JPH05330611A - Mobile shelf device of multispeed operation type - Google Patents

Abstract

PURPOSE:To improve work efficiency and safety by setting a plural number of operation patterns by controlling travel speed of a movable shelf to multispeed so as to suit the change of application of the shelf and multipurpose application. CONSTITUTION:A mobile shelf device in which a plural number of movable shelves provided with reversible motors M1 to M4 for running respectively are arranged by means of work passages is provided with a travel speed selector switch CS which changes over travel speed of the movable shelves to multispeed operation. deceleration space detection switches BS1 to BS5 which detects reduction of the work passages, and inverters IV1 to IV4 which set the slow start function which accelerates steplessly at the time of start, operation frequency which makes the shelves run at a constant speed in respective multispeed operation due to the travel speed selector switch CS, the halfway stop deceleration function which stops the travel of the shelves halfway at the time of emergency or arbitrarily, and the slow step function which corresponds to respective multispeed operation which decelerates stepslessly when the shelves stop at the fixed position.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention comprises a plurality of movable shelves that are densely arranged, leaving at least one working space to serve as a passage for cargo handling work. An electric moving rack device that forms a passage for cargo handling between desired shelves, and can be set to switch the moving speed of movable shelves to multiple speeds to suit different cargo handling forms depending on the type of industry, application, etc. The present invention relates to a shelf device.

[0002]

2. Description of the Related Art In order to allow a large number of movable shelves to be arranged in a narrow space, a working space for cargo handling formed between shelves is left for one passage, and other movable shelves are spaced apart. Mobile shelving equipment that is placed in a densely packed state without being opened, and these movable shelves are moved by inverter control by aisle selection operation corresponding to each aisle to form work aisles between desired shelves for cargo handling work. Was previously known.

In the movable rack equipment, an approach detector for detecting the mutual approach between the racks is installed for each movable rack, and a software for increasing the speed of the racks at a constant acceleration through an inverter in a controller of a reversible motor. A start function, a soft down function for decelerating at a constant acceleration, and a brake function are installed.When the shelves are moved by operating the start switch, the proximity detector and control device operate to detect the proximity detector. After activating the soft start function based on the signal to softly accelerate the shelves, the shelves are run at a constant high speed, and then when it is detected that the mutual intervals between the shelves have decreased, the soft It is configured to activate the down function to softly reduce the speed of the shelf and to activate the braking function to stop the shelf in place.

Further, in order to improve the stop accuracy of the moving shelf equipment, a moving shelf equipment provided with a function of detecting the stop position of the shelf in addition to the function of detecting the start position of the soft down of the shelf is also known in the related art. It was being done.

In the movable rack equipment, a first approach detector for detecting the mutual approach between the racks is installed for each movable rack, and
In particular, a second approach detector that detects a specific stop position closer to each other between the shelves is installed, and when the shelves are moved by the operation of the start switch, by the operation of the control device via the inverter, First, after activating the soft down function based on the detection signal of the first approach detector, the brake is applied at the time when the specific position of the shelf to be stopped is detected based on the detection signal of the second approach detector. It is configured to stop the shelf that activated the function in place.

[0006]

However, in the movable rack equipment, although consideration is given to safety when the movable rack is accelerated, decelerated and stopped.
The operation pattern of the movable shelf is set to one, and the moving speed after acceleration of the movable shelf is always fixed, regardless of the type of load, shape, etc. Has a problem in that it is difficult to avoid problems such as collapse of cargo when traveling at high speed, and it is difficult to change applications and adapt to multipurpose applications.

Further, since the width of the passage between the shelves varies greatly depending on the cargo handling work facility, the cargo handling form, etc., if the moving speed is insufficient and slow, it takes a lot of time to open and close, resulting in a decrease in work efficiency. There was a problem.

Further, in equipment such as manual picking where the passage width is narrow, or when a wide passage width is divided into a plurality of passages for simultaneous use and for inventory work, if the moving speed is too fast, it is dangerous for the operator. There was a problem that it had a psychological effect and that safety was impaired at high speeds.

The present invention solves each of the conventional problems described above, and sets the plurality of operation patterns by controlling the movement speed of the rack to a multi-speed operation so that it can be adapted to the change of the use of the shelf and the multipurpose use. Therefore, it is an object of the present invention to provide a multi-stage speed operation type moving rack device capable of improving work efficiency and safety performance.

[0010]

According to the present invention, a plurality of movable shelves each having a reversible motor for traveling are provided in a compartment divided by a fixed shelf or a side wall with a margin space corresponding to one working passage. In the electric movable shelving device, which is arranged individually, and at the time of receipt and delivery of articles, the plurality of movable shelves between the spare space and the desired passage are moved simultaneously by operating the passage selecting means of the desired passage. Moving speed changeover switch for switching the moving speed of the multistage speed operation, a deceleration space detection switch for detecting the decrease of the margin space for each passage, and stopping the movable shelf at a fixed position, and the reversible motor. Slow start function for continuously accelerating at the time of starting, operating frequency for constant speed traveling in each of the multi-speed operation, and multi-step speed for continuously decelerating when stopped at the fixed position And a slow-stop function corresponding to each of the rotations, and when the movable shelf moves to form the passage by operating the passage selecting means, the deceleration space detection corresponding to the spare space is detected. The reversible motors of the movable shelves to be moved by the space detection signal of the switch are simultaneously activated by the slow start function via the inverter, and are set by one of the multi-speed operation set by the moving speed changeover switch. A means for traveling at high speed and stopping at the fixed position by a slow stop function corresponding to one of the set multi-speed operation by a deceleration detection signal of the deceleration space detection switch, a fixed shelf or a side wall. A plurality of movable shelves each equipped with a reversible motor for traveling are arranged in the compartment with a margin space corresponding to at least one working passage. At the time of goods receipt and disbursement,
By operating the passage selecting means of the desired passage, the plurality of movable shelves between the spare space and the desired passage are moved at the same time, and the spare space is divided between the plurality of shelves to form a plurality of passages. In the electric movable shelf device that is made possible, a moving speed changeover switch that switches the moving speed of the movable shelf to a multi-speed operation, and a decrease in the margin space for each of the passages are detected to set the movable shelf at a fixed position. A deceleration space detection switch for stopping the reversible motor, a slow start function for continuously accelerating at the time of starting the reversible motor, an operating frequency for traveling at a constant speed in each of the multi-speed operation, and a stop device for stopping the movable shelf during movement. The slow stop function corresponding to each of the intermediate stop deceleration function of stopping at an intermediate position by operation and the multi-speed operation of continuously decelerating when stopped at the fixed position. And an inverter for setting a function, and when the movable shelf moves to form the passage by the operation of the passage selecting means, the movable rack is moved by a space detection signal of the deceleration space detection switch corresponding to the spare space. The reversible motors of the movable shelves should be simultaneously activated by the slow start function via the inverter, and the vehicle travels at a constant speed in one of the multi-speed operations set by the moving speed changeover switch to detect the deceleration space. According to the deceleration detection signal of the switch, the slow stop function corresponding to one of the set multi-step speed operations is used to stop at the fixed position, and the intermediate stop deceleration function is used to stop at the intermediate position when the plural passages are formed. The above problem was solved by adopting any one of the means.

[0011]

According to the present invention having the above-described structure, when a passage for receipt and delivery work is formed between desired shelves at the time of goods receipt and delivery, the moving speed of the movable shelf suitable for the application is operated by operating the moving speed changeover switch. After setting, the open switch which is the passage selecting means is operated to start the movement of the movable shelf so as to form the passage. At this time, the inverter activates the slow start function by the space detection signal of the deceleration space detection switch to gradually accelerate the movable shelf, and further moves the movable shelf to move one of the multi-speed operation according to the selection operation of the speed changeover switch. Drive at speed. After that, with the deceleration detection signal of the deceleration space detection switch that detects the passage width decrease as the movable shelf travels, the slow stop function is activated according to one moving speed of the multi-speed operation, and the movable shelf is gradually decelerated. , And stop at a fixed position. If a safety bar device (not shown) is activated during this period, or if the shelf is to be stopped urgently or to stop the shelf at will, by operating the reset button, which is a stopping means during movement, A stop signal is issued to activate the intermediate stop deceleration function to stop the movable shelf. Further, in the case where one passage is divided into a plurality of passages, a new passage is formed by operating the open switch for forming another passage on the remaining side of the passage space after arbitrarily stopping the passage. The side shelves are moved to form a plurality of work passages.

