CN111485669A - Temperature-adjustable cement light wallboard and manufacturing process thereof - Google Patents

Abstract

The invention relates to the technical field of cement wallboards, in particular to a temperature-adjustable cement lightweight wallboard and a manufacturing process thereof. The cement light wallboard with the adjustable temperature has the advantage that the indoor environment can be heated. The utility model provides a cement light wallboard that can adjust temperature, includes the plate body that foaming cement made and sets up the water service subassembly in the plate body, the shaping has the multichannel parallel and gets the round hole along riser body length direction in the plate body, the plate body is run through at the both ends of round hole, the water service subassembly is including setting up in the stainless steel pipe in every round hole, the external diameter of stainless steel pipe and the internal diameter of round hole equal. Through set up the stainless steel pipe as leading to water subassembly in the plate body, closely cooperate between stainless steel pipe and the round hole in order to prevent that the stainless steel pipe from droing. The indoor environment can be heated by introducing hot water into the water introducing assembly so as to adapt to the unique requirements of cold regions. Cold water can be introduced to cool the indoor environment in a hot environment, so that the purpose of adjusting the temperature is achieved.

Description

Temperature-adjustable cement light wallboard and manufacturing process thereof

Technical Field

The invention relates to the technical field of cement wallboards, in particular to a temperature-adjustable cement lightweight wallboard and a manufacturing process thereof.

Background

The light partition wall board is a new type of energy-saving wall material, it is a wall material with the same appearance as hollow floor slab, but its both sides have male and female tenon grooves, when it is installed, it only needs to erect the board, after the male and female tenons are coated with a small quantity of caulking mortar, the board can be assembled together. The high-efficiency energy-saving building material is prepared from various industrial waste residues such as harmless phosphogypsum, light steel slag, fly ash and the like through variable-frequency steam pressurization curing. The light partition board has the advantages of light weight, high strength, multiple environmental protection, heat preservation and insulation, sound insulation, breathing and humidity regulation, fire prevention, rapid construction, wall body cost reduction and the like. The inner layer is provided with the inorganic foaming section bar or other heat preservation materials with reasonable layout, heat insulation and sound absorption, the wallboard is formed by pouring, leveling and scientific maintenance through the production line, the production automation degree is high, and the specifications and varieties are multiple.

The prior utility model with the publication number of CN201635215U discloses a light-weight cement composite thermal-insulation wallboard. Good heat preservation effect is played through setting up the heated board in this scheme.

The above prior art solution has the following drawbacks: the requirement that the indoor environment needs to be heated in cold regions cannot be met.

Disclosure of Invention

One of the objects of the present invention is to provide a temperature adjustable cement lightweight wallboard which is advantageous in that the indoor environment can be heated.

The above object of the present invention is achieved by the following technical solutions: the utility model provides a cement light wallboard that can adjust temperature, includes the plate body that foaming cement made and sets up the water service subassembly in the plate body, the shaping has the multichannel parallel and gets the round hole along riser body length direction in the plate body, the plate body is run through at the both ends of round hole, the water service subassembly is including setting up in the stainless steel pipe in every round hole, the external diameter of stainless steel pipe and the internal diameter of round hole equal.

Through adopting above-mentioned technical scheme, through set up the stainless steel pipe as leading to water the subassembly in the plate body, closely cooperate between stainless steel pipe and the round hole in order to prevent that the stainless steel pipe from droing. The indoor environment can be heated by introducing hot water into the water introducing assembly so as to adapt to the unique requirements of cold regions. Cold water can be introduced to cool the indoor environment in a hot environment, so that the purpose of adjusting the temperature is achieved.

The invention is further configured to: two end faces of the plate body in the length direction are respectively provided with a semicircular groove along the width direction of the plate body, and the semicircular grooves are communicated with each circular hole; and a stainless steel semicircular pipe is embedded in each semicircular groove, and the section of each stainless steel semicircular pipe is the same as that of each semicircular groove.

