CN220096787U - Conveying and stacking device on non-woven fabric - Google Patents

Abstract

The utility model relates to the field of packaging equipment, in particular to a non-woven fabric on-conveying stacking device which comprises a mounting bracket, a conveying assembly and a limiting assembly, wherein the conveying assembly is used for driving a non-woven fabric plate to move, the limiting assembly comprises a belt, a baffle and a belt wheel, the belt wheel is rotationally connected to the mounting bracket, the belt is wound on the belt wheel to form an annular structure, the baffle is connected to the outer side wall of the belt, the belt can drive the baffle to move along the conveying direction, and the baffle can be attached to the side surface of the non-woven fabric plate in the moving process. The utility model has the effect of reducing the occurrence of dislocation in the transportation process of the multi-layer cloth in the non-woven fabric plate.

Description

Conveying and stacking device on non-woven fabric

Technical Field

The utility model relates to the technical field of packaging equipment, in particular to a conveying and stacking device on non-woven fabrics.

Background

In the packaging of sheet-like products (e.g. wet tissues, nonwoven webs, etc.), the packaging is largely divided into two steps, stacking and packaging. The production equipment is divided into an upper conveying device and a lower conveying device according to the process. Wherein the upper conveying device is mainly used for stacking products. Taking stacking of nonwoven fabric boards as an example, after the nonwoven fabric boards are cut, two nonwoven fabric boards (in this embodiment, the nonwoven fabric boards are formed by cutting a plurality of layers of stacked nonwoven fabrics) are conveyed at intervals, and in some packages, the adjacent two nonwoven fabric boards need to be attached to each other on the sides close to each other, so that the two nonwoven fabric boards conveyed at intervals need to be aligned first, and then stacking is performed.

The upper conveying device mainly comprises a mounting bracket, a conveying belt and an alignment pressing piece. The conveyor belts are arranged in two, the two conveyor belts are arranged on the mounting bracket at intervals in parallel along the horizontal direction, and the rotation axis of the conveyor belts is perpendicular to the ground. A stacking channel is arranged on the mounting bracket at a position corresponding to the position between the two conveyor belts. The two sides of the non-woven fabric plate are erected at the edges of the two sides of the stacking channel, and the two sides of the non-woven fabric plate parallel to the conveying direction of the conveying belt are attached to the belt of the conveying belt and keep a certain pressure. The hold-down is disposed above the conveyor belt and is slidable in a vertical direction. The pushing piece comprises a pressing part and a blocking part, the pressing part is of a rectangular plate-shaped structure, and the pressing part is horizontally arranged. The blocking part is of a plate-shaped structure and is vertically welded below the pressing part. When the stacking device works, the non-woven fabric plate is driven to move under the action of friction force between the belt of the conveyor belt and the non-woven fabric plate. When the nonwoven fabric sheet moves below the hold-down member, the hold-down member moves downward. In the downward moving process of the pressing piece, the baffle firstly blocks the non-woven fabric plate from moving from one side of the non-woven fabric plate, and the non-woven fabric plate positioned behind the non-woven fabric plate continues to move until the mutually approaching side surfaces of two adjacent non-woven fabric plates are mutually attached. And then the pressing piece continuously moves downwards, the pressing part abuts against the upper surface of the non-woven fabric plates along with the movement of the pressing piece, and the pressing piece drives the two non-woven fabric plates to simultaneously fall on the stacking plate through the stacking channel. Repeating the steps, and carrying out the next packaging process after stacking a certain number of non-woven fabric plates on the stacking plates.

In the related art, the non-woven fabric plate is driven to move by the conveyor belt through friction force, and after the equipment is used for a period of time, the friction coefficient of each part on the conveyor belt changes due to different wear degrees. When the friction force on the belts of the two conveyor belts is uneven, the two conveyor belts cannot drive the multi-layer cloth in the non-woven fabric plate to move at the same time. Thereby causing the dislocation of the multi-layered cloth in the nonwoven fabric panel during the conveyance of the nonwoven fabric panel, such as: the frictional forces between the belts of the two conveyor belts and the sides of the nonwoven fabric panel are different in magnitude, causing the nonwoven fabric panel to rotate about the vertical axis. Or the belt of the conveyor belt has different friction force in the vertical direction, so that the multi-layer cloth in the paperboard is misplaced in the vertical direction. The palletizing apparatus in the related art is thus liable to be dislocated in the multi-layered cloth in the cardboard during the conveyance of the paper towel.