[0012]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described in detail with reference to the drawings. FIG. 1 is a plan view showing an extra space corresponding to a work passage, an arrangement of shelves in a state in which a passage 1 is formed, and an external appearance in the device of the present invention, FIG. 2 is a front view thereof, and FIG. 3 is a rear view thereof. In the figure, R is a guide rail laid on the floor, and fixed shelves A and F are arranged at both end positions of the rail R, and movable shelves B and C between the fixed shelves A and F.
D and E are arranged on the guide rail R so as to be movable in the left-right direction via traveling wheels.

The fixed shelves A and F and the movable shelves B, C and D
-E is a shelving device in the embodiment. Among them, the fixed shelves A and F are arranged if necessary, but may be omitted or may be a wall surface. In this embodiment, fixed shelves A and F will be described for convenience of explanation.

Between each of the shelves A, B, C, D, E, F,
Aisles 1, 2, 3, 4, 5 can be formed between adjacent shelves,
In FIG. 1, the movable shelves B, C, D, and E are moved to the right side to be densely packed, and the passage 1 portion is opened as wide as possible to serve as a receipt and delivery work passage, so that the receipt and delivery work can be performed smoothly. ..

Below the movable shelves B, C, D and E,
Reversible motors (three-phase induction motors) M1 and M2 for self-propelling
-M3 and M4 are attached, the traveling wheels are rotated through a speed reducer, and an opening is formed on the front side of each of the movable shelves B, C, D, and E to form a work passage between desired shelves. Switch (path selection means) OS1, OS2, OS3,
OS4 / OS5, and reset switches (also means for intermediate stop during movement) RS1, RS2, RS3, RS4, RS5 for unlocking the formed passage are provided respectively, and in particular, the movable shelf B is provided. A moving speed changeover switch CS for setting the moving speed of each of the movable shelves B, C, D, and E is provided at substantially the center of the front surface.

The open switches OS1, OS2, O
S3, OS4, and OS5 are selection switches for selecting the passages between the shelves, of which OS1 and OS2 are movable shelves B.
, OS1 is a selection switch for selecting the passage 1 between the fixed shelf A and the movable shelf B, and OS2 is the selection switch for selecting the passage 2 between the movable shelf B and the movable shelf C. The open switch OS3 is attached to the front end of the movable shelf C on the right end side and is a selection switch for selecting the passage 3 between the movable shelf C and the movable shelf D. The open switch OS4 is attached to the front end of the movable shelf D on the right end side and is a selection switch for selecting the passage 4 between the movable shelf D and the movable shelf E. The open switch OS5 is provided on the movable shelf E. It is attached to the right end on the front side, and has a passage 5 between the movable shelf E and the fixed shelf F.
Is a selection switch for selecting.

The reset switch RS1, RS2, R
Of S3, RS4, RS5, RS1 and RS2 are attached to both ends in front of the movable shelf B, respectively.
1 is a reset switch for unlocking the formed passage 1, RS2 is a reset switch for unlocking the formed passage 2,
The reset switch RS3 is attached to the right end side on the front surface of the movable shelf C and is a reset switch for unlocking the formed passage 3. Further, the reset switch RS4 is attached to the right end side on the front surface of the movable shelf D, and is a reset switch for unlocking the formed passage 4, and a reset switch RS5.
Is attached to the right end of the front of the movable shelf E,
It is a reset switch for unlocking the formed passage 5.

The moving speed changeover switch CS is attached to the front of the movable shelf B substantially in the center thereof, and in the present embodiment, the moving speed of each of the movable shelves B, C, D and E is set low.
It is a changeover switch that can be appropriately selected and switched to three stages of medium speed and high speed. The moving speed changeover switch CS
May be attached to a shelf other than the movable shelf B, or may be attached to a side wall or the like in some cases.

On the back side of each of the movable shelves B, C, D, and E, in order to detect the reduction of the extra space (corresponding to the working passage) for each passage, to stop the movable shelves at a fixed position. Deceleration space detection switch BS1, BS2, BS3, BS4
BS5 is installed. Each of the deceleration space detection switches BS1, BS2, BS3, BS4, BS5 is composed of an inter-shelf space, that is, a space between adjacent shelves and a photoelectric switch for detecting a space decrease.

Each of the deceleration space detection switches BS1 and BS
Of 2, BS3, BS4, BS5, BS1 and BS2 are respectively attached to the left and right side surfaces of the back side of the movable shelf B, and the deceleration space detection switch BS1 on one side is of the fixed shelf A and the movable shelf B. Detection switch for detecting the space between and the reduction of space, deceleration space detection switch BS2 on the other side
Is a detection switch for detecting the space between the movable shelves B and C and the reduction of the space. The deceleration space detection switch BS3 is a detection switch that is attached to the right side surface on the back side of the movable shelf C and detects the space between the movable shelf C and the movable shelf D and the reduction of the space. Further, the deceleration space detection switch BS4 is a detection switch that is attached to the right side surface on the back side of the movable shelf D and detects the space between the movable shelf D and the movable shelf E and the reduction of the space. Further, the deceleration space detection switch BS5 is a detection switch which is attached to the right side surface on the back side of the movable shelf E and detects the space between the movable shelf E and the fixed shelf F and the reduction of the space.

The movable shelves B, C, C, D, E will be described in detail later on the back side of the movable shelves B, C, D, E, respectively.
Control devices CL1 and CL2 for controlling the movement of D and E
・ CL3 and CL4 are installed respectively and control device CL
1, CL2, CL3, CL4 are connected to each other via a transition cable Y arranged on the back surface of each shelf A to E, and the transition cable Y is connected to a power source via a fixed shelf A. Has been done.

FIG. 4 is a movement selection circuit diagram of the movable shelf in the device of the present invention. The movement command relay contact so, the intermediate stop relay contact sd, and the open switches OS1 to OS5.
Contacts c1 and c2 of the passage selection relay operated by the operation of
-C3, c4, c5, left traveling relays R1, R2, R3, R that are activated when moving the movable shelves B to E to the left
4, contacts r1, r2, r3 of the left traveling relays R1 to R3,
Right traveling relays F1, F2, F3, F4 and right traveling relays F2 that are activated when moving the movable shelves B to E to the right.
To contacts F2, f3, and f4 of F4 and contacts bs1, bs2, bs3, and bs of the deceleration space detection switches BS1 to BS5
4 ・ bs5, contacts rl1 ・ rl2 ・ of passage lock relay
It is composed of rl3, rl4, and rl5, and a diode D that allows a current to flow in only one direction. These circuits are used for the control devices CL1, CL2, CL3, CL4, which will be described later.
They are dispersed inside and are connected by a crossover cable Y.

FIG. 5 is a block diagram showing a main part of a control system in the device of the present invention, in which R, S, T are three-phase power terminals, and the control device CL1 of the movable shelf B is open. Switches OS1 and OS2, reset switch RS1
・ RS2, deceleration space detection switch BS1, BS2 operation signal or detection signal is input, and path selection relay C1
-C2 (not shown), passage lock relays RL1 and RL2
(Not shown), the function of selecting and locking the passages 1 and 2 controlled by the left traveling relay R1, the right traveling relay F1 and the like, the function of releasing the passage lock, the traveling direction of the movable shelf B and the operation and stop. And a control unit controlled by the movement command relay SO, the midway stop relay SD, and the like.

The control device CL2 of the movable shelf C receives the operation signal or the detection signal of the open switch OS3, the reset switch RS3 and the deceleration space detection switch BS3, and the passage selection relay C3 and the passage lock relay RL3.
(Both not shown), left traveling relay R2, right traveling relay F
It is configured to have a function of selecting and locking the aisle 3 controlled by 2 and the like, a function of unlocking the aisle, a traveling direction of the movable shelf C, a function of stopping, and the like.

