CN112012388A - Heat-preservation recycled aggregate floor and processing technology thereof - Google Patents

Abstract

The application relates to a heat preservation regeneration aggregate floor and a processing technology thereof, which comprises a floor body, a reinforcing steel bar frame is pre-buried inside the floor body, a heat preservation plate is pre-buried inside the floor body, the heat preservation plate is provided with two and two relatively, the heat preservation plate is arranged on two sides of the reinforcing steel bar frame respectively, each a heat insulation vacuum cavity is all arranged inside the heat preservation plate, the heat insulation vacuum cavities are distributed at two ends inside the heat preservation plate relatively, each are arranged inside the heat insulation vacuum cavity, the heat insulation reinforcing plate is a ceramic fiber plate, and the whole ceramic fiber plate is matched with the heat insulation vacuum cavity. This application has multiple thermal-insulated, the strong effect of thermal insulation performance.

Description

Heat-preservation recycled aggregate floor and processing technology thereof

Technical Field

The application relates to the field of building components, in particular to a heat-preservation recycled aggregate floor and a processing technology thereof.

Background

The recycled aggregate floor is a floor made of recycled aggregate, and the recycled aggregate is made of waste concrete in construction waste through crushing and screening.

In the related technology, the floor is constructed by laying the laminated slab on the floor by a crane, binding reinforcing steel bars on the laminated slab, pouring concrete, and solidifying the concrete.

In view of the above-mentioned related art, the inventors have considered that there is a drawback in that when people live in a house constructed by the related art, it is difficult to maintain the temperature in the room for a long time, thereby causing loss of hot or cold air in the room, and thus increasing power consumption.

Disclosure of Invention

In order to improve the heat preservation performance, the application provides a heat preservation recycled aggregate floor and a processing technology thereof.

In a first aspect, the application provides a heat-insulating recycled aggregate floor, which adopts the following technical scheme:

the utility model provides a heat preservation regeneration aggregate floor, includes the floor body, the inside pre-buried reinforcing bar frame that has of floor body, this internal pre-buried heated board that has of floor, the heated board is provided with two relatively, two the heated board sets up respectively in the both sides of reinforcing bar frame, each thermal-insulated vacuum cavity has all been seted up in the heated board, thermal-insulated vacuum cavity both ends in the heated board of relative distribution, each thermal-insulated vacuum intracavity all is provided with thermal-insulated reinforcing plate, what thermal-insulated reinforcing plate chooseed for use is ceramic fiber board, the whole adaptation of ceramic fiber board is in thermal-insulated vacuum intracavity.

By adopting the technical scheme, indoor heat can be blocked by the heat-insulating plate, so that the heat-insulating plate is difficult to penetrate through the floor body, and therefore indoor hot air or cold air can continuously exist indoors, so that the indoor temperature can be kept constant, and the heat-insulating function is realized; in addition, the arrangement of the heat insulation vacuum cavity can further reduce the loss of heat, thereby further improving the heat preservation function of the heat insulation device; in addition, the ceramic fiber board has a lower heat conductivity coefficient, the compressive strength of the ceramic fiber board is high, and the toughness is also good, so that the strength of the heat-insulating board is improved while the heat-insulating effect is further improved due to the arrangement of the ceramic fiber board, and the service life of the heat-insulating board is prolonged.

Preferably, the insulation board is a phenolic foam board.

By adopting the technical scheme, the phenolic foam board has high closed-cell rate, so that the phenolic foam board has low heat conductivity coefficient, namely, good heat insulation performance; in addition, the phenolic aldehyde has a benzene ring structure, namely the size is stable, and the phenolic aldehyde foam board has stable chemical components and has the characteristics of corrosion resistance and ageing resistance, so that the service life of the insulation board is prolonged.

Preferably, a vacuum insulation board is embedded in the floor body and is positioned between the two insulation boards.

