JP6190734B2 - Shutter obstacle detection system - Google Patents

Description

  The present invention relates to a shutter obstacle detection system that detects an obstacle to a shutter curtain that opens and closes an opening.

  2. Description of the Related Art Conventionally, an electric fire and smoke prevention shutter device that forms a fire prevention and smoke prevention section in a building by fully closing an opening provided in various buildings when a fire occurs is widely used. FIG. 15 is a diagram conceptually showing such a conventional shutter device 100 and a fire alarm system 110 linked to the shutter device. The shutter device 100 is generally configured to include a shutter curtain 101, an opening / closing device 102, an automatic closing device 103, a manual closing device 104, and an interlocking relay 105. On the other hand, the fire alarm system 110 includes a fire detector 111 and a disaster prevention panel 112. In a normal state, when the user operates the manual closing device 104, the opening / closing machine 102 rotates a winding shaft (not shown) around which the shutter curtain 101 is wound, and the shutter curtain 101 is raised or lowered electrically. . Further, when a fire is detected by the fire detector 111, a fire detection signal is output from the fire detector 111 to the disaster prevention panel 112, and a transfer signal is output from the disaster prevention panel 112 to the interlocking relay 105. Then, the automatic closing device 103 releases the brake of the switch 102 based on the control signal from the interlock repeater 105, so that the shutter curtain 101 wound around the winding shaft is lowered by its own weight, and the fire and smoke-proof section. Form.

  Further, such a shutter device 100 is generally provided with an obstacle detection system (danger prevention system) 120. The obstacle detection system 120 stops the lowering of the shutter curtain 101 when the shutter curtain 101 comes into contact with an obstacle when the shutter curtain 101 is lowered by electric or dead weight to close the opening. It is a system for preventing harming the obstacle. The obstacle detection system 120 is generally configured to include a seat plate switch 121, a signal line 122, and a cord reel 123. The seat plate switch 121 detects that the seat plate 106 provided at the lower end portion of the shutter curtain 101 is in contact with an obstacle, and outputs a detection signal when the contact is detected. The signal line 122 is a line that connects the seat plate switch 121 and the interlock repeater 105 so that wired communication is possible. The interlock repeater 105 outputs a control signal to the switch 102 to operate the brake when the detection signal of the seat plate switch 121 is received via the signal line 122 while the shutter curtain 101 is descending. Then, the descent of the shutter curtain 101 is stopped. The cord reel 123 winds the signal line 122 so that the unwinding length of the signal line 122 is always maintained at an appropriate length even when the seat switch 121 moves up and down as the shutter curtain 101 is opened and closed. Take up or unwind.

  However, with regard to the conventional wired obstacle detection system 120 using such a signal line 122, the signal line 122 may not function properly due to disconnection due to mischief, or the signal line 122 or the code reel 123 may There are problems such as detracting from the beauty of the shutter device 100 due to exposure. In view of such a problem, the inventors of the present application focused on transmitting and receiving information on an obstacle detection state when the shutter curtain 101 is lowered by radio waves. Specifically, instead of the cord reel 123, the shutter curtain 101 is provided with a transmitter that wirelessly transmits the signal of the seat plate switch 121, and a receiver is provided above the shutter device 100 in which the shutter curtain 101 is housed. By providing this, a wireless obstacle detection system is configured. When the seat plate switch 121 detects that the lower end portion of the shutter curtain 101 is in contact with an obstacle while the shutter curtain 101 is being lowered, a signal of the seat plate switch 121 is transmitted from the transmitter. Then, this signal is received by the receiver and output to the interlock repeater 105, and a control signal is output from the interlock repeater 105 to the switch 102 to operate the brake, thereby stopping the descent of the shutter curtain 101 ( For example, see Patent Document 1).

JP2012-202130A

  However, depending on the radio wave environment around the shutter device, it may be difficult to install a wireless obstacle detection system because the communication between the transmitter and receiver becomes unstable. In some cases, the obstacle detection system had to deal with it. Therefore, conventionally, both a wired obstacle detection system and a wireless obstacle detection system are prepared, and one of the obstacle detection systems is selected according to the radio wave environment around the shutter device. It was set. In this case, the communication method between the interlock repeater and the cord reel in the wired obstacle detection system and the communication method between the interlock repeater 105 and the receiver in the wireless obstacle detection system are mutually different. Because of the different methods, different interlocking repeaters were prepared for each method and selected according to the method of the obstacle detection system. For this reason, the manufacturing cost of the obstacle detection system has increased.

  Furthermore, since the radio wave environment around the shutter device can be influenced by the shutter device itself, it is often impossible to specify until the shutter device is actually installed. For this reason, it was discovered that the wireless obstacle detection system could not be used after the shutter device was installed even though a wireless obstacle detection system was prepared. The trouble of installing the obstacle detection system has increased due to the necessity of replacing the system.

  The present invention is for solving the above-described problems in the prior art, and increases the compatibility between a wired obstacle detection system and a wireless obstacle detection system, thereby reducing the manufacturing cost of the obstacle detection system. An object of the present invention is to provide a shutter obstacle detection system that can reduce the installation effort.

  In order to solve the above-described problems and achieve the object, the shutter obstacle detection system according to claim 1 is a shutter obstacle detection system that detects an obstacle with respect to a shutter curtain that opens and closes an opening. An obstacle sensor that detects that an obstacle that obstructs the closing operation of the shutter curtain is present in the opening, and a control unit that performs opening / closing control of the shutter curtain based on an obstacle detection state by the obstacle sensor And a means for outputting a signal indicating a detection state of the obstacle sensor to the control means, a wired relay means wired to the obstacle sensor and the control means, and the obstacle sensor Second communication means wirelessly connected to the first communication means for transmitting a signal indicating the detection state and wired to the control means; Any one of them can be selectively connected to the control means, and each of the wired relay means and the second communication means changes a resistance value of a connection destination including itself as a connection destination to the control means. Accordingly, a signal indicating the detection state of the obstacle sensor is output to the control means, and the control means is responsive to whether the wired relay means or the second communication means is included in its connection destination. First, the detection state of the obstacle sensor is specified based on the resistance value of the connection destination.

  Further, the shutter obstacle detection system according to claim 2 is the shutter obstacle detection system according to claim 1, wherein the control means includes a plurality of detection states that can be taken by the obstacle sensor, and a resistance. A setting range which is a value setting range and is commonly set for the wired relay unit and the second communication unit is set in association with each other, and the wired relay unit and the second communication unit Each of the obstacles by changing the resistance value of the connection destination to a resistance value included in the setting range corresponding to the detection state according to each of a plurality of detection states that the obstacle sensor can take. A signal indicating the detection state of the obstacle sensor is output to the control means, the control means specifies the resistance value of the connection destination, and the detection state of the obstacle sensor includes the set resistance value including the specified resistance value. Identifying a detection state of the corresponding obstacle sensor.

  Further, the shutter obstacle detection system according to claim 3 is the shutter obstacle detection system according to claim 2, wherein the wired relay unit and the obstacle are included in a resistance value setting range set in the control unit. The resistance value setting range when the signal line connecting the object sensor or the control means is disconnected, and the resistance value when the predetermined state relating to the communication failure with the first communication means in the second communication means occurs. The setting range is the same setting range.

  According to the shutter obstacle detection system according to claim 1, the control unit is based on the resistance value of the connection destination regardless of whether the wired relay unit or the second communication unit is included in the connection destination of the shutter obstacle detection system. Because the detection status of the obstacle sensor is specified, it is possible to use a common control means regardless of whether the obstacle detection system is wired or wireless. The compatibility between the system and the wireless obstacle detection system can be improved. Therefore, it is not necessary to prepare different control means for the wired type and the wireless type as in the prior art, and the manufacturing cost of the obstacle detection system can be reduced. In addition, since the shutter device is actually installed, either the wired relay means or the second communication means can be selected and connected to the common control means according to the radio wave environment around the shutter device. It becomes possible to reduce the trouble of mounting the object detection system.

  According to the shutter obstacle detection system according to claim 2, the control means is set in common to each of a plurality of detection states that the obstacle sensor can take, the wired relay means, and the second communication means. Since the setting range of the resistance value is set in association with each other, the control means can determine the connection destination regardless of whether the wired relay means or the second communication means is included in its connection destination. By specifying the detection state corresponding to the resistance value, the detection state of the obstacle sensor can be specified. Therefore, the resistance value of the connection destination including the wired relay means and the resistance value of the connection destination including the second communication means are set in advance to resistance values that match the common resistance value setting range. It is possible to construct an obstacle detection system simply by selecting either the wire relay means or the second communication means according to the radio wave environment around the shutter device and connecting to the common control means.

  According to the shutter obstacle detection system according to claim 3, the resistance value setting range when the signal line connecting the wired relay means and the obstacle sensor or the control means is disconnected, and the first communication means in the first communication means. Since the setting range of the resistance value when the predetermined state related to the communication failure with the communication means occurs is set to the same setting range, the disconnection of the signal line which is a failure peculiar to the wired obstacle detection system, Communication faults, which are peculiar to the wireless obstacle detection system, can be specified in the control means by the same setting range.

1 is a front view conceptually showing a shutter device, a fire alarm system, and a shutter obstacle detection system according to Embodiment 1 of the present invention. It is a block diagram which shows the electric constitution of an interlocking repeater. It is a figure which shows the structural example of a connection destination state table. It is a block diagram which shows the electric constitution of a transmitter. It is a block diagram which shows the electric constitution of a receiver. It is a figure which shows the structural example of an internal resistance table. It is a flowchart of a registration process. It is a flowchart of a regular report process. It is a flowchart of a dead weight drop process. FIG. 10 is a flowchart of the dead weight lowering process following FIG. 9. FIG. It is a flowchart of a dead weight fall stop process. It is a flowchart of dead weight resumption restart processing. It is a flowchart of the own weight fall resumption process following FIG. It is a figure which shows the structural example of the connection destination state table which concerns on Embodiment 2. FIG. It is a front view which shows notionally the conventional shutter apparatus, a fire alerting | reporting system, and an obstruction detection apparatus.

  Embodiments of a shutter obstacle detection system according to the present invention will be described below in detail with reference to the accompanying drawings. [I] First, the basic concept of the embodiment will be described, then [II] the specific contents of the embodiment will be described, and [III] Finally, modifications to the embodiment will be described. However, the present invention is not limited to the embodiments.

[I] Basic Concept of Embodiment First, the basic concept of the present embodiment will be described. This shutter obstacle detection system is a system that detects an obstacle to a shutter curtain that opens and closes an opening. The shutter device provided with the shutter curtain can take any purpose, installation location, structure, etc., unless otherwise specified, and is configured as, for example, a heavy shutter, a lightweight shutter, a grill shutter, or a smoke proof wall, The heavy shutter is configured as a shutter used for a plurality of purposes such as a fire shutter, a smoke shutter, an airtight shutter, a management shutter, a soundproof shutter, or a combined management shutter. The opening / closing direction of the shutter curtain is also arbitrary, and includes the vertical direction and the horizontal direction. In the following, an example in which the shutter obstacle detection system is applied to a management combined fire and smoke prevention shutter device that opens and closes a shutter curtain along the vertical direction will be described.

  “Detecting obstacles” means detecting people and objects that can be an obstacle to the shutter curtain that opens and closes the opening. Including obstacle detection for, but not limited to harm prevention, it can target obstacle detection based on any purpose or law. In the following, an example will be described in which the shutter obstacle detection system is configured as a hazard prevention system for the purpose of preventing harm at the time of descent of the management-combined shutter device.

[II] Specific Contents of Embodiment Next, specific contents of the embodiment will be described.

[Embodiment 1]
First, the shutter obstacle detection system according to the first embodiment will be described. In the first embodiment, the control means specifies the state of the connection destination based on the resistance value of the connection destination without determining which of the wired relay means or the second communication means is connected. It is.

(Configuration-Shutter device)
Next, the configuration of the shutter device to which the shutter obstacle detection system according to Embodiment 1 is applied will be described. However, the shutter device can be configured in the same manner as in the prior art, and the configuration and processing not specifically mentioned are the same as in the prior art. FIG. 1 is a front view conceptually showing the shutter device 10, the fire alarm system 20, and the shutter obstacle detection system 30 according to Embodiment 1 of the present invention.

  This shutter device 10 is an electric fire-proof shutter device that forms a fire-proof section in this building by fully closing the opening 1 provided in the building when a fire breaks out. A shutter curtain 12, an opening / closing device 13, an automatic closing device 14, and a manual closing device 15 are provided. In the following description, the X direction in FIG. 1 is referred to as the width direction, the Y direction is referred to as the height direction (the + Y direction is upward, the −Y direction is downward), and the direction orthogonal to the X direction and the Y direction is referred to as the front-rear direction. .

(Configuration-Shutter device-Shutter housing)
The shutter accommodating portion 11 is a hollow body for accommodating each portion of the shutter device 10, and is attached to a position near the upper end of the opening portion 1. Inside the shutter storage unit 11, the opening / closing device 13, the automatic closing device 14, the interlocking relay 16, the winding shaft (not shown), and a receiver 33 (or shutter failure) described later of the shutter obstacle detection system 30. A cord reel 34 (shown by an imaginary line in FIG. 1) described later of the object detection system 30 is accommodated. Further, in a state where the shutter curtain 12 is wound around the winding shaft, the shutter curtain 12 is also housed inside the shutter housing portion 11 together with a transmitter 32 described later of the shutter obstacle detection system 30. On the lower surface of the shutter storage portion 11, a not-shown mass is formed over the entire length in the opening width direction, and the shutter curtain 12 is taken in and out via this mass.

