CN112325068A - Power equipment fault detection device and system - Google Patents

Abstract

The invention discloses a power equipment fault detection device which comprises a detection body, wherein a positioning sleeve column is arranged at the upper part of the detection body, a positioning sleeve block is sleeved on the positioning sleeve column in a sliding manner and connected with a detection sensor, the positioning sleeve block is also connected with a linkage rod, and the linkage rod is connected with a linkage device; the bottom of the linkage rod is provided with a hinged block, the hinged block is hinged with a hinged diagonal rod, and the two hinged diagonal rods are connected with the driver together. According to the invention, the driving motor is started, the driving bevel gear rotates, the driving bevel gear is meshed with the driven bevel gear, the driven bevel gear rotates, the power rotating shaft rotates, the positive thread area and the negative thread area rotate, the thread block rotates, the thread block drives the limiting slide block to move, the angle of the hinged inclined rod changes at the same time, the height change of the linkage rod is driven, and the height change of the sensor is detected, so that the height adjustment change can be carried out according to the requirement of power equipment to detect, and the detection efficiency is improved.

Description

Power equipment fault detection device and system

Technical Field

The invention relates to the technical field of power equipment, in particular to a power equipment fault detection device and system.

Background

The power equipment mainly comprises power generation equipment and power supply equipment, the power generated and supplied by the power equipment is closely related to the life of people, the stability of the power supply of the power equipment is determined by whether the use environment of the power equipment is safe or not and whether the power equipment can normally work or not, and the power equipment is greatly influenced by weather; the power secondary equipment forms a system, not only the device itself, such as alternating current, direct current, control loop, etc., but also the state of the equipment can not be analyzed and judged in real time because some loops have no monitoring means. Therefore, most of the protection is not in a condition for the condition of the overhaul in a strict sense in terms of the current application of the electrical secondary equipment.

Most of the existing power equipment fault detection devices are heavy, the detection operation is not very convenient, and the use efficiency is reduced, so that further improvement and treatment are needed.

Disclosure of Invention

The present invention is directed to a power equipment fault detection apparatus and system to solve the above problems.

In order to achieve the purpose, the invention provides the following technical scheme:

a power equipment fault detection device comprises a detection body, wherein a positioning sleeve column is arranged at the upper part of the detection body, a positioning sleeve block is sleeved on the positioning sleeve column in a sliding manner and connected with a detection sensor, and the positioning sleeve block is also connected with a linkage rod which is connected with a linkage device; the bottom of the linkage rod is provided with a hinge block, the hinge block is hinged with a hinge inclined rod, and the two hinge inclined rods are connected with a driver together;

an installation cavity is arranged in the detection body, an installation plate is arranged in the installation cavity, and the driver is arranged on the installation plate; the driver comprises a driving motor, an output shaft of the driving motor is connected with a driving bevel gear, the driving bevel gear is meshed with a driven bevel gear, the driven bevel gear is connected with a power rotating shaft, a positive thread area and a negative thread area are arranged on the power rotating shaft, the positive thread area and the negative thread area are respectively in threaded connection with a thread block, the upper part of the thread block is connected with a hinged inclined rod through a through block, a limiting slide block is arranged at the lower part of the thread block and is in sliding contact with an installation plate, and the limiting slide block is connected with a limiter on;

the installation cavity is internally provided with a buffer assembly, the buffer assembly is connected with a movable column, and the movable column penetrates through the detection body and is connected with a movable wheel.

Preferably, the top end of the positioning sleeve column is provided with a stop block.

Preferably, the linkage device comprises a linkage sleeve, a linkage sliding block is arranged in the linkage sleeve in a sliding mode, a linkage column is arranged on the upper portion of the linkage sliding block, the linkage sliding block is connected with the inner bottom wall of the linkage sleeve through a linkage spring, a linkage moving block is arranged at the top end of the linkage column, and the linkage moving block is connected with the linkage rod.

