CN110295705B

CN110295705B - Non-bearing wall body insulating brick

Info

Publication number: CN110295705B
Application number: CN201910605846.0A
Authority: CN
Inventors: 丁纪友; 尹健国; 其他发明人请求不公开姓名
Original assignee: Shandong Pingan Yijia Building Material Co ltd
Current assignee: SHANDONG PINGAN YIJIA BUILDING MATERIAL Co.,Ltd.
Priority date: 2019-07-05
Filing date: 2019-07-05
Publication date: 2021-08-20
Anticipated expiration: 2039-07-05
Also published as: CN110295705A

Abstract

The invention relates to the field of insulating bricks, in particular to a non-bearing wall insulating brick which comprises a main body, a sliding mechanism, an installation mechanism, an insulating mechanism, an extrusion mechanism and a connecting rod, wherein the main body is provided with a sliding groove; the top surface of the main body and the ground are respectively provided with an installation mechanism, when the two main bodies are spliced, cement mortar is placed on the top surface of one main body, the cement mortar is stored in the installation mechanism on the top surface of the main body, the other main body is placed on the top surface of the main body, the main bodies are extruded downwards, the installation mechanism on the bottom surface of the main body enters the installation mechanism on the top surface of the main body, the cement mortar is solidified to fix the two main bodies together, and the cement mortar is stored in the installation mechanism, so that the seepage amount of the cement mortar from the joint of the main bodies is reduced, the waste is reduced, and the firmness of the joint of the two main bodies is improved; the inside sliding connection extrusion mechanism of heat preservation mechanism makes heat preservation mechanism strut in the inside of main part, makes heat preservation mechanism hug closely the inside of main part, improves the heat insulating ability of main part.

Description

Non-bearing wall body insulating brick

Technical Field

The invention relates to the field of insulating bricks, in particular to a non-bearing wall insulating brick.

Background

The insulating brick is a new type of building material, which is synthesized by high molecular material and also processed by coal slag and slag. The wall filling material is mainly used for filling walls of buildings, has the advantages of light weight, convenient construction, heat preservation and the like, and becomes a main wall material of modern buildings.

In the construction process of the insulating bricks, some cement mortar leaks outwards from the joint of the two insulating bricks, so that the waste of the cement mortar is caused, and the strength of the joint of the insulating bricks is reduced.

Disclosure of Invention

Aiming at the problems in the prior art, the invention provides a non-bearing wall insulating brick, wherein the top surface of a main body and the ground are respectively provided with an installation mechanism, when two main bodies are spliced, cement mortar is placed on the top surface of one main body, the cement mortar is stored in the installation mechanism on the top surface of the main body, the other main body is placed on the top surface of the main body, the main body is downwards extruded, the installation mechanism on the bottom surface of the main body enters the installation mechanism on the top surface of the main body, the cement mortar is solidified to fix the two main bodies together, the cement mortar is stored in the installation mechanism, the seepage amount of the cement mortar from the joint of the main bodies is reduced, the waste is reduced, the firmness of the joint of the two main bodies is increased, an insulating mechanism is installed in the main body, the inside of the insulating mechanism is slidably connected with an extrusion mechanism, the extrusion mechanism moves in the insulating mechanism, so that the insulating mechanism is propped up in the main body, the heat preservation mechanism is tightly attached to the inside of the main body and fixed in the main body, so that the heat preservation performance of the main body is improved.

The technical scheme adopted by the invention for solving the technical problems is as follows: a non-bearing wall insulating brick comprises a main body, a sliding mechanism, an installation mechanism, an insulating mechanism, an extrusion mechanism and a first connecting rod; the mounting mechanism for splicing the insulating bricks is mounted on the top surface of the main body and the ground, the insulating mechanism for improving the insulating performance of the insulating bricks is mounted in the main body, and the sliding mechanism is mounted at the joint of the insulating mechanism and the main body; the interior of the heat preservation mechanism is connected with the extrusion mechanism in a sliding manner, the interior of the extrusion mechanism is obliquely provided with the first connecting rod for increasing the stability of the extrusion mechanism, and the first connecting rod is connected with the interior of the main body in a sliding manner; the main body is provided with a flow guide hole.

