CN220551624U - Anti-slip stainless steel flange - Google Patents

Abstract

The utility model discloses an anti-skid stainless steel flange, which comprises a flange, two pipelines are symmetrically arranged at two ends of the flange, a connecting block is arranged at one side of the pipeline, a device groove is formed in the connecting block, a sliding plate is arranged in the device groove in a sliding mode, a clamping block is arranged at one end of the sliding plate, a driving motor is arranged on the inner wall of the device groove, a connecting rod is arranged at the top end of the driving motor, a rotating gear is arranged at the top end of the connecting rod, the connecting rod is driven to rotate by the driving motor in the device groove, so that the rotating gear is driven to rotate, the rotating gear rotates on the sliding plate and drives the clamping block arranged on the sliding plate to approach the flange, the purpose of clamping the flange is achieved, and the rotating block, a sleeve rod and a stretching rod sleeved in the sleeve rod are arranged in the C-shaped mounting block to move together.

Description

Anti-slip stainless steel flange

Technical Field

The utility model relates to the technical field of stainless steel flanges, in particular to an anti-slip stainless steel flange.

Background

Stainless steel flanges have mechanical design strength and relatively high stretchability, and have the properties of a very good stainless steel material. Stainless steel flanges are commonly used for the connection of pipes and valves, and are widely used in many industries due to their excellent properties.

The prior patent number: CN218348121U discloses an anti-slip stainless steel flange, which comprises a flange body and a pipeline, wherein the two side surfaces of the flange body are fixedly provided with the pipeline through bolts, the flange body pre-limits the position of the pipeline through an adjusting structure, and the adjusting structure comprises four groups of storage grooves formed on the peripheral surfaces of the outer walls of the two sides of the flange body, a rotating shaft arranged on the inner wall surfaces of the storage grooves, sliding grooves formed on the two side surfaces of the inner wall of a rotating piece, sliding rods arranged on the inner side surfaces of the sliding blocks and mounting seats rotatably arranged on the inner side surfaces of the two groups of sliding rods; through setting up regulation structure, anchor clamps and revolution mechanic etc, effectively avoided the flange to take place to rotate along with the rotation of bolt easily, lead to the flange to take place the dislocation, other through-holes on the flange can't keep on same horizontal plane with other through-holes on the pipeline, lead to other unable normal running through of bolt, the problem that the flange can't install has improved the practicality of device.

However, this device has the following problems: the structure is complex and the operation is not easy.

There is a need for a slip resistant stainless steel flange to meet the needs of people.

Disclosure of Invention

The utility model aims to provide an anti-slip stainless steel flange, which solves the problems of complex structure and difficult operation in the prior art.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides an antiskid formula stainless steel flange, includes the flange, two pipelines are installed to the both ends symmetry of flange, the connecting block is installed to one side of pipeline, has seted up the device groove in the connecting block, slidable mounting has the sliding plate in the device groove, the joint piece is installed to the one end of sliding plate, install driving motor on the device inslot wall, install the connecting rod on the driving motor, install the rotation gear on the connecting rod, the rotation gear meshes with the sliding plate, install the fixed block on the flange, install C shape installation piece on the fixed block top, install two mutually symmetrical rotation pieces on the C shape installation piece, the loop bar is installed to the one end of rotation piece, the one end slidable mounting of loop bar has the stretching rod, the connecting piece has been arranged to the one end of stretching rod, install the clamp splice on the connecting piece, be connected with extension spring between rotation piece and the connecting piece.

Preferably, the pipeline is provided with a limit groove.

Preferably, the sliding grooves are formed in two sides of the sliding plate, the sliding blocks are arranged in the sliding grooves in a sliding mode, and the sliding blocks are arranged on the inner walls of the device grooves.

Preferably, a sliding groove is formed in the loop bar, and the stretching bar slides in the sliding groove.

Preferably, a plurality of tooth grooves are arranged on the sliding plate, and the tooth grooves are matched with the rotating gears.

Preferably, rubber anti-slip layers are uniformly distributed on the two clamping blocks.

Preferably, anti-slip coatings are arranged on the outer surfaces of the two clamping blocks, and a plurality of anti-slip grooves are formed in the anti-slip coatings.

