CN217759531U - Energy-saving weight-reducing type sintered perforated brick - Google Patents

Abstract

The utility model discloses an energy-saving and weight-reducing type sintered perforated brick, which comprises a brick body, wherein a clamping frame is fixedly connected with the left side of the brick body, a clamping groove is formed in the right side of the brick body, a rectangular hole is formed in the surface of the brick body, a heat preservation strip is bonded in the rectangular hole, a transverse groove is formed in the surface of the brick body, a flocculus is filled in the transverse groove, a convex block a extends outwards from the top end of the brick body, a convex block b extends outwards from the bottom end of the brick body, a groove a is formed in the top end of the brick body, a groove b is formed in the bottom end of the brick body, heat storage paint is coated on the surface of the brick body, and the flocculus, the heat preservation strip and the heat storage paint are matched to improve the heat preservation capability of the whole sintered perforated brick; the clamping frame, the clamping groove, the convex block and the groove are matched, so that the adjacent sintered perforated bricks can be conveniently installed and positioned.

Description

Energy-saving and weight-reducing type sintered perforated brick

Technical Field

The utility model relates to an energy-conservation subtracts weight type sintering perforated brick specifically is energy-conservation subtracts weight type sintering perforated brick, belongs to sintering perforated brick technical field.

Background

The sintered porous brick is made up by using clay, shale, coal gangue, flyash, silt (river and lake silt) and other solid wastes as main raw materials through the processes of roasting, and is mainly used for bearing portion of building.

The prior art sintered perforated bricks have the following disadvantages: 1. the existing sintered porous bricks have poor heat insulation performance, and when an air conditioner is turned on in summer or winter, the whole building can quickly dissipate heat, so that electric power is wasted; 2. the bricks are easy to skew in the process of stacking the sintered porous bricks, and need to be pushed down for reconstruction, and the construction speed is slow, so that the problems are improved.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the problems and provide an energy-saving and weight-reducing type sintered perforated brick, wherein the flocculus, the heat preservation strip and the heat storage coating are matched to improve the overall heat preservation capacity of the sintered perforated brick; the clamping frame, the clamping groove, the convex block and the groove are matched, so that the adjacent sintered perforated bricks can be conveniently installed and positioned.

The utility model discloses a following technical scheme realizes above-mentioned purpose, and energy-conserving weight reduction type sintering perforated brick, including the brick body, brick body left side fixedly connected with card frame, the draw-in groove has been seted up on brick body right side, the rectangular hole has been seted up on brick body surface, it has the heat preservation strip to bond in the rectangular hole, horizontal groove has been seted up on brick body surface, the horizontal inslot is filled with the flocculus, the outside extension in brick body top has lug an, the outside extension in brick body bottom has lug b, recess an has been seted up on brick body top, recess b has been seted up to brick body bottom, brick body surface coats and has the heat accumulation coating.

Preferably, the clamping frame is connected with a clamping groove in a sliding mode and is of a Y-shaped structure.

Preferably, the surface of the brick body is provided with through holes, and the rectangular holes are positioned on two sides of the through holes.

Preferably, anti-skidding grooves are formed in two ends of the brick body, and the groove a is located on the left side of the convex block a.

Preferably, the groove b is located on the right side of the bump b, and the groove a is located above the bump b.

Preferably, the bump a is located above the groove b, and the flocculus is made of hollow fibers.

Preferably, the rectangular hole is located on the outer side of the transverse groove, and the heat preservation strip is made of aluminum silicate fibers.

The beneficial effects of the utility model are that:

1. the flocculus, the heat preservation bar and the heat storage coating are matched to improve the overall heat preservation capacity of the sintered perforated brick; many transverse grooves have transversely been seted up on the brick surface, the transverse groove intussuseption is filled with the material and is hollow fiber's flocculus, contain a large amount of still air in the hollow fiber, the overall mass is lighter, better heat preservation effect has, it has the material to be aluminium silicate fiber's heat preservation strip to bond in a plurality of rectangular holes that the brick was seted up simultaneously, the heat preservation strip has the thermal conductivity rate low, the thermal expansion is little and good heat-proof quality, can hinder indoor heat outwards transmission, play better heat preservation ability, and brick surface coating has the heat storage coating, mix in the heat storage coating has the phase transition microcapsule, the heat storage material phase transition microcapsule stores after can absorbing indoor heat, thereby release and adjust indoor temperature after indoor temperature is lower, thereby with the flocculus, the cooperation of heat preservation strip plays heat preservation energy saving effect.

