JP2005095332A - Electric moving rack - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an electric moving rack rejecting the moving of a moving rack facing a working passage, securing the safety of workers in the working passage and being used as a moving rack of multi-passage type. <P>SOLUTION: The electric moving rack is provided with an operation switch 4 for the right; an operation switch 6 for the left; a control means 50, while a signal for the right is output, moving the moving rack to the right, and while a signal for the left is output, moving the moving rack to the left; adjoining rack detecting means 65 and 66 measuring a distance between adjoining racks; and passage entry detecting means 61 and 62 formed between the racks. The control means 50 controls to move the moving rack in the same direction as the moving of the adjoining moving rack and to hold a fixed distance toward the adjoining moving rack and, when the sensors 65 and 66 detect an approach of an adjoining moving rack to a predetermined distance, and rejects the moving of the moving rack, when entry detecting means 61 and 62 detect the entry of a moving rack. The moving racks other than the moving rack rejected its driving can arbitrarily move. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to an improvement of an electric moving shelf that can move a moving shelf with a sense of pushing with a manual force while the drive source is an electric motor, and in particular, works in a work path formed between the moving shelves. While performing, it is possible to improve the safety of the workers in the work passage, and to divide into a plurality of mobile shelf groups with any mobile shelf as a boundary, between any mobile shelves constituting each mobile shelf group This also realizes a multi-passage system capable of forming a work passage.

  If a plurality of movable shelves that can move the storage racks by traveling wheels are arranged side by side, a work path can be formed only on the front surface of the storage racks where articles are to be taken in and out. Since they can be gathered together, there is an advantage that a limited space can be efficiently used as an article storage space.

In general, as the drive type of the movable shelf, the rotational operation handle is manually rotated to transmit the rotational force to the traveling wheel via the power transmission mechanism having the speed reduction mechanism, and the traveling wheel is It can be roughly divided into a rotary operation handle type that is driven to rotate and an electric type that uses the driving force of the motor. The present invention belongs to the category of electric moving shelves, but unlike conventional electric moving shelves, the moving is made according to the intention of the operator, and the electric force is as if it supports driving by the operator. The present invention relates to a power assist type electric moving shelf that operates. This type of electric movable shelf includes a traveling wheel, a motor that reciprocally moves the traveling wheel by rotating the traveling wheel forward and backward, an operation switch provided on both sides of the movement direction of the movable shelf, A power supply circuit for supplying power so that the motor is driven in one direction when operating one and the motor is driven in the opposite direction when operating the other of the operation switches. (For example, refer patent document 1).
JP 2001-238738 A

  When a command to form a work path between specific movable shelves is issued, the conventional electric movable shelf is based on the relationship between the position where the work path should be formed and the position of the space where the work path can be moved. The moving shelf to be moved and its moving direction are determined, and based on this, the energization control of the motor and the rotation direction of each moving shelf are controlled. This complicates the control circuit or control software. Furthermore, it is necessary to detect and stop each moving shelf when there is no space to move. Also, if there are workers or obstacles in the moving space, it is necessary to detect and stop them. The width of the work path formed between the shelves is constant and cannot be an arbitrary width.

  On the other hand, according to the electric assist shelf of the power assist method, the determination of the movement control is left to a human, so that the circuit configuration is simplified, and a movable shelf that is less expensive than a conventional electric movable shelf is provided. be able to. In addition, by using a DC motor that can obtain the maximum torque at the time of startup as a drive source, it is possible to move quickly, shorten the waiting time when forming the passage, and improve work efficiency. it can. The width of the work path formed between the shelves can be any width according to the operator's intention.

  The applicant also measures the distance between the adjacent mobile shelves by using a distance sensor in at least one of the mobile shelves adjacent to each other. When the sensor detects the movement shelf, the control means controls the movement shelf to move in the same direction as the movement direction of the adjacent movement shelf and to keep the distance from the adjacent movement shelf constant. A patent application was previously filed regarding a method for controlling a moving shelf (see Japanese Patent Application No. 2003-284095).

  According to the invention relating to the above prior application, the movement of each moving shelf is controlled in accordance with the movement of the adjacent moving shelf, and the position of each moving shelf is designated to form the work path as in the conventional moving shelf. Since there is no need to determine the moving shelf to be moved and its moving direction from the relationship with the determined position and control the moving shelf, it is not necessary to exchange control signals between the moving shelves, and control operations and control The configuration of the means is simple, and the wiring between the moving shelves can be simplified.

The inventors of the present invention have continually studied whether it is possible to add a new function by utilizing the features of the power assist type electric moving shelf, or whether there is any further improvement. As a result, it was found that it is necessary to remove the anxiety about the safety of workers in the already formed work passage even in the power assist type electric moving shelf, and the multi-passage method is relatively It can be easily realized.
The power assist type electric moving shelf moves the moving shelf according to the intention of the operator. If the operator knows that the worker is already in the already formed work passage, the operator can move. You can expect not to move the shelves. Even if it is moved, it is possible to provide a safety device that stops the moving shelf by, for example, an operator in the passage touching the safety bar switch. However, since the workers in the passage suddenly start to move, they become worried that they will be pinched between the shelves, so it has been found necessary to eliminate such anxiety.

