CN114348349A - All-steel movable floor packaging device - Google Patents

Abstract

The invention relates to the technical field of floor processing and conveying, in particular to an all-steel movable floor packaging device. The invention provides an all-steel movable floor packaging device, which comprises: the automatic cutting machine comprises a workbench, a conveying part, two printing parts, two cutting assemblies, a linkage cooling part and a conveying frame; the linkage cooling portion includes: the device comprises a linkage motor, two fixing plates, two linkage conveying belts, a linkage assembly and a cooling assembly; the printing part can be used for simultaneously coating films on two ends of the floor and carrying out hot melting and marking; the linkage assembly is abutted against two sides of the floor so that the protective film belts on two sides are attached to two sides of the floor; when the floor moves to the middle section of the linkage assembly, the next floor downwards extrudes the linkage assembly to compact the protective film belt; when the floor moves to the rear end of the linkage assembly and is positioned below the cooling assembly, the cooling assembly can blow air to the hot-melt printing points at the two ends of the floor for cooling; when the next floor presses the linkage assembly downwards, the rear end of the linkage assembly is overturned to enable the floor below the cooling assembly to fall onto the conveying frame.

Description

All-steel movable floor packaging device

Technical Field

The invention relates to the technical field of plate processing and conveying, in particular to an all-steel movable floor packaging device.

Background

Application No.: CN201921059265.3, publication (bulletin) No.: CN210619345U, a panel conveyor, this application discloses a panel conveyor, including the frame and rack-mounted lower transport mechanism and last transport mechanism, lower transport mechanism is including the bottom suspension fagging, linear guide mechanism and first actuating mechanism, go up transport mechanism including last backup pad, second actuating mechanism, leading rail, vice guide rail and guiding mechanism, when the position that needs adjustment panel carried, backup pad removal in linear guide mechanism can be driven through first drive block to first actuating mechanism, then second actuating mechanism can drive vice guide rail through the second drive block and move on guiding mechanism, thereby can realize the position that accurate adjustment panel carried, the convenience of using has been improved.

Realize accurate adjustment panel through the setting of last backup pad and direction machine among the prior art and carry, but in the use, panel transports on different conveyer belts, needs connection structure to adjust panel, and mostly operate through the manual work among the prior art, consequently, it is very necessary to develop an all steel raised floor packing plant.

Disclosure of Invention

The invention aims to provide an all-steel movable floor packaging device.

In order to solve the technical problem, the invention provides an all-steel raised floor packaging device, which comprises: the conveying part is arranged on the workbench in a circulating and rotating mode and is suitable for conveying floors;

the two printing parts are fixed at the upper end of the workbench, the printing parts are arranged above the conveying part, one printing part corresponds to one end of the floor, and the printing parts are suitable for hot melt marking after film coating is carried out on the two ends of the floor;

the cutting assemblies are arranged on one side of the printing portion, one cutting assembly corresponds to one printing portion, and the cutting assemblies are suitable for cutting off the protective film belt;

the conveying frame is fixed at the discharging end of the workbench and arranged below the linkage cooling part;

linkage cooling portion sets up in the workstation and is close to the top of transport portion unloading end, linkage cooling portion includes: the device comprises a linkage motor, two fixing plates, two linkage conveying belts, a linkage assembly and a cooling assembly, wherein the two fixing plates are vertically fixed on the workbench and are arranged in parallel relatively;

the two linkage conveyer belts are respectively and rotatably arranged on the inner side walls of the two fixed plates, and are in transmission connection with the linkage motor;

the linkage motor is fixed on the outer side wall of the fixed plate;

the linkage assembly is arranged on the inner side wall of the fixed plate in a vertically sliding manner and is arranged between the two linkage conveying belts;

the cooling assembly is arranged above the linkage conveying belt and is linked with the linkage assembly; wherein

When the transportation part drives the floor to horizontally move to the lower end of the printing part, the printing part can simultaneously coat films on two ends of the floor and thermally melt and print marks;

when the floor moves to abut against the front end of the linkage assembly and the linkage assembly is extruded downwards, the linkage assembly abuts against the two sides of the floor so that the protective film belts on the two sides are attached to the two sides of the floor;

when the floor moves to the middle section of the linkage assembly, the next floor downwards presses the linkage assembly, so that the linkage assembly downwards presses the floor at the middle section position to compact the protective film belt;

when the floor moves to the rear end of the linkage assembly and is positioned below the cooling assembly, the cooling assembly can blow air to the hot-melt printing points at the two ends of the floor for cooling;

when the next floor presses the linkage assembly downwards, the rear end of the linkage assembly is turned over to turn the floor below the cooling assembly onto the conveying frame.

Further, the linkage assembly includes: the connecting rod, the lifting plate and the cooling plate are arranged along the moving direction of the linkage conveying belt;

the lifting plate is arranged on the inner side wall of the fixed plate in a sliding mode and arranged at the feeding end of the linkage conveying belt, an included angle is formed between the lifting plate and the workbench, and one end of the connecting rod is fixed on the lifting plate;

the cooling plate is rotatably arranged between the two fixing plates through a rotating shaft, and the other end of the connecting rod is hinged to one end, far away from the lifting plate, of the cooling plate; wherein

When the floor abuts against the lifting plate, the floor extrudes the lifting plate to slide downwards, the lifting plate pushes the cooling plate to turn over circumferentially by taking the rotating shaft as an axis through the connecting rod, so that the floor on the cooling plate slides onto the conveying frame;

after the floor is driven by the linkage conveyer belt to move towards the cooling plate, the lifting plate slides upwards to abut against the linkage conveyer belt so as to clean the outer ring of the linkage conveyer belt positioned above.

