CN213741873U - Energy-saving building heat-insulation building block - Google Patents

Abstract

The utility model discloses an energy-conserving building insulation block, including first heat preservation piece, heat preservation mechanism and dehumidification mechanism, heat preservation mechanism installs at first heat preservation piece inboardly, the silica gel board is installed to first heat preservation piece lateral wall, the spout has all been seted up to first heat preservation piece lateral wall, and the spout inboard is provided with the connecting block, the draw-in groove has all been seted up to first heat preservation piece outside below, and the draw-in groove inboard is provided with the fixture block, and fixture block outside below is connected with the dead lever simultaneously, the dead lever lateral wall is provided with the gim peg, and the dead lever inboard has seted up the activity groove, and the activity inslot side is provided with the movable rod simultaneously. The utility model discloses a dead lever, activity groove and the movable rod that set up like this and can cooperate the convenient adjustment second heat preservation piece of activity structure in activity groove and the interval between the first heat preservation piece through the movable rod, can adjust the device's thickness as required, the effectual controllability that improves the device.

Description

Energy-saving building heat-insulation building block

Technical Field

The utility model relates to an energy-conserving building correlation technique field especially relates to energy-conserving building insulation block.

Background

The energy-saving building is a basic method following climate design and energy saving, after researching building planning subareas, groups and monomers, building orientation, space, solar radiation, wind direction and external space environment, the designed low-energy-consumption building has the main indexes that the building planning and plane layout are favorable for natural ventilation, the greening rate is not lower than 35%, the building space is ensured to ensure that at least one living space of each household can obtain full window sunshine for 2 hours in the severe cold day, and the like, aiming at the current situation that the traditional design mode is difficult to adapt to the design requirement of the ecological energy-saving building, the integrated design concept is introduced by combining international reference of foreign experience, namely, professional personnel for ecological energy saving starts to intervene in the initial design scheme stage, a primary ecological energy-saving scheme is provided, and the comprehensive building, landscape planning, structure, heating ventilation and air conditioning, water supply and drainage, and subsequent design are carried out, Building electricity and building control, indoor design and other professionals are organically integrated and closely cooperated, mature high and new technologies and products are comprehensively adopted to form a whole set of ecological energy-saving system, and in order to reduce energy consumption, the temperature stability inside a building is ensured by physical means, so that energy-saving building insulation blocks are needed.

However, the energy-saving building insulation block used at present has the advantages of single structure, weak adjusting capacity and protective capacity, easy damage to the outer wall, low durability and low functionality, and the gap between the insulation modules is easily affected by damp and bred mould to influence the service life.

Therefore, there is a need to provide an energy-saving building insulation block to solve the above technical problems.

SUMMERY OF THE UTILITY MODEL

The utility model provides an energy-conserving building insulation block has solved the energy-conserving building insulation block who uses at present, and single structure, regulating power is weak, and protective capacities is weak, and the easy impaired durability of outer wall is low to functional lower, the space between the insulation module wets easily and breeds mould influence life's problem.

For solving the technical problem, the utility model provides an energy-conserving building insulation block, including first heat insulating block, heat preservation mechanism and dehumidification mechanism, heat preservation mechanism installs at first heat insulating block inboardly, the silica gel board is installed to first heat insulating block lateral wall, the spout has all been seted up to first heat insulating block lateral wall, and the spout inboard is provided with the connecting block, the draw-in groove has all been seted up to first heat insulating block outside below, and the draw-in groove inboard is provided with the fixture block, and fixture block outside below is connected with the dead lever simultaneously, the dead lever lateral wall is provided with the gim peg, and the dead lever inboard has seted up the activity groove, and the activity inslot inboard is provided with the movable rod simultaneously, movable rod outside below is connected with the second heat insulating block, dehumidification mechanism installs at first heat insulating block lateral wall.

Preferably, the heat preservation mechanism includes the polystyrene foam layer, rock wool layer and ceramic grained layer, and polystyrene foam layer outside below is provided with the rock wool layer, and rock wool layer outside below is provided with the ceramic grained layer simultaneously, polystyrene foam layer size is unanimous with ceramic grained layer size.

Preferably, the surface of the silica gel plate and the surface of the first heat preservation block are both in open-cell design, and the size of the silica gel plate is consistent with that of the first heat preservation block.

