher than the first predetermined set temperature Thp1 because the morning air temperature is relatively low, the temperature rises during the daytime, and the detected indoor temperature becomes the predetermined temperature Thps. When the second state S2 is detected at a higher level, if the number of times of use is relatively small, energy saving can be prioritized.

  That is, when the second state S2 in which the indoor temperature is relatively high is detected within the second time Tm2 in which the number of uses is equal to or greater than the second predetermined number and less than the first predetermined number, the target temperature Tht of the seating surface S is detected. Is changed to the first predetermined set temperature Thp1, which is a temperature at which the user does not feel cold, to save energy of the toilet seat apparatus 1.

  Further, the target temperature setting unit 13b sets the target temperature Tht of the seating surface S set by the target temperature setting unit 13b within the third time Tm3 detected by the third time detection unit 13j, among the plurality of set temperatures. The temperature is changed to a third predetermined set temperature Thp3 that is lower than the one predetermined set temperature Thp1. The third predetermined set temperature Thp3 is the first set temperature in the present embodiment.

  In the third time Tm3 in which the number of uses is less than the second predetermined number of times, the target temperature Tht of the seating surface S is set to a third predetermined setting whose temperature is lower than the first predetermined set temperature Thp1. By changing to the temperature Thp3, energy saving of the toilet seat device 1 is further achieved.

  Next, target temperature change control, which is control for changing the target temperature Tht executed by the control device 13 described above, will be described with reference to the flowchart of FIG. When the heating device 22 performs on / off control so that the temperature of the seating surface S becomes the target temperature Tht, target temperature change control is executed.

  The control device 13 acquires the selected temperature Ths in step S102 (selected temperature acquisition unit 13a), and sets the selected temperature Ths to the target temperature Tht in step S104 (target temperature setting unit 13b). Subsequently, the control device 13 stores the seating of the user in time series in step S106 (storage unit 13f), and derives the number of uses for each time zone in step S108 (use number derivation unit 13g). Further, in step S110, the control device 13 detects the first time Tm1 to the third time Tm3 (first time detection unit 13h, second time detection unit 13i, third time detection unit 13j).

  Subsequently, in step S112, the control device 13 determines whether or not the current time is the first time Tm1. For example, when the number of times of use in the time zone corresponding to the current time is equal to or more than the first predetermined number of times, the current time is the first time Tm1. In this case, the control device 13 determines “YES” in step S112, and determines whether or not the current time is the first state S1 in step S114 (first state detection unit 13d).

  If the selected temperature Ths is a set temperature higher than the first predetermined set temperature Thp1, or if the indoor temperature is higher than the predetermined temperature Thps, the current state is not the first state S1. In this case, the control device 13 determines “NO” in step S114, and returns the program to step S102 without changing the target temperature Tht.

  On the other hand, when the selected temperature Ths is a set temperature equal to or lower than the first predetermined set temperature Thp1 and the indoor temperature is equal to or lower than the predetermined temperature Thps at the time of step S114, the time of step S114 is the first state S1. is there. In this case, the control device 13 determines “YES” in step S114. Subsequently, in step S116, the control device 13 changes the target temperature Tht to the second predetermined set temperature Thp2 (target temperature changing unit 13k), and returns the program to step S112.

  Further, when the number of times of use in the time zone corresponding to the time point of step S112 is less than the first predetermined number of times, the time point of step S112 is not the first time Tm1. In this case, the control device 13 determines “NO” in step S112, and determines whether or not the current time is the second time Tm2 in step S118.

  When the number of times of use in the time zone corresponding to the time point of step S118 is equal to or more than the second predetermined number of times and less than the first predetermined number of times, the time point of step S118 is the second time Tm2. In this case, the control device 13 determines “YES” in step S118, and determines whether or not the second state S2 is in step S120 (second state detection unit 13e).

