JP7185206B2 - shutter device - Google Patents

Description

The present invention relates to a shutter device.

Japanese Unexamined Patent Application Publication No. 2002-200003 discloses a shutter device that stores the current position of the shutter curtain in a volatile memory as needed to control opening and closing operations of the shutter curtain while always recognizing the current position.

Incidentally, when the power supply to the shutter device is stopped due to a power failure or the like, the current position data in the memory disappears. Therefore, when the power supply is restored, the shutter device may not know the current position of the shutter curtain and may not be able to accurately control the opening/closing operation of the shutter curtain.

Therefore, when the power supply is restored, the user presses the "open" button on the operation unit as a restoration operation of the shutter device, thereby fully opening the shutter curtain and making the position of the shutter curtain recognizable. There is a way.

JP 2016-160622 A

However, in the above method, when the power supply is restored, the user is forced to perform a predetermined return operation of pressing "open" on the operation unit. do not have.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a shutter device with improved intuitive operability in a return operation.

One aspect of the present invention is a shutter device that opens and closes a shutter curtain, and executes a lower limit detection process for detecting a fully closed state of the shutter curtain and an upper limit detection process for detecting a fully open state of the shutter curtain. and the control unit controls the lower limit when the closing operation is performed as the opening/closing operation after the restoration of the power supply when the power supply to the shutter device is restored from the stopped state. A shutter characterized by: performing detection processing, and recognizing the position of the shutter curtain by executing the upper limit detection processing when an opening operation is performed as the opening/closing operation after the restoration of the power supply. It is a device.

An aspect of the present invention is the shutter device described above, wherein, when the opening operation is performed as the first opening/closing operation after restoration of the power supply, the control unit performs the upper limit detection process together with the opening operation. is performed, and when the closing operation is performed as the first opening/closing operation after the restoration of the power supply, the lower limit detection processing is performed together with the closing operation, thereby recognizing the position of the shutter curtain.

An aspect of the present invention is the shutter device described above, which includes a motor that drives the shutter curtain to open and close, and the lower limit detection process detects the fully closed state based on a motor load that indicates the load applied to the motor. It is a process to

An aspect of the present invention is the above-described shutter device, wherein the controller controls, during the lower limit detection process, the moving distance of the shutter curtain when closing the shutter curtain is not greater than or equal to a first distance. In this case, after the shutter curtain is opened by the first distance or more, the shutter curtain is closed again to perform the lower limit detection process.

One aspect of the present invention is the shutter device described above, which includes a load detection unit that detects the motor load based on a position pulse according to the rotation of the motor, and the first distance is the fully closed state. is the distance at which a sufficient amount of the position pulse can be obtained at the load detector to detect .

An aspect of the present invention is the shutter device described above, wherein the control unit includes a lower limit detection unit that detects an overload state of the motor based on the motor load during the closing operation of the shutter curtain; a drive control unit that opens and closes the shutter curtain by controlling driving of a motor, wherein the drive control unit detects an overload state of the motor by the lower limit detection unit in the lower limit detection process. In this case, the closing operation of the shutter curtain is stopped, and the shutter curtain is opened by a second distance from the stop position of the stopped shutter curtain, thereby controlling the shutter curtain to the lower limit position.

According to one aspect of the present invention, the shutter device described above includes a recognition unit that recognizes the position of the shutter curtain by the lower limit detection process, and the recognition unit detects the position of the shutter curtain by executing the lower limit detection process. Recognize that the position is the stop position or the lower limit position.

As described above, according to the present invention, it is possible to improve the intuitive operability in the return operation.

It is a figure showing an example of a schematic structure of shutter system A provided with a shutter device concerning one embodiment of the present invention. 1 is a schematic configuration diagram of a shutter control device 9 according to an embodiment of the present invention; FIG. 4 is a functional block diagram of a control section 12 for executing recovery processing of the shutter control device 9 according to one embodiment of the present invention; FIG. FIG. 4 is a flowchart of return processing according to one embodiment of the present invention; It is a figure explaining the return processing which concerns on one Embodiment of this invention. FIG. 4 is a flow diagram of initialization according to an embodiment of the present invention; It is a figure explaining the initial setting which concerns on one Embodiment of this invention.

A shutter device according to an embodiment of the present invention will be described below with reference to the drawings.

FIG. 1 is a diagram showing an example of a schematic configuration of a shutter system A including a shutter device according to one embodiment of the present invention.
A shutter system A shown in FIG. 1 includes a shutter device 1 and an operation unit 2 .

The shutter device 1 is an electric shutter device that opens or closes openings such as windows and doors of a building. The shutter device 1 includes a shutter curtain 3 and can open or close the opening by opening and closing the shutter curtain 3 based on an operation signal from the operation unit 2 .

The operation unit 2 is connected by wire or wirelessly to the shutter device 1 to be operated, and can communicate with the shutter device 1 mutually. The operation unit 2 is operable by a user or an operator, and includes means for inputting an operation signal to the shutter device 1. For example, the operation unit 2 is a remote control device.

In this embodiment, the operation unit 2 is provided with an open switch SWo, a close switch SWc, and a stop switch SWt. Therefore, by pressing these switches, the user can instruct the shutter device 1 to open and close the shutter curtain 3 and stop the opening and closing operation.

