CN216516254U - Inorganic vitrified micro bubble thermal insulation mortar external wall thermal insulation structure - Google Patents

Abstract

The utility model relates to the technical field of heat-insulating mortar external wall heat-insulating structures, in particular to an inorganic vitrified micro-bead heat-insulating mortar external wall heat-insulating structure which comprises a wall body, wherein a plurality of mounting holes are formed in the wall body, connecting pieces with fixing and guiding functions are arranged in the mounting holes, and the connecting pieces are connected with a heat-insulating plate; make the screw rod rotate through the hexagonal spanner, the rotation of screw rod makes the clamp plate remove along the slide bar to further extrude the spring, make the bounce-back grow of spring, thereby make the power of card key block roller bigger, make the heated board inseparabler with the face laminating of wall body, then pour into the heat preservation mortar to the guide way inslot, the heat preservation mortar flows into the cross slot through the guide way in, treats that warm mortar solidifies the back, makes heated board and wall body fixed more firm.

Description

Inorganic vitrified micro bubble thermal insulation mortar external wall thermal insulation structure

Technical Field

The utility model relates to the technical field of heat-insulating mortar external wall heat-insulating structures, in particular to an inorganic vitrified micro bubble heat-insulating mortar external wall heat-insulating structure.

Background

At present, requirements for saving energy and protecting the environment are continuously improved, building energy conservation becomes an important link for improving the energy utilization efficiency of the whole society, building materials and building heat insulation structures are the most basic leaps for realizing building energy conservation, the most widely applied outer wall heat insulation mode at present is outer wall heat insulation, an adhesive layer, a heat insulation plate and the like are mainly coated on the surface of an outer wall in sequence, and the heat insulation plate is manufactured by pouring inorganic vitrified micro-bead heat insulation mortar on a steel bar net.

In order to increase the connection strength between the heat-insulating plate and the reinforcing body, a large number of additional connecting pieces are usually needed to further connect the heat-insulating plate and the wall body, and the installation is complicated.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide an inorganic vitrified micro bubble thermal insulation mortar external wall thermal insulation structure to solve the problems in the background technology.

In order to achieve the purpose, the utility model provides the following technical scheme: the inorganic vitrified micro bubble thermal insulation mortar outer wall thermal insulation structure comprises a wall body, wherein a plurality of mounting holes are formed in the wall body, connecting pieces with fixing and guiding functions are arranged in the mounting holes, and the connecting pieces are connected with a thermal insulation board;

the connecting piece includes the casing, sets up the screw rod in the casing, screw rod spiro union clamp plate, two sets of slide bars of clamp plate sliding connection, and the spring is established to the cover on the slide bar, and the board is accepted to the equal sliding connection L type of two sets of slide bars, and the board one end fixed connection card key is accepted to the L type.

Preferably, the heated board includes the heated board main part, and heated board main part one side symmetry sets up two sets of guide ways, sets up two sets of rollers in the guide way, and the equidistance sets up three transverse grooves of group between two sets of guide ways.

Preferably, the shell is fixed in the mounting hole, one end of the shell is provided with a rectangular guide hole, and the rectangular guide hole is connected with the L-shaped bearing plate in a sliding mode.

Preferably, one end of the screw is provided with a bearing, and the bearing is embedded in the inner wall of the shell.

Preferably, the slide bar is slidably connected with two groups of upright bearings, one group of upright bearings is embedded into the pressure plate, and the other group of upright bearings is embedded into the L-shaped bearing plate.

Preferably, the width of the guide groove is equal to the width of the clamping key, and the guide groove is connected with the clamping key in a sliding mode.

Preferably, the transverse groove is communicated with the guide groove, two groups of bearings are symmetrically arranged at two ends of the roller, and the bearings are embedded into the insulation board main body.

