CN110108961B

CN110108961B - Power equipment detection device based on big data

Info

Publication number: CN110108961B
Application number: CN201910411772.7A
Authority: CN
Inventors: 段炼; 方贤文
Original assignee: Anhui University of Science and Technology
Current assignee: Anhui University of Science and Technology
Priority date: 2019-05-17
Filing date: 2019-05-17
Publication date: 2021-03-23
Anticipated expiration: 2039-05-17
Also published as: CN110108961A

Abstract

The invention belongs to the technical field of power equipment installation detection, and particularly relates to a power equipment detection device based on big data; the device comprises a mounting frame, side plates and an elastic cushion block; the side plates are uniformly provided with supporting sliding seats, T-shaped sliding rods are inserted in the supporting sliding seats in a sliding mode, and sliding grooves are formed in the T-shaped sliding rods; a pressure spring is inserted in the sliding groove, and a sliding seat is inserted in the pressure spring; the bottom end of the installation frame is uniformly provided with an elastic cushion block, the elastic cushion block is positioned right below the rotating wheel, and the interior of the elastic cushion block is of a cavity structure; the mounting frame and the side plate are both provided with air guide grooves, one ends of the air guide grooves are communicated with the supporting slide seat, and the other ends of the air guide grooves are communicated with the elastic cushion blocks of the cavity structures; the rotation wheel that sets up cooperates the support of elastic cushion under the effect of pressure spring, and the effort that equipment produced the vibration can offset each other under the external environment, and the effectual vibration that has reduced because equipment when using, and the equipment operation unstable phenomenon that leads to.

Description

Power equipment detection device based on big data

Technical Field

The invention belongs to the technical field of power equipment installation detection, and particularly relates to a power equipment detection device based on big data.

Background

The continuous progress of society makes the electric wire netting scale enlarge day by day, and the power equipment increases. The unstable parameters of the power equipment are more and more generated during operation, but the fault point cannot be found and maintained in time in a plurality of power equipment, and great economic loss is caused.

The development trend of the electric power is spread comprehensively, the electric power provides great convenient enjoyment for people in life and work, and the electric power brings convenience for people and can cause injury and trouble for people in life under the condition of improper use, so that the gravity center of the electric power equipment production and work field in China is not only put on the research and development and popularization of products, but also put a great part of the gravity center on the use safety of the electric power equipment.

When the existing power equipment is installed and detected, due to the fact that the shape of the power equipment is different, vibration or shaking of the power equipment is easily caused due to external shaking after the installation of the power equipment is completed, and then stable detection of a power equipment detection device is influenced, and the problem that when the power equipment is operated, the output of voltage and current is stable when the power equipment is operated in different states is difficult to detect in real time.

Disclosure of Invention

In order to make up for the defects of the prior art, the invention provides a power equipment detection device based on big data, which is mainly used for solving the problem that after the existing power equipment is installed, the vibration or shake phenomenon of the power equipment is easily caused by external shake, so that the stable detection of the power equipment detection device is influenced, and the stable output of voltage and current when the power equipment runs in different states is difficult to detect in real time.

The technical scheme adopted by the invention for solving the technical problems is as follows: the invention relates to a big data-based power equipment detection device which comprises an installation frame, side plates and an elastic cushion block, wherein the side plates are arranged on the installation frame; a side plate is fixed on the side wall of the mounting frame through a fixing column, and a supporting sliding seat is uniformly arranged on the side plate; a T-shaped sliding rod is inserted in the supporting sliding seat in a sliding manner, and a sliding groove is formed in the T-shaped sliding rod; a pressure spring is inserted in the sliding groove, a sliding seat is inserted in the pressure spring, a rotating wheel is rotatably arranged at the end part of the sliding seat, and an extrusion ring is arranged on the sliding seat; the extrusion ring is positioned at the port of the sliding groove, and the diameter of the extrusion ring is equal to that of the sliding groove; the distance from the side surface of the plurality of the rotating wheels to the side wall of the side plate is increased from top to bottom in sequence; the bottom end of the mounting frame is uniformly provided with an elastic cushion block, the elastic cushion block is positioned right below the rotating wheel, and the interior of the elastic cushion block is of a cavity structure; the mounting frame and the side plate are both provided with air guide grooves, one ends of the air guide grooves are communicated with the supporting slide seat, and the other ends of the air guide grooves are communicated with the elastic cushion blocks of the cavity structures;