The control device CL3 of the movable shelf D has the open switch OS4 and the reset switch R as in the above.
S4, the operation signal or the detection signal of the deceleration space detection switch BS4 is input, and the passage 4 controlled by the passage selection relay C4, the passage lock relay RL4 (both not shown), the left traveling relay R3, the right traveling relay F3, etc. The selection and lock function, the passage lock release function, the traveling direction of the movable shelf D, the operation, and the stop function are provided.

The control device CL4 of the movable shelf E has an open switch OS5 and a reset switch R as in the above.
S5, the operation signal or the detection signal of the deceleration space detection switch BS5 is input, and the passage 5 controlled by the passage selection relay C5, the passage lock relay RL5 (both not shown), the left traveling relay R4, the right traveling relay F5, etc. It is provided with a selection and lock function, a passage lock release function, a traveling direction of the movable shelf E and a function such as operation and stop.

Controllers CL1 to CL for the movable shelves B to E
4 are connected to each other, for example, the movable shelf B
When all the movable shelves of the to E or a plurality of adjacent movable shelves simultaneously move in the same direction, various information obtained by the control device of the movable shelf that moves the head, or the head moves. It also has a function of outputting various commands in accordance with various commands output by the control device for the movable shelf to the movable shelf which is in charge of itself. With this function, the movable shelves B to E are subordinately moved with a plurality of movable shelves,
Also, it is possible to stop at a fixed position at the same time while maintaining the slave state.

The inverter command control units CC1, CC2, CC3, CC4 of the movable shelves B to E respectively move the movable shelves B according to the operation of selecting the moving speed of the moving speed changeover switch CS.
The moving speed is set to one of three stages of low speed, medium speed, and high speed for each E, and the inverters IV1, IV2, IV3, and IV, which will be described later, together with the commands from the control devices CL1 to CL4.
Command 4

The inverter IV1 of the movable shelf B operates according to the commands of the controller CL1 and the inverter command control unit CC1 of the movable shelf B, and the reversible motor M1 of the movable shelf B operates according to the commands of the various functions. It has a function to control. The inverter IV1 is specifically a variable frequency power supply device for changing the speed of the reversible motor M1, and for use in the device of the present invention, an operating frequency corresponding to each operation mode of low speed traveling, medium speed traveling and high speed traveling is provided. The slow stop function is configured according to the acceleration time (the rate of change that increases the frequency) that configures the slow start function at startup and each operation mode that decelerates and stops the deceleration travel distance from each operation mode. It has a function of setting a deceleration time that constitutes a halfway stop deceleration function of stopping a shelf being moved by a halfway deceleration time (a rate of change for reducing the frequency) and a halfway stop signal by a halfway stop means or the like.

The inverter IV2 of the movable shelf C operates according to the commands of the controller CL2 and the inverter command control unit CC2 of the movable shelf C, and the reversible motor M2 of the movable shelf C operates according to the commands of the various functions. Of the inverter IV1 and the other features are the same as those of the inverter IV1.

The inverter IV3 of the movable shelf D operates according to the commands of the control device CL3 and the inverter command controller CC3 of the movable shelf D, and the reversible motor M3 of the movable shelf D operates according to the commands of the various functions. Of the inverter IV1 and the other features are the same as those of the inverter IV1.

The inverter IV4 of the movable shelf E operates according to the commands of the controller CL4 and the inverter command control unit CC4 of the movable shelf E, and the reversible motor M4 of the movable shelf E operates according to the commands of the various functions. Of the inverter IV1 and the other features are the same as those of the inverter IV1.

FIG. 6 shows the inverters IV1 to IV4.
FIG. 4 is an input / output circuit diagram of the left traveling relay contacts r1 to r4, which are forward rotation instruction contacts, right traveling relay contacts f1 to f4, which are reverse rotation instruction contacts, and low speed instruction contacts sl related to the moving speed changeover switch CS, Medium speed command contact sm, low speed deceleration command contact dsl, medium speed deceleration command contact dsm, midway stop deceleration command contact sds, inverter control ground terminal G, inverter forward rotation command terminal I1, inverter reverse rotation related to the moving speed changeover switch CS Command terminal I2, inverter medium speed command terminal I3, inverter low speed command terminal I4, inverter deceleration command terminals I5, I6, three-phase power input terminal RS
T and output terminals U, V, for reversible motors M1 to M4
It is composed of W and.

In the input / output circuit diagram of each of the inverters IV1 to IV4, it is equivalent to a high speed command being issued when the low speed command contact sl and the medium speed command contact sm are open, and the low speed deceleration command contact dsl. When the medium speed deceleration command contact dsm is open, it is equivalent to a deceleration command at high speed being issued. Further, the operating frequency corresponding to each operating mode, and the set values of the acceleration time and the deceleration time at the time of startup are input in advance on the operation panel of the inverter or the like to set the function.

FIG. 7 is a front view showing the operation mode of the moving speed changeover switch CS. When the knob is set to the neutral position, the middle speed running is selected and the middle speed command contact sm is closed. Is selected to close the low speed command contact sl, and when turned to the right, high speed running is selected and the medium speed command contact sm is selected.
And the low speed command contact sl is opened, and the inverter I
V1 to IV4 are configured to detect high speed running.

FIG. 8 is a diagram showing specific examples of operation patterns for low speed traveling, medium speed traveling, and high speed traveling. The movable shelves for which low speed traveling has been selected by the traveling speed changeover switch CS and movement has been commanded, After the acceleration start UP is continued for a predetermined time by the slow start function, the low speed travel SL is maintained when the low speed travel speed VL is reached, and then the low speed deceleration travel DL is performed when the deceleration travel distance LB is detected. It moves according to the driving pattern of stopping at a fixed position. On the other hand, the movable rack, which has been selected to move at a medium speed and has been instructed to move, continues acceleration traveling UP for a predetermined time by the slow start function, and then moves at a medium speed VM higher than the low speed moving speed VL.
The vehicle moves in accordance with an operation pattern in which the medium speed traveling SM is maintained at the time point, and the medium speed deceleration traveling DM is then performed at the time point when the deceleration traveling distance LB is detected and the vehicle stops at a fixed position. On the other hand, the movable shelf selected for high-speed traveling and instructed to move reaches a high-speed moving speed VH higher than the medium-speed moving speed VM after continuing the accelerated running UP for a predetermined time by the slow start function. The vehicle moves in accordance with an operation pattern in which the high-speed traveling SH is maintained, and thereafter, the high-speed deceleration traveling DH is performed when the deceleration traveling distance LB is detected and the vehicle is stopped at a fixed position. The deceleration travel distance LB is the distance from the position where the deceleration space detection switch detects the decrease of the extra space to the stop of the shelf at the fixed position.

When the safety bar device (not shown) is activated during the low speed travel SL or when the midway stop signal due to the operation of the midway stop means is detected, the low speed midway stop deceleration travel SDL having a large braking force is performed. To stop and drive at medium speed S
When the midway stop signal is detected during M as described above, the midway midway stop deceleration traveling SDM with large braking force is performed to stop, and when the midway stop signal is detected during high speed traveling SH as described above. , High-speed stop with a large braking force, deceleration SD
Although H is performed to stop, these controls are controls equivalent to the operation control at the time of an arbitrary stop operation performed by a predetermined operation.

FIG. 9 is a flowchart for low speed running in the device of the present invention. This is a flowchart for forming the path 4 by running at low speed from the state where the inter-shelf path 1 shown in FIGS. 1 to 3 is open. Yes, it will be described with reference to the circuit diagrams shown in FIGS.

First, the power source is turned on, the moving speed switching switch CS shown in FIGS. 2 and 7 is set to a low speed (low speed running) in advance (step 21), and then the open switch O shown in FIG.
When S4 is operated (step 22), the control devices CL1, CL2, CL3 of the control system in the device of the present invention shown in FIG.
Is activated and the passage selection relay C4 operates in the movement selection circuit diagram shown in FIG. 4 (step 23) and the movement command relay SO operates (step 24), the deceleration space detection switch BS1 moves the fixed shelf A and the movable shelf. The space between B and B is detected (step 25), and the left traveling relays R1, R2, R3 operate (step 26). In this state, when the moving speed changeover switch CS is set to low speed running, the inverter command control units CC1, CC2, CC3 of the control system in the device of the present invention shown in FIG. 5 operate to output a low speed command (step 27). As a result, in the input / output circuit diagram of the inverters IV1, IV2, and IV3 shown in FIG. 6, the forward rotation command input is performed and the contacts r1, r2, r3 of the left traveling relay are closed, and the low speed command input is performed, and the low speed command contacts s.
1 is closed (step 28). As a result, the reversible motors M1, M2, M3 start low speed acceleration forward rotation (step 29), and the movable shelves B, C, D start low speed acceleration left travel UP in the operation pattern shown in FIG. 8 (step 3).
0).