Preferably, the outer side wall of the linkage sleeve is further provided with an auxiliary cross rod, an auxiliary vertical post is arranged on the auxiliary cross rod, an auxiliary sleeve is sleeved on the auxiliary vertical post and is connected with the linkage moving block through an auxiliary connecting rod, and a positioning block is arranged at the top end of the auxiliary vertical post.

Preferably, the limiter comprises a limiting box, a touch block is arranged in the limiting box in a sliding mode, the touch block is connected with a touch column, the touch column is connected with a limiting sliding block, a movable contact piece is arranged on the touch block, a static contact piece is arranged on the inner side wall of the limiting box, the movable contact piece and the static contact piece are in contact with each other and used for alarming of an alarm, and the alarm is arranged on the outer side wall of the limiting box.

Preferably, two of the touch blocks are connected by a touch spring.

Preferably, the buffering assembly comprises a buffering box, a buffering slide block is arranged in the buffering box in a sliding manner, the lower part of the buffering slide block is connected with the moving column, the upper part of the buffering slide block is connected with a buffering fixed block through a vertical spring, the buffering fixed block is arranged on the inner top wall of the buffering box, the inner top wall of the buffering box is also provided with a supporting mechanism, the supporting mechanism is connected with the buffering slide block,

preferably, the lower part of the buffer sliding block is further hinged with a buffer inclined rod, a buffer transverse block is arranged on the inner bottom wall of the buffer box and is arranged in a buffer transverse groove in the inner bottom wall of the buffer box in a sliding manner, the buffer transverse block is hinged with the buffer inclined rod and is connected with the buffer inclined rod through a transverse spring.

Preferably, the supporting mechanism comprises a supporting box, a supporting slide block is arranged in the supporting mechanism in a sliding mode, the supporting slide block is connected with a supporting slide column, the supporting slide column is connected with a buffering slide block, and the supporting slide block is connected with the inner top wall of the supporting box through a supporting spring.

The utility model provides a system of power equipment fault detection device, includes detects the body, detects inductor, driver, buffering subassembly and removes the wheel, detects the inductor and is used for power equipment fault detection, and the driver is used for drive control to detect the height of inductor, and the buffering subassembly is used for removing the buffering of device structure when taking turns to remove.

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

(1) According to the invention, the driving motor is started, the driving bevel gear rotates, the driving bevel gear is meshed with the driven bevel gear, the driven bevel gear rotates, the power rotating shaft rotates, the positive thread area and the negative thread area rotate, the thread block rotates, the thread block drives the limiting slide block to move, the angle of the hinged inclined rod changes at the same time, the height change of the linkage rod is driven, and the height change of the sensor is detected, so that the height adjustment change can be carried out according to the requirement of power equipment to detect, and the detection efficiency is improved.

(2) The locating sleeve block slides on the locating sleeve column, the linkage column is driven to slide in the linkage sleeve through the linkage rod, the linkage spring is compressed and reset, meanwhile, the auxiliary sleeve slides on the auxiliary vertical column, and the motion stability of the detection sensor is further improved.

(3) The device removes, drives and removes the post removal, and the buffering slider slides in the cushion box then, erects the spring and realizes compressing and reseing, slides in supporting the box through supporting the slider simultaneously, and further compression of supporting spring and reseing, the change of buffering down tube angle drive the buffering horizontal block and slide in the buffering horizontal groove in addition, and further compression of horizontal spring, reseing, the device plays the buffering effect in the walking, has improved device structure protection effect.

(4) The movable contact piece and the static contact piece are in contact with each other to be used for alarming of the alarm, so that the effect of limiting the threaded block and simultaneously alarming is achieved.

Drawings

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

FIG. 2 is a schematic diagram of a driver according to the present invention;

FIG. 3 is a schematic view of a linkage according to the present invention;

FIG. 4 is a schematic view of the stopper of the present invention;

FIG. 5 is a schematic view of a buffer assembly according to the present invention.