(Configuration-Shutter device-Shutter curtain)
The shutter curtain 12 is shielding means that brings the opening 1 into a fully open state, a fully closed state, or a state between these two states by being wound or unwound by a winding shaft. Both end portions of the shutter curtain 12 in the width direction are inserted into guide rails 2 provided along the vertical direction at the left and right inner edges of the opening 1, and the inside of the guide rail 2 can be slid in the vertical direction. In addition, the front and rear direction is restricted so as not to drop out of the guide rail 2. A horizontal seat plate 17 is provided at the lower end of the shutter curtain 12, and a seat plate switch 31 described later of the shutter obstacle detection system 30 is attached to the seat plate 17.

(Configuration-Shutter device-Opening and closing device)
The opening / closing machine 13 is an elevating unit that electrically lifts and lowers the shutter curtain 12 by rotationally driving the winding shaft, and includes a brake (not shown) that brakes the rotation of the winding shaft. The automatic closing device 14 is a means for controlling the lowering of the weight of the shutter curtain 12, and based on a control signal from the interlocking relay 16, the brake is released by pulling the brake lever of the opening / closing device 13, thereby releasing the shutter curtain. The self-weight drop of the shutter curtain 12 is stopped by lowering the weight of the shutter curtain 12 or operating the brake by returning the brake lever of the switch 13 based on the control signal from the interlocking relay 16.

When the shutter curtain 12 is lifted and lowered electrically, the automatic closing device 14 does not operate, and the opening / closing device 13 releases the brake by itself and drives the winding shaft in a predetermined winding direction or feeding direction to thereby release the shutter. The curtain 12 is raised or lowered electrically to fully open or close the opening 1.
On the other hand, by releasing the brake by the automatic closing device 14, the shutter curtain 12 is lowered by its own weight so that the opening 1 is fully closed, or the brake is operated to brake the rotation of the winding shaft, thereby releasing the shutter. The descent of the curtain 12 is stopped.

(Configuration-Shutter device-Manual closing device)
The manual closing device 15 is an operating means for operating the shutter curtain 12, and includes a lift button for electrically raising the shutter curtain 12, a lower button for electrically lowering, and a stop button for stopping the shutter curtain 12 being lifted and lowered. When the up button, the down button, or the stop button is pressed by the user, an operation signal corresponding to the pressed button is output to the interlocking relay 16 so that the shutter curtain 12 is electrically driven via the switch 13. Ascend and descend, or stop raising and lowering the shutter curtain 12. Further, the manual closing device 15 has an emergency closing button, and when the emergency closing button is pressed, the shutter curtain 12 starts its own weight drop as in the case of a fire that will be described later. Moreover, this manual closing device 15 has a recovery button, and when the recovery button is pressed by the user during the weight drop, the weight drop is stopped. Furthermore, although not shown, the manual closing device 15 is provided with an indicator lamp for notifying the occurrence of an abnormality.

(Configuration-Shutter device-Interlocking repeater)
The interlock repeater 16 is a control means for interlocking each part of the shutter device 10 and is a relay means for interlocking the fire alarm system 20 with the shutter device 10. The interlock repeater 16 includes a switchboard 13, an automatic closing device 14, a manual closing device 15, a disaster prevention panel 22 described later of the fire alarm system 20, and a receiver 33 or a cord reel 34 described later of the shutter obstacle detection system 30. It is electrically connected to either one (indicated by imaginary lines in FIGS. 1 and 2). In particular, the interlock repeater 16 outputs a control signal to the automatic closing device 14 so as to lower the weight of the shutter curtain 12 or stop the weight of the shutter curtain 12 from dropping. Further, when the control signal is output to the automatic closing device 14 in this way, the interlock repeater 16 outputs a signal corresponding to the control content to the receiver 33. Specifically, the interlock repeater 16 outputs a “start-up signal” or a “start-off signal”. The “start-up signal” is a signal indicating that the shutter curtain 12 has been lowered. The “start-off signal” is a signal indicating that the descent of the shutter curtain 12 has been completed.

  FIG. 2 is a block diagram showing an electrical configuration of the interlock repeater 16. The interlock repeater 16 includes two first terminals 16a, two second terminals 16b, two third terminals 16c, an input unit 16d, an output unit 16e, a display unit 16f, a storage unit 16g, a power supply unit 16h, and a control. The parts 16i are connected as shown in the figure.

  The two first terminals 16a are input means for receiving an input of an output from a later-described receiver 33 or a later-described cord reel 34 of the shutter obstacle detection system 30, for example, a signal to the receiver 33 or the cord reel 34, respectively. It is configured as a terminal connected via a line 51. Specific connection of the receiver 33 or the cord reel 34 to the first terminal 16a will be described later.

  The two second terminals 16 b are output means for outputting a start-on signal to the receiver 33 of the shutter obstacle detection system 30. For example, the signal lines 52 are respectively connected to the two second terminals 33 b of the receiver 33. It is comprised as a terminal connected via. Specifically, a current transmitted through a predetermined one of the two second terminals 16b is input to a predetermined one of the two second terminals 33b of the receiver 33 via the signal line 52, and this current Is output from the predetermined other of the two second terminals 33b of the receiver 33, and this current is input to the predetermined other of the two second terminals 16b of the interlocking repeater 16 via the signal line 52. Here, these two second terminals 16b can be freely opened and closed by a contact switch (not shown). Then, by switching the contact switch to the closed state, a current is passed to the receiver 33 via the second terminal 16b, and thereby a start-on signal can be output to the receiver 33. . On the other hand, by switching the contact switch to the open state, the current flowing to the receiver 33 via these second terminals 16b is stopped, so that a start-off signal is output to the receiver 33. Can do.

  The two third terminals 16 c are power means for supplying power to the receiver 33 of the shutter obstacle detection system 30. For example, the two third terminals 16 c are connected to the two third terminals 33 c of the receiver 33 via the power lines 53, respectively. Configured as a terminal. Specifically, a current transmitted through a predetermined one of the two third terminals 16c is input to a predetermined one of the two third terminals 33c of the receiver 33 via the power line 53, and this current is The current is output from the predetermined other of the two third terminals 33 c of the receiver 33, and this current is input to the predetermined other of the two third terminals 16 c of the interlock repeater 16 through the power line 53. This makes it possible to supply power from the interlock repeater 16 to the receiver 33.

  The input unit 16d is an input unit that receives an input of an output from a disaster prevention panel 22 (to be described later) of the switch 13, the automatic closing device 14, the manual closing device 15, and the fire alarm system 20, for example, the switch 13 (or automatic It is configured as an input terminal connected to an output terminal of the closing device 14, the manual closing device 15, or a disaster prevention panel 22, which will be described later, via a signal line (not shown).

  The output unit 16e is an output unit that outputs various signals to a disaster prevention panel 22 described later of the switch 13, the automatic closing device 14, the manual closing device 15, and the fire alarm system 20, for example, the switch 13 (or The automatic closing device 14, the manual closing device 15, or the output terminal connected to the input terminal of the disaster prevention panel 22, which will be described later, via a signal line (not shown).

  The display unit 16f is an output unit that displays various types of information based on the control of the control unit 16i, and is configured as an LED, for example.

  The storage unit 16g is a storage unit that stores various programs and data necessary for operating the interlock repeater 16 in a nonvolatile manner, and is configured as, for example, an EEPROM. The storage unit 16g includes a connection destination state table 16j.

  The connection destination state table 16j is connection destination state storage means for storing information for specifying the state of the connection destination described later. FIG. 3 is a diagram illustrating a configuration example of the connection destination state table 16j. As shown in FIG. 3, the connection destination state table 16 j is configured by associating an item “resistance value setting range”, an item “connection destination state”, and information corresponding to each item. Here, the information corresponding to the item “resistance value setting range” is information for specifying the resistance value setting range of the connection destination of the interlock repeater 16, for example, from the upper limit value to the lower limit value of the setting range. A value (specifically, 15 kΩ to 60 kΩ or the like) indicating a range (or one of an upper limit value and a lower limit value) is applicable. The information corresponding to the item “connection destination state” is information for specifying the connection destination state of the interlock repeater 16, and corresponds to, for example, “obstacle detection state”.

  The power supply unit 16h is a power supply unit that supplies power supplied from an AC power source (not shown) or the like via a power line (not shown) to each unit of the interlocking relay 16.

  The control unit 16i is a control unit that controls each unit of the interlock repeater 16, and includes, for example, a CPU that executes a program stored in the storage unit 16g. The control unit 16i functions as a periodic notification processing unit that executes a periodic notification process described later, and a descent processing unit (obstacle detection processing unit) that executes an electric descent process and a dead weight lowering process described later, and measures various times. An internal timer (not shown) is provided as a time measuring means.

(Configuration-Shutter device-Lower limit switch)
In addition, the shutter housing portion 11 of the shutter device 10 is provided with a lower limit switch (not shown). In this lower limit switch, the lower end of the shutter curtain 12 is positioned on either the upper side or the lower side with respect to a predetermined position (hereinafter referred to as a lower limit position) set at a predetermined distance (several centimeters) above the floor surface. It is a switch for detecting whether or not The lower limit switch includes, for example, a potentiometer that detects the amount of rotation of the winding shaft of the shutter curtain 12 and a counter type limit switch, and the lower end of the shutter curtain 12 is positioned below the lower limit position. If it is, the lower limit signal is output to the interlock repeater 16.

(Configuration-Fire alarm system)
Next, the structure of the fire alarm system 20 linked with the shutter obstacle detection system 30 according to the first embodiment will be described. However, the fire alarm system 20 can be configured in the same manner as in the past, and the configuration and processing that are not specified are the same as in the past. The fire notification system 20 is a system that detects and notifies the occurrence of a fire in a monitoring area set in a building, and includes a fire detector 21 and a disaster prevention panel 22. The fire detector 21 outputs a fire detection signal to the disaster prevention panel 22 when a fire occurrence in the monitoring area is detected. When the fire prevention signal is received from the fire detector 21, the disaster prevention panel 22 outputs an alarm sound and turns on the fire indicator light, and fully closes the shutter curtain 12 to form a fire prevention zone to spread the fire. In order to prevent expansion, a transfer signal for notifying the occurrence of a fire is output to the interlocking repeater 16.

(Configuration-Shutter obstacle detection system)
Next, the configuration of the shutter obstacle detection system 30 according to the first embodiment will be described. The shutter obstacle detection system 30 is a system that detects an obstacle to the shutter curtain 12 that opens and closes the opening 1 as described above. The shutter obstacle detection system 30 includes a seat plate switch 31 and the interlock repeater 16 described as a component of the shutter device 10. Furthermore, the shutter obstacle detection system 30 includes any one of a transmitter 32, a receiver 33, and a cord reel 34. As will be described later, the transmitter 32 is a communication unit that performs both transmission and reception of signals. However, in the first embodiment, the transmitter 32 is referred to as a “transmitter” for convenience of explanation. As will be described later, the receiver 33 is a communication unit that performs both transmission and reception of signals, but in the first embodiment, for convenience of explanation, the receiver 33 is referred to as a “receiver”.

(Configuration-Shutter obstacle detection system-Seat switch)
The seat plate switch 31 is an obstacle sensor that detects that the tip portion (the seat plate 17 in the first embodiment) at the time of the closing operation of the shutter curtain 12 has come into contact with the obstacle. The seat plate switch 31 is configured, for example, in the same manner as in the past, and includes two first terminals 31 a, and the two first terminals 31 a are connected to the two first terminals of the transmitter 32 via the signal line 54. 32b or two second terminals 34b of the cord reel 34. The seat plate switch 31 mechanically changes the displacement when the seat plate 17 comes into contact with an obstacle and is lifted upward relative to the shutter curtain 12 when the shutter curtain 12 is closed. Detecting and outputting to the transmitter 32 or the code reel 34 according to the detection result.

  Specifically, as shown in FIG. 2, when the transmitter 32 is connected to the seat plate switch 31, the two first terminals 32 b of the transmitter 32 and the two terminals 31 a of the seat plate switch 31 are connected to each other. Each is connected via a signal line 54. Then, the current transmitted through the predetermined one of the two first terminals 32 b in the transmitter 32 is input to the predetermined one of the two terminals 31 a of the seat plate switch 31 via the signal line 54. When the seat plate switch 31 is in the closed state because it detects an obstacle, this current flows to the seat plate switch 31, and a predetermined current at the two first terminals 31 a of the seat plate switch 31 is detected. From the other side, the signal is input to a predetermined other of the two first terminals 32 b in the transmitter 32 via the signal line 54. Alternatively, when the current transmitted through the predetermined one of the two first terminals 32b in the transmitter 32 is in an open state because the seat plate switch 31 has not detected an obstacle, the current No longer flows. Thus, since the presence or absence of current changes depending on whether the seat plate switch 31 is in the open state or in the closed state, the seat plate switch 31 is opened when the transmitter 32 detects this current change. (= Output when no obstacle is detected; hereinafter, seat plate switch-off output) and output when seat plate switch 31 is closed (= output when obstacle is detected; hereinafter, seat plate switch) ON output) can be distinguished.

  On the other hand, when the cord reel 34 is connected to the seat plate switch 31, a terminating resistor 54 a is provided between the two signal lines 54 that connect the cord reel 34 and the seat plate switch 31. And the seat board switch 31 will be in an open state in the state which the seat board 17 is not contacting the obstruction. In this case, the current flowing from the interlock repeater 16 to the signal line 54 via the signal line 51 and the cord reel 34 does not flow to the open seat plate switch 31 and returns to the cord reel 34 via the terminating resistor 54a. The signal is input to the interlocking repeater 16 via the signal line 51. On the other hand, in a state where the seat plate 17 is in contact with the obstacle, the seat plate switch 31 is closed by lifting the seat plate 17 upward. In this case, since the resistance of the seat plate switch 31 is smaller than the termination resistor 54a, the current flowing from the interlocking relay 16 to the signal line 54 via the signal line 51 and the cord reel 34 is the closed seat plate switch. The signal is returned to the cord reel 34 via 31 and input to the interlocking repeater 16 via the signal line 51. Thus, since the resistance of the path through which the current flows differs between when the seat plate switch 31 is in the open state and when it is in the closed state, by detecting this resistance change in the interlock repeater 16, A seat plate switch-off output and a seat plate switch-on output can be distinguished.