  Also, in the power assist type electric movable shelf, when a work passage is formed between arbitrary movable shelves and an article is taken in and out, a work passage is formed at another arbitrary position. However, it has been found that it is convenient to use a multi-passage system that allows the work to be taken in and out of goods, and how to achieve this has been a problem.

The present invention has been made based on the above viewpoint, and in a power assist type electric moving shelf, when an operator or the like is in the formed work path, the work path is temporarily located at another position. Even if the movable shelf is driven to form the above, the movement of the movable shelf facing the work passage containing the above-mentioned workers is refused to ensure the safety of workers in the work passage and The purpose is to eliminate.
The present invention is also a power assist type electric movable shelf, and uses a movable shelf group on one side and a movable shelf group on the other side, with a work passage formed at an arbitrary position as a boundary, for each movable shelf group. It is an object of the present invention to form a work passage, that is, to enable use as a so-called multi-passage type moving shelf.

  In order to achieve the above object, the present invention provides a traveling device, a motor that rotates the traveling device forward and backward to reciprocate the movable shelf, a rightward operation switch that outputs a rightward signal, and a leftward signal. The left-hand operation switch to output, and while the right-handed signal is being output, the motor is driven to move the moving shelf to the right, and while the left-handed signal is being output, the moving shelf is left Control means for driving and controlling the motor in the reverse direction so as to move toward the vehicle, and an adjacent shelf for detecting that the other movable shelf adjacent to each other in at least one of the adjacent movable shelves has approached a certain distance Detecting means and an entry detecting means for detecting an intruder entering a passage formed between adjacent moving shelves, wherein the control means detects that the adjacent moving shelves have approached a certain distance. When the adjacent shelf detecting means detects the movement shelf, the adjacent shelf detecting means performs drive control so as to move the moving shelf in the same direction as the movement direction of the adjacent moving shelf, and the entry detecting means When the intruder detects an intruder, by rejecting the drive of the movable shelf detected by the entry detection means, work is performed at an arbitrary position for each other movable shelf group with the movable shelf rejected as a boundary. The main feature is that a passage can be formed.

  In a moving shelf where the right-handed operation switch or left-handed operation switch is operated, the drive circuit rotates the motor forward or backward by the right-handed signal or left-handed signal that is output while this operation switch is being operated. Run the mobile shelf to the right or left. When this moving shelf approaches another moving shelf, the other moving shelf also moves in the same direction. When the operation switch is released and the rightward signal or the leftward signal is interrupted, the traveling of the movable shelf is stopped. When the operator selects an arbitrary moving shelf and runs, an operation path can be formed between the intended moving shelves. When an operator or the like enters this work path, the moving shelf entry detecting means located on both sides of the work path detects this, and the drive of the moving shelves on both sides of the work path is rejected. Except for the moving shelves that are rejected to be driven, they can be driven according to a right-handed signal or a left-handed signal. Therefore, the movable shelf group on one side and the movable shelf group on the other side can be arbitrarily moved with the movable shelf refused to drive as a boundary, and a working path can be formed at an arbitrary position. . That is, a multipath system can be realized. A lock operation member may be provided on each movable shelf, and the drive of the movable shelf that operates the lock operation member may be rejected.

  As described above, according to the present invention, when an operator or the like enters the formed work passage, the entry detection means detects this and a so-called interlock is applied to the shelf. Even if a left-handed signal is input, driving is rejected, so the work path remains formed, and it is possible to ensure the safety of the worker in the work path and to worry about the worker in the work path. Never give. In addition, since a multi-passage system can be realized, it is possible to perform an efficient article loading / unloading operation. If the lock operation member is provided, a work path can be formed at an arbitrary position for each movable shelf group divided with the movable shelf on which the lock operation member is operated as a boundary.

Hereinafter, embodiments of an electric moving shelf according to the present invention will be described with reference to the drawings.
In FIG. 2, the code | symbol 2 has shown the movement shelf. In the example shown in FIG. 2, five movable shelves 2 are arranged so as to be movable. In FIG. 2, the first moving shelf 2 is A, the second moving shelf 2 is B, the third moving shelf 2 is C, the fourth moving shelf 2 is D, and the fifth moving shelf 2 is E. . Each of these movable shelves 2 has traveling wheels 8 before and after the traveling direction at the bottom, and also has a motor 52 that rotationally drives each traveling wheel. Each traveling wheel 8 rotates on a rail laid on the floor, and is guided by this rail so that each moving shelf 2 can move. However, the moving shelf according to the present invention is not limited to the moving shelf of the type that moves on the rail, but by performing the skew prevention control using the detection signal of the distance sensor described later, the railless system Can be applied to moving shelves.

  In the example shown in FIG. 2, the front surface of each movable shelf, that is, the article loading / unloading surface is oriented in a direction perpendicular to the paper surface, and each movable shelf is moved in a direction perpendicular to the front surface (a horizontal direction parallel to the paper surface). It has become. In this specification, the front surface of each movable shelf is defined as the right side surface or the left side surface, and the vertical surface perpendicular to the front surface and on which the operation unit appears as shown in FIG. To do.

