CN219349923U - Shock attenuation mounting bracket of reactor - Google Patents

Abstract

The application discloses reactor shock attenuation mounting bracket relates to reactor mounting bracket technical field. The application includes the bottom plate, the bottom plate side is fixed with the protection frame, the loading board is installed to the bottom plate upper end, a plurality of mounting hole that is rectangular array and arranges has been seted up to the loading board upper end, the mounting hole inner wall is fixed with two guide blocks that are symmetrical arrangement, the loading board lower extreme is provided with installation mechanism. This application is when installing the reactor, place the reactor on the loading board, make the stopper slip through removing the slide bar, utilize spacing subassembly to carry out spacingly to the slide bar when stopper and reactor contact, realize the quick installation to the reactor, improve installation effectiveness, through removing to touching the pole for L shaped plate contacts with the reactor, carries out preliminary spacing fixedly to the reactor position, is convenient for install the reactor, and the reactor receives the condition that the collision produced the skew to take place in the reduction installation, promotes the convenience of use.

Description

Shock attenuation mounting bracket of reactor

Technical Field

The utility model relates to the technical field of reactor mounting frames, in particular to a shock absorption mounting frame for a reactor.

Background

The reactor is an element acting as impedance in the circuit, is an air coil without magnetic conductive material, has larger voltage drop when the circuit system is short-circuited, and can ensure the stable operation of the user electrical equipment on the non-fault circuit.

The vibration reduction mounting frame of the reactor, which is mentioned in the prior China publication (issued publication number: CN 217008859U), has good vibration reduction effect when the reactor is subjected to jolt vibration by arranging the vibration reduction table assembly, so that the stability is improved.

However, in the actual use process, the reactor is generally fixed by adopting a structure such as a bolt, other tools are needed in the installation process, the reactor is large in volume, and when the reactor is fixed by using the tools, the operation space is small and limited by the reactor, so that the installation is inconvenient.

Disclosure of Invention

The utility model aims at: the utility model provides a shock absorption mounting rack for a reactor, which aims to solve the problem that other tools are needed to be used in the mounting process of the reactor so as to be inconvenient to mount.

The utility model adopts the following technical scheme for realizing the purposes:

the utility model provides a reactor shock attenuation mounting bracket, includes the bottom plate, the bottom plate side is fixed with the protection frame, the loading board is installed to the bottom plate upper end, the mounting hole that a plurality of is rectangular array and arranges is seted up to the loading board upper end, the mounting hole inner wall is fixed with two guide blocks that are symmetrical arrangement, the loading board lower extreme is provided with installation mechanism, installation mechanism includes the stopper of sliding connection in the guide block side, the special-shaped groove has been seted up to the stopper side, be sliding connection between special-shaped groove and the guide block, the stopper lower extreme articulates there is the horizontal pole, the horizontal pole side is provided with drive assembly, the loading board side is provided with spacing subassembly.

Through adopting above-mentioned technical scheme, when needs installation reactor, place the reactor on the loading board for the mounting hole site aligns, utilizes installation mechanism to install fast the reactor, promotes the use convenience, when utilizing installation mechanism to install the reactor, makes the stopper rotate with drive assembly, when stopper and reactor are inconsistent, utilizes spacing subassembly to carry out spacingly to it, realizes the quick installation to the reactor.

Further, the drive assembly includes the push rod of fixing in the horizontal pole lower extreme, the push rod tip is fixed with the carrier block, the carrier block side is fixed with the guide post, guide post side sliding connection has the sliding block, the chute has been seted up to the sliding block side, be sliding connection between chute and the guide post, the sliding block side is fixed with the slide bar, be sliding connection between slide bar and the loading board.

Through adopting above-mentioned technical scheme, when installing the reactor, change the sliding block position through removing the slide bar to make the push rod remove in vertical direction, make the stopper rotate, carry out spacing fixedly to the reactor, promote convenient shape.