Specifically, when any switch is pressed by the user, the operation unit 2 outputs an operation signal corresponding to the switch to the shutter device 1 .
For example, when the open switch SWo is operated, the operation unit 2 transmits to the shutter device 1 a first operation signal instructing the opening operation of the shutter curtain 3 . Further, when the close switch SWc is operated, the operation unit 2 transmits a second operation signal instructing the closing operation of the shutter curtain 3 to the shutter device 1 . Furthermore, when the stop switch SWt is operated, the operation unit 2 transmits a stop signal to the shutter device 1 to instruct the shutter curtain 3 to stop opening or closing the shutter curtain 3 .

Next, an example of a schematic configuration of the shutter device 1 according to one embodiment of the present invention will be described.

As shown in FIG. 1, the shutter device 1 includes a shutter curtain 3, guide rails 4a and 4b, and a shutter box 5. As shown in FIG.

The shutter curtain 3 has a plurality of elongated slats 3a connected in the vertical direction and a baseboard portion 3b provided at the lowest end.

The baseboard part 3b is an elongated member having a rectangular cross section connected to the lowermost slat 3a.
The baseboard portion 3b is formed so as to protrude so as to come into contact with the magnet (not shown) or the shutter box 5 when the shutter curtain 3 is in a fully open state (opening of the opening). That is, when the shutter curtain 3 is in the fully open state, the baseboard portion 3b comes into contact with the magnet (not shown) or the shutter box 5. As shown in FIG. On the other hand, when the shutter curtain 3 is in a fully closed state (opening is closed), the baseboard portion 3b contacts the lower frame of the frame of the shutter device 1 and the floor surface.
The above-mentioned magsa is a parting member for the opening of the shutter device 1 formed by raising the shutter curtain 3 , and may be provided below the shutter box 5 .

The guide rail 4a and the guide rail 4b are provided as a pair at both ends of the shutter curtain 3 in the width direction, and stand vertically with respect to the bottom surface. The guide rail 4a and the guide rail 4b regulate lateral displacement of each slat 3a constituting the shutter curtain 3. As shown in FIG.

The shutter box 5 is provided above the shutter device 1 . The shutter box 5 rewinds the shutter curtain 3 (when the shutter curtain 3 is closed) or winds it (when the shutter curtain 3 is opened).

An example of the schematic configuration of the shutter box 5 according to one embodiment of the present invention will be described below. As shown in FIG. 1, the shutter box 5 comprises a shaft 6, a motor 7, an output section 8 and a shutter controller 9. As shown in FIG.

Shaft 6 is connected to the upper end of shutter curtain 3 and motor 7 . The shaft 6 is rotationally driven in forward and reverse directions by a motor 7 . As the shaft 6 rotates, the shutter curtain 3 is rewound or wound. The shutter curtain 3 wound around the shaft 6 is accommodated in the shutter box 5. - 特許庁

The motor 7 is a driving source for opening and closing the shutter curtain 3 by rotationally driving the shaft 6, and is composed of, for example, a DC motor. The motor 7 rotates forward, reverse, or stops rotating based on a drive signal from the shutter control device 9 .

The output unit 8 has a function of outputting the drive status of the motor 7 . The output unit 8 is an encoder built into the motor 7, for example. The output unit 8 outputs position pulses according to the rotation of the motor 7 to the shutter control device 9 . For example, the output unit 8 outputs one position pulse to the shutter control device 9 when the motor 7 rotates once. Note that the output unit 8 is not limited to an encoder, and can be arbitrarily selected as long as it has a configuration capable of grasping the rotation amount of the winding shaft or the motor 7, such as measuring the rotation angle amount of the motor 7, for example.

FIG. 2 is a schematic configuration diagram of the shutter control device 9 according to one embodiment of the present invention.
As shown in FIG. 2 , the shutter control device 9 has a communication section 10 , a drive section 11 and a control section 12 .

The communication unit 10 transmits and receives information by communicating with the operation unit 2 . The communication method of the communication unit 10 is not particularly limited, but in this embodiment, a wireless communication method such as the short-range wireless communication standard RF4CE (Radio Frequency for Consumer Electronics) or Bluetooth (registered trademark) is used.

The drive unit 11 drives or stops the motor 7 by generating a drive signal according to the command from the control unit 12 and outputting it to the motor 7 .

The control unit 12 is composed of, for example, a microprocessor such as a CPU or MPU, a microcontroller such as an MCU, a storage device, and the like, and controls the driving of the motor 7 according to the operation of the switches of the operation unit 2 .

The control unit 12 controls the rotation of the motor 7 based on the operation signal from the operation unit 2 , thereby controlling the opening/closing operation or stopping operation of the shutter curtain 3 .

Specifically, when the control unit 12 receives a first operation signal corresponding to the open switch SWo from the operation unit 2 via the communication unit 10 , the control unit 12 winds the shutter curtain 3 around the shaft 6 . It outputs to the drive unit 11 a command to open the door (hereinafter referred to as "open command"). As a result, the drive unit 11 rotates the motor 7 forward to open the shutter curtain 3 .

Further, when the control unit 12 receives a second operation signal, which is an operation signal corresponding to the close switch SWc, from the operation unit 2 via the communication unit 10, the control unit 12 unwinds the shutter curtain 3 from the shaft 6. A command for closing operation (hereinafter referred to as a “close command”) is output to the drive unit 11 . As a result, the drive unit 11 rotates the motor 7 in reverse to close the shutter curtain 3 .

