CN112982820A - Prefabricated wallboard of heat preservation energy-saving building - Google Patents

Abstract

The invention provides a heat-insulating energy-saving building prefabricated wallboard, which belongs to the technical field of prefabricated wallboards and comprises a prefabricated wallboard and a heat-insulating structure arranged in the prefabricated wallboard, wherein the heat-insulating structure comprises a cavity arranged in the prefabricated wallboard, two groups of heat-insulating curtains arranged in the cavity and a connecting assembly used for connecting and fixing the two groups of heat-insulating curtains; a driving structure for driving the two groups of heat-insulating curtains to approach or depart from each other is arranged in the cavity; when the driving structure drives the two groups of heat preservation curtains to approach each other, the two groups of heat preservation curtains can be automatically connected through the connecting component; the invention provides a heat-insulation energy-saving building prefabricated wallboard which can intelligently identify whether heat insulation is needed indoors or not through a temperature sensor, control two groups of heat-insulation curtains and two groups of sleeve plates to be close to or far away from each other through a driving structure, and automatically connect through a connecting component, so that the purposes of intelligent heat insulation and external temperature isolation are achieved.

Description

Prefabricated wallboard of heat preservation energy-saving building

Technical Field

The invention belongs to the field of prefabricated wallboards, and particularly relates to a heat-insulating energy-saving building prefabricated wallboard.

Background

The prefabricated slab is mostly used for building and assembling the wall body, can improve the industrial and mechanical construction degree, improve the on-site construction efficiency, reduce the on-site wet operation and save the on-site labor.

The prefabricated wallboard of current heat preservation energy-saving is through adding the cotton realization of heat preservation in prefabricated wallboard inside, but behind the prefabricated wallboard inside increase heat preservation cotton, when wanting with indoor and outdoor when carrying out the ventilation, the cotton circulation of indoor outer heat that has restricted greatly that keeps warm, and then makes indoor heat can't obtain abundant giving off.

Disclosure of Invention

Aiming at the defects of the prior art, the technical problem to be solved by the embodiment of the invention is to provide a heat-insulating energy-saving building prefabricated wallboard.

In order to solve the technical problems, the invention provides the following technical scheme:

a heat-insulating energy-saving building prefabricated wallboard comprises a prefabricated wallboard and a heat-insulating structure arranged inside the prefabricated wallboard, wherein the heat-insulating structure comprises a cavity arranged inside the prefabricated wallboard, two groups of heat-insulating curtains arranged inside the cavity and a connecting assembly used for connecting and fixing the two groups of heat-insulating curtains;

a driving structure for driving the two groups of heat-insulating curtains to approach or depart from each other is arranged in the cavity; when the driving structure drives the two groups of heat preservation curtains to approach each other, the two groups of heat preservation curtains can be automatically connected through the connecting component; when drive structure drives two sets ofly when the heat preservation curtain keeps away from each other, two sets of between the heat preservation curtain coupling assembling can automatic disconnection.

As a further improvement of the invention: the cavity is internally provided with a heat insulation device, and the driving structure can drive the heat insulation devices to be close to or far away from each other.

As a further improvement of the invention: the driving structure comprises two groups of sliding columns which are arranged at one end of the heat-insulation curtain respectively, two groups of sliding rings are sleeved on the outer sides of the sliding columns in a sliding mode and are fixedly connected with two ends of the heat-insulation curtain respectively through a first connecting rod, and a control structure which is used for driving the two groups of sliding rings to move in opposite directions is arranged in the cavity

As a further improvement of the invention: the control structure comprises two groups of second connecting rods arranged on one side of the heat-insulation curtain, the two groups of second connecting rods are perpendicular to the two groups of first sliding columns and the two groups of second sliding columns in pairs, the two groups of sliding rings are fixedly connected with the corresponding second connecting rods through the third connecting rods respectively, and one ends of the two groups of second connecting rods are provided with moving assemblies used for driving the two groups of connecting rods to be relatively close to or away from each other.

As a further improvement of the invention: the movable assembly is arranged in the cavity and is screwed to two groups of opposite screw rods, the opposite sides of the screw rods are fixedly connected through a coupler, the outer sides of the screw rods are provided with lantern rings in a threaded sleeve mode, the two ends of the connecting rods are respectively fixedly connected with the screw rods, one group of the connecting rods is far away from the other group of the screw rods, and one end of each screw rod is provided with a rotating assembly used for driving the screw rods to rotate.

