CN216689834U - Energy-saving heat-insulating building material - Google Patents

Abstract

The utility model relates to the technical field of heat-insulating materials, and discloses an energy-saving heat-insulating building material which comprises an installation frame, a first heat-insulating mechanism, a second heat-insulating mechanism, a connecting mechanism and a fixing mechanism, wherein the first heat-insulating mechanism is positioned at the inner end of the installation frame, the second heat-insulating mechanism is positioned on the right side of the first heat-insulating mechanism, the connecting mechanism is positioned between the first heat-insulating mechanism and the second heat-insulating mechanism, the connecting mechanism is symmetrically distributed at the upper end and the lower end of the first heat-insulating mechanism and the second heat-insulating mechanism, and the fixing mechanism is positioned at the outer end of the connecting mechanism. This energy-conserving insulation building material penetrates the locating hole inside with the locating pin axle, can make left connection piece, right connection piece respectively with first heated board, second heated board swing joint, consequently can the heated board receive the exogenic action time, drive left connection piece and right connection piece activity to for the heated board provides the buffering, can improve the stability of being connected between first heated board and the second heated board from this.

Description

Energy-saving heat-insulating building material

Technical Field

The utility model relates to the technical field of heat insulation materials, in particular to an energy-saving heat insulation building material.

Background

The heat insulation material generally refers to a material with a thermal coefficient less than or equal to 0.12, the heat insulation material is developed quickly, and good heat insulation technology and materials are adopted in industry and buildings, so that the effect of achieving twice the result with half the effort can be achieved.

In the prior art, the heat-insulating building materials are mostly connected by bolts and nuts, so that when the heat-insulating building materials expand with heat and contract with cold, the occupied space after expansion is increased, the bolts and the nuts can not provide corresponding extension space for the heat-insulating building materials, and therefore the heat-insulating building materials are likely to be extruded mutually to cause deformation, so that the attractiveness and the service life are influenced.

SUMMERY OF THE UTILITY MODEL

Technical problem to be solved

The utility model aims to provide an energy-saving heat-insulating building material, which aims to solve the problems that in the prior art provided by the background art, heat-insulating building materials are mostly connected by bolts and nuts, so that when the heat-insulating building materials expand with heat and contract with cold, the occupied space of the heat-insulating building materials is increased after expansion, the bolts and nuts cannot provide corresponding extension space for the heat-insulating building materials, and therefore the heat-insulating building materials are likely to be extruded with each other to cause deformation, so that the attractiveness and the service life are influenced.

(II) technical scheme

In order to achieve the purpose, the utility model provides the following technical scheme: the utility model provides an energy-conserving heat preservation building material, includes installing frame, first heat preservation mechanism, second heat preservation mechanism, coupling mechanism and fixed establishment, first heat preservation mechanism is located the inner of installing frame, second heat preservation mechanism is located the right side of first heat preservation mechanism, coupling mechanism is located between first heat preservation mechanism and the second heat preservation mechanism, coupling mechanism symmetric distribution is at the upper and lower both ends of first heat preservation mechanism and second heat preservation mechanism, fixed establishment is located coupling mechanism's outer end.

Preferably, first heat preservation mechanism includes first insulation board, first recess and first chamfer, first insulation board fixed mounting is in the inner left side of installing frame, first recess sets up both ends about first insulation board, first recess equidistance distributes both ends about first insulation board, first chamfer sets up both ends about first insulation board, first chamfer symmetric distribution is in the upper and lower both sides at both ends about first insulation board, through setting up first recess, can conveniently link together first insulation board and coupling mechanism, makes to have sufficient space adaptation extrusion force between the two between the first insulation board and the second insulation board through setting up first chamfer.

Preferably, second heat preservation mechanism includes second heated board, second recess and second chamfer, second heated board swing joint is on the right side of first heated board, the second recess sets up both ends about the second heated board, second recess equidistance distributes both ends about the second heated board, the second chamfer sets up both ends about the second heated board, second chamfer symmetric distribution is in the upper and lower both sides at both ends about the second heated board, through setting up the second recess, can conveniently link together second heated board and coupling mechanism, makes to have sufficient space adaptation extrusion force that receives between the two between first heated board and the second heated board through setting up the second chamfer.

Preferably, the connecting mechanism comprises a connecting long shaft, a left connecting piece, a right connecting piece, a positioning hole, a positioning pin shaft and a limiting block, the connecting long shaft is positioned inside the first chamfer and the second chamfer, the left connecting piece is movably arranged at the outer end of the connecting long shaft, the right connecting piece is movably arranged at the outer end of the connecting long shaft, the left connecting piece is equidistantly arranged at the outer end of the connecting long shaft, the right connecting piece is movably connected with the left connecting piece, the left connecting piece is matched with the first groove, the right connecting piece is matched with the second groove, the positioning hole is arranged at the outer end of the left connecting piece, the positioning hole is arranged at the outer end of the right connecting piece, when the first heat-insulating plate and the second heat-insulating plate are required to be installed together, the two connecting long shafts which are symmetrically distributed up and down are fixed together, the left connecting piece is then inserted inside the first groove and the right connecting piece is inserted inside the second groove.