By adopting the technical scheme, the vacuum insulation panel has lower heat conductivity coefficient, the thickness of the vacuum insulation panel is thinner, and the weight of the vacuum insulation panel is lighter, so that the vacuum insulation panel has better heat insulation effect and can save materials.

Preferably, two groups of reinforcing steel frames are arranged in the floor body, and the two reinforcing steel frames are respectively arranged on two sides of the vacuum insulation panel facing the two insulation boards.

Through adopting above-mentioned technical scheme, the reinforcing bar frame that sets up relatively has increased the inside reinforcing bar volume of floor body, can further improve floor body's atress ability like this to improve floor body's intensity, consequently improved the security in the house that this application was made.

Preferably, two one side that the steel reinforcement frame deviates from each other is provided with the locating part respectively, the locating part includes touch panel and connecting rod, the one end fixed connection of connecting rod is in the one side of touch panel, two run through respectively on the heated board and set up the connecting hole that supplies the connecting rod to wear to establish, the conflict board is located the heated board and keeps away from one side of corresponding steel reinforcement frame, the connecting rod passes corresponding connecting hole and connects on corresponding steel reinforcement frame.

Through adopting above-mentioned technical scheme, the setting of locating part can be fixed in the heated board on the reinforcing bar frame, and the in-process that the heated board was pour at the floor body like this can be fixed in the mould more steadily, has improved the stability when the floor body produces promptly.

Preferably, two one side that the heated board is close to the steel reinforcement frame all is provided with a plurality of locking boards corresponding with the connecting rod, each locking screw hole has all been seted up on the locking board, connecting rod threaded connection is in locking screw hole, just the locking board all contradicts in corresponding heated board.

Through adopting above-mentioned technical scheme, the setting of locking plate for the heated board can be locked firmly between locking plate and conflict board, just so can further restrict the position of heated board, thereby stability when further improving floor body production.

Preferably, the two ends of the vacuum heat insulation plate are respectively provided with a clamping plate, the two side walls of each clamping plate are respectively connected with the reinforcing steel bar frames on the two sides of each clamping plate, one side of each clamping plate, which is close to the vacuum heat insulation plate, is respectively provided with a clamping groove, and the two ends of each vacuum heat insulation plate are respectively embedded in the clamping grooves.

Through adopting above-mentioned technical scheme, the setting of grip block can be fixed in the vacuum insulation panels between two steel reinforcement framves, and the in-process that the floor body was pour of vacuum insulation panels like this can be fixed in the mould more steadily, has further improved the stability when floor body produces promptly.

In a second aspect, the application provides a construction process of a heat-preservation recycled aggregate floor, which adopts the following technical scheme:

a processing technology of a heat-preservation recycled aggregate floor comprises the following steps:

s10, building a mould which is consistent with the outline of the floor body by adopting a steel plate, vertically placing the mould and reserving an opening at the upper end;

s20, manufacturing and placing embedded parts, embedding two ends of the vacuum insulation panel into clamping grooves of the clamping plates respectively, and welding the side walls on two sides of the vacuum insulation panel to reinforcing steel bar frames on two sides; then, respectively installing the limiting pieces on the heat insulation plates, and locking the heat insulation plates by using the locking plates; then, welding the connecting rods to the corresponding reinforcing steel bar frames to fix the two heat insulation plates; finally, the whole embedded part is placed in the built die from the opening at the upper end of the die;

and S30, pouring concrete, pouring the concrete into the mold, and finishing processing after solidification.

By adopting the technical scheme, a constructor firstly builds a mould which is consistent with the outline of the floor body by adopting the steel plates, then vertically places the mould and reserves an opening at the upper end, so that concrete can be gradually filled into the mould from bottom to top after being poured into the mould, and the strength of the floor body is ensured; then, two ends of the vacuum heat-insulating plate are respectively embedded in clamping grooves of the clamping plates, side walls on two sides of the vacuum heat-insulating plate are welded to reinforcing steel bar frames on two sides, then the limiting parts are respectively installed on the heat-insulating plates, the heat-insulating plates are locked by using the locking plates, then connecting rods are welded to the corresponding reinforcing steel bar frames to fix the two heat-insulating plates, and then the whole embedded part is placed in the built die from an opening at the upper end of the die; and finally, pouring concrete into the mold, and finishing processing after solidification.

