CN113863522B - Composite heat-insulating board and processing method thereof - Google Patents

Abstract

The invention belongs to the technical field of heat-insulating plate processing, and particularly relates to a composite heat-insulating plate and a processing method thereof; the technology can improve the effect of the composite insulation board on resisting the impact of sand and stone; the processing method of the composite heat-insulating plate comprises the following steps: s1: after cutting a pair of heat preservation boards, bending the two ends of the heat preservation boards respectively to enable the ends of the heat preservation boards to tilt; s2: controlling two ends of the heat-insulating plate to synchronously bend through the shaping assembly; s3: a positioning groove which can be attached to the wall body is processed on one of the heat-insulating plates; s4: the two heat-insulating boards are buckled in a staggered way, and then heat-insulating materials are filled in the heat-insulating boards to form a composite heat-insulating board; the composite heat-insulating plate comprises heat-insulating plates, assembling buckling edges and positioning grooves, the assembling buckling edges are arranged at two ends of the heat-insulating plates, the two heat-insulating plates are arranged, the two heat-insulating plates can be buckled together by the assembling buckling edges in a staggered manner, and a plurality of positioning grooves are formed in one heat-insulating plate.

Description

Composite heat-insulating board and processing method thereof

Technical Field

The invention belongs to the technical field of heat-insulating plate processing, and particularly relates to a composite heat-insulating plate and a processing method thereof.

Background

The traditional heat preservation and insulation material mainly improves the gas phase void ratio and reduces the heat conductivity coefficient and the conduction coefficient, and the fiber heat preservation material needs to have thicker coating in order to raise the convection heat transfer and the radiation heat transfer in the use environment; the inorganic heat-insulating materials such as the section materials are assembled and constructed, and the defects of more joints, attractive appearance, poor water resistance, short service life and the like exist, so that people are always seeking and researching a novel material capable of greatly improving the heat-insulating and reflecting properties of the heat-insulating materials; however, after the existing composite heat-insulating board is installed on a wall body, the effect of resisting sand and stone impact is poor.

Disclosure of Invention

In view of the above, the technical problem to be solved by the invention is to provide a composite insulation board and a processing method thereof, which can improve the effect of the composite insulation board on resisting sand and stone impact.

The invention provides a processing method of a composite insulation board, which comprises the following steps:

s1: after cutting a pair of heat preservation boards, bending the two ends of the heat preservation boards respectively to enable the ends of the heat preservation boards to tilt;

s2: controlling two ends of the heat-insulating plate to synchronously bend through the shaping assembly;

s3: a positioning groove which can be attached to the wall body is processed on one of the heat-insulating plates;

s4: and (3) buckling the two heat-insulating boards in a staggered manner, and then filling heat-insulating materials into the inner side to form the composite heat-insulating board.

The shaping assembly comprises a supporting plate, supporting arms, extension control arms, corner bending frames, pinch rollers and shaping wheel frames, the supporting arms are all installed at four corners of the upper end of the supporting plate, the corner bending frames are rotationally connected between the two supporting arms on the same side, two pinch rollers for bending the end parts of the heat insulation plates are installed on the corner bending frames, the extension control arms are all installed at the two ends of the corner bending frames, and the shaping wheel frames for positioning and compacting the heat insulation plates are installed between the two supporting arms on the same side.

The composite heat-insulating plate comprises heat-insulating plates, assembling buckling edges and positioning grooves, the assembling buckling edges are arranged at two ends of the heat-insulating plates, the two heat-insulating plates are arranged, the two heat-insulating plates can be buckled together by the assembling buckling edges in a staggered manner, and a plurality of positioning grooves are formed in one heat-insulating plate.

Drawings

The invention will be described in further detail with reference to the accompanying drawings and detailed description.

FIG. 1 is a flow chart of a method for processing a composite insulation board provided by the invention;

fig. 2 is a schematic structural view of an insulation board provided by the invention;

FIG. 3 is a schematic view of a positioning groove according to the present invention;

FIG. 4 is a schematic structural view of a pallet according to the present invention;

FIG. 5 is a schematic view of a carriage according to the present invention;

FIG. 6 is a schematic view of a pressing plate according to the present invention;

FIG. 7 is a schematic view of a top plate according to the present invention;

FIG. 8 is a schematic view of the structure of the grinding ring frame provided by the invention;

FIG. 9 is a schematic diagram of a belt according to the present invention;

FIG. 10 is a schematic view of a conveying roller according to the present invention;

FIG. 11 is a schematic diagram of a runner plate according to the present invention;

fig. 12 is a schematic structural view of a corner bending frame provided by the present invention;

FIG. 13 is a schematic view of the structure of the shaped wheel frame provided by the invention;

FIG. 14 is a schematic diagram of a puck according to the present invention;

FIG. 15 is a schematic view of a control lever according to the present invention;

FIG. 16 is a schematic view of a positioning carriage according to the present invention;

FIG. 17 is a schematic view of the structure of the hollow transfer roller provided by the invention;

FIG. 18 is a schematic view of the structure of the interceptor arm of the present invention;

fig. 19 is a schematic structural view of a turret according to the present invention.

