WO2023149048A1 - Remote operation system - Google Patents

Abstract

A remote operation system, wherein: a server (3) is provided with a storage unit (31) for storing monitoring unit status information indicating the status of each of a plurality of remote monitoring units (4), and a status information transmission unit (35) for transmitting the monitoring unit status information stored in the storage unit (31) to each of the plurality of remote monitoring units (4); and each of the plurality of remote monitoring units (4) is provided with a display device (42) for displaying the monitoring unit status information transmitted from the status information transmission unit (35).

Description

remote control system

The present disclosure relates to a remote operation system that can resolve an error that has occurred in a work device through remote operation from a remote monitoring unit.

Conventionally, when an error occurs in a work device, there has been known a remote operation system capable of resolving the error by remote operation. In such a remote operation system, when an error occurs in the work device, information about the error (error information) is sent to the remote monitoring unit. Then, when the operator of the remote monitoring unit performs an error elimination operation (error elimination operation) based on the error information, the operation information is transmitted to the work device, and the work device operates according to the operation information, thereby eliminating the error. The problem is solved (for example, Patent Document 1 below).

JP 2021-015469 A

In such a remote operation system, when a plurality of remote monitoring units are installed, a server as a relay unit is arranged between the working device and the remote monitoring unit, and which remote monitoring unit to send the error information to. In other words, the configuration can be such that the server can select to which remote monitoring unit the error resolution operation job is given. In this case, the server grasps the status (state) of each remote monitoring unit, and transmits error information to the remote monitoring unit that is in a state where the operator can perform an error elimination operation.

However, even if the server knows the status of all remote monitors, each operator does not know the status of other remote monitors (that is, the status of other operators). Appropriate actions may not always be taken to smoothly proceed with processing, and a situation may occur in which error resolution processing in the entire remote operation system stagnate.

Therefore, the present disclosure aims to provide a remote operation system that allows each operator to take appropriate action according to the status of other remote monitoring units and prevents the situation where error resolution processing is stagnant. aim.

A remote operation system according to the present disclosure includes a plurality of working devices, a server, and a plurality of remote monitoring units. When an error occurs in one of the plurality of working devices, the server relays information about the error. An error is transferred to one of a plurality of remote monitoring units, and the operator of the remote monitoring unit that receives the information of the error that occurred among the multiple remote monitoring units receives the error information from the remote monitoring unit that receives the information of the error that occurred. It is configured to perform an operation to eliminate The server includes: a storage unit for storing monitoring unit status information indicating the status of each of the plurality of remote monitoring units; a status information transmission unit for transmitting the monitoring unit status information stored in the storage unit to each of the plurality of remote monitoring units; and each of the plurality of remote monitoring units has a display unit for displaying the status of other remote monitoring units among the plurality of remote monitoring units based on the monitoring unit status information transmitted from the status information transmitting unit.

According to the present disclosure, each operator can take appropriate actions according to the status of other remote monitoring units, and it is possible to prevent a situation in which error resolution processing is stagnant.

FIG. 1 is a configuration diagram of a remote operation system according to one embodiment of the present disclosure. FIG. 2 is a diagram showing information flow in the remote operation system according to the embodiment of the present disclosure. FIG. 3 is a side view of a working device that constitutes a remote control system according to an embodiment of the present disclosure; FIG. 4 is a perspective view of part of a working device included in the remote control system according to the embodiment of the present disclosure; FIG. 5 is a block diagram showing the control system of the remote operation system according to one embodiment of the present disclosure. FIG. 6A is a diagram illustrating an example of an image of an error occurrence location displayed on the display device of the remote monitoring unit included in the remote operation system according to the embodiment of the present disclosure; 6B is a diagram illustrating an example of an image of an error occurrence location displayed on the display device of the remote monitoring unit included in the remote operation system according to the embodiment of the present disclosure; FIG. FIG. 7 is a diagram showing an example of a presence/absence information input screen displayed on the display device of the remote monitoring unit provided in the remote operation system according to the embodiment of the present disclosure. FIG. 8A is a diagram showing an example of monitoring unit status information displayed on each display device of a plurality of remote monitoring units included in the remote operation system according to the embodiment of the present disclosure. FIG. 8B is a diagram illustrating an example of monitoring unit status information displayed on each display device of each of a plurality of remote monitoring units included in the remote operation system according to the embodiment of the present disclosure; FIG. 8C is a diagram illustrating an example of monitoring unit status information displayed on each display device of a plurality of remote monitoring units included in the remote operation system according to the embodiment of the present disclosure; FIG. 9 is a diagram showing an example of monitoring unit status information displayed on the display device of the remote monitoring unit included in the remote operation system according to the embodiment of the present disclosure.

