CN212868993U

CN212868993U - Low-energy-consumption assembled heat-insulation support ring

Info

Publication number: CN212868993U
Application number: CN202021367637.1U
Authority: CN
Inventors: 王云超; 杨柳; 薛瑞方; 黄小如
Original assignee: Jiangsu Longying Pipeline New Material Co ltd
Current assignee: Jiangsu Longying Pipeline New Material Co ltd
Priority date: 2020-07-13
Filing date: 2020-07-13
Publication date: 2021-04-02
Anticipated expiration: 2030-07-13

Abstract

The utility model discloses an assembled thermal-insulated support ring of low energy consumption, including two semi-circular arc pipe clamps 2 of embracing the steam conduit 6 of vertical setting, it has a plurality of stereoplasm heat insulating blocks 3 all to have filled in proper order along its circumference in every pipe clamp 2, is located and has passed through fastening clamp 1 fixed connection between two adjacent stereoplasm heat insulating blocks 3 and the pipe clamp 2 in same pipe clamp 2, and pipe clamp 2 wraps up insulating casing 9 and outer jacket 10 from interior to exterior in proper order, between stereoplasm heat insulating block 3 and the steam conduit 6, all be provided with soft insulating layer 7 between two adjacent stereoplasm heat insulating blocks 3. The utility model discloses an effect supports the insulation material layer on the steam conduit of vertical setting, prevents to collapse under the insulation material layer on the steam conduit of the vertical setting of long distance, sets up one at every one section distance on the steam conduit of vertical setting the utility model discloses a support ring.

Description

Low-energy-consumption assembled heat-insulation support ring

Technical Field

The utility model belongs to the technical field of long heat transmission network engineering, in particular to assembled thermal-insulated support ring of low energy consumption.

Background

The vertical pipe supporting ring used in the existing steam heating network engineering is generally directly welded on a steam pipe or a heat insulation layer is not arranged between a pipe clamp and the steam pipe, so that the problems of heat bridge and large heat loss exist; the supporting ring is heavy in weight and has influence on long-term safe operation of the vertical pipeline; when the steam pipeline vibrates, the supporting ring can drop down. For solving the not enough of the perpendicular pipeline supporting ring structure technique that uses among the current steam heating network engineering, the utility model discloses to the problem that current perpendicular pipeline supporting ring structure exists, optimize and improve.

SUMMERY OF THE UTILITY MODEL

The utility model provides a low energy consumption assembled support ring that insulates against heat to solve the problem among the prior art.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

the utility model provides an assembled thermal-insulated support ring of low energy consumption, includes that two encircle the semi-circular arc pipe clamp 2 of the steam conduit 6 of vertical setting, all have a plurality of stereoplasm heat insulating blocks 3 along its circumference packing in proper order in every pipe clamp 2, lie in and through fastening clamp 1 fixed connection between two adjacent stereoplasm heat insulating blocks 3 and the pipe clamp 2 in same pipe clamp 2, pipe clamp 2 has thermal shell 9 and outer jacket 10 from interior to exterior parcel in proper order. Soft heat insulation layers 7 are arranged between the hard heat insulation blocks 3 and the steam pipeline 6 and between two adjacent hard heat insulation blocks 3.

Furthermore, each hard heat insulation block 3 is of a 60-degree arc plate-shaped structure, three hard heat insulation blocks 3 are filled in each pipe clamp 2, and the three hard heat insulation blocks 3 are spliced into a semicircular ring. Preferably, the hard insulation block 3 can be a hard insulation tile. Hard heat insulation blocks 3 are poured by a mold, a heat insulation support ring is embedded into six same hard heat insulation blocks 3, namely 3 hard heat insulation blocks 3 in one pipe clamp 2 are spliced into a semicircular ring, 6 hard heat insulation blocks 3 in two pipe clamps 2 are spliced into a circular ring, the hard heat insulation blocks 3 are convenient to produce, and the tiles can be effectively prevented from cracking.

Furthermore, a supporting vertical plate 8 is arranged in the hard heat insulation block 3 positioned in the middle in the same pipe clamp 2, one end of the supporting vertical plate 8 is fixed on the outer wall of the steam pipeline 6, the other end of the supporting vertical plate 8 penetrates through the soft heat insulation layer 7 and is inserted into the hard heat insulation block 3, and the supporting vertical plate 8 prevents the heat insulation supporting ring from sliding downwards.