Furthermore, the linkage assembly also comprises a compaction column, and the compaction column is vertically fixed at the middle section of the connecting rod; the other end of the compaction column extends to the linkage conveying belt; wherein

When the connecting rod synchronous belt compaction column vertically slides downwards, the compaction column is propped against the floor on the linkage conveying belt.

Furthermore, one end of the connecting rod, which is close to the lifting plate, is provided with an arc-shaped elastic sheet, and the arc surface of the arc-shaped elastic sheet faces the side wall of the floor; wherein

When the floor moves to abut against the lifting plate, the arc-shaped elastic sheet abuts against the floor from the end wall so as to compact the protective belt film on the side walls at the two ends of the floor.

Furthermore, two limiting columns are vertically fixed at two ends of one side wall of the lifting plate;

the inner side wall of the fixed plate is provided with a limiting groove matched with the limiting column, the limiting groove is vertically formed, a compression spring is arranged in each limiting groove, one end of each compression spring is fixed on the bottom wall of the limiting groove, and the other end of each compression spring is fixed on the outer wall of the limiting column; wherein

When the floor extrudes the lifting plate, the lifting plate pushes the limiting column to slide downwards along the limiting groove;

after the floor moves to the linkage conveyer belt, the compression spring pushes the limiting column to move upwards, so that the upper end of the lifting plate is abutted to the outer ring of the linkage conveyer belt.

Furthermore, a slope cleaning surface is arranged at the upper end of the lifting plate and is parallel to the outer ring of the linkage conveying belt; wherein

When the compression spring pushes the limit column to slide upwards to the slope cleaning surface to be abutted against the outer ring of the linkage conveying belt, the slope cleaning surface can clean impurities on the outer ring of the linkage conveying belt.

Further, the cooling assembly includes: the cooling air cylinder is vertically fixed on the transverse plate, the blowing plate is fixed at the end part of a piston rod of the cooling air cylinder, and the blowing plate is arranged below the transverse plate;

the two guide posts respectively penetrate through the transverse plate and are vertically fixed on the air blowing plate;

the blowing plate is horizontally arranged, blowing holes are respectively formed in the two sides of the blowing plate, which correspond to the floor, and a fan communicated with the blowing holes is fixed on the blowing plate; wherein

When the floor moves to the upper end of the cooling plate, the cooling cylinder pushes the air blowing plate to move to the floor to be offset, and the fan blows cold air to the two ends of the floor through the air blowing holes so as to cool the floor hot melting printing part.

Further, the printing part includes: the printing machine comprises a support, a printing cylinder, an unreeling assembly, a printing straight plate, a printing motor, a printing assembly, two hot-melting printing blocks and a pull belt assembly, wherein the support is vertically fixed on a workbench, the printing cylinder is vertically fixed at the upper end of the support, the unreeling assembly is fixed at one side, close to the printing cylinder, of the upper end of the support, and the unreeling assembly is suitable for supporting a protective film tape roll;

the printing straight plate is fixed at the end part of the piston rod of the printing cylinder and arranged below the bracket;

the printing assembly is fixed at the lower end of the printing straight plate and is linked with the pull belt assembly, and the printing assembly is suitable for pushing the protective film coil to be wound on the outer wall of the pull belt assembly;

the printing motor is fixed on the printing assembly, the drawstring assembly is arranged at the end part of a rotating shaft of the printing motor, and the drawstring assembly is horizontally arranged;

the two hot-melting marking blocks are symmetrically arranged at the lower end of the printing component; wherein

When the protection film roll coil of strip was from unreeling subassembly downwardly extending to stamp subassembly one side, stamp motor drive stretching strap subassembly rotated 180 to make the both ends of protection film area correspond two hot melt mark seal blocks, stamp cylinder drive hot melt mark seal block downstream, offset and hot melt mark with the floor in order to promote the protection film area.

Further, the draw tape assembly comprises: the hot melt marking device comprises a drawstring plate, two radian plates and a plurality of clamping blocks, wherein the drawstring plate is rectangular, the drawstring plate is vertically fixed at the end part of a rotating shaft of a printing motor, and two printing grooves matched with the hot melt marking blocks are formed in the drawstring plate in a mirror image manner;

two sides of each printing groove are respectively hinged with a clamping block, and the clamping blocks are closed and opened to clamp the protective film belt;

the two radian plates are respectively fixed at the two ends of the strap plate; wherein

When one clamping block clamps the protective film belt, the printing motor drives the drawstring plate to rotate 180 degrees so as to drive the protective film belt to be correspondingly placed on the floor printing station.

