CN114883932A - Intelligent cabinet with remote self-checking function based on Internet and method - Google Patents

Abstract

The invention discloses an intelligent cabinet with a remote self-checking function based on the Internet and a method thereof, relates to the technical field of intelligent cabinets, and aims to solve the problems that the existing device can only detect a local high-temperature area in the using process, can not further check and process faults, and has insufficient functionality. The transmission frame is arranged on the rear end faces of the first cabinet door and the second cabinet door and is connected with the first cabinet door and the second cabinet door through a welding machine; horizontal belt guide, it is installed transmission frame inside intermediate position department, install first slider on the horizontal belt guide, and first slider is connected with horizontal belt guide transmission, install vertical belt guide on the outer wall of first slider, install the second slider on vertical belt guide, and the second slider is connected with vertical belt guide transmission, second step motor is all installed to the one end of horizontal belt guide and vertical belt guide.

Description

Intelligent cabinet with remote self-checking and checking functions based on Internet and method

Technical Field

The invention relates to the technical field of intelligent cabinets, in particular to an intelligent cabinet with a remote self-checking function based on the Internet and a method.

Background

The intelligent power distribution cabinet is a precise power distribution cabinet, is a power distribution cabinet which comprehensively collects all energy data aiming at the tail end of energy of a data center machine room, provides high-precision measurement data for a terminal energy monitoring system, and reflects electric energy quality data in real time through a display unit;

can carry out intelligent power distribution cabinet who monitors automatically as application number CN208782315U name, including the box, with box articulated closing cap, one side of closing cap is equipped with two first spouts that are parallel to each other, all installs the second slider in two first spouts, and one side of two second sliders is fixed with the carriage release lever jointly, install the moving member on the carriage release lever, one side of moving member is fixed with the mounting panel, the opposite side of moving member is equipped with drive arrangement, one side of mounting panel is fixed with camera, thermal imager and LED lamp in proper order, and camera, thermal imager and LED lamp are the triangle-shaped setting.

In the using process of the device, the device can only detect a local high-temperature area, cannot further check and process faults and has insufficient functionality; therefore, an intelligent cabinet and a method with a remote self-checking function based on the internet are provided, so as to solve the problems provided in the prior art.

Disclosure of Invention

The invention aims to provide an intelligent cabinet with a remote self-checking and troubleshooting function based on the Internet and a method thereof, and solve the problems that the existing device provided in the background technology can only detect a local high-temperature area in the using process, cannot further check and process faults, and is insufficient in functionality.

In order to achieve the above purpose, the invention provides the following technical scheme: an intelligent cabinet with remote self-checking function based on the internet comprises an intelligent cabinet main body, a control seat is arranged at the middle position in the intelligent cabinet main body, a touch display screen is arranged on the front end face of the control seat, a first cabinet door is arranged above the front end face of the intelligent cabinet main body, a second cabinet door is arranged below the front end face of the intelligent cabinet main body, one side of each of the first cabinet door and the second cabinet door is rotatably connected with the intelligent cabinet main body through a hinge, the other sides of the first cabinet door and the second cabinet door are both connected with the intelligent cabinet main body in a locking way through a bounce lock, a bus chamber is arranged in the upper part of the intelligent cabinet main body, a ground group row is arranged at the upper end in the bus chamber, a function chamber is arranged in the lower part of the intelligent cabinet main body, a wire inlet seat is arranged on the upper end face of the intelligent cabinet main body, and a wire outlet seat is arranged on the lower end face of the intelligent cabinet main body;

further comprising:

the transmission frame is arranged on the rear end surfaces of the first cabinet door and the second cabinet door and is connected with the first cabinet door and the second cabinet door through welding machines;

the transverse belt guide rail is arranged in the middle of the inside of the transmission frame, a first sliding block is arranged on the transverse belt guide rail and is in transmission connection with the transverse belt guide rail, a longitudinal belt guide rail is arranged on the outer wall of the first sliding block, a second sliding block is arranged on the longitudinal belt guide rail and is in transmission connection with the longitudinal belt guide rail, and a second stepping motor is arranged at one end of each of the transverse belt guide rail and the longitudinal belt guide rail;

the electric push rod is arranged on the front end surface of the second sliding block;

the wiring tightening mechanism is arranged on the output end of the electric push rod;

and the temperature sensing probe is arranged above the electric push rod.

Preferably, first guide pillars are arranged above and below the transverse belt guide rail, first guide blocks are arranged behind two ends of the longitudinal belt guide rail, and the first guide blocks are connected with the first guide pillars in a sliding mode.

Preferably, the outside of wiring take-up unit is provided with the casing, and is provided with the radiating groove on the outer wall of casing, the internally mounted of casing has servo motor, install the worm on servo motor's the output, the turbine is installed to the top of worm, the internally mounted of turbine has the driven shaft, torque sensor is installed to the rear end of driven shaft, install concentric wheel on the outer wall of driven shaft front end, the front end of driven shaft runs through and extends to the outside of casing, and installs the roating seat, the inside of roating seat is provided with the hexagonal constant head tank, the electro-magnet is installed to the rear end of hexagonal constant head tank.

