JP3230014U - Elevator switch device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a non-contact type elevator switch device which can be miniaturized, can be used hygienically, and operates properly according to a user operation. SOLUTION: This is an elevator switch device mounted in an elevator basket or on a wall surface of an elevator landing, and a plurality of floodlights and a plurality of receivers that receive the floodlights of the floodlights are vertically and horizontally optical axes in a switch space 13. A switch unit 1 that is arranged to face each other so as to generate V1 to V4 and H1 to H3, and forms a plurality of switch positions S1 to S10 in a matrix at the intersections of vertical and horizontal optical axes in the switch space 13. To be equipped. [Selection diagram] Fig. 1

Description

The present invention relates to an elevator switch device that is attached to the inside of an elevator car or the wall surface of an elevator landing and is operated by a user in a non-contact manner.

Normally, elevator switches are provided in the elevator car and on the wall of the elevator landing on each floor, and the user pushes or touches those elevator switches to turn them on and use the elevator. .. Contact switches are widely used as this type of elevator switch, and for example, movable contact switches or capacitive touch switches are used therein.

In recent years, from the viewpoint of hygiene, there is a desire for users to avoid contact with elevator switches, and there is a demand for the use of non-contact elevator switches in place of the above-mentioned contact switches. Therefore, it has been considered to use a conventional non-contact switch as described in Patent Document 1 below as an elevator switch.

Japanese Patent No. 2869619

However, the conventional non-contact switch of this type has a complicated structure, and the switch device becomes large, so that it is difficult to install it in a limited space. Further, this non-contact switch is an optical type that projects a plurality of optical axes into a space and detects the light-shielding state of the optical axes with a light receiver, and arranges a plurality of switch positions in a matrix on the switch plane. When the user inserts his / her finger into the switch space, the switch position is detected by shading the vertical and horizontal optical axes, and a switch signal is generated.

However, in the switch space, since the operating fingers and the like move freely, it is easy to detect a plurality of switch positions at substantially the same time, and there is a great possibility that the correct switch signal conscious of the user cannot be generated.

For this reason, it was considered to prohibit the output of switch signals when multiple switch positions were detected at approximately the same time, but in this case, the elevator did not move even though the elevator switch was operated, and the user was informed. It is easy to feel confused and frustrated.

The present invention has been made in view of the above problems, and provides a non-contact type elevator switch device that can be miniaturized, can be used hygienically, and can operate properly according to user operation. The purpose is to do.

The elevator switch device according to the present invention is
A non-contact elevator switch device that can be mounted inside an elevator car or on the wall of an elevator landing.
A plurality of floodlights and a plurality of receivers that receive light from the floodlights are arranged so as to generate vertical and horizontal optical axes in the switch space, and the vertical and horizontal optical axes in the switch space are arranged. A switch unit that forms multiple switch positions in a matrix at the intersection position,
An image board that is arranged in the back of the switch space of the switch unit and has the number of floors and the switch position in the door opening / closing diagram.
A floodlight circuit that outputs floodlight signals to the floodlight in order, and
A light receiving circuit that sequentially captures a light receiving signal or a light shielding signal output from the light receiving receiver,
A scanning circuit that sends a light projecting signal to the light projecting circuit at a predetermined timing and operates the light receiving circuit to scan the switch unit.
A switch position determining means for determining a switch operation position from a switch position of the first light-shielding signal sent from the light receiving circuit at each scanning by the scanning circuit.
An output circuit that outputs a switch output signal based on the switch operation position determined by the switch position determination means, and
It is characterized by being equipped with.

According to the switch device for an elevator of the present invention, the switch position determination means determines the switch operation position from the switch position of the first shading signal, so that even if a plurality of switch positions are turned on at substantially the same time, the first shading is performed. Since the signal is taken in and the signal indicating the switch position is output, even if the user accidentally turns on a plurality of switch positions, a command signal can be immediately sent to the elevator to operate the switch properly.

Here, the elevator switch device having the above configuration further stops the output of the signal indicating the switch position when a plurality of light-shielding signals are sent from the light-receiving circuit at each scanning by the scanning circuit. The means may be provided, and the presence or absence of operation of the multiple detection stop means may be switched by a changeover setting switch.

