JP2008503231A - Composite cigarette filter manufacturing apparatus and method - Google Patents

Abstract

Apparatus for the production of combined filters or recess filters for cigarettes is disclosed, the apparatus comprising: a feeder (12) for feeding a plurality of filter segments (2, 4) along a path; a wrapper downstream of the feeder (12) for wrapping the plurality of segments in a web of material (18) to form a rod (20); a combiner (52, 58, 68) operative at a location between the feeder (12) and the wrapper for forming a stream of aligned segments from the plurality of segments (2, 4) and for transporting the stream of aligned segments along the path to the wrapper, and cutting means (24, 28) for severing the rod (20) into a plurality of discrete rods each comprising a plurality of segments, the combiner (52, 58, 68) being adapted to maintain the alignment of segments in the stream of aligned segments as it transports the stream of aligned segments to the wrapper so that, in use, relative movement of the segments in the stream is substantially prevented over the entire length of the path from the combiner to the wrapper.

Description

  The present invention relates to an apparatus and method for manufacturing a rod composed of a plurality of segments, and is particularly applicable to the manufacture of a synthetic filter or a recess filter for tobacco.

  Cigarettes usually have a rolled tobacco column, optionally with a filter at the tip. The filter may be a composite multi-component filter composed of a plurality of filter rod segments. The filter rod segments that make up the composite filter may comprise different basic filter materials or may be composed of the same basic filter material, but alternating segments are impregnated with particulate material. FIG. 1a shows a composite filter rod composed of alternating segments of cellulose acetate 2 and cellulose acetate 4 impregnated with carbon particles. This composite filter consists of a segment consisting of an air gap, recess or cavity adjacent to or between other filter rod segments to form a composite filter, which is filled with particulate material or other material. Also good. FIG. 2 a shows a composite filter rod comprising a cellulose acetate segment 2, a cellulose acetate segment 4 impregnated with carbon particles, and an air gap or cavity 6 interposed between adjacent cellulose acetate segments 2. The plurality of dissimilar segments 2, 4, 6 of the composite filter rod shown in FIGS. 1a and 2a are fixed to each other by winding the composite filter rod with glued paper known as plug wrap. A composite filter composed of a plurality of dissimilar filter rod segments including one or more air gaps or cavities is known as a recess filter. A composite filter that does not include an air gap is commonly referred to as a combined filter.

  It is known to produce cigarettes with synthetic or recessed filters using a two-stage double winding process. In the first stage, a synthesizer is used to form a continuous flow of two or more different types of aligned alternating filter rod segments, which are then wound with a web of plug wraps to form a continuous filter Form a rod. The continuous filter rods are then cut at regular intervals by a cutting mechanism to form a series of individual composite filter rods. In the second stage of the process, a tip processing machine is used to join individual composite filter rods to tobacco columns that have been pre-wound with tip processing paper to form tobacco.

  Usually, the individual composite filter rods made in the first stage of the double winding process are of multi-unit length, i.e. contain two or more composite filters, each of which is combined with a tobacco column to produce tobacco. Form. For example, the individual composite composite filter rods made in the first stage may have a pair of 1-up first filter rods on either side of a centrally located 2-up first filter rod segment (first filter rod segment of double unit length). Includes two aligned filter rod sections. In the second stage of the double winding process, individual composite synthetic filter rods are joined at both ends to a wound tobacco post to form a 2-up tobacco centered on a 2-up filter. Finally, each two 2-up cigarettes are cut at the midpoint of the composite synthetic filter rod, and two 1-up filter cigarettes each having a synthetic filter that includes one second filter rod segment and half the first filter rod segment. Form.

  2a forms a continuous filter rod consisting of a group 8 of filter rod segments 2, 4 separated by an air gap 6, and then cuts the continuous rod to the desired length. Can be manufactured. If the air gap 6 is left unfilled, the individual recess filter rods of FIG. 2a can be cut in half at the center to form a pair of 2-up recess filter rods, Each can then be cut in half at the center in the air gap 6 to form four individual 1-up recess filters. Similarly, the individual synthesis filter rods shown in FIG. 1a form four synthesis filters when cut into four equal length sections.

  The filtration characteristics of composite tobacco filters depend on the length of the filter segments and, in the case of recess filters, their spacing. Therefore, in the double winding process described above, the exact location of each cut made with respect to a plurality of aligned filter rod segments in a continuous filter rod is very important. This is because it determines the length of the outermost or outer filter rod segment of the individual composite filter rod to be formed.

  Known devices for manufacturing composite filters have a plurality of filter rod segments assembled into a desired composite filter or recess filter configuration by a synthesizer to create a composite filter that is wound into a plug wrap web and locked in place. Previously, it suffered from the drawback of being able to shift slightly from one another. As a result, the filter rod segments that make up the composite filter are not always in the correct position within the continuous filter rod at the time it is cut, and therefore, as shown in FIG. Individual composite filter rods are formed. When manufacturing a recess filter using such a known device, the relative movement of the filter rod segments prior to wrapping with a paper web is determined as shown in FIG. 2b. In the air gap or cavity length.