Preferably, the hexagonal screwdriver head seat is installed inside the hexagonal positioning groove, the front end of the hexagonal screwdriver head seat is provided with a strong magnetic screwdriver head, the screwdriver head seat is installed on one side of the interior of the bus chamber and the interior of the function chamber, and a plurality of hexagonal grooves are formed in the interior of the screwdriver head seat.

Preferably, female mount pad of arranging is installed to the inside rear end of generating line room, and female mount pad of arranging is provided with two, the functional unit mount pad is installed to the inside rear end of functional room, and the functional unit mount pad is provided with four, female both ends of arranging mount pad and functional unit mount pad pass through the bolt respectively with the inner wall threaded connection of generating line room and functional room, the inside of arranging mount pad and functional unit mount pad all is provided with cellular active silica gel layer, the front end of arranging mount pad and functional unit mount pad all is provided with the guide rail strip, and the both ends of guide rail strip with arrange mount pad and functional unit mount pad welded connection.

Preferably, heat dissipation frame is installed to the rear end face of intelligence cabinet main part, heat dissipation frame's internally mounted has the ball screw guide rail, and the ball screw guide rail is provided with threely, first step motor is installed to the one end of ball screw guide rail, the rear end on cellular active silica gel layer all is provided with the exhaust fan, and is adjacent through the synchronous online of linkage post between the exhaust fan, adjacent top the exhaust fan passes through the slip table and is connected with the transmission of ball screw guide rail, adjacent below the second guide block is installed to the exhaust fan lower extreme, the internally mounted of second guide block has the second guide pillar, and the both ends and the heat dissipation frame inner wall fixed connection of second guide pillar.

Preferably, a protective net is installed on the front end face of the exhaust fan, and a dust separation net is installed on the rear end face of the honeycomb-shaped active silica gel layer.

Preferably, temperature and humidity sensors are installed on the other sides of the interior of the bus chamber and the interior of the function chamber, and a semiconductor refrigerating piece is installed on the rear end face of the exhaust fan.

Preferably, a central processing module, a semiconductor controller, a wireless data transmission module and a motor driving module are installed inside the control seat, the output end of the central processing module is electrically connected with the input end of the semiconductor refrigeration piece through the semiconductor controller, the output end of the central processing module is electrically connected with the input ends of the first stepping motor, the second stepping motor, the servo motor, the electric push rod and the exhaust fan through the motor driving module, the input ends of the temperature sensing probe, the torque sensor and the temperature and humidity sensor are electrically connected with the output end of the central processing module, the output end of the central processing module is electrically connected with the input end of the electromagnet, the central processing module is electrically connected with the touch display screen and the wireless data transmission module in a bidirectional mode, the output end of the wireless data transmission module is connected with the input end of the monitoring terminal, and the wireless data transmission module is connected with the image processing cloud in a bidirectional mode, the image processing cloud is connected with the database in a bidirectional mode.

Preferably, the intelligent cabinet self-checking method with the remote self-checking function based on the internet comprises the following steps:

the method comprises the following steps: when the intelligent cabinet main body is used, the bus unit and the functional unit are respectively arranged on the guide rail bars of the bus mounting seat and the functional unit mounting seat, cellular active silica gel layers are arranged inside the bus mounting seat and the functional unit mounting seat, moisture in the cabinet is adsorbed all the time, before troubleshooting is performed, under the condition that the elements in the cabinet are ensured to be normally arranged, a central processing module sends a signal to a motor driving module to drive a second stepping motor to operate, a transverse belt guide rail is utilized to drive a longitudinal belt guide rail to move to a middle position, a longitudinal belt guide rail drives a temperature sensing probe on a second sliding block to scan image information of the elements in the cabinet, and the image information is uploaded to an image processing cloud through a wireless data transmission module and stored in a database;

step two: during troubleshooting, firstly, a central processing module sends a signal to a motor driving module to drive a second stepping motor to run, image information in the cabinet is scanned by utilizing the cooperation of a transverse belt guide rail and a longitudinal belt guide rail and is uploaded to an image processing cloud end, the image processing cloud end compares the image information with an image stored in a database in advance after receiving the image information and feeds a comparison result back to the central processing module, if the comparison result is different from the image, the possibility that a maintenance tool is omitted in the cabinet by a maintenance worker exists, and at the moment, the central processing module sends an alarm to remind the maintenance worker to carry out maintenance, and if the difference does not exist, the next troubleshooting is carried out;