According to this, depending on the control device of the elevator to be applied, or depending on the usage environment of the elevator, the user can press the switch multiple times when a plurality of light-shielding signals are generated by the switching operation of the changeover setting switch. When the above occurs, it is possible to switch and use whether or not the multiple detection stop means for stopping the output of the signal indicating the switch position is activated.

Further, here, the scanning circuit repeats scanning of only one of the vertical and horizontal optical axes, the vertical optical axis or the horizontal optical axis, and when the first light-shielding signal is sent from the light receiving circuit, then the other horizontal optical axis. Alternatively, it can be configured to scan the vertical optical axis. As a result, when the user operates the switch device with a finger or the like, the time until the switch position is detected can be shortened.

Further, here, when the switch position determination means inputs a light-shielding signal or determines a switch operation position from the switch position of the light-shielding signal, a notification means for notifying by sound or light can be provided.

According to the elevator switch device of the present invention, the switch unit can be miniaturized, operates properly according to the operation of the user, and can be used hygienically without contact.

It is a perspective view of the switch device for an elevator which shows one Embodiment of this invention. It is a vertical sectional view of the switch device. It is a block diagram of the switch device. It is a flowchart which shows the operation of the switch device. It is explanatory drawing which shows the operation of the switch part at the time of scanning. It is a perspective view of the switch device for a landing.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings. FIG. 1 shows a front perspective view of an elevator switch device, and the switch unit 1 of the switch device has a structure that reacts in a non-contact manner and outputs a signal indicating the switch position.

As shown in FIGS. 1 to 3, in the switch portion 1, a rectangular frame 10 is provided on the four side front edges of the rectangular back plate 11, and a rectangular switch space 13 is formed in the frame 10. The switch unit 1 generates vertical optical axes V1 to V4 and horizontal optical axes H1 to H3 orthogonally in the switch space 13, and at the intersections of these optical axes, the respective floor switch positions S1 to S8 and the door. Switch positions S9 and S10 are generated in a matrix. Since the switch unit can be configured only in the frame 10 having the switch space 13, the switch device can be miniaturized.

As shown in FIGS. 2 and 3, floodlights LD1 to LD7, which are composed of, for example, LEDs for emitting infrared rays, are arranged at predetermined intervals inside each side of the frame 10, and the floodlights LD1 to LD7 Receivers PD1 to PD7 such as photodiodes are arranged at opposite positions. As a result, the vertical optical axes V1 to V4 and the horizontal optical axes H1 to H3 that are orthogonal to each other are generated in the switch space 13, and the floor switch positions S1 to are located at the intersections of the generated vertical optical axes V1 to V4 and the horizontal optical axes H1 to H3. S8 and door switch positions S9 and S10 are generated.

As shown in FIG. 3, a scanning circuit 5 is connected to the light emitting circuits 4a and 4b of the floodlights LD1 to LD7 and the light receiving circuits 3a and 3b of the light receivers PD1 to PD7. The scanning circuit 5 is an element selection circuit that sequentially selects and lights the floodlights LD1 to LD7 at a predetermined timing and sequentially selects the receivers PD1 to PD7 at a predetermined timing to perform a light receiving operation.

As shown in FIG. 3, the floodlights LD1 to LD7 are connected to the floodlight circuits 4a and 4b, and are sequentially turned on and projected at predetermined timings by a scanning floodlight signal (pulse signal) sent from the scanning circuit 5. It glows. The photoreceivers PD1 to PD7 are connected to the light receiving circuits 3a and 3b, and at the time of scanning, the light receiving signals are sequentially taken in by the light receiving timing signal sent from the scanning circuit 5 and sent to the processing circuit 7 in order. During standby, for example, the scanning circuit 5 generates only the vertical optical axes V1 to V4 in order, operates the receivers PD1 to PD4 to receive light, and sends the received signals to the processing circuit 7.

As a result, the switch position can be detected in a shorter time than scanning the vertical and horizontal optical axes. It should be noted that during standby, only the horizontal optical axes H5 to H7 can be generated in order, the receivers PD5 to PD7 can be operated to receive light, and the received signals can be sent to the processing circuit 7.

On the other hand, the processing circuit 7 takes in the light receiving signals sent from the light receiving circuits 3a and 3b in order, and when an effective shading signal (a signal when the vertical optical axes V1 to V4 are cut off with a finger or the like) is input, then , The horizontal optical axes H1 to H3 are generated in order, and the received signals of the receivers PD5 to PD7 on the horizontal optical axis are sequentially captured to scan the horizontal optical axis.