Detailed Description

The invention provides a composite insulation board and a processing method thereof, and the composite insulation board and the processing method thereof are described in detail by combining the drawings in the embodiment of the invention.

A processing method of a composite insulation board comprises the following steps:

s1: after cutting a pair of heat preservation boards, bending the two ends of the heat preservation boards respectively to enable the ends of the heat preservation boards to tilt;

s2: controlling two ends of the heat-insulating plate to synchronously bend through the shaping assembly;

s3: a positioning groove which can be attached to the wall body is processed on one of the heat-insulating plates;

s4: and (3) buckling the two heat-insulating boards in a staggered manner, and then filling heat-insulating materials into the inner side to form the composite heat-insulating board.

The material filled between the two heat-insulating plates can be an expanding agent;

the heat-insulating plate can resist the impact of sand and stone;

the heat insulation material can realize heat insulation performance.

Embodiments of the present invention are described with reference to fig. 3, 9-12:

the shaping assembly comprises a supporting plate 2.1, supporting arms 2.2, an extension control arm 6.2, corner bending frames 6.4, pinch rollers 6.5 and shaping wheel frames 6.6, wherein the supporting arms 2.2 are fixedly connected to four corners of the upper side face of the supporting plate 2.1, the corner bending frames 6.4 are rotationally connected between the two supporting arms 2.2 on the same side, the corner bending frames 6.4 are hinged to the two pinch rollers 6.5 capable of bending the edge of the heat-insulating plate, the extension control arm 6.2 is mounted at two ends of the corner bending frames 6.4, and the shaping wheel frames 6.6 capable of positioning and compacting the heat-insulating plate are fixedly connected between the two supporting arms 2.2 on the same side.

The heat-insulating board is supported by the shaping wheel frames 6.6 at the two sides, and then the corner bending frame 6.4 rotates by taking the axis of the pin shaft of the corner bending frame as a shaft by prolonging the control arm 6.2, so that the two ends of the heat-insulating board are curled;

in the process of controlling the corner bending frame 6.4 to rotate by taking the axis of the pin shaft of the corner bending frame as an axis, the pinch roller 6.5 can be controlled to rotate by taking the axis of the corner bending frame as an axis in a manual mode, so that the pinch roller 6.5 rubs the edge of the heat-insulating plate, the temperature of the bending part is increased, the heat-insulating plate is easy to deform, and the surface effect of the deformed part can be increased;

the tilting center of the processed heat-insulating plate is collinear with the axis of a pin shaft for controlling the corner bending frame 6.4 to be hinged on the supporting arm 2.2;

after the hemming processing is repeatedly carried out on the two heat-insulating boards, the two heat-insulating boards can be mutually buckled, and then the heat-insulating materials are filled in the heat-insulating boards to form the composite heat-insulating board;

the heat-insulating plate can resist the impact of sand and stone;

the two corner bending frames 6.4 are controlled to synchronously rotate by the extension control arm 6.2, so that the two ends of the heat insulation plate can be synchronously bent, and the stability of the device for clamping and supporting the heat insulation plate is improved.

Embodiments of the present invention are described with reference to fig. 9-12:

a heating column is arranged in the pinch roller 6.5, and two power receiving ends of the heating column are respectively connected with the anode and the cathode of the power supply. The heating column is designed, so that the bending convenience effect of the device on the heat insulation board can be improved;

further, the design of the heating column can enable the device to bend the heat insulation plate, and after heat treatment, the fatigue degree of the bending position due to deformation is reduced.

Embodiments of the present invention are described with reference to fig. 12-14:

the shaping wheel frame 6.6 is fixedly connected with a flat pressing frame 6.7, the flat pressing frame 6.7 is in surface contact with two sides of the heat insulation board, and the flat pressing frame 6.7 is in fit with the round side face of the pressing wheel 6.5.

