CN112081298B - Composite heat-insulating wallboard and processing equipment - Google Patents

Abstract

The invention discloses a composite heat-insulation wallboard and processing equipment, which comprise a first panel, a second panel and a heat-insulation core layer arranged between the first panel and the second panel, wherein the first panel, the second panel and the heat-insulation core layer jointly form a composite heat-insulation board, and a first connecting piece and a second connecting piece are respectively arranged on two opposite sides of the composite heat-insulation board, the composite heat-insulation board is connected with the first connecting piece and the second connecting piece in a matching way, so that the composite heat-insulation boards can be paved on a straight wall surface or paved on an external corner of the wall surface and can be directly spliced through the first connecting piece and the second connecting piece, the sealing property of the joint of the two composite heat-insulation boards is increased, the joint of the two composite heat-insulation boards has higher firmness and safety, and the two composite heat-insulation boards can be directly spliced and installed at the external corner, the construction efficiency is high, the construction mode is simple, the connection mode is universal at the straight wall surface and the external corner.

Description

Composite heat-insulating wallboard and processing equipment

Technical Field

The invention relates to the technical field of building materials, in particular to a composite heat-insulation wallboard and processing equipment.

Background

A composite thermal-insulating wall board is an assembled building material and has a sandwich structure, and is composed of two face plates, which are wrapped by internal thermal-insulating core layer consisting of foamed polystyrene plate, profiled steel plate and galvanized steel plate.

Present composite insulation wallboard when laying, generally with polylith composite insulation wallboard bonding smooth on the wall, then rely on the external fixation mode to fix composite insulation wallboard and accomplish on the wall and lay, nevertheless have corresponding defect when current composite insulation wallboard is laid:

1. the composite heat-insulation wall boards lack a connecting structure for auxiliary connection, the two composite heat-insulation wall boards are directly paved during laying, and are connected through filling mortar or using an external connecting piece, so that the connecting strength, firmness and safety of the connecting part between the two composite heat-insulation wall boards are low;

2. secondly, at the external corner department of outer wall, can't directly install between two compound insulation wallboard, be difficult to carry out seamless concatenation, need carry out field machining to it, not only the efficiency of construction is lower, and the firm of junction and degree of safety are all lower.

Disclosure of Invention

The invention aims to provide a composite heat-insulation wallboard and processing equipment, and solves the problems that the existing composite heat-insulation wallboard is directly paved on a wall surface so that the firmness and safety of a joint are low, and the composite heat-insulation wallboard needs to be additionally processed at the external corner of an external wall so that the construction efficiency is low and the firmness and safety of the joint are low.

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

the utility model provides a composite insulation wallboard, is in including first panel, second panel and setting heat preservation sandwich layer between first panel and the second panel, composite insulation board is constituteed jointly to first panel, second panel and heat preservation sandwich layer, the both sides that carry on the back mutually on the composite insulation board are provided with first connecting piece and second connecting piece respectively, and pass through cooperation connected mode between first connecting piece and the second connecting piece realizes between a plurality of heat preservation composite sheet that the general cooperation of external corner department and non-external corner department is connected.

As a preferable scheme of the present invention, the first connecting member includes a first extending panel and a first extending core layer, the first extending panel is connected to one side of the first panel, the first extending core layer is connected to one side of the heat insulating core layer, and the first extending core layer is provided with a plurality of fitting grooves at equal intervals;

the second connecting piece includes that the second extends the panel and extends the core layer group, just the second extend the panel with one side of second panel is connected, keep away from on the second extends the panel one side of second panel outwards extends there is the bar piece, extend core layer group including a plurality of with the cooperation piece that the opposite side of heat preservation core layer is connected, and every the cooperation piece all with another cooperation groove on the composite insulation board corresponds and is connected.

In a preferred embodiment of the present invention, the thickness of the first core extension layer is equal to the length of the fitting block, and the thickness of the first core extension layer is equal to the depth of the fitting groove.

In a preferred embodiment of the present invention, the first panel and the second panel have the same thickness, and the vertical distance between the bottom of the fitting groove and the end of the second panel is the same as the extension length of the bar block.

