CN106886164B

CN106886164B - Monitoring system simulator

Info

Publication number: CN106886164B
Application number: CN201611129042.0A
Authority: CN
Inventors: 山下翔平
Original assignee: Mitsubishi Electric Building Techno Service Co Ltd
Current assignee: Mitsubishi Electric Building Solutions Corp
Priority date: 2015-12-15
Filing date: 2016-12-09
Publication date: 2021-05-25
Anticipated expiration: 2036-12-09
Also published as: JP6173418B2; JP2017111544A; CN106886164A

Abstract

A monitoring system simulator is provided which can confirm the control of an apparatus supposed to be controlled in a monitoring system in a short period of time and can suppress unexpected operation control of the apparatus in the monitoring system. The simulator (50) has: a specific state input section for selecting a specific state from a plurality of states assumed in a facility having a plurality of devices; an apparatus state output section for outputting a state of each apparatus; and a control unit (20) that associates a specific state with the state of each device corresponding to the specific state, based on control software for controlling the operation of the plurality of devices in the monitoring system, and displays the state of each device associated therewith on a device state output unit.

Description

Monitoring system simulator

Technical Field

The present invention relates to a monitoring system simulator (monitoring system), and more particularly to a monitoring system simulator used for confirming operation control of equipment in a monitoring system for monitoring facilities such as buildings and amusement parks.

Background

Conventionally, as a simulator, there is a simulator for an air conditioner described in patent document 1. The simulator is used for grasping the operation state of the air conditioner. When an input condition for determining an operation condition is input from an input unit, the simulator outputs data relating to the operation of the air conditioner corresponding to the input condition on a display unit.

[ patent document 1 ] Japanese patent application laid-open No. 2006 and 242429

Disclosure of Invention

Problems to be solved by the invention

However, when a building monitoring system that monitors a plurality of devices such as lighting, air conditioners, automatic sprinkler systems, elevators, etc. is constructed, it is preferable to construct devices in advance at a place different from the installation place, for example, a plant, and then install the devices on the site, and to confirm the operation of the devices. However, in construction with a short construction period, it is sometimes impossible to build equipment in advance in a factory or the like, and building of a building monitoring system must be already performed on site. In this case, when the equipment performs an unexpected operation during the operation check in the field, it is not easy to determine whether there is a problem in the control software of the monitoring controller that controls the operation of each equipment or a problem in the construction in the field, for example, an erroneous wiring connection or the like, and it may take a long time to check the operation. Further, in the operation check in the field, it is necessary to check whether the control software is appropriate or not and to check whether the wiring connection or the like is appropriate or not, and therefore, it is easy to cause a check omission, and sometimes the device is not found even if it unexpectedly operates.

An object of the present invention is to provide a monitoring system simulator capable of checking a situation in which a monitoring system performs assumed plant control in a short period of time and suppressing unexpected operation control of a plant in the monitoring system.

Means for solving the problems

A monitoring system simulator according to the present invention simulates operation control of a plurality of devices in a monitoring system that monitors operations of the plurality of devices in a facility having the plurality of devices, the monitoring system simulator comprising: a specific state input section that selects a specific state from a plurality of states assumed to be generated in the facility; an apparatus state output unit that outputs a state of the apparatus; and a control unit that associates the specific state with a state of the device corresponding to the specific state, and displays the associated state of the device on the device state output unit, based on control software for controlling operations of the plurality of devices in the monitoring system.

According to the present invention, when a specific state assumed to occur in a facility is selected and input, the operation of a device associated with the specific state is output in control software of a monitoring system. Therefore, by checking whether the output operation is an assumed operation, it is possible to check in advance whether or not there is a problem in the control software of the monitoring system in a plant or the like other than the site where the system is installed. Therefore, even when a problem occurs on the site at the time of the construction of the monitoring system, it can be determined that the problem is caused by the construction on the site, and the time required for the operation check can be shortened. Further, since the confirmation of the adequacy of the control software is completed before the construction at the site, it is only necessary to perform the confirmation other than the confirmation of the adequacy of the control software, for example, the confirmation of the wiring connection or the like at the site. Therefore, since the number of confirmation items on site is reduced, there is a low possibility that the operation control other than the assumption of the device in the monitoring system is overlooked.

In the present invention, the monitoring system simulator may further include a timing selection input unit for automatically selecting the specific state from the plurality of states in a time-series manner.

According to the above configuration, since the operation states of the continuous devices with respect to the continuously generated specific states can be confirmed, a time-series operation of the devices for schedule management in the monitoring system can be confirmed.

