JP6278424B2 - Forklift management device - Google Patents

Description

  The present invention relates to a forklift management device for performing a cargo handling operation by an operator's operation.

  In a forklift that performs a cargo handling operation by an operator's operation, a management device that detects the operation state of a forklift and calculates and stores the number of occurrences of a predetermined unsafe operation such as a sudden turn based on the detection result is known. (See Patent Document 1). In this management device, data on the number of occurrences of a predetermined unsafe operation such as a sudden turn operation in which the detected value of turning acceleration of the forklift is equal to or greater than a predetermined threshold is collected.

  In another forklift that performs a cargo handling operation by an operator's operation, a management device that detects the amount of a predetermined operation of the forklift as a level value that is an easy-to-understand index for management is known (see Patent Document 2). ). Since this level value is stored as a maximum level value for each unit time, important data effective for management can be efficiently collected.

  By the way, when an operator performs a cargo handling operation with a forklift, he / she often takes care to handle very important luggage. If it is possible to manage and analyze what kind of cargo handling work has an impact on the operator, it can be used to solve various problems related to cargo handling work, such as improving the operator's ability of cargo handling work. . However, the conventional forklift management device cannot manage and analyze the influence on the operator during the cargo handling operation.

Japanese Patent Laid-Open No. 2005-280992 JP 2008-56436 A

  Therefore, a problem to be solved by the present invention is to provide a forklift management device capable of managing and analyzing the influence on an operator during a cargo handling operation.

In order to solve the above problems, the present onset Ming,
A forklift management device that manages the influence on an operator during a cargo handling operation using a forklift,
A cargo handling operation detection unit for detecting the cargo handling operation of the forklift,
A biological information detector for detecting biological information of an operator who operates the forklift;
A time acquisition unit for acquiring time;
A collection unit for collecting information from the cargo handling operation detection unit, the biological information detection unit, and the time acquisition unit;
Based on the information collected in the collection unit, a display unit for displaying the value of biological information for each predetermined time and the type of cargo handling operation at the same time as the biological information in a predetermined table or graph, Prepare.

Preferably,
The cargo handling operation detector
A first detector for detecting turning of the forklift vehicle;
A second detector for detecting the advance and retreat of the forklift mast;
A third detector for detecting the lifting and lowering of the lift bracket of the forklift;
A fourth detector for detecting the loading and unloading of the forklift.

Preferably,
The display section
Display the value of biometric information and the type of cargo handling operation in a predetermined graph,
When a predetermined location in the graph is selected, the value of the biological information at the selected location and the type of cargo handling operation at the same time as the value of the biological information are displayed at a different location from the graph.

Preferably,
The display section
Display the value of biometric information and the type of cargo handling operation in a predetermined table,
When a predetermined location in the table is selected, the value of the biological information at the selected location and the type of cargo handling operation at the same time as the value of the biological information are displayed at a different location from the table.

  Since the forklift management device according to the present invention can acquire and display the biological information of the operator and the operation information of the forklift, based on these display information, manage and analyze the influence on the operator during cargo handling work, It can be used for solving various problems related to cargo handling work, such as improving the operator's ability of cargo handling work.

The forklift is shown, (A) is a plan view, (B) is a side view. The block diagram which shows the management apparatus of a forklift. The figure which shows the screen of the display part of 1st Embodiment. The figure which shows another screen of the display part of 1st Embodiment. The figure which shows the screen of the display part of 2nd Embodiment. The figure which shows another screen of the display part of 2nd Embodiment. The figure which shows the screen of the display part of 3rd Embodiment. The figure which shows another screen of the display part of 3rd Embodiment.

Hereinafter, an embodiment relating to a forklift management device according to the present invention will be described with reference to the drawings.
In addition, the front-rear direction X, the left-right direction Y, and the up-down direction Z of the vehicle body are each a right angle.

[forklift]
As shown in FIG. 1, a reach-type forklift 100 (hereinafter referred to as “forklift”) has a pair of masts 50 standing in front of the vehicle body 5. The masts 50 are arranged at intervals in the left-right direction Y of the vehicle body. The lift bracket 51 is supported so as to move up and down in the vertical direction Z of the vehicle body along the mast 50.