  Each of the motors 52 is a direct current motor having a characteristic that a maximum torque can be obtained at the time of startup due to characteristics. Each motor 52 rotates forward and backward by switching the polarity of the DC power supply to be supplied, and can reciprocate the movable shelf by rotating each traveling wheel 8 forward and backward. Each moving shelf is provided with operation switches 4 and 6 on both sides in the moving direction. In the illustrated example, a side panel is attached to the front of each movable shelf 2, and operation switches 4 and 6 are provided on the front and rear ends of the side panel in the traveling direction of the movable shelf, respectively. The operation switch 4 is a rightward operation switch that is pushed toward the right side when the movable shelf 2 is to be moved to the right side, and the operation switch 6 is toward the left side when the movable shelf 2 is to be moved to the left side. Left-handed operation switch to be pressed. The motor 52 as a drive source may be an AC motor.

  Next, an electric circuit built in each movable shelf 2 will be described with reference to FIG. In FIG. 1, reference numeral 20 indicates a circuit board built in each movable shelf 2. The circuit board 20 has terminals 22, 23, 24, 28, and 29 connected to the circuit board 20 of the moving shelf 2 adjacent to the left side, and is connected to the circuit board 20 of the moving shelf 2 adjacent to the right side. 42, 43, 34, 38, 39. The terminal 24 is a ground terminal and is connected to the terminal 34. The circuit board 20 includes a central processing unit (hereinafter referred to as “CPU”) 50, a DC / DC converter 53, and a drive circuit 54. For example, DC 24V is introduced into the circuit board 20 from an appropriate DC power source. The drive circuit 54 supplies power to the motor 52 based on the control of the CPU 50 to drive the motor 52 in the forward and reverse directions. The DC / DC converter 53 converts the DC 24V power source into a voltage suitable as a power source for the CPU 50 and holds the voltage stably. The DC / DC converter 53 is supplied with 24V DC power from an AC / DC converter 55 that converts commercial AC power into DC.

  The CPU 50 is connected to the right-handed operation switch 4 and the left-handed operation switch 6 described with reference to FIG. 2, and is further connected to an emergency stop switch 56. The emergency stop switch 56 may be, for example, a switch that is manually operated in an emergency, or a switch that is installed on the front surface of the movable shelf 2 and that operates when a human body or other foreign matter comes into contact with the emergency stop switch 56. Good. When installed on the frontage surface, it is installed on the frontage surface on both sides, the emergency stop switches 56 on both frontage surfaces are connected in parallel, and one of the emergency stop switches 56 operates to generate an emergency stop signal. It is output. The CPU 50 controls the drive circuit 54 by operating the rightward operation switch 4, drives the motor 52 so that the movable shelf 2 moves rightward, and outputs a rightward signal at the same time. . The rightward signal is introduced from the terminal 23 to the circuit board 20 of the movable shelf 2 adjacent to the right side from the terminal 43. Further, the CPU 50 controls the drive circuit 54 by operating the leftward operation switch 6 to drive the motor 52 so that the movable shelf 2 moves to the left, and simultaneously outputs a leftward signal. ing. The leftward signal is introduced from the terminal 42 to the circuit board 20 of the moving shelf 2 adjacent to the left side from the terminal 22.

  The CPU 50 also controls the drive circuit 54 when a leftward signal is input from another movable shelf through the terminal 42, drives the motor 52 so that the movable shelf 2 moves leftward, and outputs a leftward signal. Then, the signal is transmitted from the terminal 22 to the moving shelf on the left side. Similarly, when a rightward signal is input from another movable shelf through the terminal 23, the CPU 50 controls the drive circuit 54 to drive the motor 52 so that the movable shelf 2 moves rightward, and to the rightward signal. Is transmitted from the terminal 43 to the right moving shelf.

  Each movable shelf 2 is provided with an entry detecting means for detecting when a person, a forklift or a carriage enters a work path formed between adjacent movable shelves. The entry detection means is configured to detect advancing into a work path formed between a moving shelf adjacent to the left side and a work path formed between the left entry detection means 61 and a movement shelf adjacent to the right side. It comprises right entry detection means 62 for detecting advance. These intrusion detection means 61 and 62 may be of a known appropriate type. For example, at least a pair of light-emitting elements and light-receiving elements are arranged between the moving shelves 2 facing each other so that a light beam is emitted and received, and an operator or the like enters the work passage when the light beam is blocked. It is also possible to detect what is being detected. Or what used an infrared sensor, what detected the worker in a work path using the change of an electrostatic capacitance, etc. may be used.

  Each movable shelf 2 is also provided with a left passage width detecting means 63 for detecting the width of a working passage formed between the movable shelf adjacent to the left side and a working passage formed between the movable shelf adjacent to the right side. The right passage width detecting means 64 for detecting the width of each of the moving shelves is input to the CPU 50 of each moving shelf. As the passage width detecting means 63 and 64, a known appropriate type may be used. For example, a method of measuring the time until an ultrasonic wave is emitted toward the opposite moving shelf and reflecting it, and converting it to a distance, and the opening angle of a swing arm passed between adjacent moving shelves. A method of measuring mechanically can be selected and used. The passage width detection means 63, 64 indicates that the interval between the work passages formed at least between the moving shelves adjacent to each other is, for example, a predetermined passage width necessary for an operator to enter and put in and out articles. Anything that can be detected is acceptable.

