JP2016121459A - Urinal flushing device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a urinal flushing device which can suppress erroneous detection.SOLUTION: A urinal flushing device according to the present invention includes a human body sensor for generating an ultrasonic pulse and transmitting the ultrasonic pulse toward a prescribed region in which a user of a urinal is positioned and receiving a reflection wave of the ultrasonic pulse, a detection section for detecting the reflection wave from an output signal of the human body sensor and invalidating the output signal of the human body sensor after a lapse of prescribed time in which arrival of the reflection wave is expected, and a washing section for washing the urinal based on the detection result of the detection section.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a urinal washing apparatus.

  As a toilet cleaning device, there is a cleaning device that detects a user and automatically discharges cleaning water (Patent Document 1). This type of cleaning apparatus includes, for example, an ultrasonic sensor as a sensor for detecting a user. According to this cleaning apparatus, for example, when the user leaves the urinal based on the detection result of the ultrasonic sensor, the cleaning water can be automatically discharged.

JP-A 63-212275

  The ultrasonic sensor provided in the above-described cleaning apparatus is attached to, for example, a wall surface on which a urinal is installed. When a urinal is placed on each of two walls facing each other in a public toilet, etc., the urinal cleaning device sensor installed on one wall surface is the urinal cleaning device installed on the other wall surface. A situation can occur that faces the other sensor. In such a situation, both sensors may interfere with each other and erroneous detection may occur.

  In addition, even when the urinal is installed only on one wall surface, if the distance between the wall surface where the urinal is installed and the wall surface on the opposite side is short, the ultrasonic wave sent from the sensor of the cleaning device May be reflected by the wall surface on the opposite side, and the reflected wave may be received by the sensor of the cleaning device. In this case, the cleaning device may be operated even though the facing wall is erroneously detected as a user and the user is absent.

  The present invention has been made in view of the above circumstances, and an object thereof is to provide a urinal washing apparatus capable of suppressing erroneous detection.

In order to solve the above-described problems, a urinal washing apparatus according to the present invention generates and transmits an ultrasonic pulse toward a predetermined area where a user of the urinal is located, and receives a reflected wave of the ultrasonic pulse. A human body sensor, and a detection unit that detects the reflected wave from the output signal of the human body sensor and invalidates the output signal of the human body sensor after a predetermined time after the arrival of the reflected wave has elapsed, A urinal washing device comprising: a washing unit for washing the urinal based on a detection result of the detection unit.
According to this configuration, since the distance can be calculated from the time until the ultrasonic pulse is received as the reflected wave, a user existing in a predetermined region (distance) can be detected. Thereby, for example, it is possible to suppress malfunction due to mutual interference of ultrasonic pulses between urinals arranged face-to-face, and malfunction due to interference of reflected waves on a wall or the like.

In the urinal washing apparatus, for example, the human body sensor is provided inside or outside the stool of the urinal.
According to this configuration, even when the user approaches the urinal, the distance between the human body sensor and the user can be kept constant. Accordingly, it is possible to suppress malfunction due to a reflected wave from the vicinity of the human body sensor.

In the urinal washing apparatus, for example, the ultrasonic pulse generated by the human body sensor is composed of a pulse train including a plurality of pulses in one cycle, and the number of the plurality of pulses is variable.
According to this configuration, the detection sensitivity can be adjusted by adjusting the number of ultrasonic pulses in accordance with the environment of the installation location of the urinal. Therefore, the detection sensitivity can be set according to the environment of the place where the urinal is installed.

In the urinal washing apparatus, for example, the ultrasonic pulse generated by the human body sensor is composed of a pulse train including a plurality of pulses in one cycle, and the repetition cycle of the pulse train is variable.
According to this configuration, it is possible to prevent erroneous detection while obtaining necessary detection sensitivity by adjusting the period of the ultrasonic pulse train in accordance with the environment of the installation location of the urinal. Therefore, power consumption can be suppressed.

In the urinal washing apparatus, for example, the ultrasonic pulse generated by the human body sensor is composed of a pulse train including a plurality of pulses in one cycle, and the repetition cycle of the pulse train is set at random. .
According to this configuration, since the probability that the timing is different from the timing of the ultrasonic pulse output from another cleaning apparatus is increased, erroneous detection due to interference can be further effectively suppressed.

In the urinal washing apparatus, for example, when the pulse train is continuously detected a plurality of times, the detection unit determines that the reflected wave has been detected.
According to this configuration, for example, when interference of ultrasonic pulses occurs temporarily, such as when a person simply passes in front of a urinal, the detection result is not fixed. For this reason, erroneous detection can be prevented.

In the urinal washing apparatus, for example, when the detection unit detects the pulse train N times (N is a predetermined natural number smaller than M) when the number of the pulse trains is M, the reflected wave is detected. It is characterized by determining that it has been detected.
According to this configuration, if any N pulse trains among the M pulse trains are detected, the detection of the reflected wave is confirmed, so that the detection of the reflected wave can be made flexible. Therefore, for example, when receiving a reflected wave, the reflected wave can be detected stably even if some of the M pulse trains are not detected.

  According to the present invention, erroneous detection can be suppressed.