In order to solve the above technical problems, the present invention further provides the following technical solutions:

a processing device for a composite heat-insulation wallboard comprises a raw material processing chamber for producing the composite heat-insulation board and a characteristic processing device for performing characteristic processing on the composite heat-insulation board produced by the raw material processing chamber, wherein the composite heat-insulation board is transported from the raw material processing chamber to the characteristic processing device through a product transporting device;

the characteristic processing device comprises a processing table and clamping pieces, wherein the processing table is used for receiving the composite insulation board to be processed, the clamping pieces are arranged on two sides of the processing table and used for installing the composite insulation board, and the processing table is provided with characteristic processing pieces used for processing the characteristics of the first connecting piece and the second connecting piece on the composite insulation board.

As a preferred scheme of the invention, the characteristic processing part comprises two portal frames arranged on the processing table, each portal frame is provided with a hydraulic telescopic device, a horizontal displacement assembly for driving the hydraulic telescopic device to do linear motion is arranged between each portal frame and the corresponding hydraulic telescopic device, the bottom of each hydraulic telescopic device is provided with a connecting seat, the bottom of one connecting seat is provided with a longitudinal cutting edge, the bottom of the other connecting seat is provided with a transverse cutting edge, and the composite heat-insulation board is driven by a clamping piece to process the structural characteristics of the first connecting piece and the second connecting piece sequentially through the longitudinal cutting edge and the transverse cutting edge.

As a preferred scheme of the invention, the clamping member comprises two side seats symmetrically arranged at two sides of the processing table and two longitudinal movement grooves arranged at one opposite side of the two side seats, a longitudinal movement screw is arranged in each longitudinal movement groove through a bearing, one end of each longitudinal movement screw is connected with a first driving device, each longitudinal movement screw is in threaded connection with a threaded connection seat in sliding connection with the inside of the longitudinal movement groove, each threaded connection seat is provided with a transverse movement assembly, one opposite side of each threaded connection seat is provided with an L-shaped clamping plate for clamping the composite insulation board, and the transverse movement assemblies drive the corresponding L-shaped clamping plates to move oppositely to clamp the composite insulation board.

As a preferable scheme of the invention, the transverse movement assembly comprises a transverse movement groove arranged on the threaded connecting seat and a transverse movement screw rod arranged in the transverse movement groove through a bearing, one end of the transverse movement screw rod is connected with a second driving device, a threaded clamping seat in sliding connection with the inside of the transverse movement groove is in threaded connection with the transverse movement screw rod, and a transmission connecting rod connected with the L-shaped clamping plate is fixedly connected to the threaded clamping seat.

As a preferable scheme of the invention, a plurality of sliding rods are arranged on one side of the L-shaped clamping plate at equal intervals, a plurality of sliding grooves are formed on the threaded connecting seat corresponding to the sliding rods, and each sliding rod is slidably connected in the corresponding sliding groove.

As a preferable scheme of the present invention, the processing table includes two supports, the clamping member and the feature processing member are both mounted on the supports, a plurality of transverse support plates are disposed between the two supports at equal intervals, and a plurality of longitudinal support plates are disposed between two adjacent transverse support plates at equal intervals.

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

according to the invention, the first connecting piece and the second connecting piece are connected in a matched manner, so that the composite heat-insulation boards can be laid on a straight wall or can be directly spliced at the external corner of the wall through the first connecting piece and the second connecting piece, the sealing property of the joint of the two composite heat-insulation boards is increased, the joint of the two composite heat-insulation boards has higher firmness and safety, the two composite heat-insulation boards can be directly spliced and installed at the external corner, the construction efficiency is high, the construction mode is simple, and the connection mode is universal at the straight wall and the external corner.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below. It should be apparent that the drawings in the following description are merely exemplary, and that other embodiments can be derived from the drawings provided by those of ordinary skill in the art without inventive effort.

FIG. 1 is a schematic structural view of a composite thermal insulation wallboard according to an embodiment of the present invention;

FIG. 2 is a schematic bottom structure view of a composite thermal insulation wall panel according to an embodiment of the present invention;

FIG. 3 is a schematic top view of a composite thermal insulation wallboard according to an embodiment of the present invention;

FIG. 4 is a schematic structural diagram of a processing apparatus for composite thermal insulation wall panels according to an embodiment of the present invention;

FIG. 5 is a schematic structural view of a portion of a lateral motion assembly according to an embodiment of the present invention;

fig. 6 is a schematic structural diagram of a processing table according to an embodiment of the present invention.

