CN220038029U - Effectual electrical engineering monitoring facilities of shock attenuation - Google Patents

Abstract

The utility model discloses electrical engineering monitoring equipment with good damping effect, which comprises a T-shaped base, a first damping spring, a second damping spring, a third damping spring, an electrical equipment placing plate and a fastening clamp, wherein the electrical equipment placing plate is arranged on the right side of the T-shaped base and is fixedly connected through the first damping spring and the second damping spring; the vertical plate of the T-shaped base is hinged with the left side of the electric equipment placing plate through a limiting connecting rod and a third damping spring; the surface of the electrical equipment placing plate is provided with a placing groove for placing electrical equipment; the electric equipment placing plate is provided with a fastening clamp for fastening and positioning electric equipment; and a limiting clamp for fastening and installing the detector is fixedly arranged on the right rear side of the surface of the electric equipment placing plate close to the edge. Vibration generated when the electrical equipment is operated is buffered through the three groups of damping springs, so that the vibration amplitude when the electrical equipment is operated is reduced, the monitoring equipment and the electrical equipment are stably connected, and the accuracy of a detection result is improved.

Description

Effectual electrical engineering monitoring facilities of shock attenuation

Technical Field

The utility model relates to the technical field of electrical engineering monitoring, in particular to electrical engineering monitoring equipment with good damping effect.

Background

The electric engineering comprises the subjects or engineering fields of electric energy generation, transformation, transmission, distribution, use, electrician equipment manufacture and the like. A large amount of electrical equipment is used in electrical engineering, and in order to ensure safe operation, a monitoring device is required to detect the state of the electrical equipment in real time. However, the electrical equipment is easy to shake violently during working, so that the existing electrical engineering monitoring equipment is not firmly connected with the detected electrical equipment, detection is affected, and the detection result is inaccurate.

Disclosure of Invention

Aiming at the technical defects, the utility model aims to provide the electrical engineering monitoring equipment with good damping effect, and the problem that the connection between the electrical engineering monitoring equipment and the detected electrical equipment is unstable because the electrical equipment is easy to shake violently during operation is solved.

In order to solve the technical problems, the utility model adopts the following technical scheme:

the utility model provides electrical engineering monitoring equipment with good damping effect, which comprises a T-shaped base formed by mutually perpendicular and fixedly connecting a transverse plate and a vertical plate, wherein a first damping spring, a second damping spring, a third damping spring, an electrical equipment placing plate and a fastening clamp piece are arranged on the right side of the T-shaped base and fixedly arranged on the transverse plate; the middle position of the bottom surface of the electrical equipment placing plate is fixedly connected with one end, far away from the transverse plate, of the first damping spring; the four corners of the bottom surface of the electrical equipment placing plate are symmetrically and fixedly provided with a second damping spring respectively, and one end, far away from the electrical equipment placing plate, of the second damping spring is fixedly connected with the transverse plate; two sides of the left bottom surface of the electrical equipment placing plate are respectively hinged with a vertical plate in the T-shaped base through a limiting connecting rod; a third damping spring is fixedly arranged between the left end of the electric equipment placing plate and a vertical plate in the T-shaped base; the surface of the electrical equipment placing plate is provided with a placing groove for placing electrical equipment; the electrical equipment placing plate is provided with a fastening clamp for fastening and positioning electrical equipment; the right rear side of the surface of the electric equipment placing plate is fixedly provided with a limiting clamp close to the edge, and the limiting clamp is used for fastening and installing a detector to detect electric equipment so as to form damping type electric engineering monitoring equipment.

Preferably, the fastening clamp consists of a fixed clamping plate, a transmission assembly and an inverted C-shaped supporting rod provided with the clamping plate; the transmission assembly comprises an existing screw transmission structure and a shaft rod with a sliding block, wherein the top surface of a moving block in the screw transmission structure is fixedly connected with the top surface of the sliding block on the shaft rod through an inverted C-shaped supporting rod to form a clamping plate structure capable of moving left and right; the fixed clamping plate is fixedly arranged at the left side of the electric equipment placing plate and is close to the edge, and the fixed clamping plate and the structure of the movable clamping plate can be matched with each other to form an electric equipment fixing clamp for fastening and positioning the monitored electric equipment through the clamp.

Preferably, the front side and the rear side of the electric equipment placing plate, which are close to the placing groove, are respectively provided with a U-shaped groove which is matched with the screw rod transmission structure and the shaft lever correspondingly from right to left, and the U-shaped grooves are respectively a front U-shaped groove and a rear U-shaped groove; the screw rod with the moving block in the screw rod transmission structure is arranged in the electric equipment placing plate through the front U-shaped groove, and the shaft rod with the sliding block is arranged in the electric equipment placing plate through the rear U-shaped groove; the baffle is fixedly arranged at the right end of the electric equipment placing plate and used for installing and fixing the transmission assembly, and a circular through hole matched with the front U-shaped groove is formed in the baffle and used for facilitating the screw rod to extend outwards and be connected with the rotating piece.

