CN219325301U - Cutting and discharging mechanism for extrusion molding heat insulation plate - Google Patents

Abstract

The utility model relates to a cutting and blanking mechanism of an extrusion molding heat-insulating plate, which comprises a workbench, a cutting sheet, a blanking roller and a distributing plate, wherein two moving assemblies with the same moving direction are arranged on two sides of the rotating direction of the blanking roller on the workbench, the moving direction of the moving assemblies is parallel to the central axis of the blanking roller, the cutting sheet is rotatably arranged on one of the moving assemblies, the central axis of the cutting sheet is parallel to the central axis of the blanking roller, the distributing plate is arranged above the blanking roller and is perpendicular to the central axis of the blanking roller, the distributing plate separates the moving channels of the extrusion molding heat-insulating plate to form two blanking channels, two sides of the distributing plate are respectively arranged on the two moving assemblies, the distributing plate and the cutting sheet are positioned on the same plane, and the two moving assemblies are driven to synchronously move by a driving assembly and drive the distributing plate and the cutting sheet to synchronously move; according to the utility model, the extruded insulation boards with different sizes and specifications formed by cutting are respectively fed, manual sorting is not needed, the manual labor is reduced, and the production efficiency of the extruded insulation boards is improved.

Description

Cutting and discharging mechanism for extrusion molding heat insulation plate

Technical Field

The utility model relates to the technical field of extrusion molding heat-insulating plate processing, in particular to a cutting and blanking mechanism for an extrusion molding heat-insulating plate.

Background

An extrusion molding heat-insulating board, namely an extrusion molding polystyrene heat-insulating board, is a foaming rigid plastic board formed by taking polystyrene resin as a raw material, adding other polymers and heating and extruding. The interior of the plate is formed with a plurality of closed bubble structures, has the characteristics of strong bearing capacity, good waterproof performance, chemical corrosion resistance and strong ageing resistance, is widely applied to the waterproof and moistureproof of building heat preservation and humid environment, and at present, the existing extruded heat preservation plate needs to cut off the strip-shaped extruded heat preservation plate into a certain size specification in the production process, and then the cut-off extruded heat preservation plate is subjected to blanking through a blanking mechanism.

The automatic blanking mechanism for producing the roof extruded polystyrene insulation board is provided by the Chinese patent with publication number of CN212445383U, and the automatic cutting and blanking of the extruded polystyrene insulation board is realized by the mutual matching of a roller conveyor, a hydraulic telescopic rod, a cam connecting rod mechanism, a sliding body and a cutter, so that the production efficiency of the extruded polystyrene insulation board is greatly improved.

However, the blanking mechanism still has some defects, and the blanking mechanism uniformly blanking the cut extrusion molding heat-insulation boards, so that when the extrusion molding heat-insulation boards are cut into different size specifications, the extrusion molding heat-insulation boards are also required to be sorted manually, the labor is increased, and the production efficiency of the extrusion molding heat-insulation boards is reduced.

Therefore, the utility model provides an extrusion molding insulation board cutting and blanking mechanism for solving the problems.

Disclosure of Invention

The utility model aims to solve the technical problem of providing the cutting and blanking mechanism for the extruded heat-insulating plates, which is used for respectively blanking the extruded heat-insulating plates with different sizes and specifications and is formed by cutting, so that manual sorting is not needed, the labor is reduced, and the production efficiency of the extruded heat-insulating plates is improved.

In order to solve the technical problems, the technical scheme of the utility model is as follows: the utility model provides a unloading mechanism is cut to extrusion molding heated board which innovation point lies in: comprises a workbench, a cutting sheet, a blanking roller and a distributing plate;

the blanking roller axis rotates the installation on the workstation horizontally to form extrusion molding heated board travel path in blanking roller top, two moving parts that the direction of movement is the same are installed to the both sides of blanking roller direction of rotation on the workstation, moving parts's direction of movement is parallel with the blanking roller axis, the cutting piece rotates and installs on one of them moving parts, the cutting piece axis is parallel with the blanking roller axis, the setting of dividing plate is in blanking roller top and perpendicular with the blanking roller axis, divide the flitch to separate extrusion molding heated board travel path and form two unloading paths, divide the both sides of flitch to install respectively on two moving parts, divide the flitch to be in the coplanar with the cutting piece, two moving parts pass through the drive assembly drive synchronous motion, and drive dividing flitch and cutting piece synchronous motion.