  The forklift 100 includes a pair of forks 52 for performing a cargo handling operation. The forks 52 are attached to the left and right of the lift bracket 51, and are arranged at intervals in the left-right direction Y of the vehicle body. Therefore, the fork 52 moves up and down together with the lift bracket 51.

  The forklift 100 includes a pair of straddle legs 53 at the front portion of the vehicle body 5. Each straddle leg 53 extends in the front-rear direction X of the vehicle body, and is arranged at intervals in the left-right direction Y of the vehicle body. The straddle leg 53 guides the mast 50 so as to advance and retreat in the longitudinal direction X of the vehicle body.

  The forklift 100 is provided with an operation space 55 at the rear of the vehicle body 5. A brake pedal 54 is provided in the lower part of the driving space 55, and the brake is applied and released when the operator operates the brake pedal 54 with his / her foot. The forklift 100 includes a head guard 58 that covers the top of the operating space 55 and protects the operator from falling objects.

  The forklift 100 includes a pair of front wheels 57 provided at the front portion of the straddle leg 53. Further, the forklift 100 includes a drive wheel 56 provided at the rear portion of the vehicle body 5. The forklift 100 moves the vehicle body 5 back and forth by the forward and reverse rotations of the drive wheel 56. Further, the forklift 100 turns at a predetermined angle with respect to the front-rear direction X and the left-right direction Y of the vehicle body by turning the front wheel 57 and the drive wheel 56.

  The driving space 55 is surrounded by side frames on the front side and the left and right sides of the driving space 55, and a boarding gate is formed on the rear side of the driving space 55. The forklift 100 includes an operation unit 60 in front of the operation space 55. The operation unit 60 includes a plurality of hydraulic levers 62, 63, 64, and the operator can operate the hydraulic levers 62, 63, 64 to raise, lower, tilt, and advance / retreat the fork 52.

  As the first hydraulic lever 62 tilts, the mast 50 moves forward and backward in the longitudinal direction X of the vehicle body. As the second hydraulic lever 63 tilts, the lift bracket 51 moves up and down in the vertical direction Z of the vehicle body. As the third hydraulic lever 64 tilts, the fork 52 tilts in the vertical direction Z of the vehicle body.

  The operation unit 60 includes a handle 61 and an accelerator 65 for operating the traveling direction of the vehicle body 5. By turning the handle 61, the vehicle body 5 turns at a predetermined angle with respect to the longitudinal direction X and the lateral direction Y of the vehicle body. By the tilting of the accelerator 65, the vehicle body 5 moves forward and backward at a predetermined speed.

[Management device]
As shown in FIG. 2, the forklift management device 101 includes a cargo handling operation detection unit 1 for detecting the cargo handling operation of the forklift 100. The cargo handling operation detection unit 1 includes a first detection unit 11, a second detection unit 12, a third detection unit 13, a fourth detection unit 14, and a fifth detection unit 15. The cargo handling operation detection unit 1 is provided in the forklift 100.

  The first detection unit 11 includes a potentiometer that detects the turning angle of the handle 61. The second detection unit 12 includes a potentiometer that detects the tilt angle of the first hydraulic lever 62. The third detection unit 13 includes a potentiometer that detects the tilt angle of the second hydraulic lever 63. The fourth detection unit 14 includes a pressure sensor that detects the pressure applied to the fork 52. The fifth detection unit 15 includes a GPS sensor that detects the position of the vehicle body 5.

  The first detector 11 recognizes “vehicle turning” by detecting a change in the turning angle of the handle 61. The second detection unit 12 recognizes “reach in” and “reach out” by detecting a change in the tilt angle of the first hydraulic lever 62. The third detection unit 13 recognizes “lift up” and “lift down” by detecting a change in the tilt angle of the second hydraulic lever 63. The fourth detection unit 14 recognizes “loading” and “loading” by detecting a change in pressure applied to the fork 52. The fifth detection unit 15 detects the position of the vehicle body 5 and recognizes “passage travel” and “inter-shelf travel” based on the position data and map data such as an automatic warehouse prepared in advance.