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

1. the two groups of guide grooves on the heat insulation board are completely fit with the four groups of clamping keys, then the heat insulation board slides downwards along the wall surface under the matching of the guide grooves and the clamping keys until the rollers contact the end parts of the clamping keys, the heat insulation board is pressed at the moment to enable the rollers to extrude the end parts of the clamping keys, the clamping keys pull the L-shaped bearing plates, the L-shaped bearing plates move along the sliding rods and compress the springs until the rollers slide into the inner sides of the clamping keys, and the rollers are clamped with the clamping keys under the action of the rebound force of the springs, so that the heat insulation board is pre-fixed;

2. make the screw rod rotate through the hexagonal spanner, the rotation of screw rod makes the clamp plate remove along the slide bar to further extrude the spring, make the bounce-back grow of spring, thereby make the power of card key block roller bigger, make the heated board inseparabler with the face laminating of wall body, then pour into the heat preservation mortar to the guide way inslot, the heat preservation mortar flows into the cross slot through the guide way in, treats that warm mortar solidifies the back, makes heated board and wall body fixed more firm.

Drawings

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

FIG. 2 is a partial sectional view of the combination of the structural insulation board and the connecting member of the present invention;

fig. 3 is an enlarged view of a portion a in fig. 2.

In the figure: 1. a wall body; 2. mounting holes; 3. a thermal insulation board; 4. a connecting member; 301. a heat insulation board main body; 302. a guide groove; 303. a transverse groove; 304. a roller; 401. a housing; 402. a screw; 403. pressing a plate; 404. a slide bar; 405. a spring; 406. an L-shaped bearing plate; 407. and (6) a card key.

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 to 3, the present invention provides a technical solution: an inorganic vitrified micro bubble thermal insulation mortar exterior wall thermal insulation structure comprises a wall body 1, wherein a plurality of mounting holes 2 are formed in the wall body 1, connecting pieces 4 with fixing and guiding functions are arranged in the mounting holes 2, the connecting pieces 4 are connected with a thermal insulation board 3, the thermal insulation board 3 comprises a thermal insulation board main body 301, two groups of guide grooves 302 are symmetrically arranged on one side of the thermal insulation board main body 301, two groups of rollers 304 are arranged in the guide grooves 302, three groups of transverse grooves 303 are equidistantly arranged between the two groups of guide grooves 302, the groove width of the guide grooves 302 is equal to the width of a clamping key 407, the guide grooves 302 are slidably connected with the clamping key 407, the transverse grooves 303 are communicated with the guide grooves 302, two groups of bearings are symmetrically arranged at two ends of the rollers 304, and the bearings are embedded in the thermal insulation board main body 301; the end parts of the clamping keys 407 are provided with chamfer angles, when the heat insulation board 3 needs to be installed, two groups of guide grooves 302 on the heat insulation board 3 are completely matched with four groups of clamping keys 407, then the heat insulation board 3 slides downwards along the surface of the wall body 1 under the matching of the guide grooves 302 and the clamping keys 407 until the roller 304 contacts the end parts of the clamping keys 407, at the moment, the heat insulation board 3 is pressed to enable the roller 304 to extrude the end parts of the clamping keys 407, the clamping keys 407 pull the L-shaped bearing plates 406, the L-shaped bearing plates 406 move along the sliding rods 404 and compress the springs 405 until the roller 304 slides into the inner sides of the clamping keys 407, and under the action of the counter-elastic force of the springs 405, the clamping of the roller 304 and the clamping keys 407 is realized, so that the heat insulation board 3 is pre-fixed, and then the matching setting of the guide grooves 302 and the clamping keys 407 is realized for installing and fixing the heat insulation board 3 to play a role in guiding and positioning;

the connecting piece 4 comprises a shell 401, a screw 402 is arranged in the shell 401, the screw 402 is screwed with a pressing plate 403, the pressing plate 403 is connected with two groups of sliding rods 404 in a sliding manner, a spring 405 is sleeved on each sliding rod 404, each group of sliding rods 404 is connected with an L-shaped bearing plate 406 in a sliding manner, one end of each L-shaped bearing plate 406 is fixedly connected with a clamping key 407, the shell 401 is fixed in the mounting hole 2, one end of the shell 401 is provided with a rectangular guide hole which is connected with the L-shaped bearing plate 406 in a sliding manner, one end of the screw 402 is provided with a bearing, the bearing is embedded in the inner wall of the shell 401, the sliding rods 404 are connected with two groups of vertical bearings in a sliding manner, one group of vertical bearings is embedded into the pressing plate 403, the other group of vertical bearings is embedded into the L-shaped bearing plate 406, a hole is arranged in the other end of the screw 402 and can be rotated by a hexagonal wrench, after the heat insulation board 3 is pre-fixed, the screw 402 is rotated by the hexagonal wrench, the rotation of the screw 402 enables the pressing plate 403 to move along the sliding rods 404, and further extrude spring 405, make the bounce-back force of spring 405 grow to make the power of card key 407 block roller 304 bigger, make the face laminating of heated board 3 and wall body 1 inseparabler, then pour into the heat preservation mortar into guide way 302, the heat preservation mortar flows into the cross slot 303 through guide way 302, after the temperature mortar solidifies, makes heated board 3 and wall body 1 fixed more firm.