  Each movable shelf 2 includes a distance sensor that measures the distance from the other movable shelf adjacent to each other. The distance sensor includes a right distance sensor 65 that measures the distance to the moving shelf adjacent to the right side, and a left distance sensor 66 that measures the distance to the moving shelf adjacent to the left side. The distance sensors 65 and 66 only need to detect that the adjacent movable shelf has approached a certain distance in accordance with at least a rightward signal or a leftward signal. That is, the distance sensors 65 and 66 need only have a function as an adjacent shelf detection means at a minimum. When the sensor 65 or 66 detects that the adjacent moving shelf 2 has approached a certain distance according to the right-handed signal or the left-handed signal, the CPU 50 as the control means of each moving shelf 2 moves to the moving shelf. Is moved in the same direction as the movement direction of the adjacent moving shelf, and the program is configured to control the drive while keeping the distance from the adjacent moving shelf close to each other. In the illustrated embodiment, the distance sensors 65 and 66 can detect the distance to the adjacent movable shelf in several stages. As can be seen from the operation described later, the distance sensors 65 and 66 The speed control of the moving shelf is performed according to the detected distance.

  FIG. 3 shows an example of the distance sensors 65 and 66. The distance sensor shown in FIG. 3 is a non-contact distance sensor using ultrasonic waves. This distance sensor has a pulse transmitter / counter circuit 30. The pulse transmitter is a part that generates an ultrasonic signal, and radiates the generated ultrasonic wave from a sounding body 31 corresponding to a speaker toward a reflector 33. The sounding body 31 has high directivity. A sound sensor 32 corresponding to a microphone is connected to the counter circuit of the pulse transmitter / counter circuit 30. The sound sensor 32 also has high directivity. The sound sensing body 32 is configured to receive the ultrasonic wave reflected by the reflector 33 and convert it into an electrical signal and input it to the counter circuit. The sounding body 31 and the sound sensing body 32 are arranged on the same plane. The pulse transmitter / counter circuit 30 counts the time from when an ultrasonic wave is emitted from the sound generator 31 until the reflected wave is received by the sound sensor 32. This count value is input and processed by a microcomputer or a microprocessor including the control means, whereby the distance between the sounding body 31 and the sound sensing body 32 and the reflector 33 can be measured. Since the distance sensor itself using such an ultrasonic wave is known, detailed description is omitted. The right distance sensor 65 may also serve as the right passage detection means 64, and the left distance sensor 66 may also serve as the left passage detection means 63.

  The circuit board 20 built in each movable shelf 2 has the same circuit configuration as shown in FIG. 1, and the terminals 22, 23, 24, 28, and 29 are terminals of the circuit board 20 of the movable shelf 2 adjacent to the left side. 42, 43, 34, 38, 39, and the terminals 42, 43, 34, 38, 39 are connected to the terminals 22, 23, 24, 28, 29 of the circuit board 20 of the moving shelf 2 adjacent to the right side. Thus, when a rightward signal is generated by operating the rightward operation switch 4 of a certain mobile shelf 2, the rightward signal is transferred to the circuit board 20 on the mobile shelf 2 located on the right side of the shelf. Is transmitted through. Further, when a left-handed signal is generated by operating the left-handed operation switch 6 of a certain moving shelf 2, the left-handed signal is transmitted to the moving shelf 2 located on the left side of the shelf via the circuit board 20. Communicated. That is, the circuit pattern of the right-handed signal and the left-handed signal formed on the circuit board 20 or this circuit board constitutes a means for transmitting the right-handed signal and the left-handed signal. When a predetermined condition is satisfied in each moving shelf, the CPU 50 outputs an interlock signal to control the drive circuit 54 so as to reject the movement of the shelf, and sends the interlock signal through the terminal 39. The information is transmitted to the mobile shelf on the left side through the terminal 29 to the mobile shelf on the right side. In addition, when the interlock signal is transmitted from the mobile shelf on the right side through the terminal 38 and from the mobile shelf on the left side through the terminal 28, and the interlock signal is input from the adjacent mobile shelf, the CPU 50 Controls the drive circuit 54 to reject the movement of the shelf.

  A distance sensor using the ultrasonic wave is installed on a moving shelf. The sounding body 31 and the sound sensing body 32 of the distance sensor are directed toward the opposing surfaces of the adjacent moving shelves, and the front surfaces of the sounding body 31 and the sound sensing body 32 coincide with the front surface (frontage surface) of the moving shelf. Install in. A reflector 33 is provided on the surface of the adjacent moving shelf facing the sounding body 31 and the sound sensing body 32. The surface of the moving shelf itself may be used as the reflector 33. Since the distance sensor detects the width or distance of one work path, at least one distance sensor is provided in one work path, and therefore, at least one of two moving shelves adjacent to each other is provided. The detection signal may be transmitted to the other moving shelf. However, when used as a skew detection means for preventing the skew of the moving shelf as will be described later, it is sufficient that at least two distance sensors are installed on at least one of the opposite moving shelves.