Disclosure of Invention

In order to reduce the occurrence of paper towel stacking dislocation, the utility model provides a non-woven fabric upper conveying stacking device.

The utility model provides a non-woven fabric upper conveying stacking device which adopts the following technical scheme:

the utility model provides a carry stacking device on non-woven fabrics, includes the installing support, still includes conveying component and spacing subassembly, conveying component is used for driving the non-woven fabrics board and removes, spacing subassembly includes belt, baffle and band pulley, the band pulley rotates to be connected on the installing support, the belt winds to establish on individual band pulley, forms annular structure, the baffle is connected on the lateral wall of belt, the belt can drive the baffle and remove along direction of delivery, the baffle removes the in-process and can laminate with non-woven fabrics board side.

Through adopting above-mentioned technical scheme, pile up neatly device operation in-process, conveying component drives the non-woven fabrics board and removes. The non-woven fabrics board rotates around the belt on the belt wheel in the moving process, so that the baffle plate is driven to move towards the moving direction of the non-woven fabrics board, and the moving speed of the baffle plate is slightly higher than the moving speed of the non-woven fabrics board. The baffle plates are attached to the side surfaces of the non-woven fabric plates when moving and move along with the movement of the non-woven fabric plates. Realize that the non-woven fabrics board carries out spacingly to the non-woven fabrics board in the transportation process, reduce the phenomenon that the multilayer cloth in the non-woven fabrics board appears dislocation in the transportation process of non-woven fabrics board.

Optionally, the baffle is disposed in plurality along the circumferential direction of the belt.

Through adopting above-mentioned technical scheme, a plurality of baffles can carry out spacingly to a plurality of non-woven fabrics boards simultaneously to improve the production efficiency of pile up neatly equipment under the circumstances that does not change the belt speed.

Optionally, the mounting bracket is provided with a stabilizing component, the stabilizing component comprises a stabilizing wheel, the stabilizing wheel is rotationally connected to the mounting bracket, the rotation axis of the stabilizing wheel is parallel to the rotation axis of the belt wheel, the stabilizing wheel is located inside an annular structure formed by the belt, and the side wall of the stabilizing wheel is tangent to the inner side wall of the belt.

Through adopting above-mentioned technical scheme, the stabilizer wheel butt is on the inside wall of belt to can reduce the belt and rock the condition about because of centripetal force appears in the rotation in-process.

Optionally, the belt with conveying assembly is located the both sides of non-woven fabrics plate thickness direction respectively, be provided with the regulating part between band pulley and the installing support, the regulating part includes the regulation pole, it connects on the installing support to adjust the pole rotation, the axis of rotation of adjusting the pole is on a parallel with the axis of rotation of band pulley, the band pulley rotates to be connected on the regulating part, the axis of rotation of band pulley is located the position of keeping away from the axis of rotation of adjusting pole and installing support on adjusting the pole.

Through adopting above-mentioned technical scheme, rotate the regulation pole and can drive the band pulley whole rotation around the axis of rotation of regulation pole, and then can adjust the band pulley and follow the ascending position of direction of perpendicular to direction of delivery, realize the interval to belt and conveying assembly between. The stacking device can adapt to the stacking of non-woven fabric plates with different thicknesses.

Optionally, still be provided with tensioning adjustment mechanism on the installing support, tensioning adjustment mechanism includes the regulating wheel, the regulating wheel rotates to be connected on the installing support, the axis of rotation of regulating wheel is parallel with the axis of rotation of band pulley, the regulating wheel can be followed the direction of perpendicular to self axis of rotation and slided, the lateral wall and the belt inside wall butt of regulating wheel.

Through adopting above-mentioned technical scheme, sliding adjusting wheel can make adjusting wheel support tight belt and make the belt expand to adjust the tensioning length of belt, with the rotation that makes the belt can be more stable, improve spacing subassembly to the spacing stability of non-woven fabrics board.