The reference numerals in the drawings denote the following, respectively:

1-a first panel; 2-a second panel; 3-heat preservation core layer; 4-a first connector; 5-a second connector; 6-a raw material processing chamber; 7-feature processing means;

401-a first extension panel; 402-a first extended core layer; 403-mating grooves;

501-a second extension panel; 502-extending a core layer group; 503-bar block; 504-a fitting block;

701-a processing table; 702-a clamp; 703-feature processing piece; 704-a portal frame; 705-hydraulic telescoping device; 706-horizontal displacement assembly; 707-a connecting seat; 708-a longitudinal cutting edge; 709-transverse cutting edge; 710-side seats; 711-longitudinal movement groove; 712-a longitudinally moving screw; 713-screw joint seat; 714-a lateral motion assembly; 715-L-shaped splints; 716-a lateral movement slot; 717-transverse movement screw; 718-a threaded clamping seat; 719-drive link; 720-a slide bar; 721-a chute; 722-a bracket; 723-transverse support plate; 724-longitudinal support plate.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example 1:

as shown in fig. 1 to 3, the invention provides a composite thermal insulation wallboard, which comprises a first panel 1, a second panel 2 and a thermal insulation core layer 3 arranged between the first panel 1 and the second panel 2, wherein the first panel 1, the second panel 2 and the thermal insulation core layer 3 jointly form a composite thermal insulation board, two opposite sides of the composite thermal insulation board are respectively provided with a first connecting piece 4 and a second connecting piece 5, and the universal matching connection between a plurality of thermal insulation composite boards at an external corner and a non-external corner is realized through the matching connection mode between the first connecting piece 4 and the second connecting piece 5.

When the composite insulation board is used, the first connecting piece 4 and the second connecting piece 5 which are arranged on the two sides of the composite insulation board are matched and connected, so that the composite insulation board is universally connected, the composite insulation board can be directly spliced and installed, and the problem of low construction efficiency caused by the fact that extra processing is needed in the traditional installation at an external corner is solved.

Accompany the heat preservation sandwich layer between first panel 1 and the second panel 2, first panel 1 and second panel 2 all are the construction face, by 3 its heat preservation effects of middle heat preservation sandwich layer, and by the prefabricated shaping of the composite insulation board that first panel 1, second panel 2 and the combination of heat preservation sandwich layer 3 formed, can effectively accelerate the heat preservation efficiency of construction of outer wall body.

The first connecting piece 4 comprises a first extending panel 401 and a first extending core layer 402, the first extending panel 401 is connected with one side of the first panel 1, the first extending core layer 402 is connected with one side of the heat preservation core layer 3, and a plurality of matching grooves 403 are formed in the first extending core layer 402 at equal intervals;

the second connecting piece 5 includes the second and extends panel 501 and extends core layer group 502, and the second extends panel 501 and is connected with one side of second panel 2, and the second extends the panel 501 on keep away from one side of second panel 2 and outwards extends there is the bar piece 503, extends core layer group 502 and includes a plurality of cooperation pieces 504 of being connected with the opposite side of heat preservation core layer 3, and every cooperation piece 504 all corresponds with cooperation groove 403 on another composite insulation board and is connected.

The first extended core layer 402 and the extended core layer group 502 have the same properties and are made of the same material as the thermal insulation core layer 3.

When the first connecting piece 4 and the second connecting piece 5 are connected in a matching mode, the two conditions of straight wall surfaces and splicing at external corners of the wall surfaces are divided.

When the straight wall is installed, the two composite heat-insulation boards which are spliced are placed in opposite directions, namely the first panel 1 of one composite heat-insulation board is close to the wall, the second panel 2 of the other composite heat-insulation board is close to the wall for installation, and the two composite heat-insulation boards are spliced after being overturned.

Install one of them composite insulation board on the wall earlier, in this embodiment, the second panel 2 on this composite insulation board is installed with the wall laminating, then with the first connecting piece 4 of another composite insulation board and the second connecting piece 5 accordant connection on this composite insulation board.

Because two composite insulation boards are located same height on the horizontal direction, consequently with another composite insulation board laminating back on the wall, the location is accomplished to the relative position between cooperation piece 504 and the cooperation groove 403, can directly splice, directly promotes composite insulation board and inserts cooperation piece 504 and establish into the cooperation groove 403 that corresponds in, two composite insulation boards accomplish the connection.

Realize the dislocation cooperation of junction between two heat preservation sandwich layers 3 through being connected between cooperation piece 504 and the cooperation groove 403 and connect for the junction has higher firmness and security, and has better adaptation, and the heat preservation effect is better.