Preferably, a front rod in the inverted-C-shaped supporting rod extends into the front U-shaped groove to be fixedly connected with the moving block, and a rear rod in the inverted-C-shaped supporting rod extends into the rear U-shaped groove to be fixedly connected with the sliding block; the inverted C-shaped supporting rod moves left and right in the U-shaped groove through the transmission assembly.

Preferably, the limiting clamp is formed by combining limiting clamp blocks which are mirror symmetry and fixedly arranged at the left end and the right end of the bottom plate, and the limiting clamp blocks are formed by fixedly connecting fixed blocks with the clamp blocks through the existing telescopic limiting spring rod groups.

Preferably, the left side of the transverse plate in the T-shaped base is fixedly provided with a monitoring probe, and the monitoring probe is higher than the transverse plate in height and used for real-time and comprehensive monitoring.

The utility model has the beneficial effects that: the vibration-damping type electrical engineering monitoring equipment is convenient to use, vibration generated when the electrical equipment operates is buffered through the three groups of vibration-damping springs, the vibration amplitude of the electrical equipment during operation is reduced, the detector and the electrical equipment are tightly arranged on the same vibration-damping placing plate, the detector and the electrical equipment keep the same vibration amplitude, and the problem that the connection between the electrical engineering monitoring equipment and the detected electrical equipment is unstable due to the fact that the electrical equipment is easy to shake severely during operation is well solved; meanwhile, the accuracy of the detection result can be improved, and the electrical equipment can be comprehensively monitored through the monitoring probe, so that the electrical equipment can be conveniently maintained and replaced.

Drawings

In order to more clearly illustrate the embodiments of the utility model or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, it being obvious that the drawings in the following description are only some embodiments of the utility model, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a front view of an electrical engineering monitoring device with good damping effect according to an embodiment of the present utility model;

fig. 2 is an enlarged view of a portion a in fig. 1;

FIG. 3 is a rear view of FIG. 1;

FIG. 4 is a right side view of FIG. 1;

fig. 5 is a top view of fig. 1.

Reference numerals illustrate:

the device comprises a T-shaped base 1, a first damping spring 2, a second damping spring 3, a third damping spring 4, an electrical equipment placing plate 5, a fastening clamp 6, a limiting connecting rod 7, a limiting clamp 8 and a monitoring probe 9;

a placement groove 501, a U-shaped groove 502 and a baffle 503;

a fixed clamping plate 601, an inverted C-shaped supporting rod 602 and a transmission component 603;

a bottom plate 801 and a limiting clamp block 802.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Embodiment 1, as shown in fig. 1 to 5, an electrical engineering monitoring device with good damping effect comprises a T-shaped base 1 formed by mutually perpendicular and fixedly connecting a transverse plate and a vertical plate, a first damping spring 2, a second damping spring 3, a third damping spring 4, an electrical device placing plate 5 and a fastening clamp 6, wherein the first damping spring 2 is arranged on the right side of the T-shaped base 1 and fixedly arranged on the transverse plate; the middle position of the bottom surface of the electrical equipment placing plate 5 is fixedly connected with one end, far away from the transverse plate, of the first damping spring 2, and is used for primarily buffering vibration generated when the electrical equipment runs by utilizing the characteristics of the spring; the four corners of the bottom surface of the electrical equipment placing plate 5 are symmetrically and respectively provided with a second damping spring 3, and one end, far away from the electrical equipment placing plate 5, of the second damping spring 3 is fixedly connected with the transverse plate and is used for distributing pressure caused by vibration so as to further play a damping role; two sides of the left bottom surface of the electrical equipment placing plate 5 are respectively hinged with a vertical plate in the T-shaped base 1 through a limiting connecting rod 7 and are used for limiting the displacement of the electrical equipment placing plate caused by shaking; a third damping spring 4 is fixedly arranged between the left end of the electrical equipment placing plate 5 and a vertical plate in the T-shaped base 1 and is used for further playing a limiting role on the electrical equipment placing plate and playing a buffering role between the electrical equipment placing plate and the vertical plate; the surface of the electrical equipment placing plate 5 is provided with a placing groove 501 for placing electrical equipment; the electrical equipment placing plate 5 is provided with a fastening clamp 6 for fastening and positioning electrical equipment; the right rear side of the surface of the electric equipment placing plate 5 is fixedly provided with a limiting clamp 8 close to the edge, and the limiting clamp is used for fastening and installing a detector to detect electric equipment so as to form damping type electric engineering monitoring equipment. The elastic coefficient of the first damping spring is smaller than that of the second damping spring, so that the electric equipment placing plate can be conveniently in a vertical downward pressing state, and balance of the electric equipment placing plate is optimized.