In the process of bending the edge of the heat-insulating plate by the pinch roller 6.5, the flat pressing frame 6.7 can improve the laminating effect of the device and the ground of the heat-insulating plate, so that the boundary between the upturned part and the flat part of the heat-insulating plate is more clear, and the heat-insulating materials are convenient to fill in the two heat-insulating plates;

the design of the fit between the flattening frame 6.7 and the lateral part of the pinch roller 6.5 can increase the edge flattening effect when conveying the heat insulation board.

Embodiments of the present invention are described with reference to fig. 11-12, 14:

the extension control arm 6.2 is detachably and fixedly connected with the corner bending frame 6.4 through a polygonal pin 6.3, a sliding frame 2.3 is fixedly connected to the supporting plate 2.1, the sliding groove plate 6.1 is slidably connected to the sliding frame 2.3, two ends of the sliding groove plate 6.1 are respectively slidably connected with the extension control arms 6.2 on the two corner bending frames 6.4, and the sliding frame 2.3 is provided with two.

The sliding groove plate 6.1 is controlled to slide on the sliding frame 2.3, so that the two extension control arms 6.2 are driven to rotate, and the effect of hemming the edge of the heat insulation plate is achieved;

the design of the control arm 6.2 is prolonged, so that the labor-saving effect is achieved when the corner bending frame 6.4 carries out hemming processing on the edge of the heat-insulating plate;

the corner bending frame 6.4 and the extension control arm 6.2 are detachably and fixedly connected through the polygonal pin 6.3, and the design is convenient for adjusting the rotation amplitude of the extension control arm 6.2 for a plurality of times;

the sliding groove plate 6.1 is controlled to slide back and forth on the sliding frame 2.3, so that the shaping effect of the corner bending frame 6.4 on the tilting position of the heat-insulating plate can be improved.

Embodiments of the present invention are described with reference to fig. 9-10:

the shaping assembly further comprises a mounting frame 4.1, a transmission wheel frame 4.2, a conveying roller 4.3, a transmission belt 4.4 and a splicing conveying roller 4.5, wherein two mounting frames 4.1 are symmetrically and fixedly connected to the supporting plate 2.1, the conveying roller 4.3 is hinged between the two mounting frames 4.1, the conveying roller 4.3 is provided with a plurality of transmission wheel frames 4.2, the transmission wheel frames 4.2 are provided with a plurality of transmission wheels, the conveying roller 4.3 is connected with the transmission wheel frames 4.2 in a transmission mode through the transmission belt 4.4, and the splicing conveying roller 4.5 is connected in a sliding mode between the transmission wheel frames 4.2.

A gear motor I for controlling the conveying roller 4.3 to rotate by taking the axis of the gear motor I as a shaft is arranged on the mounting frame 4.1, and then the transmission wheel frame 4.2 and the conveying roller 4.3 are driven to synchronously rotate by the transmission belt 4.4, so that the effect of conveying the heat insulation board is realized;

the transmission wheel frames 4.2 and the conveying rollers 4.3 which are positioned at the upper side and the lower side are respectively controlled by two groups of gear motors I and transmission belts 4.4;

the transmission wheel frame 4.2 is clamped with the splicing conveying roller 4.5, so that the transmission wheel frame 4.2 drives the splicing conveying roller 4.5 to rotate together, and the distance between the transmission wheel frame 4.2 and the end part of the splicing conveying roller 4.5 can be changed, thereby being convenient for processing the middle part of the insulation board by the device.

Embodiments of the present invention are described with reference to fig. 15-16, 18:

the shaping assembly further comprises a control frame 5.1 and a control rod 5.2, a plurality of splicing conveying rollers 4.5 on the same installation frame 4.1 are all rotationally connected to the control frame 5.1, the control frame 5.1 is fixedly connected with the control rod 5.2, and the control rod 5.2 is slidably connected to the sliding frame 2.3.

Make control lever 5.2 slide on balladeur train 2.3, can make control frame 5.1 drive a plurality of concatenation conveying rollers 4.5 and remove to spill the upside of heated board, be convenient for then install and process the middle part of heated board.

Embodiments of the present invention are described with reference to fig. 15-18:

the shaping assembly further comprises a positioning sliding seat 5.3, a synchronous frame 7.1 and scraping strips 7.2, wherein a plurality of positioning sliding seats 5.3 are arranged on the control rod 5.2, the synchronous frame 7.1 is in sliding connection with the plurality of positioning sliding seats 5.3, a plurality of scraping strips 7.2 are arranged on the synchronous frame 7.1, the splicing conveying roller 4.5 is divided into a hollow conveying roller 4.5.1 and a solid conveying roller 4.5.2, the hollow conveying roller 4.5.1 is positioned at the upper side, the scraping strips 7.2 penetrate through the hollow conveying roller 4.5.1, and a positioning extending assembly is arranged between the positioning sliding seat 5.3 and the synchronous frame 7.1.