in operation, irregularly shaped electrical equipment, such as inverted cone shaped electrical equipment, is placed within the mounting frame. Along with the continuous entering of equipment into the installation frame, the side wall of the equipment can extrude the rotating wheels uniformly arranged on the outer wall of the side plate and simultaneously push the rotating wheels to rotate, so that the power equipment is conveniently placed in the installation frame, when the rotating wheels are preliminarily extruded, the extrusion rings sleeved on the sliding seats can extrude the pressure springs, the reaction force of the extruded springs can play a role of preliminary buffering and damping on the power equipment, along with the continuous extrusion of the sliding seats, the sliding seats can push the T-shaped sliding rods to slide towards the supporting sliding seats, along with the continuous placing of the equipment into the installation frame, the side wall of the power equipment can be continuously extruded to form a plurality of rotating wheels on the side plate, the rotating wheels can be tightly attached to the outer wall of the equipment under the action force of the pressure springs, along with the sliding of the plurality of T-shaped sliding rods in the supporting sliding seats, the gas in the supporting sliding seats can enter the elastic cushion block of the cavity structure, the bottom end of the equipment is supported, the expanded elastic cushion block not only plays a role in supporting the equipment, but also plays a role in damping, and the rotating wheels are uniformly arranged, and the distance between the rotating wheels is reduced from top to bottom in sequence, so that the side wall of the power equipment can be abutted tightly, the phenomenon that the power equipment is inclined in a vibrating environment is prevented, and the normal operation and stable detection of the power equipment are influenced; installation frame bottom sets up elastic cushion under the support of stranded gas in the support slide simultaneously, prevent the phenomenon that equipment rocked from top to bottom, when equipment rocked from top to bottom, can extrude the lateral wall and go up the runner, and then make the interior gas of support slide enter into the elastic cushion, make elastic cushion produce the inflation, and then the bottom face contact with equipment, the support of cooperation elastic cushion under the effect of pressure spring is taken turns in the rotation that makes the setting, the effort that equipment produced the vibration under the external environment can offset each other, the effectual vibration that has reduced because equipment when using, and the unstable phenomenon of equipment operation that leads to.

Preferably, a plurality of rubber blocks are arranged inside the elastic cushion block, and honeycomb holes are formed in the plurality of rubber blocks; the honeycomb holes are filled with solution; the during operation, in the elastic cushion who enters into the cavity structure of stranded gas in the support slide, can jack-up a plurality of rubber blocks, along with gaseous continuous with a plurality of rubber blocks jack-up that makes progress, because elastic cushion is encapsulated situation, and be provided with solution in the honeycomb holes, and then the rubber block of jack-up not only can play and absorb absorbing shock-absorbing effect, the rubber block of jack-up simultaneously can strengthen elastic cushion, prevent that equipment weight is too big, lead to the phenomenon of elastic cushion undercut.

Preferably, an L-shaped support rod is slidably arranged on one side wall of the mounting frame, a sliding cavity is formed in the bottom end of the L-shaped support rod, and an elastic lantern ring is arranged at the top end of the L-shaped support rod; a T-shaped sliding column is inserted into the sliding cavity, and the end part of the T-shaped sliding column is fixed at the upper end part of the elastic cushion block; the end part of the L-shaped supporting rod is provided with an elastic rubber rod, and one end of the elastic rubber rod is connected with the end part of a T-shaped sliding rod arranged at the bottom end of the side plate; when the device is in operation, after the device is placed, a connecting wire of the device penetrates through the elastic sleeve ring, the arranged L-shaped supporting rod is inserted between the two fixing columns, when the elastic cushion block is upwards jacked, the T-shaped sliding column connected with the upper part is driven to upwards move, the L-shaped supporting rod is arranged on the installation frame in a sliding manner, and further the connecting wire inserted on the elastic sleeve ring is driven to upwards move, when the T-shaped sliding rod arranged at the bottom end of the side plate inwards slides, the elastic rubber rod is driven to inwards slide, and further the L-shaped supporting rod connected with the elastic rubber rod is driven to slide, and further the connecting wire inserted on the elastic sleeve ring is driven to slide left and right, so that when the power device shakes under the external vibration force, the connecting wire can synchronously move with the power device, and when the power device shakes, the phenomenon that the conductivity of the connecting wire is reduced, thereby affecting the accuracy of the power detection.

