CN220249263U - Heat-insulating fireproof pipeline - Google Patents

Abstract

The utility model relates to the technical field of fireproof pipelines, in particular to a heat-insulating fireproof pipeline which comprises a silicate board layer, a partition board layer and a butt joint assembly, wherein the butt joint assembly comprises two sliding rails, two convex blocks, a first guide rail, a second guide rail, a sliding block and a connecting belt, and a strip-shaped groove is formed in the bottom of the second guide rail. When two heat-insulating fireproof pipelines need to be abutted, two protruding blocks of the other heat-insulating fireproof pipeline are matched with two sliding rails on the existing heat-insulating fireproof pipeline in a sliding mode, then the connecting belt on the other heat-insulating fireproof pipeline is pulled, the sliding block slides, and the sliding block is located between the first guide rail of the existing heat-insulating fireproof pipeline and the second guide rail of the other heat-insulating fireproof pipeline, so that the two heat-insulating fireproof pipelines are prevented from being separated from an abutting state, abutting of the two heat-insulating fireproof pipelines is achieved, a plurality of heat-insulating fireproof pipelines can be simply and quickly abutted together, and the abutting efficiency of the device is improved.

Description

Heat-insulating fireproof pipeline

Technical Field

The utility model relates to the technical field of fireproof pipelines, in particular to a heat-insulating fireproof pipeline.

Background

The silicate board is a common fireproof material, also called silicate fireproof board, and has the characteristics of excellent heat insulation and fire resistance, and the like, and the existing heat-insulating fireproof pipeline uses the silicate board as the outer layer of the pipeline for protection, so that the heat-insulating fireproof pipeline has fireproof and heat-insulating effects.

At present, the length of the heat-insulating fireproof pipeline is limited, when the required pipeline length is too long, a plurality of heat-insulating fireproof pipelines are required to be butted together for use, but the existing heat-insulating fireproof pipeline is too complex to be butted together, so that a worker is inconvenient to butt joint two heat-insulating fireproof pipelines together, and the efficiency of the device in butt joint is reduced.

Disclosure of Invention

The utility model aims to provide an insulated fireproof pipeline, which solves the problems that the length of the existing insulated fireproof pipeline is limited, when the required pipeline is too long, a plurality of insulated fireproof pipelines are needed to be butted together for use, but the existing insulated fireproof pipeline is too complex in butt joint, and the two insulated fireproof pipelines are inconvenient for workers to butt joint together, so that the efficiency of the device in butt joint is reduced.

In order to achieve the above object, the utility model provides a heat-insulating fireproof pipeline, which comprises a silicate board layer, a baffle layer and a butt joint assembly, wherein the baffle layer is arranged in the silicate board layer, the butt joint assembly comprises two sliding rails, two convex blocks, a first guide rail, a second guide rail, a sliding block and a connecting belt, the bottom of the second guide rail is provided with a strip-shaped groove, the two sliding rails are respectively arranged on the right side surface of the silicate board layer, the two convex blocks are respectively arranged on the left side surface of the silicate board layer, the two sliding rails are in sliding fit with the corresponding convex blocks, the first guide rail is fixedly connected with the right lower end of the silicate board layer, the second guide rail is fixedly connected with the left lower end of the silicate board layer, the sliding block is arranged in the second guide rail, the sliding block is in sliding fit with the first guide rail and the second guide rail, and one end of the connecting belt penetrates through the strip-shaped groove and is fixedly connected with the right bottom of the sliding block.

The butt joint assembly further comprises a clamping block, a fixing block, a cylinder, a circular ring and a spring, wherein the fixing block is arranged on the left side of the first guide rail, a first groove and a second groove are formed in the fixing block, the first groove is communicated with the second groove, the first groove is located on the left side of the second groove, one end of the cylinder penetrates through the left side wall of the fixing block and is located inside the first groove and the second groove and is in sliding fit with the first groove, the circular ring is fixedly sleeved on the cylinder and is located in the first groove, two ends of the spring are respectively fixedly connected with the left inner wall of the first groove and the circular ring, and the clamping block is fixedly connected with the lower end of the connecting belt and is in sliding fit with the second groove.

The butt joint assembly further comprises a handle, wherein the handle is fixedly connected with the cylinder and is positioned on the left side of the cylinder.

The butt joint assembly further comprises limiting blocks, wherein the limiting blocks are fixedly connected with the two protruding blocks and are located above the two protruding blocks.

The heat-insulating fireproof pipeline further comprises a plurality of cross fixing rods and a plurality of annular rods, the cross fixing rods are sequentially arranged on the inner diameter of the silicate board layer, and the annular rods are sequentially arranged and sleeved on the outer diameter of the silicate board layer.