BRIEF DESCRIPTION OF THE DRAWINGS It is an external view which shows an example of the urinal provided with the urinal washing apparatus by 1st Embodiment of this invention, (A) is a perspective view of a urinal, (B) is a side view of a urinal It is. It is a block diagram showing an example of composition of a urinal washing device by a 1st embodiment of the present invention. It is a timing chart for demonstrating an example of operation | movement of the urinal washing apparatus by 1st Embodiment of this invention. It is a timing chart for demonstrating an example of operation | movement of the urinal washing apparatus by 2nd Embodiment of this invention. It is a timing chart for demonstrating an example of operation | movement of the urinal washing apparatus by 3rd Embodiment of this invention.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
In the following embodiments, the term “pulse train” refers to a set of a plurality of pulses generated in time series. The term “ultrasonic pulse” refers to a sound wave generated based on one pulse train. Furthermore, the term “ultrasonic pulse train” refers to a plurality of ultrasonic pulses generated in time series.
(First embodiment)
FIG. 1 is an external view showing an example of a urinal 2 provided with the urinal washing device 1 according to the first embodiment of the present invention, and FIG. 1 (A) is a perspective view of the urinal 2. 1 (B) is a side view of the urinal 2.

  The urinal 2 provided with the urinal washing device 1 includes a toilet bowl portion 2A and is attached to the wall 3 of the toilet room. As shown in FIG. 1 (A), a spout 2B for discharging wash water is provided above the toilet bowl 2A. Moreover, the toilet bowl washing | cleaning apparatus 1 is integrated in the toilet bowl part 2A so that it may be located above the spout 2B. The urinal washing device 1 is an element for detecting a user of the urinal 2 and discharging washing water from the water outlet 2B. As will be described later, the urinal cleaning device 1 detects a user using an ultrasonic pulse.

  In the example of FIGS. 1A and 1B, the urinal washing apparatus 1 is schematically shown so as to be positioned above the water outlet 2B, but the constituent elements thereof are appropriate places of the urinal 2. The human body sensor 71 (ultrasonic sensor) of FIG. 2 described later included in the urinal cleaning device 1 is disposed at least above the spout 2B. In addition, the human body sensor 7 can be arrange | positioned in arbitrary positions, as long as it can detect a user not only above the spout 2B.

Next, an example of the environment where the urinal 2 is installed will be described.
In the example shown in FIG. 1B, the distance between the wall 3 to which the urinal 2 is attached and the facing wall 4 is 950 mm, and the human body described later provided in the urinal washing device 1 of the urinal 2 The distance from the sensor 71 to the wall 4 on the facing side is 850 mm. Further, the distance from the wall 3 to the distal end portion of the urinal 2 is 300 mm, and the distance from the distal end portion of the urinal 2 to the facing wall 4 is 650 mm. Under such circumstances, when there is no user of the urinal 2, the ultrasonic pulse transmitted from the urinal cleaning device 1 is reflected by the facing wall 4, and the reflected wave of the urinal cleaning device 1 The case where the human body sensor 71 is reached may occur. That is, the environment in which the urinal 2 is installed is an environment in which the wall 4 can be erroneously detected as a user. In addition, the installation environment of the urinal 2 is not limited to the example shown in FIG. 1 (B), and is arbitrary. For example, a cleaning device similar to the urinal cleaning device 1 of the urinal 2 is provided on the wall 4 on the facing side. Another urinal provided with may be attached. That is, the urinal washing device 1 may be provided in each of a plurality of urinals arranged facing each other.

Next, the configuration of the urinal cleaning device 1 will be described.
FIG. 2 is a block diagram showing an example of the configuration of the urinal washing device 1 according to the first embodiment of the present invention. The urinal cleaning device 1 includes a human body sensor 71, a drive unit 72, a control unit 73, and a cleaning device 74. The drive unit 72 includes a transmission circuit 721, a reception circuit 722, and a control circuit 723. The human body sensor 71 is a human body detection sensor that detects a user of the urinal 2 and is specifically an ultrasonic sensor. The human body sensor 71 generates and transmits an ultrasonic pulse toward a predetermined region where the user of the urinal 2 is located, receives a reflected wave of the ultrasonic pulse, and outputs a reception signal.

  As shown in FIGS. 1 (A) and 1 (B), the human body sensor 71 is provided above the water outlet 2B for discharging washing water and is exposed to the inner surface of the toilet bowl 2A. It has been. The orientation of the human body sensor 71 is set so that the ultrasonic pulse transmitted from the human body sensor 71 is directed toward the body of the user standing in front of the urinal 2. However, it is not limited to this example, and the installation site of the human body sensor 71 is arbitrary as long as the user can be detected. For example, the human body sensor 71 may be installed on the outer side surface of the toilet bowl portion 2A, or may be attached to the walls 3 and 4 or the ceiling. Further, if the user does not get too close to the human body sensor 71 (that is, a position where the user's detection by the human body sensor 71 is not hindered), the human body sensor 71 may be installed on the outer front surface of the toilet bowl 2A. . That is, the human body sensor 71 can be installed outside the toilet bowl 2A.

  The human body sensor 71 includes a piezoelectric element for generating an ultrasonic pulse (hereinafter referred to as a transmitting piezoelectric element) and a piezoelectric element for receiving a reflected wave (hereinafter referred to as a receiving piezoelectric element). Are integrated and incorporated. That is, one piezoelectric element has a function of generating an ultrasonic pulse and a function of receiving the reflected wave. The frequency of the ultrasonic pulse transmitted from the human body sensor 71 is set to 58 kHz, for example. Further, the horizontal radiation angle and the vertical radiation angle of the ultrasonic pulse transmitted from the human body sensor 71 are set to, for example, 50 ° and 28 °, respectively. Thereby, the human body sensor 71 has directivity.