Optionally, tensioning adjustment mechanism still includes adjusting part, and adjusting part includes sliding seat and adjusting screw, sliding seat sliding connection is on the installing support, the regulating wheel rotates to be connected on the sliding seat, adjusting screw sets up along the slip direction of sliding seat, adjusting screw rotates to be connected on the installing support, and adjusting screw and sliding seat threaded connection.

Through adopting above-mentioned technical scheme, rotate adjusting screw and can drive the sliding seat and remove under the effect of screw thread, make things convenient for the staff to adjust the position of regulating wheel. And threaded connection has the auto-lock nature, is difficult for removing after the position adjustment of sliding seat, can improve the stability of adjusting wheel pair belt tensioning.

Optionally, the limiting component further comprises a driving roller, the driving roller is rotatably arranged on the mounting bracket, the driving roller is located above the belt wheel, and the belt is wound on the belt wheel and the driving roller at the same time.

By adopting the technical scheme, the driving piece drives the driving roller to automatically rotate, and then drives the belt to automatically rotate.

Optionally, two limiting plates are arranged on the mounting bracket, the two limiting plates are arranged on two sides of the non-woven fabric plate along the direction perpendicular to the conveying direction, and in the moving process of the non-woven fabric plate, two side faces perpendicular to the axis of the belt wheel are attached to two side faces, close to each other, of the limiting plates.

Through adopting above-mentioned technical scheme, the non-woven fabrics board removes the in-process, and the limiting plate carries out spacingly to the both sides of non-woven fabrics board perpendicular to band pulley axis from both sides to the condition that the multilayer cloth misplaced appears in the further reduction non-woven fabrics board transportation.

In summary, the utility model has the following beneficial technical effects:

the belt wheel rotates to drive the baffle to move, so that the baffle can always limit one side of the non-woven fabric plate in the conveying process of the non-woven fabric plate, the phenomenon that multiple layers of cloth are misplaced in the non-woven fabric plate is reduced, and the uniformity of the stacking device after stacking is improved.

Drawings

Fig. 1 is a schematic overall structure of an embodiment of the present utility model.

Fig. 2 is an enlarged view of a portion a of fig. 1, mainly for illustrating a structure of the limiting assembly according to an embodiment of the present utility model.

Fig. 3 is an enlarged view of portion B of fig. 1, primarily for illustrating the construction of the tension adjusting assembly, in accordance with an embodiment of the present utility model.

Fig. 4 is an enlarged view of a portion C of fig. 1, mainly for showing the structure of the pressing mechanism, according to an embodiment of the present utility model.

Reference numerals: 1. a mounting bracket; 2. a transport assembly; 21. a rotating wheel; 22. a synchronous belt; 23. a rotating roller; 3. a limit component; 31. a belt wheel; 32. a baffle; 33. a driving roller; 34. a limiting plate; 35. a belt; 4. an adjusting member; 41. a rotating cylinder; 42. an adjusting rod; 5. a stabilizing assembly; 51. a stabilizing wheel; 52. a mounting base; 521. an adjusting plate; 522. a connecting shaft; 6. a tension adjusting mechanism; 61. an adjustment assembly; 611. a support base; 612. a sliding seat; 613. a rotating shaft; 614. adjusting a screw; 62. an adjusting wheel; 7. a pressing mechanism; 71. a pressing member; 711. pressing the plate; 712. a connecting plate; 72. a lifting assembly; 721. a rotating member; 722. and a connecting frame.

Detailed Description

The utility model is described in further detail below with reference to fig. 1-4.

The embodiment of the utility model discloses a conveying and stacking device on non-woven fabrics.

Referring to fig. 1, a device for conveying and stacking non-woven fabrics comprises a mounting bracket 1, a conveying assembly 2, a limiting assembly 3 and a pressing mechanism 7, wherein the conveying assembly 2, the limiting assembly 3 and the pressing mechanism 7 are mounted on the mounting bracket 1. The conveying assembly 2 is used for driving the non-woven fabric plate to move. The limiting component 3 is located above the conveying component 2 and is used for limiting the non-woven fabric boards which are continuously placed in the process that the conveying component 2 drives the non-woven fabric boards to move, so that the situation that dislocation occurs in multiple layers of cloth in the non-woven fabric boards is reduced. A placing table (not shown in the figure) for placing the nonwoven fabric sheet is arranged below the conveying assembly 2, and a pressing mechanism 7 is arranged above the conveying assembly 2 and is used for pressing the nonwoven fabric sheet to enable the nonwoven fabric sheet to fall onto the placing table. The pressing mechanism 7 repeats the pressing process to realize stacking of a plurality of nonwoven fabric boards.