The working principle is as follows: in the using process, the two groups of guide grooves 302 on the heat insulation board 3 are completely matched with the four groups of clamping keys 407, then under the matching of the guide grooves 302 and the clamping keys 407, the heat insulation board 3 is enabled to slide downwards along the surface of the wall body 1 until the rollers 304 contact the end parts of the clamping keys 407, at the moment, the heat insulation board 3 is pressed to enable the rollers 304 to extrude the end parts of the clamping keys 407, the clamping keys 407 pull the L-shaped bearing plates 406, the L-shaped bearing plates 406 move along the sliding rods 404, the springs 405 are compressed until the rollers 304 slide into the inner sides of the clamping keys 407, the screws 402 are rotated through the hexagonal wrench, after the heat insulation board 3 is pre-fixed, the screws 402 are rotated through the hexagonal wrench, the pressing plates are enabled to move along the sliding rods 404 through the rotation of the screws 402, the springs 405 are further extruded, then, heat insulation mortar is poured into the guide grooves 302, the heat insulation mortar flows into the transverse grooves 403 through the guide grooves 302, and the heat insulation mortar is solidified after the warm mortar is solidified.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. Inorganic glass bead heat preservation mortar outer wall insulation structure, including wall body (1), set up a plurality of mounting holes (2) on wall body (1), its characterized in that: a connecting piece (4) with fixing and guiding functions is arranged in the mounting hole (2), and the connecting piece (4) is connected with the heat-insulating plate (3);

the connecting piece (4) comprises a shell (401), a screw rod (402) is arranged in the shell (401), the screw rod (402) is in threaded connection with a pressing plate (403), the pressing plate (403) is in sliding connection with two sets of sliding rods (404), a spring (405) is sleeved on each sliding rod (404), the two sets of sliding rods (404) are in sliding connection with an L-shaped bearing plate (406), and one end of the L-shaped bearing plate (406) is fixedly connected with a clamping key (407).

2. The inorganic vitrified small ball thermal insulation mortar external wall thermal insulation structure according to claim 1, which is characterized in that: the heat-insulating plate (3) comprises a heat-insulating plate main body (301), two groups of guide grooves (302) are symmetrically arranged on one side of the heat-insulating plate main body (301), two groups of rollers (304) are arranged in the guide grooves (302), and three groups of transverse grooves (303) are arranged between the guide grooves (302) at equal intervals.

3. The inorganic vitrified small ball thermal insulation mortar external wall thermal insulation structure according to claim 1, which is characterized in that: the shell (401) is fixed in the mounting hole (2), a rectangular guide hole is formed in one end of the shell (401), and the rectangular guide hole is connected with the L-shaped bearing plate (406) in a sliding mode.

4. The inorganic vitrified small ball thermal insulation mortar external wall thermal insulation structure according to claim 1, which is characterized in that: and one end of the screw rod (402) is provided with a bearing, and the bearing is embedded into the inner wall of the shell (401).

5. The inorganic vitrified small ball thermal insulation mortar external wall thermal insulation structure according to claim 1, which is characterized in that: the sliding rod (404) is connected with two groups of vertical bearings in a sliding mode, one group of vertical bearings are embedded into the pressing plate (403), and the other group of vertical bearings are embedded into the L-shaped bearing plate (406).

6. The inorganic vitrified small ball thermal insulation mortar outer wall thermal insulation structure according to claim 2, characterized in that: the width of the guide groove (302) is equal to the width of the clamping key (407), and the guide groove (302) is connected with the clamping key (407) in a sliding mode.

7. The inorganic vitrified small ball thermal insulation mortar outer wall thermal insulation structure according to claim 2, characterized in that: the transverse groove (303) is communicated with the guide groove (302), two groups of bearings are symmetrically arranged at two ends of the roller (304), and the bearings are embedded into the heat insulation board main body (301).

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