Further, the moving assembly comprises a moving plate and a guide rail group, the guide rail group is fixedly arranged on the workbench, the moving plate is arranged above the guide rail group, a sliding block matched with the guide rail group is arranged on the bottom surface of the moving plate, the sliding block is slidably arranged on the guide rail group, and the distributing plate and the cutting piece are arranged on the upper end surface of the moving plate corresponding to the moving assembly.

Further, the drive assembly comprises a rotary driving piece, a transmission shaft and two racks, the central axis of the transmission shaft is horizontally and rotatably arranged on the workbench, the two racks are respectively arranged on the bottom surfaces of the moving plates of the two moving assemblies, two first transmission gears which are respectively in one-to-one correspondence with the two racks are fixedly sleeved on the transmission shaft, the first transmission gears are in meshed connection with the corresponding racks, a second transmission gear is fixedly sleeved on the transmission shaft, the rotary driving piece is arranged on the workbench, a driving gear is arranged at the output end of the rotary driving piece, and the driving gear is in meshed connection with the second transmission gear.

Further, the transmission shafts are provided with two transmission gears which are parallel to each other, and the second transmission gears of the two transmission shafts are respectively connected with two sides of the driving gear in a meshed mode.

Further, one side of the distributing plate, which is far away from the cutting piece, is connected with a position indicating plate, and displacement scale marks are carved below the position indicating plate on the workbench.

Further, two first compression rollers are installed above the blanking roller, the two first compression rollers are coaxially arranged and are respectively arranged on two sides of the distributing plate, a distance for the distributing plate to move is reserved between the two first compression rollers, the first compression rollers are driven to move up and down through a first linear driving piece, a feeding roller is arranged on one side, far away from the blanking roller, of the cutting piece, a second compression roller is installed above the feeding roller, and the second compression roller is driven to move up and down through a second linear driving piece.

The utility model has the advantages that:

(1) According to the utility model, the cutting piece is arranged on the moving assembly, the position of the cutting piece is adjusted by moving the moving assembly, so that the extruded heat-insulating plate is cut into different sizes, the material dividing plate is arranged, the extruded heat-insulating plate moving channels above the material discharging roller are separated to form two material discharging channels, and the material dividing plate is arranged on the moving assembly and moves synchronously with the cutting piece, so that the sizes of the two material discharging channels are adjusted according to the change of the cutting position of the cutting piece, and the extruded heat-insulating plates with different specifications formed by cutting are respectively discharged without manual sorting, thus the labor intensity is reduced, and the production efficiency of the extruded heat-insulating plate is improved.

(2) In the driving assembly, the synchronous movement of the moving plates of the two moving assemblies is realized through the mutual matching of the rotary driving piece, the driving gear, the transmission shaft, the first transmission gear, the second transmission gear and the rack, and the driving assembly has a simple structure and high movement precision.

(3) The two transmission shafts are arranged, so that the stability of torque transmission of the driving assembly is effectively improved, and when one transmission shaft is damaged for disassembly and maintenance, the other transmission shaft can still play a role in torque transmission, and the machining efficiency of the mechanism is improved.

(4) According to the utility model, the position indication plate is arranged, and the displacement scale marks are engraved below the position indication plate on the workbench, so that an operator can conveniently determine the cutting position of the cutting sheet according to the movement displacement of the material dividing plate, and the cutting precision is improved.

(5) According to the utility model, the second compression roller is matched with the feeding roller, the first compression roller is matched with the blanking roller, and the non-cut side and the cut side of the extrusion molding insulation board are limited respectively, so that the extrusion molding insulation board is prevented from moving in the cutting process, and the cutting precision is prevented from being influenced.

Drawings

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

Fig. 1 is a schematic structural view of a slitting and blanking mechanism for an extrusion molding insulation board.

Fig. 2 is a side view of the extruded insulation board slitting and blanking mechanism of the present utility model.

Fig. 3 is a schematic structural view of a driving assembly according to the present utility model.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present utility model more apparent, the technical solutions of the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model, and it is apparent that the described embodiments are some embodiments of the present utility model, but not all embodiments of the present utility model. The components of the embodiments of the present utility model generally described and illustrated in the figures herein may be arranged and designed in a wide variety of different configurations.

Thus, the following detailed description of the embodiments of the utility model, as presented in the figures, is not intended to limit the scope of the utility model, as claimed, but is merely representative of selected embodiments of the utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

The cutting and blanking mechanism of the extrusion molding heat insulation plate as shown in fig. 1-3 comprises a workbench 1, a cutting sheet 2, a blanking roller 3 and a distributing plate 4.