Embodiments of the present disclosure will be described below with reference to the drawings. 1 and 2 show a remote control system 1 according to one embodiment of the present disclosure. The remote operation system 1 includes a work line 2L composed of a plurality of work devices 2, a server 3 as a relay section, and a plurality of remote monitoring sections 4. As shown in FIG. Each working device 2 and server 3 and each remote monitoring unit 4 and server 3 are connected by wire or wirelessly so as to be able to communicate with each other. Each remote monitoring unit 4 is operated by an operator OP sitting at an operation seat (not shown) provided for each remote monitoring unit 4 .

FIG. 3 is a side view of the work device 2 that configures the remote control system 1 according to one embodiment of the present disclosure. Each work device 2 constituting the work line 2L is, in the present embodiment, a component mounting device that performs work (component mounting work) to mount the component BH on the board KB. The working device 2 includes a base 11, a conveyor 12, a tape feeder 13, a head moving mechanism 14, a mounting head 15, and a board camera 16, as shown in FIG.

FIG. 4 is a perspective view of part of the work device 2 included in the remote control system 1 according to one embodiment of the present disclosure. In FIG. 3, the transport conveyor 12 extends horizontally on the base 11 and transports the substrate KB horizontally from one end to the other end. The tape feeder 13 draws out and conveys the carrier tape CT wound around the reel RL by a built-in sprocket 13S (see also FIG. 4).

A large number of parts BH are enclosed in a line in the carrier tape CT. The tape feeder 13 supplies the component BH to the component supply position 13K by feeding the carrier tape CT toward the transport conveyor 12 (FIG. 4).

The head moving mechanism 14 consists of, for example, an XY table mechanism, and moves the mounting head 15 within the horizontal plane. The mounting head 15 has a plurality of downwardly extending nozzles 15N (FIGS. 3 and 4).

In FIGS. 3 and 4, the substrate camera 16 is attached to the mounting head 15 with the imaging optical axis facing downward. The substrate camera 16 is moved in the horizontal plane direction together with the mounting head 15 by the head moving mechanism 14 .

FIG. 5 is a block diagram showing the control system of the remote operation system 1 according to one embodiment of the present disclosure. The operation of each section of each working device 2 is controlled by a working device control section 17 (FIG. 3) which is a control section thereof. Specifically, the work device control unit 17 controls each operation of the transport conveyor 12, the tape feeder 13, the head moving mechanism 14, and the mounting head 15, as shown in FIG. As a result, the transport conveyor 12 transports and positions the board KB, and each tape feeder 13 supplies the component BH to the component supply position 13K. The head moving mechanism 14 moves the mounting head 15, and the mounting head 15 picks up the component BH with the nozzle 15N (FIG. 4). The board camera 16 is controlled by the work device control section 17 to perform an imaging operation. Image data captured by the board camera 16 is sent to the work device control section 17 .

When the work device 2 performs the component mounting work, first, the transport conveyor 12 is operated to carry in the board KB and position it at the work position. When the substrate KB is positioned at the working position, the head moving mechanism 14 is operated to move the mounting head 15 above the substrate KB, and the substrate camera 16 is caused to take an image of the substrate KB. When the board camera 16 takes an image of the board KB, the board KB is recognized based on the image.

