CN110432542B - Multi-element material combined process system - Google Patents

Abstract

The invention relates to the field of tobacco production equipment and discloses a multi-element material combination process system which comprises a material channel, a rotatable material transmission gear train and a material transmission device used for transmitting materials into the material transmission gear train, wherein the material transmission gear train comprises a stirring part used for stirring the materials to move in the material channel, and the material transmission device comprises one or more combinations of a transmission device I and a transmission device II. The invention has the following advantages and effects: the material transfer device is used for transferring materials, the material sections firstly pass through the gap eliminating mechanism I or the gap eliminating mechanism II to form continuous material flow, then pass through the accelerating wheel I or the accelerating wheel II to accelerate, gaps are formed among materials in the material flow, a stirring part in the material transfer gear train sequentially enters the gaps among the materials to stir the materials to move, and the materials are sequentially collected in the material transfer wheel to form a multi-component composite material, so that the combination efficiency is greatly improved.

Description

Multi-element material combined process system

Technical Field

The invention relates to the field of tobacco production equipment, in particular to a multi-material combined process system.

Technical Field

Tobacco production, processing and manufacturing have been a history of hundreds of years, and the awareness of tobacco and its products has gradually increased with the development of science and technology and the enhancement of human environmental and health awareness. Since the advent of the first cigarette filter using cotton as a filter material in 1930, the filter became an important part of the design of cigarettes. However, knowing the 50 s of the 20 th century, filter cigarettes began to receive consumer acceptance as acetate fibers were developed. At the beginning of the 60 s, the tobacco industry is greatly impacted due to the increasing rise of the anti-smoke exercise, and the development of low-tar safe cigarettes is one of the outlets of the tobacco industry. The filter tip is used as a bridge between a smoker and main stream smoke, not only can filter out part of harmful components in the smoke, but also can effectively intercept total particulate matters in the main stream smoke, reduce tar content and reduce harm of the smoke to human health and environment by connecting the filter tip on cigarettes. In the processing process of the filter stick, multiple sections of materials are required to be combined according to the process and design requirements, so that a multi-material combination process system is necessary to be provided.

Disclosure of Invention

The invention aims to provide a multi-element material combination process system which has the effect of combining multi-element materials.

The technical aim of the invention is realized by the following technical scheme: the multi-element material combination process system comprises a material channel, a rotatable material transmission gear train and a material transmission device used for transmitting materials into the material transmission gear train, wherein the material transmission gear train comprises a stirring part used for stirring the materials to move in the material channel, and the material transmission device comprises one or a combination of a plurality of first transmission devices and a plurality of second transmission devices; the first conveying device comprises a first gap eliminating mechanism for eliminating gaps among the material sections to form a continuous material flow and a first accelerating wheel for forming equal gaps among the materials in the material flow; the second conveying device comprises at least one material section conveying wheel which can rotate and is used for conveying material sections, a second gap eliminating mechanism which is used for eliminating gaps among the material sections and then forming continuous material flows, and a second accelerating wheel which is used for enabling the materials in the material flows to form equal gaps.

Through adopting above-mentioned technical scheme, when the complex material combination process system works, the material is the stick, cuts into the multistage back and forms the material section, and the material section gets into transmission device one, and the clearance between each material section is eliminated to the clearance eliminating mechanism one in the transmission device one, forms the material flow that links to each other end to end in proper order, and each material in the material flow contacts accelerating wheel one in proper order, and accelerating wheel one makes and forms the clearance between each material, and stirring portion in the material transmission train gets into the clearance between two adjacent materials in proper order, stirs the material and moves along the material passageway.

The material section in the second conveying device enters into the material section conveying wheels, the number of the material section conveying wheels is set according to the process requirements, the material section conveyed by the material section conveying wheels is contacted with the gap eliminating mechanism II, the gap between the material sections is eliminated by the gap eliminating mechanism II, material flows connected end to end are formed, each material in the material flows sequentially contacts with the accelerating wheel II, the accelerating wheel II enables each material to form a gap, the stirring part of the material conveying wheel train enters into the gap between two adjacent materials, and the stirring material moves along the material channel.