step three: the temperature and humidity are detected by a temperature and humidity sensor in the cabinet, when the internal humidity is detected to be higher, a central processing module sends signals to a motor driving module and a semiconductor controller, the motor driving module drives a first stepping motor and a motor in an exhaust fan to operate, the exhaust fan is driven to move in a reciprocating mode by a ball screw guide rail, meanwhile, the semiconductor controller drives a semiconductor refrigerating sheet to heat, a honeycomb-shaped active silica gel layer is dried continuously, moisture is diffused quickly by the exhaust fan, and hidden dangers caused by higher humidity are eliminated; when the internal temperature is detected to be higher, the bus room or the functional room is judged to be higher, then the central processing module sends a signal to the motor driving module, the temperature sensing probe on the guide rail scans the interior of the cabinet to confirm a heating source, then the first step motor drives the ball screw guide rail to drive the exhaust fan to move to the rear end face of a heating source element, the semiconductor refrigerating sheet is matched for refrigeration to carry out fixed-point heat dissipation on the heating source element, meanwhile, the temperature sensing probe uploads element information to the image processing cloud end to identify the specification of a wiring bolt of the heating source element, the information is fed back to the central processing module, the transverse belt guide rail is matched with the longitudinal belt guide rail to drive the wiring tightening mechanism to move to the bit seat to align the bit corresponding to the specification of the bolt, the electric push rod drives the wiring tightening mechanism to extend out to clamp the bit into the hexagonal positioning groove, and the bit is adsorbed and fixed by the electromagnet, continuously matching the transverse belt guide rail and the longitudinal belt guide rail to drive the wiring tightening mechanism to move to the wiring end of the heating element, measuring the torque during rotation by using the wiring tightening mechanism and the torque sensor, and after the torque is maximum, reversing the servo motor appropriately to enable the bolt to be in the optimal fastening torque value, so as to eliminate the heating problem caused by poor contact at the wiring position or over-tightening and over-loosening of the bolt;

step four: if the operation is not successful, the elements in the cabinet are still in a heating state, the power supply of the elements is cut off by the central processing module, an alarm is sent, and the elements are reminded to be replaced and overhauled manually.

Compared with the prior art, the invention has the beneficial effects that:

1. when the temperature and humidity sensor in the cabinet detects the temperature and humidity, the central processing module sends signals to the motor driving module and the semiconductor controller when the internal humidity is detected to be high, the motor driving module drives the first stepping motor and the motor in the exhaust fan to operate, the exhaust fan is driven to move in a reciprocating mode by virtue of the ball screw guide rail, meanwhile, the semiconductor controller drives the semiconductor refrigerating sheet to heat, the honeycomb-shaped active silica gel layer is continuously dried, moisture is rapidly released by the exhaust fan, and hidden dangers caused by high humidity are eliminated; when the internal temperature is detected to be higher, the bus room or the functional room is judged to be higher, then the central processing module sends a signal to the motor driving module, the temperature sensing probe on the guide rail scans the interior of the cabinet to confirm a heating source, then the first step motor drives the ball screw guide rail to drive the exhaust fan to move to the rear end face of a heating source element, the semiconductor refrigerating sheet is matched for refrigeration to carry out fixed-point heat dissipation on the heating source element, meanwhile, the temperature sensing probe uploads element information to the image processing cloud end to identify the specification of a wiring bolt of the heating source element, the information is fed back to the central processing module, the transverse belt guide rail is matched with the longitudinal belt guide rail to drive the wiring tightening mechanism to move to the bit seat to align the bit corresponding to the specification of the bolt, the electric push rod drives the wiring tightening mechanism to extend out to clamp the bit into the hexagonal positioning groove, and the bit is adsorbed and fixed by the electromagnet, the transverse belt guide rail and the longitudinal belt guide rail are continuously matched to drive the wiring tightening mechanism to move to the wiring end of the heating element, the wiring tightening mechanism is utilized to rotate the bolt, the torque during rotation is measured by the torque sensor, after the torque is maximum, the servo motor is properly reversed to enable the bolt to be in the optimal fastening torque value, and the heating problem caused by poor contact at the wiring position or over-tightening and over-loosening of the bolt is eliminated.

2. Before the investigation, the central processing module sends a signal to the motor driving module to drive the second stepping motor to operate, the transverse belt guide rail drives the longitudinal belt guide rail to move to a middle position, the longitudinal belt guide rail drives the temperature sensing probe on the second slide block to scan image information of elements in the cabinet, the image information is uploaded to the image processing cloud terminal through the wireless data transmission module and stored in the database, when the subsequent self-inspection is investigated, the central processing module can repeat the previous steps to scan the image information in the cabinet and transmit the image information to the image processing cloud terminal, after receiving the image information, the image processing cloud terminal compares the image information with an image prestored in the database and feeds back a comparison result to the central processing module, and if the comparison image is different, the possibility that a maintenance person omits a maintenance tool in the cabinet exists, at the moment, the central processing module gives an alarm to remind personnel to overhaul and maintain, and the self-checking functionality is further improved.