Preferably, the outer wall of the elastic lantern ring is made of an insulating rubber material; the inner part of the elastic lantern ring is provided with an annular cavity, the thickness of the inner wall of the annular cavity is smaller than that of the outer wall of the annular cavity, and the outer wall of the annular cavity is spliced with a sealing column; a plurality of elastic copper sheets are uniformly arranged on the inner wall of the elastic sleeve ring, and a voltage and current detection device is arranged at the outer end of the elastic sleeve ring; the voltage and current detection device is connected with the elastic copper sheet through a lead; when the device works, after the device is placed, the protective layer of the live wire of the connecting wire is stripped, the connecting wire is inserted into the elastic sleeve ring, the stripped live wire is in contact with the elastic copper sheet, after the inserting of the connecting wire is completed, the sealing column is pulled out, an operator fills gas into the annular cavity, the gas continuously enters the annular cavity along with the gas, the inner wall of the annular cavity is extruded, the inner wall of the elastic sleeve ring is contracted, the elastic copper sheet arranged in the elastic sleeve ring can clamp the live wire on the connecting wire, the arranged elastic copper sheet is equivalent to a wire, and the short circuit phenomenon of the live wire cannot be caused; because of the elasticity copper sheet passes through the wire to be connected with voltage current detection device, voltage current detection device sets up to the universal meter, and then can real-time detection power equipment's voltage or electric current, prevents to appear electric current or voltage transmission unstable phenomenon because of external vibrational force leads to power equipment.

Preferably, the top end of the side plate is rotatably provided with a gear disc through a rotating column, and the gear disc is connected with a pressing plate; the side plates are provided with sliding grooves, racks are arranged in the sliding grooves in a sliding mode, and the racks are meshed with the gear disc; the height of the sliding groove is greater than the thickness of the rack, the end part of the rack is connected with an elastic connecting rod, and the end part of the elastic connecting rod is connected with the end part of a T-shaped sliding rod arranged at the top end of the side plate; when the power equipment mounting frame works, after the power equipment is mounted on the mounting frame, the sliding groove can be arranged on the side plate in an inserting mode, and then the rack is arranged in the sliding groove in an inserting mode; when equipment vibrates downwards, because of the equipment is the back taper structure, and then can make the T shape slide bar inward sliding that the curb plate top set up, and then drive the rack through elastic connecting rod and inwards slide, and then make the pressure strip closely laminate with the upper surface of equipment, prevent that equipment from taking place the phenomenon of upwards rocking under external vibration's state.

Preferably, the inner side surface of the pressing plate is provided with an elastic extrusion block, and an elastic cavity is formed in the elastic extrusion block; a honeycomb-shaped cushion block is arranged in the elastic cavity; an air cavity is formed in the pressing plate, one end of the air cavity is communicated with the elastic cavity, and the other end of the air cavity is connected with a rubber hose; the rubber hose is communicated with the air guide groove; when the device works, the arranged elastic extrusion block can reduce the contact friction force between the compression plate and the upper surface of the device, meanwhile, when the T-shaped slide rod arranged at the top end of the side plate slides inwards, part of gas in the support slide seat enters the elastic cushion block to support the elastic cushion block, and the other part of gas enters the elastic cavity through the rubber hose; when equipment upwards vibrates, the upper surface of equipment can extrude the elastic extrusion piece, because the meshing of rack and gear, can make the gas in the elastic extrusion piece enter into the air guide groove through rubber hose, the rethread air guide groove enters into elastic cushion and supports in the slide, and then make elastic cushion and rotation wheel and equipment in close contact with, and simultaneously, because the meshing of rack and toothed disc, behind the equipment extrusion pressure strip, toothed disc on the pressure strip can drive the rack and outwards slide, and then drive the slip of T shape slide bar, make the rotation wheel can with the lateral wall in close contact with of equipment, the effectual external influence of rocking to equipment stable connection that has reduced.