The material that transfer device I passed out, the material that transfer device II passed out are passed by material transfer train in proper order, and the material that transfer device I passed and transfer device II passed can collect on material transfer train in the transfer in-process, combines, and the rethread material passageway discharges, gets into next step production process, has the effect of combining the multiple materials.

The invention is further provided with: the material transfer gear train comprises a first material transfer wheel, a second material transfer wheel, a third material transfer wheel and a fourth material transfer wheel, wherein the second material transfer device transfers materials to the first material transfer wheel, the first material transfer wheel transfers the materials to the second material transfer wheel, and the second material transfer wheel transfers the materials to the third material transfer wheel; the second material conveying device conveys materials to the four material conveying wheels, and the fourth material conveying wheel conveys the materials to the three material conveying wheels.

The invention is further provided with: the material transfer wheel one side wall, the material transfer wheel two side walls, the material transfer wheel three side walls and the material transfer wheel four side walls are all provided with the stirring part.

The invention is further provided with: the first gap eliminating mechanism comprises a rotatable spiral roller I; the second gap eliminating mechanism comprises a second rotatable spiral roller.

By adopting the technical scheme, the materials in front of the first spiral roller and the second spiral roller are unpowered, the first spiral roller drives each material section to move forwards, material flow is formed after clearance elimination, and the forward power of the material flow is provided while the clearance elimination is achieved.

The invention is further provided with: the two conveying devices comprise at least two material section conveying wheels.

The invention is further provided with: the material transfer device comprises a first transfer device and at least two second transfer devices.

The invention is further provided with: the device also comprises a material supply device, wherein the material supply device is provided with a plurality of conveying devices which are corresponding to the first conveying device and the second conveying device.

The invention is further provided with: the material supply device comprises a frame, wherein the material supply device comprises a discharging wheel, a synchronous toothed belt and a driving part, the discharging wheel is rotatably arranged on the frame, the synchronous toothed belt is positioned below the discharging wheel, the driving part is used for driving the synchronous toothed belt to move, a material groove I is formed in the discharging wheel, and a poking tooth is arranged on the synchronous toothed belt; the rack is provided with a blocking surface and a poking wheel rotatably connected to the rack, and the poking wheel is used for poking a plurality of sections of materials on the synchronous toothed belt to the blocking surface.

Through adopting above-mentioned technical scheme, the material embedding is in the material recess on the discharge wheel, and the discharge wheel rotates in the frame, and drive unit drive synchronous toothed belt motion, the tooth of dialling on synchronous toothed belt is dialled the material from the material recess of discharge wheel in the back, and the time that different materials break away from the discharge wheel is different, is on synchronous toothed belt surface non-collinear. The shifting wheel rotates to shift the material to the blocking surface, so that the material is positioned on the same straight line, the circular motion of the material can be converted into the straight line motion, and the material is supplied for the first and second transfer devices.

The invention is further provided with: the axis of the discharging wheel is parallel to the conveying direction of the synchronous toothed belt, the width of the poking tooth is larger than that of the first material groove, and the poking tooth is located outside the first material groove.

Through adopting above-mentioned technical scheme, dial the tooth when taking out the material in the material recess one, in not entering into the material recess one, so synchronous toothed belt's direction of delivery can be parallel with the axis of discharge wheel, the transmission of equipment and material of being convenient for, and dial the tooth and can not contact with the material recess one inner wall and cause the damage, the trouble is less during the use.

The invention is further provided with: the material supply device further comprises a feeding wheel rotatably arranged on the frame and a material storage hopper arranged above the feeding wheel, wherein a material groove II is formed in the feeding wheel, and materials on the feeding wheel can be transferred to the discharging wheel.

Through adopting above-mentioned technical scheme, feed wheel upper end part is located the material and stores the fill, and during the feed wheel rotation, the material in the material is stored the fill and is embedded in material recess two and by negative pressure absorption, rotates along with the feed wheel and breaks away from the material and store the fill, is transmitted to the discharge wheel by the feed wheel again.