The beneficial effects of the utility model are as follows: the connecting rod is driven to rotate through the driving motor in the device groove, so that the rotating gear is driven to rotate, the rotating gear rotates on the sliding plate and then drives the clamping block mounted on the sliding plate to approach the flange, the purpose of clamping the flange is achieved, the rotating block mounted in the C-shaped mounting block, the loop bar and the stretching rod sleeved in the loop bar move together through the supporting function of the fixing block and the C-shaped mounting block on the flange, the connecting rod is connected with the clamping block, and the clamping block is clamped on the surface of a pipeline through the action of the stretching spring.

Drawings

FIG. 1 is a schematic structural view of an anti-slip stainless steel flange according to the present utility model;

FIG. 2 is a schematic cross-sectional view of the structure of a fixed block and a rotating block of an anti-slip stainless steel flange according to the present utility model;

FIG. 3 is a schematic cross-sectional view of a sliding groove and a sliding block of an anti-slip stainless steel flange according to the present utility model;

fig. 4 is a schematic cross-sectional view of a rotating gear and a sliding plate of an anti-slip stainless steel flange according to the present utility model.

Fig. 5 is an enlarged schematic view of the structure of fig. 3A of an anti-slip stainless steel flange according to the present utility model.

In the figure: 1. a flange; 2. a pipe; 3. a sliding plate; 4. a connecting block; 5. a slide block; 6. a C-shaped mounting block; 7. a limit groove; 8. clamping blocks; 9. a connecting piece; 10. a stretching rod; 11. a loop bar; 12. a sliding groove; 13. a rotating block; 14. a tension spring; 15. a fixed block; 16. a device slot; 17. a driving motor; 18. a connecting rod; 19. rotating the gear; 20. a clamping block; 21. and a sliding groove.

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.

Referring to fig. 1-5, an anti-slip stainless steel flange comprises a flange 1, two pipelines 2 are symmetrically arranged at two ends of the flange 1, a connecting block 4 is arranged at one side of each pipeline 2, a device groove 16 is formed in each connecting block 4, a sliding plate 3 is arranged in each sliding plate in each device groove 16, a clamping block 20 is arranged at one end of each sliding plate 3, a driving motor 17 is arranged on the inner wall of each device groove 16, a connecting rod 18 is arranged on each driving motor 17, a rotating gear 19 is arranged on each connecting rod 18, the rotating gears 19 are meshed with each sliding plate 3, a fixing block 15 is arranged on each flange 1, a C-shaped mounting block 6 is arranged at the top end of each fixing block 15, two mutually symmetrical rotating blocks 13 are arranged on each C-shaped mounting block 6, a loop bar 11 is arranged at one end of each rotating block 13, a stretching rod 10 is arranged at one end of each loop bar 11, a clamping block 8 is arranged on each connecting piece 9, and a spring 14 is connected between each rotating block 13 and each connecting piece 9.

The connecting rod 18 is driven to rotate through the driving motor 17 in the device groove 16, thereby driving the rotating gear 19 to rotate, the rotating gear 19 rotates on the sliding plate 3 and then drives the clamping block 20 arranged on the sliding plate 3 to approach the flange 1, the purpose of clamping the flange 1 is achieved, the rotating block 13 arranged in the C-shaped mounting block 6, the loop bar 11 and the stretching rod 10 sleeved in the loop bar 11 move together through the supporting function of the fixed block 15 and the C-shaped mounting block 6 on the flange 1, the connecting rod 18 is connected with the clamping block 8, and the clamping block 8 is clamped on the surface of the pipeline 2 through the action of the stretching spring 14.

Specifically, in this embodiment, the pipe 2 is provided with a limiting groove 7.

The limit groove 7 is formed in the pipeline 2, so that the connection of the hose of the pipeline 2 with the flange 1 in the later stage is facilitated.

Specifically, in this embodiment, the sliding grooves 21 are formed on both sides of the sliding plate 3, the sliding blocks 5 are slidably mounted in the sliding grooves 21, and the sliding blocks 5 are mounted on the inner wall of the device groove 16.