  For example, when the selected temperature Ths is a set temperature equal to or lower than the first predetermined set temperature Thp1, or when the indoor temperature is equal to or lower than the predetermined temperature Thps, the current state is not the second state S2. In this case, the control device 13 determines “NO” in step S120, and returns the program to step S102 without changing the target temperature Tht.

  On the other hand, when the selected temperature Ths is a set temperature higher than the first predetermined set temperature Thp1 and the indoor temperature is higher than the predetermined temperature Thps at the time of step S120, the time of step S120 is the second state S2. . In this case, the control device 13 determines “YES” in step S120. Subsequently, in step S122, the control device 13 changes the target temperature Tht to the first predetermined set temperature Thp1 (target temperature changing unit 13k), and returns the program to step S118.

  Further, when the number of times of use corresponding to the time point of step S118 is less than the second predetermined number of times, the time point of step S118 is not the second time Tm2. In this case, the control device 13 determines “NO” in step S118, and determines whether or not the current time is the third time Tm3 in step S124.

  If the number of times of use corresponding to the time point of step S124 is less than the second predetermined number of times, the time point of step S124 is the third time Tm3. In this case, the control device 13 determines “YES” in step S124, and changes the target temperature Tht to the third predetermined set temperature Thp3 in step S126 (target temperature changing unit 13k). Then, the control device 13 returns the program to step S124.

  On the other hand, when the number of times of use corresponding to the time point of step S124 is equal to or greater than the second predetermined number of times, the time point of step S124 is not the third time Tm3. In this case, the control device 13 determines “NO” in step S124, and returns the program to step S102 without changing the target temperature Tht.

  Next, when the indoor temperature changes as shown in FIG. 8, the operation of the toilet seat device 1 when the above-described flowchart is executed will be described with reference to the time chart of FIG. In this case, since the selected temperature Ths is the second set temperature, the second set temperature is set as the target temperature Tht (steps S102 and S104).

  Moreover, the room temperature shown in FIG. 8 is a room temperature in winter (for example, December), and is a time when the temperature change of a day is relatively large. Specifically, the indoor temperature changes at a predetermined temperature Thps or less from midnight to 10:00, and changes at a temperature higher than the predetermined temperature Thps from 10:00 to 17:30. Furthermore, from 17:00 to 24:00, the temperature changes below a predetermined temperature Thps. In this case, since the selected temperature Ths is equal to or lower than the first predetermined set temperature Thp1, the time from midnight to 10:00, and from 17:00 to 24:00 correspond to the first state S1. To do.

  Furthermore, after the learning period has elapsed and the number of uses has been derived as shown in Table 2 (see FIG. 6) (step S108), the toilet seat device 1 in the case where the number of uses has changed as in the third combination P3. The operation will be described.

  In the third combination P3, the fifth, sixth, thirteenth, and fifteenth time zones v, vi, xiii, and xv are detected as the first time Tm1 because the number of uses is not less than the first predetermined number. (Step S110). In the third combination P3, the fourth, seventh to twelfth, fourteenth, and sixteenth time zones iv, vii to xii, xiv, and xvi are equal to or more than the second predetermined number of times and the first predetermined number of times. Therefore, the second time Tm2 is detected (step S110). Furthermore, in the third combination P3, the first to third time zones i to iii are detected as the third time Tm3 because they are less than the second predetermined number of times (step S110).

  As shown in FIG. 9, in the first time zone i, both the indoor temperature and the selection temperature Ths are in the first state S1, which corresponds to the third time Tm3 in which the number of times of use is extremely low. Therefore, as described above, priority is given to energy saving of the toilet seat device 1, and the target temperature Tht is changed to the third predetermined set temperature Thp3 (first set temperature) lower than the selected temperature Ths (second set temperature). (Steps S124 and 126). In FIG. 8, the selected temperature Ths is indicated by a broken line, and the target temperature Tht is indicated by a thick solid line.

  In addition, the second and third time zones ii and iii in which the time has elapsed from the first time zone i also correspond to the third time Tm3. Thus, as described above, priority is given to energy saving of the toilet seat device 1, and the target temperature Tht remains changed to the third predetermined set temperature Thp3 (steps S124 and 126).