Referring to fig. 1 and 2, the conveying assembly 2 includes two sets of rotating wheels 21 and two timing belts 22, the two sets of rotating wheels 21 being disposed at intervals in a direction perpendicular to the conveying direction. Each set of turning wheels 21 comprises two turning wheels 21, the two turning wheels 21 in the same set being arranged in the conveying direction. The rotating wheels 21 are rotatably mounted on the mounting bracket 1, and two belts 35 are provided corresponding to the two sets of rotating wheels 21 and respectively wound around the two sets of rotating wheels 21. A gap exists between the two belts 35 so that the nonwoven fabric sheet can fall from the gap between the two timing belts 22 onto the placement table when the pressing mechanism 7 presses the nonwoven fabric sheet. The mounting bracket 1 is further provided with a rotating roller 23, the rotating roller 23 is rotatably connected to the mounting bracket 1, and the rotating axis of the rotating roller 23 is parallel to the rotating axis of the rotating wheel 21. The two synchronous belts 22 are wound on the rotating roller 23, and one end of the rotating roller 23 is provided with a servo motor for driving the synchronous belts to rotate. The rotation of the driving shaft of the servo motor can drive the rotating roller 23 to rotate, and further drive the two synchronous belts 22 to rotate simultaneously. The non-woven fabrics board is located two hold-in range 22 top, and the hold-in range 22 can drive the non-woven fabrics board when rotating and remove, and then realizes the transport on the non-woven fabrics board horizontal direction.

Referring to fig. 1 and 2, the spacing assembly 3 includes a belt 35, a shutter 32, and two pulleys 31 rotatably provided on the mounting bracket 1 at intervals in the conveying direction, the belt 35 being wound around the two pulleys 31. The baffle 32 is adhered to the outer side wall of the belt 35. The belt wheel 31 can drive the belt 35 to rotate when rotating, and then drive the baffle 32 to move along the circumferential direction of the belt 35. The belt speed of the belt 35 in the limit assembly 3 is greater than the belt speed of the timing belt 22 in the conveying assembly 2. In the operation process of the stacking device, when the baffle 32 is positioned on one side of the belt 35, which is close to the conveying assembly 2, the baffle 32 can be abutted against the side surface of the non-woven fabric plate and push the rear non-woven fabric plate to approach the front non-woven fabric plate, so that the two non-woven fabric plates are attached to the side surfaces, which are close to each other, and the grouping of the non-woven fabric plates is realized. Meanwhile, in the process of pushing the non-woven fabric plate by the baffle plate 32, the baffle plate 32 is attached to the side face of the non-woven fabric plate to limit the multi-layer cloth in the non-woven fabric plate, so that the phenomenon that the multi-layer cloth in the non-woven fabric plate is misplaced in the conveying process can be reduced. To improve the efficiency of the alignment assembly in grouping the nonwoven fabric panels, the baffles 32 are arranged in plurality along the circumference of the belt 35; so that the plurality of nonwoven fabric panels can be grouped by one rotation of the belt 35. The spacing between adjacent baffles 32 should be greater than the dimension in the conveying direction of the nonwoven fabric sheets in the same group prior to being bonded to each other.

Referring to fig. 1 and 2, the limit assembly 3 further includes two limit plates 34, the limit plates 34 are mounted on the mounting bracket 1, and the two limit plates 34 are disposed on both sides of the two timing belts 22 in a direction parallel to the axis of the pulley 31, respectively. The two side faces of the non-woven fabric plate perpendicular to the axis of the belt wheel 31 are attached to the two side faces of the two limiting plates 34 close to each other in the moving process of the non-woven fabric plate, so that the two side faces of the non-woven fabric plate perpendicular to the axis of the belt wheel 31 are limited, and the situation that dislocation occurs in the multi-layer cloth in the non-woven fabric plate in the transporting process is further reduced.