  The human body sensor 71 can be any sensor as long as it can generate ultrasonic waves. The human body sensor 71 may be a separate sensor in which a transmitting piezoelectric element for generating an ultrasonic pulse and a receiving piezoelectric element for receiving a reflected wave are separated. Further, the frequency and radiation angle of the ultrasonic pulse transmitted from the human body sensor 71 can be arbitrarily set as long as the user of the urinal 2 can be detected.

  The transmission circuit 721 is an element for driving the human body sensor 71. The transmission circuit 721 includes a signal generation circuit 7211 and a drive circuit 7212. The signal generation circuit 7211 is an element for generating a pulse wave signal (rectangular wave) based on a transmission signal STX supplied from a control circuit 723 described later. The drive circuit 7212 is an element for driving the human body sensor 71 based on the pulse wave signal generated by the signal generation circuit 7211. The human body sensor 71 is driven by the drive circuit 7212 to generate and send an ultrasonic pulse.

  The receiving circuit 722 is an element for detecting the reflected wave from the output signal of the human body sensor 71 when the human body sensor 71 receives the reflected wave. The receiving circuit 722 has a function of invalidating the output signal of the human body sensor 71 after a predetermined time after the arrival of the reflected wave has elapsed since the ultrasonic pulse is transmitted from the human body sensor 71. . This function suppresses erroneous detection due to unnecessary received signals such as interference waves. Details thereof will be described later.

  The reception circuit 722 includes amplification circuits 7221 and 7222 and a detection circuit 7223. The amplifier circuits 7221 and 7222 are elements for amplifying the output signal of the human body sensor 71. The detection circuit 7223 is an element for extracting a reflected wave signal component from the signals amplified by the amplification circuits 7221 and 7222. The signal component of the reflected wave detected by the detection circuit 7223 is the received signal SRX. The detection circuit 7223 is composed of, for example, a half-wave rectifier circuit and a smoothing circuit.

  The control circuit 723 has a function as a signal detection circuit for calculating the distance to the detection target user (the distance between the human body sensor 71 and the user) from the reception signal SRX detected by the detection circuit 7223. It is an element that has. Specifically, the control circuit 723 is configured by a microcomputer, for example, and includes a comparator circuit and a logic circuit. The comparator circuit compares the signal level of the reception signal SRX detected by the detection circuit 7223 with a predetermined threshold value to determine the presence or absence of a reflected wave. The logic circuit calculates the distance to the detection target (user) using the time from when the ultrasonic pulse is transmitted from the human body sensor 71 until the reflected wave is received by the human body sensor 71. The control circuit 723 outputs information regarding the calculated distance to the control unit 73 as a signal D. This signal D represents the detection result of the control circuit 723 that functions as a signal detection circuit.

The control circuit 723 has a function of outputting the transmission signal STX to the signal generation circuit 7211 of the drive unit 72 based on an instruction from the control unit 73 in addition to the function as the above-described signal detection circuit.
The reception circuit 722 and the control circuit 723 described above detect the reflected wave from the output signal of the human body sensor 71, and after the predetermined time when the arrival of this reflected wave has passed, the output signal of the human body sensor 71 is invalidated. A detection unit is configured.
The control unit 73 is an element for controlling the entire operation of the urinal 2. For example, when the distance calculated by the control circuit 723 indicates that the user of the urinal 2 is in a predetermined area, the control unit 73 immediately or after the user leaves, from the spout 2B. A command for discharging the cleaning water is output to the cleaning device 74.

  The cleaning device 74 is an element that functions as a cleaning device (cleaning unit) for cleaning the urinal 2 based on the detection result of the control circuit 723 serving as a signal detection circuit. The cleaning device 74 receives the signal D representing the detection result of the control circuit 723 and cleans the urinal 2 by discharging cleaning water from the water outlet 2B over a predetermined time based on a command output from the control unit 73. The cleaning device 74 includes, for example, a piping unit for guiding cleaning water from a predetermined water source to a water discharge port, a valve for controlling water discharge and water stop, a driving device for controlling opening and closing of the valve, and the like. . It is not limited to this example, The structure of the washing | cleaning apparatus 74 is arbitrary.

Next, the operation of the urinal washing apparatus 1 according to the first embodiment will be described with reference to FIG.
FIG. 3 is a timing chart for explaining an example of the operation of the urinal washing apparatus 1 according to the first embodiment of the present invention.

  The drive circuit 7212 of the transmission circuit 721 drives the human body sensor 71 at a predetermined cycle T (for example, 50 ms) based on the pulse wave signal supplied from the signal generation circuit 7211. Thereby, the human body sensor 71 generates an ultrasonic pulse at a predetermined period T.

  Specifically, the control circuit 723 of the drive unit 72 generates a trigger signal STR having a predetermined period T based on an instruction from the control unit 73. Then, the control circuit 723 outputs a transmission signal STX including a pulse train composed of a plurality of pulses at a period T defined by the trigger signal STR. Here, a part of a period of one cycle of the trigger signal STR in which a pulse train composed of a plurality of pulses exists is defined as a transmission period T1. In the example of FIG. 3, a pulse train composed of five pulses exists in the transmission period T1 from time t1 to time t2 when the trigger signal STR is generated. However, the present invention is not limited to this example, and the number of pulses forming the pulse train in the transmission period T1 can be set to an arbitrary number such as 10, 20, or the like. By driving the human body sensor 71 based on the transmission signal STX including the pulse train, an ultrasonic pulse having a frequency component corresponding to the generation cycle of the pulses forming the pulse train is generated in the transmission period T1. Since the transmission period T1 repeatedly arrives at the period T defined by the trigger signal STR, the ultrasonic pulse is repeatedly generated at the period T.