Preferably, the connecting block and the first heat-insulating block form a movable mechanism through the sliding groove, and the outer side of the connecting block is tightly attached to the inner side of the sliding groove.

Preferably, the fixed rod is connected with the first heat preservation block in a clamping mode through a clamping block, and the outer side of the clamping block and the inner side of the clamping groove are both designed in a T shape.

Preferably, the second heat preservation block is of a sliding structure through the movable rod and the fixed rod, and the movable rod is symmetrically arranged with the center line of the second heat preservation block.

Preferably, the dehumidification mechanism comprises a fixed box, a groove and a dehumidification box, the inner side of the fixed box is provided with the groove, the inner side of the groove is provided with the dehumidification box, and the dehumidification box and the fixed box form a sliding structure through the groove.

Compared with the prior art, the utility model provides an energy-conserving building insulation block has following beneficial effect:

1. the utility model discloses a silica gel board that sets up, such setting can carry out the surface protection through the setting of silica gel board to first heat insulating block, causes the fish tail wearing and tearing to first heat insulating block outer wall when avoiding using, the effectual durability and the life that have improved the device to the non-skid property of silica gel board also is convenient for the staff to the transport installation and the dismantlement of heat preservation module.

2. The utility model discloses a dead lever, activity groove and the movable rod that set up like this and can cooperate the convenient adjustment second heat preservation piece of activity structure in activity groove and the interval between the first heat preservation piece through the movable rod, can adjust the device's thickness as required, the effectual controllability that improves the device.

3. The utility model discloses a dehumidification mechanism that sets up, such setting can be absorbed steam on every side through the dehumidification box that the dehumidification mechanism inboard set up, avoids the inboard space of heat preservation module to produce mould influence the device's life and security because of steam.

Drawings

Fig. 1 is a schematic top view cross-sectional structure of a preferred embodiment of the energy-saving building insulation block provided by the present invention;

FIG. 2 is a schematic view of the internal structure of the heat-retaining mechanism shown in FIG. 1;

FIG. 3 is a schematic view of the internal structure of the dehumidifying mechanism shown in FIG. 1;

fig. 4 is a schematic view of a connection structure of the fixed bar and the movable bar shown in fig. 1.

Reference numbers in the figures: 1. a first heat preservation block; 2. a heat preservation mechanism; 201. a polystyrene foam layer; 202. a rock wool layer; 203. a layer of ceramic particles; 3. a silica gel plate; 4. a chute; 5. connecting blocks; 6. a card slot; 7. a clamping block; 8. fixing the rod; 9. positioning bolts; 10. a movable groove; 11. a movable rod; 12. a second heat-insulating block; 13. a dehumidification mechanism; 1301. a fixing box; 1302. a groove; 1303. and (7) a dehumidification box.

Detailed Description

The present invention will be further described with reference to the accompanying drawings and embodiments.

Please refer to fig. 1, fig. 2, fig. 3 and fig. 4 in combination, wherein fig. 1 is a schematic top sectional view of a preferred embodiment of an energy-saving building insulation block provided by the present invention, fig. 2 is a schematic internal structure of an insulation mechanism shown in fig. 1, fig. 3 is a schematic internal structure of a dehumidification mechanism shown in fig. 1, and fig. 4 is a schematic connection structure of a fixed rod and a movable rod shown in fig. 1. This energy-conserving building insulation block, including first heat preservation piece 1, heat preservation mechanism 2 and dehumidification mechanism 13, heat preservation mechanism 2 installs at 1 inboardly of first heat preservation piece, silica gel board 3 is installed to 1 lateral wall of first heat preservation piece, spout 4 has all been seted up to 1 lateral wall of first heat preservation piece, and 4 inboards of spout are provided with connecting block 5, draw-in groove 6 has all been seted up to 1 outside below of first heat preservation piece, and 6 inboards of draw-in groove are provided with fixture block 7, 7 outside below of fixture block are connected with dead lever 8 simultaneously, 8 lateral walls of dead lever are provided with gim peg 9, and the activity groove 10 has been seted up to 8 inboards of dead lever, activity groove 10 inboards are provided with movable rod 11 simultaneously, 11 outside below of movable rod is connected with second heat preservation piece 12, dehumidification mechanism 13 installs at 1 lateral wall of first heat preservation piece.