When the work device 2 recognizes the board KB, it causes the tape feeder 13 to feed the component BH and causes the mounting head 15 to perform component pick-up and component mounting operations. The mounting head 15 sucks (picks up) the component BH supplied by the tape feeder 13 with the nozzle 15N in the component picking operation, and mounts the picked up component BH at a predetermined position on the board KB in the component mounting operation.

After mounting all the components BH to be mounted on the board KB by causing the mounting head 15 to repeatedly perform the component pick-up operation and the component mounting operation, the work device 2 operates the conveyer 12 to carry out the board KB from the work position. do. This completes the component mounting work for each board KB.

The work device 2 performs the component mounting work according to the procedure described above, but some kind of error may occur in the process. In the remote operation system 1 according to the present embodiment, when an error occurs in the work device 2 constituting the work line 2L, the error can be resolved by remote operation from the remote monitoring unit 4. there is The explanation is given below.

5, the work device control unit 17 of each work device 2 includes an error detection unit 21, an error information acquisition unit 22, an error information transmission unit 23, and a cancellation operation information reception unit 24. The error detection unit 21 detects any error that occurs in the work device 2 and interrupts the operation of all or part of the work device 2 . The error information acquisition unit 22 identifies the error occurrence location (error occurrence location) detected by the error detection unit 21, and acquires information (type and content) of the error that has occurred as "error information."

If the board camera 16 can capture an image of the error occurrence location, the error information acquisition unit 22 operates the head moving mechanism 14 to move the board camera 16 above the error occurrence location, and moves the error occurrence location to the substrate. An image is captured by the camera 16 . For example, if the mounting head 15 fails to pick up a component BH from a certain tape feeder 13 a fixed number of times in succession, the component supply position 13K of the tape feeder 13 is specified as the error occurrence location, and the component A still image or moving image of the supply position 13K is taken by the substrate camera 16. FIG.

The error information transmission unit 23 transmits the error information acquired by the error information acquisition unit 22 to the server 3 (Fig. 2). When the error occurrence location is imaged by the board camera 16, the image data (still image or moving image data) of the error occurrence location is sent to the server 3 as part of the error information.

5, the server 3 includes a storage section 31, a selection section 32, a transfer section 33, a status change section 34, and a status information transmission section 35. In addition to the error information transmitted from the work device 2, the storage unit 31 stores various data and information at any time.

The selection unit 32 is in a state in which the operator OP can perform an operation (error elimination operation) for resolving an error that has occurred in the work device 2 as a transmission (transfer) destination of the error information transmitted from the work device 2. A certain remote monitoring unit 4 is selected. Here, "the remote monitoring unit 4 in a state where the operator OP can perform an error resolution operation" specifically means that the operator OP is present at the operation seat at the time the remote monitoring unit 4 is selected. The remote monitoring unit 4 is in a state where the operator OP is not performing an error elimination operation.

When there are a plurality of remote monitoring units 4 that are candidates for error information transmission destinations, the selecting unit 32 selects one remote monitoring unit 4 based on a predetermined criterion. For example, if a criterion is set to "preferentially select the remote monitoring unit 4 for which the longest time has elapsed since the end of the last error resolution operation", a plurality of candidate Of the remote monitoring units 4, the remote monitoring unit 4 for which the longest time has elapsed since the end of the last error resolution process is selected as the transmission destination of the error information.

Monitoring unit status information indicating the status of each remote monitoring unit 4 is stored in the storage unit 31 . The status of each remote monitoring unit 4 changes depending on the action of the operator OP. When the status of each remote monitoring unit 4 changes, the monitoring unit status information stored in the storage unit 31 is changed by the status changing unit 34 . When selecting the remote monitoring unit 4 to which the error information is to be sent, the selecting unit 32 selects based on the monitoring unit status information of each remote monitoring unit 4 stored in the storage unit 31 at the time of selection.