  Further, when the time elapses and the fourth time zone iv is reached, the number of uses slightly increases and corresponds to the second time Tm2 in which the number of uses is relatively small, but remains in the first state S1. Therefore, the target temperature Tht of the seating surface S is set to the selected temperature Ths (steps S118, S120, S104).

  When the time elapses and the fifth time zone v is reached, the number of uses further increases, which corresponds to the first time Tm1 in which the number of uses is relatively large, and is in the first state S1. Therefore, the user's comfort is given priority as described above, and the second predetermined set temperature Thp2 (fourth set temperature) where the target temperature Tht of the seating surface S is higher than the selected temperature Ths (second set temperature). (Steps S112, S114, S116). Similarly, in the sixth time zone vi, the target temperature Tht of the seating surface S is changed to the second predetermined set temperature Thp2 (fourth set temperature).

  Further, when the time elapses and the seventh time zone vii is reached, the number of uses is slightly reduced, which corresponds to the second time Tm2 in which the number of uses is relatively small, but the selection temperature Ths remains relatively low. Therefore, it is not the second state S2. Therefore, the target temperature Tht of the seating surface S is set to the selected temperature Ths (steps S118, S120, S104). Similarly, for the eighth to twelfth time zones viii to xii, the target temperature Tht of the seating surface S is set to the selected temperature Ths.

  When the time elapses and it becomes the thirteenth time zone xiii, it corresponds to the first time Tm1 in which the number of times of use has increased, and the indoor temperature falls to the first state S1. Therefore, the user's comfort is given priority as described above, and the target temperature Tht of the seating surface S is changed to the second predetermined set temperature Thp2 (fourth set temperature) (steps S112, S114, S116). .

  Further, when the time elapses and the fourteenth time zone xiv is reached, it corresponds to the second time Tm2 in which the number of uses is slightly reduced, but remains in the first state S1. Therefore, the target temperature Tht of the seating surface S is set to the selected temperature Ths (steps S118, S120, S104).

  For the fifteenth time zone xv, the target temperature Tht of the seating surface S is changed to the second predetermined set temperature Thp2 (fourth set temperature), as in the thirteenth time zone xiii. And about the 16th time slot | zone xvi, the target temperature Tht of the seating surface S is set to the selection temperature Ths similarly to the 14th time slot | zone xiv.

  Next, when the indoor temperature changes as shown in FIG. 10, the operation of the toilet seat device 1 when the above-described flowchart is executed will be described with reference to the time chart of FIG. In this case, since the selected temperature Ths is the fourth set temperature, the fourth set temperature is set as the target temperature Tht (steps S102 and S104).

  The indoor temperature shown in FIG. 10 is the same as the indoor temperature shown in FIG. However, in this case, since the selected temperature Ths is higher than the first predetermined set temperature Thp1, the time from 10:00 to 17:00 is equivalent to the second state S2.

  Furthermore, after the learning period has elapsed and the number of uses has been derived as shown in Table 2 (see FIG. 6) (step S108), the toilet seat device 1 in the case where the number of uses has changed as in the third combination P3. The operation will be described. That is, as shown in FIG. 11, the first time Tm1 to the third time Tm3 are detected in the same manner as described above (step S110).

  The first to third time zones i to iii correspond to the third time Tm3 in which the number of uses is extremely small. Therefore, priority is given to energy saving of the toilet seat device 1 as described above, and the target temperature Tht is changed to the third predetermined set temperature Thp3 (first set temperature) lower than the selected temperature Ths (fourth set temperature). (Steps S124 and 126). In FIG. 11, the selected temperature Ths is indicated by a broken line, and the target temperature Tht is indicated by a thick solid line.

  Further, when the time elapses and the fourth time zone iv is reached, the number of uses slightly increases and corresponds to the second time Tm2 in which the number of uses is relatively small, but is not in the second state S2. Therefore, the target temperature Tht of the seating surface S is set to the selected temperature Ths (steps S118, S120, S104).