  “Vehicle turning” means turning of the vehicle body 5. “Reach-in” means the reverse travel of the mast 50 in the longitudinal direction X of the vehicle body. “Reach out” means forward movement of the mast 50 in the longitudinal direction X of the vehicle body. “Lift up” means the lift bracket 51 is raised in the vertical direction Z of the vehicle body. “Lift down” refers to the lowering of the lift bracket 51 in the vertical direction Z of the vehicle body. “Unloading” means lifting of a load by the fork 52. “Loading” means unloading of a load by the fork 52. “Aisle traveling” means traveling in a passage of an automatic warehouse or the like. “Traveling between shelves” means traveling between shelves of an automatic warehouse or the like.

  The forklift management device 101 includes a biological information detection unit 2 for detecting biological information of an operator who operates the forklift 100. In the present embodiment, the biological information is a pulse rate. In the present embodiment, the biological information detection unit 2 is composed of a wristwatch-type wearable terminal, and does not interfere with the driving operation of the operator even when worn by the operator.

  The forklift management device 101 includes a collection unit 3 for collecting information from the cargo handling operation detection unit 1 and the biological information detection unit 2. The collection unit 3 includes a time acquisition unit 30 for acquiring time. The collection unit 3 is configured by, for example, a memory device that stores information every predetermined time. The collection unit 3 collects information from the cargo handling operation detection unit 1 and the biological information detection unit 2 and information from the time acquisition unit 30 in association with time.

  The forklift management apparatus 101 includes a processing unit 6 for processing information and the like from the collection unit 3. The processing unit 6 includes, for example, a CPU (Central Processing Unit), an input / output interface, a ROM, a RAM, and the like, and stores a program for processing information. The processing unit 6 acquires and processes information sent from the collection unit 3.

  The forklift management device 101 includes a display unit 4 connected to the processing unit 6. The display unit 4 displays information processed by the processing unit 6. In the present embodiment, the display unit 4 is a touch panel portable information terminal configured integrally with the processing unit 6.

  The display unit 4 displays the value of biological information for each predetermined time and the type of cargo handling operation corresponding to the biological information at the same time. After the information collected by the collection unit 3 is processed by the processing unit 6, the display unit 4 displays the processed information.

[Display section screen of the first embodiment]
As shown in FIGS. 3 and 4, the display unit 4 of the first embodiment displays the value of the biological information for each predetermined time in a predetermined time interval on the screen as a line graph 40 based on the value of the biological information. In the line graph 40, the horizontal axis is time, and the vertical axis is the value of biological information. The display unit 4 displays the type of cargo handling operation on the screen in a time-series manner with the characters 41 below the line graph 40. The line graph 40 and the character 41 correspond to each other at the same time.

  When a predetermined location in the line graph 40 is selected (touched), the display unit 4 displays the value of the biological information at the selected (touched) location with the characters 42, the type of the cargo handling operation with the characters 43, and the time. It displays on the screen with the character 44.

  For example, as shown in FIG. 3, when the arrow portion of the line graph 40 is selected (touched), the character 42 is “pulse 83”, the character 43 is “work type 5th stage unloading”, and the character 44 is “ Time 10:26 ". Further, as shown in FIG. 4, when the arrow portion of the line graph 40 is selected (touched), the character 42 is “pulse 77”, the character 43 is “loading work type”, and the character 44 is “time 10: 32 ”.

[Screen of the display section of the second embodiment]
As shown in FIGS. 5 and 6, the display unit 4 of the second embodiment displays a line graph 40 and characters 41 of the type of cargo handling operation on the screen, as in the first embodiment. When a predetermined part in the line graph 40 is selected (touched), the display unit 4 displays the biometric information value at the selected (touched) part with the characters 42 and the type of the cargo handling operation on the screen in FIG. indicate.

  For example, as shown in FIG. 5, when the arrow portion of the line graph 40 is selected (touched), the character 42 is displayed as “pulse 83” and the illustration diagram 45 is displayed as a diagram representing that the cargo is being picked up. Further, as shown in FIG. 6, when the arrow portion of the line graph 40 is selected (touched), the character 42 is displayed as “pulse 77”, and the illustration diagram 45 is displayed as a diagram expressing loading.

[Screen of the display section of the third embodiment]
As shown in FIG. 7 and FIG. 8, the display unit 4 of the third embodiment displays the value of the biological information for each predetermined time in the predetermined time interval on the screen based on the value of the biological information. In the radiating bar graph 47, bar graphs are arranged radially from the center circle, and the length of the bar graph opposes the value of the biological information. Further, the display unit 4 displays a table 46 in a predetermined time interval on the screen. The table 46 is composed of a character string 46a for each predetermined time displayed in time series, a character string 46b for the value of biometric information, and a character string 46c for the type of cargo handling operation.

