CN214924694U - XPS extruded sheet crosscut pile system - Google Patents

Abstract

The utility model provides a XPS extruded sheet crosscut pile system, include horizontal guillootine and the stacking machine that is located horizontal guillootine discharge end, horizontal guillootine includes crosscut support frame (70), removes cutting frame (71), crosscut piece (72) and a pair of plate clamping device, and a pair of plate clamping device symmetry respectively is installed on removal cutting frame (71) of crosscut piece (72) both sides, and plate clamping device includes fixed support plate (77), transmission bearing roller (78), activity clamp plate (79) and clamp plate drive actuating cylinder (80), the utility model discloses the advantage is: the transverse cutting machine and the extruded sheet move synchronously to cut, the cutting machine is convenient and fast, no dust is generated, the cut extruded sheets are automatically aligned and stacked through the stacking machine, the working efficiency is improved, and time and labor are saved.

Description

XPS extruded sheet crosscut pile system

Technical Field

The utility model relates to a XPS extruded sheet production technical field, concretely relates to XPS extruded sheet crosscut pile system.

Background

At present, XPS extruded sheet is through polystyrene resin and auxiliary material polymer heating mixture simultaneously pour into catalyst extrusion moulding's rigid foam plastic board into, XPS extruded sheet has perfect obturator honeycomb, this kind of structure lets XPS extruded sheet have extremely low hydroscopicity, low thermal conductivity, high compressive resistance and ageing resistance, the usage is extensive, need carry out segmentation cutting pile after the extruded sheet shaping, current cutting is through the saw bit cutting, the in-process of cutting can produce a large amount of dusts, influence operational environment, the extruded sheet after the cutting need carry through two staff and pile up neatly, waste time and energy.

SUMMERY OF THE UTILITY MODEL

The utility model aims at the above-mentioned not enough, and provide a XPS extruded sheet crosscut pile system.

The utility model discloses a horizontal guillootine and the stacking machine that is located horizontal guillootine discharge end, horizontal guillootine includes the crosscut support frame, remove the cutting frame, crosscut blade and a pair of panel clamping device, remove the cutting frame through a pair of guide rail movable mounting on the crosscut support frame, be equipped with the translation cylinder that the drive removed the cutting frame and reset on the crosscut support frame, crosscut blade bottom one end is through guide rail movable mounting in removing the cutting frame, it is equipped with the hold-in range drive module that drives the crosscut blade and remove about to remove the cutting frame top, crosscut blade top one end is connected with the hold-in range of hold-in range drive module through the connecting plate;

a pair of plate clamping devices are respectively and symmetrically arranged on the movable cutting frames at the two sides of the transverse cutting blade, each plate clamping device comprises a fixed supporting plate, a transmission carrier roller, a movable pressing plate and a pressing plate driving air cylinder, the two ends of the transmission carrier roller are respectively provided with a vertical guide seat, the middle part of the fixed supporting plate is provided with a carrier roller mounting groove, and two ends of the carrier roller mounting groove are respectively provided with a guide groove matched with the vertical guide seat for use, two ends of the transmission carrier roller are respectively movably mounted in the carrier roller mounting groove through the vertical guide seat, a compression spring is arranged between the bottom of the vertical guide seat and the guide groove, the fixed supporting plate is fixedly connected on the movable cutting frame, the movable pressing plate is movably arranged on the movable cutting frame through a pressing plate driving cylinder, the bottom parts of the two ends of the movable pressing plate are respectively provided with a push rod corresponding to the vertical guide seat, and a transverse cutting support frame positioned on one side of the discharge end of the movable cutting frame is provided with a synchronous belt receiving conveyor;

the stacking machine comprises a material receiving rack, a translation material receiving fork frame, a lifting material receiving rack and a synchronous belt transfer conveyor, wherein the translation material receiving fork frame is movably mounted at the top of the material receiving rack through an electric sliding table, a discharging fork frame matched with the translation material receiving fork frame is arranged in the middle of the material receiving rack, the synchronous belt transfer conveyor is located below the translation material receiving fork frame, the lifting material receiving rack is movably mounted in the material receiving rack through a chain lifting device, and the lifting material receiving fork frame and the synchronous belt transfer conveyor are located between the translation material receiving fork frame and the synchronous belt.