  When the time elapses and becomes the fifth time zone v and the sixth time zone vi, the number of times of use further increases, which corresponds to the first time Tm1 where the number of times of use is relatively large. Not one state S1. Therefore, the target temperature Tht of the seating surface S is set to the selected temperature Ths (steps S112, S114, S104).

  Further, when the time elapses and the seventh time zone vii is reached, it corresponds to the second time Tm2 in which the number of uses is slightly reduced. When the second state S2 is not detected in the seventh time zone vii, the target temperature Tht of the seating surface S is set to the selected temperature Ths (steps S118, S120, S104).

  And when time passes and the 2nd state S2 is detected in the 7th time slot | zone vii, as mentioned above, priority is given to energy saving of the toilet seat apparatus 1, and the target temperature Tht is made into selection temperature Ths ( The first predetermined set temperature Thp1 (third set temperature), which is lower than the fourth set temperature), is changed (steps S118, S120, S122).

  Also, in the eighth time zone to the twelfth time zone xii, similarly to the seventh time zone vii, the first predetermined set temperature Thp1 where the target temperature Tht is lower than the selected temperature Ths (fourth set temperature). It is changed to (third set temperature). Since the second state S2 is not detected during the twelfth time zone xii, the target temperature Tht is set to the selected temperature Ths (fourth set temperature) (steps S118, S120, S104).

  Further, when the time elapses to become the thirteenth time zone xiii, it corresponds to the first time Tm1 in which the number of uses has increased, but the first state S1 is not detected. Therefore, the target temperature Tht of the seating surface S is set to the selected temperature Ths (steps S112, S114, S104).

  Further, in the fourteenth to sixteenth time zone xvi where further time has elapsed, the first state S1 or the second state S2 is not detected although it corresponds to the first time Tm1 or the second time Tm2. Therefore, the target temperature Tht of the seating surface S is set to the selected temperature Ths (steps S112, S114, S118, S120, S104).

  According to the present embodiment, the toilet seat device 1 is placed inside the toilet seat portion 20 having the seating surface S on which the user is seated when used by the user and the toilet seat portion 20 and is seated by being energized. A heating device 22 that heats the surface S, a toilet seat temperature sensor 23 that is disposed inside the toilet seat 20 and detects the temperature of the seating surface S, and an indoor temperature sensor 12 that detects the temperature of the room in which the toilet seat 20 is disposed. And a seating detection device 11 that detects the seating of the user on the seating surface S, and a control device 13 that controls at least the heating device 22. The control device 13 obtains the selected temperature acquisition unit 13a that acquires the set temperature selected by the user from among the plurality of set temperatures as the selected temperature Ths, and the selected temperature Ths acquired by the selected temperature acquisition unit 13a. The target temperature setting unit 13b that sets the target temperature Tht and the temperature of the seating surface S detected by the toilet seat temperature sensor 23 are heated to the target temperature Tht of the seating surface S set by the target temperature setting unit 13b. The temperature control unit 13c for controlling the energization amount of the device 22 and the number of times the user is seated detected by the seating detection device 11 in each of the plurality of time zones by dividing the time of the day into a plurality of time zones. The use number deriving unit 13g for deriving the number of use times, which is the number of times the user has used the toilet seat unit 20, for each of a plurality of time zones, and the indoor temperature sensor 12 The target of the seating surface S set by the target temperature setting unit 13b in each of a plurality of time zones according to the use number derived by the use number deriving unit 13g and the selection temperature Ths acquired by the selection temperature acquisition unit 13a. A target temperature changing unit 13k that changes the temperature Tht.

  According to this, the toilet seat device 1 changes the target temperature Tht of the seating surface S in accordance with the indoor temperature, the number of times the user has used, and the selected temperature Ths that is the set temperature selected by the user. Therefore, even when the daily temperature change is relatively large, the temperature of the seating surface S can be appropriately changed. Therefore, it is possible to suppress a decrease in user comfort with respect to the temperature of the toilet seat 20.

