CN214455523U - Coiling mechanism is cut in compounding of antibiotic nanometer membrane of HTR mould proof - Google Patents

Abstract

The utility model relates to a coiling mechanism is cut in compound of antibiotic nanometer membrane of HTR mould proof relates to the technical field of membrane production facility, include the transport composite construction, the cutting mechanism and the winding mechanism that connect gradually according to the membrane, still including rectifying mechanism, the membrane passes through earlier rectifying mechanism reentrants among the composite construction, rectifying mechanism is including setting up in the frame on ground, installing frame and axis angle are changeable rectify the roller, install the frame and with it connects and is used for driving to rectify the roller and change axis angle's adjusting part, install the frame and with the detection piece that the adjusting part electricity is connected, the detection piece is used for detecting the edge of membrane, and the membrane is followed rectify the roller and walk around and carry again on the composite construction. The application has the effects of high precision, less material waste and low cost during compounding.

Description

Coiling mechanism is cut in compounding of antibiotic nanometer membrane of HTR mould proof

Technical Field

The application relates to the technical field of film production equipment, in particular to a composite slitting and winding device for an HTR mildew-proof antibacterial nano film.

Background

The HTR mildew-proof antibacterial nano-film is a compact film material with special functions, has excellent air tightness, high-efficiency heat conduction, high permeability of water molecules, far-higher enthalpy efficiency than paper and remarkable energy-saving effect; and can be directly washed by water and can be normally used after being dried by air.

In the process of producing the HTR mildew-proof antibacterial nano-film, the film material and other material layers are heated and compounded by a film laminating machine, and then the film material and other material layers are rolled to complete the manufacturing process.

In the prior art, before the film material is conveyed to a laminating machine to be compounded with other material layers, the position of the film material may deviate, and in the heating and compounding process of the film and the layer to be compounded, the edge of the compounded product is irregular due to the deviation of the dried film position, so that the edge needs to be cut off, and the waste of raw materials is caused.

SUMMERY OF THE UTILITY MODEL

In order to solve the problem of uneven edges of composite products, the application provides a composite slitting and winding device of an HTR mildew-proof antibacterial nano film.

The application provides a coiling mechanism is cut to compound of antibiotic nanometer membrane of HTR mould proof adopts following technical scheme:

the utility model provides a coiling mechanism is cut in compound of antibiotic nanometer membrane of HTR mould proof, includes the transport composite structure, the cutting mechanism and the winding mechanism that connect gradually according to the membrane, still including the mechanism of rectifying, the membrane passes through earlier the mechanism of rectifying reenters into in the composite structure, the mechanism of rectifying is including setting up in the frame on ground, installing the roller of rectifying that frame and axis angle are changeable, install the frame and with the roller of rectifying is connected and is used for driving the roller of rectifying changes the adjusting part of axis angle, install the frame and with the detection piece that the adjusting part electricity is connected, the detection piece is used for detecting the edge of membrane, and the membrane is followed the roller of rectifying walks around and carries again on the composite structure.

Through adopting above-mentioned technical scheme, when the detection piece detects the edge of membrane and squints, the detection piece sends the signal of telecommunication for adjusting part, adjusting part drives the roller of rectifying and changes the axis angle, the membrane squints under the drive of the roller of rectifying, when the edge that detects the membrane is in the correct position until the detection piece, adjusting part drives the roller of rectifying and gets back to the normal position, accomplish the process of rectifying, the accuracy improves when making compound, the probability that the product edge appears jaggedly has been reduced, the waste of material has been reduced, the cost is reduced.

Optionally, the roller of rectifying rotates and installs on a support, two slide rails are installed to the frame interval, slide respectively at the both ends of support on the slide rail, just the support with the slide rail can rotate relatively, adjusting part with leg joint, just adjusting part is used for changing support length direction's angle.

Through adopting above-mentioned technical scheme, when needs adjust, adjusting part drives the support motion for the both ends of support are at two slide rail motion, and the angle changes under the guide of slide rail at the support, makes to rectify the roller and change with the support together, thereby reaches the effect of rectifying the roller to the membrane. Through the guide of slide rail for the change of support angle is comparatively accurate and stable.

