KR102449484B1 - System for monitoring launch and recovery apparatus - Google Patents

Abstract

An embodiment of the present invention provides a system for monitoring a dust recovery device, and more specifically, a system for monitoring a dust recovery device having a plurality of parts, comprising: a sensor module for detecting state information of the dust recovery device; a controller that determines the current state of the dust recovery device based on the state information and generates a control signal including information on the determined current state; and a notification unit for displaying, wherein the control unit controls the notification unit to display information on the current state of the trash recovery device in real time by using the control signal.

Description

System for monitoring launch and recovery apparatus

The present invention relates to a system, and more particularly, to a system for monitoring a dust recovery device.

Remote diving bells may be operated at sea, etc. Diving bells are designed to dispose of facilities that descend into the sea using A-frames and wire drums located on offshore facilities or ships, release them into the sea, and salvage them after use. A true recovery device for launching and recovering a diving bell is operated with a plurality of parts, and the need for a system capable of efficiently maintaining and managing the parts constituting such a true recovery device is increasing.

Republic of Korea Patent Registration No. 10-1908914 Republic of Korea Patent Registration No. 10-2019053

The technical task to be achieved by the present invention is to minimize the time required for repairing failures and increase device management efficiency by identifying and responding to the lifespan and status of parts before failure occurs through monitoring of the dust recovery device. To provide a dust recovery device monitoring system.

The technical problems to be achieved by the present invention are not limited to the technical problems mentioned above, and other technical problems not mentioned can be clearly understood by those of ordinary skill in the art to which the present invention belongs from the description below. There will be.

In order to achieve the above technical object, a dust recovery device monitoring system according to an embodiment of the present invention is a system for monitoring a dust recovery device having a plurality of parts, and a sensor for detecting state information of the dust recovery device a module; a controller that determines the current state of the dust recovery device based on the state information, and generates a control signal including information on the determined current state; information on the current state determined by the controller and a notification unit displaying to the outside, wherein the control unit may control the notification unit to display information about the current state of the dust recovery device in real time by using the control signal.

In an embodiment of the present invention, the sensor module may include a plurality of sensor units, and the plurality of sensor units may be respectively disposed on the plurality of component units to detect state information of each of the plurality of component units.

In an embodiment of the present invention, each of the plurality of sensor units may include a first measurement unit for measuring the usage time of the component part, and a second measurement unit for measuring the load applied to the component unit.

In one embodiment of the present invention, the control unit, receives the use time of the component part measured by the first measurement unit, compares the use time with a preset life reference value to determine whether to replace the component part have.

In an embodiment of the present invention, the control unit may control the notification unit to display a signal instructing replacement of the component unit when the usage time of the component unit exceeds the preset life reference value.

In an embodiment of the present invention, the control unit receives the load measurement value applied to the component part measured by the second measurement unit, compares the load measurement value with a preset load reference value, whether the component part is overloaded can be judged

In one embodiment of the present invention, the control unit, when the measured load applied to the component exceeds the preset load reference value, control the notification unit to display a signal indicating that the component is in an overload state have.

In an embodiment of the present invention, a plurality of preset life reference values are set, and the plurality of preset life reference values may include a first life reference value and a second life reference value greater than the first life reference value.

In one embodiment of the present invention, the control unit, when the usage time of the component part is greater than the first life reference value and less than the second life reference value, display a first signal notifying the replacement schedule of the part part. You can control the notification unit.

In an embodiment of the present invention, the controller may control the notification unit to display a second signal instructing replacement of the component when the usage time of the component is greater than the second life reference value.

The dust recovery device monitoring system according to the embodiments of the present invention is installed on a ship together with the dust recovery device to monitor the dust recovery device, so that the state of each part and sub-parts of the dust recovery device can be grasped in real time, , when replacement is required due to a service life or damage problem of a part or sub-part of the seismic recovery device of a ship located in the sea, an immediate replacement can be ordered.

In addition, by using the dust recovery device monitoring system according to the embodiments of the present invention, by grasping the status of spare parts stored in the ship in real time, before the spare parts are all exhausted, additional spare parts are sent to the outside of the ship. you can request Thereby, it is possible to maintain a state in which a certain amount of spare parts are provided in the ship, so that the parts or sub-parts requiring replacement can be quickly replaced.

It should be understood that the effects of the present invention are not limited to the above-described effects, and include all effects that can be inferred from the configuration of the invention described in the description or claims of the present invention.

1 shows a dust recovery device monitoring system according to an embodiment of the present invention.
FIG. 2 is a flowchart schematically illustrating a monitoring process of the dust recovery device monitoring system of FIG. 1 .
3 schematically illustrates a process in which a signal measured by a sensor module is transmitted to a control unit.
4 is a flowchart illustrating a method of monitoring the current state of each part provided in the dust recovery device according to an embodiment of the present invention.
5 is a flowchart illustrating a method of determining whether to replace each part provided in the dust recovery device according to an embodiment of the present invention.
6 is a flowchart illustrating a method of determining whether to replace each part provided in the dust recovery device according to another embodiment of the present invention.
7 is a flowchart illustrating a method of determining whether each component part provided in the dust recovery device is in an overload state according to another embodiment of the present invention.

Hereinafter, the present invention will be described with reference to the accompanying drawings. However, the present invention may be embodied in several different forms, and thus is not limited to the embodiments described herein. And in order to clearly explain the present invention in the drawings, parts irrelevant to the description are omitted, and similar reference numerals are attached to similar parts throughout the specification.

Throughout the specification, when a part is "connected (connected, contacted, coupled)" with another part, it is not only "directly connected" but also "indirectly connected" with another member interposed therebetween. "Including cases where In addition, when a part "includes" a certain component, this means that other components may be further provided without excluding other components unless otherwise stated.

The terms used herein are used only to describe specific embodiments, and are not intended to limit the present invention. The singular expression includes the plural expression unless the context clearly dictates otherwise. In the present specification, terms such as “comprise” or “have” are intended to designate that a feature, number, step, operation, component, part, or combination thereof described in the specification exists, but one or more other features It is to be understood that this does not preclude the possibility of the presence or addition of numbers, steps, operations, components, parts, or combinations thereof. Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 shows a dust recovery device monitoring system according to an embodiment of the present invention. FIG. 2 is a flowchart schematically illustrating a monitoring process of the dust recovery device monitoring system of FIG. 1 , and FIG. 3 is a schematic diagram illustrating a process in which a signal measured by a sensor module is transmitted to a control unit.