  In known devices where the continuous filter rod is not cut so that the composition of each individual composite filter rod is the same as a result of the relative movement of the filter segments, the outer filter segment of the individual composite filter rod being manufactured It is also known to constantly monitor the length and, in the case of a recess filter, the length of the air gap to maintain quality standards. If the individual composite filter rod structure is shown not to meet the predetermined criteria, the rod is marked as such and separated from the remaining satisfactory individual filter rods and removed. The generation of this useless "out of specification" individual composite filter rod is undesirable.

  To overcome the drawbacks associated with known devices, a composite cigarette that allows high accuracy during the formation of the outer filter rod segment length of both the synthesis filter and the recess filter and / or the length of the air gap of the recess filter It would be desirable to provide a filter manufacturing apparatus.

  It would also be desirable to provide a composite tobacco filter manufacturing device that can increase the processing speed of the device while maintaining the same level of final composite filter quality.

  In addition, it would be desirable to provide an apparatus for producing a composite cigarette filter that reduces waste during manufacture with respect to "out-of-spec" synthetic filter rods than known devices.

  It would also be desirable to provide a composite tobacco filter manufacturing device that requires less maintenance than known devices.

  In addition, an existing known composite tobacco filter manufacturing apparatus can be easily modified to have the above-mentioned desirable characteristics, and an existing known composite tobacco filter manufacturing apparatus can be manufactured so that both a synthetic tobacco filter and a recessed tobacco filter can be manufactured. It is also desirable to adapt.

  According to the present invention, an apparatus for manufacturing a rod composed of a plurality of segments, a feeder supplying a plurality of segments along a path, and a plurality of segments downstream of the feeder and made of a web of material Operating at a position between the feeder and the wrapping device to form an aligned segment flow from the plurality of segments, and the aligned segment flow An apparatus comprising: a synthesizer for conveying along a path to a winding device; and a cutting means for cutting the rod into a plurality of individual rods each composed of a plurality of segments. To maintain segment alignment in the aligned segment flow when conveying the aligned segment flow to the wrapping device Is response, in use, relative movement of the segments in the stream is, apparatus being characterized in that so as to be substantially prevented is provided over the entire length of the route to the device wrapping from synthesizer.

  According to the present invention, there is also provided a method for manufacturing a rod composed of a plurality of segments, the step of supplying the plurality of segments along the path to the first position, and the plurality of segments at the first position. Forming an aligned segment stream; conveying the aligned segment stream along a path from a first position to a second position; and at the second position, flowing the segment stream with a web of material. Rolling the rod to form a rod; and repeatedly cutting the rod to form a plurality of individual rods each composed of a plurality of segments, wherein the rods are aligned during the conveying step. Maintaining the alignment of the segments in the segment flow, the relative movement of the segments in the flow is such that the first position and the second position Method characterized by further comprising the step of to be substantially prevented is provided between the.

  By reducing the relative movement of rod segments, such as tobacco filter rod segments, during composite filter manufacture, the method and apparatus of the present invention provides an outer rod segment compared to known composite filter manufacturing methods and apparatus. And / or high quality standards can be maintained for changes in the length of the air gap.

  Furthermore, because the relative movement of the rod segments is thus reduced, it is not necessary to continuously monitor the length of the outer rod segments during composite filter manufacture.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.
FIG. 3 produces individual composite filter rods of the type manufactured by Sanjo Machine Works Ltd of Japan and sold under the model number ND-3 by Japan Filter Technology Ltd (JT Group). 1 shows a known device for The known device comprises a synthesizing device 10 including a delivery wheel 12, which has a plurality of dissimilar filter rod segments 2, 4 in a first preselected desired configuration as shown in FIG. 1a. Arranged on the endless belt conveyor 14. Dissimilar filter rod segments 2, 4 are transported from two or more magazines or hoppers to delivery wheel 12 by a series of conveyors (not shown). As the filter rod segments 2, 4 are delivered to the first endless belt conveyor 14, they are pressed together to form a continuous flow 16. The first belt conveyor 14 conveys the abutting filter rod segments 2, 4 to the upper surface of a continuously extending paper web 18 drawn from a bobbin (not shown). The paper web 18 has an adhesive applied to at least a portion of its upper surface, but is hung continuously around the filter rod segments 2, 4 by a garniture (not shown). A composite composite filter rod 20 is formed. The continuous paper web 18 is withdrawn from the bobbin and is conveyed downstream by the second endless belt conveyor 22 through the garniture to the cutting head 24. In the cutting head 24, continuous composite filter rods 20 are cut at regular intervals to form a series of individual composite filter rods 26. The cutting head 24 comprises a rotary knife 28 mounted for rotation at a constant speed about an axis parallel to the longitudinal axis of the continuous composite filter rod 20. A rotary knife that synchronizes with the delivery wheel 12 cuts a separate composite filter rod at each rotation. The cutting head 24 is tuned to the filter rod segment when the filter rod segments 2, 4 are locked in place by the paper web 18. When this known device operates at an optimal setting, along the path from the point where the filter rod segments 2, 4 are released by the synthesizer 10 to the point where it is wound and fixed by the continuous paper web 18. The resulting position error of the filter rod segments 2, 4 causes the same error in the cutting head 24.