In this embodiment, four vertical optical axes V1 to V4 and three horizontal optical axes H1 to H3 are generated, and at their intersections, the floor switch positions from the first floor to the eighth floor and two. Of course, it is also possible to generate more than the above number of vertical optical axes and / or horizontal optical axes to generate nine or more floor switch positions.

It is also possible to generate less than eight vertical and / or horizontal optical axes to generate less than eight floor switch positions. For example, if the floodlight and the receiver are arranged so as to increase the number of horizontal optical axes by one to generate four vertical optical axes and four horizontal optical axes, the floor switch positions from the first floor to the twelfth floor and two. Door switch position can be generated.

An image plate 12 is fixed to the front surface of the back plate 11 on the back surface of the switch space 13 of the switch unit 1, and the image plate 12 is provided with an image diagram showing the switch position and an image diagram showing the opening and closing of the door. .. By making the thickness of the space 13 sufficiently large, it is possible to prevent a user's finger or the like from accidentally touching the image plate 12 when operating the switch.

Further, since the floodlights LD1 to LD7 and the light receivers PD1 to PD7 are provided on the front side <front side> in the frame 10, the user can generate a light-shielding signal by simply inserting a finger or the like into the switch unit 1. An effective switch position signal can be obtained, and the user can operate the switch without touching the image board 12.

Further, a buzzer 18 and an indicator lamp 19 are connected to the output circuit 6 of the processing circuit 7. When the switch is operated, the processing circuit 7 outputs a notification signal to the buzzer 18 or the indicator lamp 19 through the output circuit 6 when a light-shielding signal is input or a switch position signal indicating the switch position is output, and the notification is notified. To do. As a result, the user can confirm the switch operation by simply inserting his or her finger into the switch space 13, so that it is possible to avoid unnecessarily inserting the finger into the switch unit 1 and to operate the switch easily without contact. Can be done.

The processing circuit 7 is composed of, for example, a general-purpose single-chip CPU, and based on software stored in advance, the vertical optical axis and the horizontal optical axis in the switch unit 1 are sequentially generated at each scanning by the scanning circuit 5. The matrix-like switch position is scanned, and when a signal indicating the switch operation position is obtained from the switch position of the first light-shielding signal sent from the light receiving circuit 3, the switch position signal is output from the output circuit 6. Operate. The processing circuit 7 constitutes the above-mentioned switch position determination means that determines the switch operation position from the switch position of the first light-shielding signal sent from the light receiving circuits 3a and 3b during scanning.

A changeover setting switch 9 is connected to the processing circuit 7, and the changeover setting switch 9 causes a light-shielding signal of a plurality of vertical optical axes or a plurality of horizontal optical axes when multiple pushes occur during each scan. When the above occurs, the processing circuit 7 has a function of stopping the output of the switch position signal indicating the switch position, and at the time of multiple pressing, determines the switch operation position from the switch position of the first shading signal and outputs the switch position signal. The function to be output from the circuit 6 can be switched. The function of the processing circuit 7 to stop the output of the switch position signal indicating the switch position when a light-shielding signal of a plurality of vertical optical axes or a plurality of horizontal optical axes is generated constitutes the multiple detection stop means.

As a result, the user mistakenly operates the elevator depending on the elevator to be used, or when the user presses multiple times to generate light-shielding signals of a plurality of vertical optical axes or a plurality of horizontal optical axes. It is possible to select and set whether to stop the output of the switch position signal or to detect the switch operation position from the switch position of the first light-shielding signal and output the switch position signal.

Next, the operation of the elevator switch device having the above configuration will be described with reference to FIG. When the power is turned on, the processing circuit 7 first sends a signal to the scanning circuit 5 in step 100 to scan the vertical optical axes V1 to V4. The changeover setting switch 9 is set to detect the switch operation position from the switch position of the first light-shielding signal and output the switch position signal from the output circuit 6.

At this time, the scanning circuit 5 sends an element selection signal for scanning (pulse signal of a predetermined period) to the floodlight circuit 4a for the vertical optical axis, whereby the floodlights LD1 to LD4 send the floodlights LD1 to LD4 at a predetermined time interval (for example, several tens of millimeters). The light projection operation is performed in order at (second intervals).

