CN219367318U - Multidirectional adjustable equipment base - Google Patents

Abstract

The utility model discloses a multidirectional adjustable equipment base which comprises anchor rods, steel plates, I-steel installation components I and I-steel I, wherein a plurality of steel plates are sequentially arranged in parallel at intervals, at least two anchor rods are respectively arranged at the bottom of each steel plate at intervals, and the steel plates are connected with a structural layer through the anchor rods; the first I-steel stretches over the steel plate, two I-steel installation assemblies are arranged at least in parallel along the length direction of the first I-steel, the lower parts of the first I-steel are respectively connected with the corresponding steel plate through the first I-steel installation assemblies, the first I-steel installation assemblies comprise first sliding parts and first rotating parts, the first sliding parts are connected with the steel plate, the first rotating parts are connected with the first I-steel, and the first sliding parts are spliced with the first rotating parts and limited through limiting parts. The base can adapt to equipment bases with different angles, and breaks through the constraint of horizontal and vertical directions. The construction period is saved, the equipment base can be directly installed without communicating and coordinating with equipment manufacturers for a plurality of times.

Description

Multidirectional adjustable equipment base

Technical Field

The utility model relates to a device placement base, in particular to a multidirectional adjustable device base.

Background

In the construction of a transformer substation, the construction quality of the construction and installation of electrical equipment is directly related to the stable operation of the transformer substation, and is one of the most important equipment of the transformer substation. At present, in actual design construction, some problems are often encountered, such as various equipment manufacturers, different types of equipment produced by the equipment manufacturers, and no unified standard exists; many equipment in the transformer substation adopts I-steel base, and this equipment base design size can't correspond with all kinds of producer's data, and if the scene has been under construction and has been done the adjustment very hard, will lead to the construction suspension, consequently need wait the producer drawing just can carry out equipment base design, have certain influence to construction period, construction quality is difficult to guarantee, the producer equipment size is adjusted the back and is not in time communicated, lead to the construction to need the problem of reworking to take place occasionally, carry out design manufacturing to equipment base a lot of simultaneously, the cost is increased yet.

Disclosure of Invention

The utility model aims to: in view of the above problems, an object of the present utility model is to provide a multi-directional adjustable equipment base, which solves the problem that the conventional equipment base is limited by equipment specifications, and can shorten the construction period.

The technical scheme is as follows: the multidirectional adjustable equipment base comprises anchor rods, steel plates, I-steel installation components I and I-steel I, wherein a plurality of steel plates are sequentially arranged at intervals in parallel, at least two anchor rods are respectively arranged at the bottom of each steel plate at intervals, and the steel plates are connected with a structural layer through the anchor rods; the first I-steel stretches over the steel plate, two I-steel installation assemblies are arranged at least in parallel along the length direction of the first I-steel, the lower parts of the first I-steel are respectively connected with the corresponding steel plate through the first I-steel installation assemblies, the first I-steel installation assemblies comprise first sliding parts and first rotating parts, the first sliding parts are connected with the steel plate, the first rotating parts are connected with the first I-steel, and the first sliding parts are spliced with the first rotating parts and limited through limiting parts.

Further, the first sliding piece comprises a solid cylinder, a first sliding block and a first bolt, the solid cylinder is vertically arranged, the bottom surface of the solid cylinder is fixed with the first sliding block, the middle part of the cross section of the first sliding block is a T-shaped notch, the first sliding block is matched with the steel plate to enable the upper part of the steel plate to be arranged in the T-shaped notch of the first sliding block, and when the first sliding piece slides to a set position on the steel plate, the first sliding block is fastened with the steel plate through the first bolt.

Optimally, the first rotating piece comprises a cylinder, a second sliding block and a second bolt, the cylinder is vertically arranged, the top of the cylinder is fixed with the second sliding block, the middle part of the section of the second sliding block is an inverted T-shaped notch, the second sliding block is matched with the first I-shaped steel to enable the lower part of the first I-shaped steel to be arranged in the inverted T-shaped notch of the second sliding block, the second sliding block is fastened with the first I-shaped steel through the second bolt, and a solid cylinder is inserted into the second sliding block from the bottom of the cylinder, so that the first rotating piece can rotate on the first sliding piece.

Optimally, the limiting piece comprises a limiting column, a limiting groove is formed in the outer peripheral surface of the bottom of the cylinder, when the first rotating piece rotates to a designated position, the limiting column is inserted into the limiting groove, and the limiting column is connected with the outer peripheral surface of the solid cylinder, so that the first rotating piece is limited on the first sliding piece.