Further, the cutting assembly includes: the cutting positioning plate is vertically fixed on one side, close to the printing portion, of the workbench, and the cutting cylinder is fixed on the inner side of the cutting positioning plate;

the cutting limiting plate is fixed on the inner side of the cutting limiting plate, the cutting scissors are slidably arranged in the cutting limiting plate, and a knife handle of the cutting scissors is fixed at the end part of a piston rod of the cutting cylinder;

a waist-shaped groove is formed in the side wall of the cutting limit plate, a sliding block matched with the waist-shaped groove is fixed at the end part of the other cutter handle, and the waist-shaped groove is divided into a horizontal section and an arc section; wherein

When the cutting cylinder pushes the cutting scissors to slide forwards and the sliding block slides to the horizontal section, the cutting scissors are in an open state;

and when the cutting scissors are continuously pushed to enable the sliding block to slide to the arc section, the cutting scissors are in a closed state to cut off the protective film belt.

The invention has the beneficial effects that the invention provides the all-steel movable floor packaging device, and the film can be coated on the two ends of the floor and the floor can be subjected to hot melting and marking through the arrangement of the printing part. Through the setting of shearing assembly, can cut off the unnecessary protective film area of connecting on the floor. Through the setting of linkage cooling part, can blow the cooling to the hot melt seal mark part on floor to on transporting the carriage with the floor.

Drawings

The invention is further illustrated with reference to the following figures and examples.

FIG. 1 is a perspective view of a preferred embodiment of an all steel raised floor package of the present invention;

FIG. 2 is a perspective view of the ganged cooling portion of the present invention;

FIG. 3 is a perspective view of the linkage assembly of the present invention;

FIG. 4 is a perspective view of an embossed section of the present invention;

FIG. 5 is a perspective view of the cutting assembly of the present invention.

In the figure:

1. a work table; 2. a transport section;

3. a printing part; 31. a support; 32. a printing cylinder; 33. an unwinding assembly; 34. printing a straight plate; 35. a printing motor; 36. a printing assembly; 37. hot melting the marking block; 38. a drawstring assembly; 381. a strap plate; 382. a radian plate; 383. a clamping block;

4. cutting the assembly; 41. cutting a positioning plate; 42. a cutting cylinder; 43. cutting scissors; 44. cutting a limiting plate; 45. a horizontal segment; 46. a circular arc section;

5. a linkage cooling section; 51. a linkage motor; 52. a fixing plate; 53. a linkage conveyer belt; 54. a linkage assembly; 541. a connecting rod; 542. a lifting plate; 543. a cooling plate; 544. compacting the column; 545. an arc-shaped elastic sheet; 546. a limiting column; 547. a limiting groove; 548. cleaning a slope; 55. a cooling assembly; 551. a transverse plate; 552. cooling the cylinder; 553. a guide post; 554. a blowing plate;

6. and (4) a conveying frame.

Detailed Description

The present invention will now be described in further detail with reference to the accompanying drawings. These drawings are simplified schematic views illustrating only the basic structure of the present invention in a schematic manner, and thus show only the constitution related to the present invention.

As shown in fig. 1 to 5, the present invention provides an all-steel raised floor packaging device, including: the automatic printing machine comprises a workbench 1, a conveying part 2, two printing parts 3, two cutting assemblies 4, a linkage cooling part 5 and a conveying frame 6. The table 1 is adapted to carry a transport section 2, two embossing sections 3, two cutting assemblies 4 and a coordinated cooling section 5. The conveying section is adapted to convey the floor downstream from the loading end. The printing part 3 is suitable for coating films at two ends of the floor and hot-melting and marking the floor. The cutting assembly 4 is adapted to cut the strip of protective film remaining on the printed portion 3. The linkage cooling part 5 is adapted to cool the hot melt marking portions of the respective plates in sequence. The carriage 6 is adapted to transport the cooled work pieces to a discharge end. With respect to the above components, detailed description is given below.

Working table

The setting of workstation 1 is on a horizontal plane, and workstation 1 wholly is box structure, and the 1 upper end of workstation is level and smooth, and workstation 1 can regard as the shown mounting base of all steel raised floor packing plant of this embodiment, and the upper end is suitable for placing and installs transportation portion 2, two stamp portions 3, two cutting components 4, linkage cooling portion 5 promptly.

Transport section

The rotatable setting of transportation portion 2 is on workstation 1, and transportation portion 2 sets up in workstation 1 upper end, and transportation portion 2 sets up along 1 length direction of workstation. The conveying part upper surface is suitable for placing the floor, and the conveying part is suitable for carrying the floor from the material loading end to downstream to make the floor pass through two printing portions 3, two cutting assemblies 4 and linkage cooling portion 5 in proper order, thereby carry out each item processing to the floor in proper order.