Referring to fig. 1 and 2, the spacing assembly 3 further includes a driving roller 33, the driving roller 33 is rotatably connected to the mounting bracket 1, and the rotating roller 23 is located above the pulley 31. The rotation axis of the rotating roller 23 is parallel to the rotation axis of the pulleys 31, and the belt 35 is wound around both the driving roller 33 and the two pulleys 31. One end of the driving roller 33 is provided with a servo motor, an output shaft of the servo motor is coaxially welded at one end of the driving roller 33, and a shell of the servo motor is welded on the mounting bracket 1. The output shaft of the servo motor rotates to drive the driving roller 33 to rotate, and then drives the belt 35 to rotate.

Referring to fig. 1 and 2, the mounting bracket 1 is provided with two adjustment members 4 corresponding to the pulleys 31. The adjusting member 4 includes a rotary cylinder 41 and an adjusting lever 42. The mounting bracket 1 is welded with a support shaft, the axis of which is parallel to the rotation axis of the pulley 31. The rotating cylinder 41 has a circular cylindrical structure, the rotating cylinder 41 is coaxially sleeved on the support shaft, and the rotating cylinder 41 can rotate around the axis thereof. One end of the adjusting lever 42 is welded to the outer sidewall of the rotary cylinder 41, and the other end extends in the radial direction of the rotary cylinder 41. The pulley 31 is rotatably coupled to the adjustment lever 42, and the pulley 31 is located on the adjustment lever 42 at a position away from the rotary drum 41. The rotation of the rotary drum 41 can drive the pulley 31 to rotate integrally around the axis of the rotary drum 41. Thereby achieving adjustment of the position of the pulley 31 in the vertical direction. So that the distance between the belt 35 and the timing belt 22 can be adjusted according to the thickness of the cardboard, so that the palletizing device can adapt to the production of nonwoven fabric boards with different thicknesses.

Referring to fig. 1 and 2, the end of the support shaft remote from the mounting bracket 1 is penetrated from the inside of the rotary cylinder 41. The support shaft is provided with the external screw thread far away from the one end of installing support 1 to threaded connection has lock nut. Rotating the lock nut can enable the lock nut to abut against the rotating cylinder 41, so that the rotating cylinder 41 is limited in rotation; the rotation condition of the rotating cylinder 41 in the using process of the stacking device is reduced, and the running stability of the limiting assembly 3 is improved.

Referring to fig. 1 and 2, the mounting bracket 1 is further provided with a stabilizing assembly 5, the stabilizing assembly 5 includes a stabilizing wheel 51 and a mounting base 52, and the mounting base 52 includes an adjusting plate 521 and a connecting shaft 522; the adjustment plate 521 is provided with a kidney-shaped hole penetrating in the axial direction of the pulley 31, and a locking screw is provided in the kidney-shaped hole. The locking screw passes through the kidney-shaped hole and is connected to the mounting bracket 1 in a threaded manner, so that the adjustment plate 521 is fixed. The connecting shaft 522 is welded at one end to the regulating plate 521 and at the other end extends in a direction parallel to the axis of the pulley 31 to a position away from the mounting bracket 1. The stabilizing wheel 51 is coaxially disposed at an end of the connecting shaft 522 remote from the adjustment lever 42, and is rotatable about its own axis. The stabilizing wheel 51 is located inside the belt 35, and the stabilizing wheel 51 is located on the same horizontal plane as the axis of the pulley 31. The stabilizing wheel 51 can reduce the occurrence of vertical shaking caused by centripetal force in the rotation process of the belt 35, so that the stability of the limiting assembly 3 in the use process is further improved.

Referring to fig. 1 and 3, the mounting bracket 1 is further provided with a tensioning adjustment mechanism 6, the tensioning adjustment mechanism 6 includes an adjustment wheel 62 and an adjustment assembly 61, the adjustment assembly 61 is mounted on the mounting bracket 1, and the adjustment wheel 62 is mounted on the adjustment assembly 61. The regulating wheel 62 is positioned on the inner layer of the belt 35 and is attached to the inner side wall of the belt 35. The adjusting assembly 61 can drive the adjusting wheel 62 to move along the conveying direction of the conveying assembly 2, so that the tensioning degree of the belt 35 is adjusted, and the belt 35 is more stable in the rotating process.

