CN114856012A

CN114856012A - Flame-retardant composite insulation board and processing technology thereof

Info

Publication number: CN114856012A
Application number: CN202210517427.3A
Authority: CN
Inventors: 邹积慧; 张宝; 王成峰; 李秀艳
Original assignee: Shandong Yuankai Technology Development Co ltd
Current assignee: Shandong Yuankai Technology Development Co ltd
Priority date: 2022-05-13
Filing date: 2022-05-13
Publication date: 2022-08-05

Abstract

The utility model relates to a fire-retardant composite insulation board and processing technology thereof relates to the heated board field, and it is including the panel body that has the heat preservation ability, one side of panel body is equipped with the draw-in groove, and self axial business turn over draw-in groove can be followed to the anchor nail, and the draw-in groove is located the cell wall of anchor circumference and is equipped with a plurality of fixture blocks that are used for with the spacing in the draw-in groove of anchor tip, and the fixture block all follows the radial of anchor and slides and connect in panel body. The user installs the anchor with the specific position on the wall body earlier, then presses the panel body to the direction that is close to the wall, makes in the tip embedding draw-in groove of anchor, and the user controls the fixture block cunning to move out the draw-in groove, treats panel body and wall body laminating back, and the fixture block moves to and carries on spacingly to the anchor in the draw-in groove, and then utilizes the anchor to realize being connected of wall and panel body, owing to need not the anchor to penetrate the panel body, so cold and hot bridge phenomenon is more weak, has higher heat preservation effect.

Description

Flame-retardant composite insulation board and processing technology thereof

Technical Field

The invention relates to the field of insulation boards, in particular to a flame-retardant composite insulation board and a processing technology thereof.

Background

The heat preservation performance of the building is an important index for measuring the energy consumption of the building, and particularly, when temperature regulation facilities such as heating, air conditioning and the like are installed in the building, the heat preservation effect is particularly important, so that the existing building outer wall generally adopts heat preservation measures, and the installation of heat preservation plates on the outer wall is the mainstream heat preservation measure at present.

Among the correlation technique, the heated board generally is prefabricated formula panel, and the installation of prefabricated formula heated board generally takes the mode that bonds with the wall body, can leave the seam between the adjacent heated board, can fill partial soft insulation material in the seam, for the connection of reinforcing heated board and wall body, can be in the seam crossing of heated board or directly pierce through heated board embedding anchor and anchor.

In view of the above related technologies, the inventor believes that, in the current construction mode, the external environment is directly communicated with the wall at the anchor position, so that a serious cold and hot bridge problem exists at the anchor position, and the heat preservation effect is affected.

Disclosure of Invention

In order to improve the heat preservation effect, the application provides a flame-retardant composite heat preservation plate and a processing technology thereof.

In a first aspect, the application provides a flame-retardant composite insulation board, which adopts the following technical scheme:

the utility model provides a fire-retardant composite insulation board, is including the panel body that has the heat preservation ability, one side of panel body is equipped with the draw-in groove, and self axial business turn over draw-in groove can be followed to the anchor, and the draw-in groove lies in anchor circumference's cell wall to be equipped with a plurality of fixture blocks that are used for spacing in the draw-in groove with the anchor tip, and the fixture block all slides along the radial of anchor and connects in panel is originally internal.

Through adopting above-mentioned technical scheme, the user installs the anchor to the specific position on the wall body earlier, then presses the panel body to the direction that is close to the wall, makes in the tip embedding draw-in groove of anchor, and the user controls the fixture block cunning to move out the draw-in groove, treats panel body and wall body laminating back, and the fixture block moves and carries on spacingly to the anchor in the draw-in groove, and then utilizes the anchor to realize being connected of wall and panel body, owing to need not the anchor to penetrate the panel body, so cold and hot bridge phenomenon is more weak, has higher heat preservation effect.