The invention has the following beneficial effects:

1. according to the invention, through the matching of the rotating wheel and the elastic cushion block, when the equipment shakes, the rotating wheel on the side wall is extruded, so that the sliding seat pushes the T-shaped sliding rod to slide towards the supporting sliding seat, and further, gas in the supporting sliding seat enters the elastic cushion block, so that the elastic cushion block expands and is in contact with the bottom end surface of the equipment, the rotating wheel is matched with the support of the elastic cushion block under the action of the pressure spring, the acting force of the equipment which generates vibration under the external environment can be mutually offset, and the phenomenon of unstable equipment operation caused by the vibration of the equipment in use is effectively reduced, and further the stable detection effect of the power detection equipment is influenced.

2. According to the invention, the elastic copper sheet is arranged, the elastic copper sheet arranged in the elastic sleeve ring can clamp a live wire on the connecting wire, and the elastic copper sheet is connected with the voltage and current detection device through the wire, and the voltage and current detection device is set to be a universal meter, so that the voltage or current output condition of the power equipment in operation under different states can be detected in real time, and the phenomenon of unstable current or voltage transmission of the power equipment caused by external vibration force is prevented.

Drawings

The invention will be further explained with reference to the drawings.

FIG. 1 is a front view of the present invention;

FIG. 2 is a close-up view of the hold-down plate of the present invention;

FIG. 3 is a cross-sectional view of the elastomeric grommet of the present invention;

in the figure: the device comprises a mounting frame 1, an air guide groove 11, a side plate 2, a sliding groove 201, an elastic cushion block 3, a fixed column 4, a supporting sliding seat 5, a T-shaped sliding rod 6, a sliding groove 61, a pressure spring 7, a sliding seat 8, a rotating wheel 9, a squeezing ring 10, a rubber block 21, a honeycomb hole 211, an L-shaped supporting rod 22, a sliding cavity 221, an elastic lantern ring 23, an annular cavity 231, a T-shaped sliding column 24, an elastic rubber rod 25, a sealing column 26, an elastic copper sheet 27, a voltage and current detection device 28, a gear disc 29, a pressure strip 30, an air cavity 301, a rack 31, an elastic connecting rod 32, an elastic squeezing block 33, an elastic cavity 331, a honeycomb cushion block 34 and a rubber hose.

Detailed Description

A power equipment detection device based on big data according to an embodiment of the present invention will be described below with reference to fig. 1 to 3.

As shown in fig. 1, 2 and 3, the big data-based power equipment detection device according to the present invention includes a mounting frame 1, side plates 2 and a resilient pad 3; a side plate 2 is fixed on the side wall of the mounting frame 1 through a fixing column 4, and a supporting sliding seat 5 is uniformly arranged on the side plate 2; a T-shaped sliding rod 6 is inserted in the supporting sliding seat 5 in a sliding mode, and a sliding groove 61 is formed in the T-shaped sliding rod 6; a pressure spring 7 is inserted in the sliding groove 61, a sliding seat 8 is inserted in the pressure spring 7, a rotating wheel 9 is rotatably arranged at the end part of the sliding seat 8, and an extrusion ring 10 is arranged on the sliding seat 8; the extrusion ring 10 is positioned at the port of the sliding groove 61, and the diameter of the extrusion ring 10 is equal to that of the sliding groove 61; the distance between the side surfaces of the plurality of rotating wheels 9 and the side wall of the side plate 2 is increased from top to bottom; the bottom end of the installation frame 1 is uniformly provided with elastic cushion blocks 3, the elastic cushion blocks 3 are positioned right below the rotating wheels 9, and the interior of the elastic cushion blocks 3 is of a cavity structure; the mounting frame 1 and the side plate 2 are both provided with air guide grooves 11, one ends of the air guide grooves 11 are communicated with the supporting slide carriage 5, and the other ends of the air guide grooves 11 are communicated with the elastic cushion blocks 3 of the cavity structures;

