CN218539516U - Glass manages production line heat preservation cover - Google Patents

Abstract

The utility model relates to a glass production technical field, and a glass pipe production line heat preservation cover is disclosed, including heat preservation cover unit and luffer boards, the wall that keeps warm the cover unit sets up coupling assembling, a plurality of heat preservation cover units form heat preservation cover body through coupling assembling end to end, the internal face that keeps warm the cover unit is provided with the composite bed, use through splicing a plurality of heat preservation cover units end to end, the length of the heat preservation cover body of being convenient for change in a flexible way, flexibility and convenience are stronger, when using two heat preservation cover unit end to end connections, promote positioning bolt and drive the snap ring and slide in the second spout, the snap ring slides to in the first spout in the second spout gradually, rotate in positioning bolt makes positioning bolt's lower terminal surface get into the location hole of bottom surface in the first spout, make two adjacent heat preservation cover unit connections, the snap ring of heat preservation cover unit lateral wall places two heat preservation cover unit joints end to end with the same, it is more convenient at installation heat preservation cover unit in-process, high efficiency.

Description

Glass manages production line heat preservation cover

Technical Field

The utility model relates to a glass production technical field especially relates to a glass manages production line heat preservation cover.

Background

Retrieve prior art and disclose a glass pipe production line heat preservation cover and glass pipe production line (CN 201922120037.9), glass pipe production line heat preservation cover include two relative lateral walls that set up and with the roof that the lateral wall is connected, the lateral wall is the convergent setting from being close to muffle furnace one end to keeping away from muffle furnace's one end, each the lateral wall include the backup pad and with the heat preservation piece that the backup pad is connected. The heat-insulating cover for the glass tube production line of the utility model has the advantages that the side wall comprises the supporting plate and the heat-insulating piece, and the heat-insulating piece is used for reducing air convection and preventing heat transfer inside and outside the heat-insulating cover, so that the heat-insulating effect of the heat-insulating cover is effectively improved;

wherein, prior art forms thermal-insulated protective screen through integrated into one piece's heat preservation cover, and whole heat preservation cover length is fixed can not dismantle, can not adjust its length according to the production line is nimble, is unfavorable for nimble overall arrangement and installation.

Therefore, the heat insulation cover for the glass tube production line is provided.

SUMMERY OF THE UTILITY MODEL

The utility model mainly solves the technical problem existing in the prior art and provides a heat preservation cover for a glass tube production line.

In order to realize the above-mentioned purpose, the utility model discloses a following technical scheme, a glass manages production line heat preservation cover, including heat preservation cover unit and luffer board, the window is seted up to the lateral wall face of heat preservation cover unit, the window is sealed by luffer board, the wall of heat preservation cover unit sets up coupling assembling, and a plurality of heat preservation cover units form the heat preservation cover body through coupling assembling end to end, and the internal face of heat preservation cover unit is provided with the composite bed, coupling assembling includes snap ring, positioning bolt, first spout, second spout and location hole, first spout and second spout are seted up to the wall of heat preservation cover unit, snap ring and second spout sliding connection, positioning bolt and snap ring threaded connection, location hole are still seted up to the wall of heat preservation cover unit.

As a further limitation of the scheme, the second sliding groove and the first sliding groove are formed in the opposite end faces of the heat preservation cover units, and the clamping ring can enter the first sliding groove in a sliding mode to connect the two adjacent heat preservation cover units.

As a further limitation of the scheme, the first sliding groove and the second sliding groove are both arc-shaped grooves, the circle centers of the first sliding groove and the second sliding groove are located on the same axis, the clamping ring is an arc-shaped rod with the diameter equal to that of the second sliding groove, and the clamping ring is concentric with the second sliding groove.

As the further injeciton of above-mentioned scheme, the length of second spout is greater than the length of first spout, and positioning bolt length is greater than the thickness of snap ring, and the same location hole is all seted up to the interior bottom surface that the cover unit that keeps warm is located first spout and second spout, and when the snap ring got into first spout completely, positioning bolt was located the location hole of bottom surface in the first spout, and when the snap ring got into the second spout completely, positioning bolt was located another location hole directly over, and the top surface that the cover unit that keeps warm all sets up the same coupling assembling with the lateral wall that the cover unit keeps warm.

In a further limitation of the above aspect, the composite layer includes a base layer, an aluminum hydroxide layer, a foaming layer, and a surface layer, the base layer, the aluminum hydroxide layer, the foaming layer, and the surface layer are sequentially bonded to form the composite layer, and the composite layer is fixedly connected to the inner wall surface of the heat-insulating cover unit.

As a further limitation of the above solution, the composite layer further includes a cavity and filling powder, the cavity is formed inside the foaming layer, and the cavity is filled with the filling powder.