Further, as shown in fig. 1 and 3 to 5, the fastening clip 6 is composed of a fixed clamping plate 601, a transmission assembly 603 and an inverted "C" shaped support bar 602 to which the clamping plate is mounted; the transmission assembly 603 comprises an existing screw transmission structure and a shaft rod with a sliding block, wherein the top surface of a moving block in the screw transmission structure is fixedly connected with the top surface of the sliding block on the shaft rod through an inverted C-shaped supporting rod 602 to form a clamping plate structure capable of moving left and right; the fixed clamping plate 601 is fixedly arranged at the left side of the electrical equipment placing plate 5 and is close to the edge, and the fixed clamping plate 601 and the structure of the left and right movable clamping plates are matched with each other to form an electrical equipment fixing clamp for fastening and positioning the monitored electrical equipment through the clamp.

Further, as shown in fig. 1, fig. 3, and fig. 4, the front and rear sides of the electric equipment placement plate 5, which are close to the placement groove 501, are respectively provided with a U-shaped groove 502 corresponding to the screw transmission structure and the shaft lever from right to left, and are respectively a front U-shaped groove and a rear U-shaped groove; the screw rod with the moving block in the screw rod transmission structure is arranged in the electric equipment placing plate 5 through a front U-shaped groove, and the shaft rod with the sliding block is arranged in the electric equipment placing plate 5 through a rear U-shaped groove; the baffle 503 is fixedly arranged at the right end of the electrical equipment placing plate 5 and used for installing and fixing a transmission component, and a circular through hole matched with the front U-shaped groove is formed in the baffle 503 and used for facilitating the outward extension of the screw rod and the connection of the rotating piece.

Further, as shown in fig. 1, the front rod of the inverted "C" shaped support bar 602 extends into the front U-shaped groove and is fixedly connected with the moving block, and the rear rod of the inverted "C" shaped support bar 602 extends into the rear U-shaped groove and is fixedly connected with the sliding block; the inverted C-shaped support bar 602 moves left and right in the U-shaped groove through a transmission assembly.

Further, as shown in fig. 1 and fig. 2, the limiting clamp 8 is formed by combining limiting clamp blocks 802 which are fixedly installed at the left end and the right end of the bottom plate 801 in a mirror symmetry manner, and the limiting clamp blocks 802 are formed by fixedly connecting fixed blocks with the clamp blocks through existing telescopic limiting spring rod groups.

Further, the monitoring probe 9 is fixedly installed on the left side of the transverse plate in the T-shaped base 1, and the monitoring probe is higher than the transverse plate in height and used for real-time and comprehensive monitoring.

Working principle: (1) Firstly, only the detected electrical equipment is placed in a placing groove on an electrical equipment placing plate, then a screw rod transmission assembly is rotated to drive a structure of a clamping plate capable of moving left and right to move left, and the electrical equipment is clamped and firmly installed on the electrical equipment placing plate by being matched with a fixed clamping plate; (2) The detector is buckled in the middle of the limiting clamp block, the detector is directly clamped and stably installed on the electric equipment placing plate through the telescopic limiting spring rod group clamp blocks at the two ends, the detector and the electric equipment are connected through the detection line, the detector and the electric equipment are installed and placed on the surface of the same placing panel at the moment, and the placing panel drives the detector to shake in the same direction when the electric equipment operates, so that the connection instability between the detector and the electric equipment is primarily reduced; (3) The vibration brought by the electrical equipment is buffered according to the characteristics of the springs, when the electrical equipment runs, the first damping springs and the second damping springs absorb the vibration generated by the electrical equipment, the first damping springs and the second damping springs are mutually matched to drive the placing panel to be pressed down, the third damping springs can pull the placing plate of the electrical equipment, further the shaking amplitude of the placing plate of the electrical equipment is limited, meanwhile, the left extrusion force of the placing panel is absorbed, the buffering effect is achieved, the collision of the placing panel to the transverse plate on the T-shaped base is reduced, the vibration generated by the electrical equipment is greatly reduced, the service life of the electrical equipment is prolonged, the connection stability between the detector and the electrical equipment is further guaranteed, and the accuracy of the detection result is further improved; (4) Whether the electrical equipment fails or not can be timely monitored by utilizing the monitoring probe, the detector or the combination of the monitoring probe and the detector, so that the electrical equipment can be timely maintained or replaced; when the electrical equipment is maintained or replaced, the movable clamping plate can be moved rightwards only by rotating the screw rod transmission assembly, and the electrical equipment can be taken down from the placing panel by loosening the electrical equipment, so that the operation is simple.