1 to 3 , the earth recovery apparatus monitoring system 1 may be a system for monitoring the launch and recovery apparatus 10 installed on a ship or a water structure. At this time, the true recovery device 10 may be a device for launching or recovering the diving bell (D) by being connected to the diving bell (D). In this case, the diving bell (D) connected to the dust recovery device 10 may enter the water from the water by the dust recovery device 10, or move from the water to the water surface.

Before describing the dust recovery device monitoring system 1 in detail, an embodiment of the dust recovery device 10 to be monitored will be described. The dust recovery device 10 may include a support portion S, a winding module 200 , an intermediate connection unit 300 , a lifting unit 500 , a frame unit 400 , and a lifting unit 500 . have. In addition, the dust recovery device 10 may further include a guide unit (G).

The support S may be installed on a ship (P) or an aquatic structure, where the aquatic structure may be, for example, a pier, an offshore drilling rig, an offshore plant, or the like. The support (S) may refer to a portion in which the dust recovery device 10 is installed in the vessel (P). In one embodiment, the support (S) is a part of the ship (P) or a part of the water structure, as another embodiment, the support (S) may be a structure installed separately on the ship (P) or a water structure. In this case, the support part S may include a material capable of maintaining rigidity. For example, the support part S may include a metal material.

The winding module 200 may raise or lower the diving bell (D). At this time, the winding module 200 may be disposed on the support part (S). In the winding module 200 , a cable may be wound, or a wound cable may be unwound. The winding module 200 may raise or lower the diving bell (D) connected to the cable, and detailed details thereof will be described below. In this case, the winding module 200 may include a first winding unit 210 , a second winding unit 220 , and a third winding unit 230 .

The first winding unit 210 may wind or unwind the first cable r1. The first cable r1 may connect the first winding unit 210 and the lifting unit 500 to be described later. In this case, the first cable (r1) may be connected to the diving bell (D) via the lifting unit (500). As an embodiment, when the first winding unit 210 winds the first cable (r1), the diving bell (D) connected to the first cable (r1) may rise. As another embodiment, when the first winding unit 210 unwinds the first cable (r1), the diving bell (D) connected to the first cable (r1) may descend. That is, by the first winding unit 210, the height of the diving bell (D) with respect to the spoon (水底) can be adjusted. The first winding unit 210 may be, for example, a winch, and in this case, the first winding unit 210 may be defined as a main winch.

The second winding unit 220 may wind or unwind the second cable r2 . The second cable r2 may connect the second winding unit 220 and the lifting unit 500 . In this case, the second cable r2 may be connected to the guide unit G via the elevating unit 500 . As an embodiment, when the second winding unit 220 winds the second cable r2 , the guide unit G connected to the second cable r2 may rise. As another embodiment, when the second winding unit 220 unwinds the second cable r2 , the guide unit G connected to the second cable r2 may descend. That is, the height of the guide unit G with respect to the spoon may be adjusted by the second winding unit 220 . The second winding unit 220 may be, for example, a winch, and in this case, the second winding unit 220 may be defined as a sub winch or a guide winch.

On the other hand, the guide unit (G) can guide the lower movement of the diving bell (D) by first reaching a position to descend the diving bell (D). In this case, the guide unit (G) connected to the second winding unit 220 may be disposed under the diving bell (D). When an error or malfunction occurs in the operation of the first winding unit 210, or the first cable r1 is cut, the guide unit G is combined with the diving bell D to cause the diving bell D to rise. can That is, when a problem occurs in the upper movement of the diving bell (D), when the second winding unit 220 winds the second cable (r2), the guide unit (G) is coupled to the diving bell (D) to dive It can ascend by supporting the bell (D) upwards. Accordingly, despite the failure or operation error of the first winding unit 210, as the guide unit (G) rises, the diving bell (D) may also rise together.

The third winding unit 230 may wind or unwind the third cable r3 . The third cable (r3) may be connected to the diving bell (D) via the elevating unit (500). In this case, the third cable r3 may include a network cable (not shown) and/or a gas supply pipe (not shown). In this case, the gas supply pipe may supply gas to the diving bell (D). Here, the gas supplied through the gas supply pipe may be, for example, oxygen gas. The third winding unit 230 may be, for example, a winch, and in this case, the third winding unit 230 may be defined as an umbilical winch.

The intermediate connection unit 300 may be disposed between the winding module 200 and the elevating unit 500 . In this case, the cable may be connected to the diving bell (D) from the winding module 200, through the intermediate connection unit 300 and the elevating unit 500 in turn. In this case, the intermediate connection unit 300 may include a connection body 310 and an intermediate pulley 320 .

The connection body 310 may be disposed on the support part S. Specifically, the connection body 310, the lower end of the connection body 310 is coupled to the upper surface of the support portion (S), the upper end of the connection body 310 is a column shape extending toward the upper side of the support portion (S). have. An upper plate 330 may be provided at an upper end of the connection body 310 . The upper plate 330 may extend from the top of the connection body 310 in a direction perpendicular to the height direction of the connection body 310 toward the outside of the connection body 310 .

The intermediate pulley 320 may be disposed on the upper plate 330 . Specifically, the intermediate pulley 320 may be installed at the lower end of the upper plate 330 . In this case, the intermediate pulley 320 may be connected to at least one of the first cable r1 , the second cable r2 , and the third cable r3 .

One end of the first cable (r1) is connected to the diving bell (D) via the intermediate pulley 320 and the elevating unit 500, and the other end of the first cable (r1) can be connected to the first winding unit 210. have. One end of the second cable r2 may be connected to the guide unit G via the intermediate pulley 320 and the elevating unit 500 , and the other end of the second cable r2 may be connected to the second winding unit 220 . have. And, one end of the third cable (r3) is connected to the diving bell (D) via the intermediate pulley 320 and the elevating unit 500, and the other end of the third cable (r3) is in the third winding unit 230. can be connected

The intermediate connection unit 300 may be disposed higher than the elevating unit 500 . Due to the intermediate connection unit 300 , the first winding unit 210 , the second winding unit 220 , and the third winding unit 230 may be located at different heights from the lifting unit 500 . That is, the space efficiency of the dust recovery device 10 may be increased by the intermediate connection unit 300 .

The frame unit 400 may support the lifting unit 500 to be described later. The frame unit 400 may be supported by being coupled to the support part (S). The frame unit 400 may be formed by connecting a plurality of frames. As an embodiment, the frame unit 400 may be formed by connecting the first frame 410 and the second frame 420 .