Advantageous effects

The utility model provides a glass manages production line heat preservation cover. The method has the following beneficial effects:

(1) This glass manages production line heat preservation cover, through using a plurality of heat preservation cover unit end to end concatenations, the length of the heat preservation cover body of being convenient for to nimble change, flexibility and convenience are stronger, when using two heat preservation cover unit end to end connections, promote positioning bolt to drive the snap ring and slide in the second spout, the snap ring slides to first spout in following the second spout gradually, rotate positioning bolt and make positioning bolt's lower terminal surface get into in the location hole of bottom surface in the first spout, make adjacent two heat preservation cover unit connection, the snap ring of heat preservation cover unit lateral wall covers the unit joint with two heat preservation of end to end with the same placing, it is more convenient at installation heat preservation cover unit in-process, high efficiency.

(2) This glass manages production line heat preservation cover through setting up the composite bed, and the top layer utilizes coupling agent coating on the foaming layer surface by modified walnut shell sand, and the mixture of carbon black, nickel powder chromium powder can be adopted to the packing powder, sets up the composite bed through the internal face at the heat preservation cover unit, promotes greatly to the heat preservation and heat insulation performance of whole heat preservation cover body, and energy-conserving effect is more excellent.

Drawings

The structures, proportions, sizes, and other elements shown in the specification are for the understanding of the present disclosure, and are not intended to limit the scope of the present disclosure, which is defined by the claims, but rather by the claims.

FIG. 1 is a perspective view of the present invention;

FIG. 2 is a schematic view of the installation of the snap ring and the heat-insulating cover unit of the utility model;

figure 3 is a top surface sectional view of the unit of the heat preservation cover of the utility model.

Illustration of the drawings:

10. a heat-insulating cover unit; 11. a window panel; 20. a snap ring; 21. positioning the bolt; 22. a first chute; 23. a second chute; 24. positioning the hole; 30. a base layer; 31. an aluminum hydroxide layer; 32. a foamed layer; 33. a surface layer; 34. a cavity; 35. and filling the powder.

Detailed Description

A heat-insulating cover for a glass tube production line is disclosed, as shown in figures 1-2, and comprises a heat-insulating cover unit 10 and window plates 11, wherein a window is arranged on the side wall surface of the heat-insulating cover unit 10, the window is sealed by the window plates 11, a connecting assembly is arranged on the wall surface of the heat-insulating cover unit 10, a plurality of heat-insulating cover units 10 are connected end to end through the connecting assembly to form a heat-insulating cover body, a composite layer is arranged on the inner wall surface of the heat-insulating cover unit 10, the connecting assembly comprises a clamping ring 20, a positioning bolt 21, a first sliding chute 22, a second sliding chute 23 and a positioning hole 24, the wall surface of the heat-insulating cover unit 10 is provided with the first sliding chute 22 and the second sliding chute 23, the clamping ring 20 is in sliding connection with the second sliding chute 23, the positioning bolt 21 is in threaded connection with the clamping ring 20, the wall surface of the heat-insulating cover unit 10 is also provided with the positioning hole 24, the second sliding chute 23 and the first sliding chute 22 are arranged at the opposite end surfaces of the heat-insulating cover unit 10, the clamping ring 20 can slide into the first sliding groove 22 to connect two adjacent heat-insulating cover units 10, the first sliding groove 22 and the second sliding groove 23 are both arc-shaped grooves, the centers of the first sliding groove 22 and the second sliding groove 23 are positioned on the same axis, the snap ring 20 is an arc-shaped rod with the same diameter as the second sliding groove 23, the snap ring 20 is concentric with the second sliding groove 23, the length of the second sliding groove 23 is greater than that of the first sliding groove 22, the length of the positioning bolt 21 is greater than the thickness of the snap ring 20, the heat preservation cover unit 10 is positioned on the inner bottom surfaces of the first sliding groove 22 and the second sliding groove 23 and is provided with the same positioning hole 24, when the snap ring 20 completely enters the first sliding groove 22, the positioning bolt 21 is positioned in the positioning hole 24 on the inner bottom surface of the first sliding groove 22, when the snap ring 20 completely enters the second sliding groove 23, the positioning bolt 21 is positioned right above the other positioning hole 24, the top surface of the heat preservation cover unit 10 and the side wall of the heat preservation cover unit 10 are provided with the same connecting assembly, through using a plurality of heat preservation cover unit 10 end to end concatenation, the length of the heat preservation cover body of being convenient for change in a flexible way, flexibility and convenience are stronger, when using two heat preservation cover unit 10 end to end connections, promote positioning bolt 21 and drive snap ring 20 and slide in second spout 23, snap ring 20 slides to first spout 22 in following second spout 23 gradually, rotate positioning bolt 21 and make positioning bolt 21's lower terminal surface get into the location hole 24 of bottom surface in first spout 22, make two adjacent heat preservation cover unit 10 connect, the snap ring 20 of heat preservation cover unit 10 lateral wall is with the same two heat preservation cover unit 10 joints of placing head and tail, it is more convenient at installation heat preservation cover unit 10 in-process, high efficiency.