  There is no pulse of the transmission signal STX in a period from time t2 when the pulse train ends to time t9 when the next cycle starts (that is, a period other than the transmission period T1). Hereinafter, for convenience of explanation, a signal section of the transmission signal STX corresponding to one cycle of the trigger signal STR is referred to as a “pulse block”. The period of the trigger signal STR coincides with the repetition period of the pulse block. The repetition period of the pulse block is also the repetition period of the pulse train in the transmission period T1.

  The cycle T of the trigger signal STR, that is, the repetition cycle of the pulse train in the transmission period T1, is variable. For example, the cycle T is set to an arbitrary value through the signal Tx from the control unit 73 by a dip switch (not shown) provided in the control unit 73. It is possible to do. For example, the repetition period of the pulse train given by the period T of the trigger signal STR is arbitrarily set to 250 ms, 1 s, 3 s, etc., and preferably the period T is set in the range of 50 to 250 ms. Further, the number of pulses forming the pulse train in the transmission period T1 is variable, and can be set to an arbitrary value by, for example, a dip switch. However, in the first embodiment, the period T of the trigger signal STR is fixed to a predetermined setting value, and the number of pulses forming the pulse train of the transmission signal STX in the transmission period T1 is also fixed to the predetermined setting value. It shall be. Note that that the cycle T of the trigger signal STR is variable means that the cycle of the transmission signal STX and a reception signal SRX described later is variable.

  When the trigger signal STR rises at time t1, the signal generation circuit 7211 generates a pulse wave signal corresponding to the transmission signal STX based on the transmission signal STX supplied from the control circuit 723 in the transmission period T1 from time t1 to time t2. Is generated. The drive circuit 7212 drives the human body sensor 71 based on the pulse wave signal generated by the signal generation circuit 7211 in the transmission period T1. Accordingly, the human body sensor 71 generates and transmits an ultrasonic pulse in the transmission period T1 of each cycle defined by the trigger signal STR based on the transmission signal STX.

  Here, the human body sensor 71 mechanically vibrates in order to generate an ultrasonic pulse in the transmission period T1 from time t1 to time t2, but after the pulse of the transmission signal STX disappears at time t2, Reverberation occurs due to the remaining mechanical vibration of the human body sensor 71 in the reverberation period T2 from t2 to time t3. For this reason, an ultrasonic pulse due to reverberation is generated in the reverberation period T2. Thus, the human body sensor 71 is driven based on the transmission signal STX output from the control circuit 723, and it is assumed that the user of the urinal 2 is present in the ultrasonic pulse generated by the human body sensor 71. Sent toward the area.

  As described above, when the control circuit 723 generates the trigger signal STR at the time t1, the control circuit 723 grasps the timing at which the ultrasonic pulse is transmitted from the human body sensor 71 at the time t1. Then, the control circuit 723 starts measuring time t1 as a starting point, and at time t4 after the reverberation of the human body sensor 71 has converged, the signal level of the reception permission signal SRW is changed to a high level. At the elapsed time t7, the signal level of the reception permission signal SRW is changed to a low level.

  Here, the reception permission signal SRW includes a period in which the reflected wave can be received and the output signal of the human body sensor 71 is treated as an effective signal, and a period in which the reception of the reflected wave is disabled and the output signal of the human body sensor 71 is invalidated. Is a signal that prescribes During a period when the reception permission signal SRW is at the high level, the control circuit 723 enables reception of the reflected wave, treats the reception signal SRX output from the detection circuit 7223 as an effective signal, and detects the reflection wave from the reception signal SRX. . On the other hand, during the period when the reception permission signal SRW is at the low level, the control circuit 723 disables the reception of the reflected wave, and even if the reception signal SRX output from the detection circuit 7223 exists, this is regarded as an invalid signal. Handles and does not detect reflected waves. In the present embodiment, the reception permission signal SRW is set from the high level to the low level after detecting the reflected wave, thereby making it impossible to receive an unnecessary wave such as an interference wave and suppressing erroneous detection due to the unnecessary wave. The signal level of the reception permission signal SRW can be arbitrarily defined. For example, contrary to the above example, the reception permission signal SRW may be at a low level during a period in which the reception signal SRX is valid, and the reception permission signal SRW may be at a high level during a period in which the reception signal SRX is invalid.

The reception permission signal SRW is generated so as to satisfy the following first to fourth conditions.
First condition: The timing at which the reception permission signal SRW transitions from the low level to the high level (the timing at which the detection of the reflected wave is started) is the timing at which the sum of the transmission period T1 and the reverberation period T2 of the human body sensor 71 has elapsed. Be. In the example of FIG. 3, the timing at which the reception permission signal SRW transitions from the low level to the high level is time t4, which is later than time t3 when the reverberation period T2 ends. This first condition is a condition for preventing the human body sensor 71 from erroneously detecting its own mechanical vibration (including reverberation) as a reflected wave.
When a separate sensor in which the transmitting piezoelectric element and the receiving piezoelectric element are separated is used as the human body sensor 71, no interference occurs between the transmitting piezoelectric element and the receiving piezoelectric element. The first condition can be omitted.

Second condition: The timing at which the reception permission signal SRW transitions from the high level to the low level (the timing at which the detection of the reflected wave is stopped) is reflected by the ultrasonic pulse transmitted from the human body sensor 71 and reflected by the user. The timing after the timing when the wave reaches the human body sensor 71. In the example of FIG. 3, the timing at which the reception permission signal SRW transitions from the high level to the low level is time t7, which is later than time t5 when the reception signal SRX by the reflected wave is generated. This second condition is a condition for avoiding that the output signal of the human body sensor 71 is invalidated and the detection of the reflected wave is stopped before the reflected wave from the user reaches the human body sensor 71.

