JP7075866B2 - Management system and management program - Google Patents

Description

The present invention relates to a management system and a management program.

Conventionally, aerial work platforms used for working in high places have been known (see, for example, Patent Document 1). In this aerial work platform, generally, a predetermined number is assigned to each work place, and the predetermined number of aerial work platforms are reserved in the work place.

JP-A-2017-226528

By the way, the inventor of the present application aims to detect that a single sensor (for example, an aerial work platform is running) in the aerial work platform for the purpose of efficiently operating the aerial work platform. A sensor, etc.) is provided, and the operating rate of the aerial work platform is calculated based on a single item (for example, whether or not the aerial work platform is running) that is the detection result of the sensor. I came up with the idea of using it as information for managing the operating status of the aerial work platform.

However, in the method of calculating the operating rate based on a single item which is the detection result of a single sensor, it is not possible to assume various usage states of the aerial work platform, and the accuracy of the calculated operating rate is lowered. This could reduce its usefulness as information for managing the operating status of aerial work platforms.

The present invention has been made in view of the above facts, and an object of the present invention is to provide a management system and a management program capable of calculating useful operation management information.

The management system according to claim 1 is a management system for managing a target device provided with a moving means for moving the moving target in the height direction in order to solve the above-mentioned problems and achieve the object. The acquisition means for acquiring the first information based on the time related to the movement of the moving means in the height direction, the second information based on the time related to the operation of the target device, and the first information acquired by the acquiring means. The acquisition means includes a calculation means for calculating the mutual ratio with the second information as operation management information for managing the operation status of the target device, and the acquisition means is the power-on time of the target device or the power-on time of the target device. Information that identifies either one of the off-time is acquired as the second information, and the acquisition means obtains the time when the moving means is stopped upward, the time when the moving means is moved in the height direction, and the said. Information for specifying the total time of the traveled time of the target device is acquired as the first information.

The management system according to claim 2 is a management system that manages a target device including a moving means for moving a moving target in the height direction, and is based on the time related to the movement of the moving means in the height direction. The target is the ratio between the acquisition means for acquiring the first information and the second information based on the time related to the operation of the target device, and the first information and the second information acquired by the acquisition means. The acquisition means includes a calculation means for calculating as operation management information for managing the operation status of the device, and the acquisition means acquires information for specifying a time reserved for the target device as the second information.

The management system according to claim 3 is the management system according to claim 2, wherein the acquisition means acquires information for specifying the time when the moving means has stopped upward as the first information.

The management system according to claim 4 is the management system according to claim 2, wherein the acquisition means acquires the time when the moving means moves in the height direction as the first information.

The management system according to claim 5 is the management system according to claim 2, wherein the acquisition means is a time when the moving means is stopped upward, a time when the moving means is moved in the height direction, and the above-mentioned. Information for specifying the total time traveled by the target device is acquired as the first information.

The management system according to claim 6 is a management system that manages a target device including a moving means for moving a moving target in the height direction, and is based on the time related to the movement of the moving means in the height direction. The target is the ratio between the acquisition means for acquiring the first information and the second information based on the time related to the operation of the target device, and the first information and the second information acquired by the acquisition means. The acquisition means includes a calculation means for calculating as operation management information for managing the operation status of the device, and the acquisition means acquires information for specifying the time when the moving means has stopped upward as the first information. Information that specifies the time that the target device has traveled is acquired as the second information.

The management system according to claim 7 is a management system that manages a target device including a moving means for moving a moving target in the height direction, and is based on the time related to the movement of the moving means in the height direction. The target is the ratio between the acquisition means for acquiring the first information and the second information based on the time related to the operation of the target device, and the first information and the second information acquired by the acquisition means. The acquisition means includes a calculation means for calculating as operation management information for managing the operation status of the device, and the acquisition means is information based on the product of the time when the moving means is stopped upward and the height at which the moving means is stopped. Is acquired as the first information, and information based on the product of the time when the target device is used and the upper limit height of the moving means is acquired as the second information.

The management system according to claim 8 is a management system that manages a target device including a moving means for moving a moving target in the height direction, and is based on the time related to the movement of the moving means in the height direction. The target is the ratio between the acquisition means for acquiring the first information and the second information based on the time related to the operation of the target device, and the first information and the second information acquired by the acquisition means. The acquisition means includes a calculation means for calculating as operation management information for managing the operation status of the device, and the acquisition means acquires information for specifying the time when the moving means exceeds the threshold height as the first information. Then, the information for specifying the time when the target device is used is acquired as the second information.

The management system according to claim 9 includes a first output means for outputting the ratio calculated by the calculation means in the management system according to any one of claims 1 to 8.

The management system according to claim 10 generates recommended information regarding the operation of the target device based on the ratio calculated by the calculation means in the management system according to any one of claims 1 to 9. A second output means for outputting the generated recommended information is provided.

The management system according to claim 11 is the management system according to any one of claims 1 to 10, wherein a plurality of the target devices exist, and the acquisition means is the first item for each of the plurality of target devices. The first information and the second information are acquired, the calculation means calculates the ratio between the first information and the second information for each of the plurality of target devices, and the management system calculates the calculation. A management means for managing the plurality of target devices based on the ratio of each of the plurality of target devices calculated by the means is provided.

The management program according to claim 12 is a management program for managing a target device including a moving means for moving a moving target in the height direction, and the computer is related to the movement of the moving means in the height direction. The ratio between the acquisition means for acquiring the time-based first information and the time-based second information regarding the operation of the target device, and the first information and the second information acquired by the acquisition means. , Information for specifying either the on-time or the off-time of the power supply of the target device, which functions as a calculation means for calculating as operation management information for managing the operation status of the target device. Is acquired as the second information, and the acquisition means obtains the total time of the time when the moving means stopped upward, the time when the moving means moved in the height direction, and the time when the target device traveled. The information to be specified is acquired as the first information.

The management program according to claim 13 is a management program for managing a target device including a moving means for moving a moving target in the height direction, and the computer is related to the movement of the moving means in the height direction. The ratio between the acquisition means for acquiring the time-based first information and the time-based second information regarding the operation of the target device, and the first information and the second information acquired by the acquisition means. , The second information, which functions as a calculation means for calculating as operation management information for managing the operation status of the target device, and the acquisition means specifies information for specifying a time reserved for the target device. Get as.

The management program according to claim 14 is a management program for managing a target device including a moving means for moving a moving target in the height direction, and the computer is related to the movement of the moving means in the height direction. The ratio between the acquisition means for acquiring the time-based first information and the time-based second information regarding the operation of the target device, and the first information and the second information acquired by the acquisition means. The first information includes information for specifying the time when the moving means is stopped upward, which functions as a calculation means for calculating as operation management information for managing the operation status of the target device. And the information that specifies the time that the target device has traveled is acquired as the second information.

The management program according to claim 15 is a management program for managing a target device including a moving means for moving a moving target in the height direction, and the computer is related to the movement of the moving means in the height direction. The ratio between the acquisition means for acquiring the time-based first information and the time-based second information regarding the operation of the target device, and the first information and the second information acquired by the acquisition means. The acquisition means functions as a calculation means for calculating as operation management information for managing the operation status of the target device, and the acquisition means has a time when the moving means is stopped upward and a height at which the moving means is stopped. The information based on the product is acquired as the first information, and the information based on the product of the time when the target device is used and the upper limit height of the moving means is acquired as the second information.
The management program according to claim 16 is a management program for managing a target device including a moving means for moving a moving target in the height direction, and the computer is related to the movement of the moving means in the height direction. The ratio between the acquisition means for acquiring the time-based first information and the time-based second information regarding the operation of the target device, and the first information and the second information acquired by the acquisition means. The acquisition means functions as a calculation means for calculating as operation management information for managing the operation status of the target device, and the acquisition means obtains information for specifying a time when the moving means exceeds a threshold height. The information acquired as one information and specifying the time when the target device is used is acquired as the second information.

According to the management system according to claim 1 and the management program according to claim 12, the ratio between the acquired first information and the second information is controlled by the operation for managing the operation status of the target device. By calculating as information, for example, operation management information can be calculated based on two types of information, so that useful operation management information can be calculated. Further, for example, since the first information based on the time related to the movement of the moving means in the height direction is used for the calculation of the operation management information, the relationship with the work performed by using the target device provided with the moving means. Information with a relatively high degree of sex can be reflected, and the usefulness of operation management information can be improved. Further, for example, by calculating the ratio between the first information and the second information as the operation management information, the operation status of the target device can be intuitively grasped, so that the usefulness of the operation management information can be improved. It is possible to further improve.
Further, by acquiring information for specifying either the power on time or the off time of the target device as the second information, for example, the use or non-use of the target device such as the power on time or the off time of the target device. Since the time-based information directly related to the operation management information can be reflected in the operation management information, the usefulness of the operation management information can be improved.
Further, for example, by acquiring information for specifying the total time of the time when the moving means has stopped upward, the time when the moving means has moved in the height direction, and the time when the target device has traveled as the first information, for example, the total time. And, since the ratio of the power on time or the off time of the target device is calculated as the operation management information, the actual work time and the incidental work performed before the actual work (for example, the target device is run to the work place). Since the time during which the work of moving the target device or the work of moving the moving means of the target device is performed upward or downward can be reflected in the operation management information, the usefulness of the operation management information can be improved. It will be possible. In particular, for example, since it is possible to grasp the length between the total time of the actual work time and the incidental work time and the power on time or the power off time, for example, even if the transportation means is stopped downward. Regardless, the power of the target device may be unnecessarily turned on for a long time (that is, the so-called idling operation time may be long), or the power of the target device may be long. It is possible to raise the user's awareness of the efficient operation of the target device by understanding that the time when is turned off may be extremely longer than the above-mentioned total time. ..

According to the management system according to claim 2 and the management program according to claim 13, the operation management for managing the operation status of the target device is based on the mutual ratio between the acquired first information and the second information. By calculating as information, for example, operation management information can be calculated based on two types of information, so that useful operation management information can be calculated. Further, for example, since the first information based on the time related to the movement of the moving means in the height direction is used for the calculation of the operation management information, the relationship with the work performed by using the target device provided with the moving means. Information with a relatively high degree of sex can be reflected, and the usefulness of operation management information can be improved. Further, for example, by calculating the ratio between the first information and the second information as the operation management information, the operation status of the target device can be intuitively grasped, so that the usefulness of the operation management information can be improved. It is possible to further improve.
Further, by acquiring the information for specifying the time when the target device is reserved as the second information, for example, other than the specific user (that is, the user who reserved the target device) such as the time when the target device is reserved. Since the information based on the time when the use of is prohibited can be reflected in the operation management information, it is possible to improve the usefulness of the operation management information.