The movable cutting frame is provided with a cylinder mounting plate, the pressing plate drives the cylinder to be fixedly connected onto the cylinder mounting plate, the movable pressing plate is provided with a pair of guide rods, and the cylinder mounting plate is provided with guide sleeves matched with the guide rods for use.

The transverse cutting blade is an isosceles trapezoid blade with a wide top and a narrow bottom, and two inclined edges of the isosceles trapezoid blade are respectively provided with a cutting edge.

The fork teeth of the translational material receiving fork frame are respectively distributed in a staggered way with the fork teeth of the discharging fork frame and synchronous transmission belts of the synchronous belt material receiving conveyor.

The longitudinal connecting rod of the lifting material receiving frame and each synchronous transmission belt of the synchronous belt transfer conveyor are distributed in a staggered mode.

The utility model has the advantages that: the transverse cutting machine and the extruded sheet move synchronously to cut, the cutting machine is convenient and fast, no dust is generated, the cut extruded sheets are automatically aligned and stacked through the stacking machine, the working efficiency is improved, and time and labor are saved.

Description of the drawings

Fig. 1 is a schematic structural diagram of the present invention.

Fig. 2 is a schematic view of the structure of the lateral cutting machine.

Fig. 3 is a schematic diagram of a stacking machine.

Fig. 4 is a schematic structural view of the plate clamping device.

Detailed Description

As shown in the attached drawings, the utility model comprises a transverse cutting machine and a stacking machine positioned at the discharge end of the transverse cutting machine, wherein the transverse cutting machine comprises a transverse cutting support frame 70, a movable cutting frame 71, a transverse cutting blade 72 and a pair of plate clamping devices, the movable cutting frame 71 is movably arranged on the transverse cutting support frame 70 through a pair of guide rails, a translation cylinder 75 for driving the movable cutting frame 71 to reset is arranged on the transverse cutting support frame 70, one end of the bottom of the transverse cutting blade 72 is movably arranged in the movable cutting frame 71 through the guide rails, a synchronous belt driving module 76 for driving the transverse cutting blade 72 to move left and right is arranged at the top of the movable cutting frame 71, and one end of the top of the transverse cutting blade 72 is connected with a synchronous belt of the synchronous belt driving module 76 through a connecting plate;

a pair of plate clamping devices are respectively and symmetrically arranged on the movable cutting frame 71 at two sides of the transverse cutting blade 72, each plate clamping device comprises a fixed supporting plate 77, a transmission carrier roller 78, a movable pressing plate 79 and a pressing plate driving air cylinder 80, two ends of the transmission carrier roller 78 are respectively provided with a vertical guide seat 81, the middle part of the fixed supporting plate 77 is provided with a carrier roller installation groove, two ends of the carrier roller installation groove are respectively provided with a guide groove matched with the vertical guide seats 81, two ends of the transmission carrier roller 78 are respectively and movably arranged in the carrier roller installation groove through the vertical guide seats 81, a pressing spring 82 is arranged between the bottom of the vertical guide seat 81 and the guide groove, the fixed supporting plate 77 is fixedly connected on the movable cutting frame 71, the movable pressing plate 79 is movably arranged on the movable cutting frame 71 through the pressing plate driving air cylinder 80 and is positioned above the fixed supporting plate 77, the bottoms at two ends of the movable pressing plate 79 are respectively provided with a push rod 83 corresponding to the vertical guide seats 81, a synchronous belt receiving conveyor 85 is arranged on the transverse cutting support frame 70 positioned on one side of the discharging end of the movable cutting frame 71;

the stacking machine comprises a material receiving rack 90, a translational material receiving fork frame 91, a lifting material receiving rack 92 and a synchronous belt transfer conveyor 93, wherein the translational material receiving fork frame 91 is movably installed at the top of the material receiving rack 90 through an electric sliding table, a material discharging fork frame 95 matched with the translational material receiving fork frame 91 is arranged in the middle of the material receiving rack 90, the synchronous belt transfer conveyor 93 is located below the translational material receiving fork frame 91, the lifting material receiving rack 92 is movably installed in the material receiving rack 90 through a chain lifting device, and the translational material receiving fork frame 91 and the synchronous belt transfer conveyor 93 are located between.