Optionally, the two ends of the bracket are crossed in the sliding directions of the two sliding rails to form a crossed surface, and the crossed surface is overlapped with a horizontal plane or is a right angle or an acute angle.

By adopting the technical scheme, the cross surface can be adjusted at a plurality of angles in each angle, and the angles in the length direction of the support can be adjusted, so that various possibilities exist during setting, and the thinking in design is expanded.

Optionally, the slide rail slides along its length direction and is provided with the slider, support demountable installation has the bearing, the slider with the bearing rotates to be connected.

Through adopting above-mentioned technical scheme, the normal running fit of support and slider has been realized in the setting of bearing, and slider and bearing detachable, change when being convenient for damage, and it is convenient to install.

Optionally, the slide rail is provided with a slide bar, and the slide block is slidably arranged on the slide bar in a penetrating manner.

Through adopting above-mentioned technical scheme, the setting of slide bar has further restricted the glide path of slider for the slider motion is more accurate, and reducible friction between slider and the slide rail, reduces wearing and tearing.

Optionally, the sliding block is detachably connected with a connecting rod, and the connecting rod is inserted into the inner ring of the bearing in an interference manner.

Through adopting above-mentioned technical scheme, the connecting rod is separable with the slider for need not to change when the slider needs to be changed wholly, and can maintain alone when maintaining, save the cost.

Optionally, the adjusting assembly includes a driving member rotatably mounted on the frame and electrically connected to the detecting member, and a connecting block rotatably mounted on the bracket and connected to the driving member.

Through adopting above-mentioned technical scheme, the driving piece begins to drive the connecting block motion after receiving the signal of telecommunication that the detection piece needs the adjustment, and the connecting block promotes the support motion, realizes the process of adjustment.

Optionally, the deviation rectification roller is sleeved with a rubber layer.

Through adopting above-mentioned technical scheme, the setting of rubber sleeve has improved the frictional force between rectification roller and the membrane, is convenient for realize rectifying the guide of roller to the membrane.

Optionally, the splitting mechanism comprises a splitting frame arranged between the compound mechanism and the winding mechanism, and a splitting knife arranged on the splitting frame.

By adopting the technical scheme, the compounded film can be directly cut into a plurality of strips, and the subsequent unwinding and cutting are not needed, so that the processes are reduced, the time is shortened, and the efficiency is greatly improved.

In summary, the present application includes at least one of the following beneficial technical effects:

1. the setting of rectifying roller makes the membrane position of carrying on the combined mechanism comparatively accurate, can wait that the material of recombination is accurate compound.

2. The arrangement of the slitting knife realizes immediate slitting of the compounded film, subsequent slitting is not needed, and the efficiency of film treatment is greatly improved.

Drawings

FIG. 1 is a schematic plan view of example 1.

Fig. 2 is a schematic perspective view of the deviation correcting mechanism in embodiment 1.

Fig. 3 is an enlarged schematic view of a portion a in fig. 2.

Fig. 4 is a schematic view of the three-dimensional structure of embodiment 2.

Fig. 5 is a schematic view of the three-dimensional structure of embodiment 3.

Reference numerals: 3. a slitting mechanism; 31. a cutting frame; 32. a first guide roller; 33. a slitting knife; 34. fixing the rod; 4. a deviation rectifying mechanism; 41. a frame; 411. a slide rail; 412. a slide bar; 413. a slider; 414. a connecting rod; 42. a deviation rectifying roller; 421. a support; 422. a bearing; 423. a rubber layer; 431. an electric push rod; 432. connecting blocks; 44. a detection member; 5. a compounding mechanism; 51. a composite frame; 52. a second inflatable roller; 54. a third guide roller; 55. a compression roller; 56. a heating roller; 58. a discharging roller; 59. a reversing roller; 6. a winding mechanism; 61. a winding frame; 62. a third inflatable roller; 64. a fourth guide roller; 71. a first standing frame; 72. a first guide roller; 73. a second standing frame; 74. a second guide roller.

Detailed Description

The present application is described in further detail below with reference to figures 1-5.

The application discloses coiling mechanism is cut in compound of antibiotic nanometer membrane of HTR mould proof.