According to the management system according to claim 3, by acquiring the information specifying the time when the moving means is stopped upward as the first information, for example, the time when the moving means is stopped upward and the target device are reserved. Since the ratio to the time is calculated as the operation management information, the actual work time can be reflected in the operation management information, so that the usefulness of the operation management information can be improved. In particular, for example, since it is possible to grasp the length between the actual work time and the time when the target device is reserved, for example, the target device is reserved even though the actual work is not performed. It is possible to raise the user's awareness of the efficient operation of the target device by understanding that the time spent may be long.

According to the management system according to claim 4, by acquiring the time when the moving means moves in the height direction as the first information, for example, the time when the moving means moves in the height direction and the target device reserve the time. Since the ratio to the time is calculated as the operation management information, the time during the incidental work of moving the moving means of the target device upward or downward can be reflected in the operation management information. It is possible to improve the usefulness of. In particular, for example, since it is possible to grasp the mutual length between the time during which the incidental work of moving the moving means of the target device is performed upward or downward and the time when the target device is reserved, for example, for example. There is a possibility that the target device is reserved for a long time even though the target device is used for a short time, or the work of running the target device and moving it to the work place. It is possible to raise the user's awareness of the efficient operation of the target device by understanding that there is a possibility that the operation is central.

According to the management system according to claim 5, the first information is information for specifying the total time of the time when the moving means has stopped upward, the time when the moving means has moved in the height direction, and the time when the target device has traveled. By acquiring as, for example, the ratio of the total time to the time reserved for the target device is calculated as the operation management information, so that the actual work time and the incidental work performed before the actual work (for example, the target device) The operation management information can be reflected in the operation management information because the time during which the operation is performed (such as the operation of moving the target device to the work place or the operation of moving the moving means of the target device upward or downward) can be reflected in the operation management information. It is possible to improve the usefulness of. In particular, for example, since it is possible to grasp the mutual length between the actual work time and the incidental work time and the time when the target device is reserved, for example, even though the means of transportation is stopped downward. It is possible to raise the user's awareness of the efficient operation of the target device by understanding that the target device may be reserved for a long time in vain.

According to the management system according to claim 6 and the management program according to claim 14, the ratio between the acquired first information and the second information is controlled by the operation for managing the operation status of the target device. By calculating as information, for example, operation management information can be calculated based on two types of information, so that useful operation management information can be calculated. Further, for example, since the first information based on the time related to the movement of the moving means in the height direction is used for the calculation of the operation management information, the relationship with the work performed by using the target device provided with the moving means. Information with a relatively high degree of sex can be reflected, and the usefulness of operation management information can be improved. Further, for example, by calculating the ratio between the first information and the second information as the operation management information, the operation status of the target device can be intuitively grasped, so that the usefulness of the operation management information can be improved. It is possible to further improve.
Further, by acquiring the information for specifying the time when the moving means has stopped upward as the first information and the information for specifying the time when the target device has traveled as the second information, for example, the moving means is moving upward. Since the ratio between the stopped time and the time that the target device has traveled is calculated as operation management information, the actual work time and the incidental work time that causes the target device to travel and move to the work location are reflected in the operation management information. Therefore, it is possible to improve the usefulness of the operation management information. In particular, for example, since it is possible to grasp the length between the actual work time and the incidental work time for moving the target device to the work place, for example, at a position relatively far from the work place. It is possible to grasp that the target device provided may be used by the user.

According to the management system according to claim 7 and the management program according to claim 15, the operation management for managing the operation status of the target device is based on the mutual ratio between the acquired first information and the second information. By calculating as information, for example, operation management information can be calculated based on two types of information, so that useful operation management information can be calculated. Further, for example, since the first information based on the time related to the movement of the moving means in the height direction is used for the calculation of the operation management information, the relationship with the work performed by using the target device provided with the moving means. Information with a relatively high degree of sex can be reflected, and the usefulness of operation management information can be improved. Further, for example, by calculating the ratio between the first information and the second information as the operation management information, the operation status of the target device can be intuitively grasped, so that the usefulness of the operation management information can be improved. It is possible to further improve.
Further, the information based on the product of the time when the moving means is stopped above and the stopped height of the moving means is acquired as the first information, and the information based on the product of the time when the target device is used and the upper limit height of the moving means is obtained. Is obtained as the second information, for example, the product of the information based on the product of the time when the moving means is stopped above and the stopped height of the moving means, the time when the target device is used, and the upper limit height of the moving means. Since the ratio with the information based on the above is calculated as the operation management information, the information on the stopped height of the moving means and the information on the upper limit height of the moving means can be reflected in the operation management information. It is possible to improve the usefulness of. In particular, for example, it is possible to grasp how much the target device has the ability regarding the height of the transportation means.

According to the management system according to claim 8 and the management program according to claim 16, the ratio between the acquired first information and the second information is controlled by the operation for managing the operation status of the target device. By calculating as information, for example, operation management information can be calculated based on two types of information, so that useful operation management information can be calculated. Further, for example, since the first information based on the time related to the movement of the moving means in the height direction is used for the calculation of the operation management information, the relationship with the work performed by using the target device provided with the moving means. Information with a relatively high degree of sex can be reflected, and the usefulness of operation management information can be improved. Further, for example, by calculating the ratio between the first information and the second information as the operation management information, the operation status of the target device can be intuitively grasped, so that the usefulness of the operation management information can be improved. It is possible to further improve.
Further, by acquiring the information for specifying the time when the moving means exceeds the threshold height as the first information and the information for specifying the time when the target device is used as the second information, for example, the moving means can be used. Since the ratio of the time when the threshold height is exceeded and the time when the target device is used is calculated as the operation management information, the time when the moving means exceeds the threshold height can be reflected in the operation management information. It is possible to improve the usefulness of management information. In particular, for each aerial work platform which is an example of the target device, the upper limit height of the moving means may be set to 4 m, 6 m, etc. as an example. In this case, the threshold height is set as the target device. It cannot be exceeded by the aerial work platform lower than the aerial work platform (the aerial work platform whose upper limit height is set lower), and it cannot be exceeded by the aerial work platform which is the target device. When the height at which the work can be performed is set as the threshold height, whether or not the aerial work platform, which is the target device, is performing work that cannot be replaced by the lower aerial work platform, or the time during which the work is being performed. It is possible to grasp the long and short.

According to the management system according to claim 9, by outputting the ratio calculated by the calculation means, for example, it is possible to notify the operation management information for managing the operation status of the target device.

According to the management system according to claim 10, by generating recommended information regarding the operation of the target device and outputting the generated recommended information, for example, recommended items (that is, so-called recommendations) regarding the operation of the target device can be obtained. It becomes possible to notify.

According to the management system according to claim 11, by managing the plurality of target devices based on the ratio of each of the plurality of target devices calculated by the calculation means, for example, the target devices can be used efficiently. It becomes possible.

It is a figure which shows the aerial work platform and the terminal apparatus which concerns on this embodiment. It is a block diagram which shows the aerial work platform and the terminal device functionally conceptually. It is a figure which illustrates the vehicle side state information. It is a graph which shows the state of the work floor of the aerial work platform. It is a figure which illustrates vehicle information. It is a figure which illustrates the terminal side state information. It is a flowchart of operation management information output processing. It is a figure for demonstrating the 1st integrated value.

Hereinafter, embodiments of the management system according to the present invention will be described in detail with reference to the accompanying drawings. First, [I] the basic concept of the embodiment will be described, then [II] the specific contents of the embodiment will be described, and finally, [III] a modification to the embodiment will be described. However, the present invention is not limited to the embodiments.

[I] Basic concept of the embodiment First, the basic concept of the embodiment will be described. The embodiment relates to a management system and a management program. The management system according to the present invention is a system for managing a target device provided with a moving means for moving the moving target in the height direction, for example, a dedicated system for managing the target device, or a general-purpose system. It is a concept including a system realized by implementing a function for managing a target device on a computer (for example, a mobile terminal or a terminal such as a server, a personal computer, a smartphone, etc.). Further, the management system includes, for example, an acquisition means and a calculation means, and optionally includes a first output means, a second output means, and a management means.

The "target device" is a device whose operating status is managed by a management system, specifically, a device provided with a means of transportation, for example, an aerial work platform, a forklift, a rough terrain crawler, and a tower crane. , And an elevator, etc. It should be noted that the aerial work platform and the like here are merely examples, and the “target device” may be interpreted as a concept including various mechanical and electrical equipment other than these examples. Further, the "operating status" is a status in which the target device is operating, and is a concept including, for example, a status in which the operating status of the target device can be specified.

Further, the "moving means" is a means for moving the moving object in the height direction, and is a concept including, for example, a floor (including a work floor) on which the moving object is placed, a fork, a hook, and the like. Further, the "moving object" is an object or a person who can be moved in the height direction by a means of transportation, and is a concept including, for example, materials and equipment used at a construction site, a worker, and the like. Further, the "height direction" is a concept corresponding to, for example, a vertical direction or a vertical direction.

Further, the "acquisition means" is a means for acquiring the first information based on the time related to the movement of the moving means in the height direction and the second information based on the time related to the operation of the target device.

Further, the "first information" is information based on the time related to the movement of the moving means in the height direction, for example, the moving means upper stop time, the total time, the moving means moving time, the first integrated value, or the moving means. It is a concept including information for specifying at least one of the stop times exceeding the upper threshold. Further, the "second information" is information based on the time related to the operation of the target device, for example, the vehicle power on time, the vehicle power off time, the vehicle reservation time, the vehicle running time, the second integrated value, or the vehicle use. A concept that includes information that identifies at least one of time.

Further, the "moving means upward stop time" is, for example, a time during which the moving means has stopped upward, and as an example, it is a concept including a time during which the moving means has continued to stop upward in the height direction. The concept of "stopped time" is, for example, a concept expressing the length of time, and as an example, a concept corresponding to a stopped time or the like.

Further, the "total time" is, for example, a time obtained by totaling (adding) the moving means upward stop time, the moving means moving time described later, and the vehicle traveling time described later.

Further, the "moving means moving time" is, for example, the time when the moving means moves in the height direction, for example, the time when the moving means continues to move from the lower side to the upper side, and the moving means from the upper side to the lower side. It is a concept that includes the time of continuous movement, or the total time of each of these times. The concept of "moved time" is the same as the above-mentioned "stopped time". For example, it is a concept expressing the length of time, and as an example, it corresponds to the time spent moving. It is a concept.

Further, the "first integrated value" is, for example, a value based on the product of the moving means upper stop time and the moving means stop height, and is, for example, a concept including a value corresponding to an integrated value based on each of these pieces of information. Is. The "moving means stop height" is a concept including, for example, the height of the moving means when the moving means stops upward.