According to the heat-insulating fireproof pipeline, when two heat-insulating fireproof pipelines are required to be in butt joint, the two protruding blocks of the other heat-insulating fireproof pipeline are in sliding fit with the two sliding rails on the existing heat-insulating fireproof pipeline, and then the connecting belt on the other heat-insulating fireproof pipeline is pulled to enable the sliding blocks to slide and be located between the first guide rail of the existing heat-insulating fireproof pipeline and the second guide rail of the other heat-insulating fireproof pipeline, so that the two heat-insulating fireproof pipelines are prevented from being out of butt joint, the two heat-insulating fireproof pipelines are in butt joint, and through the structural arrangement, the heat-insulating fireproof pipelines can be simply and quickly in butt joint, and the butt joint efficiency of the device is improved.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below.

Fig. 1 is a schematic overall structure of a first embodiment of the present utility model.

Fig. 2 is an overall cross-sectional view of a first embodiment of the present utility model.

Fig. 3 is a cross-sectional view taken along line A-A of fig. 2 in accordance with the present utility model.

Fig. 4 is a sectional view taken along line B-B of fig. 2 in accordance with the present utility model.

Fig. 5 is an enlarged view of a partial structure at C of fig. 2 according to the present utility model.

Fig. 6 is a schematic overall structure of a second embodiment of the present utility model.

Fig. 7 is an overall cross-sectional view of a second embodiment of the present utility model.

Fig. 8 is a sectional view taken along line D-D of fig. 7 in accordance with the present utility model.

101-silicate board layer, 102-partition board layer, 103-slide rail, 104-bump, 105-first guide rail, 106-second guide rail, 107-slide block, 108-connecting band, 109-fixture block, 110-fixed block, 111-cylinder, 112-circular ring, 113-spring, 114-grip, 115-stopper, 116-bar slot, 117-first groove, 118-second groove, 201-cross fixed rod, 202-circular rod.

Detailed Description

The following detailed description of embodiments of the utility model, examples of which are illustrated in the accompanying drawings and, by way of example, are intended to be illustrative, and not to be construed as limiting, of the utility model.

First embodiment:

referring to fig. 1 to 5, wherein fig. 1 is an overall schematic structural view of a first embodiment of the present utility model, fig. 2 is an overall sectional view of the first embodiment of the present utility model, fig. 3 is a sectional view of fig. 2 A-A of the present utility model, fig. 4 is a sectional view of fig. 2B-B of the present utility model, and fig. 5 is a partial enlarged structural view of fig. 2C of the present utility model.

The utility model provides a heat-insulating fireproof pipeline which comprises a silicate board layer 101, a partition board layer 102 and a butt joint assembly, wherein the butt joint assembly comprises two sliding rails 103, two convex blocks 104, a first guide rail 105, a second guide rail 106, a sliding block 107, a connecting belt 108, a clamping block 109, a fixed block 110, a cylinder 111, a circular ring 112, a spring 113, a handle 114 and a limiting block 115, a strip-shaped groove 116 is formed in the bottom of the second guide rail 106, and a first groove 117 and a second groove 118 are formed in the fixed block 110.

For this embodiment, the two sliding rails 103 are slidably matched with the two protruding blocks 104 of the other heat-insulating fireproof pipeline, and the sliding block 107 of the other heat-insulating fireproof pipeline is slid into the first guide rail 105 of the existing heat-insulating fireproof pipeline, so that the sliding rails 103 are prevented from being separated from the protruding blocks 104, the two heat-insulating fireproof pipelines are abutted, then the clamping block 109 of the other heat-insulating fireproof pipeline is plugged into the second groove 118 of the existing heat-insulating fireproof pipeline, and is limited by the cylinder 111, so that the limit of the sliding block 107 is achieved, the sliding of the sliding block 107 is prevented, the abutting effect of the two heat-insulating fireproof pipelines is prevented from being influenced, the abutting of the two heat-insulating fireproof pipelines can be simply and rapidly realized, and the efficiency in installation is improved.