When installation of external corner wall department, at first install a composite insulation board to the wall on for second panel 2 and wall laminating installation, and the wall parallel and level of the tip of second panel 2 and opposite side, first connecting piece 4 is located the external corner department.

Then install another composite insulation board installation laminating to the wall of opposite side on, correspond second connecting piece 5 directly with first connecting piece 4 and be connected, cooperation piece 504 corresponds to insert establishes to cooperation groove 403 in, the crisscross concatenation between two heat preservation sandwich layers 3 for the junction has higher firmness and security, secondly, needn't directly can splice the installation, and the efficiency of construction is higher.

Through two concatenation modes between first connecting piece 4 and the second connecting piece 5 for there is the concatenation mode that can use the passing through in straight wall face and external corner department between the composite insulation board, and can guarantee that composite insulation board's self function is unchangeable.

The thickness of the first extended core layer 402 is the same as the length of the mating block 504, and the thickness of the first extended core layer 402 is the same as the depth of the mating groove 403.

In order to ensure that the first connector 4 and the second connector 5 can be spliced in a time-limited and complete manner in both cases, the thickness of the first extended core 402, the length of the mating block 504 and the depth of the mating groove 403 are designed to be the same.

When the vertical wall is installed, the matching block 504 and the matching groove 403 can be completely and tightly connected, when the vertical wall is installed at the external corner, the matching block 504 needs to be inserted from the other side of the matching groove 403, the thickness of the first extending core layer 402 is consistent with the length of the matching block 504, and the connection can be completely and tightly connected.

The first panel 1 and the second panel 2 have the same thickness, and the vertical distance between the bottom of the fitting groove 403 and the end of the second panel 2 is the same as the extension length of the bar block 503.

When the panel is installed at the external corner, the corners of the ends of the first extension panel 401 and the second extension panel 502 are abutted, and the tightness of the first extension core layer 402 and the extension core layer group 502 inside is poor, so that the second extension panel 501 is extended outwards to form a sealed connection part by a strip-shaped block 503, the length of the strip-shaped block 503 should be the same as the thickness of the first panel 1, and the sealed connection part is just sealed, and the appearance is high.

Secondly, the tip of the second panel that is located same composite insulation board with strip-shaped piece 503 can offset with one side of first extension panel 401, need first extension core layer 402 on have a support region, consequently set up the perpendicular interval of the bottom of cooperation groove 403 and 2 tip of second panel and the extension length of strip-shaped piece 503 the same be used for offset with 2 tip of second panel, secondly when straight wall is connected, strip-shaped piece 503 also can directly accomplish closed connection with this region, does not influence composite insulation board's performance.

Example 2:

as shown in fig. 4 to 6, the invention provides a processing device for a composite heat-insulating wall panel, which comprises a raw material processing chamber 6 for producing a composite heat-insulating plate, and a characteristic processing device 7 for performing characteristic processing on the composite heat-insulating plate produced by the raw material processing chamber 6, wherein the composite heat-insulating plate is transported from the raw material processing chamber 6 to the characteristic processing device 7 by a product transporting device;

the characteristic processing device 7 comprises a processing table 701 for receiving the composite insulation board to be processed and clamping pieces 702 arranged on two sides of the processing table 701 and used for installing the composite insulation board, wherein the processing table 701 is provided with characteristic processing pieces 703 for processing characteristics of the first connecting piece 4 and the second connecting piece 5 on the composite insulation board.

In this embodiment, the composite insulation board is produced in the raw material processing chamber 6, and is transported to the characteristic processing device 7 through the product transportation device to be processed with the characteristic, and the structural characteristics of the first connecting piece 4 and the second connecting piece 5 are processed on the two sides of the composite insulation board.

When the feature processing device 7 processes the composite insulation board, the processing table 701 is used for receiving the composite insulation board transported by the product transporting device and providing a supporting and processing platform.

The clamp 702 clamps the composite insulation board to be processed, so that the composite insulation board 702 can keep stable during processing, and the processing effect is guaranteed.

The characteristic processing piece 703 starts to perform characteristic processing of the first connecting piece 4 and the second connecting piece 5 after the composite insulation board is clamped and mounted by the clamping piece 702.