Drawings

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic view of the internal structure of the intelligent cabinet body of the present invention;

FIG. 3 is a schematic view of a back side structure of the first cabinet door of the present invention;

FIG. 4 is a schematic view of the internal structure of the wire takeup mechanism of the present invention;

FIG. 5 is a partial structural diagram of a batch head according to the present invention;

FIG. 6 is a schematic view of the back structure of the main body of the intelligent cabinet of the present invention;

FIG. 7 is a schematic diagram of the present invention;

in the figure: 1. an intelligent cabinet main body; 2. a wire inlet seat; 3. a wire outlet seat; 4. a heat dissipation frame; 5. a first stepper motor; 6. a control seat; 7. a touch display screen; 8. a first cabinet door; 9. a second cabinet door; 10. a bounce lock; 11. a hinge; 12. a bus chamber; 13. a functional chamber; 14. a ground group row; 15. a busbar mounting seat; 16. a functional unit mount; 17. a honeycomb-shaped active silica gel layer; 18. a guide rail bar; 19. a bolt; 20. a temperature and humidity sensor; 21. a screwdriver seat; 22. a hexagonal groove; 23. a drive frame; 24. a transverse belt guide; 25. a first slider; 26. a longitudinal belt guide; 27. a first guide block; 28. a first guide post; 29. a second stepping motor; 30. a second slider; 31. a temperature sensing probe; 32. an electric push rod; 33. a wire connection tightening mechanism; 331. a housing; 332. a rotating base; 333. a hexagonal positioning groove; 334. an electromagnet; 335. concentric wheels; 336. a driven shaft; 337. a turbine; 338. a torque sensor; 339. a servo motor; 340. a worm; 34. a hexagonal screwdriver head seat; 35. a ferromagnetic batch head; 36. a ball screw guide; 37. a sliding table; 38. an exhaust fan; 39. a protective net; 40. a second guide block; 41. a second guide post; 42. a dust-proof net; 43. a linkage column; 44. a central processing module; 45. a semiconductor controller; 46. a semiconductor refrigeration sheet; 47. a wireless data transmission module; 48. and a motor driving module.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

Referring to fig. 1-7, an embodiment of the present invention is shown: the intelligent cabinet with the remote self-checking and troubleshooting function based on the Internet comprises an intelligent cabinet main body 1, a control seat 6 is arranged at the middle position inside the intelligent cabinet main body 1, a touch display screen 7 is installed on the front end face of the control seat 6, a first cabinet door 8 is installed above the front end face of the intelligent cabinet main body 1, a second cabinet door 9 is installed below the front end face of the intelligent cabinet main body 1, one sides of the first cabinet door 8 and the second cabinet door 9 are rotatably connected with the intelligent cabinet main body 1 through hinges 11, the other sides of the first cabinet door 8 and the second cabinet door 9 are connected with the intelligent cabinet main body 1 in a locking mode through bounce locks 10, a bus chamber 12 is arranged inside the upper portion of the intelligent cabinet main body 1, a ground bank 14 is installed at the upper end inside the bus chamber 12, a function chamber 13 is arranged inside the lower portion of the intelligent cabinet main body 1, a wire inlet seat 2 is installed on the upper end face of the intelligent cabinet main body 1, and a wire outlet seat 3 is installed on the lower end face of the intelligent cabinet main body 1;

further comprising:

the transmission frame 23 is arranged on the rear end faces of the first cabinet door 8 and the second cabinet door 9, and the transmission frame 23 is connected with the first cabinet door 8 and the second cabinet door 9 through a welding machine;

a transverse belt guide rail 24 which is arranged at the middle position inside the transmission frame 23, a first slide block 25 is arranged on the transverse belt guide rail 24, the first slide block 25 is in transmission connection with the transverse belt guide rail 24, a longitudinal belt guide rail 26 is arranged on the outer wall of the first slide block 25, a second slide block 30 is arranged on the longitudinal belt guide rail 26, the second slide block 30 is in transmission connection with the longitudinal belt guide rail 26, and a second stepping motor 29 is arranged at one end of each of the transverse belt guide rail 24 and the longitudinal belt guide rail 26;

an electric push rod 32 mounted on the front end surface of the second slider 30;

a wire tightening mechanism 33 mounted on an output end of the electric push rod 32;

and a temperature sensing probe 31 mounted above the electric push rod 32.

Referring to fig. 3, first guide posts 28 are disposed above and below the transverse belt guide rail 24, first guide blocks 27 are disposed behind two ends of the longitudinal belt guide rail 26, the first guide blocks 27 are slidably connected to the first guide posts 28, and the first guide posts 28 can play a role in assisting in guiding while the transverse belt guide rail 24 drives the longitudinal belt guide rail 26 to move transversely, so as to improve the movement stability.

Referring to fig. 4, a housing 331 is disposed outside the wire connection tightening/loosening mechanism 33, a heat dissipation groove is disposed on an outer wall of the housing 331, a servo motor 339 is disposed inside the housing 331, a worm 340 is disposed at an output end of the servo motor 339, a worm wheel 337 is disposed above the worm 340, a driven shaft 336 is disposed inside the worm wheel 337, a torque sensor 338 is disposed at a rear end of the driven shaft 336, a concentric wheel 335 is disposed on an outer wall of a front end of the driven shaft 336, a front end of the driven shaft 336 penetrates and extends to an outside of the housing 331, and a rotating base 332 is disposed inside the rotating base 332, a hexagonal positioning groove 333 is disposed inside the rotating base 332, an electromagnet 334 is disposed at a rear end of the hexagonal positioning groove 333, the servo motor 339 can drive the rotating base 332 to select through a transmission effect of the worm wheel 337 and the worm 340, the concentric wheel 335 can improve rotation accuracy, and the torque sensor 338 can measure a torque value when a bolt is screwed in a batch head, the tightness of the bolt can be conveniently adjusted.