Further, the "moving means upper threshold exceeding stop time" is, for example, the time when the moving means is moved to a position higher than the threshold value and stopped, and is the time when the moving means exceeds the threshold value. It is a concept including the time that the moving means has been stopped while being moved to a position above the threshold value. The concept of "time exceeded" is the same as the above-mentioned "time stopped", for example, a concept expressing the length of time, and as an example, a concept corresponding to the time exceeded. Is.

Further, the "vehicle power on time" is, for example, the time when the power of the target device is turned on, and for example, is a concept including the time when the power is continuously turned on. Further, the "vehicle power off time" is, for example, a time when the power of the target device is turned off, and for example, is a concept including a time when the power is continuously turned off.

Further, the "vehicle reservation time" is, for example, the time when the target device is reserved. The target device may be operated so as to make a reservation and use it, for example, but the "vehicle reservation time" here is, for example, a specific case of being operated in this way. It is a concept including the time when the target device is continuously reserved by the user.

Further, the "vehicle traveling time" is, for example, the time during which the target device has traveled, and as an example, it is a concept including the time during which the target device has continued to move in the horizontal direction. The concept of "running time" is the same as the above-mentioned "stopping time", for example, it is a concept expressing the length of time, and as an example, it corresponds to the running time and the like. It is a concept.

Further, the "second integrated value" is, for example, a value based on the product of the vehicle usage time and the upper limit height of the transportation means, and is a concept including, for example, a value corresponding to the integrated value based on each of these pieces of information. .. The "vehicle usage time" is, for example, the time during which the target device is used, and as an example, is a concept including the total time of the moving means upward stop time and the moving means moving time. Further, the "upper limit height of the moving means" is, for example, the maximum height at which the moving means can move, and as an example, it is a concept including a height determined based on the specifications and the like of each target device.

Further, the "calculation means" is a means for calculating the mutual ratio between the first information and the second information acquired by the acquisition means as operation management information for managing the operation status of the target device. The "operation management information" is information for managing the operation status of the target device, and is a concept including, for example, information that can specify the state in which the target device is operated.

Further, the "first output means" is a means for outputting the ratio calculated by the calculation means. Note that "output" includes, for example, display output on a display or the like, audio output on a speaker or the like, transmission output by a communication function, paper output from a printer or the like, and the like. It is a concept.

Further, the "second output means" is a means for generating recommended information regarding the operation of the target device based on the ratio calculated by the calculation means and outputting the generated recommended information. The "recommended information" is information recommended to the user regarding the operation of the target device, and is a concept including information for achieving an arbitrary purpose such as efficient operation of the target device, for example.

Further, the "management means" is a means for managing a plurality of target devices based on the ratio of each of the plurality of target devices calculated by the calculation means, and is, for example, a target device to be used for a user or the said. The concept includes means for guiding the position of the device, means for moving the target device to an arbitrary position (for example, a collection site or the current position of the user), and the like.

Then, in the embodiment shown below, a case where the "target device" is an aerial work platform and the "management system" is realized by a mobile terminal will be described as an example.

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

(Constitution)
First, the aerial work platform and the terminal device according to the present embodiment will be described. FIG. 1 is a diagram showing an aerial work platform and a terminal device according to the present embodiment, and FIG. 2 is a block diagram showing a functional concept of the aerial work platform and the terminal device. It should be noted that the aerial work platforms 1 of FIGS. 1 and 2 are configured in the same manner as in the prior art except for special matters, and the description and illustration thereof will be omitted as appropriate. Further, as shown in FIG. 1, the aerial work platforms 1 will be described separately from the aerial work platforms 101 and 102 when it is necessary to distinguish them from each other, and when it is not necessary to distinguish them from each other, the aerial work platforms 1 will be described separately. It will be generically referred to as aerial work platform 1.

(Composition-Aerial work platform)
The aerial work platform 1 of FIG. 1 is a target device, and includes, for example, a work floor 10, a communication unit 11 of FIG. 2, a recording unit 12, and a control unit 13.

(Structure-Aerial work platform-Work floor)
The work floor 10 in FIG. 1 is a means of transportation. The specific configuration of the work floor 10 is arbitrary, but for example, it moves upward or downward in the height direction with workers and materials to be moved placed on it. The movement of the work floor 10 is controlled by the control unit 13 in the same manner as in the conventional case, and is performed by using a known movement mechanism.

(Structure-Aerial work platform-Communication department)
The communication unit 11 in FIG. 2 is a communication means for communicating with an external device (for example, a terminal device 2 or the like). The specific type and configuration of the communication unit 11 is arbitrary, but it can be configured by using, for example, a known wireless communication circuit or the like.

(Structure-Aerial work platform-Recording section)
The recording unit 12 of FIG. 2 is a recording means for recording a program and various data necessary for the operation of the aerial work platform 1, and is configured by using, for example, a hard disk (not shown) as an external recording device. .. However, instead of or in combination with the hard disk, any other recording medium, including a magnetic recording medium such as a magnetic disk or an optical recording medium such as a DVD or Blu-ray disc, can be used (recording on other devices). The part shall be configured in the same way). The recording unit 12 generally includes a vehicle-side state information database 121 (hereinafter, the database is referred to as "DB").

(Structure-Aerial work platform-Recording unit-Vehicle side status information DB)
The vehicle-side state information DB 121 is a vehicle-side state information storage means for storing vehicle-side state information. The "vehicle-side state information" is information for specifying the state of the aerial work platform 1, for example, information stored in the aerial work platform 1. FIG. 3 is a diagram illustrating vehicle side state information. In FIG. 3, some information is omitted and described as "..." for convenience (the same applies to other drawings). As shown in FIG. 3, the vehicle side state information includes the item "time information", the item "power supply information", the item "vehicle traveling information", and the item "moving means movement information", and the information corresponding to each item. Are interrelated.

The information corresponding to the item "time information" is time information that specifies the time (in FIG. 3, the date and time (that is, 9:00 on October 1, 2018, etc.) are specified). For convenience of explanation, it is described as "t111", "t112", etc.). Further, the information corresponding to the item "power supply information" is the power supply information for specifying the state of the power supply of the aerial work platform 1 (in FIG. 3, "ON" for specifying the state when the power is turned on, or the power supply is "OFF" to specify the state by being turned off). Further, the information corresponding to the item "vehicle traveling information" is vehicle traveling information that specifies the traveling state of the aerial work platform 1 (in FIG. 3, it is specified that the aerial work platform 1 is traveling). "Running" or "stopping" to identify that the aerial work platform 1 is stopped). Further, the information corresponding to the item "moving means moving information" is the moving means moving information for specifying the moving state of the work floor 10 which is the moving means of the aerial work platform 1. This moving means movement information is arbitrary, but in FIG. 3, for example, a “downward stop” that specifies a state in which the work floor 10 of the aerial work platform 1 is stopped at the lower limit is stopped above the lower limit. "Upward stop" that specifies the state of being in the state and "moving" that specifies the state of moving from the lower part to the upper part or from the upper part to the lower part are stored. Further, in particular, regarding the "downward stop" and "upward stop" in FIG. 3, information for specifying the respective states and the height of the work floor 10 from the ground when stopped (for example, the height is 0). It is stored in association with "0.9" etc.) that specifies 0.9m. The "lower limit" is the lowest height at which the work floor 10 can be lowered, and is defined by the specifications of the aerial work platform 1, but is, for example, 0.9 m. Regarding "downward stop: 0.9" in FIG. 3, it is specified that the work floor 10 is stopped at the lower limit and the height of the work floor 10 is 0.9 m. "Upward stop: 2.5" specifies that the work floor 10 is stopped above the lower limit and the height of the work floor 10 is 2.5 m.

The "power supply of the aerial work platform 1" here is a power supply that is turned on when the user starts using the aerial work platform 1 and is turned off when the user ends the use, and is mainly high. It is assumed that it is a power source for supplying electric power used when the aerial work platform 1 is driven or the work floor 10 is raised and lowered. As for the aerial work platform 1, in order to constantly record the vehicle side state information, electric power is supplied to some elements of the aerial work platform 1 regardless of whether the power is turned on or off, and the aerial work platform 1 is high. It is assumed that processing other than the operation of moving the aerial work platform 1 and raising and lowering the work floor 10 can be performed at all times.

The specific storage method of such vehicle-side state information is arbitrary, but for example, a known non-illustrated state acquisition means for acquiring information of each item (for example, the current date and time) is used. A timing unit to identify (including, for example, a device or element realized by a known technique such as a timer), a power supply detector that detects whether the power is on or off (for example, by a known technique such as a current meter). The device or element to be realized), the traveling detection unit to detect whether the vehicle is running (for example, the device or element realized by a known technique such as a rotary encoder), and the work floor 10 are moved. A movement detector that detects whether it is inside or stopped (including, for example, a device or element realized by a known technique such as a potential meter), and an altitude detector that detects the height of the work floor 10 (eg,). , A pressure gauge, a laser distance meter, and other devices or elements realized by known techniques) shall be provided in the high-altitude work vehicle 1, and the control unit 13 shall be provided at predetermined time intervals (for example, from 1 second to 1 second). Information is acquired from this state acquisition means every 10 seconds, etc.), and each information is stored based on the acquired information.

FIG. 4 is a graph showing the state of the work floor of the aerial work platform. A specific example of a method for storing vehicle-side state information will be described with reference to the graph of FIG. 4 as appropriate. Here, for example, although not shown in FIG. 4, the control unit 13 acquires the date and time corresponding to “t111” from the timekeeping unit, and “the power is off” from the power supply detection unit. Is acquired, "stopped" is acquired from the travel detection unit, "stopped" is acquired from the movement detection unit, and "0.9m" is acquired from the altitude detection unit. When acquired, each information corresponding to "time information" = "111" in FIG. 3 is recorded. Then, after that, the user turns on the power of the aerial work platform 1 and runs the vehicle, then raises or lowers the work floor 10 as shown in FIG. 4, and then causes the aerial work platform 1 to run. When the power is turned off later, the control unit 13 will record each information shown in FIG.

(Structure-Aerial work platform-Control unit)
The control unit 13 in FIG. 2 is a control means for controlling the aerial work platform 1. Specifically, the CPU, various programs that are interpreted and executed on the CPU (including basic control programs such as the OS and application programs that are started on the OS and realize specific functions), programs, and various data are stored. It is a computer configured with an internal memory such as a RAM for storing (the control units of other devices are also configured in the same manner).

(Configuration-Terminal device)
The terminal device 2 of FIG. 1 is a management system, specifically a mobile terminal, and includes, for example, a communication unit 21, a touch pad 22, a display 23, a recording unit 24, and a control unit 25 of FIG.