As a still further improvement of the invention: the rotating assembly comprises a motor fixedly installed on the inner wall of the cavity, the output end of the motor corresponds to one end of the screw rod and is fixedly connected with the other end of the screw rod, and the other end of the screw rod is rotatably connected with the inner wall of the cavity.

As a still further improvement of the invention: the heat insulation device comprises a first two sets of sleeve plates and a second two sets of sleeve plates, wherein the first two sets of sleeve plates are fixedly arranged on one opposite sides of the inner wall of the cavity, the second two sets of sleeve plates are far away from one end of the second sleeve plate, the other ends of the second sleeve plates extend to the corresponding first sleeve plates respectively, the second connecting rods are fixedly penetrated through the second sleeve plates and correspond to the second sleeve plates, and the second sleeve plates are two sets of magnets with opposite magnetic poles, and the first magnet sets are fixedly embedded in one opposite sides of the second.

As a still further improvement of the invention: a second sliding groove is formed in the first sleeve plate, a sliding block is arranged on the second sliding groove in a sliding mode, and one end of the sliding block is fixedly connected with the second sleeve plate correspondingly.

As a still further improvement of the invention: the connecting assembly comprises a plurality of groups of magnets with opposite magnetic poles, which are respectively arranged on one side of the heat-preservation curtain opposite to each other.

Compared with the prior art, the invention has the beneficial effects that:

the invention aims to solve the technical problem of providing a heat-insulating energy-saving building prefabricated wall board which can intelligently identify whether heat insulation is needed indoors or not through a temperature sensor, control two groups of heat-insulating curtains and two groups of sleeve plates to be close to or far away from each other through a driving structure, and automatically connect through a connecting component, thereby achieving the purposes of intelligent heat insulation and external temperature isolation.

Drawings

FIG. 1 is a schematic structural diagram of a prefabricated wall panel for a heat-insulating and energy-saving building;

FIG. 2 is an enlarged view of area A of FIG. 1;

FIG. 3 is a schematic structural diagram of a control structure in a prefabricated wall panel of a heat-insulating and energy-saving building;

FIG. 4 is an enlarged view of the area B in FIG. 3;

FIG. 5 is a schematic connection diagram of a first sleeve plate and a second sleeve plate in a prefabricated wall panel of a heat-insulating and energy-saving building;

FIG. 6 is a schematic perspective view of a prefabricated wall panel for a heat-insulating and energy-saving building;

in the figure: the device comprises a prefabricated wall board 1, a motor 2, a screw 3, a sliding chute I4, a lantern ring 5, a sliding rod 6, a coupling 7, a sliding column I8, a heat-preservation curtain 9, a sliding column II 10, a cavity 11, a connecting rod II 12, a sliding ring 13, a connecting rod I14, a temperature sensor 15, a connecting rod III 16, a magnet II 17, a sleeve plate I18, a sleeve plate II 19, a magnet I20, a sliding chute II 21 and a sliding block 22.

Detailed Description

The technical solution of the present patent will be described in further detail with reference to the following embodiments.

Reference will now be made in detail to embodiments of the present patent, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are exemplary only for the purpose of explaining the present patent and are not to be construed as limiting the present patent.

In the description of this patent, it is to be understood that the terms "center," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like are used in the orientations and positional relationships indicated in the drawings for the convenience of describing the patent and for the simplicity of description, and are not intended to indicate or imply that the referenced devices or elements must have a particular orientation, be constructed and operated in a particular orientation, and are not to be considered limiting of the patent.

In the description of this patent, it is noted that unless otherwise specifically stated or limited, the terms "mounted," "connected," and "disposed" are to be construed broadly and can include, for example, fixedly connected, disposed, detachably connected, disposed, or integrally connected and disposed. The specific meaning of the above terms in this patent may be understood by those of ordinary skill in the art as appropriate.

Example 1

Referring to fig. 1, the embodiment provides a heat-insulating energy-saving building prefabricated wall panel, which includes a prefabricated wall panel 1 and a heat-insulating structure disposed inside the prefabricated wall panel 1, where the heat-insulating structure includes a cavity 11 disposed inside the prefabricated wall panel 1 and two sets of heat-insulating curtains 9 disposed inside the cavity 11, and a driving structure for driving the two sets of heat-insulating curtains 9 to approach to or depart from each other is disposed inside the cavity 11; when the driving structure drives the two groups of heat preservation curtains 9 to approach each other, the two groups of heat preservation curtains 9 can be automatically connected through the connecting component; work as the drive structure drives two sets ofly when the heat preservation curtain 9 kept away from each other, two sets of between the heat preservation curtain 9 coupling assembling can automatic disconnection.