The scraping strip 7.2 can automatically fall in the hollow conveying roller 4.5.1 in the process of sliding the control rod 5.2 on the sliding frame 2.3 through the positioning and extending assembly, and then a groove is processed in the middle of the inner side of the heat insulation plate after the control rod 5.2 continues to slide on the sliding frame 2.3;

the design of recess can play the direction and the spacing effect to insulation material to make the laminating effect between insulation material and the heated board improve.

Embodiments of the present invention are described with reference to fig. 5, 18-19:

the positioning and extending assembly comprises a rotating frame 2.4 and an interception arm 2.5, springs I are arranged between a synchronous frame 7.1 and a plurality of positioning sliding seats 5.3, the rotating frame 2.4 is symmetrically arranged on two sides of the sliding frame 2.3, the interception arm 2.5 is rotatably connected to the rotating frame 2.4, a torsion spring is arranged between the rotating frame 2.4 and the interception arm 2.5, and the interception arm 2.5 is matched with the synchronous frame 7.1.

The design of the spring I, the torsion spring, the rotating frame 2.4 and the interception arm 2.5 can realize the automatic limiting effect on the synchronous frame 7.1;

the device carries out hemming processing and groove processing to the edge of the heat insulation board and can synchronously process, and the clamping and supporting of the heat insulation board by the process device can be kept, so that the track of the processed groove is smooth.

An embodiment of the invention is described with reference to fig. 2-3:

the composite heat-insulating board comprises heat-insulating boards 1.1, assembling buckle edges 1.2 and positioning grooves 1.3, the assembling buckle edges 1.2 are arranged on two sides of the heat-insulating boards 1.1, the two heat-insulating boards 1.1 are arranged, the two heat-insulating boards 1.1 can be buckled together by the assembling buckle edges 1.2 in a staggered manner, and a plurality of positioning grooves 1.3 are formed in one heat-insulating board 1.1.

The heat-insulating plates 1.1 are made of harder materials, the two heat-insulating plates 1.1 are buckled together through the assembling buckle edges 1.2, and a space is reserved between the two heat-insulating plates 1.1 for filling heat-insulating materials;

the design of the positioning groove 1.3 can increase the effect of installing the heat insulation board 1.1 on one side on the wall body.

Embodiments of the present invention are described with reference to fig. 4-6, 8-9:

the positioning groove 1.3 is machined through a pressing assembly, the pressing assembly comprises a lifting seat 2.6, a pressing plate 2.7, a pressing table 2.8, a pressing ring frame 3.1, an outer tooth ring 3.2 and a top plate 3.3, the lifting seat 2.6 is connected to the supporting plate 2.1 in a sliding mode, the lifting seat 2.6 is connected to the plurality of pressing ring frames 3.1 in a rotating mode, the top plate 3.3 is connected to the pressing ring frame 3.1 in a sliding mode, a spring II is installed between the top plate 3.3 and the pressing ring frame 3.1, an outer tooth ring 3.2 is installed on the pressing ring frame 3.1, the pressing plate 2.7 is connected to the supporting plate 2.1 in a sliding mode, the pressing table 2.8 is matched with the pressing ring frame 3.1 and the top plate 3.3.

A telescopic rod is arranged between the supporting plate 2.1 and the lifting seat 2.6, and the lifting seat 2.6 drives the grinding and pressing ring frame 3.1 to be attached to the lower end of the heat insulation plate 1.1 by starting the telescopic rod;

a gear motor II for driving the outer gear ring 3.2 to rotate by taking the axis of the gear motor II as a shaft is arranged on the lifting seat 2.6, a driving gear is arranged on an output shaft of the gear motor II, the driving gear is in transmission connection with the outer gear ring 3.2, the gear motor II is started, the annular position on the lower side of the heat insulation plate 1.1 can be rubbed, and then a positioning groove 1.3 is processed on the heat insulation plate 1.1 under the pressing of the pressing table 2.8;

the design of roof 3.3 can jack-up the position after the deformation voluntarily, avoids the material of positioning groove 1.3 department to take place to tear.