Printing part

The printing portion 3 is fixed in 1 upper end of workstation, and printing portion 3 sets up in the conveying portion top, and the in-process on conveying portion 2 carried the floor, and the floor can remove to printing portion 3 below along with conveying portion. The printing portion 3 has the same two, and two printing portions 3 set gradually along conveying part length direction, and are provided with the clearance between two printing portions 3 to make one printing portion 3 correspond the one end on a floor, the floor removes to printing portion 3 below back promptly, and two printing portions 3 can be respectively to the tectorial membrane at the both ends on floor, and to floor hot melt seal mark. The printing portion 3 includes: the printing machine comprises a support 31, a printing air cylinder 32, an unreeling assembly 33, a printing straight plate 34, a printing motor 35, a printing assembly 36, two hot-melting printing blocks 37 and a drawing belt assembly 38. The support 31 is a rectangular plate horizontally placed, four corners of the support 31 are respectively and fixedly provided with four support legs, and the support 31 is fixedly connected with the workbench 1 through the support legs and keeps the support 31 suspended. The support 31 is suitable for mounting the printing cylinder 32 and the unreeling assembly 33, and meanwhile, the support 31 is vertical to the workbench 1, so that other components can be accurately positioned. The printing cylinder 32 is vertically fixed at the upper end of the support 31, the shell of the printing cylinder 32 is fixed at the upper end of the support 31, and a piston rod of the printing cylinder 32 vertically penetrates through the support 31 downwards. Unreel subassembly 33 and fix support 31 upper end is close to one side of stamp cylinder 32, it is suitable for supporting the protection film coil of strip to unreel subassembly 33. The printing straight plate 34 is fixed at the end part of a piston rod of the printing cylinder 32, and the printing straight plate 34 is arranged below the support 31. The printing plate 34 is adapted to mount a printing assembly 36, and the printing cylinder 32 is capable of driving the printing assembly 36 to rise and fall by the printing plate 34. The printing component 36 is fixed at the lower end of the printing straight plate 34, the printing component 36 is linked with the drawtape component 38, and the printing component 36 is suitable for pushing the protective film coil to be wound on the outer wall of the drawtape component 38. Stamp motor 35 is fixed on stamp subassembly 36, stamp motor 35 shell is fixed on stamp subassembly 36, and stamp motor 35's axis of rotation sets up down vertically, stretching strap subassembly 38 sets up stamp motor 35's axis of rotation tip, stretching strap subassembly 38 level sets up. Two hot melt marking blocks 37 are symmetrically arranged at the lower end of the printing component 36. The during operation, operating personnel can pull out the protection film area with the free end of protection film coil of strip to downwardly extending to 36 one sides of stamp subassembly, stamp motor 35 can drive stretching strap subassembly 38 and rotate 180, so that the both ends in protection film area correspond two hot melt mark seal blocks 37, stamp cylinder 32 drive hot melt mark seal block 37 moves down to offset with the protection film area, offsets and hot melt mark with the promotion protection film area and the floor.

In order to achieve the above-mentioned effect of clamping the protective film tape to rotate the protective film tape by 180 ° with the embossing motor 35, the draw tape assembly 38 includes: a drawstring plate 381, two arc plates 382, and a plurality of clamping blocks 383. The tape drawing board 381 is rectangular, the tape drawing board 381 is vertically fixed at the end part of a rotating shaft of the printing motor 35, and two printing grooves matched with the hot melting marking block 37 are formed in the mirror image of the tape drawing board 381. Two sides of each printing groove are respectively hinged with a clamping block 383, and the clamping blocks 383 are closed and opened to clamp the protective film strip. Two arc plates 382 are fixed at two ends of the drawstring plate 381 respectively. When one clamping block 383 clamps the protective film strip, the printing motor 35 drives the strip pulling plate 381 to rotate 180 degrees, so as to drive the protective film strip to be correspondingly placed on the floor printing station.

Cutting assembly

Cutting assembly 4 sets up in transport portion 2 both sides, specifically, cutting assembly 4 sets up in 3 low reaches in stamp portion, and the floor is through 3 tectorial membranes of stamp portion and to floor hot melt seal mark after, move to cutting assembly 4 and pass the in-process of cai jie subassembly one side, and cutting assembly 4 can cut off the protective film area to make protective film area break away from with the floor. The cutting assemblies 4 are also provided with two same cutting assemblies, one cutting assembly 4 corresponds to one printing portion 3, and one cutting assembly 4 can cut off the protective film strip after hot-melt marking of one printing portion 3.

The structure of the cutting assembly 4 is described in detail below, said cutting assembly 4 comprising: a cutting positioning plate 41, a cutting air cylinder 42, a cutting scissors 43 and a cutting limiting plate 44. The cutting positioning plate 41 is vertically fixed on one side, close to the printing portion 3, of the workbench 1, and the cutting positioning plate 41 is suitable for being provided with a cutting cylinder 42, a cutting scissors 43 and a cutting limiting plate 44. The cutting cylinder 42 is fixed inside the cutting positioning plate 41, i.e., the cutting cylinder 42 is disposed on the side toward the transporting portion 2. The cutting limiting plate 44 is fixed on the inner side of the cutting positioning plate 41, the cutting scissors 43 can be arranged in the cutting limiting plate 44 in a sliding mode, and one handle of each cutting scissors 43 is fixed at the end portion of a piston rod of the cutting cylinder 42. In addition, a waist-shaped groove is formed in the side wall of the cutting limit plate 44, a sliding block matched with the waist-shaped groove is fixed at the end of the other cutter handle, and the waist-shaped groove is divided into a horizontal section 45 and an arc section 46. When the cutting cylinder 42 pushes the cutting scissors 43 to slide forwards and the slide block slides to the horizontal section 45, the cutting scissors 43 are in an open state. When the cutting scissors 43 are pushed continuously to make the sliding block slide to the arc section 46, the cutting scissors 43 are in a closed state to cut off the protective film strip. In this way, when the floor moves between the cutting edges of the cutting scissors 43, the cutting air cylinder 42 can drive the sliding block to slide in the waist-shaped groove, so as to control the cutting scissors 43 to cut the protective film strip.