Specifically, the mounting mechanism comprises a first connecting plate, a second connecting plate, grooves, extrusion plates, through holes and sealing rods, the grooves are formed in the top surface of the main body, and the second connecting plates are mounted on the inner bottom surface of the grooves at equal intervals; the bottom surface of the main body is provided with the first connecting plates at equal intervals, the side walls of the first connecting plates are vertically provided with the extrusion plates, and the top surfaces of the extrusion plates are provided with the through holes uniformly and respectively; the first connecting plate and the extrusion plate are slidably connected with the inner portion of the groove, and the inner portion of the groove is slidably connected with the sealing rod.

Specifically, the first connecting plate and the second connecting plate are arranged at two ends of the main body in a staggered mode, the height of the first connecting plate and the height of the second connecting plate are smaller than that of the groove, and the shortest vertical distance between the first connecting plate and the second connecting plate is larger than the length of the extrusion plate.

Specifically, the heat insulation mechanism comprises a first fixing plate, a heat insulation plate and a second fixing plate, and the first fixing plate, the heat insulation plate and the second fixing plate are connected to the inside of the main body in a sliding mode; the edge of the top surface of the first fixing plate is symmetrically and rotatably connected with the heat insulation plate, and the top end of the heat insulation plate is specifically elastic and rotatably connected with the bottom surface of the second fixing plate.

Specifically, the sliding mechanism comprises a second connecting rod, a sliding chute, a clamping groove, a ball and a bump, the second connecting rod is symmetrically installed at the edge of the bottom surface of the first fixing plate, and the clamping groove is formed in the bottom end of the second connecting rod; the inside of the clamping groove is connected with the ball in a rolling manner, the hemispherical convex blocks are symmetrically arranged inside the clamping groove, and the convex blocks are connected with the ball in a sliding manner; the lateral wall equidistance of main part is equipped with the spout, the inside sliding connection of spout the sealing rod, the inside sliding connection of spout first fixed plate the heated board the second fixed plate the second connecting rod with the ball.

Specifically, the widths of the first fixing plate and the second fixing plate are smaller than the width of the sliding chute, and the height of the sliding chute is larger than the sum of the height of the sliding mechanism and the height of the heat preservation mechanism.

Specifically, the extrusion mechanism comprises a first compression block, a support frame, a second compression block, a support rod and a pointed end, the support rod is connected between the two insulation boards and inside the chute in a sliding manner, and the spherical second compression blocks are symmetrically and equidistantly arranged at two ends of the support frame respectively; the supporting rod is fixedly connected to the middle of the side wall of the supporting frame, and the spherical first compression blocks are arranged on the side wall of the supporting rod at equal intervals; the first compression block and the second compression block are connected with the inner part of the insulation board in a sliding mode, and the diameter of the first compression block is larger than that of the second compression block; the tip is installed at one end of the supporting frame and one end of the supporting rod, and the conical tip is connected with the side wall of the heat-insulation plate in a sliding mode; the water conservancy diversion hole with the support frame intercommunication, first compression piece, support frame, second compression piece, bracing piece and tip are inside to be hollow structure, just be equipped with out the thick liquid mouth on first compression piece, the second compression piece and the tip.

Specifically, the support frame with the slope installation between the bracing piece the head rod, the head rod with the inside sliding connection of spout, just the length of spout is greater than the length of support frame with the length of heated board, just the length of heated board equals the length of first fixed plate with the second fixed plate.

The invention has the beneficial effects that:

according to the non-bearing wall insulating brick, the top surfaces of the main bodies and the ground are respectively provided with the installation mechanisms, when the two main bodies are spliced, cement mortar is placed on the top surface of one main body, the cement mortar is stored in the installation mechanism on the top surface of the main body, the other main body is placed on the top surface of the main body, the main body is extruded downwards, the installation mechanism on the bottom surface of the main body enters the installation mechanism on the top surface of the main body, the cement mortar is solidified to fix the two main bodies together, and the cement mortar is stored in the installation mechanism, so that the seepage amount of the cement mortar from the joint of the main bodies is reduced, the waste is reduced, and the firmness of the joint of the two main bodies is improved.