  When the filter rod segments 2, 4 are wound around the paper web 18 to form a continuous filter rod 20, they are fixed in position relative to each other. However, the filter rod segments 2, 4 can move relative to each other while being transported downstream from the delivery wheel 12 of the synthesizer 10 by the first endless belt conveyor 14 to the paper web 18. Furthermore, if there is a difference in speed between the first belt conveyor 14 and the second endless belt conveyor 22, the filter rod segments 2, 4 are pushed when they are transferred to the continuous paper web 18. Will fit. The relative movement of the filter rod segments 2, 4 before wrapping with the paper web 18 leads to the formation of useless individual composite filter rods with different lengths of external filter rod segments, as shown in FIG. 1b. become. Between the delivery wheel 12 and the point where the filter rod segments 2, 4 are secured by the paper web 18 (typically a distance of about 40 cm), each filter rod segment 2, 4 is simply relative to the adjacent filter rod segment. As they are pressed, the length changes of the individual filter rod segments 2, 4 are summed in the individual composite filter rods 26 that are manufactured.

  FIG. 4 shows a known apparatus for manufacturing individual recess filter rods of the type sold under the model number PTCM by Morinth PLC of Milton Keynes, UK.

  Similar to the known device shown in FIG. 3, the known device shown in FIG. 4 comprises a synthesis device 30 including a delivery wheel 32, which comprises a plurality of filter rod segments 2, 4 in a first endless belt. It accumulates on the conveyor 34. This first endless belt conveyor 34 conveys the filter rod segments 2, 4 downstream to a helical spacer drum 36 which is also part of the synthesizer 30, which has an air gap between the groups 8 of segments 2, 4. By forming 6, filter rod segments 2, 4 are grouped in a preselected desired recess configuration as shown in FIG. 2a. An endless transfer belt 38 adjacent to the spiral spacer drum 36 conveys the group 8 of filter rod segments 2, 4 to the upper surface of a continuously extending paper web 40 drawn from a bobbin (not shown). The paper web 40 has an adhesive applied to at least a portion of its upper surface, but is continuously hung around the spaced apart group 8 of filter rod segments 2, 4 by a garniture (not shown). A rolled composite recess filter rod 42 is formed. Similar to the apparatus shown in FIG. 3, the continuous paper web 40 is drawn from the bobbin and passed downstream by the second endless belt conveyor 48 to the cutting head 44 having a rotary knife 46. Is done. In the cutting head 44, a continuous composite filter rod 42 is cut into individual recess filter rods 50 at regular intervals by a rotary knife 46, and the helical spacer drum 36 of the synthesizer 30 harmonizes with the rotary knife 46. Be operated.

  The distance at which the group 8 of filter rod segments 2, 4 is transported between the synthesis device 30 and the paper web 40 is reduced in the known device shown in FIG. 4 compared to the known device shown in FIG. Is done. Considered separately, this is expected to correspondingly reduce the change in the length of the outer filter rod segment of the individual recessed filter rod 50 being manufactured, but the known device shown in FIG. In the layout, other error sources are introduced in the relative positioning of the group 8 of filter rod segments 2, 4 in successive composite filter rods 42. During transfer from the helical spacer drum 36 of the synthesizer 30 to the transfer belt 38, the filter rod segments 2, 4 are free to shift in position either globally or relative to each other before being fixed by the paper web 40. To do. Furthermore, the design of the endless transfer belt 38 located above the group 8 of filter rod segments 2, 4 and the air gap 6 between them is such that the segments 2, 4 and air gap 6 are under the transfer belt 38. The paper web 40 cannot be folded around them, rather, the group 8 of filter rod segments 2, 4 must be taken out from under the transfer belt 38 before being positioned by the folded paper web 40. . Between the end of the transfer belt 38 and the point where the group 8 of filter rod segments 2, 4 is secured by the paper web 40, the group 8 of filter rod segments 2, 4, and the filter rod segment 2 in each group 8 4 also move freely relative to each other.

  The relative movement of the group 8 of filter rod segments 2, 4 before being wrapped with the paper web 40 in the apparatus of FIG. 4 makes it possible to produce useless individual recess filter rods with external filter rod segments of different lengths. In addition to incurring, as shown in FIG. 2b, it also leads to the production of useless individual recess filter rods with air gaps 6 of different lengths.