  However, any detection means for detecting an obstacle can be used in place of the seat plate switch 31. For example, an ultrasonic sensor, a capacitance sensor, or an optical sensor can be used rather than the lower end of the shutter curtain 12. It may be detected that there is an obstacle below.

(Configuration-Shutter obstacle detection system-Transmitter)
The transmitter 32 is a first communication unit that wirelessly transmits a signal (hereinafter referred to as an obstacle detection state signal) including information indicating an obstacle detection state by the obstacle sensor. FIG. 4 is a block diagram showing an electrical configuration of the transmitter 32. The transmitter 32 includes a vibration sensor 32a, two first terminals 32b, a display unit 32c, a registration switch 32d, a first transmission unit 32e, a first reception unit 32f, an antenna 32g, a storage unit 32h, a power supply unit 32i, and a control. The parts 32j are connected as shown in the figure.

  The vibration sensor 32 a is a specifying unit that specifies that the closing operation of the shutter curtain 12 is activated based on the mechanical operation of the shutter curtain 12. Specifically, the vibration sensor 32a is a vibration detection unit that detects vibration, and is fixed to the shutter curtain 12 and outputs a vibration detection signal when mechanical vibration of the shutter curtain 12 is detected. Although the specific configuration of the vibration sensor 32a is arbitrary, for example, a piezoelectric acceleration sensor can be used. However, as the specifying means for specifying the closing operation of the shutter curtain 12, a means other than the vibration sensor 32a may be used. For example, a magnet sensor for detecting that the shutter curtain 12 is mechanically displaced or a capacitance type is used. A sensor may be used, or a detector that detects mechanical rotation of a roller provided on the seat plate 17 so as to be in contact with the guide rail 2.

  The two first terminals 32 b are input means for receiving the input of the seat plate switch-on output or the seat plate switch-off output from the seat plate switch 31. For example, the two first terminals 32 b are respectively connected to the two first terminals 31 a of the seat plate switch 31. It is configured as an input terminal connected via a line 54.

  The display unit 32c is an output unit that notifies the transmitter 32 that a signal is being transmitted by the transmitter 32, and is configured as an LED, for example.

  The registration switch 32d is a registration operation means for registering the receiver 33 with which the transmitter 32 should communicate, and is configured as a push button switch that performs output according to the pressed state, for example. The registration switch 32d is also used as a test switch for testing the normality of the function of the shutter obstacle detection system 30. Of the outputs from the registration switch 32d, the output when not pressed is referred to as "test switch off output", and the output when pressed is referred to as "test switch on output".

The first transmission unit 32e is a transmission unit that transmits the obstacle detection state signal at a first frequency in a predetermined first frequency band.
The first receiving unit 32f is a receiving unit that receives a predetermined signal other than the obstacle detection state signal at a second frequency in a predetermined second frequency band.

Here, the first frequency band and the second frequency band will be described.
The first frequency band may be a frequency band in which the obstacle detection state signal can be transmitted, but in the first embodiment, the first frequency band is a frequency band in which the obstacle detection state signal can be continuously transmitted. The “frequency band in which continuous transmission is possible” is a frequency band in which continuous transmission of signals is permitted (not required to pause or stop transmission) according to communication laws and standards. In particular, in the first embodiment, carrier sense is performed at the time of signal transmission in order to prevent signal collision when a plurality of shutter obstacle detection systems 30 together with the shutter device 10 are arranged close to each other. Use the required frequency band. As the first frequency band that meets such conditions, for example, a 429 MHz band for specific low-power radio stations (specifically, a band of 40 channels at intervals of 12.5 KHz from 429.2500 MHz to 4297375 MHz). is there.

  On the other hand, the second frequency band may be a frequency band that can transmit a predetermined signal, but in the first embodiment, a frequency band that allows intermittent transmission is used. In the first embodiment, a frequency band that does not require carrier sense is used for the second frequency band. As the second frequency band that matches such a condition, for example, there is a 315 MHz band (specifically, a band exceeding 312 MHz and not more than 315.25 MHz) for a specific low-power radio station.

  In the following, for convenience of explanation, the frequency (first frequency) that is included in the first frequency band and the first transmitting unit 32e transmits a signal is “429 MHz”, and is the frequency included in the second frequency band. The frequency (second frequency) at which the first receiving unit 32f receives a signal is referred to as “315 MHz”.

  The antenna 32g is a transmission / reception element that transmits the obstacle detection state signal output from the first transmission unit 32e, or receives a predetermined signal and inputs the signal to the first reception unit 32f. Only one antenna 32g is provided, and this antenna 32g is used for transmission / reception of signals of two frequencies of 429 MHz and 315 MHz. For this reason, the total length of the antenna 32g is determined to be, for example, a predetermined integer ratio of a wavelength of 429 MHz and a predetermined integer ratio of a wavelength of 315 MHz (an antenna 33h of a receiver 33 described later). The same).

  The storage unit 32h is a storage unit that stores various programs and data necessary for operating the transmitter 32 in a nonvolatile manner, and is configured as, for example, an EEPROM. In particular, identification information (hereinafter referred to as a transmitter ID) for uniquely identifying the transmitter 32 is stored in the storage unit 32h at an arbitrary timing such as when shipped from the factory.

  The power supply unit 32 i is configured to include a battery (not shown), and supplies power supplied from the battery to each unit of the transmitter 32. That is, the transmitter 32 is a communication means that operates on the power of the battery.

  The control unit 32j is a control unit that controls each unit of the transmitter 32, and includes, for example, a CPU that executes a program stored in the storage unit 32h. The control unit 32j includes a registration processing unit that executes a registration process that will be described later, a periodic notification processing unit that performs a periodic notification process that will be described later, a descent processing unit that executes an electric descent process and a self-weight descent process that will be described later (obstacle detection process). And an internal timer (not shown) as a time-measuring means for measuring various times. Further, the control unit 32j is configured such that the closing operation of the shutter curtain 12 is activated when an activation on signal transmitted from a second transmission unit 33g of the receiver 33 described later is received by the first reception unit 32f. It is a specifying means for specifying.

(Configuration-Shutter obstacle detection system-Receiver)
Next, the configuration of the receiver 33 in FIG. 1 will be described. The receiver 33 is a second communication unit that receives an obstacle detection state signal by radio (radio wave). FIG. 5 is a block diagram showing an electrical configuration of the receiver 33. The receiver 33 includes two first terminals 33a, two second terminals 33b, two third terminals 33c, a display unit 33d, a registration switch 33e, a second reception unit 33f, a second transmission unit 33g, an antenna 33h, The storage unit 33i, the power supply unit 33j, and the control unit 33k are connected as illustrated.

  The two first terminals 33 a are output means for outputting an obstacle detection state signal to the interlocking relay 16, and are connected to the two first terminals 16 a of the interlocking relay 16 via signal lines 51, for example. Configured as a terminal.

  The two second terminals 33b are input means for receiving the input of the start-on signal output from the interlock repeater 16, and are connected to the two second terminals 16b of the interlock repeater 16 via the signal lines 52, for example. Configured as a terminal.

  The two third terminals 33c are power means for receiving power from the interlock repeater 16, and are configured as terminals connected to the two third terminals 16c of the interlock repeater 16 via the power line 53, respectively. Yes.

The display unit 33d is output means for notifying the outside of the receiver 33 that a signal is being received by the receiver 33, and is configured as an LED, for example.
The registration switch 33e is a registration operation means for registering the combination of the transmitter 32 and the receiver 33 to communicate with each other in the transmitter 32 and the receiver 33, and is configured as a push button switch, for example. ing.

The second receiving unit 33f is a receiving unit that receives the obstacle detection state signal in the first frequency band.
The second transmission unit 33g is a transmission unit that transmits a predetermined signal in the second frequency band.

  The antenna 33h is a transmission / reception element that transmits a predetermined signal output from the second transmission unit 33g or receives an obstacle detection state signal and inputs the signal to the second reception unit 33f.

  The storage unit 33i is a storage unit that stores various programs and data necessary for operating the receiver 33 in a nonvolatile manner, and is configured as, for example, an EEPROM. In particular, identification information (hereinafter referred to as a receiver ID) for uniquely identifying the receiver 33 is stored in the storage unit 33i at an arbitrary timing such as when shipped from the factory. The storage unit 33i includes an internal resistance table 33l.

  The internal resistance table 33 l is an internal resistance storage unit that stores information for specifying the internal resistance of the receiver 33. FIG. 6 is a diagram illustrating a configuration example of the internal resistance table 33l. As shown in FIG. 6, the internal resistance table 331 is configured by associating the item “connection destination state”, the item “internal resistance”, and information corresponding to each item with each other. Here, the information corresponding to the item “internal resistance” is information for specifying the internal resistance of the receiver 33, and corresponds to, for example, “first internal resistance (resistance value = 95Ω to 105Ω)”. Note that the information corresponding to the item “connection destination state” is the same as the information stored corresponding to the same item name in the connection destination state table 16j in FIG.

  In FIG. 5, the power supply unit 33 j is connected to the interlocking relay 16 via a power line (not shown), and supplies the power supplied from the interlocking relay 16 to each part of the receiver 33.

  The control unit 33k is a control unit that controls each unit of the receiver 33, and includes, for example, a CPU that executes a program stored in the storage unit 33i. The control unit 33k includes a registration processing unit that executes a registration process that will be described later, a periodic notification processing unit that performs a periodic notification process that will be described later, and a descent processing unit that executes an electric descent process and a dead weight lowering process that are described later (obstacle detection process). And an internal timer (not shown) as a time measuring means for measuring various times.

(Configuration-Shutter obstacle detection system-Cord reel)
In FIG. 2, the cord reel 34 has a signal line so that the unwinding length of the signal line 54 is always maintained at an appropriate length even if the seat plate 17 moves up and down as the shutter curtain 12 is opened and closed. In addition to winding means 54 for winding or unwinding 54, it is wired relay means for relaying the signal output from the seat plate switch 31 to the interlocking relay 16 via the signal line 51. The cord reel 34 is configured, for example, in the same manner as in the prior art, and includes two first terminals 34 a and two second terminals 34 b, and the two first terminals 34 a are the two first terminals 16 a of the interlock repeater 16. Are connected to each other via a signal line 51, and two second terminals 34 b are connected to two first terminals 31 a of the seat plate switch 31 via a signal line 54.

(Configuration-State determination based on the resistance value of the connected resistor)
In the shutter obstacle detection system 30 configured as described above, the interlock repeater 16 determines the state of the connection destination based on the resistance value of the connection destination connected to the first terminal 16a. The details will be described below.

  First, the state determination in a state where the receiver 33 is connected to the interlocking repeater 16 and the transmitter 32 is connected to the seat switch 31 (hereinafter referred to as receiver connection state) will be described.

  In this receiver connection state, the two first terminals 16 a of the interlocking repeater 16 and the two first terminals 33 a of the receiver 33 are connected via the signal line 51. And the electric current transmitted through the predetermined one of the two first terminals 16a in the interlock repeater 16 is input to the predetermined one of the two first terminals 33a of the receiver 33 via the signal line 51, This current is output from a predetermined other of the two first terminals 33a of the receiver 33 via the internal resistance of the receiver 33, and this current is supplied to the two first terminals 16a of the interlock repeater 16 via the signal line 51. Is input to the predetermined other.

  Further, in this receiver connection state, the two first terminals 32 b of the transmitter 32 and the two terminals 31 a of the seat switch 31 are respectively connected via the signal line 54. Then, the current transmitted through the predetermined one of the two first terminals 32 b in the transmitter 32 is input to the predetermined one of the two terminals 31 a of the seat plate switch 31 via the signal line 54. When the seat plate switch 31 is in the closed state because it detects an obstacle, this current flows to the seat plate switch 31, and a predetermined current at the two first terminals 31 a of the seat plate switch 31 is detected. From the other side, the signal is input to a predetermined other of the two first terminals 32 b in the transmitter 32 via the signal line 54. Alternatively, when the current transmitted through the predetermined one of the two first terminals 32b in the transmitter 32 is in an open state because the seat plate switch 31 has not detected an obstacle, the current No longer flows.

  In such a receiver connection state, the control unit 32j of the transmitter 32 specifies the open / closed state of the seat plate switch 31 based on the current value of the current obtained through the seat plate switch 31, and this identification result Based on this, it is specified which one of the seat plate switch-on output and the seat plate switch-off output is output from the seat plate switch 31, and a transmitter information signal including this identification result is generated and transmitted to the receiver 33. . In addition, the control unit 32j of the transmitter 32 identifies the battery consumption state of the power supply unit 32i, generates a transmitter information signal including the identification result, and transmits the transmitter information signal to the receiver 33. Then, the receiver 33 identifies which one of the seat plate switch-on output and the seat plate switch-off output is output from the seat plate switch 31 based on the transmitter information signal, and determines whether or not the receiver 33 outputs the self signal according to the identification result. Switch the internal resistance. Further, the receiver 33 monitors the communication state with the transmitter 32, and when it is determined that there is a communication failure, the receiver 33 switches its internal resistance according to the determination result. The interlock repeater 16 specifies the combined resistance value of the signal line 51 and the receiver 33 connected to itself based on the current values of the currents flowing through the two first terminals 16a, and according to the specified result. The state of the signal line 51 and the receiver 33 is determined.