in operation, irregularly shaped electrical equipment, such as inverted cone shaped electrical equipment, is placed within the mounting frame. Along with the continuous entering of equipment into installation frame 1, the lateral wall of equipment can extrude the rotating wheel 9 evenly arranged on the outer wall of lateral plate 2 and simultaneously push the rotating wheel 9 to rotate, so that the power equipment is placed in the installation frame 1, when the rotating wheel 9 is preliminarily extruded, the extrusion ring 10 sleeved on the sliding seat 8 can extrude the pressure spring 7, the reaction force of the extruded spring can play a role of preliminary buffering and damping on the power equipment, along with the continuous extrusion of the sliding seat 8, the sliding seat 8 can push the T-shaped sliding rod 6 to slide towards the supporting sliding seat 5, along with the continuous placing of the equipment into the installation frame 1, the lateral wall of the power equipment can continuously extrude the lateral plate 2 to be provided with a plurality of rotating wheels 9, the rotating wheels 9 can cling to the outer wall of the equipment under the action force of the pressure spring 7, along with the sliding of the plurality of T-shaped sliding rods 6 in the supporting sliding seat 5, the gas in the supporting sliding seat 5 can enter the elastic cushion block, the elastic cushion block 3 expands under the action of multiple strands of gas, so that the bottom end of the equipment is supported, the expanded elastic cushion block 3 not only plays a role in supporting the equipment, but also plays a role in damping, and the distance between the rotating wheels 9 is reduced from top to bottom in sequence through the uniformly arranged rotating wheels 9, so that the side wall of the power equipment can be tightly abutted, the phenomenon that the power equipment inclines in a vibrating environment is prevented, and the normal operation and stable detection of the power equipment are further influenced; installation frame bottom simultaneously sets up under the support of elastic cushion 3 stranded gas in supporting slide 5, prevent the phenomenon that equipment rocked from top to bottom, when equipment rocked from top to bottom, can extrude the lateral wall and go up runner 9, and then make supporting slide 5 interior gas enter into elastic cushion 3 in, make elastic cushion 3 produce the inflation, and then the bottom face contact with equipment, the support of cooperation elastic cushion 3 under the effect of pressure spring 7 is taken turns 9 in the rotation that makes the setting, the effort that equipment produced the vibration under external environment can offset each other, the effectual vibration that has reduced because equipment when using, and the unstable phenomenon of equipment operation that leads to.

As shown in fig. 1, a plurality of rubber blocks 21 are arranged inside the elastic cushion block 3, and honeycomb holes 211 are formed in the plurality of rubber blocks 21; the honeycomb holes 211 are filled with a solution; the during operation, in the elastic cushion 3 of cavity structure is entered into to stranded gas in the support slide 5, can be with a plurality of rubber blocks 21 jack-up, along with gaseous continuous jack-up that makes progress a plurality of rubber blocks 21, because elastic cushion 3 is encapsulated situation, and be provided with solution in the honeycomb holes 211, and then the rubber block 21 of jack-up not only can play the absorbing effect, the rubber block 21 of jack-up can strengthen elastic cushion 3's intensity simultaneously, prevent that equipment weight is too big, lead to the phenomenon of elastic cushion 3 undercut.

As shown in fig. 1 and 2, an L-shaped support rod 22 is slidably disposed on a side wall of the mounting frame 1, a sliding cavity 221 is formed at a bottom end of the L-shaped support rod 22, and an elastic collar 23 is disposed at a top end of the L-shaped support rod 22; a T-shaped sliding column 24 is inserted into the sliding cavity 221, and the end part of the T-shaped sliding column 24 is fixed at the upper end part of the elastic cushion block 3; an elastic rubber rod 25 is arranged at the end part of the L-shaped support rod 22, and one end of the elastic rubber rod 25 is connected with the end part of the T-shaped slide rod 6 arranged at the bottom end of the side plate 2; when the device is in operation, after the device is placed, the connecting wire of the device passes through the elastic sleeve ring 23, the arranged L-shaped support rod 22 is inserted between the two fixing columns 4, when the elastic cushion block is upwards jacked, the T-shaped sliding column 24 connected with the upper part is driven to upwards move, the L-shaped support rod is arranged on the installation frame 1 in a sliding manner, and further the connecting wire inserted on the elastic sleeve ring 23 is driven to upwards move, when the T-shaped sliding rod 6 arranged at the bottom end of the side plate 2 inwards slides, the elastic rubber rod 25 is driven to slide inwards, and further the L-shaped support rod 22 connected with the elastic rubber rod 25 is driven to slide, and further the connecting wire inserted on the elastic sleeve ring 23 is driven to slide left and right, so that when the power device shakes under the external vibration force, the connecting wire can synchronously move with the power device, and when the power device shakes, the phenomenon that the electric conductivity of the connecting wire is reduced, thereby affecting the accuracy of the power detection.