Further, a soft heat insulation layer 7 is arranged in a connecting joint of the two pipe clamps 2, and the two pipe clamps 2 are fixed through a bolt assembly 4.

Further, the bolt assembly 4 comprises a screw, a nut and a gasket, the screw sequentially extends into the pipe clamp 2, the soft heat insulation layer 7 in the joint seam of the two pipe clamps 2, the other pipe clamp 2 and the gasket, and the screw is fixed through the nut.

Furthermore, two reinforcing lug plates 5 are respectively welded on two sides of the bolt assembly 4 and used for reinforcing the connection strength of the pipe clamp 2 and preventing the reduction of the heating strength of the pipe clamp 2.

Further, the fastening clip 1 is fixed on the soft heat insulation layer 7 between two adjacent hard heat insulation blocks 3 through screws.

Further, the soft heat insulation layer 7 is made of a friction thermal ceramic fiber felt, and the thickness of the soft heat insulation layer 7 is 20-40 mm.

Compared with the prior art, the utility model discloses following beneficial effect has:

the utility model discloses an effect supports the insulation material layer on the steam conduit of vertical setting, prevents to collapse under the insulation material layer on the steam conduit of the vertical setting of long distance, sets up one at every one section distance on the steam conduit of vertical setting the utility model discloses a support ring.

Drawings

Fig. 1 is a schematic structural diagram of the present invention;

fig. 2 is a side view of the present invention;

fig. 3 is a schematic view of the installation of the present invention;

wherein: 1-fastening clamp, 2-pipe clamp, 3-hard heat insulation block, 4-bolt component, 5-reinforcing ear plate, 6-steam pipe, 7-soft heat insulation layer, 8-supporting vertical plate, 9-heat insulation shell and 10-outer protective layer.

Detailed Description

The present invention will be further described with reference to the following examples.

As shown in figures 1 and 2, the assembled thermal insulation support ring with low energy consumption comprises two semicircular arc-shaped pipe clamps 2 which encircle a steam pipeline 6 which is vertically arranged, a plurality of hard thermal insulation blocks 3 are sequentially filled in each pipe clamp 2 along the circumference of each pipe clamp, the two adjacent hard thermal insulation blocks 3 and the pipe clamps 2 in the same pipe clamp 2 are fixedly connected through fastening clamps 1, and a thermal insulation shell 9 and an outer protective layer 10 are sequentially wrapped on the outer side of each pipe clamp 2 from inside to outside. Soft heat insulation layers 7 are arranged between the hard heat insulation blocks 3 and the steam pipeline 6 and between two adjacent hard heat insulation blocks 3.

As a preferable mode, each hard heat insulation block 3 is of a 60-degree arc plate-shaped structure, three hard heat insulation blocks 3 are filled in each pipe clamp 2, and the three hard heat insulation blocks 3 are spliced into a semicircular ring. Preferably, the hard insulation block 3 can be a hard insulation tile. Hard heat insulation blocks 3 are poured by a mold, a heat insulation support ring is embedded into six same hard heat insulation blocks 3, namely 3 hard heat insulation blocks 3 in one pipe clamp 2 are spliced into a semicircular ring, 6 hard heat insulation blocks 3 in two pipe clamps 2 are spliced into a circular ring, the hard heat insulation blocks 3 are convenient to produce, and the tiles can be effectively prevented from cracking.

As a preferable mode, a supporting vertical plate 8 is arranged in the hard heat insulation block 3 located in the middle in the same pipe clamp 2, one end of the supporting vertical plate 8 is fixed on the outer wall of the steam pipe 6, the other end of the supporting vertical plate 8 penetrates through the soft heat insulation layer 7 and is inserted into the hard heat insulation block 3, and the supporting vertical plate 8 prevents the heat insulation supporting ring from sliding downwards.

As a preferable mode, two layers of soft heat insulation layers 7 are arranged in a connecting seam of the two pipe clamps 2, and the two pipe clamps 2 are fixed through bolt assemblies 4; the bolt assembly 4 comprises a screw, a nut and a gasket, the screw sequentially extends into the pipe clamp 2, the soft heat insulation layer 7 in the joint of the two pipe clamps 2, the other pipe clamp 2 and the gasket, and the screw is fixed through the nut.