At this time, at the same timing, a scanning element selection signal is sent from the scanning circuit 5 to the light receiving circuit 3a, the light receiving circuits PD1 to PD4 of the opposing light receiving circuits 3a are sequentially enabled, and the light receiving circuits LD1 to LD4 emit the signals. When light is received by the light receivers PD1 to PD4, the light receivers PD1 to PD4 generate a light receiving signal, and the light receiving circuit 3a sequentially sends the light receiving signal to the processing circuit 7. When the light receiving signals are input from all the light receivers PD1 to PD4, the processing circuit 7 returns to step 100 again on the assumption that the light receiving signal is not detected, and scans the vertical optical axis as shown in the uppermost figure of FIG. Is repeated. Therefore, if the elevator switch is not operated in the standby state, steps 100 and 110 are repeatedly executed.

When the switch operation is performed and, for example, the vertical optical axis V3 is shielded from light as shown in the intermediate diagram of FIG. 5, the light-shielding signal of the receiver PD3 is input from the light-receiving circuit 3a to the processing circuit 7, and the processing circuit 7 receives In step 110, it is determined that the shading signal is input (110). Next, in step 120, the vertical optical axis V3 is stored as the input of the first shading signal.

Next, in step 130, the processing circuit 7 sends a signal to the scanning circuit 5 to scan the horizontal optical axes H1 to H4. At this time, the scanning circuit 5 sends an element selection signal for scanning to the light projecting circuit 4b for the horizontal light axis, whereby the floodlights LD5 to LD7 sequentially project light at predetermined time intervals (for example, at intervals of several tens of milliseconds). I do.

At this time, at the same timing, the scanning element selection signal is sent from the scanning circuit 5 to the light receiving circuit 3b, and the light receiving circuits PD5 to PD7 of the opposing light receiving circuits 3b are sequentially enabled. Then, for example, as shown in the lower figure of FIG. 5, when the horizontal light axis H2 is shielded by a switch operation, the shading signal is output from the receiver PD6 and sent to the processing circuit 7. The processing circuit 7 stores the shading signal of the horizontal light axis H2, and in step 160, the vertical light axis V3 stored in step 120 and the horizontal light axis H2 stored in step 150 are switched from the switch position which is the intersection position. In S2, that is, in the example of FIG. 1, it is determined that it is the "second floor", and the switch output signal indicating the second floor is output to the control circuit of the elevator or the like. Further, when a valid switch position signal is obtained, the processing circuit 7 outputs a notification signal to the buzzer 18 or the indicator lamp 19 through the output circuit 6. As a result, when the elevator switch is operated, the user can easily recognize that the buzzer 18 or the indicator lamp 19 is turned on and a valid switch output signal is output. The notification signal may be generated when the shading signal is input in steps 110 and 140.

In this way, the user can operate the switch by blocking the vertical optical axis and the horizontal optical axis in the switch unit 1 with a finger or the like without touching the switch of the elevator. In addition, when scanning the optical axis each time, only the light-shielding signal of the first vertical optical axis or horizontal optical axis is stored as an effective light-shielding signal and used to determine the switch position. Even when a plurality of vertical optical axes or a plurality of horizontal optical axes are shielded from light at substantially the same time, it is possible to quickly react when the switch is operated to determine the switch position and output a switch output signal.

When the changeover setting switch 9 is switched to the side where the output is stopped when the switch device is pressed multiple times, shading of a plurality of vertical optical axes is detected during one scan when the switch device is used, or a plurality of horizontal optical axes are detected. When the light blocking is detected, the switch output is stopped.

In this case, instead of step 170 in the flowchart of FIG. 4, a multiple push determination step is provided to determine whether or not there is shading of a plurality of vertical optical axes or a plurality of horizontal optical axes during one scan, and a plurality of vertical lights are provided. If there is shading of the shaft or a plurality of horizontal optical axes and there are multiple pushes, a step of stopping the output of the switch output signal is provided and processed.

In this way, in the case of multiple pressing, by performing the process of stopping the switch output signal, for example, when the user uses the elevator, the switch device frequently makes a false detection and the switch output is not intended by the user. If the changeover setting switch 9 is switched to the output stop side at the time of multiple pressing, the switch output will be stopped at the time of multiple pressing, so that the problem that the switch output unintended by the user repeatedly occurs is prevented. can do. Further, it is effective when there is no processing circuit on the control circuit side of the elevator when a multiple push switch signal is input.