Through adopting above-mentioned technical scheme, link together all stainless steel pipe through the embedded stainless steel semicircle pipe that establishes in the semicircular groove for only need single department to lead to water and just can fill full water in all the pipe. Meanwhile, the stainless steel semicircular pipes at the two ends can prevent the stainless steel circular pipe from shifting in the circular hole and even separating from the plate body.

The invention is further configured to: the plane side of the stainless steel semicircular pipe is flush with the end face of the plate body.

Through adopting above-mentioned technical scheme, set up the terminal surface parallel and level of stainless steel semicircle pipe plane and plate body, avoid the stainless steel semicircle pipe to influence the installation of wall and use.

The invention also aims to provide a manufacturing process of the cement lightweight wallboard.

The above object of the present invention is achieved by the following technical solutions: the manufacturing process of the cement lightweight wallboard comprises the following steps:

step one, installing a water-through component in a forming die;

putting the water-passing component without the welded flat plate into a forming groove, and sealing the two stainless steel semicircular plates;

step two, pouring foaming cement;

step three, taking out the wallboard;

and step four, welding the flat plate.

Through adopting above-mentioned technical scheme, put into the shaping inslot through the water-passing subassembly that will not weld the flat board, pour the foaming concrete through sealing back two stainless steel semicircle boards and make the shaping of water-passing subassembly inside the plate body, take out the dull and stereotyped stainless steel semicircle pipe of welding that forms of welding with the wallboard at last.

The invention is further configured to: in the first step, the forming die comprises a forming groove, a first sealing plate and a second sealing plate, the first sealing plate and the second sealing plate are located at two ends of the forming groove, the first sealing plate is welded with the forming groove, a guide groove is formed in the position, corresponding to the second sealing plate, on the inner wall of the forming groove, the second sealing plate moves along the vertical direction through the guide groove, a plurality of partition plates are welded on one side, facing the second sealing plate, of the first sealing plate, the partition plates are all vertically arranged, and the distance between every two adjacent partition plates or between the partition plates and the forming groove wall is equal to the thickness of a plate.

By adopting the technical scheme, the space between the adjacent partition plates/between the partition plates and the wall of the forming groove is used as a forming plate body by arranging the plurality of partition plates. The second sealing plate is pulled out upwards after the plate body is formed, so that the plate body can be taken out along the horizontal direction.

The invention is further configured to: convex strips along the vertical direction are formed on the first sealing plate corresponding to the positions between two adjacent partition plates/between the partition plates and the forming groove wall, the cross sections of the convex strips are semicircular, and the arc-shaped surfaces are back to the first sealing plate; the equal shaping in position corresponding with every sand grip on the second closing plate has the rectangular hole of dodging, and the length of dodging the hole equals the length of sand grip, and the width of dodging the hole equals the diameter of sand grip, and support piece inserts the shaping inslot through dodging the hole, support piece includes the columniform support column, the length of support column equals with the length of sand grip, and the diameter of support column and sand grip get the diameter and equal.

Through adopting above-mentioned technical scheme, through two stainless steel semicircle boards at sand grip and the airtight both ends of support column cooperation, avoid the foaming concrete to get into in the stainless steel pipe through stainless steel semicircle board.

The invention is further configured to: a plurality of circular grooves are formed in one side, back to the first sealing plate, of each convex strip, the distance between every two adjacent circular grooves is equal to the distance between every two stainless steel circular tubes, and the diameter of each circular groove is equal to the inner diameter of each stainless steel circular tube; the support column has many cylinders that insert the circular slot towards the shaping of one side in the mounting groove, and the diameter of cylindrical and the diameter of circular slot are equal.

Through adopting above-mentioned technical scheme, through the shaping cylinder on the support column for the cylinder passes through the stainless steel pipe and inserts the circular slot in, plays the effect that supports the stainless steel pipe, avoids the stainless steel pipe bending deformation when receiving the impact force of foaming cement.