(Configuration-Terminal device)
The communication unit 21 in FIG. 2 is a communication means for communicating with an external device (for example, an aerial work platform 1 or the like). The specific type and configuration of the communication unit 21 is arbitrary, but it can be configured in the same manner as the communication unit 11 of the aerial work platform 1, for example.

(Configuration-Terminal device-Touchpad)
The touch pad 22 of FIG. 2 is an operation means for receiving various operation inputs from the user by being pressed by a user's finger or the like. The specific type and configuration of the touch pad 22 is arbitrary, but for example, a known one provided with an operation position detecting means by a resistance film method, a capacitance method, or the like can be used.

(Configuration-Terminal device-Display)
The display 23 in FIG. 2 is a display means for displaying various images. The specific type and configuration of the display 23 are arbitrary, but for example, a flat panel display such as a known liquid crystal display or an organic EL display can be used. The touch pad 22 and the display 23 may be integrally formed as a touch panel.

(Configuration-Terminal device-Recording unit)
The recording unit 24 of FIG. 2 generally includes a vehicle information DB 241 and a terminal side state information DB 242.

(Configuration-Terminal device-Recording unit-Vehicle information DB)
The vehicle information DB 241 of FIG. 2 is a vehicle information storage means for storing vehicle information. The "vehicle information" is information that identifies the aerial work platform 1. FIG. 5 is a diagram illustrating vehicle information. As shown in FIG. 5, in the vehicle information, the item "vehicle ID", the item "movement means upper limit height information", the item "threshold information", and the information corresponding to each item are associated with each other. ..

The information corresponding to the item "vehicle ID" is identification information (identification information is referred to as "ID") that uniquely identifies the aerial work platform 1. This vehicle ID is arbitrary, but for example, it is assumed that the vehicle IDs "IDv101" and "IDv102" are set (recorded) in each of the recording units 12 of the aerial work platforms 101 and 102 in FIG. In FIG. 5, these "IDv101" and "IDv102" are recorded. The information corresponding to the item "moving means upper limit height information" is the moving means upper limit height information for specifying the above-mentioned moving means upper limit height, and more specifically, the maximum height at which the work floor 10 can be moved (ascended). Information for specifying the floor (in FIG. 5, "4" for specifying 4m, "6" for specifying 6m, "9" for specifying 9m, etc., which are not shown). The item "threshold information" is threshold information for specifying a threshold. This threshold information is arbitrary, but as a reference for determining an arbitrary event including, for example, whether or not the ability regarding the movable height of the work floor 10 of the aerial work platform 1 is fully utilized. Information is recorded. In detail, the threshold information is determined by, for example, the maximum height at which the work floor 10 can be moved by the specifications of the aerial work platform 1, but focusing on one aerial work platform 1, it is lower. The aerial work platform 1 (that is, the aerial work platform 1 whose upper limit height is set lower than that of the one aerial work platform 1) cannot be exceeded, and the one aerial work platform 1 cannot exceed it. Information that identifies the height that can be exceeded shall be recorded.

The specific storage method of such vehicle information is arbitrary, but for example, by inputting by the user or the administrator via the communication unit 21 or the touch pad 22, the control unit 25 can input the input information. To store.

(Configuration-Terminal device-Recording unit-Terminal side status information DB)
The terminal-side state information DB 242 of FIG. 2 is a terminal-side state information storage means for storing the terminal-side state information. The "terminal side state information" is information for specifying the state of the aerial work platform 1, for example, information stored in the terminal device 2. FIG. 6 is a diagram illustrating state information on the terminal side. As shown in FIG. 6, the terminal side state information includes the item "vehicle ID", the item "time information", the item "reservation information", the item "power supply information", the item "vehicle traveling information", and the item "transportation means". "Movement information" and the information corresponding to each item are associated with each other. Information corresponding to the item "Vehicle ID", information corresponding to the item "Time information", information corresponding to the item "Power supply information", information corresponding to the item "Vehicle running information", and item "Movement means movement information". The information corresponding to "" is the same as the information corresponding to the item having the same name in FIG. 3 or FIG. The information corresponding to the item "reservation information" is reservation information for specifying whether or not the aerial work platform 1 is reserved (in FIG. 6, "done" for specifying the reserved state, or reserved. "Empty" to identify that it is not.

The specific storage method of such terminal-side state information is arbitrary, but for example, for information other than reservation information, the control unit 25 controls every predetermined time (for example, 2 hours to 3 hours, etc.). , Communicates with the aerial work platform 1 via the communication unit 21, and is set (recorded) in the vehicle side state information and recording unit 12 recorded in the vehicle side state information DB 121 of the aerial work platform 1. The vehicle ID is acquired, and the acquired vehicle-side status information is recorded as information other than the reservation information of the terminal-side status information. Further, regarding the reservation information, for example, the user inputs the reservation information via the communication unit 21 or the touch pad 22 by checking the reservation management ledger or the whiteboard of the aerial work platform 1, and the control unit 25 inputs the reservation information. The information is stored, or the control unit 25 communicates with a reservation management system (a system that manages the reservation of the aerial work platform 1) (not shown) via the communication unit 21 to manage the reservation. It is stored by acquiring information that identifies whether or not it is reserved from the system.

(Configuration-Terminal device-Control unit)
The control unit 25 in FIG. 2 is a control means for controlling the terminal device 2. The control unit 25 is functionally conceptually provided with an acquisition unit 251, a calculation unit 252, and an output unit 253. The acquisition unit 251 is an acquisition unit for acquiring the first information based on the time related to the movement of the moving means in the height direction and the second information based on the time related to the operation of the target device. The calculation unit 252 is a calculation means that calculates the ratio between the first information and the second information acquired by the acquisition means as operation management information for managing the operation status of the target device. The output unit 253 is a first output means that outputs the ratio calculated by the calculation means. The processing performed by each unit of the control unit 25 will be described later.

(process)
Subsequently, the operation management information output process executed by the terminal device 2 according to the present embodiment will be described. FIG. 7 is a flowchart of the operation management information output process (steps are abbreviated as “S” in the following description of each process). The operation management information output process is a process of calculating and outputting the operation management information, and is generally a process executed by the terminal device 2. The timing for executing this operation management information output process is arbitrary, but for example, after the power of the terminal device 2 is turned on, a predetermined operation via the touch pad 22 (for example, an operation management information should be calculated) is a target. The process will be described from the point where the process is activated, assuming that it is activated when the vehicle ID of the aerial work platform 1 and an operation for specifying a period for calculating the operation management information are performed). Here, for example, the case where "IDv101" in FIG. 6 is specified as the vehicle ID and the period corresponding to "t111" to "t711" in FIG. 6 is specified as the period in which the operation management information should be calculated is illustrated. I will explain.

In SA1 of FIG. 7, the acquisition unit 251 acquires the first information. Specifically, although it is arbitrary, for example, the vehicle ID (hereinafter, also referred to as "designated vehicle ID") and the period (hereinafter, also referred to as "designated period") specified at the time of starting the operation management information output process are acquired. , In the terminal side state information of FIG. 6, the information corresponding to the acquired vehicle ID and period is specified, and the first information is acquired based on the specified information. More specifically, the information for specifying the above-mentioned moving means upper stop time, moving means moving time, total time, first integrated value, and moving means upper threshold exceeding stop time will be acquired as the first information. Obtain each information as follows. The information corresponding to the "designated vehicle ID" and the "designated period" in the terminal side state information in FIG. 6 is also referred to as "target information".

First, the acquisition unit 251 specifies the "target information" for the upper stop time of the moving means, pays attention to the time information and the moving means moving information of FIG. 6 for the specified "target information", and the moving means moving information is "upward". Add up the times that are "stopped" and get the total time. Here, for example, the time of "time information" = "t311" to "t351" and the time of "t411" to "t451" in FIG. 6 are totaled, and the total time is acquired as the moving means upper stop time.

Further, the acquisition unit 251 specifies the "target information" for the moving means moving time, pays attention to the time information and the moving means moving information in FIG. 6 for the specified "target information", and the moving means moving information is "moving". ”To total the time and get the total time. Here, for example, the "time information" in FIG. 6 = the time of "t212" to "t300", the time of "t352" to "t400", and the time of "t452" to "t500" are totaled, and the total time is calculated. Transportation means Obtained as travel time.

Further, regarding the total time, the acquisition unit 251 first acquires the moving means upper stop time and the moving means moving time as described above. Next, the acquisition unit 251 acquires the vehicle running time. In detail, the "target information" is specified, and the specified "target information" is focused on the time information and the vehicle running information of FIG. The time when the information is "running" is totaled, and the total time is acquired. Here, for example, the time of "time information" = "t113" to "t210" and the time of "t512" to "t600" in FIG. 6 are totaled, and the total time is acquired as the vehicle traveling time. Next, the above-mentioned acquired moving means upper stop time, moving means moving time, and vehicle traveling time are totaled, and the total time is acquired as the total time.

Further, the acquisition unit 251 specifies the "target information" for the first integrated value, pays attention to the time information and the movement means movement information of FIG. 6 for the specified "target information", and the movement means movement information "stops upward". The value is calculated based on the product of the time indicated by "" and the height of the work floor 10 (moving means stop height) when the vehicle is stopped upward, and the calculated value is acquired as the first integrated value. ..

FIG. 8 is a diagram for explaining the first integrated value. Note that FIG. 8 is a diagram illustrating an area A1 corresponding to the first integrated value and an area A2 corresponding to the second integrated value described later in FIG. 4. The first integrated value corresponds to, for example, the area A1 in FIG. 8 (that is, the area of the portion surrounded by the solid line indicating the time change of the height of the work floor 10 and the horizontal axis (0.9 m)). Calculate the value. The calculation method here is arbitrary, but for example, the solid line corresponding to "t211" to "t311" in FIG. 8 and the solid line corresponding to the areas A11 and "t311" to "t351" of the rectangular triangle surrounded by the broken line. And the area A12 of the rectangle (rectangle) surrounded by the broken line, the solid line corresponding to "t351" to "t411" and the area A13 of the rectangle (trapezoid) surrounded by the broken line, the solid line and the broken line corresponding to "t411" to "t451". The area of the rectangle (rectangle) surrounded by A14, the area of the rectangular triangle surrounded by solid lines and broken lines corresponding to "t411" to "t511" A15, and the calculated areas are totaled to calculate the area A1. Calculate the value corresponding to.

Regarding the rectangular area A12 and the rectangular area A14, in the moving means movement information of FIG. 6, the height of the work floor 10 corresponding to the "upward stop" and the height of the work floor 10 corresponding to the "downward stop" are shown. Specify the height from the ground, calculate the difference of each specified height, multiply the calculated difference by the time of "upward stop", and use the multiplied result as the value corresponding to each area. ..