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. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-5, in the embodiment of the present invention, an electrical equipment fault detection apparatus includes a detection body 1, a positioning sleeve column 2 is disposed on the upper portion of the detection body 1, a positioning sleeve block 3 is sleeved on the positioning sleeve column 2 in a sliding manner, the positioning sleeve block 3 is connected with a detection sensor 4, the positioning sleeve block 3 is further connected with a linkage rod 5, and the linkage rod 5 is connected with a linkage device 6; the bottom of the linkage rod 5 is provided with a hinge block 8, the hinge block 8 is hinged with a hinge inclined rod 9, and the two hinge inclined rods 9 are connected with a driver 10 together;

an installation cavity 11 is arranged in the detection body 1, an installation plate 12 is arranged in the installation cavity 11, and the driver 10 is arranged on the installation plate 12; the driver 10 comprises a driving motor 101, an output shaft of the driving motor 101 is connected with a driving bevel gear 102, the driving bevel gear 102 is meshed with a driven bevel gear 103, the driven bevel gear 103 is connected with a power rotating shaft 104, the power rotating shaft 104 is provided with a positive thread area 105 and a negative thread area 105, the positive thread area 105 and the negative thread area 105 are respectively in threaded connection with a thread block 106, the upper part of the thread block 106 is connected with a hinged inclined rod 9 through a through block 107, the lower part of the thread block 106 is provided with a limit slide block 108, the limit slide block 108 is arranged in sliding contact with a mounting plate 12, and the limit slide block 108 is connected;

the driving motor 101 is started, the driving bevel gear 102 rotates, the driving bevel gear 102 is meshed with the driven bevel gear 103, the driven bevel gear 103 rotates, the power rotating shaft 104 rotates, the positive thread area 105 and the negative thread area 105 rotate, the thread block 106 rotates, the thread block 106 drives the limiting slide block 108 to move, meanwhile, the angle change of the hinged inclined rod 9 drives the height change of the linkage rod 5, and further the height change of the inductor 4 is detected, so that the height adjustment change can be carried out according to the requirement of power equipment to detect, and the detection efficiency is improved;

the installation cavity 11 is internally provided with a buffer assembly 14, the buffer assembly 14 is connected with a movable column 15, and the movable column 15 penetrates through the detection body 1 and is connected with a movable wheel 16.

The top end of the positioning sleeve column 2 of the embodiment is provided with a stop block 7.

The linkage device 6 of the embodiment comprises a linkage sleeve 61, a linkage sliding block 62 is arranged in the linkage sleeve 61 in a sliding mode, a linkage column 63 is arranged at the upper portion of the linkage sliding block 62, the linkage sliding block 62 is connected with the inner bottom wall of the linkage sleeve 61 through a linkage spring 64, a linkage moving block 65 is installed at the top end of the linkage column 63, and the linkage moving block 65 is connected with a linkage rod 5.

The outer side wall of the linkage sleeve 61 of the embodiment is further provided with an auxiliary cross rod 66, an auxiliary vertical column 67 is arranged on the auxiliary cross rod 66, an auxiliary sleeve 68 is sleeved on the auxiliary vertical column 67, the auxiliary sleeve 68 is connected with the linkage moving block 65 through an auxiliary connecting rod 69, and a positioning block 610 is arranged at the top end of the auxiliary vertical column 67.

The positioning sleeve block 3 slides on the positioning sleeve column 2, the linkage column 63 is driven to slide in the linkage sleeve 61 through the linkage rod 5, the linkage spring 64 is compressed and reset, meanwhile, the auxiliary sleeve 68 slides on the auxiliary vertical column 67, and the motion stability of the detection sensor 4 is further improved.

The limiter 13 of the embodiment comprises a limiting box 131, a touch block 132 is arranged in the limiting box 131 in a sliding mode, the touch block 132 is connected with a touch column 133, the touch column 133 is connected with a limiting sliding block 108, a movable contact piece 134 is arranged on the touch block 132, a static contact piece 135 is arranged on the inner side wall of the limiting box 131, the movable contact piece 134 and the static contact piece 135 are in contact with each other and used for alarming of an alarm 136, and the alarm 136 is arranged on the outer side wall of the limiting box 131.