The first frame 410 may be connected to the support (S). Specifically, one end of the first frame 410 may be connected to the support part S, and the other end of the first frame 410 may extend to the outside of the support part S. In this case, the second frame 420 may be rotatably connected to the other end of the first frame 410 . More specifically, one end of the second frame 420 may be hinge-coupled to the other end of the first frame 410 to rotate with respect to the first frame 410 . In addition, the other end of the second frame 420 may extend outwardly from the first frame 410 . The first frame 410 and the second frame 420 may include a rigid material, and for example, the first frame 410 and the second frame 420 may include a metal material.

The frame unit 400 may include a driving unit (not shown). The driving unit may generate a driving force necessary for the second frame 420 to rotate with respect to the first frame 410 . The relative positional relationship between the first frame 410 and the second frame 420 may be changed by the driving unit. As an embodiment, the first frame 410 and the second frame 420 may be in a folded state. In this case, the second frame 420 may be disposed to be inclined at a predetermined angle with respect to the longitudinal direction of the first frame 410 (hereinafter, referred to as a first state). In this case, the angle between the second frame 420 and the first frame 410 may be less than 180 degrees.

As another embodiment, the first frame 410 and the second frame 420 may be in an unfolded state. In this case, the second frame 420 may be in a state (hereinafter, referred to as a second state) substantially parallel to the first frame 410 .

The frame unit 400 may be converted from the first state to the second state by rotating the second frame 420 with respect to the first frame 410 . In the second state, at least a portion of the second frame 420 may be located above the ocean 2 .

The lifting unit 500 may move in the frame unit 400 . Specifically, the lifting unit 500 may be movably connected to the frame unit 400 . In this case, the lifting unit 500 may move in the longitudinal direction of the frame unit 400 . The lifting unit 500 may be, for example, a trolley apparatus connected to a rail provided in the frame unit 400 and capable of linear movement.

Elevating unit 500 may be connected to the diving bell (D) and the guide unit (G) through a cable as described above. The lifting unit 500 may include a lifting pulley 510 . One end of the first cable (r1) is connected to the diving bell (D) via the intermediate pulley 320 and the lifting pulley 510, and the other end of the first cable (r1) can be connected to the first winding unit 210. have. And, one end of the second cable (r2) is connected to the guide unit (G) through the intermediate pulley 320 and the lifting pulley 510, and the other end of the second cable (r2) is connected to the second winding unit 220. can be connected In this case, when the first winding unit 210 operates, the diving bell (D) connected to the first cable (r1) may ascend or descend. And, when the second winding unit 220 operates, the guide unit G connected to the second cable r2 may be raised or lowered.

Similarly, one end of the third cable (r3) is connected to the diving bell (D) via the intermediate pulley 320 and the elevating pulley 510, and the other end of the third cable (r3) is a third winding unit 230 . can be connected to The third cable (r3) is provided with a gas supply wiring as described above, it is possible to supply oxygen gas to the diving bell (D) through this gas supply wiring.

The lifting unit 500 may move from the first frame 410 to the second frame 420 or move from the second frame 420 to the first frame 410 . As an embodiment, in the second state, when the lifting unit 500 moves from the first frame 410 to the second frame 420 , the diving bell D and the guide unit G are the first frame 410 . ) may be moved from the lower part of the second frame 420 to the lower part. Accordingly, the diving bell (D) and the guide unit (G) may be located in the upper portion of the ocean (2) outside the ship (P). In this state, the true recovery device 10 can move the diving bell (D) and the guide unit (G) down to the water.

When the lifting unit 500 is positioned in the second frame 420 in the frame unit 400 in the second state, tension may be applied to the cable. As a relief, in a state in which the guide unit (G) and/or the diving bell (D) is detached from the elevating unit 500, the guide unit (G) and/or the diving bell (D) may be supported by a cable. . In this case, the tension formed in the cable may correspond to a force (eg, gravity) applied downward to the guide unit (G) and/or the diving bell (D). For example, the magnitude of the tension applied to the cable may be substantially the same as the magnitude of the force (eg, gravity) applied downward to the guide unit G and/or the diving bell D.

The driving unit 600 may generate a driving force for driving the dust recovery device 10 . As an embodiment, the driving unit 600 may be a hydraulic power unit (HPU) that generates a driving force through a hydraulic pressure generating method. In this case, the driving unit 600 includes an oil tank (not shown) for storing oil hydraulic oil, a driving motor (not shown) and a pump (not shown) for generating hydraulic pressure using oil hydraulic oil, and an accumulator for storing the generated hydraulic oil. (accumulator; not shown) may be provided. In this case, the driving unit 600 may generate hydraulic pressure by driving the hydraulic oil stored in the oil tank with a driving motor and a pump. The driving unit 600 may supply the generated hydraulic pressure to the dust recovery device 10 through a valve and a pipe. In this case, the dust recovery device 10 may operate a plurality of parts of the dust recovery device 10 using the supplied hydraulic pressure. However, the present invention is not limited thereto, and the driving unit 600 may generate the driving force through a method other than the hydraulic pressure generating method.

The dust recovery device 10 monitored by the dust recovery device monitoring system 1 according to the present invention is not limited to the above-described embodiment, and various types of dust recovery devices for launching and recovering the diving bell (D) can be monitored by the dust recovery device monitoring system 1 according to the present invention. However, for convenience of description, the following description will be focused on the embodiment of the above-described dust recovery device 10 .

The dust recovery device monitoring system 1, as described above, is installed on the ship P or a water structure (not shown), and may be a system for monitoring the dust recovery device 10 having a plurality of parts. . Here, the plurality of parts provided in the dust recovery device 10 may be at least a part of the winding module 200 , the intermediate connection unit 300 , the frame unit 400 , the lifting unit 500 , and the driving unit 600 . .

The dust recovery device monitoring system 1 may include a sensor module 100 , a control unit 20 , and a notification unit 30 . In addition, the dust recovery device monitoring system 1 may further include a memory unit 40 . In this case, the control unit 20 , the notification unit 30 , and the memory unit 40 may be disposed in the ship P, but may be disposed in a space O separate from the true recovery device 10 .

The sensor module 100 may sense the state of the dust recovery device 10 . Specifically, at least one of a plurality of parts provided in the dust recovery device 10 , for example, the winding module 200 , the intermediate connection unit 300 , the frame unit 400 , the lifting unit 500 , and the driving unit 600 . By sensing the state of a part, it is possible to obtain state information of each part.