  An apparatus for manufacturing a composite filter according to a first embodiment of the present invention is shown in FIG. In FIG. 5, the same reference numerals are used to identify parts of the device of the present invention corresponding to the parts of the known device shown in FIG. 3 described above.

  The apparatus according to the first embodiment of the invention shown in FIG. 5 is an endless transfer mounted on the first endless conveyor belt 14 and the second endless conveyor belt 22 between the delivery wheel 12 and the cutting head 24. It differs from a known device of the type shown in FIG. 3 in that it further comprises a belt 52. A plurality of evenly spaced spacers or teeth 54 are mounted on the outer surface of the endless transfer belt 52 and the spacing between adjacent teeth 54 is the total number of filter rods that are fed into the first endless belt conveyor 14 by the delivery wheel 12. Equal to the length of segments 2 and 4. The endless transfer belt 52 is driven by a power pulley 56 in harmony with the cutting head 24. To prevent the endless transfer belt 52 from slipping on this power pulley 56 and causing a change in the length of the outer filter rod segment of the individual filter rod being manufactured, the endless transfer belt 52 has teeth 54. On the inner surface opposite to that, harmony pins (not shown) can be provided, which cooperate with correspondingly spaced harmony holes (not shown) provided in the power pulley 56. Endless transfer belt 52 and teeth 54 can be formed of metal, rubber, plastic, or other suitable material.

  In use, when the filter rod segments 2, 4 from the delivery wheel 12 are fed under the endless transfer belt 52 by the first endless belt conveyor 14, the teeth 54 of the endless transfer belt 52 are moved into the filter rod segment 2. 4 are separated into groups 8 of length equal to the spacing between the teeth 54, and the grouped filter rod segments 2, 4 are then transferred to the continuous moving paper web 18. The paper web 18 is then folded around a group 8 of filter rod segments 2, 4 by a known folding mechanism such as a garniture (not shown) to form a continuous composite filter rod 20, which Thereafter, it is cut at regular intervals by a rotary knife 28 of the cutting head 24 to form individual composite filter rods.

  While being transported downstream from the delivery wheel 12 toward the paper web 18 by the endless transfer belt 52, the group 8 of filter rod segments 2, 4 is held in a fixed relative position by the teeth 54 of the endless transfer belt 52. The The distance that the group 8 of filter rod segments 2, 4 must be transferred before they are fixed by the folded paper web 18 is that the filter plugs 2, 4 are folded in the delivery wheel 12 and in known devices. Compared to the distance between the points fixed by the paper web 18, it is significantly reduced. By reducing this distance and thus ensuring that the filter rod segments 2, 4 in the continuous composite rod 20 are more correctly positioned with respect to each other and the cutting head 24, the apparatus shown in FIG. And in the case of a recess filter, the air gap length 6 of the individual composite rod produced is reduced compared to known devices.

  The device according to the first embodiment of the invention shown in FIG. 5 can be used to make both individual synthetic filter rods and individual recess filter rods (unlike the known device shown in FIG. 3). When manufacturing individual recess filter rods, the endless transfer belt 52 and the second endless belt conveyor 22 carrying the paper web 18 are driven at the same speed. Thus, when the grouped filter rod segments 2, 4 are transferred to the paper web 18, the spacing 6 of the group 8 of filter rod segments 2, 4 obtained by the teeth 54 of the transfer belt 52 is maintained. As shown in FIG. 5, when this device is used to manufacture an individual recess filter rod having the configuration shown in FIG. 2a, the width of each tooth 54 is equal to the width of the air gap 6 in the recess filter. And the spacing between adjacent teeth 54 is equal to the sum of the lengths of two cellulose acetate segments 2 and one cellulose acetate segment impregnated with carbon particles.

  In order to produce individual composite filter rods, the second endless belt conveyor 22 carrying the paper web 18 is driven at a lower speed than the endless transfer belt 52. When the group 8 of filter rod segments 2, 4 is transferred to the paper web 18 by the teeth 54 of the endless transfer belt 52, the difference in speed between the endless transfer belt 52 and the second endless belt conveyor 22 causes the filter The group 8 of rod segments 2, 4 is pressed against each other to form a continuous composite filter rod. When manufacturing a synthetic filter rather than a recess filter using the apparatus according to the first embodiment of the present invention shown in FIG. 5, the width of the teeth 54 of the endless transfer belt 52 is the same as that of the endless transfer belt 52 and the second filter. Based on the speed difference from the endless belt conveyor 22, it is clear that it is not significant.