Here, the above-mentioned difference calculation was performed in consideration of "0.9 m", which is the height of the work floor 10 from the ground in the case of "downward stop", but in the case of this "downward stop". The height of the work floor 10 from the ground may not be taken into consideration, and in this case, the above-mentioned difference is set as "0 m" instead of "0.9 m" for convenience in all high-altitude work vehicles 1. The value corresponding to the area is calculated by simply multiplying the height of the work floor 10 corresponding to the "upward stop" from the ground and the time of the "upward stop" without performing the calculation of. May be good.

Here, for example, for the rectangular area A12, first, "t311", which is the time when the moving means movement information in FIG. 6 changes from "moving" to "upward stop", and "moving" from "upward stop". The time changed to "t351" is specified, and the times of these "t311" to "t351" are specified. Further, "2.5" which is the height of the work floor 10 from the ground in the case of the specified "upward stop" and "0" which is the height of the work floor 10 from the ground in the case of "downward stop". The difference from ".9" is calculated, the calculated difference is multiplied by the time of "t311" to "t351" specified above, and the multiplication result is set to the value corresponding to the area A12. Further, for example, the same applies to the rectangular area A14, in which the difference between "6.0" and "0.9" is calculated, and the calculated difference is multiplied by the time of "t411" to "t451". The multiplication result is a value corresponding to the area A14.

Regarding the area A11 of the triangle, the area A13 of the trapezoid, and the area A15 of the triangle, the height from the ground of the work floor 10 corresponding to the "upward stop" and the "downward stop" correspond to the "upward stop" in the transportation means movement information of FIG. A value corresponding to each area is calculated based on the height of the work floor 10 from the ground and the time during which the work floor 10 is “moving”. The specific calculation method of the area here is arbitrary (for example, in the case of "moving", it is calculated assuming that the work floor 10 is moving at a constant speed, etc.), so detailed explanation will be given. Is omitted.

Then, by summing the calculated areas A11 to A15, the value corresponding to the area A1 is calculated, and the calculated value is acquired as the first integrated value. Here, the case of acquiring the first integrated value is described in consideration of the areas A11, A13, and A15, but each of these areas is omitted and the work floor 10 is stopped above. The first integrated value may be calculated in consideration of only the case.

Further, regarding the stop time exceeding the upper threshold value of the moving means, the acquisition unit 251 first acquires the threshold value information corresponding to the "designated vehicle ID" with reference to the vehicle information of FIG. Next, the "target information" is specified, and the work floor when the transportation means movement information is "upward stop" by paying attention to the time information and the transportation means movement information of FIG. 6 for the specified "target information". The time when the height from the ground of 10 is higher (exceeded) than the height of the above-mentioned threshold information is specified, and the specified time is acquired. Here, for example, since the "designated vehicle ID" is "IDv101", first, "4", which is the threshold information corresponding to "vehicle ID" = "IDv101" in FIG. 5, is acquired. Next, the height of the work floor 10 from the ground when the moving means movement information is "upward stop" is set to "6" as a time higher than the above-mentioned threshold information height "4". The time of "t411" to "t451" is specified, and the time of "t411" to "t451" is acquired as the stop time exceeding the upper threshold of the moving means.

In SA2 of FIG. 7, the acquisition unit 251 acquires the second information. Specifically, although it is arbitrary, for example, as in the case of SA1, the "target information" is specified, and the second information is acquired based on the specified "target information". In detail, the above-mentioned information for specifying the vehicle power on time, the vehicle power off time, the vehicle reservation time, the vehicle running time, the second integrated value, and the vehicle usage time will be acquired as the second information. Obtain each information as follows.

First, the acquisition unit 251 specifies the "target information" for the vehicle power-on time, pays attention to the time information and the power supply information in FIG. 6 for the specified "target information", and the power supply information is "ON". Sum the time and get the total time. Here, for example, the time of "time information" = "t112" to "t600" in FIG. 6 is acquired as the vehicle power-on time.

Further, the acquisition unit 251 specifies the "target information" for the vehicle power off time, pays attention to the time information and the power supply information in FIG. 6 for the specified "target information", and the power supply information is "OFF". Sum the time and get the total time. Here, for example, the time of "time information" = "t611" to "t711" in FIG. 6 is acquired as the vehicle power-on time. Although "t111" is also "OFF" in FIG. 6, this time is a short time in the "target information", and is omitted from the description for convenience.

Further, the acquisition unit 251 specifies the "target information" for the vehicle reservation time, pays attention to the time information and the reservation information in FIG. 6 for the specified "target information", and the time when the reservation information is "completed". And get the total time. Here, for example, the time of "time information" = "t111" to "t700" in FIG. 6 is acquired as the vehicle reservation time.

Further, the acquisition unit 251 specifies the "target information" for the vehicle running time, pays attention to the time information and the vehicle running information in FIG. 6 for the specified "target information", and the vehicle running information becomes "running". Add up the time you are in and get the total time. Here, for example, the time of "time information" = "t113" to "t210" and the time of "t512" to "t600" in FIG. 6 are totaled, and the total time is acquired as the vehicle traveling time.

Further, the acquisition unit 251 for the second integrated value first acquires the upper limit height information of the moving means corresponding to the "designated vehicle ID" with reference to the vehicle information of FIG. Next, the time corresponding to the first integrated value acquired by SA1 is acquired. The "time corresponding to the first integrated value" is at least a time including a time when the work floor 10 is "upwardly stopped", and for example, the time and the work floor 10 are "moving". It is the time corresponding to the total time with the time that has become. Here, for example, the times of "t211" to "t511" in FIG. 8 are acquired. As described above, when the first integrated value acquired by SA1 is acquired by omitting the areas A11, A13, and A15, here, the times of "t311" to "t351" in FIG. 8 and "t411" are obtained. It is assumed that the total time of "t451" is acquired. Next, the above-mentioned acquired upper limit height information of the moving means is multiplied by the time corresponding to the first integrated value, and the multiplied value is taken as the second integrated value. Here, for example, a value corresponding to the area A2 in FIG. 8 is calculated, and the calculated value is used as a second integrated value.

Further, the acquisition unit 251 specifies the "target information" for the vehicle use time, and acquires and acquires the moving means upper stop time and the moving means moving time for the specified "target information" in the same manner as in the case of SA1. The total time of the moving means upward stop time and the moving means moving time are totaled, and the total time is acquired. Here, for example, the time of "time information" = "t212" to "t500" in FIG. 6 is acquired as the vehicle usage time.

In SA3 of FIG. 7, the calculation unit 252 calculates the operation management information. Specifically, although it is arbitrary, for example, the first information acquired by SA1 and the second information acquired by SA2 are acquired, and the ratio between the acquired first information and the second information is used as the operation management information. Calculate. The specific format of the "ratio between the first information and the second information" is arbitrary. For example, the format of "first information vs. second information", the division is the first information, and the division is the second. Informational division result format (that is, "first information / second information"), division result format with division as second information and division as first information (that is, "second information / first information") ) Etc. may be used, but here, for example, a case where a division result format (that is, "first information / second information") in which the division is the first information and the division is the second information is used is exemplified. I will explain.

Here, for example, the first information, the moving means upper stop time, is used as the divisor, the second information, the vehicle power-on time, is used as the divisor, and the division result is used as the first operation management information. Further, for example, the first information, the moving means upper stop time, is used as the divisor, the second information, the vehicle power off time, is used as the divisor, and the division result is used as the second operation management information. Further, for example, the total time, which is the first information, is used as the division, the vehicle power-on time, which is the second information, is used as the divisor, and the division result is used as the third operation management information. Further, for example, the total time, which is the first information, is used as the division, the vehicle power off time, which is the second information, is used as the divisor, and the division result is used as the fourth operation management information. Further, for example, the first information, the moving means upper stop time, is used as the divisor, the second information, the vehicle reservation time, is used as the divisor, and the division result is used as the fifth operation management information. Further, for example, the first information, the moving means moving time, is used as the divisor, the second information, the vehicle reservation time, is used as the divisor, and the division result is used as the sixth operation management information. Further, for example, the total time, which is the first information, is used as the divisor, the vehicle reservation time, which is the second information, is used as the divisor, and the division result is used as the seventh operation management information. Further, for example, the first information, the moving means upper stop time, is used as the divisor, the second information, the vehicle traveling time, is used as the divisor, and the division result is used as the eighth operation management information. Further, for example, the first integrated value, which is the first information, is used as the division, the second integrated value, which is the second information, is used as the divisor, and the division result is used as the ninth operation management information. Further, for example, the division is performed with the stop time exceeding the upper threshold of the moving means, which is the first information, as the divisor, and the vehicle use time, which is the second information, as the divisor, and the division result is used as the tenth operation management information.

In SA4 of FIG. 7, the output unit 253 outputs operation management information. Specifically, although it is arbitrary, for example, the operation management information calculated by SA3 is acquired, and the acquired operation management information is output. Here, for example, the first to tenth operation management information calculated by SA3 is displayed on the display 23 and output. This ends the operation management information output process.

(Effect of this embodiment)
According to the present embodiment, by calculating the ratio between the acquired first information and the second information as the operation management information for managing the operation status of the aerial work platform 1, for example, 2 Since the operation management information can be calculated based on the type of information, it is possible to calculate useful operation management information. Further, for example, since the first information based on the time related to the movement of the work floor 10 in the height direction is used for the calculation of the operation management information, the work performed by using the aerial work platform 1 provided with the work floor 10. Information with a relatively large degree of relevance can be reflected, and the usefulness of operation management information can be improved. Further, for example, by calculating the ratio between the first information and the second information as the operation management information, the operation status of the aerial work platform 1 can be intuitively grasped, so that the operation management information can be obtained. It is possible to further improve the usefulness.

Further, by acquiring information for specifying either the power on time or the off time of the aerial work platform 1 (both power off times) as the second information, for example, the power of the aerial work platform 1 is turned on. Since time-based information directly related to the use or non-use of the aerial work platform 1 such as time or off time can be reflected in the operation management information, it is possible to improve the usefulness of the operation management information. Become.

Further, by acquiring the information specifying the time when the work floor 10 is stopped above as the first information, for example, the time when the work floor 10 is stopped above and the power on time or off of the aerial work platform 1 are turned off. Since the ratio to the time is calculated as operation management information (first and second operation management information), the time during which the actual work (hereinafter referred to as actual work) performed using the aerial work platform 1 is performed is operated. Since it can be reflected in the management information, it is possible to improve the usefulness of the operation management information. In particular, for example, since it is possible to grasp the length between the time during which the actual work is being performed (hereinafter referred to as the actual work time) and the power-on time or the power-off time, for example, the actual work is not performed. Despite this, there is a possibility that the power of the aerial work platform 1 is unnecessarily turned on for a long time, or the time when the aerial work platform 1 is turned off is the actual working time. On the other hand, it is possible to raise the user's awareness of the efficient operation of the aerial work platform 1 by grasping that it may be extremely long.