  That is, in the receiver connection state, “the connection destination of the interlock relay 16” means “the signal line 51 and the receiver 33”, and “the resistance value of the connection destination” means “the resistance of the signal line 51 and It means the combined resistance value with the resistance of the receiver 33 ”. However, since the resistance value of the signal line 51 is relatively small, it can be ignored in practice. In addition, as a “connection destination state”, in the receiver connection state, an obstacle is not detected by the seat plate switch 31 (hereinafter, an obstacle is not detected), and an obstacle is detected by the seat plate switch 31. State (hereinafter referred to as an obstacle detection state), a state where a communication failure has occurred between the transmitter 32 and the receiver 33 (hereinafter referred to as a communication failure state), and the remaining battery level of the transmitter 32 is a predetermined remaining amount. The following states are assumed to be consumed (hereinafter referred to as battery consumption states). Note that signals output from the receiver 33 to the interlock repeater 16 in the obstacle undetected state, the obstacle detected state, the communication failure state, and the battery exhausted state are a seat plate switch-off signal and a seat plate, respectively. It is called a switch-on signal, a communication failure signal, or a battery consumption signal.

  Next, a specific connection configuration in a state where the cord reel 34 is connected to the interlocking repeater 16 (hereinafter referred to as a cord reel connection state) will be described.

  In this cord reel connection state, the cord reel 34 is connected to the interlock repeater 16, and the seat plate switch 31 is connected to the cord reel 34. Specifically, the two first terminals 16a of the interlock repeater 16 and the two first terminals 34a of the cord reel 34 are connected to each other via the signal line 51, and the two second terminals of the cord reel 34 are connected. 34 b and the two first terminals 31 a of the seat plate switch 31 are connected to each other through a signal line 54. When the seat plate switch 31 is closed because an obstacle is detected by the seat plate switch 31, the current transmitted through the predetermined one of the two first terminals 16a in the interlocking repeater 16 is , The signal line 51, the predetermined one of the two first terminals 34a of the cord reel 34, the two second terminals 34b of the cord reel 34, the predetermined one of the signal line 54, and the two first terminals 31a of the seat plate switch 31 To the seat plate switch 31 sequentially through the predetermined one of the two, the predetermined one of the two first terminals 31a of the seat plate switch 31, the predetermined two of the second terminals 34b of the signal line 54 and the cord reel 34. On the other hand, the predetermined one of the two first terminals 34a of the cord reel 34, the signal line 51, and the predetermined other of the two first terminals 16a of the interlocking relay 16 are sequentially entered into the interlocking relay 16. It is. Further, when the seat plate switch 31 is open because no obstacle is detected by the seat plate switch 31, the current transmitted through the predetermined one of the two first terminals 16a in the interlock repeater 16 is , Signal line 51, predetermined one of the two first terminals 34a of the cord reel 34, predetermined second of the two second terminals 34b of the cord reel 34, signal line 54, termination resistor 54a, signal line 54, cord reel 34 The predetermined other of the two second terminals 34b, the predetermined other of the two first terminals 34a of the cord reel 34, the signal line 51, and the predetermined other of the two first terminals 16a of the interlocking relay 16 are sequentially passed through. Are input to the interlocking repeater 16.

  In such a cord reel connection state, the interlock repeater 16 is connected to the signal line 51, the cord reel 34, the signal line 54, which are connected to the self based on the current value of the current obtained via the cord reel 34. Then, the combined resistance value of the seat plate switch 31 is specified, and the states of the signal line 51, the cord reel 34, the signal line 54, and the seat plate switch 31 are determined according to the specification result. Further, when the signal line 51 or the signal line 54 is disconnected, the current stops flowing through the cord reel 34, or the current value of the current flowing through the cord reel 34 changes, and the signal line 51, the cord reel 34, the combined resistance value of the signal line 54 and the seat plate switch 31 changes, so that the interlock repeater 16 determines disconnection based on the resistance value.

  That is, in the cord reel connection state, “the connection destination of the interlock repeater 16” means “the signal line 51, the cord reel 34, the signal line 54, and the seat plate switch 31”, and “the resistance value of the connection destination”. "Means the combined resistance value of the resistance of the signal line 51, the resistance 34 of the cord reel, the resistance of the signal line 54, the resistance of the termination resistor 54a, and the resistance of the seat plate switch 31". However, since the resistance values of the signal line 51 and the signal line 54 are relatively small, they can be ignored in practice. Further, as the “connection destination state”, in the cord reel connection state, in addition to the obstacle non-detection state and the obstacle detection state, a state in which the signal line 51 and the signal line 54 are disconnected (hereinafter, “disconnection state”) is assumed. doing. In these obstacle undetected state, obstacle detected state, and disconnected state, signals output from the cord reel 34 to the interlock repeater 16 are a seat plate switch-off signal, a seat plate switch-on signal, and a disconnection, respectively. This is called a signal.

  In particular, in Embodiment 1, the interlock repeater 16 does not determine which of the receiver 33 and the cord reel 34 is connected to the first terminal 16a (receiver connection state and cord reel connection state). Without distinguishing between them), the state of the connection destination is determined based on the resistance value of its own connection destination. Therefore, in the present embodiment, the connection destination state of the interlock repeater 16 in the receiver connection state and the connection destination state of the interlock repeater 16 in the cord reel connection state are the same state. The connection destination resistance value of the interlock repeater 16 in the receiver connection state and the resistance value of the connection destination of the interlock repeater 16 in the cord reel connection state are set in the connection destination state table 16j of the interlock repeater 16. Within the set range, the resistance values of the resistors at the respective connection destinations are set so that the resistance values are included in the same set range.

  For example, the resistance value in the obstacle undetected state in the receiver connected state is 47 kΩ, the resistance value in the obstacle undetected state in the cord reel connected state is 51 kΩ, and both of these resistance values are set in the connection destination state table 16j. The resistance value is included in 15 kΩ to 60 kΩ. Similarly, the resistance value in the obstacle detection state in the receiver connection state is set to 100Ω, the resistance value in the obstacle detection state in the cord reel connection state is set to 0Ω, and both of these resistance values are set in the connection destination state table 16j within a range of 10 kΩ. The resistance values included below are used. Here, since the obstacle undetected state and the obstacle detected state are states that can occur in either the receiver connected state or the cord reel connected state, the receiver connected state and the cord reel connected state Therefore, the interlock repeater 16 simply determines that the obstacle is not detected and the obstacle is detected, respectively.

  Further, for example, the resistance value in the battery consumption state in the receiver connection state is 1.1 MΩ, the resistance value in the disconnection state in the cord reel connection state is infinite, and both of these resistance values are set in the connection destination state table 16j. The resistance value is included in 500 kΩ or more. Among these, the battery consumption state is a state that can occur only when the receiver is connected, and the disconnection state is a state that can occur only when the cord reel is connected. Since it is not distinguished from the connection state, it is determined as an integrated state in which either the battery consumption state or the disconnection state has occurred (hereinafter, the battery consumption or the disconnection state).

  For example, the resistance value in the communication failure state in the receiver connection state is 100 kΩ, and this resistance value is a resistance value included in the setting range 99 kΩ to 101 kΩ in the connection destination state table 16j. Although this communication failure state can also occur only in the receiver connection state, the interlock repeater 16 determines that the communication failure state is an independent state.

(processing)
Next, processing executed in the shutter obstacle detection system 30 configured as described above will be described. This process is roughly divided into a receiver connection state process (hereinafter referred to as a receiver connection state process) and a cord reel connection state process (hereinafter referred to as a cord reel connection state process).

(Processing-Receiver connection status processing)
First, the receiver connection state process will be described. This process is roughly divided into a registration process, a periodic notification process, a dead weight lowering process, an electric descent process, and a test process. Hereinafter, after describing the processes common to these processes, each process will be described in turn. In the following, “step” is abbreviated as “S”.

First, “carrier sense”, which is a process common to the processes, will be described.
When transmitting a signal via the first transmitter 32e at 429 MHz, the transmitter 32 performs carrier sense, thereby identifying an empty channel that can be used for transmission and preventing radio wave collision.
Specifically, 40 channels of 429 MHz are set as candidate channels, and one channel is selected from the candidate channels. Then, the first transmission unit 32e is once set as a receiving unit, the received signal strength of the selected channel is measured, and the selected signal strength is determined by determining whether or not the measured signal strength is a predetermined threshold value or more. It is determined whether or not the channel is an empty channel. If it is not an empty channel, another channel is selected from the candidate channels, and the empty channel is similarly determined. Thereafter, similarly, the determination is sequentially performed on each candidate channel, the channel first determined to be an empty channel is specified as an empty channel that can be used for transmission, and the carrier sense is terminated.
The candidate channels may be limited from 40 channels. For example, for each combination of the transmitter 32 and the receiver 33 (for example, the own transmitter ID stored in advance in the storage unit 32h and the registration process) A preset channel is set as a candidate channel for each combination with the receiver ID of the communication partner stored in the storage unit 32h, or a predetermined number (for example, about 3 to 6) of channels is set as a candidate channel. May be.
Immediately after this carrier sense, a connection request signal is transmitted from the transmitter 32 to the receiver 33 via the specified empty channel, and a connection response signal is transmitted from the receiver 33 that has received this connection request signal to the transmitter 32. Thus, communication between the transmitter 32 and the receiver 33 is established.

Next, “channel scan” which is a process common to the processes will be described.
Since the receiver 33 receives a signal via the second receiver 33f at 429 MHz, by performing a channel scan, the channel used by the transmitter 32 to transmit the signal at 429 MHz is specified and transmitted on the channel. Attempts to receive the signal transmitted from the machine 32.
Specifically, one channel is selected from the candidate channels set similarly to the carrier sense of the transmitter 32. Then, it is monitored whether or not the signal can be received via the second receiving unit 33f within a predetermined time by the selected channel, and when the signal can be received, the transmitter ID included in the signal is Then, it is determined whether or not it matches the transmitter ID stored in its own storage unit 33i in the registration process described later. If the signal cannot be received within the predetermined time, or if the transmitter ID does not match even if it can be received, another channel is selected from the candidate channels, and signal reception is performed in the same manner. It is determined whether or not there is a match between the transmitter ID and the transmitter ID. Thereafter, in the same manner, each candidate channel is sequentially determined, and the channel determined to contain the matching transmitter ID is identified as the channel used by the transmitter 32 for signal transmission, and the channel scan ends. To do. In the channel scan before the registration process is performed, the transmitter ID match determination is omitted.
In the following description, it is assumed that the receiver 33 constantly repeats this channel scan unless otherwise specified.

Next, “intermittent reception”, which is a process common to the processes, will be described.
The transmitter 32 monitors whether or not a predetermined intermittent reception timing (for example, every several seconds) has arrived, and if it has arrived, supplies power to the first receiving unit 32f for a predetermined time (for example, several ms). Thus, reception is performed at 315 MHz via the first receiving unit 32f for the predetermined time. The reason why intermittent reception is performed in this way is to reduce battery power consumption required for signal reception.
Although details will be described later, if a predetermined condition is satisfied during intermittent reception every few seconds, reception processing is performed with a shorter interval between intermittent receptions. That is, when the output from the vibration sensor 32a provided in the transmitter 32 is turned on, the shutter curtain 12 is descending, and there is a high possibility that the signal is transmitted from the receiver 33 to the transmitter 32. 32 makes the interval of intermittent reception shorter than usual.
It should be noted that reception may be completely stopped in normal times, and intermittent reception may be started when the output from the vibration sensor 32a is turned on. However, when the shutter curtain 12 is smoothly lowered, the vibration is vibrated. Since there is a possibility that the sensor 32a cannot detect or a failure may occur in the function of the vibration sensor 32a, the reliability of obstacle detection is further improved by performing intermittent reception regardless of the output from the vibration sensor 32a. I am letting.
In the following description, it is assumed that the transmitter 32 constantly repeats this intermittent reception unless otherwise specified.

(Processing-Receiver connection status processing-Registration processing)
Next, the registration process will be described. FIG. 7 is a flowchart of the registration process. This registration process is a process for registering the transmitter ID of the transmitter 32 as a communication partner with the receiver 33, and is activated when the transmitter 32 and the receiver 33 are powered on.

  First, the control unit 33k of the receiver 33 monitors whether or not the registration switch 33e of the receiver 33 has been operated by the user in a predetermined method (for example, whether or not it has been continuously pressed for a predetermined time) (SA1). ), When operated (SA1, Yes), it enters a state of waiting for reception of the transmitter ID transmitted from the transmitter 32 (SA2).

  On the other hand, the control unit 32j of the transmitter 32 monitors whether or not the registration switch 32d of the transmitter 32 has been operated by the user in a predetermined method (for example, whether or not it has been continuously pressed for a predetermined time) (SA3). When operated (SA3, Yes), carrier sense at 429 MHz is performed via the first transmission unit 32e, thereby specifying an available channel that can be used for transmission (SA4, SA5). When the vacant channel can be specified (SA5, Yes), the control unit 32j sends a signal including the transmitter ID stored in the storage unit 32h in advance through the first transmission unit 32e. Transmission is performed at 429 MHz (SA6).

  On the other hand, the control unit 33k of the receiver 33 specifies a channel used by the transmitter 32 to transmit a signal at 429 MHz by performing a channel scan while waiting for transmission of the transmitter ID in SA2, and in that channel, An attempt is made to receive the signal transmitted from the transmitter 32 (SA2). If the signal including the transmitter ID can be received (SA2, Yes), the control unit 33k stores the transmitter ID included in the signal in the storage unit 33i as the transmitter ID of the transmitter 32 serving as a communication partner. Store (SA7). This completes the registration process.