The sensor module 100 may include at least one sensor unit. As an embodiment, the sensor module 100 includes a first sensor unit 110 , a second sensor unit 120 , a third sensor unit 130 , a fourth sensor unit 140 , and a fifth sensor. A unit 150 and a sixth sensor unit 160 may be provided. Here, the number of sensor units provided in the sensor module 100 is not limited, but for convenience of explanation, the sensor module 100 includes the first sensor unit 110 to the sixth sensor unit 160 . will be described based on

The first sensor unit 110 may sense the first winding unit 210 and/or the first cable r1 to obtain state information (hereinafter, first state information). The first sensor unit 110 may be disposed on the first winding unit 210 . In this case, the first sensor unit 110 may include a 1-1 measurement unit 111 and a 1-2 measurement unit 112 .

The 1-1 measuring unit 111 may measure the usage time of the first winding unit 210 . Specifically, the 1-1 measuring unit 111 may measure the usage time of the lower parts constituting the first winding unit 210 . As an embodiment, a plurality of 1-1 measurement units 111 may be provided. In this case, the plurality of 1-1 measurement units 111 may measure the usage time of each of the plurality of sub-parts constituting the first winding unit 210 . The sub-parts of the first winding unit 210 whose usage time is measured by the plurality of 1-1 measurement units 111 include, for example, a motor, a reducer, a bearing, and the like. can

The 1-2 measurement unit 112 may measure the magnitude of a force or load applied to the first winding unit 210 or the first cable r1 . The 1-2 measurement unit 112 may be implemented using, for example, a load cell. As an embodiment, a plurality of 1-2 measurement units 112 may be provided. In this case, any one of the plurality of 1-2 measurement units 112 may measure the tension applied to the first cable r1 connected to the first winding unit 210 . Another part of the plurality of first-second measuring units 112 may measure the magnitude of a load applied to lower parts constituting the first winding unit 210 . For example, any one of the plurality of 1-2 measurement units 112 except for the 1-2 measurement unit 112 that measures the tension is the first winding unit 210 when the first winding unit 210 operates. ) can measure the load applied to the motor provided.

The first state signal measured by the first sensor unit 110 may be transmitted to the control unit 20 . At this time, the first state signal includes the use time of the first winding unit 210 or its sub-parts measured through the 1-1 measuring unit 111 and the 1-2 measuring unit 112, and applied to each sub-part. Load values may be included.

The second sensor unit 120 may sense the second winding unit 220 and/or the second cable r2 to obtain status information (hereinafter, second status information). The second sensor unit 120 may be disposed at a position adjacent to the second winding unit 220 or the second winding unit 220 , in this case, the second sensor unit 120 may be the 2-1 measuring unit 121 . and a 2-2 measurement unit 122 may be provided.

The 2-1 measuring unit 121 may measure the usage time of the second winding unit 220 , that is, the usage time of a plurality of sub-parts constituting the second winding unit 220 . In this case, the sub-parts of the second winding unit 220 whose use time is measured by the 2-1 measurement unit 121 may include, for example, a motor, a reducer, a bearing, and the like.

The 2-2 measurement unit 122 may measure the magnitude of the force applied to the second winding unit 220 or the second cable r2 . At this time, a plurality of 2-2 measurement units 122 are provided, and any one of the plurality of 2-2 measurement units 122 measures the tension applied to the second cable r2 connected to the second winding unit 220 . can be measured In addition, the remaining part of the plurality of 2-2 measurement units 122 is the load applied to the sub-parts constituting the second winding unit 220 (eg, the motor constituting the second winding unit 220). size can be measured.

The second state signal measured by the second sensor unit 120 may be transmitted to the control unit 20 . At this time, the second state signal includes the use time of the second winding unit 220 or its sub-parts measured through the 2-1 measuring unit 121 and the 2-2 measuring unit 122 and the applied time to each sub-part. Load values may be included. Other specific features of the 2-1 measurement unit 121 and the 2-2 measurement unit 122 are the same as those of the 1-1 measurement unit 111 and the 1-2 measurement unit 112 described above, respectively. or similar, a redundant description thereof will be omitted.

The third sensor unit 130 may sense the third winding unit 230 and/or the third cable r3 to obtain state information (hereinafter, referred to as third state information). The third sensor unit 130 may be disposed at a position adjacent to the third winding unit 230 or the third winding unit 230 , wherein the third sensor unit 130 is the 3-1 measuring unit 131 . and a 3-2 measurement unit 132 may be provided.

The 3-1 measurement unit 131 may measure the usage time of the third winding unit 230 , that is, the usage time of a plurality of sub-parts constituting the third winding unit 230 . In this case, the lower parts of the third winding unit 230 whose usage time is measured by the 3-1 measurement unit 131 may include, for example, a motor, a reducer, a bearing, and the like.

The 3-2 measurement unit 132 may measure the magnitude of the force applied to the third winding unit 230 or the third cable r3 . A plurality of 3-2 measurement units 132 may be provided. Any one of the plurality of 3-2 measuring units 132 measures the tension applied to the third cable r3 connected to the third winding unit 230 , and the rest of the plurality of 3-2 measuring units 132 . Some may measure the magnitude of a load applied to a sub-part constituting the third winding unit 230 , for example, a motor.

The third state signal measured by the third sensor unit 130 may be transmitted to the control unit 20 . At this time, the third state signal includes the use time of the third winding unit 230 or its sub-parts measured through the 3-1 measuring unit 131 and the 3-2 measuring unit 132, and applied to each sub-part. Load values may be included. Other specific features of the 3-1 measurement unit 131 and the 3-2 measurement unit 132 are the same as those of the 1-1 measurement unit 111 and the 1-2 measurement unit 112, respectively. or similar, a redundant description thereof will be omitted.

The fourth sensor unit 140 may sense the elevating unit 500 to obtain state information (hereinafter, fourth state information) of the elevating unit 500 . The fourth sensor unit 140 may be disposed in the elevating unit 500 , wherein the fourth sensor unit 140 includes a 4-1 measurement unit 141 and a 4-2 measurement unit 142 . can do.

The 4-1st measurement unit 141 may measure the usage time of the elevating unit 500 . Specifically, the 4-1 measurement unit 141 may measure the usage time of the lower parts constituting the lifting unit 500 . In this case, the lower part of the lifting unit 500 whose use time is measured through the 4-1 measurement unit 141 may be, for example, a lifting pulley 510 or a bearing. In addition, the 4-2 measurement unit 142 may measure the magnitude of the load applied to the lifting unit 500 or a sub-part constituting the lifting unit 500 , for example, the lifting pulley 510 . The 4-2 measurement unit 142 may be implemented using, for example, a load cell.