When the control unit 12 receives a stop signal corresponding to the stop switch SWt from the operation unit 2, the control unit 12 issues a command to stop the operation of the shutter curtain 3 (hereinafter referred to as a “stop command”) to the drive unit 11. Output. As a result, the drive unit 11 stops the rotation of the motor 7 to stop the opening/closing operation of the shutter curtain 3 .

Here, the control section 12 always recognizes the position P of the shutter curtain 3 . Specifically, the control unit 12 stores the current position (hereinafter referred to as “recognized position”) P of the shutter curtain 3 in a volatile memory within the device as needed, while opening and closing the shutter curtain 3. to control.

For example, when the control unit 12 opens the shutter curtain 3 to make it fully open, the recognized position P of the shutter curtain 3 reaches the upper limit position Pu while the shutter curtain 3 is being opened. Determine whether or not When the control unit 12 determines that the position P of the shutter curtain 3 has reached the upper limit position Pu, the control unit 12 determines that the shutter curtain 3 is fully open, and stops opening the shutter curtain 3 .

Further, when closing the shutter curtain 3 to bring the shutter curtain 3 into the fully closed state, the control unit 12 causes the recognized position P of the shutter curtain 3 to reach the lower limit position Pl while the shutter curtain 3 is being closed. determine whether or not When the controller 12 determines that the recognized position P of the shutter curtain 3 has reached the lower limit position Pl, it determines that the shutter curtain 3 is in the fully closed state, and stops the closing operation of the shutter curtain 3. do.

Here, for example, the recognition position P of the shutter curtain 3 is the position of the lowest end of the shutter curtain 3 (for example, the baseboard portion 3b) and is the count value N of the position pulse output from the output section 8. . That is, the control unit 12 counts the position pulses and recognizes the current position of the shutter curtain 3 from the count value N.

For example, as an initial setting, the control unit 12 presets the count value N when the shutter curtain 3 is in the fully open state as the threshold value Nuth. As an initial setting, the control unit 12 presets the count value N when the fully open shutter curtain 3 is lowered to the fully closed state as the threshold value Nlth, using the upper limit position Pu as a reference position. Then, the control unit 12 controls the shutter curtain to the fully open state or the fully closed state using the threshold value Nuth and the threshold value Nlth obtained by the initial setting. With the upper limit position Pu as a reference position, the count value N when the shutter curtain 3 in the fully open state is lowered to the fully closed state indicates the distance between the upper limit position Pu and the lower limit position Pl.

Specifically, when the shutter curtain 3 is closed, the control unit 12 updates the count value N by adding the number of position pulses (number of pulses) from the current count value N. go. Then, when the count value N reaches the threshold value Nlth, the control unit 12 determines that the recognized position P of the shutter curtain 3 is the lower limit position Pl, that is, the shutter curtain 3 is in the fully closed state. On the other hand, the control unit 12 updates the count value N by subtracting the number of position pulses (number of pulses) from the current count value N during the opening operation of the shutter curtain 3 . Then, when the count value N reaches the threshold value Nuth, the control unit 12 determines that the recognized position P of the shutter curtain 3 is the upper limit position, that is, the shutter curtain 3 is in the fully open state.

However, when the power supply to the shutter device 1 is stopped (that is, when the power is cut off) due to the power plug of the shutter device 1 being disconnected from the outlet or a power failure, etc., the The recognition position P of the shutter curtain 3 disappears. Therefore, the shutter device 1 cannot recognize the position of the shutter curtain 3 when the power supply to the shutter device is restored. Therefore, when the power supply to the shutter device 1 is restored after the power supply to the shutter device 1 is stopped, the shutter device 1 performs processing for recognizing the recognition position P of the shutter curtain 3 (hereinafter referred to as “return processing”). I do.
The return processing includes the upper limit detection processing of opening the shutter curtain 3 and detecting the fully open state of the shutter curtain 3 (for example, the upper limit position Pu), and the closing operation of the shutter curtain 3 and the fully closed state of the shutter curtain ( For example, the position of the shutter curtain is recognized by selectively executing a lower limit detection process for detecting the lower limit position Pl or a depression position (to be described later).

Functional units of the control unit 12 for executing recovery processing of the shutter control device 9 according to one embodiment of the present invention will be described below with reference to FIG. FIG. 3 is a functional block diagram of the control section 12 for executing recovery processing of the shutter control device 9 according to one embodiment of the present invention.

Functional units of the control unit 12 according to one embodiment of the present invention will be described below.

The control unit 12 includes a storage unit 13 , a drive control unit 14 , a load detection unit 15 and a processing unit 16 .

The recognition position P is stored in the storage unit 13 by the processing unit 16 . For example, storage unit 13 is a volatile memory.

The drive control unit 14 controls opening and closing operations of the shutter curtain 3 .

For example, when power supply to the shutter device 1 is restored from a stopped state, the drive control unit 14 outputs an open command to the drive unit 11 when receiving an operation signal from the operation unit 2 via the communication unit 10 . When the first operation signal is acquired, the opening operation of the shutter curtain 3 is executed. Further, when the power supply to the shutter device 1 is restored from the stopped state, the drive control unit 14 outputs a close command to the drive unit 11 to close the shutter curtain 3 when the second operation signal is acquired. Execute the opening operation.
The drive control unit 14 outputs a stop command to the drive unit 11 when the upper limit detection process or the lower limit detection process ends, and stops the opening/closing operation of the shutter curtain 3 .