The invention is further configured to: and a handle is formed on one side of the support column, which is back to the cylinder.

Through adopting above-mentioned technical scheme, set up the handle with easy to assemble and take out support piece.

The invention is further configured to: and step two, pouring foaming cement into the forming groove, forming the foaming cement into a plate body between adjacent partition plates in the forming groove, and coating and forming the water passing assembly in the foaming cement.

Through adopting above-mentioned technical scheme, pour foamed cement and lead to water subassembly cladding inside.

The invention is further configured to: and in the fourth step, the stainless steel flat plate is butted on the side surface of the stainless steel semicircular plate, and the aligned side edges of the stainless steel flat plate and the stainless steel semicircular plate are welded to form the complete stainless steel semicircular pipe.

By adopting the technical scheme, the stainless steel semicircular pipe is formed by welding the stainless steel flat plate and the stainless steel semicircular plate after the plate body is formed.

In conclusion, the beneficial technical effects of the invention are as follows:

1. a stainless steel round pipe is arranged in the plate body to serve as a water passing assembly, and hot water is led into the water passing assembly to heat the indoor environment so as to meet the unique requirements of cold regions;

2. all stainless steel round pipes are connected together by embedding the stainless steel semi-circular pipes in the semi-circular grooves, so that all round pipes can be filled with water only by introducing water in a single position, and the stainless steel round pipes at two ends can be prevented from shifting in the round holes and even being separated from the plate body.

Drawings

FIG. 1 is a schematic structural view of a wall panel in an embodiment;

FIG. 2 is a cross-sectional schematic view of an embodiment wall panel;

FIG. 3 is a schematic structural view of a molding die in the example.

Reference numerals: 1. a plate body; 2. a water-through component; 3. a circular hole; 4. a semicircular groove; 5. a stainless steel round tube; 6. a stainless steel semi-circular tube; 7. a stainless steel semicircular plate; 8. a flat plate; 9. forming a groove; 10. a first sealing plate; 11. a second sealing plate; 12. a partition plate; 13. a guide groove; 14. a convex strip; 15. avoiding holes; 16. a support member; 17. a support pillar; 18. a cylinder; 19. a handle.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

The first embodiment is as follows:

as shown in fig. 1, the cement lightweight wallboard with adjustable temperature comprises a board body 1 made of foamed cement and a water passing assembly 2 arranged in the board body 1.

As shown in fig. 1 and 2, the plate body 1 is a rectangular parallelepiped, the length direction of the plate body 1 is a vertical direction, a plurality of parallel round holes 3 are formed in the plate body 1, and the round holes 3 penetrate through the plate body 1 at two ends. The upper and lower both ends face of plate body 1 all opens the half slot 4 along plate body 1 width direction, and every half slot 4 all is linked together with round hole 3.

As shown in fig. 1 and 2, the water passing assembly 2 includes a stainless steel circular tube 5 disposed in each circular hole 3, and each stainless steel circular tube 5 abuts against the inner side wall of the through hole. Every semicircular groove 4 is internally provided with a stainless steel semicircular pipe 6 embedded in the semicircular groove 4, the stainless steel semicircular pipe 6 comprises a stainless steel semicircular plate 7 and a flat plate 8 for sealing the opening side of the stainless steel semicircular plate 7, and the cross section of the stainless steel semicircular pipe 6 is the same as that of the semicircular groove 4, so that the flat side surface of the stainless steel semicircular pipe 6 is flush with the upper end surface and the lower end surface of the plate body 1. Stainless steel pipe 5 is linked together with stainless steel semicircle pipe 6, and after the wallboard installation was used, can lead to hot water to leading to water subassembly 2 through stainless steel semicircle pipe 6 and heat indoor environment.