The spacer layer 102 is disposed in the silicate board layer 101, a strip-shaped groove 116 is formed in the bottom of the second guide rail 106, two sliding rails 103 are respectively disposed on the right side surface of the silicate board layer 101, two protruding blocks 104 are respectively disposed on the left side surface of the silicate board layer 101, two sliding rails 103 are correspondingly slidably fitted with the protruding blocks 104, the first guide rail 105 is fixedly connected with the right lower end of the silicate board layer 101, the second guide rail 106 is fixedly connected with the left lower end of the silicate board layer 101, a sliding block 107 is disposed in the second guide rail 106, the sliding block 107 is slidably fitted with the first guide rail 105 and the second guide rail 106, and one end of the connecting belt 108 penetrates through the strip-shaped groove 116 and is fixedly connected with the right bottom of the sliding block 107. The silicate board layer 101 is used for enabling the pipeline to play a role in fire prevention and heat insulation, when two heat-insulation fireproof pipelines are required to be in butt joint, the two lugs 104 of the other heat-insulation fireproof pipeline are in sliding fit with the two sliding rails 103 on the existing heat-insulation fireproof pipeline, then the connecting belt 108 on the other heat-insulation fireproof pipeline is pulled, the sliding block 107 is enabled to slide, and the connecting belt is located between the first guide rail 105 of the existing heat-insulation fireproof pipeline and the second guide rail 106 of the other heat-insulation fireproof pipeline, so that the two heat-insulation fireproof pipelines are prevented from being separated from the butt joint state, the butt joint of the two heat-insulation fireproof pipelines is achieved, and the heat-insulation fireproof pipelines can be simply and quickly in butt joint through the structure, so that the efficiency of the device in butt joint is improved.

Secondly, the fixing block 110 is disposed on the left side of the first guide rail 105, the fixing block 110 is provided with a first groove 117 and a second groove 118, the first groove 117 is communicated with the second groove 118, the first groove 117 is located on the left side of the second groove 118, one end of the cylinder 111 penetrates through the left side wall of the fixing block 110 and is located inside the first groove 117 and the second groove 118 and is slidably matched with the first groove 117, the circular ring 112 is fixedly sleeved on the cylinder 111 and is located inside the first groove 117, two ends of the spring 113 are fixedly connected with the left inner wall of the first groove 117 and the circular ring 112 respectively, and the clamping block 109 is fixedly connected with the lower end of the connecting belt 108 and is slidably matched with the second groove 118. When the slider 107 is located between the first guide rail 105 of the existing adiabatic fireproof pipeline and the second guide rail 106 of the other adiabatic fireproof pipeline, the clamping block 109 of the other adiabatic fireproof pipeline is plugged into the second groove 118 of the existing adiabatic fireproof pipeline, the cylinder 111 is pushed to the left by the extrusion of the inclined plane on the clamping block 109, and when the clamping block 109 passes through the cylinder 111, under the action of the spring 113, the cylinder 111 returns to the original position again and limits the clamping block 109, so that the connecting belt 108 and the slider 107 are limited, and the sliding of the slider 107 is prevented, thereby affecting the stability of the two adiabatic fireproof pipelines after being butted.

Meanwhile, the grip 114 is fixedly connected to the cylinder 111 and is positioned at the left side of the cylinder 111. When the limit effect needs to be canceled, the handle 114 is pulled to move the cylinder 111 to the left, so that the limit on the clamping block 109 is canceled, and the limit on the connecting belt 108 and the sliding block 107 is canceled.

In addition, the limiting block 115 is fixedly connected with the two protruding blocks 104 and is located above the two protruding blocks 104. By the limiting block 115, the protrusion 104 of the other heat-insulating fireproof pipeline and the sliding rail 103 of the existing heat-insulating fireproof pipeline are limited when in butt joint, so that excessive sliding is prevented, and the situation that the two heat-insulating fireproof pipelines are difficult to align by a worker is caused.

When the heat-insulating fireproof pipeline is used, the pipeline plays a role of fire prevention and heat insulation through the silicate board layer 101, when two heat-insulating fireproof pipelines are required to be butted, the two lugs 104 of the other heat-insulating fireproof pipeline are matched with the two sliding rails 103 on the existing heat-insulating fireproof pipeline in a sliding way, then the connecting belt 108 on the other heat-insulating fireproof pipeline is pulled to enable the sliding block 107 to slide and be positioned between the first guide rail 105 of the existing heat-insulating fireproof pipeline and the second guide rail 106 of the other heat-insulating fireproof pipeline, so that the two heat-insulating fireproof pipelines are prevented from being separated from the butted state, after the sliding block 107 is positioned between the first guide rail 105 of the existing heat-insulating fireproof pipeline and the second guide rail 106 of the other heat-insulating fireproof pipeline, the clamping block 109 of the other heat-insulating fireproof pipeline is plugged into the second groove 118 of the existing heat-insulating fireproof pipeline, pushing the cylinder 111 to the left by pressing the inclined surface on the clamping block 109, when the clamping block 109 passes through the cylinder 111, under the action of the spring 113, the cylinder 111 returns to the original position again and limits the clamping block 109, thereby limiting the connecting belt 108 and the sliding block 107, preventing the sliding block 107 from sliding, thereby affecting the stability of the two heat insulation fireproof pipelines after being butted, when the limiting effect needs to be canceled, the cylinder 111 moves to the left by pulling the handle 114, thereby canceling the limitation of the clamping block 109, further canceling the limitation of the connecting belt 108 and the sliding block 107, and limiting the bump 104 of the other heat insulation fireproof pipeline and the sliding rail 103 of the existing heat insulation fireproof pipeline by the limiting block 115, prevent to slip excessively, lead to the staff to be difficult to the condition of aligning two adiabatic fire prevention pipeline, through above-mentioned structure setting, realize the butt joint of two adiabatic fire prevention pipelines, can be simple swift dock a plurality of adiabatic fire prevention pipeline together to the efficiency when having improved the device butt joint.