The central axis of the blanking roller 3 is horizontally and rotatably arranged on the workbench 1, an extrusion molding heat-insulating plate moving channel is formed above the blanking roller 3, the blanking roller 3 is provided with a plurality of parallel guide rails, two moving assemblies 5 with the same moving direction are arranged on two sides of the rotating direction of the blanking roller 3 on the workbench 1, the moving direction of each moving assembly 5 is parallel to the central axis of the blanking roller 3, each moving assembly 5 comprises a moving plate 51 and two guide rail groups 52, each of the two guide rail groups 52 is fixedly arranged on the workbench 1 through a horizontal plate 54, the horizontal plate 54 is horizontally arranged on the side wall of the workbench 1, the guide rail groups 52 are fixedly arranged on the upper end face of the corresponding horizontal plate 54, each guide rail group 52 is provided with two guide rails which are arranged in parallel, the moving plates 51 are arranged above the guide rail groups 52, the bottom surfaces of the moving plates 51 are provided with sliding blocks 53 matched with the guide rails of the guide rail groups 52, and the sliding blocks 53 are slidingly arranged on the corresponding guide rails.

The cutting blade 2 is rotatably mounted on the upper end face of the moving plate of one of the moving assemblies through the first mounting seat 21, the central axis of the cutting blade 2 is parallel to the central axis of the blanking roller 3, the cutting blade 2 is driven to rotate by a rotating motor, the rotating motor is mounted on the corresponding moving plate of the cutting blade 2, and the output end of the rotating motor is connected with the cutting blade 2. The distributing plate 4 is arranged above the blanking roller 3 and is perpendicular to the central axis of the blanking roller 3, the distributing plate 4 separates the extrusion molding heat-insulating plate moving channels to form two blanking channels, two sides of the distributing plate 4 are respectively arranged on the upper end faces of the moving plates 51 of the two moving assemblies 5 through vertical plates, the distributing plate 4 and the cutting plates 2 are positioned on the same plane, the moving plates 51 of the two moving assemblies 5 are driven to synchronously move through the driving assembly 6, and the distributing plate 4 and the cutting plates 2 are driven to synchronously move.

The driving assembly 6 comprises a rotary driving piece 61, two mutually parallel driving shafts 62 and two racks 63, the central axis of each driving shaft 62 is horizontally arranged and is arranged below the blanking roller 3, two ends of each driving shaft 62 are respectively and rotatably arranged on the workbench 1 through second mounting seats 68, the two racks 63 are respectively and fixedly arranged on the bottom surfaces of the moving plates 51 of the two moving assemblies 5, the racks 63 are arranged between the two guide rail groups 52 positioned on the same side, two first transmission gears 64 which are respectively and one-to-one corresponding to the two racks 63 are fixedly sleeved on each driving shaft 62, the first transmission gears 64 are in meshed connection with the corresponding racks 63, the driving shafts 62 are fixedly sleeved with second transmission gears 65, the rotary driving piece 61 is arranged on the workbench 1, the rotary driving piece 61 is driven by a motor, the output end of the rotary driving piece 61 is provided with a driving gear 66, one side of the driving gear 66, which is far away from the rotary driving piece 61, is arranged on the workbench 1 through a third mounting seat 67, and the second transmission gears 65 of the two driving shafts 62 are respectively in meshed connection with two sides of the driving gear 66.

In this embodiment, one side of the dividing plate 4 far away from the cutting plate 2 is connected with a position indicating plate 7, a scale plate 71 is horizontally arranged below the position indicating plate 7 on the workbench 1, two ends of the scale plate 71 are respectively connected to the horizontal plates 54 on the same side, displacement scale marks are engraved on the upper end face of the scale plate 71, and an operator can conveniently determine the cutting position of the cutting plate according to the movement displacement of the dividing plate, so that the cutting precision is improved.

Two first compression rollers 8 are installed to the unloading roller top that is close to cutting piece 2, two first compression rollers 8 coaxial setting and set up respectively in dividing flitch 4 both sides, leave the distance that supplies dividing flitch 4 to remove between two first compression rollers 8, first compression roller 8 passes through first linear drive spare 9 drive and reciprocates, first linear drive spare 9 has two, and set up side by side, first linear drive spare 9 passes through mounting bracket 91 and installs on workstation 1, two first compression rollers 8 rotate the cover and install on same pivot 81, the axis of pivot 81 is parallel with the axis of unloading roller 3, the both ends of pivot 81 are connected with the flexible end of two first linear drive spare 9 respectively, first linear drive spare 9 adopts electric putter, one side that cutting piece 2 kept away from unloading roller 3 on workstation 1 is equipped with feed roller 10, a second compression roller 11 is installed to the top of feed roller 10, second compression roller 11 passes through second linear drive spare drive and reciprocates, mutually support through second compression roller 11 and feed roller 10, first compression roller 8 and unloading roller 3, cut the thermal insulation board has not taken place in the cutting accuracy in the thermal insulation board cutting has not taken place in the thermal insulation board cutting process.