  Here, it is assumed that the transmitter 32 and the receiver 33 perform one-to-one communication, and the registration process is performed in a state where the communication partner transmitter ID is already stored in the storage unit 33i of the receiver 33. In this case, it is assumed that the transmitter ID of the storage unit 33i is overwritten by the newly received transmitter ID. However, when performing one-to-many communication, a plurality of transmitter IDs may be registered in the storage unit 33i. The registration process is valid only for a predetermined time (for example, one minute) after the registration switch 32d is pressed by the user. If the transmitter ID of the communication partner cannot be received within this time, the registration process is performed. May be terminated. Further, the receiver ID may be registered in the transmitter 32 by the same process as the registration of the transmitter ID. That is, the receiver ID may be transmitted from the receiver 33 to the transmitter 32, and the receiver ID may be stored in the storage unit 32h of the transmitter 32. In this case, after that, when the transmitter 32 intermittently receives a signal transmitted from the receiver 33 at 315 MHz, the transmitter 32 stores the receiver ID included in the signal in its own storage unit 33i. It may be determined whether or not the receiver ID matches, and the signal may be accepted as a valid signal only if it matches.

(Processing-Receiver connection status processing-Periodic notification processing)
Next, the periodic notification process will be described. FIG. 8 is a flowchart of the regular notification process. This process is a process of periodically transmitting information on the normality of the function of the transmitter 32 and the output state of the seat switch 31 to the receiver 33, and is automatically and repeatedly activated after the registration process.

  First, the control unit 33k of the receiver 33 monitors whether or not a predetermined periodic notification timing (for example, every several days) has arrived (SB1), and if it has arrived (SB1, Yes), a periodic notification request signal Is transmitted at 315 MHz via the second transmitter 33g (SB2). The periodic notification request signal is a signal including data indicating that a periodic notification is requested, and is generated in a predetermined format.

  On the other hand, when the control unit 32j of the transmitter 32 receives the periodic notification request signal from the receiver 33 by intermittent reception (SB3, Yes), the carrier sense is performed to identify an empty channel (SB4, SB5), and the periodic A report signal is generated and transmitted at 429 MHz through an empty channel via the first transmitter 32e (SB6). This periodic notification signal (obstacle detection state signal) is data indicating whether the output from the seat plate switch 31 is a seat plate switch-off output or a seat plate switch-on output, and an output test switch-off output from the test switch. And a signal including the transmitter switch ID set in the storage unit 32h and generated in a predetermined format.

  At this time, the determination of whether or not the battery is consumed is performed, for example, as follows. That is, the control unit 32j compares the battery voltage obtained by a known method with a predetermined threshold value, and determines that there is no battery consumption if the voltage is equal to or higher than the predetermined threshold value. Judge that there is. Alternatively, the control unit 32j continuously calculates the elapsed time after the battery is connected to the transmitter 32 (more specifically, the elapsed time after the battery power is supplied to each unit of the transmitter 32). The elapsed time is compared with a predetermined time (for example, several years). If the elapsed time is less than the predetermined time, it is determined that the battery is not consumed. If the elapsed time is equal to or longer than the predetermined time, the battery is consumed. Is determined. When it is determined that the battery is consumed, the control unit 32j notifies the outside that the battery is consumed by lighting or blinking the display unit 32c.

  Next, the control unit 33k of the receiver 33 monitors whether or not the communication establishment associated with the carrier sense of the transmitter 32 can be established within a predetermined time after SB2 (SB7) and establishes the communication. If it is not possible (SB7, No), a communication failure signal is output to the interlock repeater 16 (SB8), and the periodic notification process is terminated.

  At this time, as processing for the communication failure, for example, when the communication unit 33k cannot establish communication, the state of the connection destination = communication failure state is specified. Next, the control unit 33k refers to the information specifying the internal resistance stored in the internal resistance table 33l to thereby determine the internal resistance corresponding to the communication failure state (that is, the third internal resistance (resistance shown in FIG. 6). Value = 99 kΩ to 101 kΩ) and changing its own internal resistance to the above-described third internal resistance, a communication failure signal is output via the two first terminals 33a (communication of SC11 described later) The same applies to the output of the fault signal).

  In this case, the control unit 16i of the interlock repeater 16 determines the resistance value of the connection destination of the interlock repeater 16 (that is, the signal line 51 based on the current value of the signal line 51 acquired from the two first terminals 16a. Based on the identified resistance value by referring to the information specifying the connection destination state stored in the connection destination state table 16j. The connection destination state = communication failure state is specified (more specifically, when the specified resistance value = 100 kΩ, the connection destination state = communication failure state is specified). Then, the control unit 16i lights or blinks the display unit 16f, lights or blinks an indicator lamp provided in the manual closing device 15, or sends a communication failure signal to a predetermined external device via the output unit 16e. Or the like, the occurrence of these states is notified to the outside.

  On the other hand, if the communication can be established within the predetermined time (SB7, Yes), the control unit 33k receives the periodic notification signal at 429 MHz via the second receiving unit 33f by the established communication (SB9, Yes), processing corresponding to the content of the periodic notification signal is performed (SB10). For example, the control unit 33k specifies the state of the connection destination based on the periodic notification signal, and refers to the information specifying the internal resistance stored in the internal resistance table 33l, thereby determining the state of the specified connection destination. By specifying the internal resistance corresponding to, and changing its own internal resistance to the specified internal resistance, the seat plate switch-off signal, the seat plate switch-on signal, and the battery consumption signal are Output via the first terminal 33a.

  At this time, the controller 33k determines that the seat plate switch-off signal and the seat plate switch-on signal are changed (when the seat plate switch-off signal is switched to the seat plate switch-on signal, or the seat plate switch-on signal is In the case of switching to the seat plate switch-off signal), the seat plate switch-off signal or the seat plate switch-on signal is output in preference to the other signals. On the other hand, if there is no change in the seat plate switch-off signal and the seat plate switch-on signal for a predetermined time (for example, several hundred seconds), a signal other than the seat plate switch-off signal or the seat plate switch-on signal is output. To do. Here, when there are a plurality of signals to be output, only a signal with the highest priority (for example, a battery exhaustion signal) is output based on a predetermined priority, or each signal is output in order of priority. The output is sequentially switched at a predetermined interval.

  In this case, the control unit 16i of the interlocking relay 16 specifies the resistance value of the connection destination of the interlocking relay 16 based on the current value of the signal line 51 acquired from the two first terminals 16a, and the connection destination By referring to the information specifying the state of the connection destination stored in the state table 16j, the state of the connection destination is specified based on the specified resistance value. Then, the control unit 16i lights or blinks the display unit 16f, lights or blinks an indicator lamp provided in the manual closing device 15, or sends a communication failure signal to a predetermined external device via the output unit 16e. Or the like, the occurrence of these states is notified to the outside. This completes the periodic notification process.

(Processing-Receiver connection status processing-Weight drop processing)
Next, the weight drop processing (obstacle detection processing, harm prevention processing) will be described. 9 and 10 are flowcharts of the dead weight lowering process. This process is a process for lowering the shutter curtain 12 by its own weight when a fire is detected by the fire detector 21 of the fire alarm system 20, and is started as an interrupt process for the regular report process.

  When a fire is detected by the fire detector 21 of the fire alarm system 20, the fire detector 21 outputs a fire detection signal to the disaster prevention panel 22, and the disaster prevention panel 22 outputs a transfer signal to the interlock repeater 16, The interlock repeater 16 outputs an activation signal to the automatic closing device 14, and the automatic closing device 14 releases the brake of the opening / closing machine 13 and starts the weight drop of the shutter curtain 12. Alternatively, when the emergency closing button of the manual closing device 15 is pressed by the user, similarly, the interlock relay 16 outputs an activation signal to the automatic closing device 14, and the automatic closing device 14 applies the brake of the switch 13. It cancels | releases and the dead weight fall of the shutter curtain 12 is started. When the self-weight drop is started in this way, the interlock repeater 16 continuously outputs a start-on signal to the receiver 33 via the two second terminals 16b.

  After that, as shown in FIG. 9, when the activation on signal is received via the two second terminals 33b of the receiver 33 (SC1, Yes), the control unit 33k of the receiver 33 receives the activation on signal. Is transmitted at 315 MHz via the second transmitter 33g (SC2).

  On the other hand, when the shutter curtain 12 starts to descend, the vibration sensor 32a that detects the vibration of the shutter curtain 12 that occurs with the descending outputs a vibration detection signal. When this vibration detection signal is output (SC3, Yes), the control unit 32j of the transmitter 32 outputs the vibration detection signal even if a predetermined time (for example, 1s) has elapsed since the output. (SC4, No), if not output (SC4, No), it returns to SC3 assuming that the temporary vibration of the shutter curtain 12 due to an earthquake or wind is detected. On the other hand, if it is output (SC4, Yes), it is assumed that the continuous vibration of the shutter curtain 12 due to the descent has been detected, and whether or not the timing of intermittent reception at regular intervals at normal times has arrived. Regardless, interrupt reception at 315 MHz is performed via the first receiver 32f (SC5). For example, the interrupt reception is performed by shortening the reception interval of the intermittent reception that is normally performed. If the vibration detection of the vibration sensor 32a is the descent control of the shutter curtain 12 based on the activation signal output from the interlock repeater 16, the activation on signal should be transmitted from the receiver 33. Therefore, it is for trying to promptly receive the activation on signal transmitted from the receiver 33.

  If the activation on signal is not received within the predetermined time (SC6, No), the controller 32j determines that the vibration detected by the vibration sensor 32a is not caused by the descent of the shutter curtain 12, and SC3 Return to. On the other hand, when the activation on signal can be received within the predetermined time (SC6, Yes), the control unit 32j identifies that the closing operation of the shutter curtain 12 has been activated, and transmits the state information from the transmitter 32 to the transmitter side. Is transmitted to the receiver side, carrier sense is performed at 429 MHz, and an empty channel used for transmission is specified (SC7, SC8).

  Next, the control unit 32j generates a transmitter information signal, and continuously transmits this transmitter information signal through the first transmission unit 32e through an empty channel at 429 MHz for a predetermined time (SC9). This transmitter information signal includes data indicating whether the output from the seat plate switch 31 is a seat plate switch-off output or a seat plate switch-on output, the output from the test switch, the test switch-off output, and the test switch-on output. This is a signal including data indicating which one is, data indicating whether or not the battery is exhausted, and a transmitter ID set in the storage unit 32h, and is generated in a predetermined format. The transmitter information signal indicates whether the output from the seat plate switch 31 is a seat plate switch-off output or a seat plate switch-on output as the minimum information necessary for the own weight descent process or the electric descent process. Only the data and the transmitter ID may be included. Since the output from the seat plate switch 31 is off at the beginning of transmission of the transmitter information signal, a transmitter information signal including data indicating that the seat plate switch is off is transmitted. Is transmitted, a transmitter information signal including data indicating the state after the change is transmitted.

  Thereafter, in order to manage the lapse of a predetermined time for performing this continuous transmission, the control unit 32j starts measuring the transmission time by the internal timer of the control unit 32j simultaneously with or immediately after the SC9, as shown in FIG. As described above, it is monitored whether or not the measured time has become a predetermined continuous transmission stop determination time (for example, 5 minutes) or more (SC14). Then, the continuous transmission of the transmitter information signal is stopped (SC15), the communication established with the receiver 33 is interrupted, the intermittent reception is restored, and the dead weight lowering process is terminated. This process is performed when the seat plate switch 31 fails to output the seat plate switch 31 for some reason when it is fully closed. This is to avoid the problem.

  During the continuous transmission stop determination time of the continuous transmission managed in this way, the control unit 32j sequentially generates and transmits a transmitter information signal including data corresponding to the output for each time point from the seat plate switch 31. To do. When the shutter curtain 12 hits an obstacle during the continuous transmission stop determination time of the continuous transmission, or when the shutter curtain 12 is fully closed, the output from the seat plate switch 31 is the seat plate switch. When the output is turned on (SC13, Yes), in order to stop the self-weight drop of the shutter curtain 12, the self-weight drop stop process is started (SC16). Details of the self-weight drop stopping process will be described later. In addition, when the output from the seat plate switch 31 becomes the seat plate switch-on output, the control unit 32j turns on or blinks the display unit 32c so that the output of the seat plate switch 31 is on. Inform the outside that there is.

  On the other hand, as shown in FIG. 9, the control unit 33k of the receiver 33 starts timing by the internal timer of the control unit 32j in order to measure the communication establishment time simultaneously with or immediately after the transmission of the activation on signal in SC2. Then, it is monitored whether or not communication with the transmitter 32 can be established before the measured time exceeds a predetermined time (SC10). If communication cannot be established even after a predetermined time (SC10, No), a communication failure signal is output to the interlocking relay 16 (SC11). As the processing for the communication failure, the control unit 33k causes the display unit 33d of the receiver 33 to display an indication of the state at the time of the communication failure, as well as the communication failure processing of SB8, The occurrence of a communication failure is notified to the outside by outputting a communication failure signal to a predetermined external device such as the disaster prevention panel 22. On the other hand, if communication can be established with carrier sense in SC7 of the transmitter 32 before the predetermined time or longer, the transmitter information signal from the transmitter 32 at 429 MHz is transmitted via the second receiver 33f. Receive continuously (SC12).

  Further, the control unit 33k starts timing by the internal timer of the control unit 32j in order to measure the reception time at the same time or immediately after reception of the transmitter information signal in the SC 12, as shown in FIG. It is monitored whether or not the measured time exceeds a predetermined time (SC18). If the measured time exceeds the predetermined time (SC18, Yes), reception of the transmitter information signal is stopped (SC19). The communication established with No. 32 is cut off and the dead weight lowering process is terminated.

  During the predetermined reception time managed in this way, the control unit 33k monitors the data corresponding to the output of the seat plate switch 31 included in the transmitter information signal for each time point, and during this predetermined reception time. In addition, when the data indicating that the output from the seat plate switch 31 is the seat plate switch-on output is received (Yes in SC17), the own weight lowering stop process is started in order to stop the own weight lowering of the shutter curtain 12. (SC16). Details of the self-weight drop stopping process will be described later.