Preferably, the locating pin axle runs through the locating hole and extends to the front and back both ends of first heated board, the locating pin axle runs through the locating hole and extends to the front and back both ends of second heated board, through setting up the locating pin axle, penetrates the locating hole inside with the locating pin axle, can make left connection piece, right connection piece respectively with first heated board, second heated board swing joint, consequently can receive the exogenic action at first heated board and second heated board and act on time, drive left connection piece and right connection piece activity to provide the buffering for first heated board and second heated board.

Preferably, the limiting blocks are arranged at the front end and the rear end of the positioning pin shaft, the limiting blocks are detachably connected with the positioning pin shaft, and the limiting blocks limit the positioning pin shaft and prevent the positioning pin shaft from being separated from the first heat-insulating plate and the second heat-insulating plate.

Preferably, the fixing mechanism comprises a fastening bolt, a positioning nut and a fastening nut, the fastening bolt is in threaded connection with the long connecting shaft, the positioning nut is fixedly installed at the lower end of the fastening bolt, the fastening nut is in threaded connection above the outer end of the fastening bolt, the fastening bolt is arranged, and the two long connecting shafts which are symmetrical up and down can be fixed together by the aid of the fastening bolt, so that stability and firmness of the connecting mechanism are improved.

Compared with the prior art, the utility model has the beneficial effects that:

1. according to the energy-saving heat-insulating building material, the left connecting piece and the right connecting piece are arranged, when the first heat-insulating plate and the second heat-insulating plate are required to be installed together, the left connecting piece is inserted into the first groove, the right connecting piece is inserted into the second groove, and the positioning pin shaft penetrates into the positioning hole, so that the left connecting piece and the right connecting piece are respectively movably connected with the first heat-insulating plate and the second heat-insulating plate, the left connecting piece and the right connecting piece can be driven to move when the first heat-insulating plate and the second heat-insulating plate are subjected to external force, buffering is provided for the first heat-insulating plate and the second heat-insulating plate, and therefore the connection stability between the first heat-insulating plate and the second heat-insulating plate can be improved;

2. according to the energy-saving heat-insulating building material, the heat-insulating plates can be conveniently connected with the connecting mechanism through the grooves, enough space can be formed between the first heat-insulating plate and the second heat-insulating plate to adapt to extrusion force between the first heat-insulating plate and the second heat-insulating plate through the chamfers, and the first heat-insulating plate and the second heat-insulating plate can be conveniently buffered when being stressed;

3. this energy-conserving insulation building material, through setting up the stopper, this stopper carries on spacingly to the locating pin axle, prevents that it from breaking away from first heated board and second heated board.

Drawings

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

FIG. 2 is a schematic perspective view of the connecting mechanism of the present invention;

FIG. 3 is a schematic perspective view of a fixing mechanism according to the present invention;

fig. 4 is a schematic perspective view of a first groove of the present invention.

In the figure: 1. installing a frame; 2. a first heat preservation mechanism; 201. a first heat-insulating plate; 202. a first groove; 203. a first chamfer; 3. a second heat preservation mechanism; 301. a second insulation board; 302. a second groove; 303. a second chamfer; 4. a connecting mechanism; 401. connecting the long shaft; 402. a left connecting sheet; 403. a right connecting sheet; 404. positioning holes; 405. positioning a pin shaft; 406. a limiting block; 5. a fixing mechanism; 501. fastening a bolt; 502. positioning a nut; 503. and (5) tightening the nut.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-4, the present invention provides a technical solution: an energy-saving heat-insulating building material comprises an installation frame 1, a first heat-insulating mechanism 2, a second heat-insulating mechanism 3, a connecting mechanism 4 and a fixing mechanism 5, wherein the first heat-insulating mechanism 2 is positioned at the inner end of the installation frame 1, the second heat-insulating mechanism 3 is positioned on the right side of the first heat-insulating mechanism 2, the connecting mechanism 4 is positioned between the first heat-insulating mechanism 2 and the second heat-insulating mechanism 3, the connecting mechanisms 4 are symmetrically distributed at the upper end and the lower end of the first heat-insulating mechanism 2 and the upper end and the lower end of the second heat-insulating mechanism 3, and the fixing mechanism 5 is positioned at the outer end of the connecting mechanism 4;