  Moreover, the toilet seat apparatus 1 changes the target temperature Tht of the seating surface S according to a user's use frequency. For this reason, when the frequency | count of a user's usage is comparatively few, it can suppress changing so that the temperature of the seating surface S may become comparatively high. Therefore, it is possible to suppress a decrease in the comfort of the user with respect to the temperature of the toilet seat portion 20 while suppressing the power consumption of the toilet seat device 1.

  Further, the control device 13 detects, as the first time Tm1, a first time detection unit 13h that detects a time zone in which the number of uses derived by the use number deriving unit 13g is equal to or more than the first predetermined number among the plurality of time zones. The first state detector 13d detects the first state S1 in which the selected temperature Ths is equal to or lower than the first predetermined set temperature Thp1 and the indoor temperature detected by the indoor temperature sensor 12 is equal to or lower than the predetermined temperature Thps. And further. When the first state S1 is detected by the first state detecting unit 13d within the first time Tm1 detected by the first time detecting unit 13h, the target temperature changing unit 13k is set to the target temperature setting unit 13b at the first time Tm1. The target temperature Tht of the seating surface S set by is changed to a second predetermined set temperature Thp2 that is higher than the first predetermined set temperature Thp1 among the plurality of set temperatures.

  According to this, the selection temperature Ths which is the target temperature Tht of the seating surface S selected by the user within the first time Tm1 in which the number of times the user uses the first predetermined number or more of the day is the first. When the room temperature is equal to or lower than the predetermined set temperature Thp1 and the indoor temperature is equal to or lower than the predetermined temperature Thps, the toilet seat device 1 sets the target temperature Tht of the seating surface S to a second predetermined temperature higher than the first predetermined set temperature Thp1. Change to set temperature Thp2. Therefore, when the number of times of use is relatively large, when the indoor temperature is equal to or lower than the predetermined temperature Thps, the use of the toilet seat portion 20 is suppressed while the temperature of the seating surface S remains equal to or lower than the first predetermined set temperature Thp1. Is done. Therefore, it is possible to suppress a decrease in user comfort with respect to the temperature of the toilet seat 20.

  In addition, when the indoor temperature is equal to or lower than the predetermined temperature Thps, the toilet seat device 1 has the target temperature Tht of the seating surface S within the first time Tm1 in which the number of times the user uses the first predetermined number of times or more. Change to be higher. Therefore, when the frequency | count of a user's use is comparatively few, it is suppressed that the temperature of the toilet seat part 20 is changed so that it may become comparatively high. Therefore, the comfort of the user with respect to the temperature of the toilet seat portion 20 can be suppressed while suppressing the power consumption of the toilet seat device 1.

  In addition, the control device 13 detects, as the second time Tm2, a time zone in which the usage count derived by the usage count deriving unit 13g is equal to or more than the second predetermined count and less than the first predetermined count among the plurality of time zones. The second time detection unit 13i detects a second state S2 in which the selected temperature Ths is higher than the first predetermined set temperature Thp1 and the indoor temperature detected by the indoor temperature sensor 12 is higher than the predetermined temperature Thps. A state detector 13e. When the second state S2 is detected by the second state detection unit 13e within the second time Tm2 detected by the second time detection unit 13i, the target temperature changing unit 13k is set to the target temperature setting unit 13b at the second time Tm2. The target temperature Tht of the seating surface S set by is changed to the first predetermined set temperature Thp1.

  According to this, in the second time Tm2 in which the number of times of use of the user is more than the second predetermined number and less than the first predetermined number of times in the day, the selection is the target temperature Tht of the seating surface S selected by the user. When the temperature Ths is higher than the first predetermined set temperature Thp1 and the room temperature is higher than the predetermined temperature Thps, the toilet seat device 1 sets the first predetermined temperature Tht so as to lower the target temperature Tht of the seating surface S. Change to set temperature Thp1. Therefore, when the number of times of use by the user is relatively small, the temperature of the seating surface S can be set to a temperature at which the user does not feel cold according to the selected temperature Ths and the room temperature. Accordingly, it is possible to suppress a decrease in the comfort of the user with respect to the temperature of the toilet seat portion 20 while appropriately suppressing the power consumption of the toilet seat device 1.