In addition, when the monitoring system simulator includes the timing selection input unit, the monitoring system simulator may further include: a stop input unit that stops selection of continuity of the specific state and selects the specific state at a specific time; a fast-forward input unit that fast-forwards the specific time; and a rewind input section that rewinds the specific time.

According to the above configuration, since the selection of the continuity of the specific state can be stopped at the specific time, it can be confirmed whether or not the operation of the device on the control software is normal at the specific time. Further, since the specific time can be fast-forwarded or rewound, the state of each device at the specific time to be confirmed can be easily displayed, and the state of the device at the specific time can be easily confirmed.

Effects of the invention

According to the present invention, it is possible to check the device control assumed by the monitoring system in a short period of time and suppress unexpected operation control of the device in the monitoring system.

Drawings

Fig. 1 is a conceptual diagram illustrating the construction of a general monitoring system for short-term construction.

FIG. 2 is a conceptual diagram illustrating a method of use of a monitoring system simulator.

FIG. 3 is a block diagram of a monitoring system emulator.

Fig. 4 is a schematic diagram showing an example of a display image displayed on the display unit of the monitoring system simulator.

Fig. 5 is a partially enlarged schematic view of a part of the display image.

Description of the reference symbols

20 a control unit; 50 monitoring the system simulator; 71 a timing selection input section; 74 stop input section; 75 fast forward input; 76 rewinding the input; the system is monitored 90.

Detailed Description

Embodiments of the present invention will be described in detail below with reference to the drawings. Hereinafter, when a plurality of embodiments, modifications, and the like are included, it is assumed from the beginning that these features are appropriately combined to form another embodiment.

Fig. 1 is a schematic configuration diagram showing a monitoring system 90 capable of simulating operation control of a device in a facility to be monitored by using a monitoring system simulator disclosed in the present invention. First, the structure of the monitoring system 90, the construction of the monitoring system 90 generally performed in short-term construction, and problems in the construction will be described with reference to fig. 1.

The monitoring system 90 monitors the building. In this example, a case where the monitoring target is a building is described, but the monitoring target may be an amusement park, a marine museum, or the like, or may be any facility having a plurality of devices other than a building. As shown in fig. 1, the monitoring system 90 includes a central monitoring computer 61, a central monitoring server 62, and a central monitoring controller 63.

The central monitoring computer 61 is preferably constituted by a personal computer, a workstation, or the like. The central monitoring computer 61 is connected to the central monitoring server 62 and the central monitoring controller 63, and transmits and receives signals to and from the central monitoring server 62 and the central monitoring controller 63. The central monitoring computer 61 has an input unit including a plurality of keys, a mouse, and the like, and a system checker or the like can input a signal to the central monitoring controller 63 using the input unit. The central monitoring computer 61 has a display unit constituted by a monitor or the like, and the display unit displays the operating state of the devices 81-1 to 81-n in the building.

The central monitoring server 62 is connected to the central monitoring controller 63, and transmits and receives signals to and from the central monitoring controller 63. The central monitoring server 62 is provided with a database of data required when the central monitoring controller 63 controls the local facility controllers 80-1 to 80-n, and the required data can be retrieved and extracted appropriately.

The central monitoring controller 63 is connected to the devices 81-1 to 81-n in the building via a plurality of local device controllers 80-1 to 80-n (n is an arbitrary natural number, the same applies hereinafter). The devices 81-1 to 81-n include, for example, air conditioners, lighting, elevators, and automatic water-spraying fire extinguishing devices. The plurality of devices are determined for each facility. The central monitoring controller 63 is provided with control software for controlling the local equipment controllers 80-1 to 80-n to control the equipment 81-1 to 81-n. When the central monitoring controller 63 receives the input of the conditions from the central monitoring computer 61, it refers to the data in the central monitoring server 62 and outputs control signals based on the input conditions to the local facility controllers 80-1 to 80-n.

The local plant controllers 80-1 to 80-n are provided with control software for controlling the operations of the plants 81-1 to 81-n in accordance with control signals from the central monitoring controller 63. The local device controllers 80-1 to 80-n are built with a control circuit controlled by a signal from the central monitoring controller 63, and the control circuit includes a plurality of relays. When the local equipment controllers 80-1 to 80-n receive a control signal from the central monitoring controller 63, the on/off of each relay in the control circuit is determined. The local device controllers 80-1 to 80-n control the devices 81-1 to 81-n according to a control circuit configured by determining on and off of each relay.