The load detector 15 detects a load applied to the motor 7 (hereinafter referred to as "motor load"). The load detection unit 15 according to this embodiment includes a counter 151 and a load measurement unit 152 .

The counter 151 starts counting the number of position pulses when the return process is executed.

The load measuring section 152 measures the motor load based on the position pulse output from the output section 8 . Specifically, for example, the load measurement unit 152 measures the pulse width of the position pulse output from the output unit 8 as the motor load for each position pulse (for each count value N of the counter 151).

Here, the pulse width of the position pulse increases as the rotation speed of the motor 7 decreases, and decreases as the rotation speed of the motor 7 increases. That is, when the shutter curtain 3 reaches the upper limit position Pu and the baseboard 3b comes into contact with the mulch or the shutter box 5, the motor 7 is overloaded. As a result, the rotation speed of the motor 7 becomes slower and the pulse width of the position pulse becomes larger.
When the shutter curtain 3 reaches the lower limit position Pl and the base board 3b comes into contact with the floor or the lower frame, and the closing operation continues, the base board 3b presses against the floor or the lower frame. be in a state of As a result, a load is applied to the motor 7 and the motor 7 becomes overloaded. As a result, the rotation speed of the motor 7 becomes slower and the pulse width of the position pulse becomes larger.
Therefore, the load measurement unit 152 calculates the pulse width of the motor 7 as the motor load by measuring the pulse width of each position pulse (every count value N). The load measurement unit 152 associates the count value N with the motor load and outputs the result to the processing unit 16 .

The processing unit 16 includes a selection unit 161 , an upper limit detection unit 162 , a lower limit detection unit 163 , a distance determination unit 164 and a recognition unit 165 .

When the power supply to the shutter device 1 is restored from the stopped state and the closing operation is performed as the opening/closing operation after the restoration of the power supply, the selection unit 161 selects the lower limit detection process as the process used for the restoration process. select. On the other hand, when the power supply to the shutter device 1 is restored from the stopped state and the opening operation is performed as the opening/closing operation after the restoration of the power supply, the selection unit 161 detects the upper limit as the processing used for the restoration processing. Choose an action.
However, the present invention is not limited to this, and for example, when the power supply to the shutter device 1 is stopped and then the power supply is restored, the selection unit 161 obtains from the operation unit 2 via the communication unit 10 Either the upper limit detection process or the lower limit detection process may be selected as the process used for the return process based on the operation signal. For example, after the power supply to the shutter device 1 is restored, the selection unit 161 selects , select the upper limit detection process. On the other hand, after the power supply to the shutter device 1 is restored, the selection unit 161 selects , to select the lower limit detection process. Note that when the selection unit 161 receives the stop signal as the first operation signal after the power supply to the shutter device 1 is restored, the selection unit 161 waits for reception of the first operation signal and the second operation signal. to maintain

The upper limit detection unit 162 executes the upper limit detection process based on the motor load output from the load detection unit 15 when the upper limit detection process is selected by the selection unit 161 and the opening operation is performed. For example, the upper limit detector 162 determines whether the motor 7 is overloaded based on the motor load output from the load detector 15 . For example, in the upper limit detection processing mode, the upper limit detection unit 162 determines that the motor 7 is overloaded when the motor load or the rate of change of the motor load exceeds a threshold. The upper limit detector 162 determines that the shutter curtain 3 is fully open when the motor 7 is overloaded in the upper limit detection process. For example, the upper limit detector 162 detects the upper limit position Pu by detecting an overloaded state of the motor 7 . When the upper limit detector 162 detects an overload state of the motor 7 , the upper limit detector 162 outputs the detection result to the drive controller 14 . As a result, the opening operation of the motor 7 is stopped.

The lower limit detection unit 163 executes the lower limit detection process based on the motor load output from the load detection unit 15 when the lower limit detection process is selected by the selection unit 161 and the closing operation is performed . For example, the lower limit detector 163 determines whether the motor 7 is overloaded based on the motor load output from the load detector 15 . For example, the lower limit detector 163 determines that the motor 7 is overloaded when the motor load or the rate of change of the motor load exceeds the threshold. The lower limit detector 163 determines that the shutter curtain 3 is fully closed when the motor 7 is overloaded in the lower limit detection process. For example, the lower limit detector 163 detects the lower limit position Pl by detecting an overloaded state of the motor 7 . When the lower limit detector 163 detects an overload state of the motor 7 , the lower limit detector 163 outputs the detection result to the drive controller 14 . As a result, the opening operation of the motor 7 is stopped.

Here, as described above, the lower limit detection unit 163 detects the overload state of the motor 7 based on the motor load. At the position where the shutter curtain 3 is further closed from the lower limit position Pl and the shutter curtain 3 pushes the floor surface or the lower frame (hereinafter referred to as the "pushed position"), the motor 7 detects overload conditions. However, the distance ΔH (for example, the number of position pulses counted) between the depression position and the lower limit position Pl can be obtained in advance by experiments or the like. Therefore, the lower limit detector 163 can obtain the lower limit position Pl from the depression position using the known distance ΔH. That is, the lower limit detector 163 can detect the lower limit position Pl by detecting the pressed position.