(2) According to the non-bearing wall insulating brick, the heat preservation mechanism is arranged inside the main body, the extrusion mechanism is connected inside the heat preservation mechanism in a sliding mode, the extrusion mechanism moves inside the heat preservation mechanism to enable the heat preservation mechanism to be spread inside the main body, the heat preservation mechanism is made to be tightly attached to the inside of the main body, the heat preservation mechanism is fixed inside the main body, the heat preservation performance of the main body is improved, when too much cement mortar is arranged inside the installation mechanism, the cement mortar extrudes the top end of the installation mechanism, components inside the installation mechanism enter the inside of the sliding mechanism, the cement mortar enters the inside of the heat preservation mechanism, the heat preservation mechanism is fixed again, and the cement mortar is prevented from leaking.

Drawings

The invention is further illustrated with reference to the following figures and examples.

FIG. 1 is a schematic structural view of a non-load-bearing wall insulating brick according to a preferred embodiment of the present invention;

FIG. 2 is a schematic structural view of the mounting mechanism shown in FIG. 1;

FIG. 3 is a cross-sectional view of the internal structure of the main body shown in FIG. 1;

FIG. 4 is a schematic view of the internal structure of the sliding mechanism shown in FIG. 2;

fig. 5 is a schematic structural view of the pressing mechanism shown in fig. 2.

In the figure: 1. the main part, 2, slide mechanism, 21, the second connecting rod, 22, the spout, 23, the draw-in groove, 24, the ball, 25, the lug, 3, installation mechanism, 31, first connecting plate, 32, the second connecting plate, 33, the recess, 34, the stripper plate, 35, the through-hole, 36, the sealing rod, 37, the water conservancy diversion hole, 4, heat preservation mechanism, 41, first fixed plate, 42, the heated board, 43, the second fixed plate, 5, the extrusion mechanism, 51, first compression piece, 52, the support frame, 53, the second compression piece, 54, the bracing piece, 55, the tip, 56, play thick liquid hole, 6, the first connecting rod.

Detailed Description

In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the invention easy to understand, the invention is further described with the specific embodiments.

As shown in fig. 1-5, the non-bearing wall insulating brick of the present invention comprises a main body 1, a sliding mechanism 2, an installation mechanism 3, an insulating mechanism 4, an extrusion mechanism 5 and a first connecting rod 6; the installation mechanism 3 for splicing the insulating bricks is installed on the top surface of the main body 1 and the ground, the heat insulation mechanism 4 for improving the heat insulation performance of the insulating bricks is installed in the main body 1, and the sliding mechanism 2 is installed at the joint of the heat insulation mechanism 4 and the main body 1; the interior of the heat preservation mechanism 4 is slidably connected with the extrusion mechanism 5, the interior of the extrusion mechanism 5 is obliquely provided with the first connecting rod 6 for increasing the stability of the extrusion mechanism 5, and the first connecting rod 6 is slidably connected with the interior of the main body 1; the main body 1 is provided with a diversion hole 37.