Further, the limiting assembly comprises an annular block fixed on the side face of the bearing plate, a rotating block is sleeved outside the sliding rod in a sliding mode, the rotating block is in threaded connection with the annular block, and a damper is arranged at the lower end of the bearing plate.

Through adopting above-mentioned technical scheme, after moving the slide bar to suitable position, rotatory rotating block makes cyclic annular piece and slide bar counterbalance contact, carries out spacingly to the slide bar.

Further, an anti-slip pad is fixed at the end part of the limiting block, and the anti-slip pad is strip-shaped.

Through adopting above-mentioned technical scheme, when stopper and reactor contact, slipmat is inconsistent with the reactor for the two laminating is inseparabler.

Further, the damper comprises a plurality of rubber damping blocks which are fixed at the upper end of the bottom plate and are arranged in a rectangular array, a spring is fixedly arranged at the upper end of each rubber damping block, an abutting block is fixedly arranged at the end of each spring, a telescopic rod is fixedly arranged at the lower end of each abutting block, the telescopic rods are fixedly connected with the rubber damping blocks, and the abutting blocks are in threaded connection with the bearing plate.

Through adopting above-mentioned technical scheme, when the reactor produced vibration in the course of the work, outside vibration transmitted to the spring, the rubber damping piece can reduce the amplitude, has the shock attenuation effect to the reactor.

Furthermore, the equal sliding connection in protection frame both sides has the conflict pole, conflict pole quantity is two and is symmetrical arrangement, conflict pole tip is fixed with the L shaped plate, conflict pole tip is provided with fixed subassembly.

Through adopting above-mentioned technical scheme, when placing the reactor on the loading board, make L shaped plate and reactor contact through removing to touching the pole, carry out preliminary fixed to the reactor, be convenient for install.

Further, the fixed subassembly is including fixing the fixed block in supporting the feeler lever side, the fixed slot has been seted up to the protection frame side, be fixed with the shell fragment in the fixed slot, the shell fragment contacts with the fixed block.

Through adopting above-mentioned technical scheme, when contacting the removal to support feeler lever to L shaped plate and reactor, press the fixed block and get into the fixed slot, carry out spacingly to support feeler lever, carry out preliminary fixed to the reactor.

In summary, the present application includes at least one of the following beneficial effects:

1. this application, when the installation reactor, place the reactor on the loading board, make the stopper slip through removing the slide bar, utilize spacing subassembly to carry out spacingly to the slide bar when stopper and reactor contact, realize the quick installation to the reactor, improve installation effectiveness.

2. The utility model discloses a through removing to touching the pole for L shaped plate contacts with the reactor, carries out preliminary spacing fixedly to the reactor position, is convenient for install the reactor, reduces the reactor and receives the condition emergence that the collision produced the skew in the installation, promotes the convenience of use.

Drawings

FIG. 1 is a schematic perspective view of a base plate according to the present utility model;

FIG. 2 is a schematic perspective view of the mounting mechanism of the present utility model;

FIG. 3 is an enlarged schematic view of the utility model at A in FIG. 1;

FIG. 4 is a cross-sectional view of a securing assembly of the present utility model;

fig. 5 is a schematic perspective view of a limiting assembly according to the present utility model.

Reference numerals illustrate:

1. a bottom plate; 2. a protective frame; 3. a carrying plate; 4. a mounting hole; 5. a guide block; 6. a mounting mechanism; 61. a limiting block; 62. a special-shaped groove; 63. a cross bar; 64. a drive assembly; 65. a limit component; 641. a push rod; 642. a bearing block; 643. a guide post; 644. a sliding block; 645. a chute; 646. a slide bar; 651. an annular block; 652. a rotating block; 66. an anti-slip pad; 7. a damper; 71. a rubber damping block; 72. a spring; 73. a collision block; 74. a telescopic rod; 81. a touch-up rod; 82. an L-shaped plate; 83. a fixing assembly; 831. a fixed block; 832. a fixing groove; 833. and the elastic sheet.