As shown in fig. 2 and 3, the outer wall of the elastic collar 23 is made of an insulating rubber material; an annular cavity 231 is formed in the elastic lantern ring 23, the thickness of the inner wall of the annular cavity 231 is smaller than that of the outer wall of the annular cavity 231, and a sealing column 26 is inserted into the outer wall of the annular cavity 231; a plurality of elastic copper sheets 27 are uniformly arranged on the inner wall of the elastic sleeve ring 23, and a voltage and current detection device 28 is arranged at the outer end of the elastic sleeve ring 23; the voltage and current detection device 28 is connected with the elastic copper sheet 27 through a lead; when the device works, after the device is placed, the protective layer of the live wire of the connecting wire is stripped, the connecting wire is inserted into the elastic sleeve ring 23, the stripped live wire is in contact with the elastic copper sheet 27, after the inserting of the connecting wire is completed, the sealing column 26 is pulled out, an operator fills gas into the annular cavity 231, the gas continuously enters the annular cavity 231, the inner wall of the annular cavity 231 is squeezed, the inner wall of the elastic sleeve ring 23 is contracted, the elastic copper sheet 27 arranged in the elastic sleeve ring 23 can clamp the live wire on the connecting wire, the arranged elastic copper sheet 27 is equivalent to a wire, and the short circuit phenomenon of the live wire cannot be caused; because of elasticity copper sheet 27 is connected with voltage current detection device 28 through the wire, voltage current detection device 28 sets up to the universal meter, and then can real-time detection power equipment's voltage or electric current, prevents to lead to power equipment to appear electric current or voltage transmission unstable phenomenon because of external vibrational force.

As shown in fig. 1 and 2, a gear plate 29 is rotatably arranged at the top end of the side plate 2 through a rotating column, and a pressing plate 30 is connected to the gear plate 29; the side plate 2 is provided with a sliding chute 201, a rack 31 is arranged in the sliding chute 201 in a sliding mode, and the rack 31 is meshed with the gear disc 29; the height of the sliding chute 201 is greater than the thickness of the rack 31, the end of the rack 31 is connected with an elastic connecting rod 32, and the end of the elastic connecting rod 32 is connected with the end of a T-shaped sliding rod 6 arranged at the top end of the side plate 2; during operation, after the power equipment is installed on the installation frame 1, the sliding groove 61 can be penetrated and arranged on the side plate 2, and then the rack 31 is penetrated and arranged in the sliding groove 201, because the height of the sliding groove 201 is greater than the thickness of the rack 31, an operator manually presses the rack 31 downwards to enable the rack 31 to be disengaged from the gear disc 29, and then the compression plate 30 is rotated to enable the compression plate 30 to be in close contact with the upper part of the equipment, and when the operator dials the gear upwards, the rack 31 is engaged with the gear disc 29; when equipment vibrates downwards, because of the equipment is the back taper structure, and then can make the T shape slide bar 6 inside slip that 2 tops of curb plate set up, and then drive rack 31 inside slip through elastic connecting rod 32, and then make pressure strip 30 closely laminate with the upper surface of equipment, prevent that equipment from taking place the phenomenon of upwards rocking under external vibration's state.

As shown in fig. 1 and 2, an elastic pressing block 33 is disposed on an inner side surface of the pressing plate 30, and an elastic cavity 331 is formed in the elastic pressing block 33; a honeycomb-shaped cushion block 34 is arranged in the elastic cavity 331; an air cavity 301 is formed in the pressing plate 30, one end of the air cavity 301 is communicated with the elastic cavity 331, and the other end of the air cavity 301 is connected with a rubber hose 35; the rubber hose 35 is communicated with the air guide groove 11; when the device works, the arranged elastic extrusion block 33 can reduce the contact friction force between the compression plate 30 and the upper surface of the device, meanwhile, when the T-shaped slide rod 6 arranged at the top end of the side plate 2 slides inwards, one part of gas in the supporting slide seat 5 enters the movable elastic cushion block 3 to support the elastic cushion block 3, the other part of gas enters the elastic cavity 331 through the rubber hose 35, and as the honeycomb-shaped cushion block is arranged in the elastic cavity 331, the honeycomb-shaped cushion block is continuously expanded along with the continuous entering of the gas, so that the elastic extrusion block 33 is supported and expanded, and the phenomenon that the elastic extrusion block 33 is deformed due to overlarge stress is prevented; when equipment upwards vibrates, the upper surface of equipment can extrude elasticity extrusion piece 33, because the meshing of rack 31 and gear, can make the gas in the elasticity extrusion piece 33 enter into air guide groove 11 through rubber hose 35, the rethread air guide groove 11 enters into elasticity cushion 3 and support slide 5, and then make elasticity cushion 3 and running wheel 9 and equipment in close contact with, simultaneously, because the meshing of rack 31 and toothed disc 29, behind equipment extrusion pressure strip 30, toothed disc 29 on the pressure strip 30 can drive rack 31 and outwards slide, and then drive T shape slide bar 6 and slide, make running wheel 9 can with the lateral wall in close contact with of equipment, the effectual influence of external rocking to equipment stable connection that has reduced.