The beneficial effects of the invention are as follows: the material transfer device is used for transferring materials, the material sections firstly pass through the gap eliminating mechanism I or the gap eliminating mechanism II to form continuous material flow, then pass through the accelerating wheel I or the accelerating wheel II to accelerate, gaps are formed among materials in the material flow, a stirring part in the material transfer gear train sequentially enters the gaps among the materials to stir the materials to move, and the materials are sequentially collected in the material transfer wheel to form a multi-component composite material, so that the combination efficiency is greatly improved.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings required for the description of the embodiments will be briefly described below, and it is apparent that the drawings in the following description are only some embodiments of the present invention, and other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

Fig. 1 is a schematic structural diagram of embodiment 1.

Fig. 2 is a schematic view of the material supply device of embodiment 1.

Fig. 3 is a schematic diagram of the thumbwheel structure of embodiment 1.

Fig. 4 is a schematic structural view of a first transfer device of embodiment 1.

Fig. 5 is a schematic structural diagram of a second transmission device of embodiment 1.

In the figure, 1, a material transmission wheel system; 11. a first material transfer wheel; 12. a second material transfer wheel; 13. a material transfer wheel III; 14. a material transfer wheel IV; 15. a toggle part; 2. a material transfer device; 21. a first transfer device; 211. an anti-backlash mechanism I; 212. an accelerating wheel I; 22. a second transmission device; 221. a material section transfer wheel; 222. a second gap eliminating mechanism; 223. an accelerating wheel II; 3. a material supply device; 31. a feed wheel; 311. a second material groove; 312. an annular groove; 32. a discharging wheel; 321. a first material groove; 33. a synchronous toothed belt; 331. tooth pulling; 34. a thumb wheel; 341. a groove is arranged; 35. a blocking surface; 36. a discharge channel; 37. a material storage hopper; 38. a slitting device; 381. a cutter shaft; 382. a cutter; 4. and (5) material.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments. It will be apparent that the described embodiments are only some, but not all, embodiments of the invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to fall within the scope of the invention.

Example 1: the multi-element material combination process system is shown in fig. 1, and comprises a frame, a material transmission gear train 1 and a material transmission device 2 for transmitting materials 4 into the material transmission gear train 1, wherein material channels are formed in the frame and the material transmission gear train 1 for transmitting the materials 4. The material transfer gear train 1 comprises a stirring part 15, and the stirring part 15 is used for stirring the material 4 to move in the material channel.

As shown in fig. 1 and 2, the material transfer device 2 includes a first transfer device 21 and a second transfer device 22, one transfer device 21 is provided, and two transfer devices 22 are provided. The material supply device 3 is provided with three materials which respectively correspond to the first transmission device 21 and the second transmission device 22. The material supply device 3 comprises a feeding wheel 31 rotatably arranged on the frame, and a material 4 storage hopper 37 arranged above the feeding wheel 31, wherein the material 4 storage hopper 37 is internally filled with materials 4, an opening is arranged at the lower end of the material 4 storage hopper 37, and the upper end of the feeding wheel 31 is arranged in the opening. A plurality of second material grooves 311 are formed in the circumferential surface of the feeding wheel 31, the lengths of the second material grooves 311 are axially arranged along the feeding wheel 31, and the second material grooves 311 are uniformly distributed along the circumferential direction of the feeding wheel 31. The frame is provided with a negative pressure system which can be a negative pressure suction fan. The feeding wheel 31 is internally provided with a first inner cavity and a plurality of first air holes which are connected with a negative pressure system, and the first inner cavity is communicated with a second material groove 311 at each position through the first air holes. A first driving motor for driving the feeding wheel 31 to rotate is fixed on the frame, the first driving motor drives the feeding wheel 31 to rotate, the material 4 is embedded in the second material groove 311, the negative pressure system sucks air to enable the first inner cavity to form negative pressure, and the material 4 is adsorbed in the second material groove 311, rotates along with the feeding wheel 31 and is separated from the material 4 storage hopper 37.