Example 1

Referring to fig. 1, the composite slitting and winding device comprises a deviation correcting mechanism 4, a composite mechanism 5, a slitting mechanism 3 and a winding mechanism 6, wherein a film is conveyed to the deviation correcting mechanism 4 after being coated, dried and cured, and then conveyed to the composite mechanism 5 after being corrected by the deviation correcting mechanism 4, a material layer to be compounded is placed in the composite mechanism 5, the material layer is compounded with the dried film after being uncoiled, and then conveyed to the slitting mechanism 3 for slitting after being compounded, and then conveyed to the winding mechanism 6 for winding after being slit, so that the compounding, slitting and winding work of the HTR mildew-proof antibacterial nano film is completed.

Referring to fig. 2, the deviation rectifying mechanism 4 includes a frame 41 and a deviation rectifying roller 42, the frame 41 is fixed on the ground, two sliding rails 411 are installed on the upper surface of the frame 41 at intervals along the width direction of the film, two sliding rods 412 are fixed on the sliding rails 411, the length direction of the sliding rods 412 is parallel to the length direction of the sliding rails 411, a sliding block 413 is slidably arranged on the two sliding rods 412, and the sliding block 413 is also slidably matched with the sliding rails 411. In the embodiment, the sliding directions of the two sliders 413 are crossed to form a crossed plane, and the crossed plane is overlapped with the horizontal plane.

Referring to fig. 3, the deviation rectifying roller 42 is rotatably mounted on a support 421, two ends of the support 421 in the length direction are respectively connected to two sliders 413, and a bearing 422 is fixedly embedded in the support 421; a connecting rod 414 in a T shape is fixed on the sliding block 413 through a bolt, the vertical part of the connecting rod 414 is in a cylindrical shape, and the cylindrical part of the connecting rod 414 is in interference insertion fit with the inner ring of the bearing 422, so that the support 421 and the connecting rod 414 can rotate relatively.

Referring to fig. 2, the deviation correcting mechanism 4 further includes an adjusting assembly and a detecting member 44, the adjusting assembly includes a driving member and a connecting block 432, the driving member is an electric push rod 431, one end of the electric push rod 431, which is far away from the push rod, is rotatably mounted on the frame 41, and a rotation plane of the electric push rod 431 is parallel to the intersecting plane; the connecting block 432 is rotatably mounted on the push rod of the electric push rod 431, and the connecting block 432 is fixedly connected with the support 421.

Referring to fig. 3, the detecting member 44 is a distance sensor and is electrically connected to the electric push rod 431, and the two distance sensors are fixedly mounted on the frame 41 and located at both sides of one edge of the film at the standard position, for detecting whether the edge of the film is between the two distance sensors. When the detection piece 44 detects that the film is deviated, the detection piece 44 sends an electric signal to the electric push rod 431, the push rod of the electric push rod 431 stretches, the connecting block 432 and the push rod move synchronously, the support 421 and the connecting block 432 move synchronously, the purpose of changing the bottom of the film by driving the rectification roller 42 is realized, the angle of the rectification roller 42 is changed to drive the film to move laterally until the detection piece 44 detects that the film is at the standard position, and the electric push rod 431 returns to the original position to finish the rectification process.

Referring to fig. 2, in order to improve the film-driving effect of the rectification roller 42, a rubber layer 423 is fixedly sleeved outside the rectification roller 42, thereby improving the frictional force between the rectification roller 42 and the film.

Referring to fig. 1, the compound mechanism 5 includes a compound frame 51, a second inflatable roller 52, a second motor (not shown), a compound motor (not shown), a third guide roller 54, a press roller 55, a heating roller 56, and a heating motor (not shown), wherein the compound frame 51 is fixed on the ground, and the compound frame 51 is fixedly connected to the frame 41. The second inflatable roller 52 is rotatably arranged on the composite frame 51, and the material roll to be composited is sleeved on the second inflatable roller 52; the compound motor is fixed on the compound frame 51, and the compound motor and the second inflatable roller 52 are in meshing transmission through gears. The heating roller 56 is rotatably arranged on the composite frame 51, the heating motor is fixed on the composite frame 51, and the heating motor is also in meshing transmission connection with the heating roller 56 through a gear; the pressure roller 55 is rotatably mounted on the compounding frame 51 directly above the heating roller 56.