Linkage cooling part

The linkage cooling part 5 is arranged at the downstream of the cutting assembly 4, the linkage cooling part 5 is fixed on the workbench 1, and the linkage cooling part 5 is arranged above the blanking end of the conveying part 2. After the floor is conveyed to the tail end of the linkage cooling part 5, the floor can be moved to the linkage cooling part 5 from the conveying part 2, the linkage cooling part 5 can blow and cool the hot melting marking part of the floor, and the floor is conveyed to the conveying frame 6.

The structure of the freezing and cooling unit will be described in detail below, and the interlocking cooling unit 5 includes: linkage motor 51, two fixed plates 52, two linkage conveyer belts 53, linkage assembly 54 and cooling assembly 55. The two fixing plates 52 are vertically fixed on the workbench 1, and the two fixing plates 52 are arranged in parallel relatively. The linkage motor 51 is fixedly arranged on the outer side wall of the fixing plate 52 on one side, and the linkage motor 51 is horizontally arranged. The housing of the linkage motor 51 is fixed on the fixing plate 52, the output shaft of the linkage motor 51 is horizontally arranged, and the output shaft of the linkage motor 51 passes through the fixing plate 52. Two the link conveyer belt 53 is rotatable setting respectively two the fixed plate 52 inside wall, and two the link conveyer belt 53 all with the transmission of link motor 51 is connected, particularly, two link conveyer belt 53 both ends are provided with the runner, the runner rotates with the fixed plate 52 of both sides respectively and is connected, the runner that corresponds on two link conveyer belts 53 passes through a pivot and connects, the pivot is coaxial fixed with link motor 51's output shaft, link motor 51 during operation, can drive and correspond runner axial rotation, the both ends of a link conveyer belt 53 are connected through a belt, and a link conveyer belt 53 includes two-layer that vertical direction interval set up, the floor gets into between two fixed plates 52 after, can follow between two-layer belt of two link conveyer belt 53, and carry to carriage 6 directions under the transport of belt. The linkage assembly 54 is slidably disposed on an inner sidewall of the fixing plate 52, and the linkage assembly 54 is disposed between the two linkage belts 53. When the floor moves to abut against the front end of the linkage assembly 54 and the linkage assembly 54 is pressed downwards, the linkage assembly 54 abuts against the two sides of the floor so that the protective film belts on the two sides are attached to the two sides of the floor. The cooling unit 55 is disposed above the interlocking conveyor belt 53, and the cooling unit 55 is interlocked with the interlocking unit 54. Specifically, after the floor is moved to the rear end of the linkage assembly 54, the cooling assembly 55 can blow air to cool the hot melt printing points at both ends of the floor. In addition, when the next floor presses the linkage assembly 54, the rear end of the linkage assembly 54 flips to slide the floor below the cooling assembly 55 down onto the carriage 6.

In order to achieve the above-mentioned effects, the linkage assembly 54 includes: link 541, lift plate 542, and cooling plate 543. The connecting rods 541 are arranged along the moving direction of the linkage conveying belt 53, the connecting rods 541 are arranged in parallel, the connecting rods 541 are respectively located on the inner sides of the two fixing plates 52, the lifting plate 542 is slidably arranged on the inner side wall of the fixing plate 52, and the lifting plate 542 is arranged at the feeding end of the linkage conveying belt 53. Lifter plate 542 with workstation 1 is equipped with the contained angle, specifically, and lifter plate 542 inclines to set up, and lifter plate 542 one end is located transport portion 2 below, and the other end of lifter plate 542 is towards linkage conveyer belt 53. One end of the connecting rod 541 is fixed to the lifting plate 542. When the floor presses the lifting plate 542, the lifting plate 542 drives the connecting rod 541 to slide up and down integrally. The cooling plate 543 is rotatably disposed between the two fixing plates 52 through a rotating shaft, specifically, the cooling plate 543 is rotatably disposed on a rotating shaft along a length direction, and the other end of the connecting rod 541 is hinged to an end of the cooling plate 543 away from the lifting plate 542. In this way, when the next floor abuts against the lifting plate 542, the floor presses the lifting plate 542 to slide downward, and the lifting plate 542 pushes the cooling plate 543 via the connecting rod 541 to turn over around the rotating shaft, so that the floor on the cooling plate 543 slides down onto the carriage 6.

In addition, a slope cleaning surface 548 is arranged at the upper end of the lifting plate 542, and the slope cleaning surface 548 is parallel to the outer ring of the linkage conveying belt 53. When the lifting plate 542 is not pressed by the floor, the slope cleaning surface 548 abuts against the upper outer ring of the linkage conveyor belt 53, and the slope cleaning surface 548 can clean the impurities on the outer ring of the linkage conveyor belt 53. To prevent impurities on the floor from being contaminated, and transferred to the next floor through the interlocking conveyor belt 53 while passing through the interlocking conveyor belt 53.