Further, by acquiring as the first information information specifying the total time of the time when the work floor 10 is stopped upward, the time when the work floor 10 is moved in the height direction, and the time when the aerial work platform 1 is traveled. For example, since the ratio of the total time to the power on time or off time of the aerial work platform 1 is calculated as the operation management information (third and fourth operation management information), the actual work time and before the actual work. (For example, the work of moving the aerial work platform 1 to the work place, the work of moving the work floor 10 of the aerial work platform 1 upward or downward, etc.) Since the time spent can be reflected in the operation management information, it is possible to improve the usefulness of the operation management information. In particular, for example, since it is possible to grasp the length between the total time of the actual work time and the incidental work time and the power on time or the power off time, for example, the work floor 10 is stopped downward. Nevertheless, the power of the aerial work platform 1 may be unnecessarily turned on for a long time (that is, the so-called idling operation time may be long), or The user regarding the efficient operation of the aerial work platform 1 by understanding that the time when the power of the aerial work platform 1 is turned off may be extremely longer than the above-mentioned total time. It is possible to raise the awareness of.

Further, by acquiring the information for specifying the reserved time of the aerial work platform 1 as the second information, for example, a specific user (that is, a high place) of the time when the aerial work platform 1 is reserved. Since the information based on the time when the use other than the user who reserved the work platform 1) is prohibited can be reflected in the operation management information, the usefulness of the operation management information can be improved.

Further, by acquiring the information for specifying the time when the work floor 10 is stopped above as the first information, for example, the time when the work floor 10 is stopped above and the time when the aerial work platform 1 is reserved. Since the ratio of is calculated as the operation management information (fifth operation management information), the actual work time can be reflected in the operation management information, so that the usefulness of the operation management information can be improved. In particular, for example, since it is possible to grasp the mutual length between the actual work time and the time when the aerial work platform 1 is reserved, for example, the aerial work platform 1 can be grasped at a high place even though the actual work is not performed. It is possible to raise the user's awareness of the efficient operation of the aerial work platform 1 by grasping that the reserved time of the work platform 1 may be long.

Further, by acquiring the time when the work floor 10 moves in the height direction as the first information, for example, the time when the work floor 10 moves in the height direction and the time when the aerial work platform 1 is reserved. Is calculated as the operation management information (sixth operation management information), so that the time during the incidental work of moving the work floor 10 of the aerial work platform 1 upward or downward can be reflected in the operation management information. Therefore, it is possible to improve the usefulness of the operation management information. In particular, for example, the length between the time during which the work floor 10 of the aerial work platform 1 is moved upward or downward and the time during which the aerial work platform 1 is reserved is grasped. Therefore, for example, there is a possibility that the aerial work platform 1 is reserved for a long time even though the aerial work platform 1 is used for a short time, or the aerial work platform 1 may be reserved for a long time. Make sure that the operation is centered on work in which the aerial work platform 1 is driven and moved to the work place, and the user's awareness of the efficient operation of the aerial work platform 1 is raised. It will be possible to improve.

Further, by acquiring as the first information information specifying the total time of the time when the work floor 10 is stopped upward, the time when the work floor 10 is moved in the height direction, and the time when the aerial work platform 1 is traveled. For example, since the ratio of the total time to the time reserved for the aerial work platform 1 is calculated as the operation management information (7th operation management information), the actual work time and the incidental work performed before the actual work are performed. (For example, work of moving the aerial work platform 1 to the work place, work of moving the work floor 10 of the aerial work platform 1 upward or downward, etc.) Since it can be reflected in the information, it is possible to improve the usefulness of the operation management information. In particular, for example, since it is possible to grasp the length between the actual work time and the incidental work time and the time when the aerial work platform 1 is reserved, for example, the work floor 10 is stopped downward. By making them aware that the aerial work platform 1 may be reserved for a long time in spite of the fact that the aerial work platform 1 is used, the user's awareness of the efficient operation of the aerial work platform 1 is raised. It will be possible to improve.

Further, by acquiring the information for specifying the time when the work floor 10 has stopped above as the first information and the information for specifying the time when the aerial work platform 1 has traveled as the second information, for example, the work Since the ratio of the time when the floor 10 is stopped above and the time when the aerial work platform 1 has traveled is calculated as the operation management information (8th operation management information), the actual work time and the aerial work platform 1 are driven. Since the incidental work time to be moved to the work place can be reflected in the operation management information, the usefulness of the operation management information can be improved. In particular, for example, since it is possible to grasp the mutual length between the actual work time and the incidental work time for moving the aerial work platform 1 to the work place, for example, it is relatively relatively from the work place. It is possible to grasp that the aerial work platform 1 provided at a distant position may be used by the user.

Further, the first integrated value, which is information based on the product of the time when the work floor 10 is stopped above and the stopped height of the work floor 10, is acquired as the first information, and the time when the aerial work platform 1 is used. By acquiring the second integrated value, which is information based on the product of the upper limit height of the work floor 10, as the second information, for example, the ratio between the first integrated value and the second integrated value can be obtained as operation management information (9th operation). Since it is calculated as management information), the information on the stopped height of the work floor 10 and the information on the upper limit height of the work floor 10 can be reflected in the operation management information, so that the usefulness of the operation management information is improved. It is possible to make it. In particular, for example, it is possible to grasp how much the ability of the aerial work platform 1 with respect to the height of the work floor 10 is utilized.

Further, by acquiring the information for specifying the time when the work floor 10 exceeds the threshold height as the first information and the information for specifying the time when the aerial work platform 1 is used as the second information, for example. Since the ratio of the time when the work floor 10 exceeds the threshold height and the time when the aerial work platform 1 is used is calculated as the operation management information (10th operation management information), the work floor 10 determines the threshold height. Since the exceeded time can be reflected in the operation management information, it is possible to improve the usefulness of the operation management information. In particular, the aerial work platform 1 may have an upper limit height of the work floor 10 set to 4 m, 6 m, or the like as an example. In this case, the threshold height is set lower than that of the aerial work platform 1. The height that cannot be exceeded by the aerial work platform 1 (the aerial work platform 1 whose upper limit height is set lower) and can be exceeded by the aerial work platform 1 is set as the threshold height. If it is determined, it becomes possible to grasp whether or not the aerial work platform 1 is performing work that cannot be replaced by the lower aerial work platform 1, or whether or not the length of time during which the work is being performed can be grasped.

Further, by outputting the ratio calculated by the calculation unit 252, for example, it is possible to notify the operation management information for managing the operation status of the aerial work platform 1.

[III] Modifications to the Embodiment The embodiment of the present invention has been described above, but the specific configuration and means of the present invention are within the scope of the technical idea of each invention described in the claims. Can be arbitrarily modified and improved. Hereinafter, such a modification will be described.

(About the problem to be solved and the effect of the invention)
First, the problem to be solved by the invention and the effect of the invention are not limited to the above-mentioned contents, and may differ depending on the implementation environment and the details of the configuration of the invention, and only a part of the above-mentioned problems. May be resolved or only some of the above effects may be achieved.

(About distribution and integration)
Further, each of the above-mentioned electrical components is a functional concept and does not necessarily have to be physically configured as shown in the figure. That is, the specific form of dispersion or integration of each part is not limited to the one shown in the figure, and all or part of them may be functionally or physically dispersed or integrated in any unit according to various loads and usage conditions. Can be configured. For example, after mounting a part of the functions of the terminal device 2 on the server device, the terminal device 2 and the server device communicate with each other to perform the processing described in the embodiment. May be good.

(About shape, numerical value, structure, time series)
With respect to the components exemplified in the embodiments and drawings, the shape, numerical value, or the mutual relationship of the structure or time series of the plurality of components shall be arbitrarily modified and improved within the scope of the technical idea of the present invention. Can be done.

(About operation management information)
Further, in the above embodiment, the case where the first to tenth operation management information is calculated in SA3 of FIG. 7 has been described, but the present invention is not limited to this. For example, it may be configured to calculate only a part of the first to tenth operation management information. In this case, the user may specify the operation management information to be calculated, and the designated operation management information may be calculated. Further, in this case, the SA1 and SA2 may be configured to acquire only the first information and the second information related to the operation management information to be calculated.

(About terminal status information)
Further, each information other than the reservation information of the terminal side state information of FIG. 6 of the above embodiment may be stored by another method. For example, the control unit 25 of the terminal device 2 acquires information on the state acquisition means provided on the aerial work platform 1 by communication at predetermined time intervals (for example, 1 second to 5 seconds), and obtains the acquired information. It may be configured to store based on.

(About the second output section)
Further, the second output unit may be mounted on the control unit 25 of the terminal device 2 of the above embodiment. The "second output unit" is a second output means that generates recommended information regarding the operation of the aerial work platform 1 based on the ratio calculated by the calculation unit 252 and outputs the generated recommended information. The specific mounting method of the second output unit is arbitrary, but for example, the recording unit 24 may be configured to store the recommended information specific information and then process it as follows. The "recommended information specific information" is information in which the recommended information and the range of the operation management information corresponding to the recommended information are mutually related. For example, the first operation management information is "recommended information". "The power is turned on uselessly, let's try to save energy" and "less than 0.6" which is the "range of operation management information" and "recommended information" which is "properly operated. This information includes "Let's drive in good condition" and "0.6 or more" which is the "range of operation management information". The "recommended information specific information" includes information corresponding to the second to tenth operation management information, but since these information can be arbitrary, detailed explanation is omitted. do. The specific storage method of this recommended information specific information is arbitrary, but for example, the administrator grasps and grasps the operation management information and the operation status of the aerial work platform 1 based on past examples. It may be recorded by inputting it to the terminal device 2 after generating it in consideration of an actual example or the like. Further, for example, it is decided that the user inputs feedback to the terminal device 2 whether or not the output recommended information was appropriate, and if not, what was the appropriate recommended information, and this feedback is used. , The control unit 25 of the terminal device 2 may be configured to update and store the recommended information specific information by using the technique of machine learning.

Then, the second output unit acquires the operation management information calculated by SA3 in FIG. 7, refers to the "recommended information specific information" of the recording unit 24, and acquires the recommended information corresponding to the acquired operation management information ( It may be configured to generate) and display the acquired recommended information on the display 23 for output. Here, for example, when the second output unit acquires "0.3" as the first operation management information, it is "less than 0.6", so that the "recommended information" is "power is turned on uselessly". Let's try to save energy. ”Will be acquired and output. When configured in this way, by generating recommended information regarding the operation of the aerial work platform 1 and outputting the generated recommended information, for example, recommended items regarding the operation of the aerial work platform 1 (that is, so-called recommendations). Can be notified.