Referring to fig. 1 and 3, the adjustment assembly 61 includes a support base 611, a slide base 612, and a rotation shaft 613, the support base 611 is welded to the mounting bracket 1, and the slide base 612 is slidably coupled over the support base 611 in the conveying direction. The rotation shaft 613 is disposed in a direction parallel to the axis of the pulley 31, and both ends of the rotation shaft 613 are welded to the slide seat 612. The regulating wheel 62 is coaxially provided on the rotation shaft 613, and the regulating wheel 62 is rotatable about its own axis. The sliding seat 612 slides to drive the rotating shaft 613 to move, and then drives the adjusting wheel 62 to move, so as to adjust the tensioning degree of the belt 35.

Referring to fig. 1 and 3, the adjusting assembly 61 further includes an adjusting screw 614, an adjusting block (not shown) is welded to a side of the sliding seat 612 adjacent to the supporting seat 611, the adjusting screw 614 is disposed along a sliding direction of the sliding seat 612, and one end of the adjusting screw 614 passes through the adjusting block and is rotatably connected to the supporting seat 611. The adjusting block is provided with a threaded hole corresponding to the position of the adjusting screw 614, and the adjusting screw 614 is in threaded fit with the threaded hole. Rotating the adjusting screw 614 can drive the adjusting block to move and further drive the sliding seat 612 to move, so that the position of the sliding seat 612 can be conveniently adjusted by a worker. Meanwhile, due to the self-locking property of the threads, the sliding seat 612 is not easy to move after the position adjustment is completed, so that the tensioning degree of the belt 35 can be stably in a certain state, and the running stability of the limiting assembly 3 is improved.

Referring to fig. 1 and 4, the pressing mechanism 7 includes a pressing piece 71 and a lifting assembly 72, the lifting assembly 72 is mounted on the mounting bracket 1, and the lifting assembly 72 is located inside the belt 35. The pressing piece 71 is mounted on the lifting assembly 72, and the lifting assembly 72 can drive the pressing piece 71 to lift, so that the pressing piece 71 can press the non-woven fabric plate on the synchronous belt 22 to the object placing table through a gap between the two synchronous belts 22.

Referring to fig. 1 and 4, the pressing piece 71 includes a connection plate 712 and two pressing plates 711, the two pressing plates 711 being provided on both sides of the belt 35 in a direction parallel to the axis of the pulley 31, respectively. The connection plate 712 is located between the two pressing plates 711, and the connection plate 712 is welded simultaneously with the two pressing plates 711, forming a U-shape with the opening of the pressing piece 71 facing the conveying device. During the up-and-down movement of the pressing piece 71, the belt 35 moves in the gap between the two pressing pieces 711.

Referring to fig. 1 and 4, the elevating assembly 72 includes a rotation member 721 and a connection frame 722, the rotation member 721 is rotatably connected to the mounting bracket 1, and the rotation axis of the rotation member 721 is parallel to the rotation axis of the pulley 31. The connection frame 722 is rotatably connected to the rotation member 721, and the rotation axis between the connection frame 722 and the rotation member 721 is located at a position on the rotation member 721 away from the rotation axis thereof. The pressing piece 71 is fixedly connected to one side of the connecting frame 722, which is close to the synchronous belt 22, through a screw, when the rotating piece 721 rotates, the connecting frame 722 can be driven to rotate around the rotation axis of the rotating piece 721, so that the connecting frame 722 is driven to lift, and the pressing piece 71 always keeps the state that the opening faces the conveying device under the action of gravity, so that the non-woven fabric plate is pressed.

The implementation principle of the conveying and stacking device on the non-woven fabric provided by the embodiment of the utility model is as follows: during operation of the palletizer apparatus, nonwoven fabric panels are arranged in the conveying direction on the timing belt 22. The rotation of the belt wheel 31 drives the synchronous belt 22 to rotate, and further drives the non-woven fabric plate to move. In the moving process of the non-woven fabric plate, the driving roller 33 drives the belt 35 to rotate, and then drives the baffle 32 connected to the belt 35 to move. The belt speed of the belt 35 is greater than that of the timing belt 22, and therefore, the baffle 32 is attached to the side surface of the nonwoven fabric panel during rotation of the belt 35, and the occurrence of misalignment of the multiple layers of cloth in the nonwoven fabric panel can be reduced. In addition, the nonwoven fabric panels are moved forward by the pushing force of the baffle 32, and bonded to the nonwoven fabric panels located in front, thereby realizing the grouping of the nonwoven fabric panels.