Third condition: The timing at which the reception permission signal SRW transitions from the high level to the low level (the timing at which the detection of the reflected wave is stopped) is earlier than the timing at which the sound wave assumed as an unnecessary wave reaches the human body sensor 71. Be. For example, when the reflected wave from the facing wall 4 shown in FIG. 1B is an unnecessary wave, in the example of FIG. 3, the timing at which a sound wave assumed as an unnecessary wave reaches the human sensor 71 is the human sensor. It is time t8 when the ultrasonic pulse transmitted from 71 is reflected by the facing wall 4 and the reflected wave reaches the human body sensor 71. In this case, the timing at which the reception permission signal SRW transitions from the high level to the low level (the timing at which the detection of the reflected wave is stopped) is set at time t7, which is earlier than time t8. The third condition is a condition for suppressing erroneous detection due to unnecessary waves such as interference waves. The earlier the timing at which the reception permission signal SRW transitions from the high level to the low level, the more effective the effect of suppressing erroneous detection due to unnecessary waves. Therefore, it is preferable to set the timing at which the reception permission signal SRW transitions from the high level to the low level (timing to stop the detection of the reflected wave) as early as possible within a range that does not inhibit the next fourth condition. .

Fourth condition: a period between the timing when the reception permission signal SRW transitions from the low level to the high level and the timing when the reception permission signal SRW transitions from the high level to the low level (a period during which the reflected wave can be detected) That is, the period T4 in which the reception permission signal SRW is at a high level is a period sufficient to detect a reflected wave from the reception signal SRX. In the example of FIG. 3, the period during which the reception permission signal SRW is at the high level is a period from time t4 to time t7 including a period from time t5 to time t6 when the pulse of the reception signal SRX is generated. The fourth condition is a condition for ensuring a minimum period necessary for detecting a reflected wave from the reception signal SRX. In the example of FIG. 3, the period during which the reception permission signal SRW is at a high level includes the entire period from time t5 to time t6 when the pulse of the reception signal SRX is generated, but a reflected wave is detected from the reception signal SRX. If the minimum period required for the reception can be secured, the period during which the reception permission signal SRW is at the high level is a part of the period from the time t5 to the time t6 when the pulse of the reception signal SRX is generated. May be included.

  In an environment where a plurality of urinals are arranged facing each other, unnecessary waves (interference waves) transmitted from the urinal on the facing side are generated during the generation period of the pulse of the reception signal SRX assumed when there is a user. May be received. In this case, erroneous detection may occur. However, if the high-level period T4 of the reception permission signal SRW defined by the above-described fourth condition is shortened, erroneous detection due to unnecessary waves when the urinals are arranged face-to-face The frequency can be reduced.

An example of each timing when a user exists will be described.
In the installation environment as shown in FIG. 1B, when the distance from the human body sensor 71 to the user is 400 mm, the period T3 including the transmission period T1 and the reverberation period T2 is set to 1.7 ms, and the reception permission signal SRW The high level period (reception permission period) T4 is set to 0.6 ms. In this example, if the time for which the ultrasonic pulse transmitted from the human body sensor 71 reciprocates between the human body sensor 71 and the user (800 mm = 0.8 m in the reciprocation) is the reflection time, the reflection time is 0. .8 [m] /346.7 [m / s] = 2.307 ms. In FIG. 3, this reflection time corresponds to the time from time t1 when the pulse train of the transmission signal STX starts to time t5 when the pulse train of the reception signal SRX by the reflected wave starts.

  Therefore, the time (t4 to t5) from when the reception permission signal SRW changes to the high level at time t4 to when the pulse of the reception signal SRX by the reflected wave is generated at time t5 is from the above time t1 to time t5. By subtracting the period T3 (1.7 ms) including the transmission period T1 and the reverberation period T2 from the reflection time (2.307 ms) corresponding to the time of 0.607 ms, 0.607 ms is obtained. According to the second condition described above, the timing at which the reception permission signal SRW transitions from the high level to the low level (hereinafter referred to as the first timing) reflects the ultrasonic pulse transmitted from the human body sensor 71 to the user. The timing after the reflected wave reaches the human body sensor 71 (hereinafter referred to as the second timing). For this reason, the lower limit of the first timing is the second timing. When the first timing matches the second timing, the high-level period of the reception permission signal SRW is 0.607 ms in the above example.

An example of each timing when there is no user will be described.
In the installation environment as shown in FIG. 1B, when there is no user, the reflection time is defined as the time for reciprocating between the human body sensor 71 and the wall 4 on the facing side (1700 mm = 1.7 m when reciprocating). For example, the reflection time is 1.7 [m] /346.7 [m / s] = 4.903 ms. This reflection time corresponds to the time from time t1 to time t8 in FIG. Therefore, the timing until the ultrasonic pulse transmitted from the human body sensor 71 is reflected by the wall 4 and the reflected wave reaches the human body sensor 71 is after the timing when the reception permission signal SRW transits from the high level to the low level. It is. For this reason, the erroneous detection resulting from the reflected wave from the wall 4 is prevented.