After that, when the moving speed of each of the movable shelves B, C, D reaches the moving speed VL (operating frequency of low speed traveling) in the operation pattern shown in FIG. 8, the reversible motors M1, M2 ,.
M3 maintains a low speed constant forward rotation (step 3
1) Each of the movable shelves B, C, D maintains the low speed constant left traveling SL (step 32). Then, when the deceleration space detection switch BS1 detects the decrease in the space between the fixed shelf A and the movable shelf B and detects the deceleration start position (step 33),
In the movement selection circuit diagram shown in FIG. 4, the left traveling relay R1.
R2 and R3 are restored (step 34), and the inverter command control units CC1, CC2 and CC3 output a low speed deceleration command (step 35). Inverter IV1 · I of FIG.
In the V2 / IV3 input / output circuit diagram, a stop command is input and the contacts r1, r2, r3 of the left traveling relay are opened, and
The low speed deceleration command is input and the low speed deceleration command contact dsl is closed (step 36). Thereby, the reversible motor M1
・ M2 and M3 start low speed deceleration forward rotation (Step 3
7), each of the movable shelves B, C, D starts the low speed deceleration left traveling DL in the operation pattern shown in FIG. 8 (step 3).
8). When the vehicle travels the decelerated travel distance LB and reaches the home position, the reversible motors M1, M2, M3 stop (step 39), and the movable shelves B, C, D stop at the left home position (step 40). ..

When each of the movable shelves B, C, D is stopped, the passage lock function of the control device CL4 of the control system in the device of the present invention shown in FIG. 5 is activated, and the passage selection circuit diagram shown in FIG. When the lock relay RL4 operates to open the contact rl4, the movable shelves D and E forming the inter-shelf passage 4 are locked (step 41), and the passage selection relay C4 is restored (step 42). S
O returns (step 43). In this state the movable shelf D
When the cargo handling work is performed in the inter-shelf passage 4 formed between E (step 44), and after the cargo handling work is finished (step 45), the reset switch RS4 is operated (step 46), the present invention shown in FIG. The release function of the passage lock of the control device CL3 of the control system in the device is activated, the passage lock relay RL4 is restored (step 47), and the control device CL3 is restored (step 48). This makes it possible to form the next passage.

FIG. 10 is a flow chart of the medium speed running in the device of the present invention. This is a flow chart in the case where the inter-shelf aisle 4 is open and the middle speed running is performed to form the aisle 2, and FIGS. This will be described with reference to the circuit diagram shown in FIG.

First, the power source is turned on, and the moving speed switching switch CS shown in FIGS. 2 and 7 is set to the medium speed (medium speed running) in advance (step 51), and then the open switch O shown in FIG.
When S2 is operated (step 52), the control devices CL1, CL2, CL3 of the control system in the device of the present invention shown in FIG.
4 operates and the passage selection relay C2 operates in the movement selection circuit diagram shown in FIG. 4 (step 53) and the movement command relay SO operates (step 54), the deceleration space detection switch BS4 moves between the movable shelves D and E. Is detected (step 55), and the right traveling relays F2 and F3 are operated (step 56). In this state, if the medium speed running is set, the inverter command control units CC2 and CC3 of the control system in the device of the present invention shown in FIG. 5 operate to output the medium speed command (step 57). As a result, in the input / output circuit diagram of the inverters IV2 and IV3 shown in FIG. 6, a reverse rotation command is input and the contacts f2 and f3 of the right traveling relay are closed, and
The medium speed command is input and the medium speed command contact sm is closed (step 58). As a result, the reversible motors M2 and M3 start middle speed acceleration reverse rotation (step 59), and each movable shelf C.
D is the middle speed acceleration right running U in the operation pattern shown in FIG.
Start P (step 60).

Thereafter, the moving speeds of the movable shelves C and D are shown in FIG.
When the moving speed VM (operating frequency for medium-speed traveling) that is higher than the moving speed VL in the operation pattern shown in Fig. 6 is reached, the reversible motors M2 and M3 maintain the state of constant reverse rotation at medium speed (step 61), and each movable rack. C and D are constant middle speed right running S
Maintain M (step 62). Then, when the deceleration space detection switch BS4 detects the decrease in the space between the movable shelves D and the movable shelves E and detects the deceleration start position (step 63), the right traveling relay in the movement selection circuit diagram shown in FIG. F2 and F3 are restored (step 64), and the inverter command control units CC2 and CC3 output the medium speed deceleration command (step 65). In the input / output circuit of the inverters IV2 and IV3 shown in FIG. 6, a stop command is input to open the contacts f2 and f3 of the right traveling relay, and a middle speed deceleration command is input to close the middle speed deceleration command contact dsm (step 6).
6). As a result, the reversible motors M2 and M3 start deceleration and reverse rotation at medium speed (step 67), and the movable shelves C and D are moved to the positions shown in FIG.
The middle speed deceleration right running DM in the operation pattern shown in (4) is started (step 68). When the vehicle travels the decelerated travel distance LB and reaches the fixed position, the reversible motors M2 and M3 stop (step 69), and the movable shelves C and D stop at the right fixed position (step 70).

When the movable shelves C and D are stopped, the control device C of the control system in the device of the present invention shown in FIG.
The passage lock function of L1 operates, and the passage lock relay RL2 operates in the movement selection circuit diagram shown in FIG.
Movable shelf B in which passage 2 between shelves is formed by opening l2
C is locked (step 71), the path selection relay C2 is restored (step 72), and the movement command relay SO
Returns (step 73). Movable shelves B and C in this state
When the cargo handling work is performed in the inter-shelf passage 2 formed between them (step 74) and after the cargo handling work is finished (step 75), the reset switch RS2 is operated (step 76), the device of the present invention shown in FIG. The release function of the passage lock of the control device CL1 of the control system is activated, the passage lock relay RL2 is restored (step 77), and the control device CL1 is restored (step 78). This makes it possible to form the next passage.

FIG. 11 is a flow chart of high-speed traveling in the device of the present invention, which is a flow chart in the case where the inter-shelf passage 2 is opened and the high-speed traveling forms the passage 5. FIGS. The description will be made with reference to the circuit diagram shown in FIG.

First, the power source is turned on, and the moving speed switching switch CS shown in FIGS. 2 and 7 is set to a high speed (high speed running) in advance (step 81), and then the open switch O shown in FIG.
When S5 is operated (step 82), the control devices CL1 to CL4 of the control system in the device of the present invention shown in FIG. 5 are activated, and the passage selection relay C5 is operated in the movement selection circuit diagram shown in FIG. 4 (step 83). , Movement command relay SO
Is operated (step 84), the deceleration space detection switch BS2 detects the space between the movable shelves B and C (step 8).
5) The left traveling relays R2, R3 and R4 operate (step 86). In this state, if high speed running is set, the inverter command control units CC2, CC3, CC4 of the control system in the device of the present invention shown in FIG. 5 operate to output a high speed command (step 87). As a result, in the input / output circuit diagram of the inverters IV2, IV3, and IV4 shown in FIG. 6, the forward rotation command is input and the contacts r2 and r of the left traveling relay are input.
When 3 · r4 is closed, a high speed command is input to open the low speed command contact sl and the medium speed command contact sm (step 88). As a result, the reversible motors M2, M3, and M4 start high-speed acceleration forward rotation (step 89), and each movable shelf C.
D and E start high-speed acceleration left traveling UP in the operation pattern shown in FIG. 8 (step 90).