In winter, the indoor heat preservation is needed, the driving structure is controlled to start, the two groups of heat preservation curtains 9 are driven to be close to each other and are automatically connected through the connecting component, so that the two groups of heat preservation curtains 9 can cover the inside of the cavity 11, the heat preservation effect is realized, and the dissipation of indoor heat is further avoided; in summer, need ventilate indoor and outdoor, distribute away indoor hot-air, control drive structure starts, drives two sets of heat preservation curtains 9 and keeps away from each other, and then makes the hot-air obtain abundant exchange, and then satisfies resident family's life requirement.

Referring to fig. 1, in this embodiment, a thermal insulation device is disposed inside the cavity 11, and the driving structure can drive the thermal insulation devices to approach or separate from each other.

In winter, the indoor heat insulation is needed, the driving structure is controlled to be started, and the driving structure drives the heat insulation device to insulate the outdoor temperature, so that the loss of indoor heat is further avoided.

Referring to fig. 1 and fig. 2, in the embodiment, the driving structure includes two sliding columns respectively disposed at one end of the two sets of thermal insulation curtains 9, two sets of sliding rings 13 are slidably sleeved outside the sliding columns, the two sets of sliding rings 13 are respectively and fixedly connected to two ends of the two sets of thermal insulation curtains 9 through a first connecting rod 14, and a control structure for driving the two sets of sliding rings 13 to move in opposite directions is disposed inside the cavity 11.

The sliding column comprises a first sliding column 8 and a second sliding column 10.

When heat preservation is needed, the control structure drives the two sets of sliding rings 13 to move relatively, and the two sets of sliding rings 13 slide along the first sliding columns 8 and the second sliding columns 10 respectively, so that the two sets of heat preservation curtains 9 are driven to approach each other, and the effect of heat preservation on indoor air is achieved; when the heat preservation is not needed, the control structure drives the two groups of sliding rings to be relatively far away, and the two groups of sliding rings 13 respectively slide along the first sliding column 8 and the second sliding column 19, so that the two groups of heat preservation curtains 9 are driven to be far away from each other. The flow of indoor air and outdoor air is realized, and the driving structure can be replaced by two groups of hydraulic cylinders.

Referring to fig. 3, in the present embodiment, the control structure includes two sets of two connecting rods 12 disposed at one side of the thermal insulation curtain 9, the two sets of two connecting rods 12 are perpendicular to the two sets of sliding posts 8 and the two sets of sliding posts 10, two teams of the sliding rings 13 are respectively and fixedly connected to the two corresponding connecting rods 12 through three connecting rods 16, and one end of each of the two sets of two connecting rods 12 is provided with a moving component for driving the two sets of two connecting rods 12 to approach or separate from each other.

When heat preservation is needed, the moving control assembly drives the two groups of second connecting rods 12 to approach each other, and drives the four groups of sliding rings 13 to move relatively through the three connecting rods 16, so that the two groups of heat preservation curtains 9 are driven to approach each other, and the purpose of heat preservation is achieved; when heat preservation is not needed, the moving assembly is controlled to drive the two groups of the second connecting rods 12 to be away from each other, the sliding ring 13 and the two groups of the heat preservation curtains 9 are driven to be away from each other through the third connecting rod 16, the purpose of indoor and outdoor heat exchange is further achieved, and the moving assembly can be replaced by controlling the rotation of the two groups of symmetrical rotating rods.

In the process of moving the second sleeve plate 19, the sliding block 22 is driven to slide along the inside of the second sliding groove 21, so that the second sleeve plate 19 can stably move on the first sleeve plate 18.

Referring to fig. 1, in this embodiment, the moving assembly includes two sets of screws 3 disposed inside the cavity 11 and having opposite rotation directions, opposite sides of the two sets of screws 3 are fixedly connected through a coupler 7, the outer sides of the two sets of screws 3 are both threadedly sleeved with a collar 5, one ends of two sets of connecting rods 12 are respectively fixedly connected to the two sets of screws 3, and a rotating assembly for driving the screws 3 to rotate is disposed at one end of one set of screws 3 away from the other set of screws 3.