Referring to fig. 2, 4 and 5, a hexagonal screwdriver seat 34 is installed inside the hexagonal positioning groove 333, a strong magnetic screwdriver head 35 is installed at the front end of the hexagonal screwdriver seat 34, a screwdriver seat 21 is installed on one side inside each of the bus chamber 12 and the function chamber 13, a plurality of hexagonal grooves 22 are installed inside the screwdriver seat 21, and multiple screwdriver heads with different specifications are placed in the hexagonal grooves 22 in the screwdriver seat 21, so that the device can conveniently select a proper screwdriver head to install according to the specification of the bolt of the failed component to adjust the tightness of the bolt.

Referring to fig. 2, a busbar mounting seat 15 is mounted at the rear end inside a busbar chamber 12, two busbar mounting seats 15 are provided, a functional unit mounting seat 16 is mounted at the rear end inside a functional chamber 13, four functional unit mounting seats 16 are provided, two ends of the busbar mounting seat 15 and two ends of the functional unit mounting seat 16 are respectively in threaded connection with the inner walls of the busbar chamber 12 and the functional chamber 13 through bolts 19, cellular active silica gel layers 17 are respectively provided inside the busbar mounting seat 15 and the functional unit mounting seats 16, guide rail bars 18 are respectively provided at the front ends of the busbar mounting seat 15 and the functional unit mounting seats 16, two ends of the guide rail bars 18 are welded with the busbar mounting seat 15 and the functional unit mounting seats 16, and the cellular active silica gel layers 17 can absorb humidity inside the cabinet and avoid the occurrence of a high humidity condition.

Referring to fig. 1 and 6, a heat dissipation frame 4 is installed on the rear end face of an intelligent cabinet main body 1, three ball screw guide rails 36 are installed inside the heat dissipation frame 4, a first stepping motor 5 is installed at one end of each ball screw guide rail 36, exhaust fans 38 are installed at the rear ends of honeycomb-shaped active silica gel layers 17, adjacent exhaust fans 38 are synchronously connected through linkage columns 43, adjacent upper exhaust fans 38 are in transmission connection with the ball screw guide rails 36 through sliding tables 37, a second guide block 40 is installed at the lower end of adjacent lower exhaust fans 38, a second guide column 41 is installed inside the second guide block 40, two ends of the second guide column 41 are fixedly connected with the inner wall of the heat dissipation frame 4, and the ball screw guide rails 36 can drive the exhaust fans 38 to move, so that dehumidification and refrigeration are realized.

Referring to fig. 6, a protective net 39 is installed on the front end surface of the exhaust fan 38, a dust-proof net 42 is installed on the rear end surface of the honeycomb-shaped activated silica gel layer 17, and both the protective net 39 and the dust-proof net 42 have a good protection effect and can isolate dust and prevent dust from entering the cabinet.

Referring to fig. 2 and 7, temperature and humidity sensors 20 are mounted on the other sides of the interior of the bus chamber 12 and the interior of the function chamber 13, a semiconductor cooling plate 46 is mounted on the rear end surface of the exhaust fan 38, the temperature and humidity sensors 20 are used for detecting temperature and humidity in the cabinet, and the semiconductor cooling plate 46 can be switched between a heating mode and a cooling mode according to requirements.

Referring to fig. 7, a central processing module 44, a semiconductor controller 45, a wireless data transmission module 47 and a motor driving module 48 are installed inside the control base 6, an output end of the central processing module 44 is electrically connected with an input end of the semiconductor cooling plate 46 through the semiconductor controller 45, an output end of the central processing module 44 is electrically connected with input ends of the first stepping motor 5, the second stepping motor 29, the servo motor 339, the electric push rod 32 and the exhaust fan 38 through the motor driving module 48, input ends of the temperature sensing probe 31, the torque sensor 338 and the temperature and humidity sensor 20 are electrically connected with an output end of the central processing module 44, an output end of the central processing module 44 is electrically connected with an input end of the electromagnet 334, the central processing module 44 is electrically connected with the touch display screen 7 and the wireless data transmission module 47 in a bidirectional manner, an output end of the wireless data transmission module 47 is connected with an input end of the monitoring terminal, the wireless data transmission module 47 is connected with the image processing cloud in a bidirectional mode, the image processing cloud is connected with the database in a bidirectional mode, and the central processing module 44 is used for completing signal transmission work in the cabinet.