After that, when the moving speeds of the movable shelves C, D, and E reach the moving speed VH (operating frequency of high-speed traveling), which is the highest speed in the operation pattern shown in FIG. 8, the reversible motors M2, M3, M4 are activated. The high-speed constant forward rotation state is maintained (step 91), and the movable shelves C, D, E maintain the high-speed constant left traveling SH (step 92). Then, when the deceleration space detection switch BS2 detects the decrease of the space between the movable shelves B and C and detects the deceleration start position (step 9).
3) In the movement selection circuit diagram shown in FIG. 4, the left travel relays R2, R3, R4 are restored (step 94), and the inverter command control units CC2, CC3, CC4 output a high speed deceleration command (step 95). Inverter IV of FIG.
In the input / output circuit diagram of 2 · IV3 · IV4, the stop command input is made to open the contacts r2, r3, r4 of the left traveling relay, and the high speed deceleration command input is made to make the low speed deceleration command contact d.
sl and the medium speed deceleration command contact dsm are opened (step 9
6). As a result, the reversible motors M2, M3, M4 start high speed deceleration forward rotation (step 97), and the movable shelves C, D are moved.
E starts high speed deceleration leftward travel DH in the operation pattern shown in FIG. 8 (step 98). When the vehicle travels the deceleration travel distance LB and reaches a fixed position, the reversible motor M2.
M3 and M4 stop (step 99), and each movable shelf C and D
-E stops at the left home position (step 100).

When each of the movable shelves C, D, E is stopped, the passage lock function of the control device CL4 of the control system in the device of the present invention shown in FIG. 5 is activated, and the passage selection circuit diagram shown in FIG. By operating the lock relay RL5 to open the contact rl5, the movable shelf E forming the inter-shelf passage 5 is locked (step 101), and the passage selection relay C5 is restored (step 102), and the movement command relay S is moved.
O returns (step 103). Movable shelf E in this state
When the cargo handling work is performed in the inter-shelf passage 5 formed between the fixed rack F and the fixed shelf F (step 104), and after the cargo handling work is finished (step 105), the reset switch RS5 is operated (step 106), the result shown in FIG. The passage lock release function of the control device CL4 of the control system in the device of the present invention shown below operates and the passage lock relay RL5 returns (step 10).
7) Then, the control device CL4 returns (step 108).
This makes it possible to form the next passage.

FIG. 12 is a flow chart for forming a plurality of passages in the apparatus of the present invention. This is an intermediate stopping means (reset switch operation during movement) while the passage 1 is divided from the open state of the inter-shelf passage 5. Is a flowchart of high-speed traveling / medium-speed traveling when the shelf is stopped at an intermediate position and the passage 3 on the side having the remaining space is divided and formed by the operation of
The description will be made with reference to the circuit diagrams shown in FIGS.

First, the power is turned on, the moving speed switching switch CS shown in FIGS. 2 and 7 is set to a high speed (high speed running) in advance (step 121), and then the open switch OS1 shown in FIG. 2 is operated ( Step 122), the control devices CL1 to CL4 of the control system in the device of the present invention shown in FIG. 5 operate, and the passage selection relay C1 operates in the movement selection circuit diagram shown in FIG. 4 (step 123) to move instruction relay SO. Is operated (step 124), the deceleration space detection switch BS5 detects the space between the movable shelf E and the fixed shelf F (step 125), and the right traveling relays F1, F2, F3.
-F4 operates (step 126). In this state, when the vehicle is set to high speed running, the inverter command control unit CC1 CC of the control system in the device of the present invention shown in FIG.
2.CC3 and CC4 operate to output a high speed command (step 127). As a result, the inverter IV shown in FIG.
In the input / output circuit diagram of 1, IV2, IV3, and IV4, the reverse rotation command is input, and the contact points f1, f2, and f3 of the right traveling relay are input.
When f4 is closed, a high speed command is input and the low speed command contact sl and the medium speed command contact sm are opened (step 1
28). As a result, reversible motors M1, M2, M3, M
4 starts high-speed acceleration reverse rotation (step 129), and each movable rack B, C, D, and E starts high-speed acceleration right running UP in the operation pattern shown in FIG. 8 (step 130).

After that, when the moving speeds of the movable shelves B, C, D, and E reach the moving speed VH (operating frequency of high-speed running), which is the highest speed in the operation pattern shown in FIG. 8, the reversible motors M1, M2 ,. M3 and M4 maintain the state of high speed constant reverse rotation (step 131), and moveable shelves B, C, D and E.
Keeps the high speed constant right running SH (step 132).
During this running, the reset switch RS1, RS2, R, which is also a means for stopping midway when the passage 1 opens about halfway
When any switch among S3, RS4, and RS5 is operated to perform an arbitrary halfway stop operation (step 133),
In the movement selection circuit diagram shown in FIG. 4, the intermediate stop relay SD
Operates (step 134), and the right traveling relays F1 and F2
F3 and F4 are restored (step 135), and the inverter command control units CC1, CC2, CC3, and CC4 output the intermediate stop deceleration command (step 136). In the input / output circuit diagram of the inverters IV1, IV2, IV3, and IV4 in FIG. 6, the stop command input is made and the contact f1 of the right traveling relay is input.
When f2, f3, and f4 are opened, the midway stop deceleration command input is made and the midway stop deceleration command contact sds operates (step 137). As a result, the reversible motor M1 ・ M
2. M3 and M4 start midway stop deceleration reverse rotation (step 138), and each movable shelf B, C, D, and E starts midway stop deceleration right running SDH in the operation pattern shown in FIG. 8 (step 139). ..

After a lapse of a small predetermined time, the reversible motors M1, M2, M3, M4 are stopped in accordance with the braking force (step 140), and the movable shelves B, C, D, E are stopped at midway positions. (Step 141). As a result, the inter-shelf passage 1
Are divided and formed, and cargo handling work is performed (step 14).
2). On the other hand, when the movable shelves B, C, D, and E stop, the passage lock function of the control device CL1 of the control system in the device of the present invention shown in FIG. 5 operates, the passage lock relay RL1 operates, and the movable shelves B move. It is locked (step 143), the path selection relay C1 is restored (step 144), the movement command relay SO is restored (step 145), and the midway stop relay SD is restored (step 146).

Next, for example, when the open switch OS3 is operated (step 147), the path selection relay C3 operates in the movement selection circuit diagram of FIG. 4 (step 14).
8) When the movement command relay SO operates (step 14
9) Then, the deceleration space detection switch BS5 detects the space between the movable shelf E and the fixed shelf F (step 150), and the right traveling relays F3 and F4 operate (step 151). In this state, the moving speed changeover switch C shown in FIGS.
When S is set to the medium speed running by a preselected operation when the open switch OS3 is operated (step 152), the inverter command control units CC3 and CC4 of the control system in the device of the present invention shown in FIG. It operates and outputs a medium speed command (step 153). As a result, in the input / output circuit diagram of the inverters IV3 and IV4 shown in FIG. 6, the reverse rotation command is input and the contacts f3 and f4 of the right traveling relay are input.
Is closed, the middle speed command is input and the middle speed command contact sm is closed (step 154). As a result, the reversible motors M3 and M4 start the medium speed acceleration reverse rotation (step 1
55), the movable shelves D and E start the middle speed acceleration right running UP in the operation pattern shown in FIG. 8 (step 156).

Thus, the predetermined time has elapsed, and the reversible motor M
3. M4 maintains constant reverse rotation at medium speed (step 15
7) After the movable shelves D and E maintain the middle speed constant right traveling SM in the operation pattern shown in FIG. 8 (step 158),
When the deceleration space detection switch BS5 detects a decrease between the movable shelf E and the fixed shelf F and detects the deceleration start position (step 159), the right traveling relays F3 and F4 in the movement selection circuit diagram shown in FIG. Return (step 160).
At this stage, the inverter command control unit CC3 / CC4 outputs a medium speed deceleration command (step 161), and in the input / output circuit diagram of the inverters IV3 / IV4 shown in FIG. 6, a stop command is input to contact the right running relay contact f3. When f4 opens, the middle speed deceleration command input is made and the middle speed deceleration command contact ds
m is closed (step 162).

Then, the contacts f3 and f of the right traveling relay
When 4 opens and the middle speed deceleration command contact dsm closes,
The reversible motors M3 and M4 do not perform middle speed deceleration reverse rotation (step 163), the movable shelves D and E do not perform middle speed deceleration right running DM (step 164), and further the deceleration running distance LB in the operation pattern shown in FIG. Reversible motor M3 when running
・ M4 stops driving (step 165) and the movable shelf D ・
E stops at the right home position (step 166). As a result, the inter-shelf passage 3 is divided and formed, and the cargo handling work is started here (step 167). On the other hand, reversible motor M3
When M4 stops, in the movement selection circuit diagram shown in FIG. 4, the aisle lock relay RL3 operates to lock the movable shelves C and D (step 168), and further the aisle selection relay C
3 is restored (step 169), and the movement command relay SO is restored (step 170).