Example two:

a manufacturing process of a temperature-adjustable cement lightweight wallboard comprises the following steps:

step one, installing a water-passing component 2 in a forming die;

as shown in fig. 2 and 3, the forming mold includes a forming groove 9, and a first sealing plate 10 and a second sealing plate 11 located at two ends of the forming groove 9, wherein a plurality of partition plates 12 fixedly connected with the first sealing plate 10 are formed on a side of the first sealing plate 10 facing the second sealing plate 11. The partition boards 12 are vertically arranged, and the distance between the adjacent partition boards 12 is equal to the thickness of the plate body 1.

As shown in fig. 2 and 3, a guide groove 13 is formed in the inner wall of the forming groove 9 at a position corresponding to the second sealing plate 11, the second sealing plate 11 is vertically movable by the guide groove 13, and when the second sealing plate 11 is inserted into the guide groove 13, the side surface of the second sealing plate 11 abuts against the partition plate 12. Convex strips 14 along the vertical direction are formed on the first sealing plate 10 corresponding to the positions between two adjacent partition plates 12/between the partition plates 12 and the wall of the forming groove 9, the cross sections of the convex strips 14 are semicircular, and the arc-shaped surfaces face away from the first sealing plate 10. One side of the convex strip 14 back to the first sealing plate 10 is formed with a plurality of circular grooves, the distance between every two adjacent circular grooves is equal to the distance between every two stainless steel circular tubes 5, and the diameter of each circular groove is equal to the inner diameter of each stainless steel circular tube 5.

As shown in fig. 2 and 3, rectangular avoiding holes 15 are formed in the second sealing plate 11 at positions corresponding to the protruding strips 14, the length of the avoiding hole 15 is equal to the length of the protruding strip 14, the width of the avoiding hole 15 is equal to the diameter of the protruding strip 14, and the supporting member 16 is inserted into the forming groove 9 through the avoiding hole 15. The supporting piece 16 comprises a cylindrical 18-shaped supporting column 17, the length of the supporting column 17 is equal to that of the convex strip 14, the diameter of the supporting column 17 is equal to that of the convex strip 14, a plurality of cylindrical columns 18 inserted into circular grooves are formed on one side, facing the mounting groove, of the supporting column 17, and the diameter of each cylindrical column 18 is equal to that of each circular groove. The side of the support column 17 facing away from the cylinder 18 is formed with a handle 19 to facilitate mounting and removal of the support member 16.

As shown in fig. 2 and 3, the water passing assembly 2 without the welded flat plate 8 is placed in the forming groove 9, the convex strip 14 is clamped at the concave surface of the stainless steel semicircular plate 7, the column 18 passes through the stainless steel circular tube 5 and is inserted into the circular groove, and the support column 17 is clamped at the concave surface of the stainless steel semicircular plate 7 at the other end.

Step two, pouring foaming cement;

and (3) pouring foaming cement into the forming groove 9, forming the foaming cement into the plate body 1 between the adjacent partition plates 12 in the forming groove 9, and coating and forming the water passing component 2 in the foaming cement.

Step three, taking out the wallboard;

the support member 16 is first pulled out of the forming groove 9 and then the second sealing plate 11 is pulled upwards and the wall panel is pulled out from the side where the second sealing plate 11 was originally installed.

Step four, welding the flat plate 8;

and butting the stainless steel flat plate 8 on the side surface of the stainless steel semicircular plate 7, and welding the aligned side edges of the stainless steel flat plate 8 and the stainless steel semicircular plate 7 to form the complete stainless steel semicircular tube 6.

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

Claims (10)

1. A cement light wallboard that can adjust temperature, characterized by: plate body (1) and the logical water subassembly (2) of setting in plate body (1) that make including foaming cement, the shaping has the multichannel parallel and obtains round hole (3) along riser body (1) length direction in plate body (1), plate body (1) is run through at the both ends of round hole (3), lead to water subassembly (2) including setting up stainless steel pipe (5) in every round hole (3), the external diameter of stainless steel pipe (5) and the internal diameter of round hole (3) equal.