  Next, an operation example of the moving shelf control means according to the present invention will be described with reference to FIG. In FIG. 4, the operation steps are represented as “S11”, “S12”. An example of this control flow includes a parameter reading step S11, a distance measuring step S12, a control amount calculating step S13, a control output S14, a determination step S15 for determining whether the target position is reached, and a stopping step S16. When the operation is started, various parameters are first read (S11). One of the parameters is the interlocking distance. The interlocking distance is the predetermined distance when a plurality of movable shelves move in parallel while maintaining a predetermined distance. In other words, when the adjacent shelves approach, they move so as to escape while controlling the speed of the moving shelves. This is the distance between the moving shelves. The second parameter is the braking distance. The braking distance is the distance when the moving shelf approaches the distance measuring surface such as an adjacent moving shelf or a wall or an end stopper, reaches the moving limit, and starts to apply braking in order to slow down the moving speed of the moving shelf. . Another parameter is the stopping distance. The stop distance is a distance when the moving shelf reaches the moving limit and stops moving the moving shelf. These parameters are set in advance, and are read and stored in the memory.

  Next, the distance to the adjacent movable shelf is measured (S12), and a specific driving speed is calculated based on the measurement result (S13). In this control amount calculation (S13), the moving speed of each moving shelf is calculated while referring to the various parameters read first, and further, whether or not the position to be braked has been reached is calculated. Based on the calculation result, a speed control signal is output (S14), the speed of the drive motor is controlled according to this control signal, and when the predetermined braking position is reached, the individual drive motors are decelerated and controlled. Apply braking. When the predetermined target position is reached (S15), the drive motor is stopped (S16) and the operation is terminated.

  The image of the above operation is shown in FIG. 5 in comparison with the operation of a conventional electric moving shelf. In a conventional electric movable shelf, for example, when an open command switch is operated to form a work path between desired movable shelves, it moves from the relationship between the current position of all the movable shelves and the positions where work paths should be formed. The moving shelf to be moved and its moving direction are determined, and the moving shelf is moved according to the determination. FIG. 5 (a) shows an example of this. In a state where the movable shelf 11 and the movable shelf 12 are close to each other and a work path is formed between the movable shelf 12 and the movable shelf 13, When a command is issued to form a work path with the movable shelf 12, the movable shelf 12 is controlled to move leftward based on the above determination. Reference numeral 12A indicates a state where the movable shelf 12 is moving. Further, when the movable shelf 12 is moved by this control and comes into contact with the movable shelf 13 or when an appropriate proximity switch is detected, the movement of the movable shelf 12 is stopped.

  In contrast to the operation of the conventional moving shelf, in the power-assisted electric moving shelf according to the present invention shown in FIG. 5 (b), the moving shelf itself for which a movement command is issued to form a work path is used. The operation is not different from the conventional one, except that the movement of the other moving shelf is controlled by the movement of the adjacent moving shelf. More specifically, in the embodiment shown in FIG. 5 (b), the three movable shelves 11, 12, and 13 are movably arranged on the floor as in the conventional example shown in FIG. 5 (a). In addition, all the moving shelves can be converged, and a working path for taking in and out the stored articles can be formed between arbitrary moving shelves. Traveling devices 21, 22, and 23 are incorporated at the bottoms of the movable shelves 11, 12, and 13, and the traveling devices 21, 22, and 23 can move linearly on the floor.

  Now, assuming that the movement direction of each movable shelf in FIG. 5 is the left-right direction, it is assumed that a command is issued to move the movable shelf 11 to the left side so as to form a work path on the right side of the movable shelf 11. If a work path is formed on the left side of the movable shelf 11, only the movable shelf 11 moves to the left. However, as shown in FIG. 5B, in the current situation where there is a moving shelf 12 next to the moving shelf 11, when a command is issued to move the moving shelf 11 to the left side, the moving shelf 12 is moved to the moving shelf 12. 11 is approaching, and the distance sensor as the adjacent shelf detecting means of the moving shelf 12 detects that the moving shelf 11 has approached a certain distance. Alternatively, when the movable shelf 11 approaches the movable shelf 12 in a state where the movable shelf 11 and the movable shelf 12 are largely separated from each other, a distance sensor as an adjacent shelf detection unit of the movable shelf 12 detects this. Based on this detection signal, the CPU 50 that is the control means of the movable shelf 12 drives and controls the motor that is the drive source of the movable shelf 12 through the drive circuit 54 so that the movable shelf 12 is moved to the left. Moreover, the control means of the moving shelf 12 controls the moving speed of the moving shelf 12 so that the distance between the moving shelf 11 and the moving shelf 12 is kept constant with the moving shelf 11 and the moving shelf 12 approaching each other. Reference numeral 12A indicates a state where the movable shelf 12 is moving. In this manner, the movable shelf 12 moves away from the movable shelf 11, and conversely, the movable shelf 11 follows the movable shelf 12 and moves in parallel with the distance between the movable shelves kept constant.

  When the movable shelf 12 approaches the movable shelf 13 to a predetermined distance, the movable shelf 13 also moves to the left side with a certain distance from the movable shelf 12 by the detection operation of the distance sensor of the movable shelf 13. The moving limit is reached in the order of the moving shelf 12 and the moving shelf 11. The movement limit means that a distance from a distance measuring surface such as an end stopper in a moving direction of the moving shelf or a distance from an adjacent moving shelf approaches a predetermined stop distance as viewed from each moving shelf. When the distance sensor of each moving shelf detects the above movement limit, the driving of the motor as a driving source is stopped so that the control means of each moving shelf stops the moving shelf on the spot.