The feature processing part 703 comprises two portal frames 704 arranged on the processing table 701, each portal frame 704 is provided with a hydraulic telescopic device 705, a horizontal displacement assembly 706 used for driving the hydraulic telescopic device 705 to do linear motion is arranged between each portal frame 704 and the corresponding hydraulic telescopic device 705, the bottom of each hydraulic telescopic device 705 is provided with a connecting seat 707, the bottom of one connecting seat 707 is provided with a longitudinal cutting edge 708, the bottom of the other connecting seat 707 is provided with a transverse cutting edge 709, and the composite heat insulation board is driven by the clamping of the clamping part 702 to process the structural features of the first connecting part 4 and the second connecting part 5 sequentially through the longitudinal cutting edge 708 and the transverse cutting edge 709.

The feature work piece 703 is used to machine the structural features of the first connector 4 and the second connector 5.

The machining of the structural features for the first connecting element 4 and the second connecting element 5 is carried out in two steps, first of all by machining the side walls of the mating groove 403 and of the mating block 504 from the longitudinal cutting edge 708 on one of the portal frames 704.

The longitudinal cutting blade 708 is processed from one side of the composite heat insulation board, and in the present embodiment, the side wall of the fitting groove 403 is first cut to form the groove wall of the fitting groove 403.

During machining, the hydraulic telescoping device 705 is started firstly, so that the longitudinal cutting edge 708 is gradually close to the surface of the composite insulation board and gradually cuts until the boundary between the first extension panel 401 and the first extension core layer 402 is stopped.

The hydraulic telescopic device 705 is started to contract so that the longitudinal cutting edge 708 is gradually far away from the surface of the composite heat insulation board, the horizontal displacement assembly 706 is started, and the hydraulic telescopic device 705 is driven to move for a distance, wherein the distance is the length of the matching groove 403.

The hydraulic rams 705 are again activated so that the longitudinal cutting edge 708 is gradually brought closer to the composite insulation panel and cuts the other side wall of the mating groove 403, and then the longitudinal cutting edge 708 is again driven away from the composite insulation panel.

The hydraulic telescopic device 705 is now driven by the horizontal displacement assembly 706 to move a distance, the length of which is the distance between two mating grooves 403.

The side walls of the plurality of mating grooves 403 are sequentially machined according to the above operations to define a machining boundary for subsequent machining, and the cut portions are partially separated from the first extended core layer 402 to facilitate subsequent machining.

The partially machined mating groove 403 sidewall portions are then moved under another gantry 704 by clamping with clamps 702, and the hydraulic stretcher 705 is actuated so that the transverse cutting edge 709 gradually approaches the composite insulation board and cuts the portion between the machined mating groove 403 sidewalls so that it is machined into the finished mating groove 403.

Secondly, after the matching groove 403 is machined, the clamping member 702 drives the composite insulation board to move by the width distance of one bar block 503 for transverse cutting, so that the second panel 2 is separated from the insulation core layer 3 under the cutting of the transverse cutting edge 706 and the unique driving of the clamping member 702.

During machining of the mating grooves 403, the longitudinal cutting edge 708 simultaneously cuts the boundary of the mating pieces 504 and, by moving the clamp 702 under the second gantry 704, the section between the two mating pieces 504 is cut by the transverse cutting edge 709.

Secondly, a transverse cutting edge 709 needs to be driven to cut the width of the strip-shaped blocks 503 from the second panel 2 and the insulation core layer 3 on one side of the composite insulation board so as to process and form the strip-shaped blocks 503.

The clamping piece 702 comprises two side bases 710 symmetrically arranged on two sides of the machining table 701 and two longitudinal movement grooves 711 arranged on one side, opposite to the side bases 710, of each longitudinal movement groove 711, each longitudinal movement groove 712 is internally provided with a longitudinal movement screw 712 through a bearing, one end of each longitudinal movement screw 712 is connected with a first driving device, each longitudinal movement screw 712 is connected with a threaded connection seat 713 in sliding connection with the inside of each longitudinal movement groove 711 in a threaded connection mode, each threaded connection seat 713 is provided with a transverse movement assembly 714, one side, opposite to the two threaded connection seats 713, is provided with an L-shaped clamping plate 715 used for clamping the composite heat-insulating plate, and the transverse movement assemblies 714 drive the corresponding L-shaped clamping plates 715 to move oppositely to clamp the composite heat-insulating plate.

When the composite insulation board enters the processing table, the clamping piece 702 drives the corresponding L-shaped clamping plates 715 to move oppositely through the transverse movement assembly 714, so that the composite insulation board is clamped by the two L-shaped clamping plates 715, and the composite insulation board is stabilized by static friction between the L-shaped clamping plates 715 and the composite insulation board.