Referring to fig. 1, a plurality of third guide rollers 54 are rotatably installed on the compound, and the height of at least one third guide roller 54 is higher than that of the deviation rectification roller 42, and the height of at least one third guide roller 54 is lower than that of the deviation rectification roller 42; the second motor is fixedly mounted on the composite frame 51, and an output shaft of the second motor is in chain transmission connection with one of the third guide rollers 54, so that an auxiliary traction effect is achieved. . The film is conveyed from the rectification roller 42 to the third guide roller 54 which is lower than the rectification roller 42, bypasses the third guide roller 54, bypasses the other third guide rollers 54 positioned below the highest end of the heating roller 56, and then is conveyed onto the heating roller 56; at the same time, the material layer to be laminated is unwound around the third guide roller 54 having a height higher than that of the heating roller 56 and moved above the film on the heating roller 56, and the film and the material layer to be laminated are laminated together under the nip action of the pressing roller 55 and the heating roller 56 and under the effect of the heating roller 56.

Referring to fig. 1, a discharging roller 58 is rotatably mounted on one side of the composite frame 51 far away from the frame 41, a reversing roller 59 is rotatably mounted at the lower end of the composite frame 51 right below the discharging roller 58, and the composite finished product firstly bypasses the discharging roller 58 and then bypasses the reversing roller 59.

Referring to fig. 1, a second standing frame 73 is further provided between the compound frame 51 and the winding mechanism 6, a worker can stand on the second standing frame 73, the worker can observe the compound condition, a second guide roller 74 is rotatably mounted right below the second standing frame 73, and the product bypassing the reversing roller 59 moves onto the second guide roller 74 to pass below the second standing frame 73.

Referring to fig. 1, the slitting mechanism 3 includes a slitting frame 31, three first guide rollers 32, and a slitting knife 33, the slitting frame 31 is placed on the ground and located between the second standing frame 73 and the winding mechanism 6, the number of the first guide rollers 32 is three, the three first guide rollers 32 are all rotatably mounted on the slitting frame 31, and the film sequentially bypasses the three first guide rollers 32 from the second guide roller 74 and then enters the winding mechanism 6. The cutting frame 31 is fixed with a fixing rod 34, the cutting knives 33 are provided with a plurality of circular sheet-shaped blades, the cutting knives 33 are fixed on the fixing rod 34 through bolts, and the cutting edges of the cutting knives 33 can cut the passing film to realize the cutting purpose. And the position of the slitting knife 33 on the fixing rod 34 can be adjusted as required.

Referring to fig. 1, the winding mechanism 6 includes a plurality of winding frames 61, third inflatable rollers 62, a winding motor (not shown in the figure) and fourth guide rollers 64, the plurality of third inflatable rollers 62 are rotatably mounted on the winding frames 61, the winding motor is fixedly mounted on the winding frames 61, and the winding motor is in transmission connection with the third inflatable rollers 62 through gears; the number of the fourth guide rollers 64 is plural, and the rollers are rotatably mounted on the winding frame 61. The third inflatable roller 62 is sleeved with winding cores, the winding motor drives the third inflatable roller 62 to rotate, and the product moves to the winding frame 61 from the first guide roller 32 close to the winding frame 61 and bypasses the plurality of fourth guide rollers 64 to be finally wound on each winding core.

The implementation principle of the compound slitting and winding device of the HTR mildew-proof antibacterial nano-film in the embodiment of the application is as follows:

during production, the dried and cured film is subjected to deviation correction and unfolding through the matching of the detection piece 44, the electric push rod 431 and the deviation correction roller 42, the film subjected to deviation correction enters the compound frame 51, the film on the heating roller 56 and a material to be compounded are compounded together under the action of the heating and pressing roller 55 to form a product, the formed product passes through the lower part of the second standing frame 73 and then is conveyed to the slitting frame 31, the slitting knife 33 performs slitting, and finally the slit film is wound on the winding cores of the third air expansion rollers 62, so that the production is completed.