  In another operation example of the electric movable shelf according to the present invention shown in FIG. 5C, the movable movable shelf 11 has two movable shelves 11 and 12, and a wall 14 as a distance measuring surface exists on the left side of the movable shelf 12. ing. A working path consisting of a large space is formed between the moving shelf 11 and the moving shelf 12, and is smaller than the working path between the moving shelf 12 and the wall 14, but the moving shelf 12 is directed to the left. A sufficiently movable space is formed. Now, it is assumed that a command is issued to move the movable shelf 11 toward the left in order to form a work path on the right side of the movable shelf 11. The moving shelf 11 starts to move toward the moving shelf 12. When the moving shelf 11 approaches the moving shelf 12 to a predetermined distance, the distance sensor (adjacent shelf detecting means) of the moving shelf 12 detects this, and the control means of the moving shelf 12 moves according to the detection signal from the distance sensor. The drive motor of the shelf 12 is rotationally driven. At this time, the control means of the movable shelf 12 controls the speed of the drive motor according to the detection signal from the distance sensor, and keeps the distance between the movable shelf 11 and the movable shelf 12 constant.

  The moving shelf 12 approaches the wall 14 by the movement. When the distance sensor of the movable shelf 12 detects that the distance from the wall 14 has approached the fixed stop distance a, the control unit of the movable shelf 12 drives the drive motor of the movable shelf 12 to stop the movable shelf 12. Stop. Further, when the distance sensor of the movable shelf 11 detects that the distance from the movable shelf 12 has approached a certain stop distance b, the control means of the movable shelf 12 causes the drive motor of the movable shelf 12 to stop the movable shelf 12. Stop driving. Thus, in each moving shelf, the control means of each moving shelf has a predetermined distance from an adjacent moving shelf or a distance from a distance measuring surface made up of a wall 14 or an end stopper in the moving direction of the moving shelf. When the stop distance is approached, the movable shelf provided with the control means is stopped. A predetermined space may be formed between the stopped moving shelves and between the moving shelves and the distance measuring surface. By forming these spaces, it is possible to ensure the circulation of air in the moving shelf.

  FIG. 5 is drawn assuming a railless type moving shelf. That is, the moving shelf shown in FIG. 5 employs an endless track system as a traveling device. Even if the endless track method is adopted, the moving shelf may be skewed due to various factors. Therefore, the left and right endless tracks are independently driven when the moving shelf is viewed from the traveling direction, that is, viewed from the front side. Like that. In addition, distance sensors (which correspond to the distance sensors 65 and 66 shown in FIG. 1) that measure the distance to the adjacent shelf are provided on the left and right as viewed from the front side, and the right and left are measured according to the measurement results of each distance sensor. Control the driving speed of the endless track. By doing so, it is possible to eliminate the skew of the movable shelf even if there is no rail, so that it is possible to realize a substantially railless movable shelf.

FIG. 6 shows more specifically the operation when the adjacent shelf approaches the stopped shelf. As shown in FIG. 6 i, when the right shelf (2) approaches the distance “a” to the shelf (1) that is not interlocked, the shelf (1) moves slowly while the shelf (1) starts slowly. Begin to move in the same direction. As shown in FIG. 6ii, the shelf (1) and the shelf (2) move toward the left side in the figure while maintaining a distance interval of “b” between them at the same speed. As shown in FIG. 6iii, when the distance from the wall where the shelf (1) is the movement limit becomes “c”, the shelf (1) is controlled to decelerate, and as shown in FIG. 6iv, the distance from the wall is “c”. When the distance becomes smaller than “d”, the operation stops. Similarly, the shelf (2) is controlled to decelerate when the distance from the shelf (1) becomes "c" and stops when the distance "d" is reached. Here, the relationship between the distances is as follows:
a>b>c> d
It becomes.

  In the power assist type electric movable shelf described so far, when an operator, a forklift, or the like enters between work paths formed between the shelves, the entry detection means detects this. The right entry detection means 62 detects the left moving shelf with the work passage in between, and the left entry detection means 61 detects the right movement shelf. In the moving shelf having the entry detecting means that has performed the detection operation, that is, the moving shelf located on both sides of the work path, the CPU 50 (see FIG. 1) as the control means instructs the drive circuit 54 to reject the driving of the moving shelf. . The contents of the rejection command are to reject the driving of the motor 52 based on these signals even when a rightward signal or a leftward signal is input to the drive circuit 54, that is, to apply an interlock.

As described above, by interlocking the movable shelf that sandwiches the work path, even if another operator operates the operation switch to form the work path at another position, the movable shelf that sandwiches the work path moves. Therefore, the safety of workers in the work passage is ensured.
In the circuit example shown in FIG. 1, when an interlock is applied to the movable shelf on the left side of the formed passage, an interlock signal is transmitted from the terminal 39 to the right adjacent movable shelf, and on the right side of the formed passage. When an interlock is applied to a certain mobile shelf, an interlock signal is transmitted from the terminal 29 to the mobile shelf adjacent to the left. In addition, an interlock signal generated in the right adjacent moving shelf across the passage is introduced through the terminal 38, and an interlock signal generated in the left adjacent moving shelf is introduced through the terminal 28. By introducing such an interlock signal, the movable shelf can be interlocked.