The utility model provides a glass pipe production line heat preservation cover, as shown in fig. 1 and fig. 3, the composite bed includes stratum basale 30, aluminium hydroxide layer 31, foaming layer 32 and top layer 33, stratum basale 30, aluminium hydroxide layer 31, foaming layer 32, top layer 33 bonds in proper order and forms the composite bed, composite bed and heat preservation cover unit 10 internal face fixed connection, the composite bed still includes cavity 34 and packing powder 35, foaming layer 32's inside vacuole formation 34, cavity 34 fills packing powder 35, through setting up the composite bed, top layer 33 utilizes coupling agent coating on foaming layer 32 surface by modified walnut shell sand, packing powder 35 can adopt carbon black, the mixture of nickel powder chromium powder, through setting up the composite bed at the internal face of heat preservation cover unit 10, heat preservation and heat insulation performance to whole heat preservation cover body promotes greatly, energy-conserving effect is more excellent.

The utility model discloses a theory of operation: with the use of splicing of a plurality of heat preservation cover units 10 end to end, when using two heat preservation cover units 10 end to end connections, promote positioning bolt 21 and drive snap ring 20 and slide in second spout 23, snap ring 20 slides to first spout 22 in following second spout 23 gradually, rotate positioning bolt 21 and make positioning bolt 21's lower terminal surface get into in the positioning hole 24 of bottom surface in first spout 22, make two adjacent heat preservation cover units 10 connect, the snap ring 20 of heat preservation cover unit 10 lateral wall is with same two heat preservation cover unit 10 joints with end to end of placing, stratum basale 30, aluminium hydroxide layer 31, foaming layer 32, top layer 33 bonds in proper order and forms the composite bed and fixes and form thermal-insulated protective screen at the internal face that heat preservation cover unit 10.

The foregoing shows and describes the basic principles and principal features of the invention, together with the advantages thereof. It should be understood by those skilled in the art that the present invention is not limited to the above embodiments, and the above embodiments and descriptions are only illustrative of the principles of the present invention, and that various changes and modifications may be made without departing from the spirit and scope of the present invention, and all such changes and modifications fall within the scope of the present invention as claimed.

Claims (6)

1. The utility model provides a glass manages production line heat preservation cover, includes heat preservation cover unit (10) and luffer board (11), and the window is seted up to the side wall face of heat preservation cover unit (10), the window is sealed by luffer board (11), its characterized in that: the wall of heat preservation cover unit (10) sets up coupling assembling, and a plurality of heat preservation cover units (10) form the heat preservation cover body through coupling assembling end to end, and the internal face of heat preservation cover unit (10) is provided with the composite bed, coupling assembling includes snap ring (20), positioning bolt (21), first spout (22), second spout (23) and positioning hole (24), first spout (22) and second spout (23) are seted up to the wall of heat preservation cover unit (10), snap ring (20) and second spout (23) sliding connection, positioning bolt (21) and snap ring (20) threaded connection, positioning hole (24) are still seted up to the wall of heat preservation cover unit (10).

2. The heat-insulating cover for glass tube production line according to claim 1, characterized in that: the second sliding groove (23) and the first sliding groove (22) are arranged on the opposite end faces of the heat preservation cover units (10), and the clamping ring (20) can slide into the first sliding groove (22) to connect the two adjacent heat preservation cover units (10).

3. The heat-insulating cover for glass tube production line according to claim 2, characterized in that: the first sliding groove (22) and the second sliding groove (23) are arc-shaped grooves, the circle centers of the first sliding groove (22) and the second sliding groove (23) are located on the same axis, the clamping ring (20) is an arc-shaped rod with the diameter equal to that of the second sliding groove (23), and the clamping ring (20) is concentric with the second sliding groove (23).

4. The heat-insulating cover for glass tube production line according to claim 3, characterized in that: the length of second spout (23) is greater than the length of first spout (22), positioning bolt (21) length is greater than the thickness of snap ring (20), the interior bottom surface that heat preservation cover unit (10) are located first spout (22) and second spout (23) all sets up same location hole (24), when snap ring (20) get into first spout (22) completely, positioning bolt (21) are located the location hole (24) of bottom surface in first spout (22), when snap ring (20) get into second spout (23) completely, positioning bolt (21) are located another location hole (24) directly over, the top surface of heat preservation cover unit (10) and the lateral wall of heat preservation cover unit (10) all set up the same coupling assembling.

5. The heat-insulating cover for glass tube production line according to claim 1, characterized in that: the composite layer comprises a substrate layer (30), an aluminum hydroxide layer (31), a foaming layer (32) and a surface layer (33), wherein the substrate layer (30), the aluminum hydroxide layer (31), the foaming layer (32) and the surface layer (33) are sequentially bonded to form the composite layer, and the composite layer is fixedly connected with the inner wall surface of the heat-insulating cover unit (10).

6. The heat-insulating cover for glass tube production line according to claim 5, characterized in that: the composite layer further comprises a cavity (34) and filling powder (35), the cavity (34) is formed inside the foaming layer (32), and the cavity (34) is filled with the filling powder (35).

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