The specific working process is as follows:

in operation, irregularly shaped electrical equipment, such as inverted cone shaped electrical equipment, is placed within the mounting frame. Along with the continuous entering of equipment into installation frame 1, the lateral wall of equipment can extrude the rotating wheel 9 evenly arranged on the outer wall of lateral plate 2 and simultaneously push the rotating wheel 9 to rotate, so that the power equipment is placed in the installation frame 1, when the rotating wheel 9 is preliminarily extruded, the extrusion ring 10 sleeved on the sliding seat 8 can extrude the pressure spring 7, the reaction force of the extruded spring can play a role of preliminary buffering and damping on the power equipment, along with the continuous extrusion of the sliding seat 8, the sliding seat 8 can push the T-shaped sliding rod 6 to slide towards the supporting sliding seat 5, along with the continuous placing of the equipment into the installation frame 1, the lateral wall of the power equipment can continuously extrude the lateral plate 2 to be provided with a plurality of rotating wheels 9, the rotating wheels 9 can cling to the outer wall of the equipment under the action force of the pressure spring 7, along with the sliding of the plurality of T-shaped sliding rods 6 in the supporting sliding seat 5, the gas in the supporting sliding seat 5 can enter the elastic cushion block, the elastic cushion block 3 expands under the action of a plurality of strands of gas, so that the bottom end of the equipment is supported, the expanded elastic cushion block 3 not only supports the equipment, but also has a damping effect, and the distance between the rotating wheels 9 is sequentially reduced from top to bottom through the uniformly arranged rotating wheels 9, so that the side wall of the power equipment can be tightly abutted; after the equipment is placed and is accomplished, pass the connecting wire of equipment in the elastic sleeve ring 23, simultaneously, operating personnel manually presses rack 31 downwards, makes rack 31 and toothed disc 29 break away from the meshing, and then rotates pressure strip 30, makes pressure strip 30 can with the upper portion in close contact with of equipment, stir the gear when operating personnel upwards, and then makes rack 31 and toothed disc 29 mesh, and then makes pressure strip 30 and power equipment's surface closely laminate.

In the description of the present invention, it is to be understood that the terms "center", "front", "rear", "vertical", "horizontal", "top", "bottom", "inner", "outer", etc., indicate orientations or positional relationships based on those shown in the drawings, and are used only for convenience in describing the present invention and for simplicity in description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore, should not be taken as limiting the scope of the present invention.

While the invention has been described with reference to specific embodiments, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted without departing from the scope of the invention. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the invention without departing from its scope. Therefore, it is intended that the invention not be limited to the particular embodiment disclosed, but that the invention will include all embodiments falling within the scope of the appended claims.