  In the example of the interlock described above, if it is detected that an operator or the like has entered the work passage, the interlock is applied only by that and is not related to the width of the work passage. Therefore, even if the width of the passage is not large enough for the operator's entire body to enter, the interlock is also applied, for example, by entering only the hand and taking out the article. This will result in inconvenient interlocking and may be inconvenient in return. Therefore, the passage width detection means 63 and 64 are used to detect that the passage width detection means 63 or 64 has a constant passage width, and that an operator has entered the work passage. When the detection means 61 or 62 detects, it is preferable to interlock the moving shelves on both sides of the work path.

  In the present invention, interlocking is an indispensable condition. By using this interlock, a so-called multi-passage type moving shelf can be realized even in a power assist type moving shelf. Specifically, each movable shelf is provided with a lock operation member including an operation switch for realizing a multi-passage system, and when the lock operation member is operated, the drive of the movable shelf is rejected. That is, the movable shelf is interlocked. By doing so, moving shelves that have been rejected to drive are rejected even if a right-handed signal or left-handed signal is input, and other moving shelves receive these signals by inputting right-handed signals or left-handed signals. Can move according to. Therefore, it is possible to form a work path for each moving shelf group partitioned by the moving shelving rejected, and a so-called multi-passage type electric moving shelf is realized in the power assist type moving shelf. . An example of the operation at this time is shown in FIG.

  In FIG. 8, first, in S31, it is determined whether or not an adjacent moving shelf has approached. This determination is made based on the detection signal of the distance sensor 65 or 66, or based on the detection signal of the passage width detection means 63 or 64. In any one movable shelf, when the adjacent movable shelf is closer than a predetermined distance, it is determined whether or not the next interlock is applied (S32). Is rejected (S33). If the interlock is not applied in S32, the moving operation is continued in S34. This moving operation is the same as the moving operation shown in FIGS. 4 and 5B and 5C.

  FIG. 7 shows an example in which a multi-passage system is applied with an interlock. FIG. 7 shows an example in which six movable shelves (1) to (6) are arranged, a work path A is formed between the shelves 3 and 4, and the shelves 3 and 4 sandwiching the path A are interlocked. Show. The shelves 3 and 4 cannot move because the drive is rejected. In contrast, the two shelves (5) and (6) on the right side of the shelf 4 and the shelves (1) and (2) on the left side of the shelf 3 can move as long as there is a transition margin. Therefore, with the passage A as a boundary, in other words, working passages can be formed at desired positions on the right and left sides with respect to the passage A, respectively.

As described above, even in the power assist type electric movable shelf, the one movable shelf group and the other movable shelf group are divided into one passage on the basis of one interlocked movable shelf. It is possible to realize a multi-passage type moving shelf capable of forming If a plurality of movable shelves to be interlocked are provided, the movable shelf group can be divided into three or more groups, and a work path can be formed for each group.
As described above, while a worker or the like is in the formed work passage, interlocking is applied to the movable shelves on both sides of the work passage. This is a multi-passage system in which a working passage can be formed by each of the moving shelf group and the other moving shelf group.

In the above embodiment, if an operator or the like exits from the work passage, the interlock is released. However, after the worker enters the work passage and the interlock is temporarily applied, the worker etc. exits. Alternatively, the interlock may not be released unless a lock release operation is performed.
Even if there are no workers or the like in the work path, by operating the lock operation members of the movable shelves on both sides to apply the interlock, a plurality of other than the work path, a plurality of work paths are formed. A working passage can be formed at the position.
There may be only one moving shelf on which the lock operating member is operated to interlock. The moving shelves on both sides sandwiching the formed passage are not limited to being interlocked, and only one moving shelf may be interlocked.

  Some conventional electric moving shelves can be made into multi-passage moving shelves. However, the width of the work path that can be formed in the conventional multi-passage type electric movable shelf is a predetermined fixed width, or is limited to twice that width, and may be an arbitrary width. I couldn't. In that respect, according to the electric movable shelf according to the present invention, the width of the work passage formed between the movable shelves is arbitrary. It is also possible to interlock the movable shelves on both sides in a state where a work passage of an arbitrary width is formed, and one movable shelf group divided by the work passage of the arbitrary width and the other A work passage having an arbitrary width can be formed for each movable shelf group. Therefore, it is only necessary to determine the width of the passage according to various conditions such as the size of the article to be taken in and out, whether or not a forklift is used, whether or not a carriage is used, etc. can do. In addition, since it is not necessary to form a large working passage without darkness, it is possible to form working passages at more positions, and from this point, work efficiency can be improved.

  When the condition that the passage width detecting means detects that the passage width is constant is a condition for applying the interlock, the case where the work passage between the moving shelf and the moving shelf adjacent thereto is being opened further It is better to make it a condition. That is, when the passage between the moving shelf and the moving shelf adjacent to the moving shelf is opening, the CPU 50 as the control means has a passage width detected by the passage width detecting means equal to or larger than a certain width, and When the entry detecting means detects an intruder or the lock operation member is operated, the moving shelf is interlocked and its drive is rejected. In this case, in order to prioritize safety, the interlock is applied with priority given to the case where the intrusion detection means detects the intruder or the operation of the lock operation member over the detection by the passage width detection means. It is good to make it.