Optionally, one side of the fixture block, which is away from the anchor, is provided with a first elastic element, the length of the fixture block in the clamping groove is in the longest state in a natural state of the first elastic element, the side surface of the fixture block, which is close to the bottom of the clamping groove, is a plane, the end surface of the fixture block, which is close to the center of the clamping groove, is an inclined surface, and when the anchor moves in the clamping groove, the end of the anchor pushes the fixture block to the direction away from the center of the clamping groove by abutting against the inclined surface of the fixture block.

By adopting the technical scheme, when the anchor is abutted against the inclined surface of the clamping block, the clamping block extrudes the first elastic piece and automatically moves the clamping block outwards from the clamping groove; after the plate body is attached to the wall, the clamping blocks automatically rebound to clamp the end parts of the anchor bolts under the rebound action force of the first elastic piece, and the structure is simple and convenient to use.

Optionally, the panel body includes heat preservation core and gypsum board, and the heat preservation core arranges and the two fixed connection along the thickness direction of panel body with the gypsum board, and the draw-in groove sets up on the gypsum board.

Through adopting above-mentioned technical scheme, the heat preservation ability of heat preservation core guarantee panel body, and the hardness of gypsum board can promote the holistic physical properties such as resistance to deformation of panel body, and the draw-in groove is located the gypsum board simultaneously, is difficult for taking place to damage because of being connected with the anchor nail, and life hands over longer.

Optionally, a plurality of steel frames corresponding to the clamping grooves are fixedly arranged in the gypsum board, the clamping grooves are located in the center positions of the corresponding steel frames, and the clamping blocks are connected with the corresponding steel frames in a sliding mode.

Through adopting above-mentioned technical scheme, the steel frame has stronger hardness, when playing limiting displacement to the fixture block, great with the area of contact of panel body, is favorable to further increase of service life.

Optionally, a deformed steel bar is fixedly connected between the adjacent steel frames.

Through adopting above-mentioned technical scheme, the screw-thread steel plays the limiting action to the relative position between a plurality of steel frames, can strengthen the connection effect with the gypsum board simultaneously, is favorable to further increase of service life.

Optionally, the panel body is established to first side and second side along two sides of self central symmetry, has all seted up the spread groove on the heat preservation core of first side and second side, and sliding connection has the connecting block in the spread groove of first side, is equipped with the second elastic component between connecting block and the spread groove tank bottom, and under the second elastic component natural state, the length that the connecting block is located outside the spread groove is in the longest state.

By adopting the technical scheme, the connecting blocks are embedded into the connecting grooves on the second side edges of the adjacent plate bodies, so that the joint of the adjacent plate bodies forms a structure similar to a tongue-and-groove joint, and compared with a butt joint, the blocking of the connecting blocks can weaken the cold and hot bridge phenomenon at the joint, thereby improving the heat preservation effect.

Optionally, one side of the connecting block, which deviates from the connecting groove, is provided with a slope surface, and when the second side edge of the adjacent plate body abuts against the slope surface, the connecting block is pushed into the connecting groove corresponding to the first side edge.

Through adopting above-mentioned technical scheme, the user presses the panel body and carries out the in-process of installing, can push the spread groove with the connecting block automatically under domatic effect, and after panel body and wall laminating, the connecting block is in the spread groove of adjacent panel body second side edge of automatic slipping under the effect of second elastic component, and simple structure control is convenient.

In a second aspect, the application provides a processing technology of a flame-retardant composite insulation board, which comprises the following steps:

s1: the clamping block and the first elastic piece are well arranged according to the position of the clamping groove;

s2: and (3) forming the plate, namely embedding the clamping blocks and the like into the plate body by pouring, and compounding the heat-insulating material after solidification to improve the heat-insulating capacity of the plate body.

Through adopting above-mentioned technical scheme, utilize the pouring mode with the fixture block isotructure embedding panel body of joint anchor in, and then utilize the pressing mode to utilize the fixture block to realize installing the panel body with the joint of anchor, do not need the anchor to penetrate the panel body, weaken the cold and hot bridge phenomenon of anchor department, be favorable to improving the heat preservation effect.