Furthermore, the base also comprises a second I-steel and a second I-steel installation assembly, wherein at least one second I-steel is arranged and spans over the adjacent first I-steel, and the lower part of the second I-steel is respectively connected with the upper part of the corresponding first I-steel through the second I-steel installation assembly.

Optimally, the second I-steel installation component has the same structure as the first I-steel installation component.

The beneficial effects are that: compared with the prior art, the utility model has the advantages that:

1. the device can adapt to the device bases with different angles, and breaks the constraint of horizontal and vertical directions.

2. The base can be adjusted, and the base construction is facilitated.

3. The I-steel installation component I can be prefabricated for production, and is convenient for construction.

4. The construction period is saved, the equipment base can be directly installed without communicating and coordinating with equipment manufacturers for a plurality of times.

5. The base is convenient to position, and the size deviation of the base caused by the construction quality problem is prevented.

6. The base has good integrity and can reduce uneven sedimentation.

Drawings

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is a schematic view of a side of a limiting member according to the present utility model;

FIG. 3 is a schematic top view of the present utility model;

FIG. 4 is a schematic perspective view of the present utility model;

fig. 5 is a schematic structural view of a first i-steel mounting assembly.

Detailed Description

The utility model will be further elucidated with reference to the drawings and to specific embodiments, it being understood that these embodiments are only intended to illustrate the utility model and are not intended to limit the scope thereof.

The multidirectional adjustable equipment base comprises an anchor rod 1, a steel plate 2, a I-steel mounting assembly I, a I-steel I5 and a limiting piece as shown in figures 1-5.

The steel plates 2 are sequentially arranged at intervals in parallel, at least two anchor rods 1 are respectively arranged at the bottom of each steel plate 2 at intervals, and the steel plates 2 are connected with the structural layer through the anchor rods 1 to play a role in fixation. The first I-steel 5 stretches across the upper portion of the steel plate 2, two I-steel mounting assemblies are arranged at least in parallel along the length direction of the first I-steel, the lower portions of the first I-steel 5 are respectively connected with the corresponding steel plate 2 through the first I-steel mounting assemblies, the first I-steel mounting assemblies comprise first sliding parts 3 and first rotating parts 4, the first sliding parts 3 are connected with the steel plate 2, the first rotating parts 4 are connected with the first I-steel 5, and the first sliding parts 3 are spliced with the first rotating parts 4 and are limited through limiting parts.

The first sliding piece 3 comprises a solid cylinder 31, a first sliding block 32 and a first bolt, wherein the solid cylinder 31 is vertically arranged, the bottom surface of the solid cylinder is fixed with the first sliding block 32, the middle part of the cross section of the first sliding block 32 is a T-shaped notch, and the first sliding block 32 is matched with the steel plate 2 so that the upper part of the steel plate 2 is arranged in the T-shaped notch of the first sliding block 32; the first rotating member 4 comprises a cylinder 41, a second slider 42 and a second bolt, the cylinder 41 is vertically arranged, the top of the cylinder 41 is fixed with the second slider 42, the middle of the cross section of the second slider 42 is an inverted T-shaped notch, the second slider 42 is matched with the first I-steel 5 to enable the lower portion of the first I-steel 5 to be placed in the inverted T-shaped notch of the second slider 42, and the solid cylinder 31 is inserted into the inverted T-shaped notch from the bottom of the cylinder 41 to enable the first rotating member 4 to rotate on the first sliding member 3.

The limiting member comprises a limiting post 61, and a limiting groove 62 is formed in the outer peripheral surface of the bottom of the cylinder 41.