In addition, fig. 1 shows a state where each of the local device controllers 80-1 to 80-n is connected to only one device 81-1 to 81-n, but actually each of the local device controllers 80-1 to 80-n is connected to a plurality of devices.

In general short-term construction, the monitoring system 90 is constructed on site, and whether or not the operation control of the devices 81-1 to 81-n is appropriate is also confirmed on site. Specifically, the central monitoring computer 61, the central monitoring server 62, and the central monitoring controller 63 are connected to each other on site, and the local facility controllers 80-1 to 80-n are also connected to the central monitoring controller 63 on site. Each of the devices 81-1 to 81-n is also connected to the corresponding local device controller 80-1 to 80-n on site, and by inputting a signal for realizing a specific state to the central monitoring computer 61, whether the device 81-1 to 81-n performs an assumed operation or not is confirmed on site.

In the construction of the monitoring system 90, when the devices 81-1 to 81-n unexpectedly operate during the operation check in the field, it is difficult to determine whether there is a problem in the control software of the central monitoring controller 63 that controls the operation of each of the devices 81-1 to 81-n, or there is a problem in the control software of the controllers 80-1 to 80-n for the faulty wiring connection or local devices in the field, and it may take a long time to perform the operation check.

Fig. 2 is a conceptual diagram illustrating a method of using the monitoring system simulator 50.

The monitoring system simulator 50 (hereinafter referred to as a unit simulator) 50 is preferably constituted by a personal computer, a workstation, or the like. As shown in fig. 2, the simulator 50 is used in connection with a central monitoring computer 61, a central monitoring server 62, and a central monitoring controller 63.

Fig. 3 is a block diagram of the emulator 50.

The simulator 50 includes an input unit 1, a display unit 5, a storage unit 15, and a control unit 20. The input unit 1 is composed of a plurality of operation units. In the case where the emulator 50 is a personal computer, the input section 1 includes a mouse and/or a plurality of keys. The input unit 1 is provided to input a specific state assumed to occur in a building. For example, a state in which a fire breaks out at a specific floor of a building, a state in which all or a part of lighting in the building is turned off when a predetermined time has elapsed, or the like can be input through the input unit 1.

The display unit 5 displays the status of each of the devices 81-1 to 81-n in the building by being controlled by the control unit 20. When the emulator 50 is a personal computer, the display unit 5 is configured by a monitor or the like, and the storage unit 15 is configured by a hard disk, a memory or the like. The storage unit 15 stores simulator software. As described above, when the central monitoring controller 63 outputs signals to the local equipment controllers 80-1 to 80-n, the local equipment controllers 80-1 to 80-n control the operations of the equipment 81-1 to 81-n based on the signals. The emulator software associates the signal of the central monitoring controller 63 with a signal indicating the operation state of the equipment 81-1 to 81-n controlled by the local equipment controllers 80-1 to 80-n.

When the specific state is input from the input unit 1, the central monitoring controller 63 that receives the signal from the input unit 1 outputs the signal to the simulator 50. Then, the simulator software associates the signal from the central monitoring controller 63 with the signal indicating the assumed operation state of each of the devices 81-1 to 81-n, and displays the associated operation state of each of the devices 81-1 to 81-n on the display unit 5. In the monitoring system 90, the central monitoring controller 63 actually controls the operation of the devices 81-1 to 81-n, and the simulator 50 simulates the control of the central monitoring controller 63, and displays the operation states of the devices 81-1 to 81-n under the simulation control on the display unit 5.

Fig. 4 is a diagram showing an example of a display image displayed on the display unit 5 of the emulator 50. In fig. 4, a case where n is 6 and the monitoring system 90 has 6 local device controllers 80-1 to 80-6 is specifically illustrated, but n may be any natural number as described above.

The display image shown in fig. 4 includes a local controller display unit (hereinafter referred to as an LC display unit) 70. The LC display unit 70 includes 6 specific local controller display units (hereinafter referred to as TLC display units) 70-1 to 70-6. As will be described in detail below, the TLC display sections 70-1 to 70-6 are used for inputting signals for causing the corresponding controllers 80-1 to 80-6 for the local devices to control the devices 81-1 to 81-6 so as to reproduce specific states, and for displaying output states of the devices 81-1 to 81-6 for the input signals. The display image includes a continuous output display unit 55 formed of a band-shaped region extending in the vertical direction. The display image includes a timing selection input unit 71, a time change input unit 72, a time interval change input unit 73, a stop input unit 74, a fast forward input unit 75, and a rewind input unit 76.