Detailed Description

The present application is described in further detail below in conjunction with figures 1-5.

The embodiment of the application discloses a reactor shock attenuation mounting bracket.

Referring to fig. 1 and 2, a reactor shock attenuation mounting bracket, including bottom plate 1, bottom plate 1 side is fixed with protection frame 2, loading board 3 is installed to bottom plate 1 upper end, a plurality of mounting hole 4 that is rectangular array and arranges has been seted up to loading board 3 upper end, the mounting hole 4 inner wall is fixed with two guide blocks 5 that are symmetrical arrangement, loading board 3 lower extreme is provided with installation mechanism 6, installation mechanism 6 includes the stopper 61 of sliding connection in guide block 5 side, special-shaped groove 62 has been seted up to stopper 61 side, special-shaped groove 62's shape is the line segment that one section is parallel with stopper 61 length direction, the line segment tip has the slope of one section outside slope, special-shaped groove 62's width is greater than the diameter of guide block 5 and is convenient for guide block 5 to slide in special-shaped groove 62, be sliding connection between special-shaped groove 62 and the guide block 5, stopper 61 lower extreme articulates has horizontal pole 63, horizontal pole 63 side is provided with drive assembly 64. When the reactor needs to be installed, the reactor is placed on the bearing plate 3, the positioning hole on the bearing plate 3 is aligned with the installation hole 4 hole on the reactor, the sliding rod 646 is moved outwards, the sliding block 644 is moved, the push rod 641 is limited by the guide post 643 to move downwards, the cross rod 63 is further moved downwards, the limiting block 61 is limited by the special-shaped groove 62 to rotate, when the reactor is rotated to be in contact with the reactor, the reactor is quickly installed, the annular block 651 is extruded through rotating the rotating block 652, the annular block 651 is internally tightened to abut against the sliding rod 646, limiting of the sliding rod 646 is achieved, and when the reactor is installed, the reactor can be quickly installed through moving the sliding rod 646 and screwing the rotating block 652.

Referring to fig. 1 and 2, the driving assembly 64 includes a push rod 641 fixed at the lower end of the cross rod 63, a bearing block 642 is fixed at the end of the push rod 641, a guide post 643 is fixed at the side of the bearing block 642, a guide post 643 is fixed at the end of the push rod 641, a sliding block 644 is slidably connected at the side of the guide post 643, a chute 645 is provided at the side of the sliding block 644, the inclined direction of the chute 645 extends from the lower part of the sliding block 644 near one end of the sliding rod 646 to the upper part of the other end of the sliding block 644, sliding connection is provided between the chute 645 and the guide post 643, the sliding rod 646 is fixed at the side of the sliding block 644, sliding connection is provided between the sliding rod 646 and the bearing plate 3, and the limiting assembly 65 is provided at the side of the bearing plate 3. When the reactor needs to be mounted by using the driving assembly 64, the sliding rod 646 is moved inwards, so that the sliding block 644 moves inwards, the guide post 643 is limited by the chute 645 to slide in the chute 645, the guide post 643 moves from one end of the chute 645 away from the sliding rod 646 to the other end, so that the push rod 641 is driven to move downwards, the cross rod 63 is driven to move downwards, the limiting block 61 is limited by the special-shaped groove 62 to rotate, and when the limiting block rotates to be in contact with the reactor, the rapid mounting of the reactor is realized.

Referring to fig. 1, 3 and 5, the limiting assembly 65 includes an annular block 651 fixed on a side surface of the bearing plate 3, a rotating block 652 is slidably sleeved outside the sliding rod 646, the rotating block 652 is in threaded connection with the annular block 651, and a damper 7 is arranged at the lower end of the bearing plate 3. When the slide lever 646 is moved to a proper position, the rotating block 652 is rotated to be in contact with the annular block 651, the annular block 651 is pressed by the rotating block 652 to be in contact with the slide lever 646, and the position of the slide lever 646 is limited, so that the position of the limiting block 61 is limited.