An air cylinder mounting plate is arranged on the movable cutting frame 71, a pressing plate driving air cylinder 80 is fixedly connected onto the air cylinder mounting plate, a pair of guide rods is arranged on the movable pressing plate 79, and guide sleeves matched with the guide rods for use are arranged on the air cylinder mounting plate.

The transverse cutting blade 72 is an isosceles trapezoid blade with a wide top and a narrow bottom, and two oblique edges of the isosceles trapezoid blade are respectively provided with a cutting edge.

The fork teeth of the translational receiving fork frame 91 are respectively staggered with the fork teeth of the discharging fork frame 95 and the synchronous transmission belts of the synchronous belt receiving conveyor 85.

The longitudinal connecting rods of the lifting material receiving frame 92 and the synchronous transmission belts of the synchronous belt transfer conveyor 93 are distributed in a staggered manner.

The working mode is as follows: the formed extruded sheet passes through between a fixed support plate 77 and a movable press plate 79 of a transverse cutting machine, under the default condition, a transmission carrier roller 78 is under the action of a pressing spring 82, one part of the roller surface of the transmission carrier roller 78 is positioned outside the fixed support plate 77, the extruded sheet passes through the transmission carrier roller 78 to reduce friction, after the extruded sheet moves to a certain length, a pair of press plate driving cylinders 80 are synchronously started, the press plate driving cylinders 80 drive the movable press plate 79 to move downwards to press the extruded sheet onto the fixed support plate 77, at the moment, a movable cutting frame 71 moves forwards along with the extruded sheet, a synchronous belt driving module 76 is started while clamping, a transverse cutting blade 72 is driven to transversely move to cut the extruded sheet, in the process of pressing the movable press plate 79 downwards, the transmission carrier roller 78 is firstly pressed downwards into the fixed support plate 77 through a push rod 83, and the bottom of the extruded sheet after clamping is not contacted with the transmission carrier roller 78, after cutting, the extruded sheet falls onto the synchronous belt receiving conveyor 85 and is conveyed backwards. Then the clamp plate drives the movable clamp plate 79 of air cylinder 80 drive and resets, the drive bearing roller 78 resets under the effect of hold-down spring 82, the translation cylinder 75 starts, push away the removal cutting frame 71 to the initial position, according to the stroke of cutting, the guide rail both ends on the crosscut support frame 70 are equipped with the stopper respectively, under the default condition, the translation cylinder 75 is the state of stretching out, be equipped with the push pedal with removing the contact of cutting frame 71 on the piston rod of translation cylinder 75, support removing the cutting frame 71 on the stopper of front end, when the clamping device of panel starts, the translation cylinder 75 withdraws, be convenient for remove the smooth translation on the crosscut support frame 70 of the moving direction that the cutting frame 71 can follow the extruded sheet.

The synchronous belt receiving conveyor 85 and the synchronous belt transferring conveyor 93 are formed by arranging a plurality of synchronous belts, a gap is arranged between two adjacent synchronous belts, the translational receiving fork frame 91 is an L-shaped fork frame, in an initial state, a horizontal section fork tooth of the L-shaped fork frame extends into the synchronous belt receiving conveyor 85, when a cut extruded sheet is moved out from the discharge end of the synchronous belt receiving conveyor 85, the translational receiving fork frame 91 synchronously moves backwards, so that the extruded sheet falls on the translational receiving fork frame 91, in the process of retreating the translational receiving fork frame 91, the extruded sheet is blocked by the discharging fork frame 95 and falls on the lifting receiving frame 92 below, the front ends of the extruded sheets can be aligned in the discharging process of the discharging fork frame 95, after the extruded sheet completely falls on the lifting receiving frame 92, the lifting receiving frame 92 moves a sheet placing position downwards under the control of a chain lifting device, the translational receiving fork frame 91 resets, and receiving the next cut extruded sheet.

The longitudinal connecting rod of the lifting material receiving frame 92 and each synchronous transmission belt of the synchronous belt transfer conveyor 93 are distributed in a staggered mode, when the lifting material receiving frame 92 descends to the lowest position, the extruded sheet stacked on the lifting material receiving frame 92 falls onto the synchronous belt of the synchronous belt transfer conveyor 93, the synchronous belt transfer conveyor 93 is started to move away the stacked extruded sheet, then the lifting material receiving frame 92 resets to the uppermost initial position, and the second batch of extruded sheet stacking is carried out. The transverse cutting blade 72 is an isosceles trapezoid blade with a wide top and a narrow bottom, cutting edges are respectively arranged on two oblique edges of the isosceles trapezoid blade, the transverse cutting blade 72 is driven by the synchronous belt driving module 76 to reciprocate, and the cutting can be performed twice by one reciprocating movement.