When the shutter curtain 3 reaches the pushed-in position, the shutter curtain 3 may be bent. Therefore, when the lower limit detection unit 163 detects that the motor 7 is overloaded, the drive control unit 14 stops the closing operation of the motor 7 and also closes the shutter curtain 3 to eliminate the deflection. The opening operation may be performed from the pushed position to the lower limit position Pl. For example, the drive control unit 14 obtains in advance the number of position pulses ΔK corresponding to the distance ΔH (second distance) from the depression position to the lower limit position by experiments or the like, and reverses the motor 7 by the number of pulses ΔK. By rotating the shutter curtain 3, the shutter curtain 3 may be moved from the pushed position to the lower limit position Pl.
In the following description, the process of opening the shutter curtain 3 from the pushed position to the lower limit position Pl in order to eliminate the deflection of the shutter curtain 3 is referred to as "deflection process". Note that the pushed position corresponds to the "stop position" of the present invention.
However, when overload detection is used as the lower limit detection process, the lower limit detection unit 163 does not have the deflection or if the deflection is tolerable (for example, the deflection does not impair the function of the shutter device 1). Alternatively, the pressing position may be set to the lower limit position without executing the deflection elimination process.

As described above, the processing unit 16 of the present embodiment performs the upper limit detection process when the opening operation of the shutter curtain 3 is performed as the first opening/closing operation when the power supply to the shutter device 1 is restored from the stopped state. , and when the closing operation of the shutter curtain 3 is performed as the first opening/closing operation, lower limit detection processing is performed.

When the overload state of the motor 7 is detected in the lower limit detection processing mode, the distance determination unit 164 determines the moving distance H by which the shutter curtain 3 moves in the closing direction due to the closing operation of the shutter curtain 3 in the lower limit detection processing mode. Ask for Then, the distance determination unit 164 determines whether or not the movement distance H is equal to or greater than the predetermined distance Hth. For example, the count value of the counter 151 in the lower limit detection processing mode indicates the movement distance of the shutter curtain 3 in the lower limit detection processing mode. Therefore, for example, the distance determination unit 164 determines whether or not the count value N is equal to or greater than the count value Nth corresponding to the predetermined distance Hth. Then, if the count value N is equal to or greater than the count value Nth, the distance determination unit 164 determines that the movement distance H is equal to or greater than the predetermined distance Hth.

Here, the reason why it is determined whether or not the moving distance H is equal to or greater than the predetermined distance Hth is that if the moving distance H is less than the predetermined distance Hth, the number of motor load data is small, so the lower limit detection process is performed with sufficient accuracy. This is because it is not possible to Therefore, when the movement distance H is less than the predetermined distance Hth, the distance determination unit 164 outputs a retry signal to the drive control unit 14 to cause the drive control unit 14 to execute retry processing. On the other hand, when the movement distance is equal to or greater than the predetermined distance H, distance determination section 164 outputs the determination result to recognition section 165 without outputting a retry signal.
Here, the retry process is a process of opening the shutter curtain 3 by a predetermined distance Hth or more, and then closing the shutter curtain 3 again to execute the lower limit detection process. This predetermined distance Hth is a distance at which the load detector 15 can obtain a sufficient amount of position pulses to detect the fully closed state (for example, the lower limit position Pl or the depressed position).
Note that the predetermined distance Hth is an example of the "first distance" in the present invention.

When the fully open state of the motor 7 is detected in the upper limit detection process, the recognition unit 165 recognizes that the shutter curtain 3 is in the fully open state, and stores the fully open position (for example, the upper limit position) as the recognition position P in the storage unit 13 . Store the position Pu).

When the fully closed state of the motor 7 is detected in the lower limit detection process and the movement distance exceeds the predetermined distance Hth, the recognition unit 165 recognizes that the shutter curtain 3 is in the fully closed state, and stores the shutter curtain 3. The fully closed position (for example, the lower limit position Pl or the pushed position) is stored as the recognized position P in the section 13 . For example, when the overload of the motor 7 is detected in the lower limit detection process and the movement distance exceeds the predetermined distance H, the recognition unit 165 recognizes that the current position of the shutter curtain 3 is the pushed position. Then, the depression position is stored as the recognition position P in the storage unit 13 . However, when detecting the fully closed state of the shutter curtain 3 by a method different from the overload detection of the motor 7 as the lower limit detection process, the recognition unit 165 detects the fully closed state of the motor 7, and the shutter It recognizes that the current position of the curtain 3 is at the lower limit position Pl, and stores the lower limit position Pl as the recognized position P in the storage unit 13 .
Here, when the deflection elimination process is executed, the recognition unit 165 recognizes that the recognized position P of the shutter curtain 3 is the lower limit position Pl, and stores the lower limit position Pl as the recognized position P in the storage unit 13. do.

Next, the flow of return processing according to one embodiment of the present invention will be described with reference to FIGS. 4 and 5. FIG. FIG. 4 is a flow diagram of return processing according to one embodiment of the present invention. FIG. 5 is a diagram for explaining return processing according to an embodiment of the present invention.

For example, when the power supply to the shutter device 1 that has been stopped due to a power failure is restored (step S101), the control unit 12 determines whether or not the switch operation of the operation unit 2 has been performed (step S102). . This switch operation is an operation for opening or closing the shutter curtain 3, and is, for example, pressing an open switch SWo or a close switch SWc.

When receiving an operation signal from the operation unit 2, the control unit 12 determines whether a switch operation has been performed, and determines which of the open switch SWo and the closed switch SWc has been operated (step S103). On the other hand, when no operation signal is received from the operation unit 2, the control unit 12 determines that the switch operation has not been performed, and returns to the processing of the switch S102.