Claims (4)

1. A processing method of a composite insulation board is characterized in that: the method comprises the following steps:

s1: after cutting a pair of heat preservation boards, bending the two ends of the heat preservation boards respectively to enable the ends of the heat preservation boards to tilt;

s2: controlling two ends of the heat-insulating plate to synchronously bend through the shaping assembly;

s3: a positioning groove which can be attached to the wall body is processed on one of the heat-insulating plates;

s4: the two heat-insulating boards are buckled up in a staggered way, then heat-insulating materials are filled at the inner side to form the composite heat-insulating board,

the shaping assembly comprises a supporting plate (2.1), supporting arms (2.2), an extension control arm (6.2), a corner bending frame (6.4), a pressing wheel (6.5) and a shaping wheel frame (6.6), wherein the supporting arms (2.2) are arranged at four corners of the upper end of the supporting plate (2.1), and two supporting arms (2.2) on the same side

The corner bending frame (6.4) is rotationally connected between the two support arms, two pinch rollers (6.5) for bending the end parts of the heat insulation boards are arranged on the corner bending frame (6.4), extension control arms (6.2) are arranged at the two ends of the corner bending frame (6.4), a shaping wheel frame (6.6) for positioning and compacting the heat insulation boards is arranged between the two support arms (2.2) at the same side,

a flat pressing frame (6.7) is arranged on the shaping wheel frame (6.6), the flat pressing frame (6.7) is contacted with two sides of the heat insulation board through surfaces, the flat pressing frame (6.7) is matched with the side part of the pinch roller (6.5) in a fitting way,

the extension control arm (6.2) is detachably connected with the corner bending frame (6.4) through a polygonal pin (6.3), a carriage (2.3) is arranged on the supporting plate (2.1), a sliding groove plate (6.1) is connected on the carriage (2.3) in a sliding way, two ends of the sliding groove plate (6.1) are respectively connected with the extension control arms (6.2) on the two corner bending frames (6.4) in a sliding way, the carriage (2.3) is provided with two,

the shaping assembly further comprises a mounting frame (4.1), a transmission wheel frame (4.2), conveying rollers (4.3), a transmission belt (4.4) and splicing conveying rollers (4.5), two mounting frames (4.1) are symmetrically arranged on the supporting plate (2.1), a plurality of conveying rollers (4.3) are rotationally connected between the two mounting frames (4.1), a plurality of transmission wheel frames (4.2) are rotationally connected on the two mounting frames (4.1) respectively, the transmission wheel frames (4.2) are in transmission connection with the conveying rollers (4.3) through the transmission belt (4.4), the splicing conveying rollers (4.5) are in sliding connection with the transmission wheel frames (4.2),

the shaping assembly also comprises a control frame (5.1) and a control rod (5.2), a plurality of splicing conveying rollers (4.5) on one mounting frame (4.1) are all rotationally connected to the control frame (5.1), the control rod (5.2) is arranged on the control frame (5.1), the control rod (5.2) is in sliding connection with the sliding frame (2.3),

the shaping assembly further comprises a positioning sliding seat (5.3), a synchronous frame (7.1) and scraping strips (7.2), wherein a plurality of positioning sliding seats (5.3) are arranged on the control rod (5.2), the synchronous frame (7.1) is in sliding connection with the plurality of positioning sliding seats (5.3), the synchronous frame (7.1) is provided with the plurality of scraping strips (7.2), the splicing conveying roller (4.5) is divided into a hollow conveying roller (4.5.1) and a solid conveying roller (4.5.2), the hollow conveying roller (4.5.1) is located at the upper side, the scraping strips (7.2) penetrate through the hollow conveying roller (4.5.1), and a positioning extending assembly is arranged between the positioning sliding seat (5.3) and the synchronous frame (7.1).

2. The method for processing the composite insulation board according to claim 1, wherein the method comprises the following steps: a heating column is arranged in the pinch roller (6.5).

3. The method for processing the composite insulation board according to claim 1, wherein the method comprises the following steps: the positioning and extending assembly comprises a rotating frame (2.4) and an interception arm (2.5), springs I are arranged between a synchronous frame (7.1) and a plurality of positioning sliding seats (5.3), the rotating frame (2.4) is symmetrically arranged on two sides of the sliding frame (2.3), the interception arm (2.5) is rotationally connected to the rotating frame (2.4), a torsion spring is arranged between the rotating frame (2.4) and the interception arm (2.5), and the interception arm (2.5) is matched with the synchronous frame (7.1).

4. The composite insulation board processed by the composite insulation board processing method according to claim 3 is characterized by comprising insulation boards (1.1), assembling buckle edges (1.2) and positioning grooves (1.3), wherein the assembling buckle edges (1.2) are arranged at two ends of the insulation boards (1.1), the two insulation boards (1.1) are arranged, the two insulation boards (1.1) can be buckled together by the assembling buckle edges (1.2), and a plurality of positioning grooves (1.3) are formed in one insulation board (1.1).