Further, heat preservation mechanism 2 includes polystyrene foam layer 201, rock wool layer 202 and ceramic particle layer 203, and polystyrene foam layer 201 outside below is provided with rock wool layer 202, rock wool layer 202 outside below is provided with ceramic particle layer 203 simultaneously, polystyrene foam layer 201 size is unanimous with ceramic particle layer 203 size, such setting can strengthen the device's heat preservation effect through polystyrene foam layer 201, rock wool layer 202 and ceramic particle layer 203's heat preservation ability, the effectual physics heat preservation ability that has improved the device.

Further, 3 surfaces of silica gel plate and 1 surfaces of first heat preservation piece are trompil formula design, and 3 sizes of silica gel plate are unanimous with 1 size of first heat preservation piece, such setting can carry out the surface protection to 1 of first heat preservation piece through the setting of silica gel plate 3, cause the fish tail wearing and tearing to 1 outer wall of first heat preservation piece when avoiding using, the effectual durability and the life that have improved the device, and the anti-skidding ability of silica gel plate 3 also is convenient for the staff to the transport installation and the dismantlement of heat preservation module.

Further, connecting block 5 constitutes the movable mechanism through spout 4 and first heat preservation piece 1, and the 5 outsides of connecting block closely laminate with the spout 4 is inboard, and such setting can be established ties each heat preservation module through the convenient with each heat preservation module of split type connecting block 5 cooperation spout 4's movable structure, the effectual unlimited concatenation ability that has improved the device.

Further, the dead lever 8 is connected with 1 block of first heat preservation piece through fixture block 7, and the fixture block 7 outside is "T" font design with draw-in groove 6 inboard, and convenient installation and dismantlement dead lever 8 and movable rod 11 can be connected through the block to such setting, and the effectual work burden that has reduced the staff has improved the device's convenient installation and dismantlement ability.

Further, second heat preservation piece 12 is through being sliding construction between movable rod 11 and the dead lever 8, and movable rod 11 uses the symmetry of second heat preservation piece 12 central line to set up, sets up like this and can adjust the device's thickness according to actual need through the convenient adjustment second heat preservation piece 12 of movable structure of movable rod 11 cooperation activity groove 10 and the interval between the first heat preservation piece 1, the effectual controllability that improves the device.

Further, dehumidification mechanism 13 includes fixed box 1301, recess 1302 and dehumidification box 1303, and fixed box 1301 inboard all sets up recess 1302, and recess 1302 inboard is provided with dehumidification box 1303 simultaneously, and dehumidification box 1303 constitutes sliding structure through recess 1302 and fixed box 1301, and such setting can be come to absorb surrounding steam through the dehumidification box 1303 that dehumidification mechanism 13 inboard set up, avoids the inboard space of heat preservation module to produce mould because of steam and influences the life and the security of the device.

The utility model provides an energy-conserving building insulation block's theory of operation as follows:

for the energy-saving building insulation block, firstly, the insulation effect of the device is enhanced through the insulation capacity of the polystyrene foam layer 201, the rock wool layer 202 and the ceramic particle layer 203 arranged on the inner side of the first insulation block 1, the physical insulation capacity of the device is effectively improved, then the surface protection is carried out on the first insulation block 1 through the arrangement of the silica gel plate 3, the scratch abrasion on the outer wall of the first insulation block 1 when in use is avoided, the durability and the service life of the device are effectively improved, the anti-skid capacity of the silica gel plate 3 is convenient for workers to carry, install and disassemble the insulation modules, secondly, the insulation modules can be conveniently connected in series through the split type connecting block 5 in cooperation with the movable structure of the sliding groove 4, the unlimited splicing capacity of the device is effectively improved, and then the distance between the second insulation block 12 and the first insulation block 1 is conveniently adjusted through the movable rod 11 in cooperation with the movable structure of the movable groove 10, can adjust the device's thickness according to actual need, the effectual controllability that improves the device comes to absorb steam on every side through dehumidification box 1303 that dehumidification mechanism 13 inboard set up at last, avoids the inboard space of heat preservation module to produce mould because of steam and influences the life and the security of device, just so energy-conserving building insulation block's instructions have just been accomplished.