FIG. 6 shows a switch device installed on the wall surface of the elevator landing. Similar to the above embodiment, this switch device generates a vertical optical axis V5 and horizontal optical axes H4 and H5 in the switch space 33 in the frame 31, and uses a light-shielding signal of the optical axis generated by a non-contact operation to position the switch. Is detected. A rectangular switch space 33 is formed in the rectangular frame 31, and an upper switch position and a lower switch position indicating raising and lowering of the elevator car are set in the frame 31. A plurality of floodlights LD8 to LD10 and receivers PD8 to PD10 are installed facing each other inside the frame 31, and one vertical optical axis V5 and two horizontal optical axes H4 and H5 are orthogonal to each other in the switch space 33. It is supposed to occur. When scanning the switch space 33, the upper switch position and the lower switch position are detected by the light-shielding states of the vertical optical axis V5 and the horizontal optical axes H4 and H5.

The landing switch device generates the vertical light axis V5 during standby, scans the horizontal light axis when the vertical light axis is shielded, and detects the light shielding of the upper horizontal light axis H4, the switch output at the upper switch position. When a signal is output and shading of the lower horizontal optical axis H5 is detected, the switch output signal at the lower switch position is output.

1 Switch part 3a, 3b Light receiving circuit 4a, 4b Floodlight circuit 5 Scanning circuit 6 Output circuit 7 Processing circuit 9 Switching setting switch 10 Frame 11 Back plate 12 Image board 13 Switch space 18 Buzzer 19 Indicator light LD1 to LD10 Floodlight PD1 to PD10 Receiver

Claims (4)

A non-contact elevator switch device that can be mounted inside an elevator car or on the wall of an elevator landing.
A plurality of floodlights and a plurality of receivers that receive the light projected by the floodlights are arranged to face each other so as to generate vertical and horizontal optical axes in the switch space, and the vertical and horizontal optical axes in the switch space. A switch unit that forms a plurality of switch positions in a matrix at the intersection position of
An image board that is placed in the back of the switch space of the switch unit and has the number of floors and the switch position in the door opening / closing diagram.
A floodlight circuit that outputs floodlight signals to the floodlight in order, and
A light receiving circuit that sequentially captures a light receiving signal or a light shielding signal output from the light receiving receiver,
A scanning circuit that sends a light projecting signal to the light projecting circuit at a predetermined timing and operates the light receiving circuit to scan the switch unit.
A switch position determining means for determining a switch operation position from a switch position of the first light-shielding signal sent from the light receiving circuit at each scanning by the scanning circuit.
An output circuit that outputs a switch output signal based on the switch operation position determined by the switch position determination means, and
Elevator switch device characterized by being equipped with. A non-contact elevator switch device that can be mounted inside an elevator car or on the wall of an elevator landing.
A plurality of floodlights and a plurality of receivers that receive the light projected by the floodlights are arranged to face each other so as to generate vertical and horizontal optical axes in the switch space, and the vertical and horizontal optical axes in the switch space. A switch unit that forms a plurality of switch positions in a matrix at the intersection position of
An image board that is placed in the back of the switch space of the switch unit and has the number of floors and the switch position in the door opening / closing diagram.
A floodlight circuit that outputs floodlight signals to the floodlight in order, and
A light receiving circuit that sequentially captures a light receiving signal or a light shielding signal output from the light receiving receiver,
A scanning circuit that sends a light projecting signal to the light projecting circuit at a predetermined timing and operates the light receiving circuit to scan the switch unit.
A switch position determining means for determining a switch operation position from a switch position of the first light-shielding signal sent from the light receiving circuit at each scanning by the scanning circuit.
An output circuit that outputs a switch output signal based on the switch operation position determined by the switch position determination means, and
Multiple detection stop means for stopping the output of the signal indicating the switch position when a plurality of light-shielding signals are sent from the light-receiving circuit at each scanning by the scanning circuit.
The elevator switch device is characterized in that the presence or absence of operation of the multiple detection stop means can be switched by a changeover setting switch. The scanning circuit repeats scanning of only one of the vertical light horizontal or horizontal optical axes, and when the first light-shielding signal is sent from the light receiving circuit, then scans the other horizontal light axis or vertical light axis. The elevator switch device according to claim 1 or 2. The first aspect of claim 1 or 2. The elevator switch device according to 2.

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