The transfer unit 33 transmits (transfers) the error information transmitted from the work device 2 to one remote monitoring unit 4 selected by the selection unit 32 . As a result, the error information sent from the working device 2 to the server 3 is sent (transferred) to one of the plurality of remote monitoring units 4 .

In FIG. 1, each of the plurality of remote monitoring units 4 is composed of, for example, a personal computer. Each remote monitoring section 4 includes a remote monitoring control section 41, a display device 42 and an input device 43, as also shown in FIG.

5, the remote monitoring control unit 41 includes an error information receiving unit 51, an error information display control unit 52, a clearing operation information transmitting unit 53, a presence/absence input control unit 54, and a presence/absence information notification unit 55. It has The error information receiving section 51 receives error information transmitted (transferred) from the server 3 , and the error information display control section 52 causes the display device 42 to display the error information received by the error information receiving section 51 .

6A and 6B are diagrams showing an example of an image of an error occurrence location displayed on the display device 42 of the remote monitoring unit 4 included in the remote operation system 1 according to the embodiment of the present disclosure. FIG. 6A shows an image GZ of an error occurrence location as an example of error information displayed on the display device 42 by the error information display control unit 52 . The image shown in FIG. 6A shows an area including the component supply position 13K of the tape feeder 13 when the component BH is picked up incorrectly as described above. It matches the lower end position (nozzle lower end position KC). When the image of the error occurrence location is displayed on the display device 42, the operator OP performs an error elimination operation from the input device 43 while viewing the image.

The nozzle lower end position KC should originally match the component supply position 13K, but in the image of FIG. 6A in which an error has occurred, the nozzle lower end position KC and the component supply position 13K do not match. In this case, the operator OP moves the position of the mounting head 15 during component pickup so that the nozzle lower end position KC coincides with the component supply position 13K of the tape feeder 13 . Specifically, an offset for moving the position of the mounting head 15 during component pickup is performed so that the difference between the nozzle lower end position KC and the component supply position 13K in the image of FIG. 6A is canceled and the state of FIG. 6B is obtained. The amount (direction of movement and amount of movement) is input from the input device 43 .

The elimination operation information transmission unit 53 transmits to the server 3 the information of the error elimination operation input from the input device 43 (elimination operation information). When the server 3 receives the cancellation operation information, it transmits (transfers) the received cancellation operation information from the transfer unit 33 to the working device 2 that is the sender of the error information (FIG. 2).

The work device 2 to which the solution operation information has been sent (transferred) from the server 3 (the work device 2 that has sent the error information to the server 3) receives the solution operation information by the solution operation information receiving unit 24 . The work device control unit 17 of the work device 2 that has received the cancellation operation information cancels the error by activating the part related to the error occurrence location based on the received cancellation operation information. When the error is resolved, the work device control unit 17 cancels the interrupted state of the component mounting work and restarts the component mounting work.

As described above, the remote operation system 1 according to the present embodiment includes a plurality of working devices 2, a server 3, and a plurality of remote monitoring units 4. When an error occurs in any of the plurality of working devices 2, the error occurs. The server 3 relays the error information received and transfers it to one of the plurality of remote monitoring units 4, and the operator OP of the remote monitoring unit 4 receives the transfer of the error information (error information) from the remote monitoring unit 4. An operation (job) is performed to resolve the error.

FIG. 7 is a diagram showing an example of a presence/absence information input screen displayed on the display device 42 of the remote monitoring unit 4 included in the remote operation system 1 according to the embodiment of the present disclosure. In the remote operation system 1 according to the present embodiment, the operator OP of each remote monitoring unit 4 can notify the server 3 when leaving the operator's seat of the remote monitoring unit 4 in charge. When the operator OP intends to leave the operating seat of the remote monitoring unit 4 he is in charge of, he/she first performs a predetermined operation using the input device 43 . As a result, the presence/absence input control unit 54 of the remote monitoring control unit 41 causes the display device 42 to display a presence/absence information input screen 60 as shown in FIG. 7, for example. The presence/absence information input screen 60 is provided with a presence button 61 and an absence button 62 .