Further, the processing of the second output unit may be arbitrarily changed. For example, recommended information is provided based on a part of the operation management information specified by the user among the first to tenth operation management information. It may be configured to generate and output.

(About the management department)
Further, the management unit may be mounted on the control unit 25 of the terminal device 2 of the above embodiment. The "management unit" manages a plurality of aerial work platforms 1 based on the ratio of each of the plurality of aerial work platforms 1 (for example, aerial work platforms 101, 102, etc.) calculated by the calculation unit 252. It is a management means. The specific implementation method of this management unit is arbitrary, but for example, it may be configured to store the aerial work platform operation management information in the recording unit 24 and then process it as follows. The "aerial work platform operation management information" is information in which the vehicle ID of each aerial work platform 1 and the operation management information of the aerial work platform 1 are associated with each other. The specific storage method of the aerial work platform operation management information is arbitrary, but for example, the control unit 25 of the terminal device 2 has a predetermined time interval (for example, every day, etc.) in the terminal side state information of FIG. The information for one day for each aerial work platform 1 is set as the above-mentioned "target information", and the processing of SA1 to SA3 in FIG. 7 is configured to be repeated, and the operation management information calculated by SA3 is stored. May be configured to store aerial work platform operation management information.

Then, when the management unit receives the processing start command from the user or at any other timing, the operation management information of the aerial work platform operation management information of the recording unit 24 is referred to, and based on the referred operation management information. By specifying the aerial work platform 1 to be used by the user and displaying the specified aerial work platform 1 on the display 23 and outputting it, the user is instructed to use the aerial work platform 1. You may. The specific method for specifying the aerial work platform 1 here is arbitrary, but for example, a threshold value for specifying the aerial work platform 1 to be guided is stored in the recording unit 24, and this method is used. The stored threshold value may be compared with the operation management information, and the aerial work platform 1 corresponding to the operation management information less than or equal to the threshold value may be guided. The threshold value here and the operation management information to be compared with the threshold value (at least one or more of the above-mentioned 1st to 10th operation management information) are configured so as to be specified by the user, and are specified. It may be configured to be specified by using the threshold value and the operation management information. Further, the display mode of the aerial work platform 1 here is arbitrary, and is configured to output, for example, the unit name of the aerial work platform 1 (for example, "Unit 1" for the aerial work platform 101). Alternatively, it may be configured to output the position of the aerial work platform 1 after making it possible to grasp the current position of the aerial work platform 1 by using a known technique. Further, for example, the aerial work platform 1 is provided with an automatic driving function, and when the aerial work platform 1 to be used is not currently used, the aerial work platform 1 is configured to be moved to a designated place. You may. In this configuration, by managing the plurality of aerial work platforms 1 based on the ratio for each of the plurality of aerial work platforms 1 (aerial work platforms 101, 102, etc.) calculated by the calculation unit 252. For example, the aerial work platform 1 can be used efficiently.

(Additional note)
The management system of Appendix 1 is a management system that manages a target device including a moving means for moving the moving target in the height direction, and is the first information based on the time related to the movement of the moving means in the height direction. And the ratio between the acquisition means for acquiring the second information based on the time related to the operation of the target device and the first information and the second information acquired by the acquisition means, the operation of the target device. It is provided with a calculation means for calculating as operation management information for managing the situation.

In the management system according to the appendix 1, the management system of the appendix 2 acquires information for specifying either the on-time or the off-time of the power supply of the target device as the second information.

In the management system according to the appendix 2, the management system of the appendix 3 acquires the information for specifying the time when the moving means has stopped upward as the first information.

The management system of the appendix 4 is the management system of the appendix 2, in which the acquisition means has a time when the moving means has stopped upward, a time when the moving means has moved in the height direction, and a running time of the target device. Information for specifying the total time of the time is acquired as the first information.

In the management system according to the appendix 1, the management system of the appendix 5 acquires, as the second information, the information for specifying the time when the target device is reserved.

In the management system according to the appendix 5, the management system of the appendix 6 acquires the information for specifying the time when the moving means has stopped upward as the first information.

In the management system according to the appendix 5, the management system of the appendix 7 acquires the time when the moving means moves in the height direction as the first information.

The management system of the appendix 8 is the management system of the appendix 5, in which the acquisition means has a time when the moving means has stopped upward, a time when the moving means has moved in the height direction, and a running time of the target device. Information for specifying the total time of the time is acquired as the first information.

In the management system according to the appendix 1, the management system of the appendix 9 acquires the information for specifying the time when the moving means has stopped upward as the first information, and the target device travels. Information for specifying the time is acquired as the second information.

In the management system according to the appendix 1, the management system according to the appendix 10 provides information based on the product of the time when the moving means is stopped upward and the height at which the moving means is stopped, the first information. And the information based on the product of the time when the target device was used and the upper limit height of the moving means is acquired as the second information.

In the management system according to the appendix 1, the management system of the appendix 11 acquires the information for specifying the time when the moving means exceeds the threshold height as the first information, and the target device obtains the information. Information that identifies the time used is acquired as the second information.

The management system of Supplementary Note 12 includes a first output means for outputting the ratio calculated by the calculation means in the management system according to any one of Supplementary note 1 to 11.

The management system of Supplementary Note 13 generates recommended information regarding the operation of the target device based on the ratio calculated by the calculation means in the management system according to any one of Supplementary note 1 to 12, and the generated recommended information. A second output means for outputting the above.

In the management system according to any one of the items 1 to 13, the management system of the appendix 14 has a plurality of the target devices, and the acquisition means has the first information and the said first information for each of the plurality of target devices. The second information was acquired, the calculation means calculated the ratio between the first information and the second information for each of the plurality of target devices, and the management system was calculated by the calculation means. A management means for managing the plurality of target devices based on the ratio for each of the plurality of target devices is provided.

The management program of Appendix 15 is a management program for managing a target device including a moving means for moving the moving target in the height direction, and is based on a computer based on the time related to the movement of the moving means in the height direction. The target is the ratio between the acquisition means for acquiring the first information and the second information based on the time related to the operation of the target device, and the first information and the second information acquired by the acquisition means. It functions as a calculation means for calculating operation management information for managing the operation status of the device.

(Effect of appendix)
According to the management system described in Appendix 1, for example, by calculating the ratio between the acquired first information and the second information as operation management information for managing the operation status of the target device, for example, 2 Since the operation management information can be calculated based on the type of information, it is possible to calculate useful operation management information. Further, for example, since the first information based on the time related to the movement of the moving means in the height direction is used for the calculation of the operation management information, the relationship with the work performed by using the target device provided with the moving means. Information with a relatively high degree of sex can be reflected, and the usefulness of operation management information can be improved. Further, for example, by calculating the ratio between the first information and the second information as the operation management information, the operation status of the target device can be intuitively grasped, so that the usefulness of the operation management information can be improved. It is possible to further improve.

According to the management system described in Appendix 2, for example, by acquiring information for specifying either the power-on time or the off time of the target device as the second information, for example, the power-on time or the power-off time of the target device is turned off. Since time-based information directly related to the use or non-use of the target device, which is time, can be reflected in the operation management information, the usefulness of the operation management information can be improved.

According to the management system described in Appendix 3, by acquiring the information specifying the time when the moving means has stopped upward as the first information, for example, the time when the moving means has stopped upward and the power supply of the target device. Since the ratio to the on-time or off-time is calculated as the operation management information, the time during which the actual work performed using the target device (hereinafter referred to as the actual work) can be reflected in the operation management information. , It is possible to improve the usefulness of operation management information. In particular, for example, since it is possible to grasp the length between the time during which the actual work is being performed (hereinafter referred to as the actual work time) and the power-on time or the power-off time, for example, the actual work is not performed. Despite this, the power of the target device may be unnecessarily turned on for a long time, or the power of the target device may be turned off for a long time compared to the actual working time. It is possible to raise the user's awareness of the efficient operation of the target device by grasping the possibility that the target device is present.

According to the management system described in Appendix 4, the first information is information that specifies the total time of the time when the moving means has stopped upward, the time when the moving means has moved in the height direction, and the time when the target device has traveled. By acquiring, for example, the ratio of the total time to the power-on time or off time of the target device is calculated as operation management information, so that the actual work time and incidental work performed before the actual work (for example, the target). Operation management can be reflected in the operation management information because the time during which the device is run and moved to the work place, or the moving means of the target device is moved upward or downward, etc.) can be reflected in the operation management information. It is possible to improve the usefulness of information. In particular, for example, since it is possible to grasp the length between the total time of the actual work time and the incidental work time and the power on time or the power off time, for example, even if the transportation means is stopped downward. Regardless, the power supply of the target device may be unnecessarily turned on for a long time (that is, the so-called idling operation time may be long), or the power supply of the target device may be long. It is possible to raise the user's awareness of the efficient operation of the target device by understanding that the time when is turned off may be extremely longer than the above-mentioned total time. ..

According to the management system described in Appendix 5, by acquiring the information for specifying the time when the target device is reserved as the second information, for example, a specific user (that is, the time when the target device is reserved). , Information based on the time when use by anyone other than the user who reserved the target device) can be reflected in the operation management information, so that the usefulness of the operation management information can be improved.

According to the management system described in Appendix 6, by acquiring the information specifying the time when the moving means has stopped upward as the first information, for example, the time when the moving means has stopped upward and the target device are reserved. Since the ratio to the time spent is calculated as the operation management information, the actual work time can be reflected in the operation management information, so that the usefulness of the operation management information can be improved. In particular, for example, since it is possible to grasp the length between the actual work time and the time when the target device is reserved, for example, the target device is reserved even though the actual work is not performed. It is possible to raise the user's awareness of the efficient operation of the target device by understanding that the time spent may be long.

According to the management system described in Appendix 7, by acquiring the time when the moving means moves in the height direction as the first information, for example, the time when the moving means moves in the height direction and the target device are reserved. Since the ratio to the time spent is calculated as the operation management information, the time during the incidental work of moving the moving means of the target device upward or downward can be reflected in the operation management information. It is possible to improve the usefulness. In particular, for example, since it is possible to grasp the mutual length between the time during which the incidental work of moving the moving means of the target device is performed upward or downward and the time when the target device is reserved, for example, for example. There is a possibility that the target device is reserved for a long time even though the target device is used for a short time, or the work of running the target device and moving it to the work place. It is possible to raise the user's awareness of the efficient operation of the target device by understanding that there is a possibility that the operation is central.