FIG. 5 is an enlarged view of the TLC display section 70-1. The TLC display section 70-1 has the same structure as the other TLC display sections 70-2 to 70-6. The structural description of the TLC display units 70-2 to 70-6 is omitted because the description refers to the structural description of the TLC display unit 70-1. Referring to fig. 5, the plurality of display units shown as the DIPIs are input display units, and the plurality of display units shown as the DO are output display units. When the input display unit is clicked, the management items and the current state related to the input display unit are displayed. The state of the input side is, for example, expressed as if it is ON (ON) state, the input display portion is lit with the 1 st color, and if it is OFF (OFF) state, the input display portion is not lit. The TLC display units 70-1 to 70-6 include all input display units constituting specific state input units. The 1 st color is preferably yellow, but the 1 st color may be any color other than yellow.

The system confirmer can input the specific state by appropriately clicking the input display unit. In the TLC display unit 70-1, CT1 to CT8 indicate slot numbers of the local apparatus controllers 80-1 corresponding to the TLC display unit 70-1. Each of the local device controllers 80-1 to 80-6 has a plurality of slots into which the control boards are inserted. The slot numbers are numbers assigned to the plurality of slots in the controllers 80-1 to 80-6 for the local devices. In the example shown in fig. 5, the DIPI00 of the card slot CT2, the DIPI03 of the card slot CT2, and the DI02J of the card slot CT5 are turned ON and lit in the 1 st color in response to an input from a system checker or the like. The specific state to be input is, for example, a state in which the lighting of the 1 st floor and the 3 rd floor is turned off and the air conditioner of the 2 nd floor is stopped.

When the specific state is input, the state of the device 81-1 corresponding to the specific state is displayed on the output display unit. When the output display unit is clicked, the management items and the current state related to the output display unit are displayed. The management items include, for example, 3-layer air conditioning, 4-layer lighting, and the like. The current state on the output side is represented, for example, by: if the state is ON, the output display part is lighted with the 2 nd color, and if the state is OFF, the output display part is not lighted. The TLC display units 70-1 to 70-6 include all of the output display units and the continuous output display unit 55 (see FIG. 4) as the equipment status output unit.

The 2 nd color is preferably set to a color different from the 1 st color, but may be set to the same color as the 1 st color. Preferably, the output-side 2 nd color is a striking color such as red that can call attention of a system checker or the like. In this example, the DO02 of the card slot CT5, the DOACC of the card slot CT5, the DO05C of the card slot CT8, and the DO05H of the card slot CT8 are turned ON and lit in the 2 nd color. These output states correspond to, for example, states in which the lighting of the 1 st floor and the 3 rd floor is turned off and the air conditioning of the 2 nd floor is stopped.

A system checker or the like can reproduce a specific state by appropriately selecting and operating a specific display unit from among the plurality of input-side display units and turning ON (ON) the specific display unit, and can check the state of the device in the specific state by checking the lighting state of the output display unit.

Referring again to fig. 4, the timing selection input section 71 is used to activate the following functions: a specific state generated in time series in a building to be managed is associated with the time at which the state is generated and continuously and automatically input. In building management, there are cases where specific states are linked, and for example, when the a device is operating, the B device is also operating. Thus, a schedule table in a specific period can be incorporated in advance as needed, and data of the schedule table can be stored in advance in the central monitoring server 62 or the central monitoring controller 63. The data of the schedule is data for causing a specific state to be continuously executed in time series, and is, for example: when 9 o' clock is reached, the door lock is unlocked, and the illumination is lightened; turn on the air conditioner at 9 am, turn off the air conditioner at 11 pm, etc. The schedule may also be different depending on external conditions such as season. In the present embodiment, a program for executing a plurality of schedules in a time-series manner in a specific state generated in a time-series manner is stored in advance in the central monitoring server 62 or the central monitoring controller 63. The system checker or the like can select and execute a specific schedule from among a plurality of schedules by dragging and clicking the timing selection input unit 71 with a mouse.

The time change input unit 72 is used to set an initial time of a specific state that occurs continuously in time series. When the time change input unit 72 is clicked, the time can be displayed, and by changing the time, the initial time of the continuous specific state can be selected. The time interval change input unit 73 sets the time interval of the specific state continuously generated in the simulation based on the schedule. When the time interval change input unit 73 is clicked, the time can be displayed, and by changing the time, the time interval of the specific state that occurs continuously can be selected.

Referring to fig. 4, the continuous output display unit 55 displays the states of the devices 81-1 to 81-6 in a specific state generated continuously in time series. In one example, the continuous output display unit 55 displays the year, month, day, time, ON (ON) or OFF (OFF) of the management items, and an alarm in each row. The sequential output display unit 55 displays the new history on the upper side of the old history, and the old history is gradually fed downward.