Referring to fig. 1 to 7, the intelligent cabinet self-checking method with remote self-checking function based on the internet includes the following steps:

the method comprises the following steps: when the intelligent cabinet main body 1 is used, the bus units and the functional units are respectively installed on the guide rail strips 18 of the bus bar installation seat 15 and the functional unit installation seat 16, cellular activated silica gel layers 17 are arranged inside the bus bar installation seat 15 and the functional unit installation seat 16, moisture in the cabinet is adsorbed all the time, before the inspection, under the condition that the arrangement of elements in the cabinet is normal, a central processing module 44 sends signals to a motor driving module 48 to drive a second step motor 29 to operate, a transverse belt guide rail 24 is used for driving a longitudinal belt guide rail 26 to move to a middle position, the longitudinal belt guide rail 26 drives a temperature sensing probe 31 on a second sliding block 30 to scan image information of the elements in the cabinet, and the image information is uploaded to an image processing cloud through a wireless data transmission module 47 and stored in a database;

step two: during troubleshooting, firstly, the central processing module 44 sends a signal to the motor driving module 48 to drive the second stepping motor 29 to operate, the transverse belt guide rail 24 is matched with the longitudinal belt guide rail 26 to scan image information in the cabinet and transmit the image information to the image processing cloud, after the image processing cloud receives the image information, the image information is compared with an image stored in the database in advance, a comparison result is fed back to the central processing module 44, the comparison image is different, the possibility that a maintenance worker omits a maintenance tool in the cabinet exists, at the moment, the central processing module 44 sends an alarm to remind the worker of maintenance, and if the difference does not exist, next-step troubleshooting is carried out;

step three: the temperature and humidity are detected by a temperature and humidity sensor 20 in the cabinet, when the internal humidity is detected to be high, a central processing module 44 sends signals to a motor driving module 48 and a semiconductor controller 45, the motor driving module 48 drives a first stepping motor 5 and a motor in an exhaust fan 38 to operate, the exhaust fan 38 is driven to move in a reciprocating mode by virtue of a ball screw guide rail 36, meanwhile, the semiconductor controller 45 drives a semiconductor refrigerating sheet 46 to heat, the honeycomb-shaped active silica gel layer 17 is dried continuously, moisture is rapidly emitted by the exhaust fan 38, and hidden dangers caused by high humidity are eliminated; when the internal temperature is detected to be higher, the temperature in the bus chamber 12 or the temperature in the function chamber 13 is judged to be higher, then the central processing module 44 sends a signal to the motor driving module 48, the temperature sensing probe 31 on the guide rail scans the interior of the cabinet to confirm a heating source, then the first stepping motor 5 drives the ball screw guide rail 36 to drive the exhaust fan 38 to move to the rear end face of a heating source element, the semiconductor refrigerating sheet 46 is matched for refrigeration to carry out fixed-point heat dissipation on the heating source element, meanwhile, the temperature sensing probe 31 uploads element information to the image processing cloud end to identify the specification of a wiring bolt, the information is fed back to the central processing module 44, the transverse belt guide rail 24 is matched with the longitudinal belt guide rail 26 to drive the wiring loosening mechanism 33 to move to the position of the batch head seat 21 to align the batch head corresponding to the specification of the bolt, the electric push rod 32 drives the wiring loosening mechanism 33 to extend out to clamp the batch head into the hexagonal positioning groove 333, after the electromagnet 334 is used for adsorbing and fixing the bolt, the transverse belt guide rail 24 and the longitudinal belt guide rail 26 are continuously matched to drive the wiring tightening mechanism 33 to move to the wiring end of the heating element, the wiring tightening mechanism 33 is used for rotating the bolt, the torque sensor 338 is used for measuring the torque during rotation, after the torque is maximum, the servo motor 339 is reversed moderately, the bolt is in the optimal fastening torque value, and the heating problem caused by poor contact at the wiring end or over-tightening and over-loosening of the bolt is eliminated;

step four: if the operation is not successful and the elements in the cabinet are still in a heating state, the central processing module 44 cuts off the power supply of the elements and sends an alarm to remind people to replace and overhaul the elements.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims (10)

1. An intelligent cabinet with a remote self-checking function based on the Internet comprises an intelligent cabinet main body (1), wherein a control seat (6) is arranged at the middle position inside the intelligent cabinet main body (1), a touch display screen (7) is installed on the front end face of the control seat (6), a first cabinet door (8) is installed above the front end face of the intelligent cabinet main body (1), a second cabinet door (9) is installed below the front end face of the intelligent cabinet main body (1), one sides of the first cabinet door (8) and the second cabinet door (9) are rotatably connected with the intelligent cabinet main body (1) through hinges (11), the other sides of the first cabinet door (8) and the second cabinet door (9) are connected with the intelligent cabinet main body (1) in a locking mode through bounce locks (10), a bus chamber (12) is arranged inside the intelligent cabinet main body (1), and a ground bank (14) is installed at the upper end inside the bus chamber (12), a function chamber (13) is arranged in the lower part of the intelligent cabinet main body (1), a wire inlet seat (2) is arranged on the upper end face of the intelligent cabinet main body (1), and a wire outlet seat (3) is arranged on the lower end face of the intelligent cabinet main body (1);

the method is characterized in that: further comprising:

the transmission frame (23) is arranged on the rear end faces of the first cabinet door (8) and the second cabinet door (9), and the transmission frame (23) is connected with the first cabinet door (8) and the second cabinet door (9) through welding machines;

the transverse belt guide rail (24) is installed at the middle position inside the transmission frame (23), a first sliding block (25) is installed on the transverse belt guide rail (24), the first sliding block (25) is in transmission connection with the transverse belt guide rail (24), a longitudinal belt guide rail (26) is installed on the outer wall of the first sliding block (25), a second sliding block (30) is installed on the longitudinal belt guide rail (26), the second sliding block (30) is in transmission connection with the longitudinal belt guide rail (26), and a second stepping motor (29) is installed at one end of each of the transverse belt guide rail (24) and the longitudinal belt guide rail (26);

an electric push rod (32) mounted on the front end surface of the second slider (30);

a wire tightening mechanism (33) mounted on an output end of the electric push rod (32);

and a temperature sensing probe (31) mounted above the electric push rod (32).