Further, as shown in FIG. 8, when a predetermined location in the radiant bar graph 47 is selected (touched), the display unit 4 uses the character 42 to indicate the value of the biological information at the selected (touched) location, and the type of cargo handling operation. Is displayed on the screen as characters 43 and time is displayed as characters 44.
For example, as shown in FIG. 8, when the arrow portion of the radiation bar graph 47 is selected (touched), the character 42 is “pulse 82”, the character 43 is “work type being unloaded”, and the character 44 is “time 10: 29 ".

As mentioned above, although preferable embodiment of this invention was described, the structure of this invention is not limited to these embodiment. For example,
The biological information may be a blood pressure value, a heart rate, or the like.
The display unit 4 may be a smartphone, a notebook computer, an in-vehicle display, or the like.
As a type of cargo handling operation, a tilt operation in which the fork 52 tilts in the vertical direction Z of the vehicle body may be added.
-You may add the high-speed driving | running | working and low-speed driving | running | working of the vehicle body 5 as a kind of cargo handling operation | movement.
-The magnitude | size of the center circle part of the radiation bar graph 47 may change according to a heart rate.
The time acquisition unit 30 may be provided in the cargo handling operation detection unit 1 and the biological information detection unit 2. In that case, the cargo handling operation detection unit 1 stores each cargo handling operation and each time, and the biological information detection unit 2 stores each biological information and each time, and sends them to the collection unit 3.
The collection unit 3 may be provided on the display unit 4.
The graph 40 and the table 46 can change a predetermined time interval to be displayed by scrolling (sliding) the display left and right or up and down.

The effects of the present invention are as follows.
The forklift management apparatus 101 according to the present invention can acquire and display the biological information of the operator and the operation information of the forklift. Based on the display information, the operator and the manager can manage and analyze the influence on the operator during the cargo handling work and can use it for solving various problems related to the cargo handling work. For example,
-The type of cargo handling operation with a high pulse rate can be extracted to know the cargo handling operation that the operator is not good at.
-It can be used to improve the ability of an operator's cargo handling work by an administrator instructing the operator for poor cargo handling work or an operator practicing poor cargo handling work.
-When the operator performs unsatisfactory cargo handling work, it is possible to alert the operator with music, voice, images, etc.

DESCRIPTION OF SYMBOLS 1 Handling operation detection part 2 Biological information detection part 3 Collection part 4 Display part 11 1st detection part 12 2nd detection part 13 3rd detection part 14 4th detection part 30 Time acquisition part 40 Graph 100 Forklift 101 Management apparatus

Claims (4)

A forklift management device that manages the influence on an operator during a cargo handling operation using a forklift,
A cargo handling operation detection unit for detecting the cargo handling operation of the forklift;
A biological information detector for detecting biological information of an operator who operates the forklift;
A time acquisition unit for acquiring time;
A collection unit for collecting information from the cargo handling operation detection unit, the biological information detection unit, and the time acquisition unit;
Based on the information collected in the collection unit, the value of the biological information for each predetermined time and the type of the cargo handling operation at the same time as the biological information are displayed in a predetermined table or graph A forklift management device comprising: a display unit; The cargo handling operation detector is
A first detector for detecting turning of the forklift vehicle;
A second detector for detecting the advance and retreat of the forklift mast;
A third detector for detecting the lifting and lowering of the lift bracket of the forklift;
The forklift management device according to claim 1, further comprising: a fourth detection unit for detecting loading and loading of the forklift. The display unit
A type of the cargo handling operation and the value of the biological information is displayed in the graph,
When a predetermined location in the graph is selected, the value of the biological information at the selected location and the type of the cargo handling operation at the same time as the value of the biological information are different from the graph. The forklift management device according to claim 1, wherein the forklift management device is displayed. The display unit
A type of value as the cargo handling operation of the biological information is displayed in the table,
When a predetermined location in the table is selected, the value of the biological information at the selected location and the type of the cargo handling operation at the same time as the value of the biological information are different from the table. The forklift management device according to claim 1, wherein the forklift management device is displayed.