In order to compact the thermal printing on the floor during the transportation of the floor by the interlocking conveyor belt 53, the interlocking unit 54 further includes a compression column 544, and the compression column 544 is vertically fixed to the middle section of the connecting rod 541. The other end of the compression column 544 extends toward the conveyor belt 53. When the connecting rod 541 synchronously drives the compaction column 544 to slide vertically downward, the compaction column 544 abuts against the floor on the linkage conveying belt 53, so as to compact the hot-melt printing on the floor. Therefore, in this embodiment, three floor boards can be simultaneously present inside the linkage cooling unit 5, and when the floor board located at the rearmost position presses the lifting plate 542, the lifting plate 542 drives the pressing column 544 through the link 541 to press the thermal print located at the upper end of the floor board located at the middle stage, and the link 541 drives the cooling plate 543 to rotate, so that the floor board located at the frontmost position slides onto the carriage 6.

In order to enable the protective film strips connected to two ends of the floor in a hot melting mode to be attached to the floor tightly and prevent the protective film strips from being hung on the connecting rod 541, an arc-shaped elastic sheet 545 is arranged at one end, close to the lifting plate 542, of the connecting rod 541, and the arc surface of the arc-shaped elastic sheet 545 faces the side wall of the floor. When the floor moves to abut against the lifting plate 542, the arc-shaped resilient pieces 545 abut against the floor from the end walls, thereby compressing the protective tape film against the side walls at both ends of the floor.

In order to guide the lifting direction of the lifting plate 542 and drive the lifting plate 542 to reset, two limiting columns 546 are vertically fixed at two ends of a side wall of the lifting plate 542, a limiting groove 547 matched with the limiting columns 546 is formed in the inner side wall of the fixing plate 52, the limiting groove 547 is vertically formed, and the lifting plate 542 can slide in the limiting groove 547 through the limiting columns 546, so that the effect that the lifting plate 542 can vertically lift under the pressing of the floor is achieved. Meanwhile, a compression spring is arranged in each limiting groove 547, one end of each compression spring is fixed to the bottom wall of the limiting groove 547, and the other end of each compression spring is fixed to the outer wall of the limiting column 546. After the floor moves to the linkage conveyer belt 53, the compression spring pushes the limit post 546 to move upwards, so that the slope cleaning surface 548 abuts against the upper layer outer ring of the linkage conveyer belt 53, and the upper layer of the linkage conveyer belt 53 is cleaned.

In order to cool the floor thermal fusing printing part 3 when the floor is moved above the cooling plate 543, the cooling module 55 includes: a cross plate 551, a cooling cylinder 552, two guide posts 553, and a blow plate 554. The two ends of the transverse plate 551 are respectively fixed on the two fixing plates 52, the transverse plate is horizontally arranged, the cooling cylinder 552 is vertically fixed on the transverse plate 551, and the piston rod of the cooling cylinder 552 vertically penetrates through the transverse plate 551 downwards. The blow plate 554 is fixed to the end of the piston rod of the cooling cylinder 552, and the blow plate 554 is disposed below the cross plate 551. The two guide posts 553 respectively penetrate the cross plate 551 and are vertically fixed to the blowing plate 554, and the blowing plate 554 can be ensured to slide in the vertical direction by the arrangement of the two guide posts 553. The blowing plate 554 is horizontally arranged, blowing holes are formed in the two sides, corresponding to the floor, of the blowing plate 554 respectively, and a fan communicated with the blowing holes is fixed on the blowing plate 554. When the floor moves to cooling plate 543 upper end, cooling cylinder 552 promotes to blow board 554 and removes to offset to the floor, and the fan blows cold wind to floor both ends through blowing the hole to cool off floor hot melt stamp position, after the cooling is accomplished, cooling cylinder 552 drive blows board 554 and breaks away from with the floor, and lifter plate 542 is pressed to next floor, and cooling plate 543 upset, so that the floor after the cooling landing is on carriage 6.

Conveying rack

The conveying frame 6 is fixed at the blanking end of the workbench 1, and the conveying frame 6 is arranged below the cooling plate 543. The carriage 6 can convey the floor dropped on the upper surface of the carriage 6 toward the blanking end of the carriage 6.

In light of the foregoing description of the preferred embodiment of the present invention, it is to be understood that various changes and modifications may be made by one skilled in the art without departing from the spirit and scope of the invention. The technical scope of the present invention is not limited to the content of the specification, and must be determined according to the scope of the claims.

Claims (10)

1. An all-steel raised floor packaging unit, comprising:

the floor cutting machine comprises a workbench (1), a conveying part (2), two printing parts (3), two cutting assemblies (4), a linkage cooling part (5) and a conveying frame (6), wherein the conveying part (2) is arranged on the workbench (1) in a circulating and rotating mode, and the conveying part (2) is suitable for conveying floors;

the two printing parts (3) are fixed at the upper end of the workbench (1), the printing parts (3) are arranged above the conveying part (2), one printing part (3) corresponds to one end of the floor, and the printing parts (3) are suitable for hot melt marking after film coating is carried out on the two ends of the floor;

the cutting assemblies (4) are arranged on one side of the printing portion (3), one cutting assembly (4) corresponds to one printing portion (3), and the cutting assemblies (4) are suitable for cutting off the protective film belt;

the conveying frame (6) is fixed at the discharging end of the workbench (1), and the conveying frame (6) is arranged below the linkage cooling part (5);