After that, when the cargo handling work is completed in the inter-shelf aisle 1 (step 171) and the reset switch RS1 is operated (step 172), the aisle lock relay RL1 is restored in the movement selection circuit diagram shown in FIG. 4 ( In step 173), the passage formation selection of the inter-shelf passage 2 becomes possible (step 174). On the other hand, when the cargo handling work of the inter-shelf aisle 3 is completed (step 175) and the reset switch RS3 is operated (step 176), the aisle lock relay RL3 is restored in the movement selection circuit diagram shown in FIG. 4 (step 177). ), Which causes the control circuit to recover (step 178).

As described above with reference to the embodiments, according to the present invention, the operation pattern according to the application is selected from the three-step operation patterns of low speed traveling, medium speed traveling and high speed traveling by operating the moving speed changeover switch CS. It is a multi-stage speed operation type moving shelf device that moves the movable shelf and thus improves the safety of the articles in the shelf and the worker himself.The movable shelf can be arbitrarily moved to the midway position by operating the reset switch even during operation. It is possible to stop with the help of an emergency situation and not only enhance the safety, but also operate the reset switch to divide the aisle between shelves into multiple aisles according to the purpose of goods delivery work. It is also possible to select and use the moving speed according to the divided passage width, which is excellent in safety and workability. And the configuration for practical operation control by setting the operating frequency to determine the moving speed, repurposing, can be readily adapted to multi-purpose applications, it is to improve work efficiency.

Although not shown in the apparatus of the present invention,
It goes without saying that a movable bar surface facing the inter-shelf passage is provided with a safety bar device, an obstacle in the closed passage is detected, and the obstacle is promptly stopped at that time. Further, the same effect can be obtained by using a semiconductor circuit, a sequencer or the like instead of the circuit of this embodiment.

[0060]

According to the first aspect of the present invention, the moving speed of the movable shelf operated by the moving speed changeover switch is selectively set, and then the set moving speed is set while performing slow start via the inverter. Since it adopts a configuration to carry out the operation in, it is possible to appropriately set the operation pattern of the movable shelf that suits the intended use, improving the work efficiency of goods receipt and delivery work, as well as the goods in the shelf and the worker himself. Improves the safety of. According to the second aspect of the present invention, the configuration is such that the operation is performed at the set movement speed while performing the slow start via the inverter, the configuration is configured to stop the movable shelf during an emergency or during the movement, and one Since the work aisle space is divided into multiple shelves to form multiple aisles, a wide aisle width is required to use the cargo handling machine, or a narrow aisle width such as manual picking is required. It can also be applied to work modes where payments are made in multiple aisles at the same time, and it is possible to operate at a moving speed according to the intended use each time, improving the safety of the goods in the shelf and the worker himself. Workability and work efficiency of goods receipt and delivery work are further improved.

[Brief description of drawings]

FIG. 1 is a plan view showing the arrangement and appearance of shelves in the device of the present invention.

FIG. 2 is a front view showing the arrangement and appearance of shelves in the device of the present invention.

FIG. 3 is a rear view showing the arrangement and appearance of shelves in the device of the present invention.

FIG. 4 is a movement selection circuit diagram of a movable shelf in the device of the present invention.

FIG. 5 is a block diagram showing a main part of a control system in the device of the present invention.

FIG. 6 is an input / output circuit diagram of an inverter in the device of the present invention.

FIG. 7 is a front view showing an operation mode of a moving speed changeover switch in the device of the present invention.

FIG. 8 is an explanatory diagram showing specific examples of operation patterns of low speed traveling, medium speed traveling, and high speed traveling set in the device of the present invention.

FIG. 9 is a flowchart of low speed running in the device of the present invention.

FIG. 10 is a flowchart of medium speed running in the device of the present invention.

FIG. 11 is a flowchart of high-speed traveling in the device of the present invention.

FIG. 12 is a flowchart for forming a plurality of passages in the device of the present invention.

[Explanation of symbols]

A / F fixed shelf, B-E movable shelf, 1-5 passage between shelves, OS1-OS5 open switch, RS1
-RS5 reset switch, M1-M4 reversible motor, BS1-BS5 deceleration space detection switch, CS
Movement speed changeover switch, so Movement command relay contact, c1 to c5 Path selection relay contact, R1 to R
4 left traveling relay, r1 to r4 left traveling relay contact, F1 to F4 right traveling relay, f1 to f4 right traveling relay contact, bs1 to bs5 deceleration space detection switch contact, rl1 to rl5 passage lock relay contact, sd Midway stop relay contacts, CL1 to CL4
Control device of each movable shelf, CC1 to CC4 Inverter command control unit of each movable shelf, IV1 to IV4 Inverter of each movable shelf.

─────────────────────────────────────────────────── ───

[Procedure amendment]

[Submission date] December 11, 1992

[Procedure Amendment 1]

[Document name to be amended] Statement

[Correction target item name] 0011

[Correction method] Change

[Correction content]

[0011]

According to the present invention having the above-described structure, when a passage for receipt and delivery work is formed between desired shelves at the time of goods receipt and delivery, the moving speed of the movable shelf suitable for the application is operated by operating the moving speed changeover switch. After setting, the open switch which is the passage selecting means is operated to start the movement of the movable shelf so as to form the passage. At this time, the inverter activates the slow start function by the space detection signal of the deceleration space detection switch to gradually accelerate the movable shelf, and further moves the movable shelf to move one of the multi-speed operation according to the selection operation of the speed changeover switch. Drive at speed. After that, with the deceleration detection signal of the deceleration space detection switch that detects the passage width decrease as the movable shelf travels, the slow stop function is activated according to one moving speed of the multi-speed operation, and the movable shelf is gradually decelerated. , And stop at a fixed position. If a safety bar device (not shown) is activated during this period, or if the shelf is to be stopped urgently or to stop the shelf at will, by operating the reset switch , which is a stop means during movement, A stop signal is issued to activate the intermediate stop deceleration function to stop the movable shelf. Further, in the case where one passage is divided into a plurality of passages, a new passage is formed by operating the open switch for forming another passage on the remaining side of the passage space after arbitrarily stopping the passage. The side shelves are moved to form a plurality of work passages.

[Procedure Amendment 2]

[Document name to be amended] Statement

[Correction target item name] 0026

[Correction method] Change

[Correction content]

The control device CL4 of the movable shelf E has an open switch OS5 and a reset switch R as in the above.
S5, the input operation signal or the detection signal of the deceleration space detection switch BS5 is, the path selector relay C5, (both not shown) passage lock relay RL5, left travel relay R4, passage is controlled by the right traveling relay F 4, etc. 5 And the lock function, the passage lock release function, the traveling direction of the movable shelf E, the operation, and the stop function.

[Procedure 3]

[Document name to be amended] Statement

[Correction target item name] 0039

[Correction method] Change

[Correction content]

[0039] First, turn on the power, FIG. 2, is set in advance low speed (low speed) of the moving speed switching switch's CS shown in FIG. 7 (step 21), then an open switch OS4 shown in FIG. 2 When operated (step 22), the control devices CL1, CL2, CL of the control system in the device of the present invention shown in FIG.
3, the passage selection relay C4 operates in the movement selection circuit diagram shown in FIG. 4 (step 23), and the movement command relay SO operates (step 24), the deceleration space detection switch BS1 is movable with the fixed shelf A. The space between the rack and the shelf B is detected (step 25), and the left traveling relays R1, R2, R3 are detected.
Operates (step 26). In this state, if the moving speed changeover switch CS is set to low speed running,
The inverter command controller CC1, CC2, CC3 of the control system in the device of the present invention shown in FIG. 5 operates to output a low speed command (step 27). As a result, in the input / output circuit diagram of the inverters IV1, IV2, IV3 shown in FIG. 6, the forward rotation command is input and the contacts r1, r2, r3 of the left traveling relay are input.
Is closed, the low speed command is input and the low speed command contact sl is closed (step 28). As a result, the reversible motors M1, M2, M3 start low speed acceleration forward rotation (step 29), and the movable shelves B, C, D start low speed acceleration left travel UP in the operation pattern shown in FIG. 8 (step 3).
0).