Compared with the prior art, the utility model provides an energy-conserving building insulation block has following beneficial effect:

1. the utility model discloses a silica gel plate 3 that sets up, such setting can carry out the surface protection through silica gel plate 3's setting to first heat insulating block 1, causes the fish tail wearing and tearing to 1 outer wall of first heat insulating block when avoiding using, the effectual durability and the life that have improved the device to the anti-skidding ability of silica gel plate 3 also is convenient for the staff to the transport installation and the dismantlement of heat preservation module.

2. The utility model discloses a dead lever 8, activity groove 10 and the movable rod 11 that set up, set up like this and can cooperate the convenient adjustment second heat preservation piece 12 of activity structure in activity groove 10 and the interval between the first heat preservation piece 1 through movable rod 11, can adjust the device's thickness as required, the effectual controllability that improves the device.

3. The utility model discloses a dehumidification mechanism 13 that sets up, such setting can be through the dehumidification box 1303 of the inboard setting of dehumidification mechanism 13 come to absorb steam on every side, avoids the inboard space of heat preservation module to produce mould because of steam and influences the device's life and security.

The above only is the embodiment of the present invention, not limiting the scope of the present invention, all the equivalent structures or equivalent processes of the present invention are used in the specification and the attached drawings, or directly or indirectly applied to other related technical fields, and the same principle is included in the protection scope of the present invention.

Claims (7)

1. The energy-saving building heat-insulation block comprises a first heat-insulation block (1), a heat-insulation mechanism (2) and a dehumidifying mechanism (13), and is characterized in that the heat-insulation mechanism (2) is installed on the inner side of the first heat-insulation block (1), a silica gel plate (3) is installed on the outer side wall of the first heat-insulation block (1), sliding grooves (4) are formed in the outer side wall of the first heat-insulation block (1), connecting blocks (5) are arranged on the inner sides of the sliding grooves (4), clamping grooves (6) are formed in the lower portion of the outer side of the first heat-insulation block (1), clamping blocks (7) are arranged on the inner sides of the clamping grooves (6), fixing rods (8) are connected to the lower portion of the outer side of the clamping blocks (7), positioning bolts (9) are arranged on the outer side wall of the fixing rods (8), movable grooves (10) are formed in the inner side of the movable grooves (10), movable rods (11) are connected to second heat-insulation blocks (12) below the outer sides of the movable rods (11), and the dehumidifying mechanism (13) is arranged on the outer side wall of the first heat-insulating block (1).

2. The energy-saving building insulation block as claimed in claim 1, wherein the insulation mechanism (2) comprises a polystyrene foam layer (201), a rock wool layer (202) and a ceramic particle layer (203), the rock wool layer (202) is arranged below the outer side of the polystyrene foam layer (201), the ceramic particle layer (203) is arranged below the outer side of the rock wool layer (202), and the size of the polystyrene foam layer (201) is consistent with the size of the ceramic particle layer (203).

3. The energy-saving building heat-insulating block according to claim 1, wherein the surface of the silica gel plate (3) and the surface of the first heat-insulating block (1) are both in open-cell design, and the size of the silica gel plate (3) is consistent with that of the first heat-insulating block (1).

4. The energy-saving building heat-insulating block according to claim 1, wherein the connecting block (5) and the first heat-insulating block (1) form a movable mechanism through the sliding groove (4), and the outer side of the connecting block (5) is tightly attached to the inner side of the sliding groove (4).

5. The energy-saving building heat-insulating block as claimed in claim 1, wherein the fixing rod (8) is connected with the first heat-insulating block (1) in a clamping manner through a clamping block (7), and the outer side of the clamping block (7) and the inner side of the clamping groove (6) are both in a T-shaped design.

6. The energy-saving building heat-insulating block as claimed in claim 1, wherein the second heat-insulating block (12) is of a sliding structure through the movable rod (11) and the fixed rod (8), and the movable rod (11) is symmetrically arranged with the central line of the second heat-insulating block (12).

7. The energy-saving building heat-insulating block of claim 1, wherein the dehumidifying mechanism (13) comprises a fixing box (1301), a groove (1302) and a dehumidifying box (1303), the inner sides of the fixing box (1301) are respectively provided with the groove (1302), the inner side of the groove (1302) is provided with the dehumidifying box (1303), and the dehumidifying box (1303) and the fixing box (1301) form a sliding structure through the groove (1302).

Images