  In the known apparatus for producing the individual recess filter rods shown in FIG. 4, a spiral spacer drum 36 groups the filter rod segments 2, 4 to form the necessary air gap 6 therebetween, The endless conveyor belt 38 then moves the grouped filter rod segments 2, 4 toward the paper web 40. As already mentioned with reference to FIG. 4, the transfer of the group 8 of filter rod segments 2, 4 between the helical spacer drum 36 and the transfer belt 38 is a filter rod in the continuous recess filter rod 42 to be manufactured. An additional error source is introduced in the relative positioning of segments 2 and 4. In the device according to the first embodiment of the invention shown in FIG. 5, the endless transfer belt 52 with teeth 54 serves as both the helical spacer drum 36 and the transfer belt 38 of the known device of FIG. Avoid introducing additional error sources.

  Conveniently, the endless transfer belt 52 of the apparatus of FIG. 5 may be mounted for pivotal movement about a power pulley 56 so that the filter rod segment 2 under the transfer belt 52 during manufacture. 4 under the transfer belt 52 so that it can be easily cleaned when jammed 4 compared to the transfer belt 38 of the known device of FIG.

  An apparatus for manufacturing a composite filter according to a second embodiment of the present invention is shown in FIG. In FIG. 6, the same reference numerals are used to identify parts of the device according to the second embodiment of the invention corresponding to the known devices already described.

  The structure of the apparatus according to the second embodiment of the invention shown in FIG. 6 is mounted on the first endless conveyor belt 14 and the second endless conveyor belt 22 between the delivery wheel 12 and the cutting head 24. It differs from a known device of the type shown in FIG. 3 in that it further comprises a transfer device 58. In use, the transfer device 58 moves the filter rod segments 2, 4 from the delivery wheel 12 along a second endless belt conveyor 22 just upstream of the garniture or other known folding mechanism (not shown). In position, it is repeatedly delivered to a continuously extending paper web 18.

  The transfer device 58 comprises three adjacent wheels 60, 62, 64 mounted so as to rotate about a parallel axis perpendicular to the direction of movement of the filter rod segments 2, 4 in the first endless belt conveyor 14. . Each wheel 60, 62, 64 has a plurality of spaced rounded teeth 66 disposed around it, and the spacing of adjacent teeth 66 in each wheel 60, 62, 64 is adjusted by the delivery wheel 12 to a first The total number of filter rod segments 2, 4 fed to the endless belt conveyor 14 is approximately equal in length. The two outer wheels 60, 64 of the transfer device 58 have a row of teeth 66 disposed around them, while the inner wheel 62 has a pair of opposing rows of teeth 66 disposed around it. . When the three wheels 60, 62, 64 are rotated during use, the teeth 66 on the two outer wheels 60, 64 are replaced by the outer wheels 60, 64 and the inner wheels. 62 are attached to each other in the transfer device 58 so as to pass between the teeth 66 of the inner row 62 facing each other in the inner wheel 62. The wheels 60, 62, 64 and their teeth 66 are made of metal or other suitable material.

  In use, when the filter rod segments 2, 4 from the delivery wheel 12 are fed by the first endless belt conveyor 14 below the transfer device 58 of the apparatus of FIG. 6, the teeth 66 of the first outer wheel 60 are The filter rod segments 2, 4 are separated into groups 8 of length equal to the spacing of the teeth 66. As the first outer wheel 60 rotates, the group 8 of filter rod segments 2, 4 held between its teeth 66 is conveyed downstream toward the counter-rotating inner wheel 62. When the teeth 66 of the first outer wheel 60 are adjacent to the teeth 66 of the inner wheel 62, the group 8 of filter rod segments 2, 4 held between the teeth 66 of the first outer wheel 62 becomes the teeth of the inner wheel 62. 66. Then, when the inner wheel 62 further rotates, the group 8 of filter rod segments 2 and 4 transferred from the first outer wheel 60 is conveyed further downstream toward the second outer wheel 64 that rotates in the reverse direction. When the teeth 66 of the second outer wheel 64 interlock with the teeth 66 of the inner wheel 62, the filter rod previously transferred from the first outer wheel 60 to the inner wheel 62 and held between the teeth 66 of the inner wheel 62. The group 8 of segments 2, 4 is transferred between the teeth 66 of the second outer wheel 64. As the second outer wheel 64 rotates further, the group 8 of filter rod segments 2, 4 is transferred to the continuously extending paper web 18. The paper web 18 is then folded around the filter rod segments 2, 4 by a known folding mechanism (not shown) such as a garniture to form a continuous composite filter rod 20, which is then It is cut at regular intervals by a rotary knife 28 of the cutting head 24 to form individual composite filter rods. The rotation of each of the three wheels 60, 62, 64 of the transfer device 58 of the apparatus of FIG. 6 is coordinated with the cutting head 24, resulting in an accurate cut of the continuous composite filter rod 20 by the rotary knife 28.