The operator OP operates the presence button 61 from the input device 43 when he/she is seated at the operating seat of the remote monitoring unit 4 in charge, and operates the leave button 62 from the input device 43 before leaving the operating seat. After leaving the operating seat by operating the leaving button 62, the operator OP operates the presence button 61 when returning to the operating seat and taking a seat again.

The operator OP is temporarily unable to respond to new error information from the time he/she leaves the operator's seat of the remote monitoring unit 4 until he/she returns to the operator's seat. For this reason, the operation of the leave button 62 by the operator OP corresponds to an "unsupportable input" indicating that the operator is temporarily incapable of responding to new error information (unable to respond). , the input device 43 of the remote monitoring unit 4 functions as an input unit for performing an unsupportable input.

The presence button 61 and the leave button 62 are designed to be lit alternatively, the one that was operated most recently lights up and the other goes out. FIG. 7 shows a state in which the presence button 61 that has been operated most recently by the operator OP is lit, and the other leave button 62 is not lit.

When the operator OP operates the presence button 61 , the presence/absence information notification unit 55 lights the presence button 61 and transmits the presence button operation information to the server 3 . As a result, the server 3 is notified that the operator OP of the remote monitoring unit 4 is present, and the server 3 recognizes that the operator OP is present at the remote monitoring unit 4 .

On the other hand, when the operator OP operates the leave button 62 , the presence/absence information notification unit 55 lights the leave button 62 and transmits the leave button operation information to the server 3 . As a result, the server 3 is notified that the operator OP of the remote monitoring unit 4 is away from the seat, and the server 3 recognizes that the operator OP of the remote monitoring unit 4 is away from the seat.

As described above, in the present embodiment, the presence/absence information notification unit 55 provided in each remote monitoring unit 4 responds to the fact that the operator OP has operated the absence button 62 from the input device 43, that is, from the input unit. This is a notifying section that notifies the server 3 that an invalid input has been made.

Based on the error information sent to the remote monitoring unit 4, the presence button operation information, the leaving button operation information, and the cancellation operation information sent from the remote monitoring unit 4, the server 3 causes the remote monitoring unit 4 to "wait." It determines which of the statuses of "in operation", "operating", and "away", and stores information indicating the processing status of each remote monitoring unit 4 in the storage unit 31 as monitoring unit status information. When the processing status is changed, the status changing unit 34 changes the processing status, and stores (overwrites) the changed processing status in the storage unit 31 again.

Here, the "waiting" status is a state in which the operator OP is at the operation seat of the remote monitoring unit 4 (is present) but is not performing an error resolution operation, that is, waiting for error information to be sent. This status indicates that the The "operating" status is a status indicating that the operator OP who is present is performing an error elimination operation, and the "away" status is a status indicating that the operator OP is away from the operator's seat. be.

When the presence button operation information is first sent from the remote monitoring part 4, the status changing part 34 of the server 3 sets the status of the remote monitoring part 4 to "waiting" and stores it in the storage part 31. . Since the operator OP of the remote monitoring unit 4 whose status is "waiting" is in a situation where he can perform an operation to resolve the error that has occurred in the work device 2, the server 3 is in a state where the remote monitoring unit 4 whose status is "waiting" can be used as a candidate for the destination of the error information.

When the error information is sent to the remote monitoring unit 4 whose status is "waiting", the status changing unit 34 changes the status of the remote monitoring unit 4 stored in the storage unit 31 from "waiting" to "operating". ” and stores (overwrites) in the storage unit 31 again. Then, the status of the remote monitoring unit 4 is maintained as "in operation" until the remote monitoring unit 4 sends the cancellation operation information. When resolution operation information is sent from the remote monitoring unit 4 whose status is "in operation", the status change unit 34 changes the status of the remote monitoring unit 4 stored in the storage unit 31 from "in operation" to " "Standby" and stored again in the storage unit 31.