In step S102, when the first operation signal is received from the operation unit 2, the control unit 12 determines that the open switch SWo has been operated. is executed (step S105).

For example, the upper limit detector 162 determines whether the motor 7 is overloaded based on the motor load output from the load detector 15 . When determining that the motor 7 is overloaded, the upper limit detector 162 determines that the position P of the shutter curtain 3 has reached the upper limit position Pu. That is, the upper limit detector 162 detects the upper limit position Pu. Then, the recognition unit 165 recognizes that the shutter curtain 3 is fully open (step S106). That is, the recognition unit 165 recognizes that the current position of the shutter curtain 3 is the upper limit position Pu, and stores the upper limit position Pu as the recognition position P in the storage unit 13 .

As described above, when the power supply to the shutter device 1 is stopped due to a power failure or the like, and the position P of the shutter curtain 3 disappears, the shutter device 1 will not be opened by the user after the power supply is restored. An upper limit detection process is executed according to the operation of the switch SWo. As a result, the shutter device 1 can move the shutter curtain 3 in the direction desired by the user, and determine the position P of the shutter curtain 3 that has become unknown due to the stoppage of the power supply (power off).

In step S102, the control unit 12 determines that the close switch SWc has been operated when the second operation signal is received from the operation unit 2, and closes the drive control unit 14 (step S107). is performed (step S108). Therefore, in FIG. 5A, when the recognized position P of the shutter curtain 3 when the power supply is restored is P1, the shutter curtain 3 closes and approaches the lower limit position Pl. It should be noted that the counter 151 starts counting position pulses as the closing operation of the shutter curtain 3 is started in step S107.

For example, the lower limit detector 163 determines whether the motor 7 is overloaded based on the motor load output from the load detector 15 as lower limit detection processing. When the lower limit detector 163 determines that the motor 7 is overloaded, the drive controller 14 stops closing the shutter curtain 3 . Furthermore, when the lower limit detection unit 163 determines that the motor 7 is in an overloaded state, the distance determination unit 164 determines whether or not the counter value N is equal to or greater than the count value Nth (step S109).

When the distance determination unit 164 determines that the counter value N is equal to or greater than the count value Nth, the lower limit detection process (overload detection) in step S108 is enabled, and the recognition unit 165 determines that the shutter curtain 3 is in the fully closed state. (step S110). Then, the recognition unit 165 stores the lower limit position Pl as the recognition position P in the storage unit 13 .

As described above, when the power supply to the shutter device 1 is stopped due to a power failure or the like, and the position P of the shutter curtain 3 disappears, the shutter device 1 will be closed by the user after the power supply is restored. A lower limit detection process is executed according to the operation of the switch SWc. As a result, the shutter device 1 can move the shutter curtain 3 in the direction desired by the user, and determine the recognition position P of the shutter curtain 3 that has become unknown due to the stoppage of the power supply (power off).

However, in this case, the current position P of the shutter curtain 3 is not the lower limit position Pl, but the pushed position. Therefore, the shutter curtain 3 is flexed. Therefore, the drive control unit 14 executes deflection elimination processing (step S111). That is, the drive control unit 14 reversely rotates the motor 7 by the number of pulses ΔK corresponding to the distance between the depressed position and the lower limit position Pl, thereby opening the shutter curtain 3 by the corresponding distance to the lower limit position Pl. Move the shutter curtain 3.

On the other hand, in the process of step S109, when the distance determination unit 164 determines that the counter value N is less than the count value Nth, the control unit 12 (for example, the distance determination unit 164) performs the lower limit detection process of step S108. (overload detection) is disabled. That is, as shown in FIG. 5B, when the position P of the shutter curtain 3 when the power supply is restored is the position P2 which is less than the predetermined distance Hth from the pushed-in position, the motor load is measured. The amount of position pulse data (number of pulses) is not sufficient. Therefore, the control unit 12 disables the lower limit detection process (overload detection) when the counter value N is less than the count value Nth, and performs the retry process to execute the lower limit detection process when the counter value N is equal to or greater than the count value Nth. Run.

Specifically, first, the drive control unit 14 resets the count value N of the counter 151 and executes the opening operation of the shutter curtain 3 (step S112). The counter 151 starts counting position pulses when the opening operation of step S112 is started.

While continuing the opening operation of the shutter curtain 3, the drive control unit 14 determines at regular intervals whether or not the count value N is equal to or greater than the count value Nth (step S113). When the drive control unit 14 determines that the count value N is equal to or greater than the count value Nth, the drive control unit 14 stops the opening operation of the shutter curtain 3 and starts the closing operation (step S107). Then, the lower limit detection process is executed again.

Next, a method for initializing the upper limit position Pu and the lower limit position Pl of the control section 12 according to one embodiment of the present invention will be described with reference to FIGS. 6 and 7. FIG. FIG. 6 is a flow diagram of initialization according to one embodiment of the present invention. FIG. 7 is a diagram illustrating initial settings according to an embodiment of the present invention.

First, the control unit 12 determines whether or not a setting operation has been performed on the operation unit 2 . This setting operation is an operation for instructing execution of initial setting by the user. Two or more switches may be pressed simultaneously, or one or more switches may be pressed for a long time. Furthermore, when the operation unit 2 is provided with a setting switch, the setting operation may be an operation (for example, short press) on the setting switch.