The above embodiments are not intended to limit the scope of the present utility model, so: all equivalent changes in structure, shape and principle of the utility model should be covered in the scope of protection of the utility model.

Claims (8)

1. The utility model provides a carry stacking device on non-woven fabrics, includes installing support (1), its characterized in that: still including conveying subassembly (2) and spacing subassembly (3), conveying subassembly (2) are used for driving the non-woven fabrics board and remove, spacing subassembly (3) are including belt (35), baffle (32) and band pulley (31), band pulley (31) rotate and connect on installing support (1), belt (35) are around establishing on individual band pulley (31), form annular structure, baffle (32) are connected on the lateral wall of belt (35), belt (35) can drive baffle (32) and remove along the direction of delivery, baffle (32) remove in-process can laminate with non-woven fabrics board side.

2. A nonwoven fabric feeding and stacking device according to claim 1, wherein: the baffle plates (32) are arranged in a plurality along the circumferential direction of the belt (35).

3. A nonwoven fabric feeding and stacking device according to claim 1 or 2, characterized in that: be provided with on installing support (1) stable subassembly (5), stable subassembly (5) are including stabilizing wheel (51), stabilizing wheel (51) rotate and connect on installing support (1), the axis of rotation of stabilizing wheel (51) is on a parallel with the axis of rotation of band pulley (31), stabilizing wheel (51) are located inside the annular structure that belt (35) formed, and stabilizing wheel lateral wall is tangent with belt (35) inside wall.

4. A nonwoven fabric feeding and stacking device according to claim 3, wherein: be provided with regulating part (4) between band pulley (31) and installing support (1), regulating part (4) are including adjusting pole (42), adjust pole (42) rotation and connect on installing support (1), the axis of rotation of adjusting pole (42) is on a parallel with the axis of rotation of band pulley (31), band pulley (31) rotation is connected on regulating part (4), the axis of rotation of band pulley (31) is located the position of keeping away from the axis of rotation of adjusting pole (42) and installing support (1) on adjusting pole (42).

5. The nonwoven fabric feeding and stacking device according to claim 4, wherein: still be provided with tensioning adjustment mechanism (6) on installing support (1), tensioning adjustment mechanism (6) are including regulating wheel (62), regulating wheel (62) rotate and connect on installing support (1), the axis of rotation of regulating wheel (62) is parallel with the axis of rotation of band pulley (31), regulating wheel (62) can follow the direction of perpendicular to self axis of rotation and slide, the lateral wall and the inside wall butt of belt (35) of regulating wheel (62).

6. The nonwoven fabric feeding and stacking device according to claim 5, wherein: the tensioning adjustment mechanism (6) further comprises an adjustment assembly (61), the adjustment assembly (61) comprises a sliding seat (612) and an adjustment screw (614), the sliding seat (612) is slidably connected to the mounting bracket (1), the adjustment wheel (62) is rotatably connected to the sliding seat (612), the adjustment screw (614) is arranged along the sliding direction of the sliding seat (612), the adjustment screw (614) is rotatably connected to the mounting bracket (1), and the adjustment screw (614) is in threaded connection with the sliding seat (612).

7. The nonwoven fabric feeding and stacking device according to claim 6, wherein: the limiting assembly (3) further comprises a driving roller (33), the driving roller (33) is rotatably arranged on the mounting bracket (1), the driving roller (33) is located above the belt wheel, and the belt (35) is wound on the belt wheel (31), the adjusting wheel (62) and the driving roller (33) at the same time.

8. The nonwoven fabric feeding and stacking device according to claim 7, wherein: two limiting plates (34) are arranged on the mounting bracket (1), the two limiting plates (34) are arranged on two sides of the non-woven fabric plate along the direction perpendicular to the conveying direction, and in the moving process of the non-woven fabric plate, two side faces perpendicular to the axis of the belt wheel (31) are attached to two side faces, close to each other, of the limiting plates (34).