the first heat preservation mechanism 2 comprises a first heat preservation plate 201, a first groove 202 and a first chamfer 203, the first heat preservation plate 201 is fixedly installed on the left side of the inner end of the installation frame 1, the first groove 202 is arranged at the left end and the right end of the first heat preservation plate 201, the first groove 202 is equidistantly distributed at the left end and the right end of the first heat preservation plate 201, the first chamfer 203 is arranged at the left end and the right end of the first heat preservation plate 201, the first chamfer 203 is symmetrically distributed at the upper side and the lower side of the left end and the right end of the first heat preservation plate 201, through arrangement of the first groove 202, the first heat preservation plate 201 and the connecting mechanism 4 can be conveniently connected together, through arrangement of the first chamfer 203, enough space is formed between the first heat preservation plate 201 and the second heat preservation plate 301 to adapt to the extrusion force applied between the first heat preservation plate 201 and the second heat preservation plate 301, and enough space is convenient for the first heat preservation plate 201 and the second heat preservation plate 301 to be buffered when stressed; the second heat insulation mechanism 3 comprises a second heat insulation plate 301, a second groove 302 and a second chamfer 303, the second heat insulation plate 301 is movably connected to the right side of the first heat insulation plate 201, the second groove 302 is arranged at the left end and the right end of the second heat insulation plate 301, the second groove 302 is equidistantly distributed at the left end and the right end of the second heat insulation plate 301, the second chamfer 303 is arranged at the left end and the right end of the second heat insulation plate 301, the second chamfer 303 is symmetrically distributed at the upper side and the lower side of the left end and the right end of the second heat insulation plate 301, through the arrangement of the second groove 302, the second heat insulation plate 301 and the connecting mechanism 4 can be conveniently connected together, through the arrangement of the second chamfer 303, enough space is formed between the first heat insulation plate 201 and the second heat insulation plate 301 to adapt to the extrusion force received between the first heat insulation plate 201 and the second heat insulation plate 301, and enough space is convenient for the first heat insulation plate 201 and the second heat insulation plate 301 to be buffered when stressed; the connecting mechanism 4 comprises a connecting long shaft 401, a left connecting piece 402, a right connecting piece 403, a positioning hole 404, a positioning pin 405 and a limiting block 406, the connecting long shaft 401 is positioned inside the first chamfer 203 and the second chamfer 303, the left connecting piece 402 is movably arranged at the outer end of the connecting long shaft 401, the right connecting piece 403 is movably arranged at the outer end of the connecting long shaft 401, the left connecting piece 402 is equidistantly arranged at the outer end of the connecting long shaft 401, the right connecting piece 403 is equidistantly arranged at the outer end of the connecting long shaft 401, the left connecting piece 402 is movably connected with the right connecting piece 403, the left connecting piece 402 is matched with the first groove 202, the right connecting piece 403 is matched with the second groove 302, the positioning hole 404 is arranged at the outer end of the left connecting piece 402, the positioning hole 404 is arranged at the outer end of the right connecting piece 403, by arranging the left connecting piece 402 and the right connecting piece 403, when the first heat-preserving plate 201 and the second heat-preserving plate 301 are required to be installed together, firstly, fixing two long connecting shafts 401 which are distributed vertically and symmetrically together, then enabling left connecting pieces 402 to be in one-to-one correspondence with first grooves 202, enabling right connecting pieces 403 to be in one-to-one correspondence with second grooves 302, inserting the left connecting pieces 402 into the first grooves 202, and inserting the right connecting pieces 403 into the second grooves 302;

the positioning pin shaft 405 penetrates through the positioning hole 404 and extends to the front end and the rear end of the first heat-insulation plate 201, the positioning pin shaft 405 penetrates through the positioning hole 404 and extends to the front end and the rear end of the second heat-insulation plate 301, and the positioning pin shaft 405 penetrates into the positioning hole 404, so that the left connecting sheet 402 and the right connecting sheet 403 can be movably connected with the first heat-insulation plate 201 and the second heat-insulation plate 301 respectively, when the first heat-insulation plate 201 and the second heat-insulation plate 301 are subjected to external force, the left connecting sheet 402 and the right connecting sheet 403 can be driven to move, buffering is provided for the first heat-insulation plate 201 and the second heat-insulation plate 301, and therefore the connection stability between the first heat-insulation plate 201 and the second heat-insulation plate 301 can be improved; the limiting blocks 406 are arranged at the front end and the rear end of the positioning pin shaft 405, the limiting blocks 406 are detachably connected with the positioning pin shaft 405, and the limiting blocks 406 limit the positioning pin shaft 405 to prevent the positioning pin shaft from separating from the first heat-insulating plate 201 and the second heat-insulating plate 301; fixing mechanism 5 includes fastening bolt 501, set nut 502 and fastening nut 503, fastening bolt 501 with be connected threaded connection between the major axis 401, set nut 502 fixed mounting is at fastening bolt 501's lower extreme, fastening nut 503 threaded connection is in the top of fastening bolt 501 outer end, through setting up fastening bolt 501, utilize fastening bolt 501, can be in the same place two connection major axes 401 of longitudinal symmetry to improve coupling mechanism 4's stability and fastness.