2. The clamping frame, the clamping groove, the convex block and the groove are matched, so that the adjacent sintered perforated bricks can be conveniently installed and positioned; when the sintered porous bricks are stacked, the brick body B is taken up to enable the position of a clamping frame on the brick body B to correspond to the position of a clamping groove formed in the right side of the brick body A, the brick body B is moved downwards to enable the clamping frame to be gradually moved downwards to be inserted into the clamping groove formed in the brick body A, the clamping frame is of a Y-shaped structure, the connection effect between the brick body A is good, after the clamping frame on the brick body B is completely inserted into the clamping groove formed in the right side of the brick body A, the brick body B is attached to the brick body A and does not shake forwards or backwards, the transverse stacking of the sintered porous bricks can be facilitated, when the multilayer sintered porous bricks are required to be stacked, the brick body B is taken up to move backwards, the brick body B is gradually moved backwards to be close to the rear brick body A, after the brick body B is continuously moved backwards, a convex block a extending outwards is inserted into a groove B formed in the brick body A, meanwhile, the convex block B extending outwards from the brick body A is inserted into a groove a formed in the brick body B, the groove a after the brick body A and the brick body B are attached to be tightly, the groove B, the groove between the brick body is not prone to shake, the brick body, the clamping frame can be positioned, the adjacent brick can be conveniently, and the brick can be positioned between the adjacent porous bricks conveniently.

Drawings

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

FIG. 2 is a schematic view of a cross-sectional structure of the brick body of the present invention;

fig. 3 is a top view of the brick body of the present invention.

In the figure: 1. a brick body; 2. a transverse groove; 3. a rectangular hole; 4. a heat-insulating strip; 5. a bump a; 6. a card slot; 7. flocculus; 8. a bump b; 9. a clamping frame; 10. a groove a; 11. a through hole; 12. an anti-slip groove; 13. a groove b; 14. a heat storage coating.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts all belong to the protection scope of the present invention.

Example 1: referring to fig. 1-3, the energy-saving and weight-reducing type sintered perforated brick comprises a brick body 1, and is characterized in that: 1 left side fixedly connected with card frame 9 of the brick body, brick body 1 is through card frame 9 and another brick body coupling, draw-in groove 6 has been seted up to 1 right side of the brick body, draw-in groove 6 is unanimous with card frame 9 shape, rectangular hole 3 has been seted up on the 1 surface of the brick body, and the rectangular hole 3 of seting up on the brick body 1 can make things convenient for the while of 4 installations of heat preservation strip to alleviate 1 whole weight of the brick body, it has heat preservation strip 4 to bond in the rectangular hole 3, horizontal groove 2 has been seted up on the 1 surface of the brick body, 2 intussuseptions of horizontal groove are filled with flocculus 7, and horizontal groove 2 that the brick body 1 was seted up can make things convenient for the installation of flocculus 7, the outside extension in 1 top of the brick body has lug an 5, the outside extension in 1 bottom of the brick body has lug B8, and the lug an a5 inserts in the recess B13 that brick body B seted up on the brick body A, and the recess a10 that brick body A went up was inserted brick body B simultaneously, 1 top is seted up fluted a10, the recess B13 is seted up in the heat accumulation coating 14, the microcapsule mixes in the microcapsule phase transition microcapsule.

Specifically, through-hole 11 has been seted up on brick body 1 surface, rectangular hole 3 is located the both sides of through-hole 11, and through-hole 11 is located between two vertical rectangular holes 3.

Specifically, the brick body 1 is provided with anti-slip grooves 12 at two ends, the anti-slip grooves 12 formed in the brick body 1 can play an anti-slip role, and the groove a10 is located on the left side of the projection a 5.

Specifically, the groove b13 is located on the right side of the bump b8, the groove b13 has the same shape as the bump b8, the groove a10 is located above the bump b8, and the groove a10 corresponds to the bump b 8.

Particularly, lug a5 is located the top of recess b13, and lug a5 corresponds with recess b13 position, can make things convenient for and install between the adjacent brick body, the material of flocculus 7 is hollow fiber, and flocculus 7 has better heat preservation ability.

Specifically, rectangular hole 3 is located the outside of horizontal groove 2, and horizontal groove 2 is located between two adjacent rectangular hole 3, the material of heat preservation strip 4 is aluminium silicate fiber, and heat preservation strip 4 has better thermal-insulated heat preservation ability.

Example 2: referring to fig. 1, the difference between the present embodiment and embodiment 1 is: the card frame 9 sliding connection has draw-in groove 6, and the brick body A goes up card frame 9 and can follow brick body B and go up draw-in groove 6 and slide and be connected with brick body B, card frame 9 is Y type structure, and the buckle nature of card frame 9 is good, difficult separation.