  Similar to the operation of the device according to the first embodiment of the invention shown in FIG. 5, the device according to the second embodiment of the invention shown in FIG. 6 is the second endless belt conveyor 22 and the wheels 60, 62 of the transfer device 58. , 64 are driven at the same speed to form a continuous recess filter rod 20 having an air gap 6 with a length equal to the width of the teeth 66 of the second outer wheel 64, thereby providing a separate recess filter. The individual endless belt conveyor 22 is driven at a lower speed than the wheels 60, 62, 64 of the transfer device 58 to form a continuous composite filter rod 20 by manufacturing the rods. It can be used as needed to produce synthetic filter rods.

  In order to avoid the pushing of the filter rod segments 2, 4 during the manufacture of the recess filter rod, the wheels 60, 62, 64 of the transfer device 58 have a tangential speed of the second outer wheel 64 of the second endless belt conveyor. Essentially the same as the tangential speed of 22, each group 8 of filter rod segments 2, 4 has little or no relative speed from the second outer wheel 64 to the second endless belt conveyor 22. In a state, it is driven to be delivered to a continuous paper web 18.

  The diameter of each wheel 60, 62, 64 of the transfer device 58, as well as the spacing of its teeth 66 and its width or width, can be varied to achieve different machine speeds and / or produce different filter types. When manufacturing a recess filter, the width of the teeth 66 of the inner wheel 62 and the second outer wheel 64 (the arcuate length) is the group of filter rod segments 2, 4 in the continuous recess filter rod 20. Preferably, it is equal to the desired width of the air gap 6 between 8. The lateral width (arched length) of the teeth 66 of the first outer wheel 60 is reduced compared to the inner wheel 62 and the second outer wheel 64, and is wider between the teeth 66 of the first outer wheel 60. It is preferable to form an interval. This wide spacing between the teeth 66 of the first outer wheel 60 is, in use, the filter rod segment 2 from the first endless belt conveyor 14 driven at a speed higher than the tangential speed of the first outer wheel 60, 4 is received at the pinch between them.

  Once the group 8 of filter rod segments 2, 4 is established between the first outer wheel 60 teeth 66, it is aligned with the other group 8 when it is transferred to the inner wheel 62. . Even if there is a shift of the group 8 of filter rod segments 2, 4 at the pinch between the first outer wheel 60 and the inner wheel 62, the rounded profile of the teeth 66 and the teeth 66 at the pinch Accepted by coincidence (superimposition relationship).

  In FIG. 6, the rotation axis of the inner wheel 62 of the transfer device 58 is shown as being vertically offset with respect to the rotation axes of the two outer wheels 60 and 64, but the rotation axes of the wheels 60, 62 and 64 are It will be clear that they may be in line with each other. In addition, the apparatus according to the third embodiment of the present invention shown in FIG. 6 includes a transfer device 58 composed of three adjacent wheels 60, 62, 64, but a transfer device 58 composed of a different number of adjacent wheels can also be used. Will be clear.

  Conveniently, the transfer device 58 of the device of FIG. 6 can also be mounted to pivot about its one end, so that the filter rod segment 2 under the wheels 60, 62, 64 during manufacture. 4 is easily cleaned under the wheels 60, 62, 64 of the transfer device 58, compared to the transfer belt 38 of the known device of FIG.

  While being transported downstream from the delivery wheel 12 toward the paper web 18 by the transfer device 58, the group 8 of filter rod segments 2, 4 is fixed relative to the teeth 66 of the three wheels 60, 62, 64. Retained. Therefore, the distance at which the filter rod segments 2, 4 are slightly shifted or pushed together is again significantly reduced compared to the known device shown in FIG. While reducing this distance and using a single transfer device 58 to perform the functions of both the helical spacer drum 36 and transfer belt 38 of the known device of FIG. 4, the device shown in FIG. 3 and 4 over the known apparatus of the type shown in FIGS. 3 and 4, the same effect already shown and examined in connection with the apparatus according to the first embodiment of the invention shown in FIG. In addition to these effects, the device according to the second embodiment of the present invention shown in FIG. 6 does not include a transfer belt and therefore requires less maintenance than the known device of the type shown in FIG.

  The apparatus for manufacturing the composite filter according to the third embodiment of the present invention has the same general structure and operation mode as the apparatus according to the second embodiment of the present invention shown in FIG. However, the structure of the device according to the third embodiment of the invention is that a plurality of holes are provided around the wheels 60, 62, 64 of the transfer device 58 instead of or in addition to the teeth 66. Different from the apparatus according to the second embodiment of the present invention. The plurality of holes are arranged in groups that are evenly spaced around the wheel, each group consisting of two or three adjacent holes arranged in a line parallel to the axis of rotation of the wheel. In use, air is drawn through the holes to transfer the filter rod segments 2, 4 from the first endless belt conveyor 14 to the first outer wheel 60 and to move the filter rod segment from the first outer wheel 60 to the inner side. Deliver to the wheel 62 and from the inner wheel 62 to the second outer wheel 64. The filter rod segments 2, 4 follow from the wheel with the transfer device 58 by releasing the suction applied to the holes in the upstream wheel as they rotate through the catch between the upstream wheel and the next wheel. Is transferred downstream to the wheel. The filter rod segments 2, 4 release the suction applied to the holes in the second outer wheel 64 as they rotate through the pinch between the second outer wheel 64 and the second endless belt conveyor 22. By doing so, it is similarly transferred from the second outer wheel 64 of the transfer device 58 to the second endless belt conveyor 22.