linkage cooling portion (5) set up in workstation (1) and are close to the top of transport portion (2) unloading end, linkage cooling portion (5) include: the device comprises a linkage motor (51), two fixing plates (52), two linkage conveying belts (53), a linkage assembly (54) and a cooling assembly (55), wherein the two fixing plates (52) are vertically fixed on the workbench (1), and the two fixing plates (52) are arranged in parallel relatively;

the two linkage conveyer belts (53) are respectively and rotatably arranged on the inner side walls of the two fixing plates (52), and the two linkage conveyer belts (53) are in transmission connection with the linkage motor (51);

the linkage motor (51) is fixed on the outer side wall of the fixing plate (52);

the linkage assembly (54) is arranged on the inner side wall of the fixed plate (52) in a vertically sliding mode, and the linkage assembly (54) is arranged between the two linkage conveying belts (53);

the cooling assembly (55) is arranged above the linkage conveying belt (53), and the cooling assembly (55) is linked with the linkage assembly (54); wherein

When the transportation part (2) drives the floor to horizontally move to the lower end of the printing part (3), the printing part (3) can be used for simultaneously laminating films on two ends of the floor and thermally melting and printing marks;

when the floor moves to abut against the front end of the linkage component (54) and the linkage component (54) is extruded downwards, the linkage component (54) abuts against the two sides of the floor so that the protective film belts on the two sides are attached to the two sides of the floor;

when the floor moves to the middle section of the linkage assembly (54), the next floor downwards presses the linkage assembly (54) so that the linkage assembly (54) downwards presses the floor at the middle section position to compact the protective film belt;

when the floor moves to the rear end of the linkage assembly (54) and is positioned below the cooling assembly (55), the cooling assembly (55) can blow air to the hot melt printing points at the two ends of the floor for cooling;

when the next floor presses the linkage assembly (54) down, the floor below the cooling assembly (55) is turned onto the carriage (6) by turning the rear end of the linkage assembly (54).

2. The all-steel raised floor packaging unit of claim 1, wherein,

the linkage assembly (54) includes: the linkage device comprises a connecting rod (541), a lifting plate (542) and a cooling plate (543), wherein the connecting rod (541) is arranged along the moving direction of the linkage conveying belt (53);

the lifting plate (542) is slidably arranged on the inner side wall of the fixing plate (52), the lifting plate (542) is arranged at the feeding end of the linkage conveying belt (53), an included angle is formed between the lifting plate (542) and the workbench (1), and one end of the connecting rod (541) is fixed on the lifting plate (542);

the cooling plate (543) is rotatably arranged between the two fixing plates (52) through a rotating shaft, and the other end of the connecting rod (541) is hinged to one end, far away from the lifting plate (542), of the cooling plate (543); wherein

When the floor abuts against the lifting plate (542), the floor extrudes the lifting plate (542) to slide downwards, the lifting plate (542) pushes the cooling plate (543) to turn over circumferentially by taking the rotating shaft as the shaft through the connecting rod (541), so that the floor on the cooling plate (543) slides down onto the conveying frame (6);

after the floor is driven by the linkage conveying belt (53) to move towards the cooling plate (543), the lifting plate (542) slides upwards to abut against the linkage conveying belt (53) so as to clean the outer ring of the linkage conveying belt (53) positioned above.

3. The all-steel raised floor packaging unit of claim 2,

the linkage assembly (54) further comprises a compaction post (544), and the compaction post (544) is vertically fixed at the middle section of the connecting rod (541); the other end of the compaction column (544) extends to the linkage conveying belt (53); wherein

When the connecting rod (541) synchronously drives the compaction column (544) to vertically slide downwards, the compaction column (544) is pressed against the floor on the linkage conveying belt (53).

4. The all-steel raised floor packaging unit of claim 3, wherein,

one end of the connecting rod (541) close to the lifting plate (542) is provided with an arc-shaped elastic sheet (545), and the arc surface of the arc-shaped elastic sheet (545) faces the side wall of the floor; wherein

When the floor moves to abut against the lifting plate (542), the arc-shaped elastic sheets (545) abut against the floor from the end walls so as to press the protective belt films on the side walls at the two ends of the floor.

5. The all-steel raised floor packaging unit of claim 4, wherein,

two limiting columns (546) are vertically fixed at two ends of one side wall of the lifting plate (542);

the inner side wall of the fixing plate (52) is provided with a limiting groove (547) matched with the limiting column (546), the limiting groove (547) is vertically formed, a compression spring is arranged in each limiting groove (547), one end of each compression spring is fixed to the bottom wall of the corresponding limiting groove (547), and the other end of each compression spring is fixed to the outer wall of the corresponding limiting column (546); wherein

When the floor extrudes the lifting plate (542), the lifting plate (542) pushes the limiting columns (546) to slide downwards along the limiting grooves (547);

after the floor moves to the linkage conveyer belt (53), the compression spring pushes the limiting column (546) to move upwards, so that the upper end of the lifting plate (542) is abutted against the outer ring of the linkage conveyer belt (53).