  On the other hand, when the work path between one moving shelf and a moving shelf adjacent thereto is becoming tight, the condition for applying the interlock is that, from the viewpoint of ensuring safety, the entry detection means detects an intruder, Alternatively, it may be a case where the lock operation member is operated.

  In the illustrated embodiment, a right-bound signal and a left-bound signal output from one movable shelf are transmitted to a movable shelf located on the right side and a movable shelf located on the left side, and each shelf moves to the right or left. However, in the individual mobile shelves, when the distance sensor or the passage width detecting means detects that the adjacent mobile shelves have approached to a certain distance, the mobile shelves to which the detected moving shelf has approached You may comprise so that it may move to the same movement direction. This has the advantage that the wiring can be simplified because it is not necessary to transfer the right-handed signal and left-handed signal transmission means between the moving shelves.

  The electric mobile shelf according to the present invention is used as a document storage shelf in an office, as a library storage shelf in a library, as a storage shelf for materials and tools in a factory, as an article storage shelf in a distribution warehouse, and for storing all other items. Or it can be used as an arrangement shelf.

It is a circuit block diagram which shows embodiment of the electrically-driven movable shelf concerning this invention. It is an external appearance side view which shows embodiment of the electrically driven movement shelf concerning this invention. It is a conceptual diagram which shows the example of the ultrasonic distance sensor applicable to this invention. It is a flowchart which shows operation | movement of the said embodiment. The embodiment of the control method of the electric movable shelf concerning this invention is shown in comparison with the conventional movable shelf, (a) is operation | movement of a prior art example, (b) is one operation | movement of this invention, (c ) Is a side view showing another operation of the present invention. It is a side view which shows more specifically the example of the control method of the electrically-driven movable shelf concerning this invention. It is a side view which shows the example of the multichannel | path formation operation | movement of the electrically driven movement shelf concerning this invention. It is a flowchart which shows the example of the multipass | path formation operation | movement of the electrically driven movement shelf concerning this invention.

Explanation of symbols

4 Right-handed operation switch 6 Left-handed operation switch 50 CPU as control means
52 motor 54 drive circuit 61 left approach detection means 62 right approach detection means 63 left passage width detection means 64 right passage width detection means 65 right distance sensor 66 left distance sensor

Claims (4)

A traveling device;
A motor that reciprocally moves the traveling shelf by rotating the traveling device forward and backward,
A right-handed operation switch that outputs a right-handed signal and a left-handed operation switch that outputs a left-handed signal;
The motor is driven so as to move the moving shelf to the right while the rightward signal is output, and the moving shelf is moved to the left while the leftward signal is output. Control means for driving and controlling the motor in the reverse direction;
Adjacent shelf detection means for detecting that the other movable shelf adjacent to each other in at least one of the adjacent movable shelves has approached a certain distance;
An entry detecting means for detecting an intruder entering a passage formed between adjacent mobile shelves;
When the adjacent shelf detecting means detects that the adjacent moving shelf has approached a certain distance, the control means detects the moving shelf detected by the adjacent shelf detecting means as the direction of movement of the adjacent moving shelf. The drive shelf is controlled to be moved in the same direction, and when the entry detection means detects an intruder, the entry of the entry detection means is rejected to drive the movement shelf, and the drive shelf is denied drive. An electric moving shelf characterized in that it is possible to form a work path at an arbitrary position for every other moving shelf group on the boundary. A traveling device;
A motor that reciprocally moves the traveling shelf by rotating the traveling device forward and backward,
A right-handed operation switch that outputs a right-handed signal and a left-handed operation switch that outputs a left-handed signal;
The motor is driven so as to move the moving shelf to the right while the rightward signal is output, and the moving shelf is moved to the left while the leftward signal is output. Control means for driving and controlling the motor in the reverse direction;
Adjacent shelf detection means for detecting that the other movable shelf adjacent to each other in at least one of the adjacent movable shelves has approached a certain distance;
A lock operation member for refusing to drive the movable shelf,
When the adjacent shelf detecting means detects that the adjacent moving shelf has approached a certain distance, the control means detects the moving shelf detected by the adjacent shelf detecting means as the moving direction of the adjacent moving shelf. Drive control is performed so that it is moved in the same direction, and when the lock operation member is operated, the drive of the locked movement shelf is rejected, so that the rest of the movement shelf is rejected. An electric mobile shelf characterized in that a work passage can be formed at an arbitrary position for each mobile shelf group. Having passage width detecting means for detecting the width of the passage formed between adjacent moving shelves;
When the passage between the moving shelf having the control means and the moving shelf adjacent thereto is opening, the control means has a passage width detected by the passage width detecting means equal to or greater than a certain width, and 3. The electric movable shelf according to claim 1, wherein when the entry detecting unit detects an intruder or the lock operation member is operated, driving of the movable shelf having the control unit is rejected. . When the passage between the moving shelf having the control means and the moving shelf adjacent thereto is closing, the control means detects the intruder or the lock operation member is operated. In the case, the drive of the movable shelf having the control means is rejected.

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