  In addition, during continuous transmission from SC9 in FIG. 9 to SC15 in FIG. 10, if it is necessary to stop this continuous transmission for some reason, the receiver that has received the output from the interlock repeater 16 The control unit 33k of 33 transmits a continuous transmission stop instruction signal for instructing stop of continuous transmission at 315 MHz via the second transmission unit 33g, and shifts to SC19 to stop reception. On the other hand, when the control unit 32j of the transmitter 32 receives the continuous transmission stop instruction signal at 315 MHz via the first receiving unit 32f, the control unit 32j proceeds to SC15 and continues even before the predetermined time of SC14 has elapsed. Stop sending. That is, in the first embodiment, the stop condition for stopping the continuous transmission of the transmitter information signal by the first transmission unit 32e is that the predetermined time of SC14 has elapsed or the continuous transmission stop instruction signal has been received. Until either one of these conditions is satisfied, the transmitter information signal is continuously transmitted regardless of the change in the output state of the seat plate switch 31, and the transmitter is transmitted according to the output state of the seat plate switch 31. Only the contents of the information signal are rewritten.

(Processing-Receiver connection status processing-Weight drop processing-Weight drop stop processing)
Next, the details of the self-weight drop stop process of SC16 will be described. FIG. 11 is a flowchart of the dead weight descent stop process. This process is a process for stopping the weight drop of the shutter curtain 12.

  First, the control unit 33k of the receiver 33 that has received data indicating that the seat plate switch-on output has been received from the transmitter 32 due to detection of an obstacle or the shutter curtain 12 being fully closed, The switch-on signal is output to the interlocking repeater 16 via the two first terminals 33a (SD1).

  As for the output of the seat plate switch-on signal, the seat plate switch-on signal is output with priority over other signals as described above. Specifically, the control unit 33k identifies the internal resistance corresponding to the state of the connection destination corresponding to the seat plate switch-on signal by referring to the information for identifying the internal resistance stored in the internal resistance table 33l. (Specifically, since the connection destination state corresponding to the seat plate switch-on signal is an obstacle detection state, the first internal resistance (resistance value = 95Ω to 105Ω) shown in FIG. 6 is specified)) By changing its own internal resistance to the specified first internal resistance, a seat plate switch-on signal is output to the interlock repeater 16 via the two first terminals 33a.

  In this case, the control unit 16i of the interlocking relay 16 specifies the resistance value of the connection destination of the interlocking relay 16 based on the current value of the signal line 51 acquired from the two first terminals 16a, and the connection destination By referring to the information specifying the connection destination state stored in the state table 16j, the connection destination state = obstacle detection state is specified based on the specified resistance value (more specifically, When the specified resistance value = 100Ω, the connection destination state = obstacle detection state is specified). And the control part 16i controls the gravity fall of the shutter curtain 12 based on the detection state of a lower limit switch, and the presence or absence of the power failure in the shutter apparatus 10 specified by the well-known method.

  Specifically, when the lower limit switch detects that the lower end of the shutter curtain 12 is located above the lower limit position, and the shutter device 10 is not out of power, it automatically closes. A control signal is output to the device 14, the automatic closing device 14 activates the brake of the switch 13 to stop the weight drop of the shutter curtain 12 once, drives the switch 13 to raise it for a predetermined time, and then stops. An operation (touch-up operation) is performed (the same applies to a self-weight drop stop process in a cord reel connection state process described later). In this case, the interlock repeater 16 continuously outputs the activation on signal to the receiver 33. However, when the recovery button of the manual closing device 15 is pressed in this state, the interlock repeater 16 outputs a start-off signal to the receiver 33.

  Alternatively, when the lower limit switch detects that the lower end of the shutter curtain 12 is located above the lower limit position, and the shutter device 10 is out of power, the automatic closing device 14 is used. A control signal is output, and the automatic closing device 14 operates the brake of the switch 13 to temporarily stop the weight drop of the shutter curtain 12 (touch stop operation) (self-weight drop stop of the cord reel connection state process described later) The same applies to processing). Also in this case, the interlock repeater 16 continuously outputs a start-on signal to the receiver 33.

  On the other hand, when it is detected by the lower limit switch that the lower end of the shutter curtain 12 is located below the lower limit position, the shutter curtain 12 can be controlled regardless of whether or not the shutter device 10 is out of power. After a predetermined time has elapsed after the lower end has passed the lower limit position, a control signal is output to the automatic closing device 14, and the automatic closing device 14 activates the brake of the switch 13 to stop the weight drop of the shutter curtain 12 ( Complete stop operation). The predetermined time at this time is set so that the shutter curtain 12 is stopped further below the position where the seat plate switch 31 is in contact with the floor surface and the seat plate switch is turned on (the code reel connection state process described later). The same applies to the dead weight descent stop process). The reason why the stop after the predetermined time elapses is to prevent a gap from being formed between the seat plate 17 and the floor surface even when the floor surface is inclined. When the complete stop operation is performed as described above, the interlock repeater 16 outputs a start-off signal to the receiver 33.

  The control unit 33k of the receiver 33 monitors the output of the start-off signal from the interlock repeater 16 (SD2). And when the start-off signal is received from the interlock repeater 16 (SD2, Yes), the start-off signal is transmitted at 315 MHz via the second transmitter 33g (SD3), and then the transmitter information signal is received. (SD4), the communication established with the transmitter 32 is cut off, the dead weight drop stop process is terminated, and the dead weight drop process of FIGS.

  On the other hand, the control unit 32j of the transmitter 32 monitors the elapsed time after the output from the seat plate switch 31 becomes the seat plate switch-on output in SC13 of FIG. Whether or not a start-off signal is received from is monitored (SD7). If the activation-off signal is received from the receiver 33 (SD7, Yes) before the elapsed time continues for a predetermined time or longer (SD5, No), it is considered that the complete stop operation has been performed. Immediately stop the continuous transmission of the transmitter information signal to suppress battery consumption (SD8), cut off the communication established with the receiver 33, and terminate the own weight drop stop processing. End the descent process.

  Further, the control unit 32j continuously monitors the output from the seat plate switch 31 while monitoring the elapsed time in SD5 and receiving the start-off signal in SD7 (SD6). When a person sandwiched between the shutter curtains 12 evacuates or the obstacle hitting the shutter curtain 12 is removed, the obstacles are not detected by the seat plate switch 31 and the output from the seat plate switch 31 When the plate switch-off output is detected (SD6, Yes), the weight reduction restart process is started in order to restart the weight reduction of the shutter curtain 12 (SD9).

  Further, before receiving the start-off signal from the receiver 33 (SD7, No) or before the output from the seat plate switch 31 becomes the seat plate switch-off output (SD6, No), the elapsed time is a predetermined time or more. When it continues (SD5, Yes), the control unit 32j stops the continuous transmission of the transmitter information signal to suppress battery consumption (SD10), and monitors the output from the seat plate switch 31 (SD11). Whether or not the start-off signal is received from the receiver 33 is monitored again (SD12). And when the start-off signal is received from the receiver 33 (SD12, Yes), the dead weight lowering stop process is terminated, and the dead weight lowering process of FIGS. On the other hand, when the output from the seat plate switch 31 becomes the seat plate switch-off output (SD11, Yes), the own weight lowering restart process is started to restart the own weight lowering of the shutter curtain 12 (SD9).

(Processing-Receiver connection status processing-Weight reduction processing-Weight reduction stop processing-Weight reduction restart processing)
Next, the weight reduction restart process will be described. 12 and 13 are flowcharts of the weight drop restart process. This process is a process for resuming the weight drop of the shutter curtain 12 stopped by the weight drop stop process.

  First, the control unit 32j of the transmitter 32 generates a transmitter information signal, and continuously transmits this transmitter information signal through the first transmission unit 32e through an empty channel at 429 MHz (SE1). This transmitter information signal is generated in the same manner as SC9 in FIG. In addition, when the dead weight resumption restart process is started by moving from SD6 in FIG. 11 to SD9, the continuous transmission of the transmitter information signal is not stopped, and the transmitter 32 is also connected to the receiver 33. Since it is not blocked, continuous transmission in SE1 can be performed without performing carrier sense or specifying an empty channel. On the other hand, when the dead weight descent resumption process is started due to the shift from SD11 to SD9 in FIG. 11, continuous transmission of the transmitter information signal is stopped in SD10, and connection with the receiver 33 in the transmitter 32 is performed. Therefore, the carrier sense and the identification of the empty channel are performed in the same manner as SC7 and SC8 in FIG. 9, and then the continuous transmission in SE1 is performed.

  On the other hand, the control unit 33k of the receiver 33 receives a transmitter information signal including data indicating that the output from the seat plate switch 31 is a seat plate switch-off output via the second receiver 33f at 429 MHz ( SE2) By switching the resistance value inside the output unit 33b, a seat plate switch-off signal indicating that the obstacle has been removed is output to the interlocking relay 16 via the two first terminals 33a (SE3).

  Specifically, the control unit 33k specifies the internal resistance corresponding to the connection destination state corresponding to the seat plate switch-off signal while referring to the information specifying the internal resistance stored in the internal resistance table 33l. (Specifically, since the state of the connection destination corresponding to the seat plate switch-off signal is an obstacle undetected state, the second internal resistance shown in FIG. 6 (resistance value = 44.7 kΩ to 49.4 kΩ)) The seat plate switch-off signal is output to the interlocking repeater 16 through the two first terminals 33a by changing its own internal resistance to the specified second internal resistance.

  In this case, the control unit 16i of the interlocking relay 16 specifies the resistance value of the connection destination of the interlocking relay 16 based on the current value of the signal line 51 acquired from the two first terminals 16a, and the connection destination While referring to the information specifying the connection destination state stored in the state table 16j, the connection destination state = obstacle undetected state is specified based on the specified resistance value (more specifically, When the specified resistance value is 45 kΩ, the connection destination state = obstacle undetected state is specified). Then, the control unit 16i outputs a control signal to the automatic closing device 14 after a predetermined time during which the caught person can evacuate from the shutter curtain 12 with certainty, and the automatic closing device 14 releases the brake of the switch 13 The weight drop of the shutter curtain 12 is resumed. At the same time, the control unit 16 i outputs a start-on signal to the receiver 33 to notify that the weight reduction of the shutter curtain 12 has been resumed.

  When the activation on signal is received via the two second terminals 33b (SE4, Yes), the control unit 33k of the receiver 33 receives the activation on signal via the second transmission unit 33g as shown in FIG. The start-up signal is received by the transmitter 32 (SE6). In FIG. 13, SE5 and SE6 are shown at the positions shown for convenience, but actually, as described above, the interlock repeater 16 sends the start-on signal to the receiver 33 until it completely stops during automatic descent. The receiver 33 does not transmit a signal until it receives a start-off signal from the interlocking repeater 16 after transmitting the start-on signal to the transmitter 32 once. Therefore, SE5 and SE6 may be described at other positions in FIG. 13 or may be omitted.

  On the other hand, the control unit 32j of the transmitter 32 starts the continuous transmission of the transmitter information signal in SE1 of FIG. 12, and then manages the passage of a predetermined time for performing this continuous transmission. By starting the measurement of the transmission time by the internal timer of the control unit 32j, as shown in FIG. 13, it is monitored whether or not the time measured has become a predetermined time or more (SE8). When the predetermined time or longer is reached (SE8, Yes), the continuous transmission is stopped (SE9), the communication established with the receiver 33 is interrupted, the intermittent reception is resumed, and the own weight drop restart process is performed. Is terminated, the own weight drop stopping process of FIG. 11 is finished, and the own weight lowering process of FIGS.

  During a predetermined period of continuous transmission managed in this way, the control unit 32j generates and transmits a transmitter information signal including data corresponding to the output from the seat plate switch 31 at each time point. Then, when the output from the seat plate switch 31 again becomes the seat plate switch-on output during the predetermined time of the continuous transmission (SE7, Yes), the weight drop of the shutter curtain 12 is stopped. 11 is started again (step SE10). Thereafter, as described above, the dead weight descent stop process and the dead weight descent restart process are repeated according to the output of the seat plate switch 31.

  On the other hand, after receiving the transmitter information signal in SE2 of FIG. 12, the control unit 33k of the receiver 33 starts timing by the internal timer of the control unit 32j in order to measure the reception time of 429 MHz. As shown in (5), it is monitored whether or not the measured time is equal to or longer than a predetermined time (SE12). When the predetermined time has elapsed (SE12, Yes), the reception is stopped (SE13), the communication established with the transmitter 32 is interrupted, the intermittent reception is resumed, and the weight reduction restart process is performed. This is the end, the weight drop stopping process in FIG. 11 is ended, and the weight falling process in FIGS.

  During the predetermined reception time managed as described above, the control unit 33k monitors data corresponding to the output of the seat plate switch 31 included in the transmitter information signal at each time point. When the data indicating that the output from the seat plate switch 31 is the seat plate switch-on output is received again during the predetermined time of reception (SE11, Yes), the weight of the shutter curtain 12 is lowered. In order to stop, the own weight drop stop process of FIG. 12 is started again (SE10). Thereafter, as described above, the dead weight descent stop process and the dead weight descent restart process are repeated according to the output of the seat plate switch 31.

(Processing-Receiver connection status processing-Electric descent processing)
Next, electric descent processing (obstacle detection processing, harm prevention processing) will be described. This process is a process for electrically lowering the shutter curtain 12 by a user's manual operation while the regular notification process is being performed, and is started as an interrupt process for the regular report process. In the following description, reference is also made to the flowcharts of FIGS.