The status changing unit 34 changes the status of the remote monitoring unit 4 stored in the storage unit 31 to "waiting" when the leaving button operation information is sent from the remote monitoring unit 4 whose status is "waiting". is changed to "away from seat" and stored again in the storage unit 31. - 特許庁When the presence button operation information is sent from the remote monitoring unit 4 whose status is "Away", the server 3 changes the status of the remote monitoring unit 4 stored in the storage unit 31 to "Away". ' is changed to 'currently seated' and stored again in the storage unit 31 .

As described above, in the present embodiment, the server 3 updates the status of the remote monitoring unit 4 that has been notified by the presence/absence information notification unit 55 that the absence button 62 has been operated as an unsupportable input. is changed to a status indicating that the user is temporarily unable to respond to new error information (here, "away" status).

Here, if the status of the remote monitoring unit 4 is "in operation", the remote monitoring unit 4 is temporarily unable to respond to new error information. Also, as described above, when the status of the remote monitoring unit 4 is "away", the remote monitoring unit 4 is temporarily unable to respond to new error information. For this reason, the server 3 does not transmit error information of an error that has occurred in the work device 2 to the remote monitoring unit 4 whose status is "operating" or "away", and whose status is "waiting". Error information is sent to the remote monitoring unit 4 .

As described above, in the remote operation system 1 according to the present embodiment, the server 3 does not send error information to the remote monitoring unit 4, which is temporarily unable to respond to new error information. Error information is transmitted only to the remote monitoring unit 4 that can respond to the information. Therefore, an error sent by the server 3 to the remote monitoring unit 4 can be immediately dealt with by the operator OP.

Further, in the present embodiment, the status information transmission unit 35 of the server 3 transmits the monitoring unit status information stored in the storage unit 31 to each remote monitoring unit 4, and each remote monitoring unit 4 receives the information sent from the server 3. The status of each remote monitoring unit 4 is displayed based on the monitoring unit status information. Since the operator OP of each remote monitoring unit 4 can know the status of the remote monitoring unit 4 he/she operates without displaying it on the display device 42, the display device 42 shows at least the status of the other remote monitoring units 4. It is enough if the status of is displayed.

8A to 8C are diagrams showing an example of monitoring unit status information displayed on the display device 42 of each of the plurality of remote monitoring units 4 included in the remote operation system 1 according to the embodiment of the present disclosure. For example, in the remote operation system 1 having three remote monitoring units 4 (remote monitoring unit "1", remote monitoring unit "2", remote monitoring unit "3"), the status of the remote monitoring unit "1" is "waiting , the status of the remote monitoring unit "2" is "away", and the status of the remote monitoring unit "3" is "operating". At this time, as shown in FIG. 8A, the display device 42 of the remote monitoring unit "1" shows that the status of the remote monitoring unit "2" is "away" and the status of the remote monitoring unit "3" is "operating". is displayed. Further, the display device 42 of the remote monitoring unit "2" displays that the status of the remote monitoring unit "1" is "waiting" and the status of the remote monitoring unit "3" is "operating" ( Figure 8B). In addition, the display device 42 of the remote monitoring unit "3" displays that the status of the remote monitoring unit "1" is "waiting" and the status of the remote monitoring unit "2" is "away" ( Figure 8C).