The rotating assembly is controlled to start to drive the two groups of screws 3 to rotate, the rotating directions of the two groups of screws are opposite to drive the two groups of lantern rings 5 to approach or separate from each other, and when heat preservation is needed, the two groups of lantern rings 5 are controlled to approach each other to further drive the two groups of heat preservation curtains 9 to approach each other, so that the purpose of heat preservation is achieved; otherwise, the two groups of lantern rings 5 are controlled to be away from each other, the two groups of heat preservation curtains 9 are driven to be away from each other, the purpose of heat exchange between the inside and the outside is achieved, and the rotating assembly can be replaced by a rotating hydraulic cylinder.

Referring to fig. 1, in this embodiment, the rotating assembly includes a motor 2 fixedly installed on the inner wall of the cavity 11, an output end of the motor 2 is fixedly connected to one end of the corresponding screw rod 3, and the other end of the other group of screw rods 3 is rotatably connected to the inner wall of the cavity 11.

The control motor 2 is started to drive the two groups of screw rods 3 to rotate, and further drive the two groups of lantern rings 5 to move relatively.

Referring to fig. 4, the heat insulation device includes two sets of first sleeve plates 18 fixedly installed on the inner wall of the cavity 11, two sets of second sleeve plates 19 are installed on opposite sides of the two sets of first sleeve plates 18, ends of the two sets of second sleeve plates 19 away from each other extend into the corresponding first sleeve plates 18, two sets of second connecting rods 12 respectively fixedly penetrate through the corresponding second sleeve plates 19, and a plurality of sets of first magnets 20 with opposite magnetic poles are fixedly embedded on opposite sides of the two sets of second sleeve plates 19.

When two sets of connecting rods two 12 are close to each other, drive two sets of lagging 19 and be close to each other for two sets of lagging 19 extend corresponding lagging 18, when two sets of lagging 19 are close to one side relatively, a plurality of groups of magnetite one 20 adsorb each other, and then realized the fixed to two sets of lagging 19, make two sets of lagging 18 and two sets of lagging 19 isolate outdoor cold air, reduced indoor thermal scattering and disappearing, the heat insulating apparatus still can replace with two sets of telescopic heat insulating boards.

The two sets of the first sleeve plates 18 and the two sets of the second sleeve plates 19 are made of heat insulation materials.

Referring to fig. 5, a second sliding groove 21 is formed in the first sleeve plate 18, a sliding block 22 is slidably disposed on the second sliding groove 21, and one end of the sliding block 22 is fixedly connected to the second sleeve plate 19.

Referring to fig. 1, the connecting assembly includes a plurality of sets of magnets 17 with opposite magnetic poles respectively mounted on opposite sides of the thermal curtain 9.

When two sets of heat preservation curtains 9 are close to each other, a plurality of sets of second magnets 17 attract each other and are fixed, and the connecting component can also be replaced by a plurality of inserting components of the box lock.

Referring to fig. 1, in this embodiment, a first sliding groove 4 communicated with the cavity 11 is formed in the prefabricated wall panel 1, two sets of sliding rods 6 are slidably disposed in the first sliding groove 4, and the other ends of the two sets of sliding rods 6 are respectively fixedly connected with the corresponding lantern rings 5.

In the process that two sets of lantern rings 5 removed, drive two sets of slide bars 6 and slide along spout 4 insides, ensured the stationarity that two sets of lantern rings 5 removed, and then stability when having realized two sets of heat preservation curtains 9 and removing.

Referring to fig. 3, in another embodiment, a temperature sensor 15 is fixedly installed on an inner wall of the cavity 11, and the temperature sensor 15 can control starting and stopping of the motor 2.

When the temperature sensor 15 monitors that the indoor temperature needs to be kept warm, the two groups of heat preservation curtains 9 are controlled to be close to the room for heat preservation, otherwise, when the temperature sensor 15 monitors that the indoor temperature does not need to be kept warm, the two groups of heat preservation curtains 9 are controlled to be far away from each other.

The control motor 2 is started to drive the two groups of screw rods 3 with opposite rotation directions to rotate, the two groups of screw rods 3 drive the two groups of lantern rings 5 to approach each other, the two groups of lantern rings 5 drive two groups of sliding rings 13 to approach each other through two groups of connecting rods two 12, the two pairs of sliding rings 13 drive the two groups of heat-insulating curtains 9 to approach and contact each other, and meanwhile, the two groups of sleeve plates two 19 approach and are fixed with each other, so that the purpose of heat insulation of the prefabricated plate can; otherwise, the purpose of heat conduction of the prefabricated plate can be realized.