  When the user performs a closing operation via the manual closing device 15, an operation signal is output from the manual closing device 15 to the interlocking relay 16, and the interlocking relay 16 outputs an activation signal to the switch 13. However, the shutter curtain 12 is electrically lowered by driving the winding shaft in the unwinding direction with the brake released. Then, similarly to SC1 and SC2 in FIG. 9, the receiver 33 that has received this activation on signal transmits the activation on signal to the transmitter 32, and this activation on signal is similar to SC6 to SC9 in FIG. The transmitter 32 that receives the signal starts continuous transmission of the transmitter information signal to the receiver 33.

  Thereafter, the output from the seat plate switch 31 becomes the seat plate switch-on output, and the transmitter information signal including the seat plate switch-on output is transmitted from the transmitter 32 to the receiver 33, as in SC13 of FIG. 11, when the seat plate switch-on output is output from the receiver 33 to the interlock repeater 16, the interlock repeater 16 controls the shutter curtain 12 based on the detection state of the lower limit detection limit switch. .

  Specifically, when the lower limit detection limit switch detects that the lower end of the shutter curtain 12 is located above the lower limit position, there is a possibility that the lower end of the shutter curtain 12 has contacted an obstacle. Therefore, the descent of the shutter curtain 12 is temporarily stopped, and then the interlocking relay 16 that receives the seat plate switch-on signal from the receiver 33 outputs a start signal to the switch 13, and the switch 13 releases the brake. In such a state, the shutter curtain 12 is lifted by a predetermined amount by driving the winding shaft in the winding direction by a predetermined amount to stop it (touch-up operation), thereby further ensuring the damage to the obstacle. To prevent.

  On the other hand, when it is detected by the lower limit detection limit switch that the lower end of the shutter curtain 12 is located below the lower limit position, it is considered that the lower end of the shutter curtain 12 is in contact with the floor surface. An operation for stopping the descent of the shutter curtain 12 (touch stop operation) is performed.

  In any of these cases, the shutter curtain 12 is not automatically lowered again during the electric lowering, but the user operates the manual closing device 15 again to lower the shutter curtain 12 as necessary.

  In any of these cases, the interlock repeater 16 outputs a start-off signal to the receiver 33, and the control unit 33j of the receiver 33 that has received this start-off signal activates similarly to SD3 in FIG. When the off signal is transmitted via the second transmitter 33f at 315 MHz and the starter off signal is received, the controller 32j of the transmitter 32 immediately stops the continuous transmission as in SD8 of FIG. Battery consumption is suppressed and communication established with the receiver 33 is cut off. However, even in the case of electric lowering, the shutter curtain 12 may be lowered again after a predetermined time after receiving the seat plate switch-off output as described above.

  When the obstacle is removed after the shutter curtain 12 is temporarily stopped and the output from the seat plate switch 31 becomes the seat plate switch-off output, the descent resuming process may not be performed. The shutter curtain 12 may be lowered again after a predetermined time after receiving the seat plate switch-off output as described above.

(Processing-Receiver connection status processing-Test processing)
Next, the test process will be described. This process is a process for performing a test on the normality of the functions of the transmitter 32 and the receiver 33, and is activated at an arbitrary timing by a user operation. First, the control unit 32j of the transmitter 32 determines whether or not the registration switch 32d of the transmitter 32 has been operated by a user in a predetermined method (for example, continuously for a predetermined time different from the pressing time of the registration switch 32d in the registration process). In the same manner as SC9 in FIG. 9, a transmitter information signal including data indicating a seat plate switch-on output is generated, and when this is operated, the transmitter information signal is generated. The signal is continuously transmitted for a predetermined time through the first transmission unit 32e on an empty channel at 429 MHz. Thus, the own weight drop stop process of FIG. 11 is performed, and the transmitter 32 and the receiver 33 are monitored by monitoring whether or not the own weight drop stop process is normally executed at the time of construction or periodic inspection. Can be tested for the normality of the function.

(Processing-Code reel connection status processing)
Next, the cord reel connection state process will be described. This process is roughly divided into a constant monitoring process, a dead weight lowering process, and an electric descent process. However, among these processes, the procedures that are not specified are the same as the procedures of the receiver connection state process, and the description thereof is omitted.

(Processing-Code reel connection status processing-Continuous monitoring processing)
First, the constant monitoring process will be described. The control unit 16i of the interlock repeater 16 constantly monitors the current value of the signal line 51 acquired from the two first terminals 16a, and based on this current value, the resistance value of the connection destination of the interlock repeater 16 (That is, the combined resistance value of the resistance of the signal line 51, the resistance of the cord reel 34, the resistance of the signal line 54, the resistance of the termination resistor 54a, and the resistance of the seat plate switch 31) While referring to the information specifying the connection destination state stored in the table 16j, the connection destination state is always specified based on the specified resistance value. Here, for example, when the signal line 51 or the signal line 54 is disconnected and the resistance value of the connection destination of the interlock repeater 16 changes (specifically, the resistance value of the connection destination of the interlock repeater 16 = infinity). When the disconnection signal is output from the cord reel 34 to the interlocking repeater 16 and the connection destination state = battery consumption or disconnection state is specified, the control unit 16i displays the display unit. By turning on or blinking 16f, turning on or blinking an indicator lamp provided in the manual closing device 15, or outputting a communication failure signal to a predetermined external device via the output unit 16e, these Inform the outside of the occurrence of the condition.

(Processing-Cord reel connection status processing-Weight drop processing)
Next, the dead weight lowering process will be described. The control unit 16i of the interlock repeater 16 starts the weight drop of the shutter curtain 12, and based on the current values of the signal lines 51 acquired from the two first terminals 16a, the resistance of the connection destination of the interlock repeater 16 The value is specified, and the state of the connection destination is specified based on the specified resistance value while referring to the information specifying the state of the connection destination stored in the connection destination state table 16j. Here, for example, when an obstacle is detected by the seat plate switch 31 and the resistance value of the connection destination of the interlock repeater 16 changes (specifically, the resistance value of the connection destination of the interlock repeater 16 = 100Ω). When the seat plate switch-on signal is output from the cord reel 34 to the interlock repeater 16, and the connection destination state = obstacle detection state is identified, the control unit 16i Start the descent stop process.

(Processing-Cord reel connection status processing-Own weight descent processing-Own weight descent stop processing)
Next, the details of the dead weight drop stop process of the dead weight drop process will be described. First, the control unit 16i of the interlock repeater 16 that has received the seat plate switch-on signal from the cord reel 34 uses the detection state of the lower limit switch and the known method in the same manner as the receiver weight state stop process of the receiver connection state process. Based on the presence or absence of a power failure in the identified shutter device 10, the weight drop of the shutter curtain 12 is controlled.

  That is, the control unit 16i of the interlock repeater 16 monitors the output from the seat plate switch 31, specifies the detection state of the lower limit switch, and the output from the seat plate switch 31 = the seat plate switch-on output, If the lower limit switch is ON, it is considered that a complete stop operation or the like has been performed. Therefore, the dead weight descent stop process is terminated, and the dead weight descent process is terminated. On the other hand, if the control unit 16i is not the output from the seat plate switch 31 = the seat plate switch on output, or the lower limit switch is not on, it is considered that the complete stop operation or the like is not performed. Start the weight drop restart process.

  At this time, in order to specify the output from the seat plate switch 31, the control unit 16i determines the resistance value of the connection destination of the interlock repeater 16 based on the current value of the signal line 51 acquired from the two first terminals 16a. The connection destination state is specified based on the specified resistance value while referring to the information specifying the connection destination state stored in the connection destination state table 16j.

(Processing-Code reel connection status processing-Weight reduction processing-Weight reduction stop processing-Weight reduction restart processing)
Next, the weight reduction restart process will be described. First, the control unit 16i of the interlock repeater 16 that has received the seat plate switch-off signal from the cord reel 34 can surely evacuate the person who is caught from the shutter curtain 12 in the same manner as the weight drop restart process of the receiver connection state process. After a predetermined time has elapsed, a control signal is output to the automatic closing device 14, and the automatic closing device 14 releases the brake of the opening / closing machine 13 and resumes the weight drop of the shutter curtain 12.

  Next, the control unit 16i of the interlock repeater 16 restarts the weight reduction of the shutter curtain 12, and then connects the interlock repeater 16 based on the current values of the signal lines 51 acquired from the two first terminals 16a. The previous resistance value is specified, and the connection destination state is specified based on the specified resistance value while referring to the information specifying the connection destination state stored in the connection destination state table 16j. Here, for example, when an obstacle is detected by the seat plate switch 31 and the resistance value of the connection destination of the interlock repeater 16 changes (specifically, the resistance value of the connection destination of the interlock repeater 16 = 100Ω). When the seat plate switch-on signal is output from the cord reel 34 to the interlock repeater 16, and the connection destination state = obstacle detection state is specified, the control unit 16i In order to stop the descent of the curtain 12, the descent stop process is started again. Thereafter, as described above, the dead weight descent stop process and the dead weight descent restart process are repeated according to the output of the seat plate switch 31.

(Processing-Cord reel connection status processing-Electric descent processing)
Next, electric descent processing (obstacle detection processing, harm prevention processing) will be described. Based on the current value of the signal line 51 obtained from the two first terminals 16a, the control unit 16i of the interlocking relay 16 outputs an activation signal to the switch 13 to electrically lower the shutter curtain 12. While specifying the resistance value of the connection destination of the interlock repeater 16 and referring to the information specifying the status of the connection destination stored in the connection destination state table 16j, based on the specified resistance value, the status of the connection destination Is identified. Here, for example, when an obstacle is detected by the seat plate switch 31 and the resistance value of the connection destination of the interlock repeater 16 changes (specifically, the resistance value of the connection destination of the interlock repeater 16 = 100Ω). When the seat plate switch-on signal is output from the cord reel 34 to the interlock repeater 16, and the connection destination state = obstacle detection state is identified, the control unit 16i determines the lower limit. The shutter curtain 12 is controlled based on the detection state of the detection limit switch. This control can be performed similarly to the electric descent process in the receiver connection state process.

[Embodiment 2]
Next, a shutter obstacle detection system according to Embodiment 2 will be described. In this second embodiment, the control means determines whether the wired relay means or the second communication means is connected, and based on the determination result and the resistance value of the connection destination, the state of the connection destination is determined. It is a specific form. However, the configuration and processing of the second embodiment are substantially the same as the configuration and processing of the first embodiment unless otherwise specified, and the same configuration and processing as those of the first embodiment are as necessary. The same reference numerals and / or names as those used in the first embodiment are attached as necessary, and the description thereof is omitted.

(Constitution)
First, the configuration of the shutter obstacle detection system 30 according to the second embodiment will be described. The shutter obstacle detection system 30 according to the second embodiment is configured in the same manner as the shutter obstacle detection system 30 according to the first embodiment. However, with respect to the configuration of the connection destination state table 16j of the storage unit 16g in the interlock repeater 16 and the switching of the resistance value of the connection destination, the following measures are taken.

(Configuration-connection destination status table)
FIG. 14 is a diagram illustrating a configuration example of the connection destination state table 16j according to the second embodiment. As illustrated in FIG. 14, the connection destination state table 16 j correlates the item “connection destination”, the item “resistance value setting range”, the item “connection destination state”, and information corresponding to each item. Configured. Here, the information corresponding to the item “connection destination” is information for specifying the connection destination, and corresponds to, for example, “receiver connection state”. The information corresponding to the item “resistance value setting range” and the item “connection destination state” is the same as the information stored corresponding to the same item name in the connection destination state table 16 j of FIG. The description is omitted.

(Configuration-Switching resistance value of connection destination)
Regarding the switching of the resistance value of the connection destination, in Embodiment 2, the interlock repeater 16 determines its connection destination (distinguishes the receiver connection state and the cord reel connection state), The state of the connection destination is determined based on the resistance value of the connection destination of the one terminal 16a. Here, in order to distinguish between the receiver connection state and the cord reel connection state, the interlock repeater 16 determines the battery consumption state and the disconnection state separately.

  In the second embodiment, the resistance value of the connection destination in the receiver connection state and the resistance value of the connection destination in the cord reel connection state in each of the plurality of connection destination states are the same as each of the plurality of connection destination states. The associated resistance value setting ranges, which are set separately for the receiver 33 and the cord reel 34, respectively (specifically, stored in the connection destination state table 16j). It is set to a resistance value included in the setting range included in the information specifying the resistance range setting range of each connection destination.

(processing)
Next, processing executed in the shutter obstacle detection system 30 configured as described above will be described. However, since this process can be performed basically in the same manner as in the first embodiment, detailed description thereof is omitted. However, unlike the first embodiment, the control unit 16i of the interlocking relay 16 determines the state of the connection destination of itself (for example, after the shutter curtain 12 is lowered by its own weight or electrically lowered) (When monitoring the output from 31), the self connection destination is determined based on the current value of the power line 53 acquired from the two third terminals 16c. That is, when the value of the current flowing through the power line 53 is equal to or greater than a predetermined value, it is determined that the self connection destination = the signal line 51 and the receiver 33 (the connection state = the receiver connection state is determined). ), When the value of the current flowing through the power line 53 is less than a predetermined value, it is determined that the self connection destination = the signal line 51, the cord reel 34, the signal line 54, and the seat plate switch 31 (connection state). = It is determined that the cord reel is connected).

  When it is determined that the receiver is in the connected state, the control unit 16i of the interlocking repeater 16 sets the “resistance value setting range” corresponding to the connection destination = receiver connected state in the connection destination state table 16j in FIG. The connection destination state is determined with reference to the “connection destination state”. For example, when the current value of the signal line 51 acquired from the two first terminals 16a = 600 kΩ, it is determined that the connection destination state = the battery consumption state.