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

1. the user firstly installs the anchor nail to a specific position on the wall body, then presses the plate body towards the direction close to the wall, so that the end part of the anchor nail is embedded into the clamping groove, the user controls the clamping block to slide out of the clamping groove, after the plate body is attached to the wall body, the clamping block moves into the clamping groove to limit the anchor nail, and then the connection between the wall and the plate body is realized by the anchor nail, and as the anchor nail is not needed to penetrate through the plate body, the cold and hot bridge phenomenon is weaker, and the heat insulation effect is higher;

2. the user presses the panel body and carries out the in-process of installing, can push the spread groove with the connecting block automatically under domatic effect, and panel body and wall laminating back, the connecting block is in the spread groove of adjacent panel body second side edge is slided automatically under the effect of second elastic component, makes the seam crossing of adjacent panel body form the structure of similar tongue-and-groove seam, compares in to the seam, and the cold and hot bridge phenomenon of seam crossing can be weakened in blockking of connecting block, and then improves the heat preservation effect.

Drawings

FIG. 1 is a schematic view of the overall structure of a flame-retardant composite insulation board of the present application.

Fig. 2 is a schematic view of the internal structure of the gypsum board of the present application.

FIG. 3 is a schematic cross-sectional structure view of a flame-retardant composite insulation board according to the present application.

Fig. 4 is an enlarged schematic view of a portion a in fig. 3.

FIG. 5 is a flow block diagram of a processing process of the flame-retardant composite insulation board.

Description of reference numerals: 100. anchoring the bolts; 1. a plate body; 11. a gypsum board; 12. a heat-insulating core material; 13. an impact resistant layer; 14. a decorative layer; 15. a first side edge; 16. a second side edge; 17. connecting grooves; 2. a steel frame; 21. a sleeve; 211. a card slot; 22. a clamping block; 221. a bevel; 23. a first elastic member; 3. deformed steel bar; 4. connecting blocks; 41. a slope surface; 5. a second elastic member.

Detailed Description

The present application is described in further detail below with reference to the accompanying drawings.

The embodiment of the application discloses flame-retardant composite insulation board.

Referring to fig. 1, a fire-retardant composite insulation board, panel body 1 including the rectangle, panel body 1 is followed self width direction and is in proper order by gypsum board 11, heat preservation core 12, shock resistance layer 13 and decorative layer 14 complex form, one side that gypsum board 11 deviates from heat preservation core 12 is equipped with the joint structure that is used for joint anchor nail 100, the user brushes the adhesive at the wall during installation, then in nailing anchor nail 100 into the wall, align anchor nail 100 with panel body 1's joint structure at last, press panel body 1 and be close to the wall, can make joint structure and anchor nail 100 joint, realize panel body 1's installation.

Referring to fig. 1, the clamping structure is uniformly distributed on the side of the gypsum board 11, and after a user brushes an adhesive, anchors 100 are installed on the wall according to the position of the clamping structure. The user selects the anchor 100 with the square end or the circular end, the embodiment selects the anchor 100 with the circular end, the user embeds the anchor 100 into the corresponding position, and the anchor 100 is exposed out of the wall by a specific length, so that the plate body 1 can be smoothly contacted with the wall.

Referring to fig. 1 and 2, the joint structure includes

steel frame

2, and 2 fixed mounting of steel frame are in gypsum board 11, and steel frame 2 is great with 11 area of contact of gypsum board, and is comparatively firm difficult for causing 1 damages of panel body. The welding has screw-thread steel 3 between adjacent steel frame 2, and under screw-thread steel 3's connection, all steel frame 2 become a whole, and the shaping of gypsum board 11 adopts the pouring mode, makes in the gypsum can get into steel frame 2, has better combination effect with steel frame 2, and life is longer, and under screw-thread steel 3's support, can promote performance such as the resistance to deformation ability of panel body 1.