Although the preferred embodiments of the present patent have been described in detail, the present patent is not limited to the above embodiments, and various changes can be made without departing from the spirit of the present patent within the knowledge of those skilled in the art.

Claims (9)

1. A heat-insulating energy-saving building prefabricated wallboard comprises a prefabricated wallboard and a heat-insulating structure arranged inside the prefabricated wallboard, and is characterized in that the heat-insulating structure comprises a cavity arranged inside the prefabricated wallboard, two groups of heat-insulating curtains arranged inside the cavity and a connecting assembly used for connecting and fixing the two groups of heat-insulating curtains;

a driving structure for driving the two groups of heat-insulating curtains to approach or depart from each other is arranged in the cavity; when the driving structure drives the two groups of heat preservation curtains to approach each other, the two groups of heat preservation curtains can be automatically connected through the connecting component; when drive structure drives two sets ofly when the heat preservation curtain keeps away from each other, two sets of between the heat preservation curtain coupling assembling can automatic disconnection.

2. An insulating energy-saving building prefabricated wall panel as claimed in claim 1, wherein a thermal insulation device is arranged in the cavity, and the driving structure can drive the thermal insulation devices to approach or move away from each other.

3. The prefabricated wall panel for heat preservation and energy saving buildings as claimed in claim 1 or 2, wherein the driving structure comprises two sets of sliding posts respectively disposed at one end of the heat preservation curtains, two sets of sliding rings are slidably sleeved outside the sliding posts, both sets of sliding rings are respectively fixedly connected to two ends of the two sets of heat preservation curtains through a first connecting rod, and a control structure for driving the two sets of sliding rings to move in opposite directions is disposed inside the cavity

4. The prefabricated wall panel for heat-insulating and energy-saving buildings as claimed in claim 3, wherein the control structure comprises two sets of two connecting rods two on one side of the heat-insulating curtain, the two sets of two connecting rods two are perpendicular to the two sets of first sliding columns and the two sets of second sliding columns, the two sets of sliding rings are respectively and fixedly connected with the corresponding two connecting rods two through three connecting rods, and one end of the two sets of two connecting rods two is provided with a moving component for driving the two sets of connecting rods two to approach to or move away from each other.

5. The prefabricated wall panel for heat preservation and energy saving buildings according to claim 4, wherein the moving assembly comprises two sets of screws which are arranged inside the cavity and have opposite rotation directions, opposite sides of the two sets of screws are fixedly connected through a coupler, the outer sides of the two sets of screws are both provided with a lantern ring in a threaded sleeve manner, one ends of the two sets of connecting rods are respectively fixedly connected with the two sets of screws, and a rotating assembly for driving the screws to rotate is arranged at one end of one set of screws, which is far away from the other set of screws.

6. The prefabricated wall panel of the heat-insulating and energy-saving building as claimed in claim 5, wherein the rotating assembly comprises a motor fixedly mounted on the inner wall of the cavity, the output end of the motor is fixedly connected with one end of the corresponding screw rod, and the other end of the other group of screw rods is rotatably connected with the inner wall of the cavity.

7. The prefabricated wall panel for heat preservation and energy saving buildings according to claim 2, wherein the heat insulation device comprises two sets of first sleeve plates fixedly installed on the inner wall of the cavity, two sets of second sleeve plates are arranged on the opposite sides of the two sets of first sleeve plates, the ends, away from each other, of the two sets of second sleeve plates extend into the corresponding first sleeve plates respectively, two sets of second connecting rods fixedly penetrate through the corresponding second sleeve plates respectively, and a plurality of sets of first magnets with opposite magnetic poles are fixedly embedded on the opposite sides of the two sets of second sleeve plates respectively.

8. The prefabricated wall panel for the heat-insulating energy-saving building as claimed in claim 7, wherein a second sliding groove is formed in the first sheathing plate, a sliding block is slidably arranged on the second sliding groove, and one end of the sliding block is fixedly connected with the second sheathing plate correspondingly.

9. The prefabricated wall panel of the heat-insulating and energy-saving building as claimed in claim 1, wherein the connecting assembly comprises a plurality of groups of magnets with opposite magnetic poles respectively mounted on opposite sides of the heat-insulating curtain.

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