  In addition, the control device 13 detects, as the third time Tm3, a time zone in which the number of uses derived by the use number deriving unit 13g is less than the second predetermined number of times less than the first predetermined number among the plurality of time zones. A third time detector 13j is further provided. The target temperature changing unit 13k sets the target temperature Tht of the seating surface S set by the target temperature setting unit 13b within the third time Tm3 detected by the third time detecting unit 13j to the first of the plurality of set temperatures. The temperature is changed to a second set temperature that is lower than the predetermined set temperature Thp1.

  According to this, the toilet seat device 1 sets the target temperature Tht of the seating surface S to the first within the third time Tm3 that is less than the second predetermined number of times less than the first predetermined number of times during the day. The second predetermined set temperature Thp2 is changed to be lower than the predetermined set temperature Thp1. Therefore, the temperature of the seating surface S can be lowered when the number of uses by the user is extremely small. Therefore, the power consumption of the toilet seat device 1 can be further appropriately suppressed.

  In the above-described embodiment, an example of the toilet seat device is shown. However, the present invention is not limited to this, and other configurations can be adopted. For example, although the toilet seat apparatus 1 is a warm water washing toilet seat, it may replace with this and may be a heating toilet seat without a washing apparatus. In this case, the toilet seat device 1 may not include the remote control device 40. Further, in this case, the selection switch SW2 may be provided in the toilet seat device body 10.

  In the above-described embodiment, the control device 13 includes the third time detection unit 13j. Alternatively, the control device 13 may not include the third time detection unit 13j. In this case, the second time detection unit 13i may detect the third time Tm3 that is used very little as the second time Tm2. That is, in this case, the second time detection unit 13i detects, as the second time Tm2, a time zone in which the number of uses derived by the use number deriving unit 13g is less than the first predetermined number among the plurality of time zones. . In this case, in the time charts shown in FIGS. 9 and 11, the first to third time zones i to iii correspond to the second time Tm2, but are not in the second state S2, and therefore the target temperature Tht is The selected temperature Ths is set.

  In the above-described embodiment, the control device 13 includes both the first time detection unit 13h and the second time detection unit 13i, but instead of this, the first time detection unit 13h and the second time detection unit. One of the parts 13i may be omitted.

  When the control device 13 does not include the second time detection unit 13i, the target temperature Tht of the seating surface S is not changed even when the second state S2 is detected when the number of times of use is relatively small. In this case, the second state detection unit 13e may not be provided.

  On the other hand, when the control device 13 does not include the first time detection unit 13h, the target temperature Tht of the seating surface S is not changed even when the first state S1 is detected when the number of times of use is relatively large. In this case, the first state detection unit 13d may not be provided.

  In the above-described embodiment, the seating detection device 11 is an infrared distance sensor, but instead of this, a pyroelectric sensor that detects infrared rays emitted by the user's human body, or a Doppler that uses microwaves. A sensor may be used.

  Further, within a range not departing from the gist of the present invention, the arrangement positions of the temperature sensors 12, 23, the arrangement of the heating elements 22b, the shape of the toilet seat portion 20, the number of time zones, and the predetermined set temperatures Thp1, Thp2, The set temperature corresponding to Thp3 may be changed.