As shown in fig. 2, a slitting device 38 is disposed on the frame, the slitting device 38 includes a cutter shaft 381 rotatably connected to the frame, a plurality of cutters 382 fixed on the cutter shaft 381, and a cutting motor for driving the cutter 382 to rotate, a plurality of annular grooves 312 are disposed on the circumferential outer wall of the feeding wheel 31, and the annular grooves 312 are disposed along the circumferential direction of the feeding wheel 31 for embedding the cutters 382. After the whole section of material 4 leaves the material 4 storage hopper 37 along with the feeding wheel 31, the whole section of material 4 is cut into a plurality of sections of material 4 which are closely arranged by the slitting device 38 to form material sections.

As shown in fig. 2, the material supply device 3 further includes a discharging wheel 32 rotatably disposed on the frame, and a second driving motor for driving the discharging wheel 32 to rotate, where the discharging wheel 32 is located below the feeding wheel 31, and the circumferential outer wall of the discharging wheel 32 is abutted against the circumferential outer wall of the feeding wheel 31. A plurality of first material grooves 321 are formed in the circumferential surface of the discharging wheel 32, the lengths of the first material grooves 321 are axially arranged along the discharging wheel 32, the first material grooves 321 are uniformly distributed along the circumferential direction of the discharging wheel 32, and the depth of the second material grooves 311 is greater than that of the first material grooves 321. The discharging wheel 32 is internally provided with a second inner cavity and a plurality of second air holes which are connected with the negative pressure system, and the second inner cavity is communicated with the first material groove 321 at each position through the second air holes. The second driving motor drives the discharge wheel 32 to rotate, the material 4 on the feed wheel 31 enters the first material groove 321 on the discharge wheel 32 from the second material groove 311, the negative pressure system sucks air to form negative pressure in the second inner cavity, and the material 4 is adsorbed in the first material groove 321 of the discharge wheel 32.

As shown in fig. 2, the frame is further provided with two synchronous wheels rotatably connected with the frame, a synchronous toothed belt 33 sleeved on the two synchronous wheels, and a driving component for driving the synchronous toothed belt 33 to move, wherein the synchronous toothed belt 33 is positioned below the discharging wheel 32, and the conveying direction of the synchronous toothed belt 33 is parallel to the axis of the discharging wheel 32. The outer wall of the synchronous toothed belt 33 is provided with a plurality of poking teeth 331, the poking teeth 331 are arranged at equal intervals, the width of each poking tooth 331 is larger than that of the first material groove 321, and the poking teeth 331 are located outside the first material groove 321. The driving part is a driving motor III fixed on the frame, and the output shaft of the driving motor III is connected with the synchronous wheel.

As shown in fig. 3, a dial wheel 34 is arranged on the stand, the dial wheel 34 is positioned above the synchronous toothed belt 33, the dial wheel 34 is rotationally connected with the stand, a driving motor IV is further arranged on the stand, and the driving motor IV is used for driving the dial wheel 34 to rotate. The dial wheel 34 is cylindrical, a dial groove 341 is formed in the outer wall of the dial wheel 34, and the central line of the dial groove 341 is parallel to the central line of the dial wheel 34. The frame is provided with a blocking surface 35, and the shifting wheel 34 is used for shifting the material 4 on the synchronous toothed belt 33 to the blocking surface 35. A discharge channel 36 is arranged on the frame for the material 4 to enter along the blocking surface 35.