According to the cutting and blanking mechanism for the extrusion molding heat-insulating plate, the cutting piece is arranged on the moving assembly, the position of the cutting piece is adjusted through moving the moving assembly, so that the extrusion molding heat-insulating plate is cut into different sizes, the two blanking channels are formed by separating the moving channels of the extrusion molding heat-insulating plate above the blanking roller through arranging the distributing plate, the distributing plate is arranged on the moving assembly and moves synchronously with the cutting piece, and the sizes of the two blanking channels are adjusted according to the change of the cutting position of the cutting piece, so that the two extrusion molding heat-insulating plates with different specifications formed by cutting are respectively blanked.

It will be understood by those skilled in the art that the present utility model is not limited to the embodiments described above, and that the above embodiments and descriptions are merely illustrative of the principles of the present utility model, and various changes and modifications may be made without departing from the spirit and scope of the utility model, which is defined in the appended claims. The scope of the utility model is defined by the appended claims and equivalents thereof.

Claims (6)

1. The utility model provides a unloading mechanism is cut to extrusion molding heated board which characterized in that: comprises a workbench, a cutting sheet, a blanking roller and a distributing plate;

the blanking roller axis rotates the installation on the workstation horizontally to form extrusion molding heated board travel path in blanking roller top, two moving parts that the direction of movement is the same are installed to the both sides of blanking roller direction of rotation on the workstation, moving parts's direction of movement is parallel with the blanking roller axis, the cutting piece rotates and installs on one of them moving parts, the cutting piece axis is parallel with the blanking roller axis, the setting of dividing plate is in blanking roller top and perpendicular with the blanking roller axis, divide the flitch to separate extrusion molding heated board travel path and form two unloading paths, divide the both sides of flitch to install respectively on two moving parts, divide the flitch to be in the coplanar with the cutting piece, two moving parts pass through the drive assembly drive synchronous motion, and drive dividing flitch and cutting piece synchronous motion.

2. The extruded insulation board slitting and blanking mechanism of claim 1, wherein: the movable assembly comprises a movable plate and a guide rail group, the guide rail group is fixedly arranged on the workbench, the movable plate is arranged above the guide rail group, a sliding block matched with the guide rail group is arranged on the bottom surface of the movable plate, the sliding block is slidably arranged on the guide rail group, and the material distributing plate and the cutting sheet are arranged on the upper end surface of the movable plate corresponding to the movable assembly.

3. The extruded insulation board slitting and blanking mechanism of claim 2, wherein: the driving assembly comprises a rotary driving piece, a transmission shaft and two racks, the central axis of the transmission shaft is horizontally and rotatably arranged on the workbench, the two racks are respectively arranged on the bottom surface of a moving plate of the two moving assemblies, two first transmission gears which are respectively in one-to-one correspondence with the two racks are fixedly sleeved on the transmission shaft, the first transmission gears are in meshed connection with the corresponding racks, a second transmission gear is fixedly sleeved on the transmission shaft, the rotary driving piece is arranged on the workbench, a driving gear is arranged at the output end of the rotary driving piece, and the driving gear is in meshed connection with the second transmission gear.

4. The extruded insulation board slitting feed mechanism according to claim 3, wherein: the transmission shafts are provided with two transmission gears which are parallel to each other, and the second transmission gears of the two transmission shafts are respectively connected with two sides of the driving gear in a meshed mode.

5. The extruded insulation board slitting and blanking mechanism of claim 1, wherein: one side of the distributing plate, which is far away from the cutting piece, is connected with a position indicating plate, and displacement scale marks are carved below the position indicating plate on the workbench.

6. The extruded insulation board slitting and blanking mechanism of claim 1, wherein: two first compression rollers are installed above the blanking roller, the two first compression rollers are coaxially arranged and are respectively arranged on two sides of the distributing plate, a distance for the distributing plate to move is reserved between the two first compression rollers, the first compression rollers are driven to move up and down through a first linear driving piece, a feeding roller is arranged on one side, far away from the blanking roller, of the cutting piece, a second compression roller is installed above the feeding roller, and the second compression roller is driven to move up and down through a second linear driving piece.

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