Referring to fig. 1 and 3, a cylindrical sleeve 21 is fixedly installed at a middle position of the steel frame 2, a space in the sleeve 21 is a clamping groove 211, an axial direction of the sleeve 21 is arranged along a thickness direction of the plate body 1, and a cross section of the clamping groove 211 is matched with an end portion of the anchor 100, so that when a user presses the plate body 1 in a direction close to a wall, the clamping groove 211 is aligned with the corresponding anchor 100, and the end portion of the anchor 100 can be smoothly inserted into the clamping groove 211.

Referring to fig. 1 and 3, four locking blocks 22 extending into the locking grooves 211 to lock the end of the anchor 100 are installed at each sleeve 21, the locking blocks 22 and the steel frame 2 are made of the same material, and after the end of the anchor 100 moves to the side of the locking block 22 away from the wall, the locking blocks 22 block the end of the anchor 100 so that the anchor 100 cannot be separated from the locking grooves 211.

Referring to fig. 1 and 3, four fixture blocks 22 are arranged at equal intervals along the circumferential direction of the clamping groove 211, the fixture blocks 22 are all slidably connected with the steel frame 2 along the radial direction of the clamping groove 211, first elastic members 23 are fixedly mounted at ends of the fixture blocks 22, which are away from the clamping groove 211, the first elastic members 23 can be made of springs or other elastic materials with high heat preservation capability, and in a natural state of the first elastic members 23, the end portions of the fixture blocks 22 in the clamping groove 211 are in a longest state, and in a process that the end portions of the anchor 100 move to the bottom of the clamping groove 211, the fixture blocks 22 need to be avoided for movement of the end portions of the anchor 100.

Referring to fig. 4, the end surface of the fixture block 22 near the center of the locking groove 211 is an inclined surface 221, and the end of the anchor 100, moving towards the bottom of the locking groove 211, abuts against the inclined surfaces 221 of the four fixture blocks 22 at the same time, so that under the action of the pressing force of the user, the inclined surface 221 makes the fixture block 22 receive a component force sliding towards the outside of the locking groove 211, and further makes the fixture block 22 extrude the corresponding first elastic member 23, and the first elastic member 23 is compressed and shortened, thereby realizing the fixture block 22 sliding towards the outside of the locking groove 211, and making the end of the anchor 100 move to the bottom of the locking groove 211 smoothly.

Referring to fig. 1 and 4, the distance between the latch 22 and the groove bottom of the latch groove 211 is matched with the thickness of the end of the anchor 100, when the end of the anchor 100 moves to the groove bottom of the latch groove 211, the end of the anchor 100 is no longer abutted against the latch 22, and at this time, the latch 22 is re-extended into the latch groove 211 under the resilience force of the first elastic element 23. The side surface of the fixture block 22 close to the bottom of the clamping groove 211 is a plane parallel to the bottom of the clamping groove 211, and the plane of the fixture block 22 is abutted against one side of the end part of the anchor 100 close to the wall, so that the anchor 100 is clamped, and the connection firmness of the plate body 1 and the wall is guaranteed; meanwhile, as the anchor 100 is not needed to penetrate through the plate body 1, the cold and hot bridge phenomenon is weaker, and the heat insulation effect is higher.

Referring to fig. 1, there is also a partial cold-hot bridge problem at the joint of two adjacent plate bodies 1. The edge of the plate body 1 is provided with a connecting structure to reduce the cold and hot bridge phenomenon at the joint.

Referring to fig. 1, since the shape is rectangular, the plate body 1 coexists on four sides, wherein two sides symmetrical along the center of the plate body 1 are set as a group, and two sides of the same group are respectively set as a first side 15 and a second side 16, i.e., two adjacent sides are the first side 15, and the remaining two sides are the second side 16, when installed, a seam may be generated between the first side 15 and the second side 16 of the adjacent plate body 1.