  When the reception permission signal SRW that satisfies the first condition to the fourth condition becomes high level at time t4, the control circuit 723 receives the reception signal SRX supplied from the detection circuit 7223 (that is, the output signal of the human body sensor 71). ) As a valid signal. Then, during the period from time t5 to time t6, a reception signal SRX including a pulse train based on a reflected wave generated when a user exists is supplied from the detection circuit 7223 to the control circuit 723. The control circuit 723 detects a reflected wave from the pulse train of the reception signal SRX supplied from the detection circuit 7223. Then, the control circuit 723 outputs a signal D indicating that the reflected wave has been detected to the control unit 73. The control unit 73 receives the signal D and outputs a command related to the cleaning operation to the cleaning device 74. In the first embodiment, if even one pulse train of the reception signal SRX corresponding to the pulse train of the transmission signal STX is detected, the control circuit 723 outputs a signal D indicating that a reflected wave has been detected.

  When the reception permission signal SRW transits from the high level to the low level at time t7, the control circuit 723 processes the reception signal SRX (that is, the output signal of the human body sensor 71) supplied from the detection circuit 7223 as an invalid signal. To do. Specifically, the control circuit 723 outputs a signal D indicating that the reflected wave is not detected to the control unit 73 regardless of the reception signal SRX supplied from the detection circuit 7223. In this case, the control unit 73 does not output a cleaning command to the cleaning device 74, and the cleaning device 74 stands by without performing cleaning.

Even when a reflected wave from the facing wall 4 is received by the human body sensor 71 at time t8 after time t7, the control circuit 723 invalidates the reception signal SRX by this reflected wave and does not detect the reflected wave. . Therefore, erroneous detection due to the reflected wave from the facing wall 4 is prevented.
Thereafter, at time t9, the trigger signal STR of the next cycle is generated and the same operation is repeated.

  According to the first embodiment described above, the distance between the human body sensor 71 and the user of the urinal 2 is calculated from the time when the reflected wave of the ultrasonic pulse transmitted from the human body sensor 71 reaches the human body sensor 71. Since the reception signal SRX is invalidated after a lapse of a predetermined time defined by the reception permission signal SRW, it is possible to accurately detect the user while suppressing the influence of disturbances such as interference waves and the like. Can be suppressed. In particular, it suppresses the erroneous detection due to the reflected wave from the opposite wall 4 facing the wall 3 where the urinal 2 is installed and the ultrasonic pulse transmitted from the sensor of the facing urinal disposed on the wall 4 can do. In the present embodiment, it is possible to suppress erroneous detection simply by providing a configuration for generating the waveform of the reception permission signal SRW, and thus it is possible to simplify measures for preventing erroneous detection. Therefore, the apparatus configuration can be simplified and the design man-hour can be shortened.

  Moreover, according to 1st Embodiment, since the human body sensor 71 was arrange | positioned inside the toilet bowl part 2A, a fixed distance can be maintained between the human body sensor 71 and the user of the urinal 2. That is, the position of the user can be restricted so that the user does not get too close to the human body sensor 71. For this reason, a reflected wave can be received in a period avoiding the transmission period T1 and the reverberation period T2, and erroneous detection due to the reverberation or the like of the human body sensor 71 can be prevented. The same applies to the case where the human body sensor 71 is disposed on the outer side surface of the toilet bowl 2A.

  In addition, according to the first embodiment, since the cycle of the ultrasonic pulse transmitted from the human body sensor 71 is variable, the number of oscillations per unit time of the ultrasonic pulse can be changed, thereby improving the detection sensitivity. Can be changed. For example, when a secondary battery such as a battery is used as the power source of the urinal cleaning apparatus 1, the ultrasonic pulse repetition period (trigger signal STR and period T) is determined by a signal Tx in accordance with a decrease in the remaining amount of the secondary battery. If the length is increased, the power consumption of the urinal cleaning device 1 can be suppressed, and the life of the secondary battery can be extended. Accordingly, it is possible to extend the operation time of the urinal cleaning device 1.

  Further, according to the first embodiment, since the number of pulses included in the transmission signal STX for one cycle is made variable, the detection sensitivity can be changed. Thereby, for example, when an erroneous detection occurs due to a decrease in the number of pulses of the reception signal SRX due to an environment in which the urinal 2 is installed, it is required by increasing the number of pulses included in the transmission signal STX. Detection sensitivity can be ensured. Therefore, the operator can easily cope with the urinal 2 installation site.

In addition, since an ultrasonic sensor is used as the human body sensor 71, the appearance color of the human body sensor 71 can be easily matched with the color scheme of the urinal 2. Therefore, the influence given to the design of urinal 2 can be controlled.
In addition, since an ultrasonic sensor is used as the human body sensor 71, the temperature characteristic is superior to that of a pyroelectric sensor, and deterioration of detection sensitivity due to temperature change can be suppressed.
Moreover, since the ultrasonic sensor excellent in directivity is used as the human body sensor 71, the detection area can be limited, and ultrasonic pulses can be transmitted efficiently.
In addition, since an ultrasonic sensor is used as the human body sensor 71, the apparatus cost can be reduced as compared with the case where another sensor such as a radio wave sensor is used.

(Second Embodiment)
Next, a second embodiment of the present invention will be described.
FIG. 4 is a timing chart for explaining an example of the operation of the urinal washing apparatus according to the second embodiment of the present invention.
In the first embodiment described above, the cycle T of the trigger signal STR generated by the control circuit 723 (that is, the cycle of the pulse block shown in FIG. 3) is fixed to, for example, 50 ms by the dip switch. For this reason, in the first embodiment, the cycle T of the transmission signal STX is a fixed cycle, and the cycle of the ultrasonic pulse generated by the human body sensor 71 is fixed. On the other hand, in the second embodiment, the control circuit 723 randomly generates the period T of the trigger signal STR, and the length of each period of the transmission signal STX defined by the trigger signal STR is randomly determined for each period. Is set. Thereby, the period of the ultrasonic pulse generated by the human body sensor 71, that is, the repetition period of the pulse train composed of a plurality of pulses included in one period of the transmission signal STX (the period corresponding to the period of the pulse block shown in FIG. 3). Is set at random and varies from period to period. Others are the same as in the first embodiment.