The fourth state signal measured by the fourth sensor unit 140 may be transmitted to the control unit 20 . At this time, the fourth state signal includes the use time of the lifting unit 500 or the parts under the lifting unit 500 measured by the 4-1 measurement unit 141 and the 4-2 measurement unit 142 and the applied time. Load values may be included.

The fifth sensor unit 150 may sense the driving unit 600 to obtain state information (hereinafter, referred to as fifth state information) of the driving unit 600 . The fifth sensor unit 150 may be disposed in the driving unit 600 , wherein the fifth sensor unit 150 includes a 5-1 measurement unit 151 and a 5-2 measurement unit 152 . can do.

The 5-1 measurement unit 151 may measure the usage time of the driving unit 600 . Specifically, the 5-1 measurement unit 151 may measure the usage time of the sub-parts constituting the drive unit 600 , the example drive motor, and the pump.

The 5-2 measurement unit 152 may measure the magnitude of the load applied to the driving unit 600 . Specifically, a plurality of 5-2 measurement units 152 may be provided. As an embodiment, a pair of 5-2 measurement units 152 may be provided. In this case, one of the pair of 5-2 measuring units 152 may be installed in the driving motor to measure a load applied to the driving motor. In addition, the other one of the pair of 5-2 measurement units 152 may be installed in the pump to measure the load applied to the pump.

The fifth state signal measured by the fifth sensor unit 150 may be transmitted to the controller 20 . At this time, the fifth state signal includes the use time of the driving unit 600 or lower parts of the driving unit 600 measured through the 5-1 th measurement unit 151 and the 5-2 th measurement unit 152 and the applied time. Load values may be included.

The sixth sensor unit 160 may sense the intermediate connection unit 300 to obtain state information (hereinafter, referred to as sixth state information) of the intermediate connection unit 300 . The sixth sensor unit 160 may be disposed in the driving unit 600 , wherein the sixth sensor unit 160 includes a 6-1 measurement unit 161 and a 6-2 measurement unit 162 . can do.

The 6-1 measurement unit 161 may measure the use time of the intermediate connection unit 300 . Specifically, the 6-1 measurement unit 161 may measure the use time of the sub-parts constituting the intermediate connection unit 300 , for example, the intermediate pulley 320 .

The 6-2 measurement unit 162 may measure the magnitude of the load applied to the intermediate connection unit 300 . Specifically, a plurality of 6-2 measurement units 162 may be provided. As an embodiment, a pair of 6-2 measurement units 162 may be provided. In this case, one of the pair of 6-2 measuring units 162 may be installed on the connection body 310 to measure a load applied to the connection body 310 . In addition, the other one of the pair of 6-2 measurement units 162 may be installed on the intermediate pulley 320 to measure the load applied to the intermediate pulley 320 .

The sixth state signal measured by the sixth sensor unit 160 may be transmitted to the controller 20 . At this time, the sixth state signal includes the use time of the lower parts of the intermediate connection unit 300 or the intermediate connection unit 300 measured through the 6-1 measurement unit 161 and the 6-2 measurement unit 162 , and The load applied thereto may be included.

The sensor module 100 may further include an additional sensor unit (not shown) in addition to the first sensor unit 110 to the sixth sensor unit 160 described above. As an embodiment, the additional sensor unit may detect state information of a control module (not shown) that controls the driving unit 600 . Specifically, a plurality of additional sensor units are provided and are respectively installed in sub-parts constituting the control module, for example, a main panel, a control panel, a control console, etc., and each of these sub-parts can detect whether it is operating normally. In this case, the additional sensor unit may transmit information about the normal operation of each detected sub-part to the control unit 20 .

The control unit 20 may determine the current state of the true recovery device 10 based on the status information of the true recovery device 10 detected by the sensor module 100 . In this case, the controller 20 may be driven in a form included in a hardware device such as a microprocessor or a general-purpose computer system. Here, the 'processor' may refer to a data processing device embedded in hardware, for example, having a physically structured circuit to perform a function expressed as a code or an instruction included in a program. As an example of the data processing device embedded in the hardware as described above, a microprocessor, a central processing unit (CPU), a processor core, a multiprocessor, an ASIC (Application-Specific Integrated) Circuit) and a processing device such as an FPGA (Field Programmable Gate Array) may be included, but the scope of the present invention is not limited thereto.

The controller 20 may receive the state information of each part from the sensor module 100 in real time, and generate current state information of each part. Specifically, the controller 20 may generate current state information of the first winding unit 210 by collecting the first state information received from the first sensor unit 110 . The controller 20 may generate current state information of the second winding unit 220 by collecting the second state information received from the second sensor unit 120 . The controller 20 may generate current state information of the third winding unit 230 by collecting the third state information received from the third sensor unit 130 . In addition, the controller 20 may generate current state information of the elevating unit 500 by collecting the fourth state information received from the fourth sensor unit 140 . The controller 20 may generate current state information of the driving unit 600 by collecting the fifth state information received from the fifth sensor unit 150 .

The generated current state information of each part includes the total usage time of the corresponding part, the total use cycle, and the magnitude and change of the force (eg, load or tension) applied to the part or its sub-parts. may contain information. In addition, the current state information of each part part may include current state information of each of the sub-parts constituting each part part.

Specifically, the current state information of the first winding unit 210 is, for example, information about each use time of the motor, the reducer, and the bearing constituting the first winding unit 210, and the load measurement value applied to the motor. may include. Similarly, the current state information of the second winding unit 220 is, for example, the use time of each of the motor, the reducer, and the bearing constituting the second winding unit 220, and a load measurement value applied to the motor. may contain information. And the current state information of the third winding unit 230 includes, for example, the use time of each of the motor, the reducer, and the bearing constituting the third winding unit 230, and information about the load measurement value applied to the motor. can do.

The current state information of the lifting unit 500 is, for example, information on the usage time of each of the lifting pulleys 510 and bearings constituting the lifting unit 500 and the load measurement value applied to each of the lifting pulleys 510 and the bearings. may include.

The current state information of the driving unit 600 may include, for example, information on a use time of each of the driving motor and the pump constituting the driving unit 600 and information on a load measurement value applied to each of the driving motor and the pump.