Claims (5)

1. An XPS extruded sheet transverse cutting and stacking system is characterized by comprising a transverse cutting machine and a stacking machine positioned at the discharge end of the transverse cutting machine, wherein the transverse cutting machine comprises a transverse cutting support frame (70), a movable cutting frame (71), a transverse cutting blade (72) and a pair of plate clamping devices, the movable cutting frame (71) is movably mounted on the transverse cutting support frame (70) through a pair of guide rails, a translation cylinder (75) for driving the movable cutting frame (71) to reset is arranged on the transverse cutting support frame (70), one end of the bottom of the transverse cutting blade (72) is movably mounted in the movable cutting frame (71) through the guide rails, a synchronous belt driving module (76) for driving the transverse cutting blade (72) to move left and right is arranged at the top of the movable cutting frame (71), and one end of the top of the transverse cutting blade (72) is connected with a synchronous belt of the synchronous belt driving module (76) through a connecting plate;

a pair of plate clamping devices are respectively and symmetrically arranged on the movable cutting frame (71) at two sides of the transverse cutting blade (72), each plate clamping device comprises a fixed supporting plate (77), a transmission carrier roller (78), a movable pressing plate (79) and a pressing plate driving cylinder (80), two ends of the transmission carrier roller (78) are respectively provided with a vertical guide seat (81), the middle part of the fixed supporting plate (77) is provided with a carrier roller mounting groove, two ends of the carrier roller mounting groove are respectively provided with a guide groove matched with the vertical guide seats (81), two ends of the transmission carrier roller (78) are respectively and movably arranged in the carrier roller mounting groove through the vertical guide seats (81), a compression spring (82) is arranged between the bottom of the vertical guide seat (81) and the guide groove, the fixed supporting plate (77) is fixedly connected on the movable cutting frame (71), the movable pressing plate (79) is movably arranged on the movable cutting frame (71) through a pressing plate driving cylinder (80), the movable pressing plate (79) is provided with push rods (83) corresponding to the vertical guide seats (81) at the bottoms of the two ends respectively, and a cross cutting support frame (70) positioned on one side of the discharge end of the movable cutting frame (71) is provided with a synchronous belt receiving conveyor (85);

the stacking machine comprises a material receiving rack (90), a translation material receiving fork frame (91), a lifting material receiving rack (92) and a synchronous belt transfer conveyor (93), wherein the translation material receiving fork frame (91) is movably installed at the top of the material receiving rack (90) through an electric sliding table, a material discharging fork frame (95) matched with the translation material receiving fork frame (91) for use is arranged in the middle of the material receiving rack (90), the synchronous belt transfer conveyor (93) is located below the translation material receiving fork frame (91), the lifting material receiving rack (92) is movably installed in the material receiving rack (90) through a chain lifting device, and the material receiving fork frame (91) and the synchronous belt transfer conveyor (93) are horizontally moved.

2. The XPS extruded sheet crosscut stacking system according to claim 1, wherein the moving cutting frame (71) is provided with a cylinder mounting plate, the pressing plate driving cylinder (80) is fixedly connected to the cylinder mounting plate, the movable pressing plate (79) is provided with a pair of guide rods, and the cylinder mounting plate is provided with guide sleeves matched with the guide rods.

3. An XPS extruded sheet crosscut stacking system according to claim 1, characterised in that the crosscut blade (72) is an isosceles trapezoid blade with a wide top and a narrow bottom, and that on both bevel edges of the isosceles trapezoid blade there are cutting edges, respectively.

4. An XPS extruded sheet crosscut stacking system according to claim 1, wherein the tines of the translating receiving fork carriage (91) are offset from the tines of the discharge fork carriage (95) and the timing belts of the timing belt receiving conveyor (85).

5. A XPS extruded sheet crosscut stacking system according to claim 1, characterised in that the longitudinal connecting rods of the lifting receiving rack (92) are staggered from the timing belts of the timing belt transfer conveyor (93).

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