  On the other hand, if it is determined that the cord reel is in the connected state, the control unit 16i of the interlock repeater 16 sets the “resistance value setting range corresponding to the connected destination = the cord reel connected state in the connected destination state table 16j in FIG. ”And“ the status of the connection destination ”, the status of the connection destination is determined. For example, when the current value of the signal line 51 acquired from the two first terminals 16a = 600 kΩ, it is determined that the connection destination state = disconnection state.

  In particular, the connection destination state table 16j in FIG. 14 corresponds to a resistance value setting range corresponding to a communication failure state or a battery exhaustion state that can occur only in the receiver connection state, and a disconnection state that can occur only in the cord reel connection state. When the resistance value setting range is set as an overlapping range (for example, in FIG. 14, the resistance value setting range corresponding to the battery consumption state and the resistance value setting range corresponding to the disconnection state are Even if both include the range of 500 kΩ or more), by distinguishing between the receiver connection state and the cord reel connection state, these communication failure state or battery consumption state and disconnection state The determination can be made by distinguishing from each other. For this reason, for example, a display lamp for performing notification in the case of a communication failure state or a battery exhaustion state and a display lamp for performing notification in the case of a disconnection state are separately provided in the interlock repeater 16 so that they are lit. May be.

[III] Modifications to Embodiments While the embodiments of the present invention have been described above, specific configurations and means of the present invention are within the scope of the technical idea of each invention described in the claims. Any modification and improvement can be made. Hereinafter, such a modification will be described.

(About problems to be solved and effects of the invention)
First, the problems to be solved by the invention and the effects of the invention are not limited to the above-described contents, and the present invention solves the problems not described above or has the effects not described above. There are also cases where only some of the described problems are solved or only some of the described effects are achieved. For example, even if it may be difficult to provide communication compatibility compared to the conventional system, if the means of the present invention is different from the means of the conventional system, the problem of the present application is solved. Yes.

(Shutter curtain lowering control)
For the lowering control of the shutter curtain 12, control different from the above may be employed. For example, in the first and second embodiments, when the electric descent is stopped because the seat plate switch is turned on at the time of the electric descent, the electric descent is automatically restarted even if the seat plate switch is turned off. Although not done, the electric descent may be automatically resumed. For example, if the seating switch is turned on during the electric descent, the electric descent is stopped and the touch-up operation is performed. Can be resumed automatically.

(Use of obstacle detection results)
In the first and second embodiments, the shutter lowering control is performed based on the detection result by the shutter obstacle detection system 30, but the detection result may be used for other purposes. For example, when the shutter device is for preventing a person from entering the security zone and is a lightweight shutter device, the shutter obstacle detection system 30 is less likely to cause harm to the obstacle. Even if an obstacle is detected by the above, the shutter curtain 12 may not be stopped and the transfer to the security system may be performed.

(About frequency band selection)
In the receiver connection state in the first and second embodiments, a frequency band other than the frequency bands exemplified above may be selected for the first frequency band and the second frequency band. For example, when transmitting an obstacle detection state signal from the transmitter 32 to the receiver 33, if it is not necessary to perform continuous transmission, a frequency band in which continuous transmission cannot be performed (after performing transmission for a certain period of time, The first frequency band may be selected as the first frequency band). Further, when there is no possibility that the signals of the shutter obstacle detection system 30 provided in each of the plurality of shutter devices 10 may interfere with each other as in the case where the shutter device 10 is installed alone. The carrier sense at the time of signal transmission from the receiver 33 to the transmitter 32 may be omitted, and a frequency band for which carrier sense is not obligated may be selected as the first frequency band. In the above-described embodiment, the first frequency band and the second frequency band are different from each other. However, they may be the same frequency.

(Receiver and transmitter, and number of frequency bands)
In the receiver connection state in the first and second embodiments, the transmitter 32 is provided with the first receiver 32f and the first transmitter 32e, and the receiver 33 is provided with the second receiver 33f and the second transmitter 33g. By providing communication using the first frequency band and the second frequency band via each receiving unit and each transmitting unit, communication in 2 systems × 2 frequency bands is performed. More than one communication system may be provided, or more than two frequency bands may be used. For example, as a system for transmitting a signal from the receiver 33 to the transmitter 32, a system for transmitting an obstacle detection state signal and a system for transmitting battery consumption may be provided separately as dedicated systems, which are different from each other. You may transmit in a frequency band. Further, when only one-way communication is performed, the first receiving unit 32f of the transmitter 32 and the second transmitting unit 33g of the receiver 33 may be omitted.

(About identification of closing action)
In the receiver connection state in the first and second embodiments, the condition for changing the reception interval of the first reception unit 32f is that the vibration detection signal is output from the vibration sensor 32a, and the first transmission unit 32e The condition for starting the continuous transmission is that the reception of the start-on signal is specified by the control unit 32j. However, these conditions may be mutually changed, or one of them may be omitted. For example, when a vibration detection signal is output from the vibration sensor 32a, the first transmission unit 32e may start continuous transmission. In other words, the output state of the vibration detection signal from the vibration sensor 32a and the reception state of the start-on signal are arbitrarily combined as an AND condition or an OR condition to change the reception interval of the first reception unit 32f, You may start the continuous transmission of the transmission part 32e.

(About changing the reception status of the transmitter 32)
In the receiver connection state in the first and second embodiments, when vibration is detected by the vibration sensor 32a, the reception state of the first receiver 32f of the transmitter 32 is changed from intermittent reception to interrupt reception. Although changed, other methods may be adopted. For example, when periodic notification is not necessary, when the vibration sensor 32a detects vibration by reducing the power consumption of the battery in the transmitter 32 by completely suspending the first receiver 32f in normal times. The first receiving unit 32f may be activated. Alternatively, the first reception unit 32f may be intermittently received during normal times, and the intermittent reception interval of the first reception unit 32f may be shortened when vibration is detected by the vibration sensor 32a. Thus, the concept of “shortening the intermittent reception interval” includes changing the reception state of the first reception unit 32f from intermittent reception to interrupt reception as in the above embodiment.
In the first and second embodiments, the reception state of the first receiving unit 32f is changed only when the output from the vibration sensor 32a continues for a predetermined time. When there is no need to consider the possibility of erroneous detection, the reception state may be changed immediately when there is an output from the vibration sensor 32a.

(About the internal resistance table)
In the first embodiment, among the information specifying the resistance value setting range stored in the connection destination table of the interlock repeater 16, the connection destination state = the resistance value setting range corresponding to the battery consumption or the disconnection state. Although it has been described that the information to be specified and the information to specify the setting range of the resistance value corresponding to the communication destination state = the communication failure state are set to different setting ranges, the present invention is not limited to this, for example, Information specifying the setting range of the resistance value corresponding to the state of the connection destination may be set in the same setting range. As a result, the set number of resistance value setting ranges can be suppressed.

(Appendix)
In order to solve the above-described problems and achieve the object, the shutter obstacle detection system according to appendix 1 is a shutter obstacle detection system that detects an obstacle with respect to a shutter curtain that opens and closes an opening. An obstacle sensor that detects that an obstacle that obstructs the closing operation of the curtain is present in the opening, and a control unit that performs opening / closing control of the shutter curtain based on an obstacle detection state by the obstacle sensor; And a means for outputting a signal indicating a detection state of the obstacle sensor to the control means, a wired relay means wired to the obstacle sensor and the control means, and detection of the obstacle sensor A second communication unit that is wirelessly connected to the first communication unit that transmits a signal indicating the state and is wired to the control unit; Any one of them can be selectively connected to the control means, and each of the wired relay means and the second communication means changes a resistance value of a connection destination including itself as a connection destination to the control means. Accordingly, a signal indicating the detection state of the obstacle sensor is output to the control means, and the control means is responsive to whether the wired relay means or the second communication means is included in its connection destination. First, the detection state of the obstacle sensor is specified based on the resistance value of the connection destination.

  Further, the shutter obstacle detection system according to appendix 2 is the shutter obstacle detection system according to appendix 1, wherein the control means includes each of a plurality of detection states that can be taken by the obstacle sensor, and a resistance value. Setting ranges that are set in common to the wired relay unit and the second communication unit are set in association with each other, and each of the wired relay unit and the second communication unit Changing the resistance value of the connection destination to a resistance value included in the setting range corresponding to the detection state according to each of a plurality of detection states that the obstacle sensor can take. A signal indicating the detection state of the obstacle sensor is output to the control unit, the control unit specifies the resistance value of the connection destination, and the detection state of the obstacle sensor is set to the set range including the specified resistance value. Identifying a detection state of the obstacle sensor response.

  The shutter obstacle detection system according to appendix 3 is the shutter obstacle detection system according to appendix 2, wherein the wired relay unit and the obstacle sensor or the obstacle sensor among the resistance value setting ranges set in the control unit A resistance value setting range when a signal line connecting the control means is disconnected, and a resistance value setting range when a predetermined state relating to a communication failure with the first communication means in the second communication means occurs. The same setting range is used.

(Additional effects)
According to the shutter obstacle detection system according to attachment 1, the control means is based on the resistance value of the connection destination regardless of whether the wired relay means or the second communication means is included in its connection destination. Since the detection state of the obstacle sensor is specified, a common control means can be used regardless of whether the obstacle detection system is wired or wireless. Therefore, the wired obstacle detection system is used. And wireless obstacle detection system can be enhanced. Therefore, it is not necessary to prepare different control means for the wired type and the wireless type as in the prior art, and the manufacturing cost of the obstacle detection system can be reduced. In addition, since the shutter device is actually installed, either the wired relay means or the second communication means can be selected and connected to the common control means according to the radio wave environment around the shutter device. It becomes possible to reduce the trouble of mounting the object detection system.

  According to the shutter obstacle detection system according to attachment 2, each of the plurality of detection states that the obstacle sensor can take and the resistance set in common for the wired relay unit and the second communication unit are included in the control unit. Since the setting range of the values is set in association with each other, the control means can determine the resistance of the connection destination regardless of whether the wired relay means or the second communication means is included in its connection destination. By specifying the detection state corresponding to the value, the detection state of the obstacle sensor can be specified. Therefore, the resistance value of the connection destination including the wired relay means and the resistance value of the connection destination including the second communication means are set in advance to resistance values that match the common resistance value setting range. It is possible to construct an obstacle detection system simply by selecting either the wire relay means or the second communication means according to the radio wave environment around the shutter device and connecting to the common control means.

  According to the shutter obstacle detection system according to attachment 3, the setting range of the resistance value when the signal line connecting the wired relay means and the obstacle sensor or the control means is disconnected, and the first communication in the second communication means Since the setting range of the resistance value when a predetermined state related to a communication failure with the means occurs is set to the same setting range, signal line disconnection, which is a failure peculiar to wired obstacle detection systems, and wireless It is possible to specify the communication failure, which is a failure peculiar to the obstacle detection system of the type, in the control means by the same setting range.

DESCRIPTION OF SYMBOLS 1 Opening part 2 Guide rail 10,100 Shutter apparatus 11 Shutter accommodating part 12,101 Shutter curtain 13,102 Opening / closing machine 14,103 Automatic closing apparatus 15,104 Manual closing apparatus 16,105 Interlocking repeater 16a, 31a, 32b, 33a , 34a First terminal 16b, 33b, 34b Second terminal 16c, 33c Third terminal 16d Input unit 16e Output unit 16f, 32c, 33d Display unit 16g, 32h, 33i Storage unit 16h, 32i, 33j Power supply unit 16i, 32j, 33k Control unit 16j Connection destination state table 17, 106 Seat plate 20, 110 Fire alarm system 21, 111 Fire detector 22, 112 Disaster prevention panel 30 Shutter obstacle detection system 31, 121 Seat plate switch 32 Transmitter 32a Vibration sensor 32d, 33e registration Switch 32e First transmitter 32f First receiver 32g, 33h Antenna 33 Receiver 33f Second receiver 33g Second transmitter 33l Internal resistance table 34, 123 Code reels 51, 52, 54, 122 Signal line 53 Power line 120 Fault Object detection device

Claims (3)

A shutter obstacle detection system that detects an obstacle to a shutter curtain that opens and closes an opening,
An obstacle sensor that detects that an obstacle that obstructs the closing operation of the shutter curtain exists in the opening; and
Control means for performing opening / closing control of the shutter curtain based on an obstacle detection state by the obstacle sensor,
As a means for outputting a signal indicating the detection state of the obstacle sensor to the control means, a wired relay means wired to the obstacle sensor and the control means, and a signal indicating the detection state of the obstacle sensor The second communication means that is wirelessly connected to the first communication means for transmitting and wired to the control means, and either one of the second communication means can be selectively connected to the control means,
Each of the wired relay means and the second communication means changes a resistance value of a connection destination that is a connection destination to the control means and includes itself, thereby giving a signal indicating a detection state of the obstacle sensor to the control means Output to
The control means specifies the detection state of the obstacle sensor based on the resistance value of the connection destination regardless of whether the wired relay means or the second communication means is included in its connection destination. To
Shutter obstacle detection system. The control means includes a plurality of detection states that the obstacle sensor can take, a resistance value setting range, and a setting range that is set in common to the wired relay means and the second communication means. Are set in association with each other,
Each of the wired relay means and the second communication means includes the resistance value of the connection destination in the setting range corresponding to the detection state according to each of a plurality of detection states that the obstacle sensor can take. By changing the resistance value to be output, a signal indicating the detection state of the obstacle sensor is output to the control means,
The control means specifies the resistance value of the connection destination, and specifies the detection state of the obstacle sensor as the detection state of the obstacle sensor corresponding to the setting range including the specified resistance value.
The shutter obstacle detection system according to claim 1. Of the resistance value setting range set in the control means, the resistance value setting range when the signal line connecting the wire relay means and the obstacle sensor or the control means is disconnected, and the second communication The setting range of the resistance value when a predetermined state relating to communication failure with the first communication means in the means is set to the same setting range.
The shutter obstacle detection system according to claim 2.

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