Current state information of the intermediate connection unit 300 is, for example, the connection body 310 and the intermediate pulley 320 constituting the intermediate connection unit 300, the use time of each and the connection body 310 and the intermediate pulley 320 ) may include information related to the load measurement value applied to each.

The control unit 20 may control the notification unit 30 to display the determined current state information of the device 10 to the outside. In this case, the control unit 20 may generate a control signal including the current state information of each component part and its sub-parts, and transmit it to the notification unit 30 .

The control unit 20 may transmit current state information of each component unit to the memory unit 40 . Specifically, the control unit 20 includes the current state information of the first winding unit 210, the current state information of the second winding unit 220, the current state information of the third winding unit 230, and the lifting unit ( The current state information of the 500 and the current state information of the driving unit 600 may be transmitted to the memory unit 40 . In this case, the memory unit 40 may classify and store the current state information of the above-described component units for each component unit.

The control unit 20 receives the state information of each part or each sub-part of the true recovery device 10 detected by the sensor module 100, and generates current state information of each part or each sub-part based on this information. can do. The controller 20 may generate a control signal including current state information of each generated component part or each sub-part, and transmit the control signal to the notification unit 30 and the memory unit 40 .

The control unit 20 determines whether replacement of each part or each sub-part is necessary and/or an overload state based on the state information of each part or each sub-part of the true recovery device 10 detected by the sensor module 100 . can determine whether The control unit 20 generates a control signal including information on whether each of the determined parts or sub-parts needs to be replaced and/or whether an overload condition is present, and transmits these control signals to the notification unit 30 and the memory unit ( 40) can be transferred. Specific features of the control unit 20 will be described later.

The notification unit 30 may externally display current state information of each part or each sub-part included in the control signal received from the controller 20 using a display unit (not shown). Specifically, the notification unit 30 may receive the current state information of each component unit collected in the dust recovery device 10 from the control unit 20 and display the information to the outside. At this time, the control unit 20 receives the status information of each component part measured in real time by the sensor module 100 and generates the current status information of each component part, and the notification unit 30 receives the information collected from the control unit 20 Current status information of each part can be received in real time and displayed externally.

The notification unit 30 may include a plurality of display areas partitioned to correspond to respective parts constituting the dust recovery device 10 . In this case, the notification unit 30 may display the current state information by dividing each part by a plurality of parts through a plurality of partitioned display areas. Accordingly, the manager of the monitoring system 1 can grasp current state information, such as usage time and load state, for each part of the dust recovery device 10 . Accordingly, it is possible to improve the efficiency of management for each part.

The notification unit 30 uses the display unit to generate a signal including information on whether each part or each sub-part determined by the control unit 20 needs to be replaced and/or whether it is in an overload state, and transmits these signals to an external device. can be displayed as

The notification unit 30 may notify the manager of the monitoring system 1 by externally displaying a replacement instruction signal of a part or sub-part requiring replacement. The manager can identify the replacement parts or sub-parts through the display unit and instruct the ship-side operator to replace the replacement parts or sub-parts with the spare parts stored in the space storage space (not shown) in the ship (P). have.

The notification unit 30 may notify the manager of the monitoring system 1 by externally displaying an overload state signal of a part or sub-part requiring inspection. Through the display unit, the manager can identify the parts or sub-parts that are overloaded and require inspection, and instruct the ship-side operator to check the load status and damage of these parts or sub-parts.

The memory unit 40 may store the current state information of each part or each sub-part received from the control unit 20 and information on whether each part or each sub-part needs to be replaced and/or whether it is in an overload state. .

4 is a flowchart illustrating a method of monitoring the current state of each part provided in the dust recovery device according to an embodiment of the present invention. 5 is a flowchart illustrating a method for determining whether to replace each part provided in the dust recovery device according to an embodiment of the present invention, and FIG. 6 is each provided in the dust recovery device according to another embodiment of the present invention. It is a flowchart illustrating a method of determining whether to replace a component part.

4 to 6 , each sensor unit may detect status information of each component corresponding to a location where each sensor unit is installed, and transmit it to the control unit 20 ( S10 ). Then, the control unit 20 may determine the current state of each part based on the received state information, and transmit a control signal including the current state to the notification unit 30 ( S20 ). Thereafter, the notification unit 30 may display the current state information of each part to the outside ( S30 ).

The control unit 20 may determine whether replacement of each component is necessary based on the usage time among the current state information of each component of the dust recovery apparatus 10 received from the sensor module 100 ( S100 , S200 ). In this case, the control unit 20 may preset at least one life reference value for determining the replacement time of each part.

As an embodiment, as shown in FIG. 5 , the control unit 20 may set one life reference value for each part or for each sub-part constituting each part ( S110 ). In this case, the life reference value corresponding to each component part may be different from the life reference value corresponding to the other part part. In addition, the life reference value corresponding to each sub-part constituting each part part may be different from the life reference value corresponding to other sub-parts. For example, the life reference value of the motor constituting the first winding unit 210, the life reference value of the reducer constituting the first winding unit 210, and the life reference value of the bearing may be different from each other.

The control unit 20, based on the initial operation time of each component unit measured by each sensor unit, calculates the total usage time of the corresponding component unit or sub-parts constituting the corresponding component unit from the current use time measured by each sensor unit. can be calculated (S120). The control unit 20 compares the calculated total usage time of each part or each sub-part with the life reference value of the corresponding part or sub-part, and determines whether replacement of the corresponding part or the sub-part is necessary. (S130).

When the calculated total usage time of each part or each sub-part exceeds the life reference value of the part or the sub-part, the control unit 20 determines that replacement of the current part or the sub-part is necessary. can do. Thereafter, in response to the control signal of the controller 20 , the notification unit 30 may display a replacement instruction signal of the part or sub-part determined to be replaced ( S140 ).

On the other hand, when the calculated total usage time of each part or each sub-part is less than the life reference value of the part or the sub-part, the control unit 20 says that the current replacement of the part or the sub-part is unnecessary. It can be determined (S130). Thereafter, according to the control signal of the controller 20 , the notification unit 30 may display the current state information of each part to the outside ( S150 ). Thereby, the manager of the monitoring system 1 can grasp the current state of the dust recovery device 10 and each component part and each sub-part constituting it in real time.