Specifically, in the example of FIG. 4, the first cycle TA of the trigger signal STR starting from time t01 is set to 250 ms, and the next cycle TB starting from time t03 is set to 200 ms. Thus, each cycle of the trigger signal STR is set at random within a range of 50 ms to 250 ms, for example. In a predetermined transmission period (time t01 to t02, time t03 to t05,...) From the beginning of each cycle set at random in this manner, a pulse train of the transmission signal STX is generated as in the example of FIG. During the period, ultrasonic pulses are generated from the human body sensor 71.
The period of the trigger signal STR is not limited to the above-described range of 50 ms to 250 ms, and can be set to an arbitrary range as long as the influence of disturbance due to unnecessary waves such as interference waves can be suppressed.

  According to the second embodiment, since the length of each cycle of the transmission signal STX is set at random, when the urinal 2 is arranged face-to-face, both are arranged face-to-face compared to the first embodiment described above. The frequency at which both the reception permission signals SRW of the urinal washing devices provided in the urinal 2 become high level decreases. For this reason, the probability of receiving the ultrasonic pulse (interference wave) transmitted from the sensor of another urinal in the period when the reception permission signal SRW is at a high level is reduced. Therefore, erroneous detection can be further suppressed.

(Third embodiment)
Next, a third embodiment of the present invention will be described.
FIG. 5 is a timing chart for explaining an example of the operation of the urinal washing apparatus according to the third embodiment of the present invention. In FIG. 5, each of the pulses of the reception signal SRX in the period from time t13 to time t14 schematically represents five pulses forming the pulse train existing in the transmission period T1 from time t1 to time t2 in FIG. . Similarly, one pulse of the reception signal SRX at times t11, t15,... In FIG. 5 schematically represents a plurality of pulses forming a pulse train. Therefore, each pulse schematically shown in FIG. 5 represents one ultrasonic pulse. In the present embodiment, the number of pulses forming the pulse train of the reception signal SRX at times t11, t15, etc. other than the time t13 to t14 in FIG. 5 is the pulse train of the reception signal SRX from the time t13 to the time t14. However, the number of pulses constituting the pulse train represented by each pulse schematically shown in FIG. 5 is arbitrarily set, as long as the reflected wave of the ultrasonic pulse can be received. Can do.

  In the first embodiment described above, if even one of a plurality of pulse trains included in the received signal SRX is detected, a signal D indicating that a reflected wave has been detected is output. On the other hand, in the third embodiment, as will be described below, when the detection unit including the reception circuit 722 and the control circuit 723 detects a pulse train continuously from the reception signal SRX a plurality of times, Confirm that the reflected wave has been detected. Here, the expression that the pulse train is detected a plurality of times in succession is the process of detecting a plurality of pulse trains without missing the pulse train existing between the pulse train detected first and the pulse train detected last, This means that a plurality of pulse trains are detected. Others are the same as each of 1st Embodiment and 2nd Embodiment.

  More specifically, in a situation where there is no user, the control circuit 723 sets the cycle of the trigger signal STR to, for example, 250 ms, and repeatedly generates a pulse train of the transmission signal STX at a cycle of 250 ms. Then, the control circuit 723 generates an ultrasonic pulse based on the pulse train of the transmission signal STX at a cycle of 250 ms, and detects the presence or absence of the reflected wave. However, at this stage, even if some reflected wave exists, it is not determined that the reflected wave from the user is detected. Here, when a reflected wave of an ultrasonic pulse generated with a period of 250 ms is detected, the control circuit 723 sets the period of the trigger signal STR to, for example, 50 ms over a predetermined period, and is the same as in the first embodiment described above. For example, the transmission signal STX including a pulse train of five pulses is repeatedly generated 20 times with a period of 50 ms. Thereby, the human body sensor 71 generates the ultrasonic pulse 20 times with a period of 50 ms in the predetermined period. However, the number of pulse trains (number of ultrasonic pulses) generated in the predetermined period can be arbitrarily set as long as the continuity of the plurality of ultrasonic pulses (plural pulse trains) can be evaluated. When the 20 ultrasonic pulses are received by the human body sensor 71, as schematically shown in FIG. 5, the received signal SRX is transmitted in the period from time t13 to time t14 corresponding to the predetermined period. A pulse train corresponding to 20 pulse trains of the signal STX is included.

  When the control circuit 723 detects 20 pulse trains of the reception signal SRX corresponding to the 20 pulse trains of the transmission signal STX continuously, that is, when all the pulse trains in the period from the time t13 to the time t14 are detected, Confirm that the reflected wave from the user has been detected. Therefore, if even one of the 20 pulse trains is missing, it is not determined that a reflected wave from the user has been detected. Even if it is determined that a reflected wave from the user has been detected when a predetermined number or more of the 20 pulse trains (for example, 10 pulse trains) are continuously detected. Good. In this case, even if a predetermined number or more of pulse trains are detected, they are not continuous pulses (that is, one pulse train existing between the first pulse train and the last detected pulse train is missing). It is not determined that a reflected wave from the user has been detected.