The vibration-damping type electrical engineering monitoring equipment is convenient to use, vibration generated when the electrical equipment operates is buffered through the three groups of vibration-damping springs, the vibration amplitude of the electrical equipment during operation is reduced, the detector and the electrical equipment are tightly arranged on the same vibration-damping placing plate, the detector and the electrical equipment keep the same vibration amplitude, and the problem that the connection between the electrical engineering monitoring equipment and the detected electrical equipment is unstable due to the fact that the electrical equipment is easy to shake severely during operation is well solved; meanwhile, the accuracy of the detection result can be improved, and the electrical equipment can be comprehensively monitored through the monitoring probe, so that the electrical equipment can be conveniently maintained and replaced.

It will be apparent to those skilled in the art that various modifications and variations can be made to the present utility model without departing from the spirit or scope of the utility model. Thus, it is intended that the present utility model also include such modifications and alterations insofar as they come within the scope of the appended claims or the equivalents thereof.

Claims (6)

1. Effectual electrical engineering monitoring facilities of shock attenuation, its characterized in that: the electric equipment placing plate comprises a T-shaped base formed by mutually perpendicular and fixedly connecting a transverse plate and a vertical plate, a first damping spring, a second damping spring, a third damping spring, an electric equipment placing plate and a fastening clamp, wherein the first damping spring is arranged on the right side of the T-shaped base and fixedly arranged on the transverse plate; the middle position of the bottom surface of the electrical equipment placing plate is fixedly connected with one end, far away from the transverse plate, of the first damping spring; the four corners of the bottom surface of the electrical equipment placing plate are symmetrically and fixedly provided with a second damping spring respectively, and one end, far away from the electrical equipment placing plate, of the second damping spring is fixedly connected with the transverse plate; two sides of the left bottom surface of the electrical equipment placing plate are respectively hinged with a vertical plate in the T-shaped base through a limiting connecting rod; a third damping spring is fixedly arranged between the left end of the electric equipment placing plate and a vertical plate in the T-shaped base; the surface of the electrical equipment placing plate is provided with a placing groove for placing electrical equipment; the electrical equipment placing plate is provided with a fastening clamp for fastening and positioning electrical equipment; the right rear side of the surface of the electric equipment placing plate is fixedly provided with a limiting clamp close to the edge, and the limiting clamp is used for fastening and installing a detector to detect electric equipment so as to form damping type electric engineering monitoring equipment.

2. The electrical engineering monitoring apparatus with good damping effect as claimed in claim 1, wherein: the fastening clamp consists of a fixed clamping plate, a transmission assembly and an inverted C-shaped supporting rod provided with the clamping plate; the transmission assembly comprises an existing screw transmission structure and a shaft rod with a sliding block, wherein the top surface of a moving block in the screw transmission structure is fixedly connected with the top surface of the sliding block on the shaft rod through an inverted C-shaped supporting rod to form a clamping plate structure capable of moving left and right; the fixed clamping plate is fixedly arranged at the left side of the electric equipment placing plate and is close to the edge, and the fixed clamping plate and the structure of the movable clamping plate are matched with each other to form the electric equipment fixing clamp.

3. The electrical engineering monitoring apparatus with good damping effect as claimed in claim 2, wherein: the front side and the rear side of the electric equipment placing plate, which are close to the placing groove, are respectively provided with a U-shaped groove which is matched with the screw rod transmission structure and the shaft lever correspondingly from right to left, and are respectively a front U-shaped groove and a rear U-shaped groove; the screw rod with the moving block in the screw rod transmission structure is arranged in the electric equipment placing plate through the front U-shaped groove, and the shaft rod with the sliding block is arranged in the electric equipment placing plate through the rear U-shaped groove; the right end of the electric equipment placing plate is fixedly provided with a baffle plate which is used for installing and fixing the transmission assembly, and the baffle plate is provided with a circular through hole which is matched with the front U-shaped groove.

4. A shock absorbing, effective electrical engineering monitoring apparatus as defined in claim 3 wherein: a front rod in the inverted C-shaped supporting rod extends into the front U-shaped groove and is fixedly connected with the moving block, and a rear rod in the inverted C-shaped supporting rod extends into the rear U-shaped groove and is fixedly connected with the sliding block; the inverted C-shaped supporting rod moves left and right in the U-shaped groove through the transmission assembly.

5. An electrical engineering monitoring apparatus with good damping effect as claimed in claim 1 or claim 4, characterized in that: the limiting clamp is formed by combining limiting clamp blocks which are mirror symmetry and fixedly arranged at the left end and the right end of the bottom plate, and the limiting clamp blocks are formed by fixedly connecting fixed blocks with the clamp blocks through the existing telescopic limiting spring rod groups.

6. An electrical engineering monitoring apparatus with good damping effect as claimed in claim 1 or claim 4, characterized in that: the left side of the transverse plate in the T-shaped base is fixedly provided with a monitoring probe, and the monitoring probe is higher than the transverse plate in height.