Specifically, the mounting mechanism 3 comprises a first connecting plate 31, a second connecting plate 32, a groove 33, a squeezing plate 34, a through hole 35 and a sealing rod 36, the groove 33 is formed in the top surface of the main body 1, and the second connecting plate 32 is mounted on the inner bottom surface of the groove 33 at equal intervals; the first connecting plates 31 are arranged on the bottom surface of the main body 1 at equal intervals, the extrusion plates 34 are vertically arranged on the side walls of the first connecting plates 31, and the through holes 35 are uniformly and respectively arranged on the top surfaces of the extrusion plates 34; the first connecting plate 31 and the pressing plate 34 are slidably connected with the inside of the groove 33, and the inside of the groove 33 is slidably connected with the sealing rod 36, so that cement mortar is conveniently put into the inside of the groove 33, the second connecting plate 32 fixes the cement mortar into the inside of the groove 33, and the first connecting plate 31 and the pressing plate 34 are put into the inside of the groove 33, so that the first connecting plate 31 and the pressing plate 34 are in contact with the cement mortar in the inside of the groove 33, the cement mortar penetrates through the through hole 35 of the side wall of the pressing plate 34, so that the pressing plate 35 is conveniently moved in the inside of the cement mortar, so that the first connecting plate 31 and the pressing plate 34 are fixed into the inside of the groove 33 by the cement mortar, thereby fixing the two bodies 1 together and into the inside of the groove 33, so as to prevent too much cement mortar from oozing out of the joint of the main body 1.

Specifically, first connecting plate 31 with second connecting plate 32 is in the setting of staggering at the both ends of main part 1, in order to prevent first connecting plate 31 with second connecting plate 32 contacts, first connecting plate 31 with the height of second connecting plate 32 is less than the height of recess 33, and it is convenient first connecting plate 31 gets into the inside of recess 33, just first connecting plate 31 with the shortest vertical distance between second connecting plate 32 is greater than the length of stripper plate 34, avoids stripper plate 34 with second connecting plate 32 contacts, and it is convenient stripper plate 34 is in the inside motion of recess 33.

Specifically, the heat insulation mechanism 4 includes a first fixing plate 41, a heat insulation plate 42 and a second fixing plate 43, and the inside of the main body 1 is slidably connected to the first fixing plate 41, the heat insulation plate 42 and the second fixing plate 43; the edge of the top surface of the first fixing plate 41 is symmetrically and rotatably connected with the heat insulation plate 42, the top end of the heat insulation plate 42 is rotatably connected with the bottom surface of the second fixing plate 43, and therefore the heat insulation performance of the main body 1 is improved in order to facilitate the first fixing plate 41, the heat insulation plate 42 and the second fixing plate 43 to enter the main body 1.

Specifically, the sliding mechanism 2 includes a second connecting rod 21, a sliding chute 22, a clamping groove 23, a ball 24 and a projection 25, the second connecting rod 21 is symmetrically installed at the bottom edge of the first fixing plate 41, and the clamping groove 23 is arranged inside the bottom end of the second connecting rod 21; the ball 24 is connected to the inside of the slot 23 in a rolling manner, the hemispherical convex blocks 25 are symmetrically arranged inside the slot 23, and the convex blocks 25 are connected with the ball 24 in a sliding manner; the lateral wall equidistance of main part 1 is equipped with spout 22, the inside sliding connection of spout 22 sealing rod 36, the inside sliding connection of spout 22 first fixed plate 41 the heated board 42 the second fixed plate 43 the second connecting rod 21 with ball 24 works as heat preservation mechanism 4 gets into during the inside of spout 22, first fixed plate 41 drives second connecting rod 21 is in the inside of spout 22 slides, second connecting rod 21 promotes ball 24 is in the inside roll of spout 22, and is convenient heat preservation mechanism 4 gets into the inside of spout 22 reduces heat preservation mechanism 4 with frictional force between the spout 22.

Specifically, the widths of the first fixing plate 41 and the second fixing plate 43 are smaller than the width of the chute 22, and the height of the chute 22 is larger than the sum of the height of the sliding mechanism 2 and the height of the heat preservation mechanism 4, so that the first fixing plate 41 and the second fixing plate 43 can conveniently enter the chute 22, and the heat preservation mechanism 4 can completely enter the main body 1.