Referring to fig. 2, an anti-slip pad 66 is fixed to an end of the stopper 61, and the anti-slip pad 66 is in a strip shape. When the limiting block 61 contacts with the reactor, the anti-slip pad 66 contacts with the reactor, so that the friction force between the limiting block 61 and the reactor is increased, and the limiting block 61 and the reactor are tightly attached.

Referring to fig. 1, the damper 7 includes a plurality of rubber damping blocks 71 fixed at the upper end of the base plate 1 and arranged in a rectangular array, a spring 72 is fixed at the upper end of the rubber damping blocks 71, a supporting block 73 is fixed at the end of the spring 72, a telescopic rod 74 is fixed at the lower end of the supporting block 73, the telescopic rod 74 is fixedly connected with the rubber damping blocks 71, and the supporting block 73 is in threaded connection with the bearing plate 3. In the working process of the reactor, the reactor can generate vibration, the vibration amplitude generated by the vibration of the reactor is transmitted to the spring 72, the abutting block 73 moves downwards, the telescopic rod 74 is contracted, the spring 72 is extruded and transmits the vibration to the rubber damping block 71, the rubber damping block 71 can reduce the vibration amplitude to reduce the rebound amplitude of the spring 72, and the damper 7 has a damping effect on the reactor. In addition, it should be noted that a damper is provided between the telescopic rods, so that the damper can play a role in damping.

Referring to fig. 1, two sides of the protection frame 2 are slidably connected with two abutting rods 81, the number of the abutting rods 81 is two and the abutting rods are symmetrically distributed, one end, away from the L-shaped plate 82, of each abutting rod 81 is fixed with the L-shaped plate 82, and the end portion of each abutting rod 81 is provided with a fixing assembly 83. When the reactor is installed, the reactor is placed on the bearing plate 3, the contact rod 81 is moved to enable the reactor to move inwards, the L-shaped plate 82 is driven to move inwards, when the reactor contacts with the L-shaped plate 82, the contact rod 81 is limited and fixed by the fixing component 83, the reactor is initially limited and fixed, and the situation that the impact position of the reactor is offset to influence the installation in the installation process is reduced.

Referring to fig. 4, the fixing assembly 83 includes a fixing block 831 fixed on a side surface of the contact rod 81, a fixing groove 832 is formed on a side surface of the protection frame 2, a spring piece 833 is fixed in the fixing groove 832, and the spring piece 833 contacts with the fixing block 831. When removing L shaped plate 82 to its and reactor contact, conflict pole 81 removes to the protection frame 2 side, presses the fixed plate and makes fixed block 831 get into fixed slot 832 in, and shell fragment 833 is inconsistent with fixed block 831, carries out spacing fixed to the position of touching pole 81, is convenient for install the reactor.

Working principle: when the reactor needs to be mounted on the mounting bracket, the sliding rod 646 is moved outwards to enable the sliding block 644 to move, so that the guide post 643 slides in the chute 645, the push rod 641 is limited by the guide post 643 to move upwards, so that the cross rod 63 moves upwards, the limiting block 61 is limited by the special-shaped groove 62 to rotate, the two limiting blocks 61 are mutually close, the rotating block 652 is used for enabling the annular block 651 to abut against the sliding rod 646 to limit the sliding rod 646, the limiting block 61 is limited, the reactor is placed above the bearing plate 3, the positioning hole on the reactor is aligned with the mounting hole 4 on the bearing plate 3, the contact rod 81 is moved to enable the L-shaped plate 82 to be in contact with the reactor, the fixing block 831 is pressed to enable the fixing block 831 to enter the fixing groove 832, the elastic sheet 833 abuts against the fixing block 831 to limit the contact rod 81, the reactor position is limited by the L-shaped plate 82 to facilitate mounting, the sliding rod 652 is moved inwards to enable the sliding block 644 to abut against the sliding rod 646, the limiting block 646 is limited by the sliding block 646 to move downwards, the guide post 643 is driven to move downwards, and the limiting block 641 is driven to move downwards to rotate downwards, and the cross rod 63 is driven to rotate downwards to rotate quickly when the reactor is mounted to the reactor 61 to rotate downwards.