  The suction applied to the holes in the wheels 60, 62, 64 holds the filter rod segments 2, 4 in position when they are transferred to the paper web 18 by the wheels and prevents their relative movement. Thus, the distance at which the filter rod segments 2, 4 are allowed to freely move or push against each other is again significantly reduced compared to known devices of the type shown in FIG. The device according to the third embodiment is advantageous over known devices of the type shown in FIGS. 3 and 4, and the same effect already shown and discussed in connection with the device according to the second embodiment of the invention shown in FIG. To demonstrate.

  In order to facilitate the transfer of the filter rod segments in the apparatus according to the second and third embodiments of the present invention, the pinching part between the first endless belt conveyor 14 and the first outer wheel 60 of the transfer device 58, the transfer A pinch between the first outer wheel 60 and the inner wheel 62 of the device 58, a pinch between the inner wheel 62 and the second outer wheel 64 of the transfer device 58, and / or a second outer wheel of the transfer device 58. A plow can be positioned at the pinched portion between 64 and the second endless belt conveyor 22.

  A synthetic filter manufacturing apparatus according to a fourth embodiment of the present invention is shown in FIG. Again, in FIG. 7, the same reference numerals are used to identify the parts of the device of the present invention that correspond to the previously described parts of the device.

  The structure of the device according to the fourth embodiment of the invention shown in FIG. 7 is that the endless suction mounted on the first endless conveyor belt 14 and the second endless conveyor belt 22 between the delivery wheel 12 and the cutting head 24. The belt 68 differs from the known device shown in FIG. 3 in that it further comprises an endless suction belt 68 driven at the same speed as the second belt conveyor 22.

  In use, when the abutting filter rod segments 2, 4 delivered to the first endless belt conveyor 14 by the delivery wheel 12 reach the upstream end of the suction belt 68, they are applied to the belt 68 by suction applied to the belt 68. It is held against and conveyed downstream toward a continuously extending paper web 18. At the downstream end of the belt, suction is released and the filter plugs 2, 4 are placed on the paper web 18, which is then folded around them using a known folding mechanism such as a garniture. , Forming a continuous composite filter rod 20. This continuous composite filter rod 20 is then cut into individual composite filter rods 26 by the rotary knife 28 of the downstream cutting head 24.

  In the apparatus of FIG. 7, the filter rod segments 2, 4 are held in a fixed relative position along the entire path from the delivery wheel 12 to the downstream end 72 of the suction belt 68 by the suction belt 68, They are released, wound by the paper web 18 and glued in place. Accordingly, the movement of the filter rod segments 2, 4 relative to each other or their movement relative to the paper web 18 and the cutting head 24 is prevented. Therefore, compared to known devices of the type shown in FIGS. 3 and 4, the accuracy of the external filter segment length of the individual composite rods manufactured using the device of the invention shown in FIG. The level of waste that occurs during manufacturing is reduced.

  The plurality of uniformly spaced teeth may be similar to that of the first embodiment shown in FIG. 5 or may be provided outside the endless suction belt 68 of the device according to the fourth embodiment of the device shown in FIG. It will be clear that it is good.

  In contrast to the known devices of the type shown in FIGS. 3 and 4, the operating speed of the device according to the first, second, third and fourth embodiments of the present invention is the quality of the individual composite filter rods produced. On the other hand, with known devices of the type shown in FIGS. 3 and 4, the reliability of the length of the outer filter rod segments of the individual composite filter rods produced can be increased with increasing processing speed. Further decreased.

  It will be apparent that the device according to the invention can be used to produce composite filter rods of a different structure than those shown in FIGS. 1a and 2a. For example, the device according to the invention can be used to produce a recessed filter rod of the type shown in FIG. 2a, in which group 8 is a single cellulose acetate filter segment. Further, the series of filter rod segments supplied to the device by the delivery wheel may include alternating filter rod segments of different lengths and / or types. In addition, the air gap 6 in the recess filter rod made with the device of the present invention includes a known delivery device, such as the third wheel 64 and garniture or other of the device according to the second embodiment of the present invention shown in FIG. Carbon and / or other adsorbent materials may be filled by a carbon delivery device mounted between known folding mechanisms.