The two touch blocks 132 of the present embodiment are connected by a touch spring 137.

The limit slider 108 moves to drive the touch column 133 to move, then the touch block 132 moves, the movable contact piece 134 and the static contact piece 135 are in contact with an alarm for the alarm 136, the limit on the thread block 106 is achieved, and meanwhile the alarm effect is achieved.

The buffer assembly 14 of this embodiment includes a buffer box 141, a buffer slider 142 is slidably disposed in the buffer box 141, a lower portion of the buffer slider 142 is connected to the moving column 15, an upper portion of the buffer slider 142 is connected to a buffer fixed block 144 through a vertical spring 143, the buffer fixed block 144 is disposed on an inner top wall of the buffer box 141, a support mechanism 145 is further disposed on the inner top wall of the buffer box 141, the support mechanism 145 is connected to the buffer slider 142,

the lower part of the buffer slide block 142 of this embodiment is further hinged with a buffer inclined rod 146, the bottom wall of the buffer box 141 is provided with a buffer transverse block 147, the buffer transverse block 147 is slidably arranged in a buffer transverse groove 148 of the bottom wall of the buffer box 141, the buffer transverse block 147 is hinged with the buffer inclined rod 146, and the two buffer transverse blocks 147 are connected through a transverse spring 149.

The supporting mechanism 145 of this embodiment includes a supporting case 1451, a supporting slider 1452 is slidably provided in the supporting mechanism 145, the supporting slider 1452 is connected to a supporting slider 1453, the supporting slider 1453 is connected to the buffering slider 142, and the supporting slider 1452 is connected to an inner top wall of the supporting case 1451 by a supporting spring 1454.

The device moves to drive the moving column 15 to move, then the buffer sliding block 142 slides in the buffer box 141, the vertical spring 143 is compressed and reset, meanwhile, the support sliding block 1452 slides in the support box 1451, the support spring 1454 further compresses and resets, in addition, the angle of the buffer inclined rod 146 changes to drive the buffer transverse block 147 to slide in the buffer transverse groove 148, the transverse spring 149 further compresses and resets, the device plays a role in buffering in walking, and the protection effect of the device structure is improved.

A system of a power equipment fault detection device comprises a detection body 1, a detection inductor 4, a driver 10, a buffer assembly 14 and a moving wheel 16, wherein the detection inductor 4 is used for detecting faults of power equipment, the driver 10 is used for driving and controlling the height of the detection inductor 4, and the buffer assembly 14 is used for buffering a device structure when the moving wheel 16 moves.

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.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (10)

1. The power equipment fault detection device is characterized by comprising a detection body (1), wherein a positioning sleeve column (2) is arranged at the upper part of the detection body (1), a positioning sleeve block (3) is sleeved on the positioning sleeve column (2) in a sliding manner, the positioning sleeve block (3) is connected with a detection sensor (4), the positioning sleeve block (3) is also connected with a linkage rod (5), and the linkage rod (5) is connected with a linkage device (6); the bottom of the linkage rod (5) is provided with a hinge block (8), the hinge block (8) is hinged with a hinge inclined rod (9), and the two hinge inclined rods (9) are connected with a driver (10) together;

a mounting cavity (11) is arranged in the detection body (1), a mounting plate (12) is arranged in the mounting cavity (11), and the driver (10) is arranged on the mounting plate (12); the driver (10) comprises a driving motor (101), an output shaft of the driving motor (101) is connected with a driving bevel gear (102), the driving bevel gear (102) is meshed with a driven bevel gear (103), the driven bevel gear (103) is connected with a power rotating shaft (104), the power rotating shaft (104) is provided with a positive thread area and a negative thread area (105), the positive thread area and the negative thread area (105) are respectively in threaded connection with a thread block (106), the upper part of the thread block (106) is connected with a hinged inclined rod (9) through a through block (107), the lower part of the thread block (106) is provided with a limiting slide block (108), the limiting slide block (108) is in sliding contact with an installation plate (12), and the limiting slide block (108) is connected with a limiter (13) on the;

be equipped with buffering subassembly (14) in installation cavity (11), buffering subassembly (14) are connected with removal post (15), and removal post (15) pass and detect body (1) and are connected with removal wheel (16).