And then starting a first driving device according to the processing progress of the composite heat-insulation board, after the two side wall parts of the matching groove 403 are processed, simultaneously driving the longitudinal moving screw rod 711 by the first driving device, driving the two threaded connecting seats 713 to move along the axis of the longitudinal moving screw rod 711 through threaded engagement until the two threaded connecting seats move to the lower part of the second portal frame 704 for processing, and similarly, when the matching block 504 is partially processed, hearing the first driving device to drive the longitudinal moving screw rod 711 to rotate, so that the part moves to the lower part of the second portal frame 704.

The transverse moving assembly 714 comprises a transverse moving groove 716 arranged on a threaded connecting seat 713 and a transverse moving screw 717 which is arranged in the transverse moving groove 716 through a bearing, one end of the transverse moving screw 717 is connected with a second driving device, a threaded clamping seat 718 which is slidably connected with the inside of the transverse moving groove 716 is screwed on the transverse moving screw 717, and a transmission link 719 which is connected with an L-shaped clamping plate 715 is fixedly connected on the threaded clamping seat 718.

The lateral motion assembly 714, when activated, drives the L-clamp plate 715 to clamp the composite insulation panel.

When the composite insulation board clamping device is started, the second driving device drives the transverse moving screw 717 to rotate, and the two threaded clamping seats 718 are driven to move oppositely through threaded engagement, so that the two L-shaped clamping plates 715 clamp the composite insulation board.

And through the drive of lateral motion screw 717 not only can have the auto-lock nature for can still keep the clamping state when the second drive arrangement does not start, and laborsaving structure when lateral motion screw 717 can reduce the power requirement to the second drive arrangement.

A plurality of sliding rods 720 are arranged on one side of the L-shaped clamp plate 715 at equal intervals, a plurality of sliding grooves 721 are formed on the screw thread connecting seat 713 corresponding to the sliding rods 720, and each sliding rod 720 is slidably connected in the corresponding sliding groove 721.

The sliding rod 720 is inserted into the sliding groove 721 on the threaded connecting seat 713 to slide, so that the occupation of the L-shaped clamping plate 715 on the external space is reduced, and the interference on the state of the composite heat-insulating plate when the composite heat-insulating plate is not in a non-clamping state is avoided.

The processing table 701 comprises two brackets 722, the clamping piece 702 and the feature processing piece 703 are both arranged on the brackets 722, a plurality of transverse supporting plates 723 are arranged between the two brackets 722 at equal intervals, and a plurality of longitudinal supporting plates 724 are arranged between two adjacent transverse supporting plates 723 at equal intervals.

During machining, a large amount of machining debris is generated, and a supporting platform structure with a mesh shape is formed by the transverse supporting plate 723 and the longitudinal supporting plate 724, so that the generated machining debris cannot remain on the surface of the machining table to affect the next feature machining.

The above embodiments are only exemplary embodiments of the present application, and are not intended to limit the present application, and the protection scope of the present application is defined by the claims. Various modifications and equivalents may be made by those skilled in the art within the spirit and scope of the present application and such modifications and equivalents should also be considered to be within the scope of the present application.

Claims (8)

1. A composite heat-insulating wallboard is characterized in that: the composite insulation board comprises a first panel (1), a second panel (2) and an insulation core layer (3) arranged between the first panel (1) and the second panel (2), wherein the first panel (1), the second panel (2) and the insulation core layer (3) jointly form the composite insulation board, a first connecting piece (4) and a second connecting piece (5) are respectively arranged on two opposite sides of the composite insulation board, and the first connecting piece (4) and the second connecting piece (5) are matched and connected with each other in a universal matching manner at an external corner and a non-external corner of an outer wall;

the composite heat-insulation wallboard machining equipment comprises a raw material machining chamber (6) for producing the composite heat-insulation board and a characteristic machining device for performing characteristic machining on the composite heat-insulation board produced by the raw material machining chamber (6), and the composite heat-insulation board is conveyed to the characteristic machining device from the raw material machining chamber (6) through a product conveying device;

the characteristic processing device comprises a processing table (701) for receiving the composite insulation board to be processed and clamping pieces (702) arranged on two sides of the processing table (701) and used for installing the composite insulation board, wherein the processing table (701) is provided with characteristic processing pieces (703) used for processing the characteristics of a first connecting piece (4) and a second connecting piece (5) on the composite insulation board;