In the mounting, first, the first slider 3 is mounted on the steel plate 2, the first slider 32 is moved vertically on the steel plate 2, and after reaching a desired specified position, the first bolt is screwed, and the first slider 32 is fastened to the steel plate 2 by the first bolt. Then, the first rotating member 4 is placed on the first sliding member 3, and when the first rotating member 4 is rotated to a specified position, the stopper post 61 is inserted into the stopper groove 62, and the stopper post 61 is connected to the outer peripheral surface of the solid cylinder 31, so that the first rotating member 4 is stopped on the first sliding member 3 to fix the rotated angle. The limiting post 61 may be welded with the solid cylinder 31, or a circle of threaded holes may be formed in the periphery of the solid cylinder 31, so that the limiting post 61 is in threaded connection with the solid cylinder 31. And finally, placing the I-steel I5 on the first rotating piece 4, and fastening the slider II 42 with the I-steel I5 through a second bolt. In addition, the first bolt and the second bolt adopt the form of bolt pressurizing sheets, and when the bolts are moved to the design position, the bolts can be tightened, and the friction force is enhanced by utilizing pressure so as to realize the purpose of fixing the sliding block. The first sliding part 3 and the steel plate 2 as well as the first rotating part 4 and the I-steel one 5 can be connected by adopting a threaded connection mode, and can also adopt a welding mode.

In addition to the steel plate, the combination of the first slider 3 and the first rotator 4 may also be placed on the i-steel. The device also comprises a second I-steel 7 and a second I-steel installation component 8. The I-steel II 7 is at least provided with one and spans the upper parts of the adjacent I-steel I5, and the lower parts of the I-steel II 7 are respectively connected with the upper parts of the corresponding I-steel I5 through two I-steel mounting assemblies II 8. The second I-steel installation component 8 has the same structure as the first I-steel installation component.

When the I-steel installation component II 8 is placed on the I-steel I5, unidirectional movement can be realized, and when the I-steel I5 is placed on the I-steel I, the I-steel II 7 is placed on the I-steel I, so that multidirectional movement can be realized.

Claims (6)

1. A multidirectional adjustable device base, characterized in that: the steel plate (2) is sequentially arranged at intervals in parallel, at least two anchor rods (1) are respectively arranged at the bottom of each steel plate (2) at intervals, and the steel plates (2) are connected with a structural layer through the anchor rods (1); the first I-steel (5) stretches across the upper portion of the steel plate (2) and is provided with two I-steel mounting assemblies (3) and first rotating members (4) respectively, the first rotating members (4) are connected with the first I-steel (5), and the first sliding members (3) are spliced with the first rotating members (4) and limited by limiting members.

2. A multi-directional adjustable device base as defined in claim 1, wherein: the first sliding part (3) comprises a solid cylinder (31), a first sliding block (32) and a first bolt, wherein the solid cylinder (31) is vertically arranged, the bottom surface of the solid cylinder is fixed with the first sliding block (32), the middle part of the cross section of the first sliding block (32) is a T-shaped notch, the first sliding block (32) is matched with the steel plate (2) to enable the upper part of the steel plate (2) to be arranged in the T-shaped notch of the first sliding block (32), and when the first sliding part (3) slides to a set position on the steel plate (2), the first sliding block (32) is fastened with the steel plate (2) through the first bolt.

3. A multi-directional adjustable device base as defined in claim 2, wherein: the first rotating piece (4) comprises a cylinder (41), a second sliding block (42) and a second bolt, the cylinder (41) is vertically arranged, the top of the cylinder is fixed with the second sliding block (42), the middle of the cross section of the second sliding block (42) is an inverted T-shaped notch, the second sliding block (42) is matched with the first I-steel (5) to enable the lower portion of the first I-steel (5) to be placed in the inverted T-shaped notch of the second sliding block (42), the second sliding block (42) is fastened with the first I-steel (5) through the second bolt, and the solid cylinder (31) is inserted into the second sliding block from the bottom of the cylinder (41), so that the first rotating piece (4) can rotate on the first sliding piece (3).

4. A multi-directional adjustable device base as defined in claim 3, wherein: the limiting piece comprises a limiting column (61), a limiting groove (62) is formed in the outer peripheral surface of the bottom of the cylinder (41), when the first rotating piece (4) rotates to a designated position, the limiting column (61) is inserted into the limiting groove (62), the limiting column (61) is connected with the outer peripheral surface of the solid cylinder (31), and the first rotating piece (4) is limited on the first sliding piece (3).

5. A multi-directional adjustable device base as defined in claim 1, wherein: the novel steel structure is characterized by further comprising a second I-steel (7) and a second I-steel mounting assembly (8), wherein at least one second I-steel (7) is arranged and spans over the adjacent first I-steels (5), and the lower parts of the second I-steels (7) are respectively connected with the upper parts of the corresponding first I-steels (5) through the second I-steel mounting assemblies (8).

6. A multi-directional adjustable device base as defined in claim 1, wherein: the second I-steel installation component (8) has the same structure as the first I-steel installation component.