As shown in fig. 2 and 3, the first driving motor drives the feeding wheel 31 to rotate, after the material 4 in the material 4 storage hopper 37 is embedded into the material groove two 311 on the feeding wheel 31, the material 4 storage hopper 37 is separated from the feeding wheel 31 by rotation, and after the whole section of material 4 is cut into a plurality of sections by the cutting device 38, a plurality of sections of material 4, namely material sections, are closely arranged. The material section is transferred from the material groove two 311 on the feeding wheel 31 to the material groove one 321 on the discharging wheel 32, the driving part drives the synchronous toothed belt 33 to move, the poking teeth 331 on the synchronous toothed belt 33 poke the material section out of the material groove one 321 of the discharging wheel 32, the poking wheel 34 pokes the material section separated from the material groove one 321 to the blocking surface 35, the synchronous toothed belt 33 conveys the material section to the discharging channel 36 along the blocking surface 35, and the material section enters the first conveying device 21 or the second conveying device 22 along the discharging channel 36.

As shown in fig. 4, the first transmission device 21 includes a first anti-backlash mechanism 211 and a first accelerating wheel 212 rotatably disposed on the frame, the first anti-backlash mechanism 211 includes a first spiral roller rotatably disposed on the frame and a first power member for driving the first spiral roller to rotate, the frame is also provided with a second power member for driving the first accelerating wheel 212 to rotate, and the first power member and the second power member may be motors. The material section supplied by the material supply device 3 is contacted with the first spiral roller, and the first spiral roller drives the material section to move forwards to provide power, and meanwhile, gaps among the material sections can be eliminated to form continuous material flow. Each material 4 in the material flow sequentially contacts the first accelerating wheel 212, the first accelerating wheel 212 drives the material 4 to accelerate to move so that gaps are formed among the materials 4, the poking part 15 in the material transfer gear train 1 enters the gaps among the materials 4, and the poking material 4 moves

As shown in fig. 5, the second transmission device 22 comprises two material section transmission wheels 221 rotatably arranged on the frame, a second gap eliminating mechanism 222, a second accelerating wheel 223 rotatably arranged on the frame, and two second gap eliminating mechanisms 222 rotatably arranged on the frame, wherein the second gap eliminating mechanism 222 comprises a second spiral roller rotatably arranged on the frame, a second power member for driving the second spiral roller to rotate, and a fourth power member for driving the second accelerating wheel 223 to rotate is arranged on the frame. The material section transfer wheel 221 lateral wall is equipped with a plurality of material sections and dials portion 15, and material section is stirred portion 15 and is entered into the clearance between each material section, transmits the material section, and material section and helical drum two phase contact, helical drum two drive material section forward motion provide power, can also eliminate the clearance between each material section simultaneously, forms continuous material flow. Each material 4 in the material flow sequentially contacts the second accelerating wheel 223, the second accelerating wheel 223 drives the material 4 to accelerate so that gaps are formed among the materials 4, and the stirring part 15 of the material transfer gear train 1 enters the gaps among the materials 4 to stir the materials 4 to move.

As shown in fig. 1, the material transfer gear train 1 comprises a first material transfer wheel 11, a second material transfer wheel 12, a third material transfer wheel 13 and a fourth material transfer wheel 14 which are rotatably connected to a frame, and a plurality of stirring parts 15 which are uniformly distributed are arranged on the side wall of the first material transfer wheel 11, the side wall of the second material transfer wheel 12, the side wall of the third material transfer wheel 13 and the side wall of the fourth material transfer wheel 14. The frame is provided with a driving motor for driving the first material transfer wheel 11, the second material transfer wheel 12, the third material transfer wheel 13 and the fourth material transfer wheel 14 to rotate. The second conveying device 22 conveys the material 4 to the first conveying wheel 11, the first conveying wheel 11 conveys the material 4 to the second conveying wheel 12, and the second conveying wheel 12 conveys the material 4 to the third conveying wheel 13; the second conveying device 22 conveys the material 4 to the fourth conveying wheel 14, the fourth conveying wheel 14 conveys the material 4 to the third conveying wheel 13, and the materials 4 in the first conveying device 21 and the second conveying device 22 are combined after being collected at the third conveying wheel 13 to form a multi-component combined material.