Referring to fig. 1 and 3, the first side 15 and the second side 16 are both provided with a connecting groove 17, the connecting groove 17 is provided along the length direction of the corresponding side, wherein a second elastic element 5 is fixedly installed at the groove bottom inside the connecting groove 17 of the first side 15, and the second elastic element 5 can be made of a rubber block or other elastic material with heat preservation capability; sliding connection has connecting block 4 in the spread groove 17 of first side 15, and one side and the 5 butt of second elastic component of connecting block 4, under the 5 natural state of second elastic component, outside connecting block 4 other side extended to the spread groove 17 that corresponds, when installation panel body 1, the user aligns first side 15 of adjacent panel body 1 with second side 16, then presses panel body 1 to the direction that is close to the wall.

Referring to fig. 1 and fig. 3, when installing plate body 1, connecting block 4 of adjacent plate body 1 needs dodge, one side that connecting block 4 deviates from second elastic component 5 is equipped with domatic 41, at the in-process that plate body 1 is close to the wall, the domatic 41 butt of connecting block 4 on plate body 1's the edge and the adjacent plate body 1 of plate body 1, and under the component force effect, make connecting block 4 compress second elastic component 5, connecting block 4 removes in to spread groove 17 simultaneously, finally dodge for plate body 1's installation.

Referring to fig. 1 and 3, after the plate body 1 is attached to a wall, the connecting block 4 on the adjacent plate body 1 is embedded into the connecting groove 17 on the second side 16 of the plate body 1, and the connecting groove 17 on the second side 16 is matched with the connecting block 4 in shape; at this moment, the connecting blocks 4 seal the joints, the joints between the adjacent plate bodies 1 form a structure similar to a tongue-and-groove joint, and the connecting blocks 4 and the heat-insulating core materials 12 are made of the same material, so that compared with the butt joint, the joints of the method are under the effect of the connecting blocks 4, the cold and hot bridge phenomenon is weaker, and the method is suitable for the installation method of pressing the plate bodies 1.

Referring to fig. 1, finally, the user fills the joint between the adjacent plate bodies 1 by using polyurethane foaming or the like.

The implementation principle of the flame-retardant composite insulation board in the embodiment of the application is as follows: a user firstly installs the anchor 100 to a specific position on a wall body, then presses the plate body 1 to a direction close to the wall, so that the end part of the anchor 100 is embedded into the clamping groove 211, after the plate body 1 is attached to the wall body, the clamping block 22 moves into the clamping groove 211 to limit the position of the anchor 100, and then the connection between the wall and the plate body 1 is realized by using the anchor 100, and the cold and hot bridge phenomenon is weaker because the anchor 100 is not required to penetrate through the plate body 1; and the joint between the adjacent plate bodies 1 forms a structure similar to a tongue-and-groove joint, and the connecting blocks 4 and the heat insulation core material 12 are made of the same material, so that compared with butt joint, the joint of the method is under the action of the connecting blocks 4, the cold and hot bridge phenomenon is weaker, and the heat insulation effect is favorably improved.

The embodiment of the application also discloses a processing technology of the flame-retardant composite insulation board.

Referring to fig. 5, a processing technology of a flame-retardant composite insulation board comprises the following steps:

s1: discharging the fixture block 22, namely selecting a mould with a size corresponding to the gypsum board 11 by a user, discharging the steel frame 2 to a corresponding position in the mould according to the position of the clamping groove 211, welding the threaded rod with the steel frame 2, and then placing the first elastic piece 23 and the fixture block 22 at the corresponding position in the steel frame 2;

s2: the sheet material is formed, a user selects a cylindrical mold matched with the shape of the clamping groove 211 to be plugged into the position, corresponding to the clamping groove 211, of the steel frame 2, then gypsum is poured into the mold, the steel frame 2 is submerged by the gypsum, all the molds are removed after solidification, and then the heat insulation core material 12 and one side, away from the clamping groove 211, of the gypsum board 11 are compounded in a mode of using an adhesive and the like, so that the heat insulation capacity of the sheet material body 1 is guaranteed;