The operator OP of each remote monitoring unit 4 can determine whether the status of the other remote monitoring units 4 other than the remote monitoring unit 4 operated by the operator is "waiting", "operating", or "away from seat". Therefore, when the operator OP tries to leave the seat, he/she can judge whether it is right or wrong and take appropriate measures. For example, if it is determined that the remote monitoring unit 4 that can respond to error information will be completely lost when the user leaves his/her seat, he/she can refrain from leaving and prepare for the next error information sent from the server 3. . As described above, in the remote operation system 1 according to the present embodiment, the operator OP can take appropriate measures according to the status of the other remote monitoring units 4, and the error resolution processing of the remote operation system 1 as a whole is delayed. It is possible to prevent an accidental situation.

As described above, according to the remote operation system 1 of the present embodiment, each operator OP of the remote monitoring unit 4 can know what the status of the other remote monitoring units 4 is. Appropriate actions can be taken according to the status of the monitoring unit 4. For this reason, for example, in a situation where the remote monitoring unit 4 that can respond to new error information disappears completely when the operator leaves his/her seat, the operator OP can refrain from leaving his/her seat, and the error resolution processing is delayed. can be prevented.

FIG. 9 is a diagram showing an example of monitoring unit status information displayed on the display device 42 of the remote monitoring unit 4 included in the remote operation system 1 according to the embodiment of the present disclosure. Although the embodiments of the present disclosure have been described so far, the present disclosure is not limited to the above, and various modifications and the like are possible. For example, in the above-described embodiment, the display device 42 of the destination remote monitoring unit 4 displays only the status of the other remote monitoring units 4 other than the remote monitoring unit 4 of the destination. However, the status of the destination remote monitoring unit 4 may be displayed. In this case, the same screen (FIG. 9) is displayed on the display devices 42 of the remote monitoring unit "1", the remote monitoring unit "2", and the remote monitoring unit "3". Further, in the above-described embodiment, a component mounting device is shown as an example of the working device 2, but the working device 2 may be a working device other than the component mounting device.

To provide a remote operation system that allows each operator to take appropriate actions according to the status of other remote monitoring units and prevents the delay of error resolution processing.

1 remote operation system 2 work device 3 server 4 remote monitoring unit 31 storage unit 34 status change unit 35 status information transmission unit 41 remote monitoring control unit 42 display device (display unit)
43 Input device (input unit)
51 Error information reception unit 52 Error information display control unit 53 Cancellation operation information transmission unit 54 Presence/absence input control unit 55 Presence/absence information notification unit (notification unit)
60 Presence/absence information input screen 61 Presence button 62 Absence button GZ Image OP Operator

Claims (4)

1. a plurality of work devices, a server, and a plurality of remote monitoring units, wherein when an error occurs in one of the plurality of work devices, the server relays information about the occurred error to monitor the plurality of remote monitors and from the remote monitoring unit to which the operator of the remote monitoring unit that has received the transfer of the occurred error information among the plurality of remote monitoring units receives the transfer of the occurred error information. A remote operation system configured to perform an operation to resolve the error,
   The server is
   a storage unit that stores monitoring unit status information indicating the status of each of the plurality of remote monitoring units;
   a status information transmission unit that transmits the monitoring unit status information stored in the storage unit to each of the plurality of remote monitoring units;
   Each of the plurality of remote monitoring units
   A remote operation system comprising a display unit that displays the status of another remote monitoring unit among the plurality of remote monitoring units based on the monitoring unit status information transmitted from the status information transmitting unit.
2. 　The remote operation system according to claim 1, wherein the monitoring unit status information includes a status indicating that the monitoring unit is temporarily unable to respond to new error information.
3. each of the plurality of remote monitoring units includes an input unit for performing an unresponsive input indicating that the remote monitoring unit is temporarily unable to respond to the new error information, and an operator inputting the unresponsive input from the input unit. and a notification unit that notifies the server that the
   The server temporarily associates the status of the remote monitoring unit notified by the notifying unit of the plurality of remote monitoring units that the unresponsive input has been made with the new error information. 3. The remote operation system according to claim 2, wherein the status is changed to that the status is not available.
4. The remote operation system according to claim 3, wherein the unresponsive input is input when the operator leaves the remote monitoring unit.

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