Claims

1. A power equipment detection device based on big data comprises an installation frame (1), side plates (2) and elastic cushion blocks (3); the method is characterized in that: the side wall of the mounting frame (1) is fixed with a side plate (2) through a fixing column (4), and the side plate (2) is uniformly provided with a supporting sliding seat (5); a T-shaped sliding rod (6) is inserted in the supporting sliding seat (5) in a sliding mode, and a sliding groove (61) is formed in the T-shaped sliding rod (6); a pressure spring (7) is inserted in the sliding groove (61), a sliding seat (8) is inserted in the pressure spring (7), a rotating wheel (9) is rotatably arranged at the end part of the sliding seat (8), and an extrusion ring (10) is arranged on the sliding seat (8); the extrusion ring (10) is positioned at the port of the sliding groove (61), and the diameter of the extrusion ring (10) is equal to that of the sliding groove (61); the distances from the side surfaces of the plurality of rotating wheels (9) to the side walls of the side plates (2) are sequentially increased from top to bottom; the bottom end of the mounting frame (1) is uniformly provided with elastic cushion blocks (3), the elastic cushion blocks (3) are positioned right below the rotating wheels (9), and the interior of the elastic cushion blocks (3) is of a cavity structure; the mounting frame (1) and the side plate (2) are both provided with air guide grooves (11), one ends of the air guide grooves (11) are communicated with the supporting slide seat (5), and the other ends of the air guide grooves (11) are communicated with the elastic cushion blocks (3) of the cavity structures; through the cooperation of rotation wheel (9) and elastic cushion block (3) that set up, when equipment rocked, can extrude and rotate driving wheel (9) on the lateral wall, and then make sliding seat promote T shape slide bar (6) to supporting slide (5) and slide, and then make and support slide (5) interior gas and enter into elastic cushion block (3), make elastic cushion block (3) produce the inflation, and then the bottom face contact with equipment, the support of cooperation elastic cushion block (3) under the effect of pressure spring (7) is taken turns (9) in the rotation that makes the setting, equipment can offset each other at the effort that external environment produced the vibration.

2. The big data-based power equipment detection device according to claim 1, wherein: a plurality of rubber blocks (21) are arranged inside the elastic cushion block (3), and honeycomb holes (211) are formed in the plurality of rubber blocks (21); the honeycomb holes (211) are filled with a solution.

3. The big data-based power equipment detection device according to claim 1, wherein: an L-shaped support rod (22) is arranged on one side wall of the mounting frame (1) in a sliding mode, a sliding cavity (221) is formed in the bottom end portion of the L-shaped support rod (22), and an elastic sleeve ring (23) is arranged at the top end portion of the L-shaped support rod (22); a T-shaped sliding column (24) is inserted in the sliding cavity (221), and the end part of the T-shaped sliding column (24) is fixed at the upper end part of the elastic cushion block (3); an elastic rubber rod (25) is arranged at the end part of the L-shaped supporting rod (22), and one end of the elastic rubber rod (25) is connected to the end part of a T-shaped sliding rod (6) arranged at the bottom end of the side plate (2).

4. The big data-based power equipment detection device according to claim 3, wherein: the outer wall of the elastic lantern ring (23) is made of an insulating rubber material; an annular cavity (231) is formed in the elastic sleeve ring (23), the thickness of the inner wall of the annular cavity (231) is smaller than that of the outer wall of the annular cavity (231), and a sealing column (26) is inserted into the outer wall of the annular cavity (231); a plurality of elastic copper sheets (27) are uniformly arranged on the inner wall of the elastic sleeve ring (23), and a voltage and current detection device (28) is arranged at the outer end of the elastic sleeve ring (23); the voltage and current detection device (28) is connected with the elastic copper sheet (27) through a lead.

5. The big data-based power equipment detection device according to claim 1, wherein: a gear disc (29) is rotatably arranged at the top end of the side plate (2) through a rotating column, and a pressing plate (30) is connected to the gear disc (29); the side plate (2) is provided with a sliding groove (201), a rack (31) is arranged in the sliding groove (201) in a sliding mode, and the rack (31) is meshed with the gear disc (29); the height of the sliding chute (201) is larger than the thickness of the rack (31), the end part of the rack (31) is connected with an elastic connecting rod (32), and the end part of the elastic connecting rod (32) is connected with the end part of a T-shaped sliding rod (6) arranged at the top end of the side plate (2).

6. The big data-based power equipment detection device according to claim 5, wherein: an elastic extrusion block (33) is arranged on the inner side surface of the compression plate (30), and an elastic cavity (331) is formed in the elastic extrusion block (33); a honeycomb-shaped cushion block (34) is arranged in the elastic cavity (331); an air cavity (301) is formed in the pressing plate (30), one end of the air cavity (301) is communicated with the elastic cavity (331), and the other end of the air cavity (301) is connected with a rubber hose (35); the rubber hose (35) is communicated with the air guide groove (11).