Preferably, in the step S30, the mold is vibrated to compact the concrete in the mold when the concrete is poured into the mold.

Through adopting above-mentioned technical scheme, the in-process of concrete pouring into the mould can constantly receive the effect of vibration, and more closely knit, just so can improve the holistic intensity of floor body, improved product quality promptly.

In summary, the present application includes at least one of the following beneficial technical effects:

1. indoor heat can be blocked by the heat-insulating plate and can hardly penetrate through the floor body, so that indoor hot air or cold air can continuously exist indoors, the indoor temperature can be kept constant, and the heat-insulating function is realized; in addition, the arrangement of the heat insulation vacuum cavity can further reduce the loss of heat, thereby further improving the heat preservation function of the heat insulation device; in addition, the ceramic fiber board has a lower heat conductivity coefficient, the compressive strength of the ceramic fiber board is high, and the toughness is also good, so that the strength of the heat-insulating board is improved while the heat-insulating effect is further improved due to the arrangement of the ceramic fiber board, and the service life of the heat-insulating board is prolonged.

2. The setting of locating part can be fixed in the heated board on the reinforcing bar frame, and the in-process that the heated board was pour at the floor body like this can be fixed in the mould more steadily, has improved the stability when floor body production promptly.

3. The method comprises the following steps that constructors firstly build a mold which is consistent with the outline of a floor body by adopting steel plates, then vertically place the mold and reserve an opening at the upper end, so that concrete can be gradually filled in the mold from bottom to top after being poured in the mold, and the strength of the floor body is guaranteed; then, two ends of the vacuum heat-insulating plate are respectively embedded in clamping grooves of the clamping plates, side walls on two sides of the vacuum heat-insulating plate are welded to reinforcing steel bar frames on two sides, then the limiting parts are respectively installed on the heat-insulating plates, the heat-insulating plates are locked by using the locking plates, then connecting rods are welded to the corresponding reinforcing steel bar frames to fix the two heat-insulating plates, and then the whole embedded part is placed in the built die from an opening at the upper end of the die; and finally, pouring concrete into the mold, and finishing processing after solidification.

Drawings

FIG. 1 is a schematic diagram of the overall structure in an embodiment of the present application;

fig. 2 is a partially enlarged view of a portion a in fig. 1.

Description of reference numerals: 1. a floor body; 2. a thermal insulation board; 21. connecting holes; 211. a heat insulation vacuum cavity; 2111. a heat insulating reinforcing plate; 3. a reinforcing steel bar frame; 4. a limiting member; 41. a touch plate; 42. a connecting rod; 5. a locking plate; 51. locking the threaded hole; 6. a vacuum insulation panel; 7. a clamping plate; 71. a clamping groove.

Detailed Description

The present application is described in further detail below with reference to figures 1-2.

The embodiment of the application discloses a heat-preservation recycled aggregate floor. Referring to fig. 1, the recycled aggregate floor comprises a floor body 1, and the floor body 1 is formed by pouring concrete. The inside pre-buried heated board 2 that has of floor body 1 to the inside heated board 2 of floor body 1 is provided with two relatively. In this embodiment, the insulation board 2 is a phenolic foam board with high insulation performance.

Referring to fig. 1, each insulation board 2 is provided with a thermal insulation vacuum cavity 211 therein, and the thermal insulation vacuum cavities 211 are distributed at two ends of the insulation board 2 relatively. All pre-buried thermal-insulated reinforcing plate 2111 that is provided with in each thermal-insulated vacuum cavity 211, what thermal-insulated reinforcing plate 2111 chose for use is ceramic fiberboard, and the whole adaptation of ceramic fiberboard is in thermal-insulated vacuum cavity 211 to improve heated board 2's heat preservation effect and intensity.