Claims (7)

1. The utility model provides a reactor shock attenuation mounting bracket, includes bottom plate (1), bottom plate (1) side is fixed with protection frame (2), loading board (3), its characterized in that are installed to bottom plate (1) upper end: the utility model discloses a bearing plate, including loading board (3), bearing plate (3), locating plate (61), special-shaped groove (62) have been seted up to loading board (3) upper end, a plurality of is mounting hole (4) that rectangular array was arranged, mounting hole (4) inner wall is fixed with two guide blocks (5) that are symmetrical arrangement, loading board (3) lower extreme is provided with installation mechanism (6), installation mechanism (6) are including stopper (61) of sliding connection in guide block (5) side, special-shaped groove (62) have been seted up to stopper (61) side, be sliding connection between special-shaped groove (62) and guide block (5), stopper (61) lower extreme articulates there is horizontal pole (63), horizontal pole (63) side is provided with drive assembly (64), loading board (3) side is provided with spacing subassembly (65).

2. The reactor vibration mount as claimed in claim 1, wherein: the driving assembly (64) comprises a push rod (641) fixed at the lower end of the cross rod (63), a bearing block (642) is fixed at the end part of the push rod (641), a guide post (643) is fixed on the side face of the bearing block (642), a sliding block (644) is slidably connected on the side face of the guide post (643), a chute (645) is arranged on the side face of the sliding block (644), the chute (645) is slidably connected with the guide post (643), a sliding rod (646) is fixed on the side face of the sliding block (644), and the sliding rod (646) is slidably connected with the bearing plate (3).

3. The reactor vibration mount as claimed in claim 2, wherein: the limiting assembly (65) comprises an annular block (651) fixed on the side face of the bearing plate (3), a rotating block (652) is sleeved outside the sliding rod (646) in a sliding mode, the rotating block (652) is in threaded connection with the annular block (651), and a damper (7) is arranged at the lower end of the bearing plate (3).

4. A reactor vibration mount according to claim 3, wherein: an anti-slip pad (66) is fixed at the end part of the limiting block (61), and the anti-slip pad (66) is strip-shaped.

5. A reactor vibration mount according to claim 3, wherein: the damper (7) comprises a plurality of rubber damping blocks (71) which are fixed at the upper end of a bottom plate (1) and are arranged in a rectangular array, springs (72) are fixedly arranged at the upper ends of the rubber damping blocks (71), abutting blocks (73) are fixedly arranged at the ends of the springs (72), telescopic rods (74) are fixedly arranged at the lower ends of the abutting blocks (73), the telescopic rods (74) are fixedly connected with the rubber damping blocks (71), and threaded connection is arranged between the abutting blocks (73) and a bearing plate (3).

6. The reactor vibration mount as claimed in claim 1, wherein: the protection frame (2) both sides all sliding connection have conflict pole (81), conflict pole (81) quantity is two and be symmetrical arrangement, conflict pole (81) end fixing has L shaped plate (82), the one end that L shaped plate (82) was kept away from to conflict pole (81) is provided with fixed subassembly (83).

7. The reactor vibration mount as set forth in claim 6, wherein: the fixing assembly (83) comprises a fixing block (831) fixed on the side face of the contact supporting rod (81), a fixing groove (832) is formed in the side face of the protection frame (2), an elastic sheet (833) is fixed in the fixing groove (832), and the elastic sheet (833) is in contact with the fixing block (831).

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