According to the third embodiment, it is possible to prevent erroneous detection when a reflected wave from a person other than the user is temporarily generated. For example, when a person passes in front of the urinal 2, a pulse train of the reception signal SRX may occur temporarily (instantly) due to a reflected wave from the person. In this case, the reflected wave disappears after a person passes by. For this reason, the number of pulse trains included in the reception signal SRX is reduced, and the pulse trains are not detected continuously 20 times. For this reason, a person who simply passes in front of the urinal 2 is not detected as a user of the urinal 2. Therefore, according to the third embodiment, it is possible to prevent erroneous detection due to a reflected wave that is temporarily generated when a person passes in front of the urinal 2 and the like, and the accuracy of detection of the reflected wave from the user is prevented. Can be further improved.
In the third embodiment, as in the second embodiment, if the length of each cycle of the trigger signal STR is changed, erroneous detection can be further suppressed and detection accuracy can be further improved. it can.

(Fourth embodiment)
Next, a fourth embodiment of the present invention will be described.
In 4th Embodiment, the above-mentioned FIG. 5 is used.
In the third embodiment described above, when all or part of the 20 pulse trains included in the received signal SRX are continuously detected in the period from time t13 to time t14 in FIG. 5, a reflected wave from the user is detected. If a missing pulse train occurs even once in the middle, the detection of the reflected wave is not confirmed. In this case, the confirmation of the detection of the reflected wave is postponed to the next and subsequent cycles, and it may take a long time to confirm.

  Therefore, in the fourth embodiment, when the receiving circuit 722 detects a pulse train for a predetermined number of times or more during the period from time t13 to time t14 in FIG. 5 regardless of whether or not the plurality of detected pulse trains are continuous, Confirm the detection of the reflected wave from. That is, the reception circuit 722 determines the number of pulse trains included in the transmission signal STX in the predetermined period (a period corresponding to a period in which the period of the trigger signal STR is set to 50 ms in the third embodiment, for example) (M is a natural number). ), When the pulse train is detected a predetermined number N (N is a natural number smaller than M) times or more from the received signal SRX (that is, when a predetermined number N or more pulse trains are detected). It is determined that the reflected wave from the person has been detected. For example, when M = 20 and N = 15, if at least 15 pulse trains are detected in the period from time t13 to time t14 in FIG. 5, that is, if the pulse train is detected 15 times, the detected pulse train is Even if it is not continuous, the control circuit 723 determines that the reflected wave from the user has been detected. The value of N can be arbitrarily set within a range in which the required detection accuracy can be obtained. Others are the same as those in the first to third embodiments.

  Here, for example, assuming that the time until detection is confirmed in the period from time t13 to time t14 in FIG. 5 is 1 second and the repetition period of one pulse train is 50 ms, 50 ms × 20 times = 1 second. = 20 is the best mode. The time until the detection is confirmed (1 second) takes into account, for example, the time until the user uses the urinal after standing in front of the urinal and the time necessary to prevent false detection. Is set. In consideration of detection accuracy, N is preferably set to M / 2 or more. However, N is arbitrary as long as the required detection accuracy can be obtained, and can be set to a value smaller than M / 2.

  According to the fourth embodiment, when the reflected wave is detected from the pulse included in the reception signal SRX, the determination of the number of reception times of the pulse can be made flexible. Therefore, even when a missing pulse occurs when receiving the reflected wave from the user of the urinal, it can be determined that the reflected wave has been detected, and the reflected wave from the user can be detected stably. It becomes possible.

  Although the embodiments of the present invention have been described above, the present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the scope of the present invention.

  DESCRIPTION OF SYMBOLS 1 ... Urinal washing apparatus, 2 ... Urinal, 2A ... Toilet bowl part, 2B ... Spout, 3, 4 ... Wall, 71 ... Human body sensor (ultrasonic sensor), 72 ... Drive part, 73 ... Control part, 74 DESCRIPTION OF SYMBOLS Cleaning device, 721 ... Transmission circuit, 722 ... Reception circuit, 723 ... Control circuit, 7211 ... Signal generation circuit, 7212 ... Drive circuit, 7221, 7222 ... Amplification circuit, 7223 ... Detection circuit.

Claims (7)

A human body sensor that generates and transmits an ultrasonic pulse toward a predetermined region where a user of the urinal is located, and receives a reflected wave of the ultrasonic pulse;
A detection unit that detects the reflected wave from the output signal of the human body sensor and invalidates the output signal of the human body sensor after a predetermined time when the reflected wave is expected to arrive;
Based on the detection result of the detection unit, a cleaning unit for cleaning the urinal,
Urinal cleaning device with   The urinal washing device according to claim 1, wherein the human body sensor is provided inside or outside the stool of the urinal.   The urinal according to claim 1 or 2, wherein the ultrasonic pulse generated by the human body sensor is composed of a pulse train including a plurality of pulses in one cycle, and the number of the plurality of pulses is variable. Cleaning device.   4. The ultrasonic pulse generated by the human body sensor is composed of a pulse train including a plurality of pulses in one cycle, and the repetition cycle of the pulse train is variable. 5. The urinal washing device as described.   The ultrasonic pulse generated by the human body sensor is composed of a pulse train including a plurality of pulses in one cycle, and the repetition cycle of the pulse train is set at random. The urinal washing device according to Item.   6. The urinal washing device according to claim 3, wherein the detection unit determines that the reflected wave has been detected when the pulse train is continuously detected a plurality of times. 6.   When the number of the pulse trains is M, and the detection unit detects the pulse trains N (N is a predetermined natural number smaller than M) times, it determines that the reflected wave has been detected. The urinal washing device according to any one of claims 3 to 5.

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