When receiving a setting signal indicating that a setting operation has been performed on the operation unit 2 from the operation unit 2, the control unit 12 determines that a setting operation has been performed on the operation unit 2 (step S201). , the shutter curtain 3 is opened (step S202).

After executing the opening operation of the shutter curtain 3, the control unit 12 executes upper limit detection processing (step S203). For example, based on the motor load output from the load detection unit 15, the control unit 12 determines at regular intervals whether the motor 7 is overloaded. When the controller 12 detects the upper limit position Pu by detecting the overload state of the motor 7, the controller 12 sets the current count value N to the upper limit position Pu.

Next, the control unit 12 starts the closing operation of the shutter curtain 3 (step S205), and executes the lower limit detection process (step S205). For example, while the shutter curtain 3 is being closed, the control unit 12 periodically determines whether the motor 7 is overloaded based on the motor load output from the load detection unit 15 . It should be noted that the control unit 12 starts counting position pulses with the upper limit position Pu as the reference position in accordance with execution of the closing operation in step S204.

When the control unit 12 determines that the motor 7 is overloaded, it sets a value obtained by subtracting the number of pulses ΔK from the current count value N as the lower limit position Pl. After that, the control unit 12 performs deflection elimination processing to move the shutter curtain 3 to the lower limit position Pl (step S206).

Although the embodiment of the present invention has been described in detail with reference to the drawings, the specific configuration is not limited to this embodiment, and design and the like are included within the scope of the gist of the present invention.

(Modification 1) In the above-described embodiment, the shutter curtain 3 may be configured with any member or structure. For example, the shutter curtain 3 may be formed of a plurality of slats 3a, may be formed of a sheet, or may be partially formed of a plurality of slats 3a.

(Modification 2) In the above-described embodiment, the load detection unit 15 uses the pulse width of the position pulse as the motor load. However, the present invention is not limited to this. It doesn't have to be. For example, the load detector 15 may detect the motor load by detecting the torque of the motor 7 using a known technique.

(Modification 3) In the above embodiment, the controller 12 uses overload detection of the motor 7 as the upper limit detection process and the lower limit detection process, but the present invention is not limited to this. That is, the control unit 12 may execute the upper limit detection process and the lower limit detection process without using the motor load. For example, the shutter device 1 may include an upper limit position detection mechanism such as a sensor or switch that detects that the lowest end (for example, the baseboard portion 3b) of the shutter curtain 3 has reached the upper limit position Pu.
That is, the control unit 12 may execute the upper limit detection process using the upper limit position detection mechanism. In this case, the control unit 12 detects the upper limit position Pu when the upper limit position detection mechanism detects that the lowest end of the shutter curtain 3 has reached the upper limit position Pu.
Further, the shutter device 1 may include a lower limit position detection mechanism such as a sensor or switch that detects that the lowermost end (for example, the baseboard portion 3b) of the shutter curtain 3 has reached the lower limit position Pl. That is, the control unit 12 may execute the lower limit detection process using the lower limit position detection mechanism. In this case, the control unit 12 detects the lower limit position Pl when the lower limit position detection mechanism detects that the lowest end of the shutter curtain 3 has reached the lower limit position Pl.
Note that the control unit 12 uses overload detection of the motor 7 for one of the upper limit detection process and the lower limit detection process, and uses a position detection mechanism such as a sensor or switch (upper limit position detection mechanism or lower limit position detection mechanism) for the other. ) may be used.

(Modification 4) In the above-described embodiment, the control unit 12 executes the deflection elimination process. may Further, the control unit 12 does not need to execute the deflection elimination process if the overload detection of the motor 7 is not used as the lower limit detection process.

(Modification 5)
In the above-described embodiment, the upper limit detector 162 detects the overload state of the motor 7 based on the motor load, and when the overload detection is used for the upper limit detection process, the base board 3b abuts on the magnet or the shutter box 5. The motor 7 is overloaded at the position where the shutter curtain 3 is tightened by further opening the shutter curtain 3 from the upper limit position Pu (hereinafter referred to as the "roll-up position"), not at the upper limit position Pu. It is also conceivable to detect the state. However, the distance between the seaming position and the upper limit position Pu (for example, the number of position pulses counted) can be obtained in advance by experiments or the like. Therefore, the upper limit detector 162 can obtain the upper limit position Pu from the tightening position using the distance between the tightening position and the upper limit position Pu. That is, the upper limit detector 162 can detect the upper limit position Pu by detecting the tightening position.
Therefore, in this case, when the overload of the motor 7 is detected in the upper limit detection process, the recognition unit 165 recognizes that the current position of the shutter curtain 3 is the tightening position, and the storage unit 13 , the seaming position is stored as the recognition position P in .
After recognizing that the current position of the shutter curtain 3 is the tightening position, the control unit 12 closes the shutter curtain 3 by a distance between the tightening position and the upper limit position Pu, thereby tightening the shutter curtain 3. Release processing for releasing may be executed. After the release process, the control unit 12 may update the recognition position P in the storage unit 13 to the upper limit position Pu.

As described above, the shutter device 1 according to this embodiment includes the control unit 12 capable of executing the lower limit detection process and the upper limit detection process. Then, when the power supply to the shutter device 1 is restored from the stopped state, the control unit 12 executes the lower limit detection process when the closing operation is performed as the opening/closing operation after the restoration of the power supply. When the opening operation is performed as the opening/closing operation after restoration of the power supply, upper limit detection processing is executed.