According to the management system described in Appendix 8, the first information is information that specifies the total time of the time when the moving means has stopped upward, the time when the moving means has moved in the height direction, and the time when the target device has traveled. By acquiring, for example, the ratio of the total time to the time reserved for the target device is calculated as operation management information, so that the actual work time and incidental work performed before the actual work (for example, the target device) can be obtained. Since the time during which the work of moving the target device to the work place or the work of moving the moving means of the target device upward or downward can be reflected in the operation management information, the operation management information can be used. It is possible to improve the usefulness. In particular, for example, since it is possible to grasp the mutual length between the actual work time and the incidental work time and the time when the target device is reserved, for example, even though the means of transportation is stopped downward. It is possible to raise the user's awareness of the efficient operation of the target device by understanding that the target device may be reserved for a long time in vain.

According to the management system described in Appendix 9, the information for specifying the time when the moving means has stopped above is acquired as the first information, and the information for specifying the time when the target device has traveled is acquired as the second information. As a result, for example, the ratio of the time when the moving means is stopped upward and the time when the target device is traveled is calculated as the operation management information, so that the actual work time and the incidental work of moving the target device to the work place are performed. Since time and time can be reflected in the operation management information, it is possible to improve the usefulness of the operation management information. In particular, for example, since it is possible to grasp the length between the actual work time and the incidental work time for moving the target device to the work place, for example, at a position relatively far from the work place. It becomes possible to grasp that the target device provided may be used by the user.

According to the management system described in Appendix 10, information based on the product of the time when the moving means is stopped above and the stopped height of the moving means is acquired as the first information, and the time when the target device is used and the moving means are acquired. By acquiring the information based on the product of the upper limit height of the moving means as the second information, for example, the information based on the product of the time when the moving means is stopped above and the height when the moving means is stopped and the time when the target device is used. Since the ratio of the information based on the product of the upper limit height of the moving means and the information based on the product is calculated as the operation management information, the information on the stopped height of the moving means and the information on the upper limit height of the moving means are reflected in the operation management information. Therefore, it is possible to improve the usefulness of the operation management information. In particular, for example, it is possible to grasp how much the target device has the ability regarding the height of the transportation means.

According to the management system described in Appendix 11, the information for specifying the time when the moving means exceeds the threshold height is acquired as the first information, and the information for specifying the time when the target device is used is acquired as the second information. By doing so, for example, the ratio of the time when the moving means exceeds the threshold height to the time when the target device is used is calculated as the operation management information, so that the time when the moving means exceeds the threshold height is the operation management information. Since it can be reflected in, it is possible to improve the usefulness of the operation management information. In particular, for each aerial work platform which is an example of the target device, the upper limit height of the moving means may be set to 4 m, 6 m, etc. as an example. In this case, the threshold height is set as the target device. It cannot be exceeded by the aerial work platform lower than the aerial work platform (the aerial work platform whose upper limit height is set lower), and it cannot be exceeded by the aerial work platform which is the target device. When the height at which the work can be performed is set as the threshold height, whether or not the aerial work platform, which is the target device, is performing work that cannot be replaced by the lower aerial work platform, or the time during which the work is being performed. It is possible to grasp the long and short.

According to the management system described in Appendix 12, by outputting the ratio calculated by the calculation means, for example, it is possible to notify the operation management information for managing the operation status of the target device.

According to the management system described in Appendix 13, by generating recommended information regarding the operation of the target device and outputting the generated recommended information, for example, the recommended items (that is, so-called recommendations) regarding the operation of the target device are notified. It becomes possible to do.

According to the management system described in Appendix 14, for example, the target device can be efficiently used by managing the plurality of target devices based on the ratio of each of the plurality of target devices calculated by the calculation means. Is possible.

According to the management program described in Appendix 15, for example, by calculating the ratio between the acquired first information and the second information as operation management information for managing the operation status of the target device, for example, 2 Since the operation management information can be calculated based on the type of information, it is possible to calculate useful operation management information. Further, for example, since the first information based on the time related to the movement of the moving means in the height direction is used for the calculation of the operation management information, the relationship with the work performed by using the target device provided with the moving means. Information with a relatively high degree of sex can be reflected, and the usefulness of operation management information can be improved. Further, for example, by calculating the ratio between the first information and the second information as the operation management information, the operation status of the target device can be intuitively grasped, so that the usefulness of the operation management information can be improved. It is possible to further improve.

1 Aerial work platform 2 Terminal device 11 Communication unit 12 Recording unit 13 Control unit 21 Communication unit 22 Touch pad 23 Display 24 Recording unit 25 Control unit 101 Aerial work platform 102 Aerial work platform 10 Work floor 121 Vehicle side status information DB
241 Vehicle information DB
242 Terminal side status information DB
251 Acquisition unit 252 Calculation unit 253 Output unit A1 Area A2 Area A11 Area A12 Area A13 Area A14 Area A15 Area

Claims (16)

A management system that manages a target device equipped with a moving means for moving a moving target in the height direction.
Acquisition means for acquiring the first information based on the time related to the movement of the moving means in the height direction and the second information based on the time related to the operation of the target device.
A calculation means for calculating the ratio between the first information and the second information acquired by the acquisition means as operation management information for managing the operation status of the target device is provided .
The acquisition means acquires information for specifying either the on time or the off time of the power supply of the target device as the second information.
The acquisition means uses information for specifying the total time of the time when the moving means is stopped upward, the time when the moving means is moved in the height direction, and the time when the target device is traveled as the first information. get,
Management system. A management system that manages a target device equipped with a moving means for moving a moving target in the height direction.
Acquisition means for acquiring the first information based on the time related to the movement of the moving means in the height direction and the second information based on the time related to the operation of the target device.
A calculation means for calculating the ratio between the first information and the second information acquired by the acquisition means as operation management information for managing the operation status of the target device is provided .
The acquisition means acquires information for specifying the time reserved for the target device as the second information.
Management system. The acquisition means acquires information for specifying the time when the moving means has stopped upward as the first information.
The management system according to claim 2 . The acquisition means acquires the time when the moving means moves in the height direction as the first information.
The management system according to claim 2 . The acquisition means uses information for specifying the total time of the time when the moving means is stopped upward, the time when the moving means is moved in the height direction, and the time when the target device is traveled as the first information. get,
The management system according to claim 2 . A management system that manages a target device equipped with a moving means for moving a moving target in the height direction.
Acquisition means for acquiring the first information based on the time related to the movement of the moving means in the height direction and the second information based on the time related to the operation of the target device.
A calculation means for calculating the ratio between the first information and the second information acquired by the acquisition means as operation management information for managing the operation status of the target device is provided .
The acquisition means acquires information for specifying the time when the moving means has stopped upward as the first information, and acquires information for specifying the time when the target device has traveled as the second information.
Management system. A management system that manages a target device equipped with a moving means for moving a moving target in the height direction.
Acquisition means for acquiring the first information based on the time related to the movement of the moving means in the height direction and the second information based on the time related to the operation of the target device.
A calculation means for calculating the ratio between the first information and the second information acquired by the acquisition means as operation management information for managing the operation status of the target device is provided .
The acquisition means acquires information based on the product of the time when the moving means is stopped upward and the stopped height of the moving means as the first information, and the time when the target device is used and the moving means. Information based on the product of the upper limit height of is acquired as the second information.
Management system. A management system that manages a target device equipped with a moving means for moving a moving target in the height direction.
Acquisition means for acquiring the first information based on the time related to the movement of the moving means in the height direction and the second information based on the time related to the operation of the target device.
A calculation means for calculating the ratio between the first information and the second information acquired by the acquisition means as operation management information for managing the operation status of the target device is provided .
The acquisition means acquires information for specifying the time when the moving means exceeds the threshold height as the first information, and acquires information for specifying the time when the target device is used as the second information. do,
Management system. A first output means, which outputs the ratio calculated by the calculation means, is provided.
The management system according to any one of claims 1 to 8 . A second output means, which generates recommended information regarding the operation of the target device based on the ratio calculated by the calculation means and outputs the generated recommended information, is provided.
The management system according to any one of claims 1 to 9 . There are a plurality of the target devices,
The acquisition means acquires the first information and the second information for each of the plurality of target devices, and obtains the first information and the second information.
The calculation means calculates the ratio between the first information and the second information for each of the plurality of target devices.
The management system is
A management means for managing a plurality of the target devices based on a ratio for each of the plurality of target devices calculated by the calculation means.
The management system according to any one of claims 1 to 10 . It is a management program that manages a target device provided with a moving means for moving a moving target in the height direction.
Computer,
Acquisition means for acquiring the first information based on the time related to the movement of the moving means in the height direction and the second information based on the time related to the operation of the target device.
The ratio between the first information and the second information acquired by the acquisition means is made to function as a calculation means for calculating as operation management information for managing the operation status of the target device.
The acquisition means acquires information for specifying either the on time or the off time of the power supply of the target device as the second information.
The acquisition means uses information for specifying the total time of the time when the moving means is stopped upward, the time when the moving means is moved in the height direction, and the time when the target device is traveled as the first information. get,
Management program. It is a management program that manages a target device provided with a moving means for moving a moving target in the height direction.
Computer,
Acquisition means for acquiring the first information based on the time related to the movement of the moving means in the height direction and the second information based on the time related to the operation of the target device.
The ratio between the first information and the second information acquired by the acquisition means is made to function as a calculation means for calculating as operation management information for managing the operation status of the target device.
The acquisition means acquires information for specifying the time reserved for the target device as the second information.
Management program. It is a management program that manages a target device provided with a moving means for moving a moving target in the height direction.
Computer,
Acquisition means for acquiring the first information based on the time related to the movement of the moving means in the height direction and the second information based on the time related to the operation of the target device.
The ratio between the first information and the second information acquired by the acquisition means is made to function as a calculation means for calculating as operation management information for managing the operation status of the target device.
The acquisition means acquires information for specifying the time when the moving means has stopped upward as the first information, and acquires information for specifying the time when the target device has traveled as the second information.
Management program. It is a management program that manages a target device provided with a moving means for moving a moving target in the height direction.
Computer,
Acquisition means for acquiring the first information based on the time related to the movement of the moving means in the height direction and the second information based on the time related to the operation of the target device.
The ratio between the first information and the second information acquired by the acquisition means is made to function as a calculation means for calculating as operation management information for managing the operation status of the target device.
The acquisition means acquires information based on the product of the time when the moving means is stopped upward and the stopped height of the moving means as the first information, and the time when the target device is used and the moving means. Information based on the product of the upper limit height of is acquired as the second information.
Management program. It is a management program that manages a target device provided with a moving means for moving a moving target in the height direction.
Computer,
Acquisition means for acquiring the first information based on the time related to the movement of the moving means in the height direction and the second information based on the time related to the operation of the target device.
The ratio between the first information and the second information acquired by the acquisition means is made to function as a calculation means for calculating as operation management information for managing the operation status of the target device.
The acquisition means acquires information for specifying the time when the moving means exceeds the threshold height as the first information, and acquires information for specifying the time when the target device is used as the second information. do,
Management program.

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