When the utility model is used for piling up the sintered perforated bricks, the brick body B is taken up to lead the position of the clamping frame 9 on the brick body B to correspond to the position of the clamping groove 6 arranged at the right side of the brick body A, the brick body B is moved downwards to lead the clamping frame 9 to be gradually moved downwards to be inserted into the clamping groove 6 on the brick body A, the clamping frame 9 is in a Y-shaped structure, the connection effect with the brick body A is good, after the clamping frame 9 on the brick body B is completely inserted into the clamping groove 6 on the right side of the brick body A, the brick body B is attached to the brick body A and does not shake forwards and backwards, can facilitate the transverse stacking of the sintered perforated bricks, when a plurality of layers of sintered perforated bricks are required to be stacked, the brick body B is taken up to move backwards, the brick body B gradually moves backwards to be close to the rear brick body A, the lug a5 extending outwards on the brick body B after continuous backward movement is inserted into the groove B13 arranged on the brick body A, meanwhile, a convex block B8 extending outwards from the brick body A is inserted into a groove a10 formed in the brick body B, the convex blocks are inserted into the grooves after the brick body A and the brick body B are tightly attached, the brick body 1 is not easy to shake up and down, a plurality of transverse grooves 2 are transversely formed in the surface of the brick body 1, flocculus 7 made of hollow fibers are filled in the transverse grooves 2, a large amount of static air is contained in the hollow fibers, the whole weight is light, and the brick has a good heat preservation effect, meanwhile, heat preservation strips 4 made of aluminum silicate fibers are bonded in a plurality of rectangular holes 3 formed in the brick body 1, the heat preservation strips 4 have low heat conductivity, small thermal expansion and excellent heat insulation performance, can block the indoor heat from transferring outwards, has better heat preservation capability, the surface of the brick body 1 is coated with heat storage coating 14, phase change microcapsules are mixed in the heat storage coating 14, the heat storage material phase change microcapsules can absorb the indoor heat and then store the indoor heat, and releasing the heat-insulating material after the indoor temperature is lower so as to adjust the indoor temperature, so that the heat-insulating material is matched with the flocculus 7 and the heat-insulating strip 4 to play a role in heat insulation and energy conservation.

It is obvious to a person skilled in the art that the invention is not restricted to details of the above-described exemplary embodiments, but that it can be implemented in other specific forms without departing from the spirit or essential characteristics of the invention. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (7)

1. Energy-conserving type of subtracting sintering perforated brick, including the brick body (1), its characterized in that: brick body (1) left side fixedly connected with card frame (9), draw-in groove (6) have been seted up on the brick body (1) right side, rectangular hole (3) have been seted up on the brick body (1) surface, rectangular hole (3) internal bonding has heat preservation strip (4), horizontal groove (2) have been seted up on the brick body (1) surface, the intussuseption of horizontal groove (2) is filled with flocculus (7), the outside extension in brick body (1) top has lug an (5), the outside extension in brick body (1) bottom has lug b (8), recess an (10) have been seted up on brick body (1) top, recess b (13) have been seted up in brick body (1) bottom, brick body (1) surface coating has heat accumulation coating (14).

2. The energy-saving and weight-reducing sintered perforated brick according to claim 1, wherein: the clamping frame (9) is connected with a clamping groove (6) in a sliding mode, and the clamping frame (9) is of a Y-shaped structure.

3. The energy-saving and weight-reducing sintered perforated brick according to claim 1, wherein: through-hole (11) have been seted up on brick body (1) surface, rectangular hole (3) are located the both sides of through-hole (11).

4. The energy-saving and weight-reducing sintered perforated brick according to claim 1, wherein: anti-skidding grooves (12) are formed in two ends of the brick body (1), and the groove a (10) is located on the left side of the protruding block a (5).

5. The energy-saving and weight-reducing sintered perforated brick according to claim 1, wherein: the groove b (13) is positioned at the right side of the lug b (8), and the groove a (10) is positioned above the lug b (8).

6. The energy-saving and weight-reducing sintered perforated brick according to claim 1, wherein: the bump a (5) is positioned above the groove b (13), and the flocculus (7) is made of hollow fibers.

7. The energy-saving and weight-reducing sintered perforated brick according to claim 1, wherein: the rectangular holes (3) are located on the outer side of the transverse groove (2), and the heat preservation strips (4) are made of aluminum silicate fibers.

Images