With continued reference to fig. 4, the stop input unit 74 is used to stop the automatic reproduction of the specific state that is chronologically continuous, and to select the specific state at the specific time. The fast-forward input unit 75 is used to fast-forward a specific time, and the rewind input unit 76 is used to rewind a specific time. The system checker or the like can easily select a specific time to be displayed by performing a mouse operation on the three

input units

74, 75, and 76.

Referring again to fig. 2, the display unit of the central monitoring computer 61 displays a display image corresponding to the display image displayed on the display unit of the simulator 50 described with reference to fig. 4 and 5. The monitor of the monitoring system 90 can reproduce a specific state through the input unit of the central monitoring computer 61. Since the central monitoring computer 61 is operated by a monitor, it is easy to understand a management item preferably indicating a device to be managed. Therefore, it is preferable to represent the management items by icons in the display image displayed on the display unit of the central monitoring computer 61. Icons of management items may also include, for example, illuminated icons and/or door icons.

According to the simulator 50 of the above embodiment, when a specific state assumed to occur in the building is selected and input, the states of the respective devices 81-1 to 81-6 associated with the specific state are output by the control software of the monitoring system 90. Therefore, by checking whether the output operation is the assumed operation, it is possible to check in advance whether there is a problem in the control software of the monitoring system 90 before the monitoring system 90 is constructed on site. Therefore, even when a problem occurs on the site at the time of the construction of the monitoring system 90, it can be determined that the problem is caused by the construction on the site, and the time required for the operation check can be shortened. Further, since the confirmation of the adequacy of the control software is completed before the construction at the site, it is only necessary to perform the confirmation other than the confirmation of the adequacy of the control software, for example, the confirmation of the wiring connection or the like at the site. Therefore, since the number of confirmation items on site is reduced, the possibility of overlooking unexpected operation control of the equipment in the monitoring system is also reduced.

Further, the time-series selection input unit 71 is provided for automatically selecting a specific state from a plurality of states in time series, so that a series of operations in time series of the respective devices 81-1 to 81-6 managed in the monitoring system 90 according to time can be confirmed.

In addition, the device also comprises: a stop input unit 74 that stops continuous selection and selects a specific state at a specific time; a fast-forward input unit 75 that fast-forwards a specific time; and a rewind input unit 76 for rewinding the specific time, so that the operation of the control software of each of the devices 81-1 to 81-6 at the specific time can be easily checked.

The present invention is not limited to the above-described embodiments and modifications thereof, and various improvements and modifications can be made within the scope of the matters recited in the claims of the present application and their equivalents.

For example, software for acquiring the time-related operation state data of the devices 81-1 to 81-n via the local device controllers 80-1 to 80-n and the central monitoring controller 63 may be installed in the central monitoring server 62. In the above-described embodiment, the example in which the emulator 50 includes the timing selection input unit 71, the stop input unit 74, the fast-forward input unit 75, and the rewind input unit 76 has been described, but the emulator may include the timing selection input unit and not include the stop input unit, the fast-forward input unit, and the rewind input unit. The emulator may not have a timing selection input unit, a stop input unit, a fast forward input unit, and a rewind input unit. The layout, the number, the shape, and the like of the input and output display portions in the display image displayed on the display portion are not limited to those described in fig. 4 and 5, and may be appropriately changed according to the specification.

Claims

1. A monitoring system simulator that simulates operation control of a plurality of devices in a monitoring system that monitors operations of the plurality of devices in a facility having the plurality of devices, the monitoring system simulator comprising a central monitoring controller that controls a plurality of local device controllers, wherein the monitoring system simulator comprises:

a specific state input section for selecting a specific state from a plurality of states supposed to be generated in the facility;

an apparatus state output section for outputting a state of the apparatus; and

and a control unit that associates the specific state with a state of the device corresponding to the specific state, based on a signal output by the central monitoring controller based on control software for controlling operations of the plurality of devices in the monitoring system and a signal from the specific state input unit, and displays the state of the associated device in the device state output unit.

2. The monitoring system simulator of claim 1,

the monitoring system simulator also has a timing selection input section for automatically selecting the specific state from the plurality of states in time series in succession.

3. The monitoring system simulator of claim 2,

the monitoring system simulator further has:

a stop input unit that stops selection of continuity of the specific state and selects the specific state at a specific time;

a fast-forward input unit that fast-forwards the specific time; and

a rewind input unit that rewinds the specific time.