Referring to fig. 2, the reinforcing steel frames 3 are embedded in the floor body 1, and two sets of reinforcing steel frames 3 are oppositely arranged in the floor body 1, and the two sets of reinforcing steel frames 3 are located between the two heat insulation boards 2. In this embodiment, the steel bar frame 3 is formed by welding a plurality of horizontal and vertical steel bars.

Referring to fig. 2, the two steel frames 3 are provided with a plurality of limiting members 4 at sides away from each other, and each limiting member 4 includes a contact plate 41 and a connecting rod 42. One end of the connecting rod 42 is fixed on one surface of the contact plate 41 by welding, and the two heat-insulating plates 2 are respectively provided with a connecting hole 21 for the connecting rod 42 to penetrate through. A plurality of locking plates 5 corresponding to the connecting rods 42 are arranged on one sides of the two heat insulation plates 2 close to the reinforcing steel bar frames 3, and each locking plate 5 is provided with a locking threaded hole 51 in a penetrating mode. The contact plate 41 is located on the side of the heat insulation plate 2 away from the steel bar frame 3, the connecting rod 42 passes through the corresponding connecting hole 21 and is screwed into the locking threaded hole 51 of the locking plate 5, and then the end of the connecting rod 42 is fixed to the corresponding steel bar frame 3 by welding. After every locking plate 5 all locks, each locking plate 5 will contradict in corresponding heated board 2 to realize heated board 2's fixed.

Referring to fig. 2, a vacuum insulation panel 6 is embedded in the floor body 1, and the vacuum insulation panel 6 is located between the two reinforcing steel frames 3. The two ends of the vacuum heat insulation plate 6 are respectively provided with a clamping plate 7, one side of each of the two clamping plates 7 close to the vacuum heat insulation plate 6 is respectively provided with a clamping groove 71, and the two ends of the vacuum heat insulation plate 6 are respectively embedded in the clamping grooves 71. The two side walls of the clamping plate 7 are respectively fixed on the reinforcing steel bar frames 3 at the two sides thereof through welding, thereby realizing the fixation of the vacuum heat insulation plate 6.

The implementation principle of the heat-preservation recycled aggregate floor in the embodiment of the application is as follows: this application is assembling behind housing construction, and the heat in the house will receive simultaneously heated board 2 and the 6 blockking of vacuum insulation panel in the floor body 1, and is difficult to pierce through floor body 1, and like this, indoor steam or air conditioning just can stop for a long time to realize heat retaining function.

The embodiment of the application also discloses a processing technology of the heat-preservation recycled aggregate floor, which comprises the following steps:

and (3) building a mould, building a mould with the outline consistent with that of the floor body 1 by adopting steel plates, vertically placing the mould and reserving an opening at the upper end.

Manufacturing and placing embedded parts, respectively embedding two ends of the vacuum heat-insulating plate 6 into the clamping grooves 71 of the clamping plates 7, and welding the side walls on two sides of the vacuum heat-insulating plate 6 to the reinforcing steel bar frames 3 on two sides of the vacuum heat-insulating plate; then, respectively installing the limiting pieces 4 on the heat insulation plates 2, and locking the heat insulation plates 2 by using the locking plates 5; then, the connecting rods 42 are welded to the corresponding reinforcing steel bar frames 3 to fix the two insulation boards 2; and finally, placing the whole embedded part into the built die from the opening at the upper end of the die.