Example 2: the multi-component material combination process system is different from the embodiment 1 in that the material supply device 3 further comprises a transition wheel rotatably arranged on the frame and a driving motor five for driving the transition wheel to rotate, a plurality of transition material grooves are formed in the transition wheel, the lengths of the transition material grooves are arranged along the axial direction of the transition wheel, the plurality of transition material grooves are uniformly distributed along the circumferential direction of the transition wheel, an inner cavity three connected with the negative pressure system and a plurality of air holes three are formed in the transition wheel, and the inner cavity three is communicated with the transition material groove at each position through the air holes three. The transition wheel is located between the feed wheel 31 and the discharge wheel 32, and is abutted against the feed wheel 31 and the discharge wheel 32.

Claims (6)

1. The multi-element material combination process system comprises a material channel, a rotatable material transmission gear train (1) and a material transmission device (2) for transmitting a material (4) into the material transmission gear train (1), wherein the material transmission gear train (1) comprises a stirring part (15) for stirring the material (4) to move in the material channel, and the material transmission device (2) comprises one or more combinations of a transmission device I (21) and a transmission device II (22);

the first conveying device (21) comprises a first gap eliminating mechanism (211) for eliminating gaps among the material sections to form a continuous material flow, and a first accelerating wheel (212) for forming equal gaps among the materials (4) in the material flow;

the second conveying device (22) comprises at least one material section conveying wheel (221) which can rotate and is used for conveying material sections, a second gap eliminating mechanism (222) which is used for eliminating gaps among the material sections and then forming continuous material flows, and a second accelerating wheel (223) which is used for enabling equal gaps among the materials (4) in the material flows to be formed; the material transfer device (2) comprises a first transfer device (21) and at least two second transfer devices (22); the material feeding device (3) comprises a frame, wherein the material feeding device (3) comprises a discharging wheel (32) rotatably arranged on the frame, a synchronous toothed belt (33) arranged below the discharging wheel (32) and a driving part used for driving the synchronous toothed belt (33) to move, a first material groove (321) is formed in the discharging wheel (32), and a poking tooth (331) is formed in the synchronous toothed belt (33); a blocking surface (35) and a poking wheel (34) rotatably connected to the stand are arranged on the stand, and the poking wheel (34) is used for poking a plurality of sections of materials (4) on the synchronous toothed belt (33) to the blocking surface (35); the axis of the discharging wheel (32) is parallel to the conveying direction of the synchronous toothed belt (33), the width of the poking tooth (331) is larger than that of the first material groove (321), and the poking tooth (331) is positioned outside the first material groove (321); the material supply device (3) further comprises a feeding wheel (31) rotatably arranged on the frame, a material (4) storage hopper (37) arranged above the feeding wheel (31), a material groove II (311) is formed in the feeding wheel (31), and the material (4) on the feeding wheel (31) can be transferred to the discharging wheel (32).

2. The multiple material combination process system of claim 1, wherein: the material transfer gear train (1) comprises a first material transfer wheel (11), a second material transfer wheel (12), a third material transfer wheel (13) and a fourth material transfer wheel (14), wherein the second material transfer device (22) transfers the material (4) to the first material transfer wheel (11), the first material transfer wheel (11) transfers the material (4) to the second material transfer wheel (12), and the second material transfer wheel (12) transfers the material (4) to the third material transfer wheel (13); the second conveying device (22) conveys the material (4) to the fourth conveying wheel (14), and the fourth conveying wheel (14) conveys the material (4) to the third conveying wheel (13).

3. The multiple material combination process system of claim 2, wherein: the side wall of the first material transfer wheel (11), the side wall of the second material transfer wheel (12), the side wall of the third material transfer wheel (13) and the side wall of the fourth material transfer wheel (14) are respectively provided with a poking part (15).

4. The multiple material combination process system of claim 1, wherein: the first gap eliminating mechanism (211) comprises a rotatable spiral roller I; the second gap eliminating mechanism (222) comprises a second rotatable spiral roller.

5. The multiple material combination process system of claim 1, wherein: the second conveying device (22) comprises at least two material section conveying wheels (221).

6. The multiple material combination process system of claim 1, wherein: the material supply device (3) is provided with a plurality of transmission devices (21) and (22) which correspond to each other.