Example 2

Referring to fig. 4, the difference between the compound slitting and winding device of the HTR mildew-proof antibacterial nano-film of the present embodiment and embodiment 1 is: the sliding directions of the two sliding blocks 413 are crossed to form a crossed surface, and the crossed surface is perpendicular to the horizontal plane, so that when the deviation is corrected, the heights of the two ends of the support 421 are changed, and meanwhile, the rotating planes of the electric push rod 431 and the connecting block 432 are still parallel to the crossed surface.

Example 3

Referring to fig. 5, the difference between the compound slitting and winding device of the HTR mildew-proof antibacterial nano-film of the present embodiment and embodiment 1 is: the sliding directions of the two sliding blocks 413 are crossed to form a crossed surface, and the crossed surface and the horizontal surface form an acute angle, so that when the deviation correction is performed, the height and the horizontal position of the two ends of the support 421 are changed, and meanwhile, the rotating planes of the electric push rod 431 and the connecting block 432 are still parallel to the crossed surface.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (9)

1. A composite slitting and winding device of an HTR mildew-proof antibacterial nano-film comprises a composite mechanism (5), a slitting mechanism (3) and a winding mechanism (6) which are sequentially connected according to the conveying of the film, and further comprises a deviation-correcting mechanism (4), wherein the film firstly passes through the deviation-correcting mechanism (4) and then enters the composite mechanism (5), the deviation rectifying mechanism (4) comprises a rack (41) arranged on the ground, a deviation rectifying roller (42) which is arranged on the rack (41) and has a changeable axis angle, an adjusting component which is arranged on the rack (41) and is connected with the deviation rectifying roller (42) and is used for driving the deviation rectifying roller (42) to change the axis angle, and a detecting piece (44) which is arranged on the rack (41) and is electrically connected with the adjusting component, the detection member (44) is used for detecting the edge of the film, and the film is conveyed to the compound mechanism (5) after bypassing the rectification roller (42).

2. The compound slitting and winding device for the HTR mildewproof antibacterial nano-films according to claim 1, which is characterized in that: the roller (42) of rectifying rotates and installs on a support (421), two slide rails (411) are installed at frame (41) interval, slide respectively at the both ends of support (421) on slide rail (411), just support (421) with slide rail (411) can rotate relatively, adjusting part with support (421) are connected, just adjusting part is used for changing support (421) length direction's angle.

3. The compound slitting and winding device for the HTR mildewproof antibacterial nano-films according to claim 2, which is characterized in that: the two ends of the support (421) are crossed in the sliding directions of the two sliding rails (411) to form a crossed surface, and the crossed surface is superposed with a horizontal plane or is at a right angle or an acute angle.

4. The compound slitting and winding device for the HTR mildewproof antibacterial nano-films according to claim 2, which is characterized in that: slide rail (411) slide along its length direction and are provided with slider (413), support (421) demountable installation has bearing (422), slider (413) with bearing (422) rotate to be connected.

5. The compound slitting and winding device for the HTR mildewproof antibacterial nano-films according to claim 4, which is characterized in that: the sliding rail (411) is provided with a sliding rod (412), and the sliding block (413) penetrates through the sliding rod (412) in a sliding mode.

6. The compound slitting and winding device for the HTR mildewproof antibacterial nano-films according to claim 5, which is characterized in that: the sliding block (413) is detachably connected with a connecting rod (414), and the connecting rod (414) is inserted into an inner ring of the bearing (422) in an interference manner.

7. The compound slitting and winding device for the HTR mildewproof antibacterial nano-films according to claim 2, which is characterized in that: the adjusting assembly comprises a driving piece which is rotatably installed on the frame (41) and is electrically connected with the detecting piece (44), and a connecting block (432) which is rotatably installed on the support (421) and is connected with the driving piece.

8. The compound slitting and winding device for the HTR mildewproof antibacterial nano-films according to claim 1, which is characterized in that: and a rubber layer (423) is sleeved outside the deviation rectifying roller (42).

9. The compound slitting and winding device for the HTR mildewproof antibacterial nano-films according to claim 1, which is characterized in that: the splitting mechanism (3) comprises a splitting frame (31) arranged between the compound mechanism (5) and the winding mechanism (6) and a splitting cutter (33) arranged on the splitting frame (31).

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