  DESCRIPTION OF SYMBOLS 1 ... Toilet seat apparatus, 2 ... Toilet room (room), 11 ... Seating detection apparatus, 12 ... Indoor temperature sensor (2nd temperature sensor), 13 ... Control apparatus, 13a ... Selected temperature acquisition part, 13b ... Target temperature setting part, 13c ... Temperature control unit, 13d ... First state detection unit, 13e ... Second state detection unit, 13f ... Storage unit, 13g ... Use count deriving unit, 13h ... First time detection unit, 13i ... Second time detection unit, 13j ... third time detection unit, 13k ... target temperature changing unit, 20 ... toilet seat unit, 22 ... heating device, 23 ... toilet seat temperature sensor (first temperature sensor), S ... seating surface, S1 ... first state, S2 ... Second state, Thp1 ... first predetermined set temperature, Thp2 ... second predetermined set temperature, Thp3 ... third predetermined set temperature, Thps ... predetermined temperature, Ths ... selected temperature, Tht ... target temperature, Tm1 ... first Time, Tm2 ... Second time, Tm ... third time.

Claims (4)

A toilet seat having a seating surface on which the user is seated when used by a user;
A heating device that is disposed inside the toilet seat and that heats the seating surface when energized;
A first temperature sensor disposed inside the toilet seat and detecting the temperature of the seating surface;
A second temperature sensor for detecting the temperature in the room where the toilet seat is disposed;
A seating detection device for detecting the seating of the user on the seating surface;
A toilet seat device comprising at least a control device for controlling the heating device,
The control device includes:
A selected temperature acquisition unit that acquires a set temperature selected by the user among a plurality of set temperatures as a selected temperature;
A target temperature setting unit that sets the selected temperature acquired by the selected temperature acquisition unit to a target temperature of the seating surface;
A temperature control unit that controls an energization amount of the heating device so that a temperature of the seating surface detected by the first temperature sensor becomes a target temperature of the seating surface set by the target temperature setting unit;
The number of times that the user has used the toilet seat portion is determined by dividing the time of the day into a plurality of time zones, and the number of times the user has been seated detected by the seating detection device in each of the plurality of time zones. A use number deriving unit for deriving each of the plurality of time periods as the number of use times
According to the indoor temperature detected by the second temperature sensor, the use frequency derived by the use frequency deriving unit, and the selected temperature acquired by the selected temperature acquisition unit, in each of the plurality of time zones. A toilet seat device comprising: a target temperature changing unit that changes a target temperature of the seating surface set by the target temperature setting unit. The control device includes:
A first time detection unit for detecting, as a first time, a time zone in which the number of uses derived by the use number deriving unit is equal to or more than a first predetermined number of times among the plurality of time zones;
A first state detecting unit for detecting a first state in which the selected temperature is equal to or lower than a first predetermined set temperature and the indoor temperature detected by the second temperature sensor is equal to or lower than a predetermined temperature; Prepared,
The target temperature changing unit is
The seating surface set by the target temperature setting unit during the first time when the first state is detected by the first state detection unit within the first time detected by the first time detection unit The toilet seat device according to claim 1, wherein the target temperature is changed to a second predetermined set temperature that is higher than the first predetermined set temperature among the plurality of set temperatures. The control device includes:
A second time detection unit that detects, as a second time, a time zone in which the number of uses derived by the use number deriving unit is less than a first predetermined number of times among the plurality of time zones;
A second state detecting unit that detects a second state in which the selected temperature is higher than a first predetermined set temperature and the indoor temperature detected by the second temperature sensor is higher than a predetermined temperature; and
The target temperature changing unit is
The seating surface set by the target temperature setting unit during the second time when the second state is detected by the second state detection unit within the second time detected by the second time detection unit The toilet seat device according to claim 1, wherein the target temperature is changed to the first predetermined set temperature. The control device includes:
A third time detection unit for detecting, as a third time, a time zone in which the number of uses derived by the use number deriving unit is less than a second predetermined number of times less than the first predetermined number among the plurality of time zones. Further comprising
The target temperature changing unit is
The target temperature of the seating surface set by the target temperature setting unit within the third time detected by the third time detection unit is set to be higher than the first predetermined set temperature among the plurality of set temperatures. The toilet seat device according to claim 2, wherein the toilet seat device is changed to a low second set temperature.

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