Pouring concrete, pouring the concrete into the mould, and vibrating the mould by using a vibrating machine when pouring the concrete into the mould so as to compact the concrete in the mould and finish processing after solidification.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (9)

1. The utility model provides a heat preservation regeneration aggregate floor, includes floor body (1), the inside pre-buried reinforcing bar frame (3) that have of floor body (1), its characterized in that: pre-buried heated board (2) in floor body (1), heated board (2) are provided with two relatively, two heated board (2) set up respectively in the both sides of reinforcing bar frame (3), each thermal-insulated vacuum cavity (211) have all been seted up in heated board (2), thermal-insulated vacuum cavity (211) distribute relatively in both ends in heated board (2), each all be provided with thermal-insulated reinforcing plate (2111) in thermal-insulated vacuum cavity (211), what thermal-insulated reinforcing plate (2111) chooseed for use is ceramic fiber board, the whole adaptation of ceramic fiber board is in thermal-insulated vacuum cavity (211).

2. The heat-insulating recycled aggregate floor as claimed in claim 1, wherein: the heat insulation board (2) is a phenolic foam board.

3. The heat-insulating recycled aggregate floor as claimed in claim 1, wherein: a vacuum insulation board (6) is also embedded in the floor body (1), and the vacuum insulation board (6) is located between the two insulation boards (2).

4. The heat-insulating recycled aggregate floor as claimed in claim 3, wherein: two groups of reinforcing steel bar frames (3) are arranged in the floor body (1), and the two reinforcing steel bar frames (3) are respectively arranged on two sides of the vacuum heat insulation plate (6) facing the two heat insulation plates (2).

5. The heat-insulating recycled aggregate floor as claimed in claim 4, wherein: two one side that reinforcing bar frame (3) deviate from each other is provided with locating part (4) respectively, locating part (4) are including touch panel (41) and connecting rod (42), the one end fixed connection of connecting rod (42) is in the one side of touch panel (41), two run through respectively on heated board (2) and set up connecting hole (21) that supply connecting rod (42) to wear to establish, touch panel (41) are located heated board (2) and keep away from one side of corresponding reinforcing bar frame (3), connecting rod (42) pass corresponding connecting hole (21) and are connected on corresponding reinforcing bar frame (3).

6. The heat-insulating recycled aggregate floor as claimed in claim 5, wherein: two one side that heated board (2) are close to steel reinforcement frame (3) all is provided with a plurality of locking boards (5) corresponding with connecting rod (42), each locking screw hole (51) have all been seted up on locking board (5), connecting rod (42) threaded connection in locking screw hole (51), just locking board (5) all contradict in corresponding heated board (2).

7. The heat-insulating recycled aggregate floor as claimed in claim 3, wherein: the two ends of the vacuum heat insulation plate (6) are respectively provided with a clamping plate (7), two side walls of the clamping plate (7) are respectively connected with the reinforcing steel bar frames (3) on the two sides of the clamping plate, clamping grooves (71) are respectively formed in one side, close to the vacuum heat insulation plate (6), of the clamping plate (7), and the two ends of the vacuum heat insulation plate (6) are respectively embedded in the clamping grooves (71).

8. A process for manufacturing a thermal insulation recycled aggregate floor according to claims 1 to 7, which is characterized in that: the method comprises the following steps:

s10, building a mould which is consistent with the outline of the floor body (1) by adopting a steel plate, vertically placing the mould and reserving an opening at the upper end;

s20, manufacturing and placing embedded parts, embedding two ends of the vacuum heat insulation plate (6) into clamping grooves (71) of a clamping plate (7) respectively, and welding the side walls of the two sides of the vacuum heat insulation plate (6) to the reinforcing steel bar frames (3) of the two sides; then, respectively installing the limiting pieces (4) on the heat insulation plates (2), and locking the heat insulation plates (2) by using the locking plates (5); then, welding the connecting rods (42) to the corresponding reinforcing steel bar frames (3) to fix the two heat insulation plates (2); finally, the whole embedded part is placed in the built die from the opening at the upper end of the die;

and S30, pouring concrete, pouring the concrete into the mold, and finishing processing after solidification.

9. The processing technology of the heat-preservation recycled aggregate floor according to claim 8, characterized in that: in step S30, when concrete is poured into the mold, the mold is vibrated to compact the concrete in the mold.

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