The working principle is as follows: firstly, align first heated board 201 with second heated board 301, then with left connection piece 402 and first recess 202 one-to-one, right connection piece 403 and second recess 302 one-to-one, left connection piece 402 inserts inside first recess 202, right connection piece 403 inserts inside second recess 302, then penetrate locating pin axle 405 inside locating hole 404, make left connection piece 402, right connection piece 403 respectively with first heated board 201, second heated board 301 swing joint, it is spacing to reuse stopper 406 with locating pin axle 405, and finally, utilize fastening bolt 501, can be in the same place two connection major axes 401 of upper and lower symmetry are fixed, can accomplish the installation connection work of this device.

Finally, it should be noted that the above-mentioned contents are only used for illustrating the technical solutions of the present invention, and not for limiting the protection scope of the present invention, and that the simple modifications or equivalent substitutions of the technical solutions of the present invention by those of ordinary skill in the art can be made without departing from the spirit and scope of the technical solutions of the present invention.

Claims (7)

1. The utility model provides an energy-conserving heat preservation building material, includes installing frame (1), first heat preservation mechanism (2), second heat preservation mechanism (3), coupling mechanism (4) and fixed establishment (5), its characterized in that: first heat preservation mechanism (2) are located the inner of installing frame (1), second heat preservation mechanism (3) are located the right side of first heat preservation mechanism (2), coupling mechanism (4) are located between first heat preservation mechanism (2) and second heat preservation mechanism (3), coupling mechanism (4) symmetric distribution is at the upper and lower both ends of first heat preservation mechanism (2) and second heat preservation mechanism (3), fixed establishment (5) are located the outer end of coupling mechanism (4).

2. The energy-saving heat-insulating building material according to claim 1, characterized in that: first heat preservation mechanism (2) are including first heat preservation board (201), first recess (202) and first chamfer (203), first heat preservation board (201) fixed mounting is in the left side of installing frame (1) inner, both ends about first recess (202) set up first heat preservation board (201), first recess (202) equidistance distributes both ends about first heat preservation board (201), first chamfer (203) set up both ends about first heat preservation board (201), first chamfer (203) symmetric distribution is in the upper and lower both sides at both ends about first heat preservation board (201).

3. The energy-saving heat-insulating building material as claimed in claim 2, wherein: second heat preservation mechanism (3) include second heated board (301), second recess (302) and second chamfer (303), second heated board (301) swing joint is on the right side of first heated board (201), second recess (302) set up both ends about second heated board (301), second recess (302) equidistance distributes both ends about second heated board (301), second chamfer (303) set up both ends about second heated board (301), second chamfer (303) symmetric distribution is in the upper and lower both sides at both ends about second heated board (301).

4. The energy-saving heat-insulating building material according to claim 3, characterized in that: the connecting mechanism (4) comprises a connecting long shaft (401), a left connecting piece (402), a right connecting piece (403), a positioning hole (404), a positioning pin shaft (405) and a limiting block (406), the connecting long shaft (401) is positioned inside a first chamfer (203) and a second chamfer (303), the left connecting piece (402) is movably arranged at the outer end of the connecting long shaft (401), the right connecting piece (403) is movably arranged at the outer end of the connecting long shaft (401), the left connecting piece (402) is equidistantly arranged at the outer end of the connecting long shaft (401), the right connecting piece (403) is equidistantly arranged at the outer end of the connecting long shaft (401), the left connecting piece (402) is movably connected with the right connecting piece (403), the left connecting piece (402) is matched with the first groove (202), the right connecting piece (403) is matched with the second groove (302), the positioning hole (404) is arranged at the outer end of the left connecting piece (402), the positioning hole (404) is arranged at the outer end of the right connecting piece (403).

5. The energy-saving heat-insulating building material according to claim 4, wherein: the positioning pin shaft (405) penetrates through the positioning hole (404) and extends to the front end and the rear end of the first heat insulation plate (201), and the positioning pin shaft (405) penetrates through the positioning hole (404) and extends to the front end and the rear end of the second heat insulation plate (301).

6. The energy-saving heat-insulating building material according to claim 5, wherein: the limiting blocks (406) are arranged at the front end and the rear end of the positioning pin shaft (405), and the limiting blocks (406) are detachably connected with the positioning pin shaft (405).

7. The energy-saving heat-insulating building material according to claim 6, wherein: the fixing mechanism (5) comprises a fastening bolt (501), a positioning nut (502) and a fastening nut (503), the fastening bolt (501) is in threaded connection with the long shaft (401), the positioning nut (502) is fixedly installed at the lower end of the fastening bolt (501), and the fastening nut (503) is in threaded connection above the outer end of the fastening bolt (501).

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