[Procedure amendment 4]

[Document name to be amended] Statement

[Correction target item name] 0041

[Correction method] Change

[Correction content]

When each of the movable shelves B, C, D is stopped, the passage lock function of the control device CL 3 of the control system in the device of the present invention shown in FIG. 5 is activated, and in the movement selection circuit diagram shown in FIG. When the passage lock relay RL4 operates to open the contact point rl4, the movable shelves D and E forming the inter-shelf passage 4 are locked (step 41), and the passage selection relay C4 is restored (step 42), and a movement command is issued. Relay S
O returns (step 43). In this state the movable shelf D
When the cargo handling work is performed in the inter-shelf passage 4 formed between E (step 44), and after the cargo handling work is finished (step 45), the reset switch RS4 is operated (step 46), the present invention shown in FIG. The release function of the passage lock of the control device CL3 of the control system in the device is activated, the passage lock relay RL4 is restored (step 47), and the control device CL3 is restored (step 48). This makes it possible to form the next passage.

[Procedure Amendment 5]

[Document name to be amended] Statement

[Correction target item name] 0043

[Correction method] Change

[Correction content]

[0043] First, open switch power on the power, shown in FIG. 2, is set in advance the medium speed movement speed switching switch's CS shown in FIG. 7 (medium speed) (step 51), then 2 When the OS2 is operated (step 52), the control devices CL1, CL2, CL of the control system in the device of the present invention shown in FIG.
3 operates, the passage selection relay C2 operates in the movement selection circuit diagram shown in FIG. 4 (step 53), and the movement command relay SO operates (step 54), the deceleration space detection switch BS4 moves the movable shelves DE. The space between them is detected (step 55), and the right traveling relays F2 and F3 operate (step 56). In this state, if the medium speed running is set, the inverter command control units CC2 and CC3 of the control system in the device of the present invention shown in FIG. 5 operate to output the medium speed command (step 57). As a result, in the input / output circuit diagram of the inverters IV2 and IV3 shown in FIG. 6, a reverse rotation command input is made to close the contacts f2 and f3 of the right traveling relay, and a middle speed command input is made to close the middle speed command contact sm ( Step 58). As a result, reversible motors M2 and M3
Starts middle speed acceleration reverse rotation (step 59), and each movable rack C / D starts middle speed acceleration right running UP in the operation pattern shown in FIG. 8 (step 60).

[Procedure Amendment 6]

[Document name to be amended] Statement

[Correction target item name] 0047

[Correction method] Change

[Correction content]

[0047] First, turn on the power, FIG. 2, is set in advance high speed (high speed) the movement speed switching switch's CS shown in FIG. 7 (step 81), then open switch OS5 shown in FIG. 2 When operated (step 82), the control devices CL1 to CL4 of the control system in the device of the present invention shown in FIG. 5 are activated, and the passage selection relay C5 operates in the movement selection circuit diagram shown in FIG. 4 (step 83) to move. Command relay SO
Is operated (step 84), the deceleration space detection switch BS2 detects the space between the movable shelves B and C (step 8).
5) The left traveling relays R2, R3 and R4 operate (step 86). In this state, if high speed running is set, the inverter command control units CC2, CC3, CC4 of the control system in the device of the present invention shown in FIG. 5 operate to output a high speed command (step 87). As a result, in the input / output circuit diagram of the inverters IV2, IV3, and IV4 shown in FIG. 6, the forward rotation command is input and the contacts r2 and r of the left traveling relay are input.
With 3 · r4 is closed, while the I fast instruction input had slow command contacts sl and medium speed command contacts sm is opened is made
That (step 88). As a result, reversible motor M2 ・ M
3. M4 starts high-speed acceleration forward rotation (step 89),
Each of the movable shelves C, D, and E starts high-speed acceleration left traveling UP in the operation pattern shown in FIG. 8 (step 90).

[Procedure Amendment 7]

[Document name to be amended] Statement

[Correction target item name] 0048

[Correction method] Change

[Correction content]

After that, when the moving speeds of the movable shelves C, D, and E reach the moving speed VH (operating frequency of high-speed traveling), which is the highest speed in the operation pattern shown in FIG. 8, the reversible motors M2, M3, M4 are activated. The high-speed constant forward rotation state is maintained (step 91), and the movable shelves C, D, E maintain the high-speed constant left traveling SH (step 92). Then, when the deceleration space detection switch BS2 detects the decrease of the space between the movable shelves B and C and detects the deceleration start position (step 9).
3) In the movement selection circuit diagram shown in FIG. 4, the left travel relays R2, R3, R4 are restored (step 94), and the inverter command control units CC2, CC3, CC4 output a high speed deceleration command (step 95). Inverter IV of FIG.
In the input / output circuit diagram of 2 · IV3 · IV4, the stop command input is made to open the contacts r2, r3, r4 of the left traveling relay, and the high speed deceleration command input is made to make the low speed deceleration command contact d.
remains had sl and medium speed deceleration command contact dsm is open (step 96). As a result, reversible motors M2 and M3
M4 starts high speed deceleration forward rotation (step 97), and each movable shelf C, D, E starts high speed deceleration left running DH in the operation pattern shown in FIG. 8 (step 98). When the vehicle travels the deceleration travel distance LB and reaches a fixed position, the reversible motors M2, M3, M4 are stopped (step 99),
Each of the movable shelves C, D, and E stops at the home position (step 1
00).

[Procedure Amendment 8]

[Document name to be amended] Statement

[Correction target item name] 0051

[Correction method] Change

[Correction content]

[0051] First, turn on the power, FIG. 2, is set in advance high speed (high speed) the movement speed switching switch's CS shown in FIG. 7 (step 121), then an open switch OS1 illustrated in FIG. 2 When operated (step 122), the control devices CL1 to CL4 of the control system in the device of the present invention shown in FIG. 5 are activated, and the passage selection relay C1 operates in the movement selection circuit diagram shown in FIG. 4 (step 123) to move. When the command relay SO operates (step 124), the deceleration space detection switch BS5 detects the space between the movable shelf E and the fixed shelf F (step 125), and the right traveling relays F1, F2, F
3. F4 operates (step 126). In this state, when the high speed running is set, the inverter command control unit CC1C of the control system in the device of the present invention shown in FIG.
C2, CC3 and CC4 operate to output a high speed command (step 127). As a result, in the input / output circuit diagram of the inverters IV1, IV2, IV3, and IV4 shown in FIG. 6, the reverse rotation command is input, and the contacts f1, f2 ,.
with f3 · f4 is closed, and remains fast instruction input had slow command contacts sl and medium speed command contacts sm is opened is made
Made (step 128). Thereby, the reversible motor M1
M2, M3, M4 start high speed acceleration reverse rotation (step 129), and each movable rack B, C, D, E starts high speed acceleration right running UP in the operation pattern shown in FIG. 8 (step 130).

[Procedure Amendment 9]

[Document name to be amended] Statement

[Correction target item name] 0052

[Correction method] Change

[Correction content]

After that, the moving speed of each movable shelf B, C, D, E
The speed is the fastest in the operation pattern shown in FIG.
Reversible when the dynamic speed VH (operating frequency for high-speed running) is reached
Motors M1, M2, M3, M4 are in high speed constant reverse rotation
(Step 131), each movable shelf B ・ C ・ D ・ E
Keeps the high speed constant right running SH (step 132).
During this run, when passage 1 opens about halfway,
Reset switch RS1, RS2, R which is also a stopping means
Operate any one of S3, RS4, RS5
And then perform any midway stop operationEmit a stop signal on the way
(Step 133), in the movement selection circuit diagram shown in FIG.
And the intermediate stop relay SD operates (step 134), right
The traveling relays F1, F2, F3, F4 are restored (step
135), the inverter command control unit CC1, CC2,
CC3 and CC4 output a halfway stop deceleration command (step
136). Inverter IV1, IV2, IV3 of FIG.
・ In the input / output circuit diagram of IV4, a stop command is input and
When the contacts f1, f2, f3, f4 of the running relay open
To the intermediate stop deceleration command
The contact sds operates (step 137). By this
The reversible motors M1, M2, M3 and M4 stop halfway and decelerate
Reverse rotation is started (step 138), and each movable shelf B / C /
D and E are midway stop deceleration in the operation pattern shown in FIG.
The right running SDH is started (step 139).