the characteristic processing piece (703) comprises two portal frames (704) arranged on the processing table (701), each portal frame (704) is provided with a hydraulic telescopic device (705), a horizontal displacement assembly (706) used for driving the hydraulic telescopic device (705) to do linear motion is arranged between each portal frame (704) and the corresponding hydraulic telescopic device (705), the bottom of each hydraulic telescopic device (705) is provided with a connecting seat (707), the bottom of one of the connecting seats (707) is provided with a longitudinal cutting edge (708), the bottom of the other connecting seat (707) is provided with a transverse cutting edge (709), and the composite insulation board sequentially passes through the longitudinal cutting edge (708) and the transverse cutting edge (709) to process the structural characteristics of the first connecting piece (4) and the second connecting piece (5) under the clamping driving of the clamping piece (702).

2. The composite thermal insulation wallboard of claim 1, wherein: the first connecting piece (4) comprises a first extending panel (401) and a first extending core layer (402), the first extending panel (401) is connected with one side of the first panel (1), the first extending core layer (402) is connected with one side of the heat preservation core layer (3), and a plurality of matching grooves (403) are formed in the first extending core layer (402) at equal intervals;

the second connecting piece (5) comprises a second extending panel (501) and an extending core layer group (502), the second extending panel (501) is connected with one side of the second panel (2), one side, far away from the second panel (2), of the second extending panel (501) extends outwards to form a strip-shaped block (503), the extending core layer group (502) comprises a plurality of matching blocks (504) connected with the other side of the heat preservation core layer (3), and each matching block (504) is correspondingly connected with the other matching groove (403) in the composite heat preservation board.

3. A composite insulating wall panel according to claim 2, wherein: the thickness of the first extended core layer (402) is the same as the length of the mating block (504), and the thickness of the first extended core layer (402) is the same as the depth of the mating groove (403).

4. The composite thermal insulation wallboard and processing equipment as claimed in claim 3, wherein: the first panel (1) and the second panel (2) have the same thickness, and the vertical distance between the bottom of the matching groove (403) and the end of the second panel (2) is the same as the extension length of the bar block (503).

5. The composite thermal insulation wallboard of claim 1, wherein: the clamping piece (702) comprises two side seats (710) symmetrically arranged at two sides of the processing table (701) and two longitudinal movement grooves (711) arranged at the opposite sides of the two side seats (710), each longitudinal movement groove (711) is internally provided with a longitudinal movement screw (712) through a bearing, one end of each longitudinal movement screw (712) is connected with a first driving device, each longitudinal movement screw (712) is in threaded connection with a threaded connection seat (713) in sliding connection with the inside of the longitudinal movement groove (711), each threaded connection seat (713) is provided with a transverse movement assembly (714), and the opposite sides of the two threaded connection seats (713) are provided with L-shaped clamping plates (715) for clamping the composite heat-insulation board, and the transverse moving assembly (714) drives the corresponding L-shaped clamping plates (715) to move oppositely to clamp the composite insulation board.

6. The composite thermal insulation wallboard of claim 5, wherein: the transverse movement assembly (714) comprises a transverse movement groove (716) arranged on the threaded connecting seat (713) and a transverse movement screw (717) installed in the transverse movement groove (716) through a bearing, one end of the transverse movement screw (717) is connected with a second driving device, a threaded clamping seat (718) in sliding connection with the inside of the transverse movement groove (716) is in threaded connection with the transverse movement screw (717), and a transmission connecting rod (719) connected with the L-shaped clamping plate (715) is fixedly connected to the threaded clamping seat (718).

7. The composite thermal insulation wallboard of claim 6, wherein: a plurality of sliding rods (720) are arranged on one side of the L-shaped clamping plate (715) at equal intervals, a plurality of sliding grooves (721) are formed in the threaded connecting seat (713) corresponding to the sliding rods (720), and each sliding rod (720) is connected into the corresponding sliding groove (721) in a sliding mode.

8. The composite thermal insulation wallboard of claim 5, wherein: the processing table (701) comprises two brackets (722), the clamping piece (702) and the feature processing piece (703) are both arranged on the brackets (722), a plurality of transverse supporting plates (723) are arranged between the two brackets (722) at equal intervals, and a plurality of longitudinal supporting plates (724) are arranged between every two adjacent transverse supporting plates (723) at equal intervals.

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