Second embodiment:

on the basis of the first embodiment, please refer to fig. 6 to 8, wherein fig. 6 is a schematic overall structure diagram of the second embodiment of the present utility model, fig. 7 is an overall cross-sectional view of the second embodiment of the present utility model, and fig. 8 is a cross-sectional view of the D-D line of fig. 7 of the present utility model.

The utility model provides a heat-insulating fireproof pipeline, which also comprises a plurality of cross fixing rods 201 and a plurality of annular rods 202.

For the present embodiment, the supporting strength of the inside of the adiabatic fireproof pipe is enhanced by the plurality of cross fixing rods 201, and the supporting strength of the periphery of the adiabatic fireproof pipe is enhanced by the plurality of ring rods 202, thereby improving the overall strength of the adiabatic fireproof pipe, and thus being more durable.

The plurality of cross fixing rods 201 are sequentially arranged on the inner diameter of the silicate board layer 101, and the plurality of annular rods 202 are sequentially arranged and sleeved on the outer diameter of the silicate board layer 101. The supporting strength of the inside of the heat insulating fireproof pipe is enhanced by the plurality of cross fixing rods 201, and the supporting strength of the periphery of the heat insulating fireproof pipe is enhanced by the plurality of ring rods 202.

In using the insulating fire protection pipe of the present utility model, the supporting strength of the inside of the insulating fire protection pipe is enhanced by the plurality of cross fixing rods 201, and the supporting strength of the periphery of the insulating fire protection pipe is enhanced by the plurality of ring rods 202, thereby improving the overall strength of the insulating fire protection pipe, and thus being more durable.

The foregoing disclosure is only illustrative of one or more preferred embodiments of the present application and is not intended to limit the scope of the claims hereof, as it is to be understood by those skilled in the art that all or part of the process of implementing the described embodiment may be practiced otherwise than as specifically described and illustrated by the appended claims.

Claims (5)

1. A heat-insulating fireproof pipeline comprises a silicate board layer and a baffle layer, wherein the baffle layer is arranged inside the silicate board layer,

the device also comprises a butt joint assembly;

the butt joint assembly comprises two sliding rails, two convex blocks, a first guide rail, a second guide rail, a sliding block and a connecting belt, wherein a strip-shaped groove is formed in the bottom of the second guide rail, the two sliding rails are respectively arranged on the right side surface of the silicate board layer, the two convex blocks are respectively arranged on the left side surface of the silicate board layer, the two sliding rails are in sliding fit with the corresponding convex blocks, the first guide rail is fixedly connected with the right lower end of the silicate board layer, the second guide rail is fixedly connected with the left lower end of the silicate board layer, the sliding block is arranged in the second guide rail, the sliding block is in sliding fit with the first guide rail and the second guide rail, and one end of the connecting belt penetrates through the strip-shaped groove and is fixedly connected with the right bottom of the sliding block.

2. The insulated fire protection conduit according to claim 1,

the butt joint assembly further comprises a clamping block, a fixing block, a cylinder, a circular ring and a spring, wherein the fixing block is arranged on the left side of the first guide rail, a first groove and a second groove are formed in the fixing block, the first groove is communicated with the second groove, the first groove is located on the left side of the second groove, one end of the cylinder penetrates through the left side wall of the fixing block and is located inside the first groove and the second groove and is in sliding fit with the first groove, the circular ring is fixedly sleeved on the cylinder and is located in the first groove, two ends of the spring are respectively fixedly connected with the left inner wall of the first groove and the circular ring, and the clamping block is fixedly connected with the lower end of the connecting belt and is in sliding fit with the second groove.

3. The insulated fire protection conduit according to claim 2,

the butt joint assembly further comprises a handle, wherein the handle is fixedly connected with the cylinder and is positioned on the left side of the cylinder.

4. The insulated fire protection conduit according to claim 3,

the butt joint assembly further comprises limiting blocks, wherein the limiting blocks are fixedly connected with the two protruding blocks and are located above the two protruding blocks.

5. The insulated fire protection duct of claim 4,

the heat-insulating fireproof pipeline further comprises a plurality of cross fixing rods and a plurality of annular rods, wherein the cross fixing rods are sequentially arranged on the inner diameter of the silicate board layer, and the annular rods are sequentially arranged and sleeved on the outer diameter of the silicate board layer.