Specifically, the extrusion mechanism 5 comprises a first compression block 51, a support frame 52, a second compression block 53, a support rod 54 and a pointed end 55, the support rod 54 is connected between the two insulation boards 42 and inside the chute 22 in a sliding manner, and the spherical second compression blocks 53 are respectively symmetrically and equidistantly mounted at two ends of the support frame 52; the supporting rod 54 is fixedly connected to the center of the side wall of the supporting frame 52, and the spherical first compression blocks 51 are installed on the side wall of the supporting rod 54 at equal intervals; the first compression block 51 and the second compression block 53 are connected with the inner part of the heat insulation plate 42 in a sliding mode, and the diameter of the first compression block 51 is larger than that of the second compression block 53; support frame 52 with the one end installation of bracing piece 54 tip 55, and conical tip 55 with the lateral wall sliding connection of heated board 42, in order to work as heated board 42 gets into completely when the inside of main part 1, the inside one end of spout 22 support frame 52, support frame 52 drives tip 55 gets into two between the heated board 42, tip 55 is conical, and is convenient tip 55 gets into two between the heated board 42, and along with the motion of support frame 52 makes bracing piece 54 first compression piece 51 with second compression piece 53 gets into two between the heated board 42, first compression piece 51 extrudees the inside residence of heated board 42, second compression piece 53 extrudees the inside bottom and the bottom of heated board 42 to make concrete elastic the both ends of heated board 42 are in respectively the top surface of first fixed plate 41 and the bottom surface of second fixed plate 43 change Moving to bend the side wall of the heat insulation board 42, and moving along with the first compression block 51 and the second compression block 53 to expand the heat insulation board 42 in the chute 22, wherein the heat insulation board 42 abuts against the inner side wall of the chute 22, so that the heat insulation board 42 is fixed in the chute 22 and the main body 1; the diversion hole 37 is communicated with the support frame 52, the first compression block 51, the support frame 52, the second compression block 53, the support rod 54 and the pointed end 55 are hollow, the first compression block 51, the second compression block 53 and the pointed end 55 are provided with slurry outlets 56, when the pressure of cement mortar between the main bodies 1 is less than 10Mpa, redundant cement mortar between the main bodies 1 flows into the extrusion mechanism 5 from the diversion hole 37, the mortar flows out from the extrusion mechanism 5, the stability of the inside is enhanced, when the pressure between the main bodies 1 is greater than 10MPA, the mortar between the main bodies 1 extrudes the sealing rod 36, the cement mortar enters the main bodies 1 from the sealing rod 36, and the connection between the main bodies 1 is more stable.

Specifically, the first connecting rod 6 is obliquely installed between the supporting frame 52 and the supporting rod 54, the first connecting rod 6 is slidably connected with the inside of the sliding groove 22, in order to increase the stability between the supporting rod 54 and the supporting frame 52, the supporting frame 52 and the supporting rod 54 conveniently enter the inside of the heat insulation board 42, the length of the sliding groove 22 is greater than the length of the supporting frame 52 and the length of the heat insulation board 42, the length of the heat insulation board 42 is equal to the length of the first fixing plate 41 and the length of the second fixing plate 43, and the first fixing plate 41, the supporting frame 52, the heat insulation board 42 and the second fixing plate 43 completely enter the sliding groove 22 and the inside of the main body 1 in order to facilitate the first fixing plate 41, the supporting frame 52, the heat insulation board 42 and the second fixing plate 43.