According to such a configuration, when the power supply to the shutter device 1 is restored, the user is not forced to press the "open" switch of the operation unit 2 for a predetermined return operation.
That is, even when the power supply to the shutter device 1 is restored, the user can press the close switch SWc to fully close the shutter curtain 3 in the same manner as during normal use without being conscious of the restoration operation. If the shutter curtain 3 is desired to be fully opened by pressing the switch SWu, the open switch SWu should be pressed. As a result, the shutter device 1 can execute the recovery process for recognizing the position of the shutter curtain 3 and open and close the shutter curtain 3 as desired by the user. Therefore, it is possible to improve the intuitive operability in the return operation, and it is possible to suppress user confusion.

In the above embodiment, the control unit 12 may detect the lower limit position Pl based on the motor load indicating the load applied to the motor 7 as the lower limit detection process.

According to such a configuration, there is no need to provide a new sensor or switch for performing the lower limit detection process.

Further, in the above-described embodiment, when the moving distance H of the shutter curtain 3 when the shutter curtain 3 is closed is not equal to or greater than the predetermined distance Hht during the lower limit detection process, the control unit 12 controls the shutter curtain 3 After opening the shutter curtain 3 by a predetermined distance Hth or more, the lower limit detection process may be performed by closing the shutter curtain 3 again.

Here, in the overload detection in the lower limit detection process, even in an overload state, the motor load does not change as significantly as in the overload detection in the upper limit detection process. Therefore, in the overload detection in the lower limit detection process, the overload state of the motor 7 cannot be accurately detected unless a sufficient amount of position pulses are used. Therefore, in the present embodiment, a distance (predetermined distance Hth) at which the load detection unit 15 can obtain a sufficient amount of position pulses to detect the lower limit position Pl is set in advance by experiment or the like, and the control unit 12 In the lower limit detection process, if the movement distance H due to the closing operation of the shutter curtain 3 is less than the predetermined distance Hth, the retry process is executed to accurately detect the overloaded state of the motor 7 .

All or part of the control unit 12 in the above-described embodiment may be realized by a computer. In this case, the computer may include a processor such as a CPU or GPU and a computer-readable recording medium. Then, a program for implementing all or part of the functions of the learning device A on a computer is recorded on the computer-readable recording medium, and the program recorded on the recording medium is read by the processor and executed. It may be realized by The term "computer-readable recording medium" as used herein refers to portable media such as flexible disks, magneto-optical disks, ROMs, and CD-ROMs, and storage devices such as hard disks incorporated in computer systems. Furthermore, "computer-readable recording medium" means a medium that dynamically retains a program for a short period of time, like a communication line when transmitting a program via a network such as the Internet or a communication line such as a telephone line. It may also include something that holds the program for a certain period of time, such as a volatile memory inside a computer system that serves as a server or client in that case. Further, the program may be for realizing a part of the functions described above, or may be capable of realizing the functions described above in combination with a program already recorded in the computer system. It may be implemented using a programmable logic device such as FPGA.

A shutter system 1 shutter device 2 operation unit 3 shutter curtain 9 shutter control device 11 drive unit 12 control unit 14 drive control unit 15 load detection unit 165 recognition unit

Claims (5)

A shutter device for opening and closing a shutter curtain,
a control unit capable of executing lower limit detection processing for detecting the fully closed state of the shutter curtain and upper limit detection processing for detecting the fully open state of the shutter curtain ;
a motor for opening and closing the shutter curtain;
The lower limit detection process is a process of detecting the fully closed state based on a motor load indicating the load applied to the motor,
When the power supply to the shutter device is restored from the stopped state, the control unit executes the lower limit detection process when the closing operation is performed as the opening/closing operation after the restoration of the power supply. recognizing the position of the shutter curtain by executing the upper limit detection process when an opening operation is performed as the opening/closing operation after the power supply is restored ;
During the lower limit detection process, if the moving distance of the shutter curtain when the shutter curtain is closed is not equal to or greater than the first distance, the controller moves the first distance relative to the shutter curtain. After opening the shutter curtain as described above, the shutter curtain is closed again to perform the lower limit detection process . When the opening operation is performed as the first opening/closing operation after restoration of the power supply, the control unit executes the upper limit detection process together with the opening operation, and performs the first opening/closing operation after restoration of the power supply. 2. The shutter device according to claim 1, wherein when said closing operation is performed as above, the position of said shutter curtain is recognized by executing said lower limit detection processing together with said closing operation. a load detection unit that detects the motor load based on a position pulse corresponding to rotation of the motor;
3. The shutter device according to claim 1, wherein the first distance is a distance at which a sufficient amount of the position pulse for detecting the fully closed state can be obtained by the load detecting section. The control unit
a lower limit detection unit that detects an overload state of the motor based on the motor load during the closing operation of the shutter curtain;
a drive control unit that opens and closes the shutter curtain by controlling the drive of the motor;
with
In the lower limit detection process, when the lower limit detection unit detects an overloaded state of the motor, the drive control unit stops the closing operation of the shutter curtain to stop the stopped shutter curtain. The shutter device according to any one of claims 1 to 3, wherein the shutter curtain is controlled to the lower limit position by opening the shutter curtain by a second distance from the position. a recognition unit that recognizes the position of the shutter curtain by the lower limit detection process;
5. The shutter device according to claim 4, wherein the recognition unit recognizes that the position of the shutter curtain is the stop position or the lower limit position by executing the lower limit detection process.

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