When the life reference value is different for each part or each sub-part, the determination of the control unit 20 as to whether replacement is necessary for each part or each sub-part constituting one part may be different. As an example, the replacement timing of the motor constituting the first winding unit 210 and the bearing or the reducer constituting the first winding unit 210 may be different from each other. As another example, the replacement timing of the motor constituting the first winding unit 210 and the motor constituting the third winding unit 230 may be different from each other. The time when the elevating unit 500 needs to be replaced may be different from each other. As another example, the elevating unit 500 and the first winding unit 210 itself need to be replaced at different times.

When it is determined that the replacement of each part or each sub-part is necessary, the control unit 20 generates an instruction signal including information on the need for replacement of the corresponding part or the sub-part, and transmits it to the notification unit 30 . can

As another embodiment, as shown in FIG. 6 , the controller 20 may set two or more life reference values for each component part or for each sub-part constituting each part part ( S210 ). At this time, although the number of set life reference values is not limited, for convenience of explanation, an embodiment in which two life reference values are set for each sub-part constituting each part will be mainly described. Here, the two life reference values will be referred to as a first life reference value and a second life reference value, respectively.

The first life reference value may be different from the second life reference value. Specifically, the second life reference value may be a value greater than the first life reference value. In this case, the control unit 20 is based on the initial operation time of each component unit measured by each sensor unit, and the total use of the component unit or the sub-parts constituting the component unit from the usage time currently measured by each sensor unit. The time may be calculated (S220). Thereafter, the control unit 20 sequentially compares the calculated total use time of each part or each sub-part with the first life reference value and the second life reference value of the part or the sub-part, and the corresponding part or the corresponding part. It is possible to determine whether sub-parts need to be replaced.

First, the controller 20 may compare the calculated total usage time of each part or each sub-part with a first life reference value of the corresponding part or the sub-part (S230). At this time, when the calculated total usage time of each part part or each sub-part is less than the first life reference value of the part part or the sub-part, the control unit 20 does not need to replace the part or the sub-part, , it can be judged that it does not correspond to the close period of replacement. Thereafter, the notification unit 30 may display current state information of each component unit and each sub-component according to a control signal of the control unit 20 ( S231 ). Accordingly, the manager can grasp the current state of the dust recovery device 10 and each component part and each sub-part constituting the same in real time.

When the calculated total use time of each part or each sub-part exceeds the first life reference value of the part or the sub-part, the control unit 20 sequentially controls the total use time of each part or each sub-part can be compared with the second life reference value of the corresponding part or the corresponding sub-part (S240). At this time, if the total usage time of each part or each sub-part exceeds the first life reference value of the part or the sub-part and is less than the second life reference value, the replacement of the current part or the sub-part is not Although unnecessary, it may be determined that the replacement is immediately necessary (hereinafter, referred to as the replacement proximity time).

Accordingly, the notification unit 30 may display a signal (a first signal) informing that the corresponding part or the corresponding sub-part corresponds to the replacement scheduled part according to the control signal of the controller 20 ( S241 ). Thereby, the manager can grasp information on the parts or sub-parts that are expected to need replacement in the near future among the respective parts and sub-parts constituting the dust recovery device 10 .

On the other hand, as for the parts or sub-parts corresponding to replacement journey parts, the status information is continuously detected by each sensor unit and transmitted to the control unit 20, and accordingly, the control unit 20 controls the current status of the corresponding component unit and the sub-part. Status information can be updated in real time. Thereafter, the control unit 20 may transmit the updated current state information to the notification unit 30 .

On the other hand, when the total usage time of each part or each sub-part exceeds the second life reference value, the controller 20 may determine that replacement of the corresponding part or the sub-part is currently necessary. Accordingly, the notification unit 30 may display a signal (second signal) instructing replacement of the corresponding part or the corresponding sub-part according to the control signal of the controller 20 ( S250 ).

As described above, the control unit 20 sets the life reference value of each part or each sub-part to two or three or more, so that the replacement time (or remaining life) of each part or each sub-part is subdivided and determined. can Accordingly, the manager or operator of the monitoring system 1 can predict in advance the replacement timing of each part constituting the dust recovery device 10 and its sub-parts, and accordingly, the dust recovery device 10 due to component aging. ) can be prevented from occurring. In addition, it is possible to determine in advance whether there are any spare parts for replacement of parts expected to be replaced in the near future or sub-parts.

7 is a flowchart illustrating a method of determining whether each component part provided in the dust recovery device is in an overload state according to another embodiment of the present invention.

Referring to FIG. 7 , the control unit 20 may determine whether each component part is in an overload state based on load information among the current state information of each part part of the dust recovery device 10 received from the sensor module 100 ( S300). In this case, the control unit 20 may preset at least one load reference value for determining whether each component part is overloaded.

As an embodiment, the control unit 20 may set at least one load reference value for each component part or for each sub-part constituting each part part ( S310 ). In this case, the load reference value corresponding to each component part may be different from the load reference value corresponding to the other part part. In addition, the load reference value corresponding to each sub-part constituting each component part may be different from the load reference value corresponding to other sub-parts. For example, the load reference value of the motor constituting the first winding unit 210, the load reference value of the reducer constituting the first winding unit 210, and the load reference value of the bearing may be different from each other.

The control unit 20 compares the load measurement value of each component part or each sub-part measured by each sensor unit with the load reference value of the corresponding part part or the sub-part to determine whether the part or the sub-part is overloaded. It can be (S320, S330).

When the measured load reference value of each part or each sub-part exceeds the load reference value of the part or the sub-part, the control unit 20 may determine that the current part or the sub-part is in an overload state. have.

When it is determined that each part or each sub-part is in an overload state, the control unit 20 generates an indication signal including information on the overload state of the corresponding part or the sub-part, and transmits it to the notification unit 30 have. Accordingly, the notification unit 30 may display a signal indicating that a specific part or a specific sub-part is in an overload state through the display unit (S340). Accordingly, the manager can grasp in real time whether the dust recovery device 10 and each component part and each sub-part constituting it are in an overload state.

On the other hand, when the measured load reference value of each part or each sub-part is less than the load reference value of the part or the sub-part, the controller 20 determines that the current part or the sub-part is in a normal load state. can judge Accordingly, the notification unit 30 may display a load value applied to the corresponding part or the corresponding sub-part according to the control signal of the controller 20 ( S350 ).

As another embodiment, the controller 20 may set two or more load reference values for each component part or for each sub-part constituting each part part. At this time, the number of set load reference values is not limited, but for convenience of explanation, an embodiment in which two load reference values are set for each sub-part constituting each part will be mainly described. Here, the two load reference values will be referred to as a first load reference value and a second load reference value, respectively.