2. The intelligent cabinet based on internet and having remote self-checking and checking function as claimed in claim 1, wherein: first guide posts (28) are arranged above and below the transverse belt guide rail (24), first guide blocks (27) are mounted behind two ends of the longitudinal belt guide rail (26), and the first guide blocks (27) are connected with the first guide posts (28) in a sliding mode.

3. The intelligent cabinet based on internet and having remote self-checking and checking function as claimed in claim 2, wherein: the outside of wiring elastic mechanism (33) is provided with casing (331), and is provided with the radiating groove on the outer wall of casing (331), the internally mounted of casing (331) has servo motor (339), install worm (340) on the output of servo motor (339), turbine (337) are installed to the top of worm (340), the internally mounted of turbine (337) has driven shaft (336), torque sensor (338) are installed to the rear end of driven shaft (336), install concentric wheel (335) on the outer wall of driven shaft (336) front end, the front end of driven shaft (336) runs through and extends to the outside of casing (331) and installs roating seat (332), the inside of roating seat (332) is provided with hexagonal constant head tank (333), electro-magnet (334) are installed to the rear end of hexagonal constant head tank (333).

4. The intelligent cabinet based on internet and having remote self-checking and checking function as claimed in claim 3, wherein: the utility model discloses a socket for bus, including socket for bus, head (35) are criticized to the internally mounted of hexagonal constant head tank (333) has the hexagonal head (34), the front end of hexagonal head tank (34) is provided with strong magnetism and criticizes head (35), head tank (21) are criticized all to the inside one side of generating line room (12) and function room (13), the inside of criticizing head tank (21) is provided with a plurality of hexagonal grooves (22).

5. The intelligent cabinet based on the internet and having the remote self-checking function as claimed in claim 4, wherein: busbar mount pad (15) is installed to the inside rear end of generating line room (12), and female row mount pad (15) is provided with two, functional unit mount pad (16) are installed to the inside rear end of functional room (13), and functional unit mount pad (16) are provided with four, female both ends of arranging mount pad (15) and functional unit mount pad (16) pass through bolt (19) respectively with the inner wall threaded connection of generating line room (12) and functional room (13), the inside of arranging mount pad (15) and functional unit mount pad (16) all is provided with cellular active silica gel layer (17), the front end of arranging mount pad (15) and functional unit mount pad (16) all is provided with guide rail bar (18), and the both ends of guide rail bar (18) and female mount pad (15) and functional unit mount pad (16) welded connection of arranging.

6. The intelligent cabinet based on internet and having remote self-checking and checking function as claimed in claim 5, wherein: a heat dissipation frame (4) is arranged on the rear end face of the intelligent cabinet main body (1), a ball screw guide rail (36) is arranged in the heat dissipation frame (4), three ball screw guide rails (36) are arranged, one end of each ball screw guide rail (36) is provided with a first stepping motor (5), the rear end of honeycomb active silica gel layer (17) all is provided with exhaust fan (38), and is adjacent through linkage post (43) synchronous online between exhaust fan (38), adjacent top exhaust fan (38) are connected with ball screw guide rail (36) transmission through slip table (37), adjacent below exhaust fan (38) lower extreme is installed second guide block (40), a second guide post (41) is arranged in the second guide block (40), and two ends of the second guide post (41) are fixedly connected with the inner wall of the heat dissipation frame (4).

7. The intelligent cabinet with the function of remote self-checking based on the Internet as claimed in claim 6, wherein: a protective net (39) is installed on the front end face of the exhaust fan (38), and a dust isolating net (42) is installed on the rear end face of the honeycomb-shaped active silica gel layer (17).

8. The intelligent cabinet based on internet and having remote self-checking and checking function as claimed in claim 7, wherein: temperature and humidity sensor (20) are all installed to the inside opposite side of generating line room (12) and function room (13), semiconductor refrigeration piece (46) are installed to the rear end face of exhaust fan (38).