2. The power equipment fault detection device according to claim 1, characterized in that the top end of the positioning sleeve column (2) is provided with a stop block (7).

3. The power equipment fault detection device according to claim 2, wherein the linkage device (6) comprises a linkage sleeve (61), a linkage sliding block (62) is arranged in the linkage sleeve (61) in a sliding mode, a linkage column (63) is arranged on the upper portion of the linkage sliding block (62), the linkage sliding block (62) is connected with the inner bottom wall of the linkage sleeve (61) through a linkage spring (64), a linkage moving block (65) is installed at the top end of the linkage column (63), and the linkage moving block (65) is connected with the linkage rod (5).

4. The power equipment fault detection device according to claim 3, wherein an auxiliary cross rod (66) is further arranged on the outer side wall of the linkage sleeve (61), an auxiliary vertical column (67) is arranged on the auxiliary cross rod (66), an auxiliary sleeve (68) is sleeved on the auxiliary vertical column (67), the auxiliary sleeve (68) is connected with the linkage moving block (65) through an auxiliary connecting rod (69), and a positioning block (610) is arranged at the top end of the auxiliary vertical column (67).

5. The power equipment fault detection device according to claim 1, characterized in that the limiter (13) comprises a limiting box (131), a touch block (132) is arranged in the limiting box (131) in a sliding manner, the touch block (132) is connected with a touch column (133), the touch column (133) is connected with a limiting slider (108), a movable contact piece (134) is arranged on the touch block (132), a static contact piece (135) is arranged on the inner side wall of the limiting box (131), the movable contact piece (134) and the static contact piece (135) are in contact with each other for alarming of an alarm (136), and the alarm (136) is arranged on the outer side wall of the limiting box (131).

6. An electrical equipment fault detection device according to claim 5, characterized in that two of the contact blocks (132) are connected by a contact spring (137).

7. The power equipment fault detection device according to claim 1, wherein the buffer assembly (14) comprises a buffer box (141), a buffer sliding block (142) is arranged in the buffer box (141) in a sliding mode, the lower portion of the buffer sliding block (142) is connected with the moving column (15), the upper portion of the buffer sliding block (142) is connected with a buffer fixed block (144) through a vertical spring (143), the buffer fixed block (144) is arranged on the inner top wall of the buffer box (141), a supporting mechanism (145) is further arranged on the inner top wall of the buffer box (141), and the supporting mechanism (145) is connected with the buffer sliding block (142).

8. The electrical equipment fault detection device according to claim 7, characterized in that a buffering inclined rod (146) is further hinged to the lower portion of the buffering slide block (142), a buffering transverse block (147) is arranged on the inner bottom wall of the buffering box (141), the buffering transverse block (147) is slidably arranged in a buffering transverse groove (148) on the inner bottom wall of the buffering box (141), the buffering transverse block (147) is hinged to the buffering inclined rod (146), and the two buffering transverse blocks (147) are connected through a transverse spring (149).

9. An electric power equipment failure detection device according to claim 1, characterized in that said support mechanism (145) comprises a support box (1451), a support slider (1452) is slidably arranged in said support mechanism (145), said support slider (1452) is connected with a support strut (1453), said support strut (1453) is connected with a buffer slider (142), and said support slider (1452) is connected with an inner top wall of said support box (1451) through a support spring (1454).

10. A system of a power equipment failure detection device according to claims 1-9, characterized by comprising a detection body (1), a detection sensor (4), a driver (10), a buffer assembly (14) and a moving wheel (16), wherein the detection sensor (4) is used for power equipment failure detection, the driver (10) is used for driving and controlling the height of the detection sensor (4), and the buffer assembly (14) is used for buffering the device structure when the moving wheel (16) moves.

Images