When the heat insulation mechanism is used, the first fixing plate 41, the heat insulation plate 42 and the second fixing plate 43 slide into the sliding groove 22, when the first fixing plate 41 slides in the sliding groove 22, the first fixing plate 41 drives the second connecting rod 21 to slide in the sliding groove 22, the second connecting rod 21 pushes the balls 24 to roll in the sliding groove 22, the friction force between the heat insulation mechanism 4 and the sliding groove 22 is reduced, the widths of the first fixing plate 41 and the second fixing plate 43 are smaller than the width of the sliding groove 22, the height of the sliding groove 22 is larger than the sum of the height of the sliding mechanism 2 and the height of the heat insulation mechanism 4, and the heat insulation mechanism 4 conveniently enters the sliding groove 22. Work as heat preservation mechanism 4 gets into completely during the inside of spout 22 the inside one end of spout 22 support frame 52, support frame 52 drives tip 55 gets into two between the heated board 42, tip 55 is conical, and is convenient tip 55 gets into two between the heated board 42, and along with support frame 52's motion makes the bracing piece 54 first compression piece 51 with second compression piece 53 gets into two between the heated board 42, a plurality of orbs first compression piece 51 extrudees the inside of heated board 42 is located, a plurality of orbs second compression piece 53 extrudees the inside bottom and the bottom of heated board 42, just the diameter of first compression piece 51 is greater than between second compression piece 53, the inside wall of heated board 42 is extruded, thereby makes specific elasticity the both ends of heated board 42 are in respectively the top surface of first fixed plate 41 with the end of second fixed plate 43 The surface rotates to bend the side wall of the heat insulation board 42, and the heat insulation board 42 is stretched in the sliding groove 22 along with the movement of the first compression block 51 and the second compression block 53, and the heat insulation board 42 is abutted against and tightly attached to the inner side wall of the sliding groove 22, so that the heat insulation board 42 is fixed in the sliding groove 22 and the main body 1. When the main bodies 1 need to be used, cement mortar is put into the top surface of one main body 1, the cement mortar is put into the inside of the groove 33, the second connecting plate 32 fixes the cement mortar in the inside of the groove 33, then the other main body 1 is put into the top surface of the main body 1, the first connecting plate 31 and the extrusion plate 34 are put into the inside of the groove 33 by the other main body 1, the first connecting plate 31 and the extrusion plate 34 are in contact with the cement mortar in the inside of the groove 33, the cement mortar penetrates through the through hole 35 on the side wall of the extrusion plate 34, the extrusion plate 35 is convenient to move in the inside of the cement mortar, and after the cement mortar is solidified, the cement mortar fixes the first connecting plate 31 and the extrusion plate 34 in the inside of the groove 33, so that the two main bodies 1 are fixed together and the cement mortar is fixed in the inside of the groove 33, and when the cement mortar in the groove 33 is too much, the cement mortar extrudes the sealing rod 36, so that the sealing rod 36 slides into the chute 22, the chute 22 is communicated with the groove 33, the excess cement mortar in the groove 33 enters the chute 22, the cement mortar is contacted with the heat-insulating plate 42, the heat-insulating plate 42 is fixed in the chute 22 again, too much cement mortar is prevented from seeping out from the joint of the main body 1, the waste of the cement mortar is reduced, most of the cement mortar is positioned between the two main bodies 1, and the stability of the joint of the two main bodies 1 is improved.

The foregoing illustrates and describes the principles, general features, and advantages of the present invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, and the embodiments and descriptions given above are only illustrative of the principles of the present invention, and various changes and modifications may be made without departing from the spirit and scope of the invention, which fall within the scope of the claims. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims

1. The utility model provides a non-bearing wall insulating brick which characterized in that: comprises a main body (1), a sliding mechanism (2), an installation mechanism (3), a heat preservation mechanism (4), an extrusion mechanism (5) and a first connecting rod (6); the installation mechanism (3) for splicing the insulating bricks is installed on the top surface of the main body (1) and the ground, the heat insulation mechanism (4) for improving the heat insulation performance of the insulating bricks is installed in the main body (1), and the sliding mechanism (2) is installed at the joint of the heat insulation mechanism (4) and the main body (1); the interior of the heat preservation mechanism (4) is connected with the extrusion mechanism (5) in a sliding manner, the interior of the extrusion mechanism (5) is obliquely provided with the first connecting rod (6) for increasing the stability of the extrusion mechanism (5), and the first connecting rod (6) is connected with the interior of the main body (1) in a sliding manner; the main body (1) is provided with a flow guide hole (37);

the mounting mechanism (3) comprises a first connecting plate (31), a second connecting plate (32), grooves (33), an extrusion plate (34), through holes (35) and sealing rods (36), the grooves (33) are formed in the top surface of the main body (1), and the second connecting plates (32) are mounted on the inner bottom surface of the grooves (33) at equal intervals; the bottom surface of the main body (1) is provided with the first connecting plates (31) at equal intervals, the side walls of the first connecting plates (31) are vertically provided with the extrusion plates (34), and the top surfaces of the extrusion plates (34) are provided with the through holes (35) uniformly and respectively; the first connecting plate (31) and the pressing plate (34) are slidably connected with the inner part of the groove (33), and the inner part of the groove (33) is slidably connected with the sealing rod (36);