2. The temperature adjustable cementitious lightweight wallboard of claim 1, wherein: two end faces of the plate body (1) in the length direction are respectively provided with a semicircular groove (4) along the width direction of the plate body (1), and the semicircular grooves (4) are communicated with each circular hole (3); all inlay in every semicircular groove (4) and be equipped with stainless steel semicircle pipe (6), the cross-section of stainless steel semicircle pipe (6) is the same with the cross-section of semicircular groove (4).

3. The temperature adjustable cementitious lightweight wallboard of claim 1, wherein: the plane side of the stainless steel semicircular pipe (6) is flush with the end face of the plate body (1).

4. A process for manufacturing a cementitious lightweight panel as defined in any of claims 1 to 3, comprising:

step one, installing a water-passing component (2) in a forming die;

putting the water passing component (2) which is not welded with the flat plate (8) into a forming groove (9), and sealing the two stainless steel semicircular plates (7);

step two, pouring foaming cement;

step three, taking out the wallboard;

and step four, welding the flat plate (8).

5. The process for making a cementitious lightweight wallboard as claimed in claim 4, wherein: in the first step, the forming die comprises a forming groove (9), a first sealing plate (10) and a second sealing plate (11), wherein the first sealing plate (10) and the second sealing plate (11) are located at two ends of the forming groove (9), the first sealing plate (10) is welded with the forming groove (9), a guide groove (13) is formed in the position, corresponding to the second sealing plate (11), on the inner wall of the forming groove (9), the second sealing plate (11) moves along the vertical direction through the guide groove (13), a plurality of partition plates (12) are welded on the first sealing plate (10) facing one side of the second sealing plate (11), each partition plate (12) is vertically arranged, and the distance between every two adjacent partition plates (12), between each partition plate (12) and between the walls of the forming groove (9), is equal to the thickness of a plate body (.

6. The process for making a cementitious lightweight wallboard as claimed in claim 5, wherein: convex strips (14) along the vertical direction are formed on the first sealing plate (10) corresponding to the positions between two adjacent partition plates (12) or between the partition plates (12) and the wall of the forming groove (9), the cross sections of the convex strips (14) are semicircular, and the arc-shaped surfaces are back to the first sealing plate (10); the position that corresponds with every sand grip (14) on second closing plate (11) all the shaping has rectangular dodge hole (15), and the length of dodging hole (15) equals the length of sand grip (14), and the width of dodging hole (15) equals the diameter of sand grip (14), and support piece (16) insert into shaping groove (9) through dodging hole (15), support piece (16) include support column (17) of cylinder (18) shape, the length of support column (17) equals with the length of sand grip (14), and the diameter of support column (17) equals with the diameter of sand grip (14).

7. The manufacturing process of the cement lightweight wallboard according to claim 6, characterized in that: a plurality of circular grooves are formed in one side, back to the first sealing plate (10), of each convex strip (14), the distance between every two adjacent circular grooves is equal to the distance between every two stainless steel circular tubes (5), and the diameter of each circular groove is equal to the inner diameter of each stainless steel circular tube (5); one side shaping that support column (17) faced in the mounting groove has many cylinders (18) of inserting the circular slot, and the diameter of cylinder (18) equals with the diameter of circular slot.

8. The process for making a cementitious lightweight wallboard as claimed in claim 7, wherein: and a handle (19) is formed on one side of the supporting column (17) back to the cylinder (18).

9. The process for making a cementitious lightweight wallboard as claimed in claim 4, wherein: and step two, pouring foaming cement into the molding groove (9), molding the foaming cement into the plate body (1) between the adjacent partition plates (12) in the molding groove (9), and coating and molding the water passing component (2) in the foaming cement.

10. The process for making a cementitious lightweight wallboard as claimed in claim 4, wherein: and in the fourth step, the stainless steel flat plate (8) is butted on the side surface of the stainless steel semicircular plate (7), and the aligned side edges of the stainless steel flat plate (8) and the stainless steel semicircular plate (7) are welded to form the complete stainless steel semicircular tube (6).

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