6. The all-steel raised floor packaging unit of claim 5, wherein,

a slope cleaning surface (548) is arranged at the upper end of the lifting plate (542), and the slope cleaning surface (548) is parallel to the outer ring of the linkage conveying belt (53); wherein

When the compression spring pushes the limit column (546) to slide upwards to the slope cleaning surface (548) to be abutted against the outer ring of the linkage conveying belt (53), the slope cleaning surface (548) can clean impurities on the outer ring of the linkage conveying belt (53).

7. The all-steel raised floor packaging unit of claim 6, wherein,

the cooling assembly (55) comprises: the device comprises a transverse plate (551), a cooling cylinder (552), two guide posts (553) and a blowing plate (554), wherein two ends of the transverse plate (551) are respectively fixed on two fixing plates (52), the cooling cylinder (552) is vertically fixed on the transverse plate (551), the blowing plate (554) is fixed at the end part of a piston rod of the cooling cylinder (552), and the blowing plate (554) is arranged below the transverse plate (551);

the two guide posts (553) respectively penetrate through the transverse plate (551) and are vertically fixed on the air blowing plate (554);

the air blowing plate (554) is horizontally arranged, air blowing holes are formed in the two sides, corresponding to the floor, of the air blowing plate (554), and a fan communicated with the air blowing holes is fixed on the air blowing plate (554); wherein

When the floor moves to cooling plate (543) upper end, cooling cylinder (552) promote to blow wind board (554) and move to offseting to the floor, and the fan blows cold wind to floor both ends through blowing the hole to cool floor hot melt stamp position.

8. The all-steel raised floor packaging unit of claim 7,

the printing section (3) includes: the device comprises a support (31), a printing cylinder (32), an unreeling assembly (33), a printing straight plate (34), a printing motor (35), a printing assembly (36), two hot-melt marking blocks (37) and a pull belt assembly (38), wherein the support (31) is vertically fixed on a workbench (1), the printing cylinder (32) is vertically fixed at the upper end of the support (31), the unreeling assembly (33) is fixed at one side, close to the printing cylinder (32), of the upper end of the support (31), and the unreeling assembly (33) is suitable for supporting a protective film tape reel;

the printing straight plate (34) is fixed at the end part of a piston rod of the printing cylinder (32), and the printing straight plate (34) is arranged below the bracket (31);

the printing assembly (36) is fixed at the lower end of the printing straight plate (34), the printing assembly (36) is in linkage with the pull belt assembly (38), and the printing assembly (36) is suitable for pushing the protective film coil to be wound on the outer wall of the pull belt assembly (38);

the printing motor (35) is fixed on the printing assembly (36), the pull belt assembly (38) is arranged at the end part of a rotating shaft of the printing motor (35), and the pull belt assembly (38) is horizontally arranged;

the two hot melting marking blocks (37) are symmetrically arranged at the lower end of the printing component (36); wherein

When the protection film tape rolls up from unreeling subassembly (33) downwardly extending to stamp subassembly (36) one side, stamp motor (35) drive stretching strap subassembly (38) rotate 180 to two hot melt mark stamp blocks (37) are corresponded to at the both ends of messenger's protection film tape, stamp cylinder (32) drive hot melt mark stamp block (37) move down, offset and hot melt mark with the floor in order to promote the protection film tape.

9. The all-steel raised floor packaging unit of claim 8,

the draw tape assembly (38) includes: the hot melt marking device comprises a tape drawing plate (381), two arc plates (382) and a plurality of clamping blocks (383), wherein the tape drawing plate (381) is rectangular, the tape drawing plate (381) is vertically fixed at the end part of a rotating shaft of the printing motor (35), and two printing grooves matched with the hot melt marking blocks (37) are formed in the mirror image of the tape drawing plate (381);

two sides of each printing groove are respectively hinged with a clamping block (383), and the clamping blocks (383) are closed and opened to clamp the protective film strip;

the two arc plates (382) are respectively fixed at two ends of the drawstring plate (381); wherein

When one clamping block (383) clamps the protective film strip, the printing motor (35) drives the strip pulling plate (381) to rotate 180 degrees so as to drive the protective film strip to be correspondingly placed on a floor printing station.

10. The all-steel raised floor packaging unit of claim 9, wherein,

the cutting assembly (4) comprises: the cutting device comprises a cutting positioning plate (41), a cutting cylinder (42), cutting scissors (43) and a cutting limiting plate (44), wherein the cutting positioning plate (41) is vertically fixed on one side, close to the printing part (3), of the workbench (1), and the cutting cylinder (42) is fixed on the inner side of the cutting positioning plate (41);

the cutting limiting plate (44) is fixed on the inner side of the cutting positioning plate (41), the cutting scissors (43) can be arranged in the cutting limiting plate (44) in a sliding mode, and one handle of each cutting scissors (43) is fixed at the end portion of a piston rod of the cutting cylinder (42);

a waist-shaped groove is formed in the side wall of the cutting limit plate (44), a sliding block matched with the waist-shaped groove is fixed at the end part of the other cutter handle, and the waist-shaped groove is divided into a horizontal section (45) and an arc section (46); wherein

When the cutting cylinder (42) pushes the cutting scissors (43) to slide forwards and the sliding block slides to the horizontal section (45), the cutting scissors (43) are in an open state;

and when the cutting scissors (43) are pushed continuously to enable the sliding block to slide to the arc section (46), the cutting scissors (43) are in a closed state to cut off the protective film strip.

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