s3: installing the connecting block 4, digging connecting grooves 17 at a first side edge 15 and a second side edge 16 of the heat insulation core material 12 by a user, then inserting the second elastic element 5 and the connecting block 4 into the connecting grooves 17 in sequence, and enabling the slope 41 to be located on one side of the connecting block 4 departing from the connecting grooves 17;

s4: installing an impact resistant layer 13, and compounding the impact resistant layer 13 with a corresponding size on one side of the heat insulation core material 12, which is far away from the gypsum board 11, by a user;

s5: and adding the decorative layer 14, and compounding the decorative layer 14 on the side of the impact-resistant layer 13, which is far away from the heat-insulating core material 12, or spraying a specific color for decoration by a user to finish processing.

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

1. The utility model provides a fire-retardant composite insulation board, includes panel body (1) that has the heat preservation ability, its characterized in that: one side of panel body (1) is equipped with draw-in groove (211), and draw-in groove (211) can be followed self axial business turn over draw-in groove (211) in anchor (100), and draw-in groove (211) are located the cell wall of anchor (100) circumference and are equipped with a plurality of fixture blocks (22) that are used for spacing in draw-in groove (211) with anchor (100) end, and fixture block (22) all slide along the radial of anchor (100) and connect in panel body (1).

2. The flame-retardant composite insulation board according to claim 1, characterized in that: one side of the clamping block (22) departing from the anchor (100) is provided with a first elastic piece (23), the length of the clamping block (22) in the clamping groove (211) is in the longest state under the natural state of the first elastic piece (23), the side face, close to the groove bottom of the clamping groove (211), of the clamping block (22) is a plane, the end face, close to the center of the clamping groove (211), of the clamping block (22) is an inclined plane (221), and when the anchor (100) moves into the clamping groove (211), the end portion of the anchor (100) is abutted to the inclined plane (221) of the clamping block (22) to push the clamping block (22) to the direction far away from the center of the clamping groove (211).

3. The flame-retardant composite insulation board according to claim 1, characterized in that: the plate body (1) comprises a heat-insulation core material (12) and a gypsum board (11), the heat-insulation core material (12) and the gypsum board (11) are arranged along the thickness direction of the plate body (1) and are fixedly connected, and the clamping groove (211) is formed in the gypsum board (11).

4. The flame-retardant composite insulation board according to claim 3, characterized in that: a plurality of steel frames (2) corresponding to the clamping grooves (211) are fixedly arranged in the gypsum board (11), the clamping grooves (211) are located at the center positions of the corresponding steel frames (2), and the clamping blocks (22) are connected with the corresponding steel frames (2) in a sliding mode.

5. The flame-retardant composite insulation board according to claim 4, characterized in that: and the adjacent steel frames (2) are fixedly connected with a deformed steel bar (3).

6. The flame-retardant composite insulation board according to claim 3, characterized in that: plate body (1) is established to first side (15) and second side (16) along two sides of self central symmetry, spread groove (17) have all been seted up on heat preservation core (12) of first side (15) and second side (16), sliding connection has connecting block (4) in spread groove (17) of first side (15), be equipped with second elastic component (5) between connecting block (4) and spread groove (17) tank bottom, under second elastic component (5) natural state, connecting block (4) are located the outer length of spread groove (17) and are in the longest state.

7. The flame-retardant composite insulation board according to claim 6, characterized in that: one side that connecting block (4) deviates from spread groove (17) is equipped with domatic (41), when second side (16) butt domatic (41) of adjacent panel body (1), with connecting block (4) to pushing in spread groove (17) of corresponding first side (15).

8. A processing technology of a flame-retardant composite insulation board, which is applied to the flame-retardant composite insulation board as claimed in any one of claims 1 to 7, comprises the following steps:

s1: the clamping block (22) is discharged, and the clamping block (22) and the first elastic piece (23) are well discharged according to the position of the clamping groove (211);

s2: the plate is formed, the clamping blocks (22) and the like are embedded into the plate body (1) through pouring, and the heat insulation material is compounded after solidification, so that the heat insulation capacity of the plate body (1) is improved.