The first load reference value may be different from the second load reference value. Specifically, the second load reference value may be a value greater than the first load reference value. In this case, the control unit 20 sequentially compares the load measurement value of each component part or each sub-part measured by each sensor unit with the first load reference value and the second load reference value of the corresponding part part or the sub-part, It is possible to determine whether the corresponding part or the corresponding sub-part is overloaded.

First, the control unit 20 may compare the measured load measurement value of each component part or each sub-part with a first load reference value of the corresponding part part or the sub-part. At this time, when the measured load measurement value of each part or each sub-part is less than the first load reference value of the part or the sub-part, the control unit 20 does not correspond to the overload state of the part or the sub-part. and it can be determined that it does not correspond to an overload proximity state either.

Thereafter, the control unit 20 may transmit the generated control signal to the notification unit 30 . In this case, the notification unit 30 may display information about the load applied to each component unit and each sub-part through the display unit. Accordingly, the manager can grasp the load state of the dust recovery device 10 and each component part and each sub-part constituting the same in real time.

When the measured load measurement value of each component part or each sub-part exceeds the first load reference value of the corresponding part part or the sub-part, the control unit 20 sequentially controls the load measurement value of each part part or each sub-part , may be compared with the second load reference value of the corresponding part or the corresponding sub-part. At this time, if the load measurement value of each part or each sub-part exceeds the first load reference value of the part or the sub-part but is less than the second load reference value, the part or the sub-part is not currently overloaded, but , it can be determined that it corresponds to a state close to overload (hereinafter referred to as an overload proximity state). Accordingly, the notification unit 30 may display a signal (third signal) indicating that the corresponding part or sub-part is in an overload proximity state according to the control signal of the controller 20 .

On the other hand, when the load measurement value of each component part or each sub-part exceeds the second load reference value, the control unit 20 may determine that the current part or the sub-part is in an overloaded state. Accordingly, the notification unit 30 may display a signal (fourth signal) indicating that the corresponding part or lower part is in an overload state according to the control signal of the controller 20 .

As described above, by setting the load reference value of each component part or each sub-component to two or three or more, the control unit 20 may subdivide whether each part or each sub-part is in an overload state. Accordingly, the manager or operator of the monitoring system 1 can predict in advance whether each part constituting the dust recovery device 10 and its sub-parts are overloaded, and accordingly, due to the excessive load applied, the dust recovery device ( 10) can be prevented from occurring.

On the other hand, the dust recovery device monitoring system 1 according to the present invention, as described above, by setting both the life reference value and the load reference value in the control unit 20, each part or each sub-unit measured by the sensor module 100 By comparing with the state information of the parts, it is possible to simultaneously determine whether replacement is necessary and whether the state is overloaded. Thereby, the manager of the monitoring system 1 can monitor and maintain the dust recovery apparatus 10 by simultaneously grasping the information applied to the usage time and load of each component part and each sub-part.

As described above, the dust recovery device monitoring system 1 according to embodiments of the present invention is installed on the ship P together with the dust recovery device 10 to monitor the dust recovery device 10, The status of each part and sub-parts of the recovery device 10 can be grasped in real time, and thereby the service life or If a replacement is required due to a damage problem, an immediate replacement can be ordered.

In addition, by using the dust recovery device monitoring system 1 according to the embodiments of the present invention, by grasping the status of spare parts stored in the ship P in real time, before the spare parts are all exhausted, the You can request to send additional spare parts to the outside. Thereby, it is possible to maintain a state provided with a certain amount of spare parts in the ship (P), and it is possible to quickly replace the parts or sub-parts requiring replacement.

The foregoing description of the present invention is for illustration, and those of ordinary skill in the art to which the present invention pertains can understand that it can be easily modified into other specific forms without changing the technical spirit or essential features of the present invention. will be. Therefore, it should be understood that the embodiments described above are illustrative in all respects and not restrictive. For example, each component described as a single type may be implemented in a distributed manner, and likewise components described as distributed may also be implemented in a combined form.

The scope of the present invention is indicated by the following claims, and all changes or modifications derived from the meaning and scope of the claims and their equivalents should be construed as being included in the scope of the present invention.

1: dust recovery device monitoring system 100: sensor module
2: Marine 200: Winding module
10: dust recovery device 300: intermediate connection unit
20: control unit 400: frame unit
30: notification unit 500: elevating unit
40: memory unit 600: drive unit

Claims (10)

A system for monitoring a dust recovery device having a plurality of parts, the system comprising:
a sensor module for detecting state information of the dust recovery device;
a control unit that determines a current state of the dust recovery device based on the state information and generates a control signal including information on the determined current state; and
and a notification unit for externally displaying information about the current state determined by the controller;
The control unit controls the notification unit to display information about the current state of the dust recovery device in real time by using the control signal,
The sensor module includes a plurality of sensor units,
A plurality of the sensor unit is disposed in each of the plurality of parts to detect the state information of each of the plurality of parts,
Each of the plurality of sensor units includes a first measuring unit for measuring the usage time of the component unit;
The control unit receives the usage time of the component part measured by the first measurement unit, compares the usage time with a preset life reference value, and determines whether replacement of the component part is necessary,
A plurality of preset life reference values are set, wherein the plurality of preset life reference values include a first life reference value and a second life reference value greater than the first life reference value. delete The method of claim 1,
Each of the plurality of sensor units includes a second measuring unit configured to measure the load applied to the component unit; further comprising, a dust recovery device monitoring system. delete The method of claim 1,
The control unit is
When the usage time of the part part exceeds the preset life reference value, the dust recovery device monitoring system controls the notification part to display a signal instructing replacement of the part part. 4. The method of claim 3,
The control unit is
A dust recovery device monitoring system for receiving the load measurement value applied to the component part measured by the second measurement unit, and comparing the load measurement value with a preset load reference value to determine whether the component part is overloaded. 7. The method of claim 6,
The control unit is
When the load measurement value applied to the component exceeds the preset load reference value, controlling the notification unit to display a signal indicating that the component is in an overload state, the dust recovery device monitoring system. delete The method of claim 1,
The control unit is
When the use time of the part part is greater than the first life reference value and less than the second life reference value, the dust recovery device monitoring system controls the notification part to display a first signal indicating a replacement schedule of the part part. The method of claim 1,
The control unit is
When the usage time of the part part is greater than the second life reference value, the dust recovery device monitoring system controls the notification part to display a second signal instructing replacement of the part part.

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