9. The intelligent cabinet based on internet and having remote self-checking and checking function as claimed in claim 8, wherein: the intelligent temperature and humidity sensor is characterized in that a central processing module (44), a semiconductor controller (45), a wireless data transmission module (47) and a motor driving module (48) are arranged inside the control base (6), the output end of the central processing module (44) is electrically connected with the input end of a semiconductor refrigerating sheet (46) through the semiconductor controller (45), the output end of the central processing module (44) is electrically connected with the input ends of a first stepping motor (5), a second stepping motor (29), a servo motor (339), an electric push rod (32) and an exhaust fan (38) through the motor driving module (48), the input ends of a temperature sensing probe (31), a torque sensor (338) and a temperature and humidity sensor (20) are electrically connected with the output end of the central processing module (44), the output end of the central processing module (44) is electrically connected with the input end of an electromagnet (334), the system comprises a central processing module (44), a touch display screen (7), a wireless data transmission module (47), a monitoring terminal, an image processing cloud terminal and a database, wherein the central processing module (44) is electrically connected with the touch display screen (7) and the wireless data transmission module (47) in a two-way mode, the output end of the wireless data transmission module (47) is connected with the input end of the monitoring terminal, the wireless data transmission module (47) is connected with the image processing cloud terminal in a two-way mode, and the image processing cloud terminal is connected with the database in a two-way mode.

10. The intelligent cabinet self-checking and screening method based on the internet and having the remote self-checking and screening function as claimed in claim 9, comprising the following steps:

the method comprises the following steps: when the intelligent cabinet main body (1) is used, a bus unit and a functional unit are respectively arranged on a guide rail strip (18) of a bus mounting seat (15) and a guide rail strip (18) of a functional unit mounting seat (16), cellular active silica gel layers (17) are respectively arranged inside the bus mounting seat (15) and the functional unit mounting seat (16), moisture in the cabinet is adsorbed all the time, before investigation, under the condition that the elements in the cabinet are normally arranged, a central processing module (44) sends a signal to a motor driving module (48) to drive a second stepping motor (29) to operate, a transverse belt guide rail (24) is utilized to drive a longitudinal belt guide rail (26) to move to an intermediate position, the longitudinal belt guide rail (26) drives a temperature sensing probe (31) on a second sliding block (30) to scan the elements in the cabinet, and the image information is uploaded to an image processing cloud through a wireless data transmission module (47), storing the data into a database;

step two: during troubleshooting, firstly, a central processing module (44) sends a signal to a motor driving module (48) to drive a second stepping motor (29) to operate, a transverse belt guide rail (24) and a longitudinal belt guide rail (26) are matched to scan image information in the cabinet and transmit the image information to an image processing cloud, the image processing cloud compares the image information with an image prestored in a database after receiving the image information, a comparison result is fed back to the central processing module (44), if the comparison result is different from the image information, the possibility that a maintenance tool is missed in the cabinet by a maintenance worker is stored, at the moment, the central processing module (44) sends an alarm to remind the maintenance worker to carry out maintenance, and if the difference is not existed, next-step troubleshooting is carried out;

step three: the temperature and humidity are detected by a temperature and humidity sensor (20) in the cabinet, when the internal humidity is detected to be high, a central processing module (44) sends signals to a motor driving module (48) and a semiconductor controller (45), the motor driving module (48) drives a first stepping motor (5) and a motor in an exhaust fan (38) to operate, the exhaust fan (38) is driven to move in a reciprocating mode by a ball screw guide rail (36), meanwhile, the semiconductor controller (45) drives a semiconductor refrigerating sheet (46) to heat, a honeycomb-shaped active silica gel layer (17) is dried continuously, moisture is rapidly dissipated by the exhaust fan (38), and hidden dangers caused by high humidity are eliminated; when the internal temperature is detected to be higher, whether the temperature in the bus room (12) or the temperature in the function room (13) is judged to be higher, then a central processing module (44) sends a signal to a motor driving module (48), a temperature sensing probe (31) on a guide rail scans the interior of a cabinet to confirm a heating source, then a first stepping motor (5) drives a ball screw guide rail (36) to drive an exhaust fan (38) to move to the rear end face of a heating source element, the heating source element is subjected to fixed-point heat dissipation by matching with refrigeration of a semiconductor refrigerating sheet (46), meanwhile, the temperature sensing probe (31) uploads element information to an image processing cloud end to identify the specification of a wiring bolt, the information is fed back to the central processing module (44), and the information is matched with a transverse belt guide rail (24) and a longitudinal belt guide rail (26) to drive a wiring tightening mechanism (33) to move to a batch head seat (21) to align the batch head corresponding to the specification of the wiring bolt, an electric push rod (32) drives a wiring tightening mechanism (33) to extend out, so that a bit is clamped into a hexagonal positioning groove (333), the bit is adsorbed and fixed by an electromagnet (334), and then is continuously matched with a transverse belt guide rail (24) and a longitudinal belt guide rail (26) to drive the wiring tightening mechanism (33) to move to the terminal of a heating element, a torque sensor (338) measures the torque generated when the bolt rotates by using the wiring tightening mechanism (33), and after the torque is maximum, a servo motor (339) rotates reversely appropriately to enable the bolt to be in the optimal fastening torque value, so that the heating problem caused by poor contact at the wiring position or over-tightening and over-loosening of the bolt is eliminated;

step four: if the operation is not successful and the components in the cabinet are still in a heating state, the central processing module (44) cuts off the power supply of the components and sends an alarm to remind people to replace and overhaul the components.

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