the heat insulation mechanism (4) comprises a first fixing plate (41), a heat insulation plate (42) and a second fixing plate (43), and the first fixing plate (41), the heat insulation plate (42) and the second fixing plate (43) are connected to the inside of the main body (1) in a sliding mode; the edge of the top surface of the first fixing plate (41) is symmetrically and rotatably connected with the heat insulation plate (42), and the top end of the elastic heat insulation plate (42) is rotatably connected with the bottom surface of the second fixing plate (43);

the sliding mechanism (2) comprises a second connecting rod (21), a sliding groove (22), a clamping groove (23), a ball (24) and a bump (25), the second connecting rod (21) is symmetrically installed at the edge of the bottom surface of the first fixing plate (41), and the clamping groove (23) is formed in the bottom end of the second connecting rod (21); the ball (24) is connected to the inside of the clamping groove (23) in a rolling manner, the hemispherical bumps (25) are symmetrically arranged inside the clamping groove (23), and the bumps (25) are connected with the ball (24) in a sliding manner; the sliding grooves (22) are equidistantly arranged on the side wall of the main body (1), the sealing rods (36) are connected to the top ends of the sliding grooves (22) in a sliding mode, and the first fixing plate (41), the heat insulation plate (42), the second fixing plate (43), the second connecting rod (21) and the balls (24) are connected to the inside of the sliding grooves (22) in a sliding mode;

the extrusion mechanism (5) comprises a first compression block (51), a support frame (52), a second compression block (53), a support rod (54) and a pointed end (55), the support rod (54) is connected between the two insulation boards (42) and inside the sliding chute (22) in a sliding mode, and the two ends of the support frame (52) are respectively provided with the spherical second compression blocks (53) symmetrically and equidistantly; the middle part of the side wall of the support frame (52) is fixedly connected with the support rod (54), and the spherical first compression blocks (51) are arranged on the side wall of the support rod (54) at equal intervals; the first compression block (51) and the second compression block (53) are connected with the inner part of the heat insulation plate (42) in a sliding mode, and the diameter of the first compression block (51) is larger than that of the second compression block (53); the pointed head (55) is installed at one end of the support frame (52) and one end of the support rod (54), the conical pointed head (55) is in sliding connection with the side wall of the heat insulation plate (42), the flow guide hole (37) is communicated with the support frame (52), the first compression block (51), the support frame (52), the second compression block (53), the support rod (54) and the pointed head (55) are of hollow structures, and slurry outlets (56) are formed in the first compression block (51), the second compression block (53) and the pointed head (55);

the first connecting rod (6) is obliquely installed between the supporting frame (52) and the supporting rod (54), the first connecting rod (6) is in sliding connection with the inner portion of the sliding groove (22), the length of the sliding groove (22) is larger than that of the supporting frame (52) and that of the heat insulation plate (42), and the length of the heat insulation plate (42) is equal to that of the first fixing plate (41) and that of the second fixing plate (43).

2. A non-load bearing wall insulating brick according to claim 1, wherein: the first connecting plate (31) and the second connecting plate (32) are arranged at two ends of the main body (1) in a staggered mode, the height of the first connecting plate (31) and the height of the second connecting plate (32) are smaller than that of the groove (33), and the shortest vertical distance between the first connecting plate (31) and the second connecting plate (32) is larger than the length of the extrusion plate (34).

3. A non-load bearing wall insulating brick according to claim 1, wherein: the width of the first fixing plate (41) and the width of the second fixing plate (43) are smaller than the width of the sliding chute (22), and the height of the sliding chute (22) is larger than the sum of the height of the sliding mechanism (2) and the height of the heat preservation mechanism (4).