FIG. 3 is a schematic view of filter rod segments in an exemplary synthetic filter rod. FIG. 1b shows the change in length of the outer filter rod segment of the synthetic filter rod of FIG. 1a caused by, for example, incorrect cutting of successive synthetic filter rods. FIG. 3 is a schematic view of a filter rod segment in an exemplary two-up recessed filter rod. FIG. 2b shows the change in the air gap length of the recess filter of FIG. 2a caused by movement of the filter rod segment during the manufacture of a continuous recess filter rod, for example. FIG. 1b is a schematic diagram of a known apparatus for producing individual composite filter rods of the type shown in FIG. 1a. Fig. 2b is a schematic view of a known apparatus for producing individual recess filter rods of the type shown in Fig. 2a. 1 is a schematic view of an apparatus according to a first embodiment of the present invention for producing a composite filter. FIG. 3 is a schematic view of an apparatus according to a second embodiment of the present invention for manufacturing a composite filter. FIG. 6 is a schematic view of an apparatus according to a fourth embodiment of the present invention for manufacturing a synthesis filter.

Claims (19)

  An apparatus for manufacturing a rod composed of a plurality of segments, a feeder (12) for supplying a plurality of segments (2, 4) along a path, and a material downstream of the feeder (12) A winding device for winding the plurality of segments on a web (18) to form a rod (20), and operating at a position between the feeder (12) and the winding device, the plurality of segments (2, A synthesizer (52, 58, 68) for forming an aligned segment flow from 4) and conveying the aligned segment flow along the path to the winding device; and the rod (20 ) For cutting into a plurality of individual rods each composed of a plurality of segments, wherein the combiner (52, 58, 68) comprises the alignment The aligned segments when transported to the wrapping device Maintaining segment alignment in the flow of the segment, so that in use, relative movement of the segment in the flow is substantially prevented over the entire length of the path from the combiner to the wrapping device. A device characterized by that.   The apparatus of claim 1, wherein the synthesizer (68) is adapted to maintain alignment of the segments in the flow of aligned segments by suction.   The apparatus according to claim 1 or 2, wherein the synthesizer comprises a plurality of spaced spacers (54, 66) for maintaining alignment of the segments in the flow of aligned segments.   4. An apparatus according to claim 1, 2 or 3, wherein the synthesizer comprises an endless belt (52, 68) mounted to move partially parallel to the path.   The apparatus of claim 4, wherein the outer surface of the endless belt (52) comprises a plurality of longitudinally spaced spacers (54).   6. A device according to claim 4 or 5, wherein the surface of the endless belt (52) has a plurality of holes through which a vacuum can be drawn during use.   Device according to claim 1, 2 or 3, wherein the synthesizer (58) comprises at least one wheel (60, 62, 64) mounted for rotation about an axis perpendicular to the path. .   The apparatus of claim 7, wherein the outer surface of each wheel (60, 62, 64) comprises a plurality of circumferentially spaced spacers (66).   The spacing between adjacent spacers (66) in the wheel (60) of the combiner (58) that is close to the feeder (12) is the same as the adjacent spacers (66 in other wheels (62, 64) of the combiner (58). 9. The device according to claim 8, wherein the device is greater than the spacing between.   10. A device according to claim 5, 6, 8 or 9, wherein the spacing between adjacent spacers (54, 66) is approximately equal to the length of the total number of segments (2, 4).   It is for manufacturing a rod composed of a plurality of segments in which one or more segments are air gaps (6), and the width of each spacer (54, 66) is set to the width of the air gap (6). 11. Apparatus according to claim 5, 6, 8, 9 or 10 which is substantially equal.   The device according to any one of claims 7 to 11, wherein the outer peripheral surface of each wheel (60, 62, 64) is provided with a plurality of holes through which a vacuum can be drawn during use.   An apparatus for producing a tobacco filter composed of a plurality of filter rod segments according to any of claims 1-12.   A method of manufacturing a rod composed of a plurality of segments, comprising: supplying a plurality of segments (2, 4) to a first position along a path; and, at the first position, the plurality of segments (2, 2). Forming an aligned segment flow from 4), conveying the aligned segment flow along the path from the first position to the second position, and at the second position, Winding a flow with a web of material (18) to form a rod (20), and repeatedly cutting the rod to produce a plurality of individual rods each composed of a plurality of segments (2, 4, 6). A step of maintaining the alignment of the segments in the stream of aligned segments during the conveying step so that the relative movement of the segments in the flow is The method further comprises the step of being substantially prevented between the first position and the second position.   The method of claim 14, further comprising providing suction to the stream of aligned segments between the first position and the second position.   15. The method of claim 14, further comprising forming an aligned segment flow comprised of spaced apart groups (8) of one or more segments (2,4) from the plurality of segments at the first location. Or 15. The method according to 15.   The method of claim 16, further comprising inserting a spacer (54, 66) between the group (8) of the one or more segments (2, 4) in the first position.   18. A method according to claim 16 or 17 for producing a rod composed of a plurality of segments, wherein one or more segments are air gaps (6).   18. A method according to any of claims 14 to 17 for producing a tobacco filter composed of a plurality of filter rod segments.

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