Through seting up spout 21 in slide plate 3 both sides, slider 5 slidable mounting is in spout 21, and slider 5 installs on the device groove 16 inner wall, and spout 21 carries out spacing direction effect to slide plate 3.

Specifically, in this embodiment, the sleeve rod 11 is provided with a sliding groove 12, and the stretching rod 10 slides in the sliding groove 12.

By arranging the sliding groove 12 in the sleeve rod 11, the stretching rod 10 slides in the sliding groove 12, and when the clamping block 20 is clamped, the stretching rod 10 can stretch and retract in the sliding groove 12, so that the aim that the clamping block 8 clamps the flange 1 is fulfilled.

Specifically, in this embodiment, a plurality of tooth grooves are disposed on the sliding plate 3, and the tooth grooves are adapted to the rotating gears 19.

Through arranging a plurality of tooth grooves on the sliding plate 3, the tooth grooves are matched with the rotating gear 19, the effect that the rotating gear 19 rotates along the sliding plate 3 is achieved, and the tooth grooves on the sliding plate 3 play a guiding role.

Specifically, in this embodiment, the two clamping blocks 20 are each provided with a rubber anti-slip layer.

By arranging the rubber anti-slip layers on the two clamping blocks 20, when the clamping blocks 20 are clamped with the surface of the pipeline 2, the rubber sealing strips deform, so that the anti-slip effect of the flange 1 is achieved.

Specifically, in this embodiment, the outer surfaces of the two clamping blocks 8 are both provided with an anti-slip coating, and a plurality of anti-slip grooves are formed in the anti-slip coating.

Through arranging anti-skidding coating at the surface of two clamp splice 8, a plurality of anti-skidding grooves have been seted up to anti-skidding coating, reach clamp splice 8 and hug closely the effect of pipeline 2, and then play the purpose of clamping flange 1.

The present utility model is not limited to the above-mentioned embodiments, and any person skilled in the art, based on the technical solution of the present utility model and the inventive concept thereof, can be replaced or changed within the scope of the present utility model.

Claims (7)

1. The utility model provides an antiskid formula stainless steel flange, its characterized in that includes flange (1), two pipelines (2) are installed to the both ends symmetry of flange (1), connecting block (4) are installed to one side of pipeline (2), have seted up device groove (16) in connecting block (4), sliding fit has sliding plate (3) in device groove (16), joint piece (20) are installed to one end of sliding plate (3), install driving motor (17) on the inner wall of device groove (16), install connecting rod (18) on driving motor (17), install rotation gear (19) on connecting rod (18), rotation gear (19) meshes with sliding plate (3), install fixed block (15) on flange (1), install C shape installation piece (6) on the top of fixed block (15), install two mutually symmetrical rotating block (13) on C shape installation piece (6), sleeve rod (11) are installed to one end of sliding fit (10) on sleeve rod (11), install clamp piece (9) on one end of stretching piece (9), an extension spring (14) is connected between the rotating block (13) and the connecting piece (9).

2. The non-slip stainless steel flange according to claim 1, wherein: and a limiting groove (7) is formed in the pipeline (2).

3. The non-slip stainless steel flange according to claim 1, wherein: sliding grooves (21) are formed in two sides of the sliding plate (3), sliding blocks (5) are arranged in the sliding grooves (21) in a sliding mode, and the sliding blocks (5) are arranged on the inner walls of the device grooves (16).

4. The non-slip stainless steel flange according to claim 1, wherein: a sliding groove (12) is formed in the sleeve rod (11), and the stretching rod (10) slides in the sliding groove (12).

5. The non-slip stainless steel flange according to claim 1, wherein: a plurality of tooth grooves are arranged on the sliding plate (3), and the tooth grooves are matched with the rotating gears (19).

6. The non-slip stainless steel flange according to claim 1, wherein: rubber anti-slip layers are arranged on the two clamping blocks (20).

7. The non-slip stainless steel flange according to claim 1, wherein: the outer surfaces of the two clamping blocks (8) are respectively provided with an anti-slip coating, and a plurality of anti-slip grooves are formed in the anti-slip coatings.