[Procedure amendment]

[Submission date] March 15, 1993

[Procedure Amendment 1]

[Document name to be amended] Statement

[Correction target item name] 0038

[Correction method] Change

[Correction content]

FIGS. 9 and 10 are flowcharts of low-speed traveling in the device of the present invention. This is for forming the passage 4 by low-speed traveling from the state where the inter-shelf passage 1 shown in FIGS. 1 to 3 is open. FIG. 4 is a flowchart of FIG. 4 and will be described with reference to the circuit diagrams shown in FIGS.

[Procedure Amendment 2]

[Document name to be amended] Statement

[Correction target item name] 0042

[Correction method] Change

[Correction content]

FIGS. 11 and 12 are flowcharts of medium-speed running in the device of the present invention, which are flowcharts in the case where the inter-shelf aisle 4 is opened and the intermediate-speed running is performed to form the aisle 2. The description will be made with reference to the circuit diagrams shown in FIGS.

[Procedure 3]

[Document name to be amended] Statement

[Correction target item name] 0046

[Correction method] Change

[Correction content]

FIGS. 13 and 14 are flow charts of high-speed traveling in the device of the present invention, which are flow charts when the high-speed traveling is performed to form the passage 5 from the state where the inter-shelf passage 2 is opened. This will be described with reference to the circuit diagrams shown in FIGS.

[Procedure amendment 4]

[Document name to be amended] Statement

[Correction target item name] 0050

[Correction method] Change

[Correction content]

FIGS. 15 to 17 are flow charts for forming a plurality of passages in the apparatus of the present invention . This is a state in which the inter-shelf passage 5 is open, the passage 1 is divided and formed, and the intermediate stop means (while moving) is being formed. 9 is a flowchart of high-speed traveling / medium-speed traveling when the shelf is stopped at an intermediate position by the operation of the reset switch and the passage 3 on the side having the remaining space is divided and formed, and the circuits shown in FIGS. The description will be given with reference to the drawings.

[Procedure Amendment 5]

[Document name to be amended] Statement

[Name of item to be corrected] Brief explanation of the drawing

[Correction method] Change

[Correction content]

[Brief description of drawings]

FIG. 1 is a plan view showing the arrangement and appearance of shelves in the device of the present invention.

FIG. 2 is a front view showing the arrangement and appearance of shelves in the device of the present invention.

FIG. 3 is a rear view showing the arrangement and appearance of shelves in the device of the present invention.

FIG. 4 is a movement selection circuit diagram of a movable shelf in the device of the present invention.

FIG. 5 is a block diagram showing a main part of a control system in the device of the present invention.

FIG. 6 is an input / output circuit diagram of an inverter in the device of the present invention.

FIG. 7 is a front view showing an operation mode of a moving speed changeover switch in the device of the present invention.

FIG. 8 is an explanatory diagram showing specific examples of operation patterns of low speed traveling, medium speed traveling, and high speed traveling set in the device of the present invention.

FIG. 9 is a flowchart of low speed running in the device of the present invention.

FIG. 10 is a flow chart for low speed running in the device of the present invention .
It is

FIG. 11 is a flowchart of medium-speed traveling in the device of the present invention .
It is

FIG. 12 is a flowchart of medium speed traveling in the device of the present invention .
It is

FIG. 13 is a flow chart for high-speed traveling in the device of the present invention.
It is

FIG. 14 is a flow chart for high-speed traveling in the device of the present invention.
It is

FIG. 15 is a flow chart for forming a plurality of passages in the device of the present invention.
It is a chart.

FIG. 16 is a flow chart for forming a plurality of passages in the device of the present invention.
It is a chart.

FIG. 17 is a flow chart for forming a plurality of passages in the device of the present invention.
It is a chart.

[Explanation of Codes] A / F fixed shelf, B to E movable shelf, 1 to 5 passage between shelves, OS1 to OS5 open switch, RS1
-RS5 reset switch, M1-M4 reversible motor, BS1-BS5 deceleration space detection switch, CS
Movement speed changeover switch, so Movement command relay contact, c1 to c5 Path selection relay contact, R1 to R
4 left traveling relay, r1 to r4 left traveling relay contact, F1 to F4 right traveling relay, f1 to f4 right traveling relay contact, bs1 to bs5 deceleration space detection switch contact, rl1 to rl5 passage lock relay contact, sd Midway stop relay contacts, CL1 to CL4
Control device of each movable shelf, CC1 to CC4 Inverter command control unit of each movable shelf, IV1 to IV4 Inverter of each movable shelf.

[Procedure Amendment 6]

[Document name to be corrected] Drawing

[Correction target item name] All drawings

[Correction method] Change

[Correction content]

[Figure 1]

[Fig. 2]

[Figure 3]

[Figure 4]

[Figure 6]

[Figure 7]

FIG. 14

[Figure 5]

[Figure 8]

[Figure 10]

[Figure 9]

FIG. 11

[Fig. 12]

[Fig. 13]

FIG. 15

FIG. 16

FIG. 17

Claims (2)

[Claims] 1. A plurality of movable shelves each provided with a reversible motor for traveling are arranged in a fixed shelf or a section divided by a side wall with a margin space corresponding to one working passage,
At the time of goods receipt and delivery, in the electric movable rack device configured to simultaneously move the plurality of movable shelves between the spare space and the desired passage by operating the passage selecting means of the desired passage, A moving speed changeover switch for switching to multi-speed operation, a deceleration space detection switch for detecting the reduction of the margin space for each passage, and stopping the movable shelf at a fixed position, and a switch for not operating when the reversible motor is started. An inverter for setting a slow start function for accelerating the gears, an operating frequency for traveling at a constant speed in each of the multi-speed operation, and a slow stop function corresponding to each of the multi-speed operation for continuously decelerating when stopped at the fixed position; And when the movable shelf moves to form the passage by operating the passage selecting means, the deceleration space corresponding to the spare space is provided. One of the multi-speed operation set by the moving speed changeover switch by simultaneously activating the reversible motors of the movable shelves to be moved by the space detection signal of the interval detection switch by the slow start function via the inverter. The multi-speed operation type characterized in that the vehicle travels at a constant speed with a deceleration detection signal from the deceleration space detection switch and is stopped at the fixed position by a slow stop function corresponding to one of the set multi-speed operations. Mobile shelf equipment. 2. A plurality of movable shelves, each having a reversible motor for traveling, are arranged in a fixed shelf or a section divided by a side wall with a margin space corresponding to at least one working passage, and when delivering and receiving articles. By operating the passage selecting means of the desired passage, the plurality of movable shelves between the spare space and the desired passage are moved at the same time, and the spare space is divided between the plurality of shelves to form a plurality of passages. In the electric movable shelf device that can be formed, a movable speed changeover switch that switches the moving speed of the movable shelf to a multi-speed operation, and a decrease in the extra space for each passage are detected to determine the movable shelf. A deceleration space detection switch for stopping at the position, a slow start function for continuously accelerating at the time of starting the reversible motor, and a driving cycle for running at a constant speed in each of the multi-speed driving Number, the slow stop function corresponding to each of the multi-stage speed operation in which the movable shelf that is moving is stopped at an intermediate position by operating the intermediate stop means, and continuously decelerated when stopped at the fixed position. When the movable shelf moves to form the passage by operating the passage selecting means, it should be moved by the space detection signal of the deceleration space detection switch corresponding to the spare space. The reversible motors of the movable shelves are simultaneously activated by the slow start function via the inverter, the vehicle travels at a constant speed in one of the multi-speed operations set by the moving speed changeover switch, and the deceleration space detection switch With the deceleration detection signal of, the slow stop function corresponding to one of the set multi-speed operations is used to stop at the fixed position, and A multi-speed operation type moving shelf device characterized in that it is stopped at an intermediate position by the intermediate stop deceleration function when several passages are formed.