As a preferable mode, two reinforcing ear plates 5 are welded to two sides of the bolt assembly 4 respectively for reinforcing the connection strength of the pipe clamp 2 and preventing the heat intensity of the pipe clamp 2 from being reduced.

Preferably, the fastening clip 1 is fixed to the soft heat insulating layer 7 between two adjacent hard heat insulating blocks 3 by screws. Specifically, the section of the fastening clip 1 is of a lower case letter n type, the fastening clip 1 is clamped into two adjacent hard heat insulation blocks 3 in the same pipe clip 2 and the outer edge of the pipe clip 2, then the fastening clip is fixed on the soft heat insulation layer 7 between the two adjacent hard heat insulation blocks 3 through screws, and the screws sequentially penetrate through the front panel and the soft heat insulation layer 7 of the fastening clip 1, then penetrate through the back panel of the fastening clip 1, and then are fixed through nuts.

Preferably, the soft heat insulation layer 7 is made of a mole thermal ceramic fiber felt, and the thickness of the soft heat insulation layer 7 is 20 to 40 mm.

As shown in fig. 3, the utility model discloses an effect is to support the insulation material layer on the steam conduit of vertical setting, prevents to collapse down on the insulation material layer of the steam conduit of the vertical setting of long distance, sets up one at every one section distance on the steam conduit of vertical setting the utility model discloses a support ring has presented two in fig. 3 the utility model discloses a support ring.

The above description is only a preferred embodiment of the present invention, and it should be noted that: for those skilled in the art, without departing from the principle of the present invention, several improvements and modifications can be made, and these improvements and modifications should also be considered as the protection scope of the present invention.

Claims

1. The utility model provides an assembled thermal-insulated support ring of low energy consumption which characterized in that: the heat insulation pipe clamp comprises two semicircular pipe clamps (2) encircling a steam pipeline (6) which is vertically arranged, a plurality of hard heat insulation blocks (3) are sequentially filled in each pipe clamp (2) along the circumference of the pipe clamp, two adjacent hard heat insulation blocks (3) in the same pipe clamp (2) are fixedly connected with the pipe clamp (2) through a fastening clamp (1), and the pipe clamp (2) is sequentially wrapped with a heat insulation shell (9) and an outer protection layer (10) from inside to outside; soft heat insulating layers (7) are arranged between the hard heat insulating blocks (3) and the steam pipeline (6) and between two adjacent hard heat insulating blocks (3).

2. The low energy consumption modular insulating support ring of claim 1, wherein: each hard heat insulation block (3) is of a 60-degree arc plate-shaped structure, three hard heat insulation blocks (3) are filled in each pipe clamp (2), and the three hard heat insulation blocks (3) are spliced into a semicircular ring.

3. The low energy consumption modular thermally insulating support ring of claim 2, wherein: a supporting vertical plate (8) is arranged in the hard heat insulation block (3) positioned in the middle in the same pipe clamp (2), one end of the supporting vertical plate (8) is fixed on the outer wall of the steam pipeline (6), and the other end of the supporting vertical plate (8) penetrates through the soft heat insulation layer (7) and is inserted into the hard heat insulation block (3).

4. The low energy consumption modular insulating support ring of claim 1, wherein: a soft heat insulation layer (7) is arranged in a connecting joint of the two pipe clamps (2), and the two pipe clamps (2) are fixed through a bolt component (4).

5. The low energy consumption modular insulating support ring of claim 4, wherein: the bolt assembly (4) comprises a screw, a nut and a gasket, the screw sequentially extends into one pipe clamp (2), the soft heat insulation layer (7) in the joint seam of the two pipe clamps (2), the other pipe clamp (2) and the gasket, and the bolt is fixed through the nut.

6. The low energy consumption modular insulating support ring of claim 4, wherein: two reinforcing ear plates (5) are respectively welded on two sides of the bolt assembly (4).

7. The low energy consumption modular insulating support ring of claim 1, wherein: the fastening clamp (1) is fixed on the soft heat insulation layer (7) between the two adjacent hard heat insulation blocks (3) through screws.

8. The low energy consumption modular insulating support ring of claim 1, wherein: the soft heat insulation layer (7) is made of Morgan thermal ceramic fiber felt; the thickness of the soft heat insulation layer (7) is 20-40 mm.