A CLEANING UNIT, A TOBACCO INDUSTRY MACHINE FOR PRODUCING MULTI-SEGMENT FILTER RODS AND A METHOD FOR CLEANING A TRAIN OF ROD-LIKE ELEMENTS

Abstract

A cleaning unit for tobacco industry machines, wherein the tobacco industry machine is configured to process a moving train (ST2) of rod-like elements (S1, S2) separated by compartments (105) and partially wrapped with a wrapper (101), wherein the compartments (105) are filled with a loose material (102) forming segments of the loose material (SC). The cleaning unit (104) includes an outlet partition (34) at an outlet from a cleaning zone (Z2) for limiting an uncontrolled displacement of contaminations from the cleaning zone (Z2) to a garniture zone (Z3), located above the train (ST2) of the rod-like elements and having a passage (35) through which the covering elements (10) pass.

Claims

1. A cleaning unit for a tobacco industry machine, wherein the tobacco industry machine is configured to process a moving train of rod-like elements separated by compartments and partially wrapped with a wrapper, wherein the compartments are filled with a loose material to form segments of the loose material, comprising: a cleaning zone, wherein the cleaning unit is positioned in the tobacco industry machine in the cleaning zone, the cleaning zone being located between a filling zone for filling the loose material into the compartments between the rod-like elements and a garniture zone for forming the train of the rod-like elements to a continuous filter rod, wherein the cleaning unit is configured to remove contaminations of the loose material from the rod-like elements, the segments of the loose material and the wrapper and wherein the cleaning unit further comprises: at least one cleaning element, located in the cleaning zone, for removing the contaminations of the loose material from the rod-like elements; at least one suction element for removing the contaminations of the loose material from the rod-like elements; a shifting mechanism configured to move covering elements to positions in which the covering elements at least partially cover the compartments filled with the loose material between the rod-like elements during movement of the train in a vicinity of the at least one suction element and wherein the covering elements, at a portion of their track of movement, are configured to move in parallel to a direction of movement of the rod-like elements; and an outlet partition at an outlet from the cleaning zone for limiting an uncontrolled displacement of contaminations from the cleaning zone to the garniture zone, located above the train of the rod-like elements and having a passage through which the covering elements pass.

2. The cleaning unit according to claim 1 further comprising: an inlet partition located at an inlet to the cleaning zone for limiting the uncontrolled displacement of contaminations from the filling zone to the cleaning zone.

3. The cleaning unit according to claim 1, further comprising: an end partition located at the inlet of the garniture zone, for limiting uncontrolled dislocation of the contaminations from the cleaning zone to the garniture zone located above the train of the rod-like elements and having a notch, through which an edge of the wrapper passes.

4. The cleaning unit according to claim 3, further comprising: a shield partition having a surface which is in parallel to the direction of movement, located in front of the end partition with respect to the direction of movement, for limiting the uncontrolled dislocation of the contaminations from the cleaning zone on to the rod-like elements of the train.

5. The cleaning unit according to claim 1, further comprising: an initial partition located at the outlet of the filling zone, for limiting uncontrolled dislocation of the contaminations from the filling zone to the cleaning zone.

6. The cleaning unit according to claim 1, further comprising: at least one partition is positioned in a direction transverse to the direction of movement.

7. The cleaning unit according to claim 1, further comprising: at least one partition, positioned in a direction transverse to the direction of movement, having a form of a flat plate.

8. The cleaning unit according to claim 1, further comprising: at least one partition, positioned in a direction transverse to the direction of movement, having a form of an arched shaped plate.

9. The cleaning unit according claim 1, further comprising: at least one partition having a main surface directed at an acute angle with respect to the direction of movement.

10. The cleaning unit according to claim 1, wherein the covering element comprises a thin-walled covering element.

11. The cleaning unit according to claim 1, wherein the at least one suction element comprises a suction nozzle having longitudinal suction opening.

12. The cleaning unit according to claim 1, wherein the at least one cleaning element comprises a scraping element in a form of a brush.

13. The cleaning unit according to claim 1, wherein the at least one cleaning element comprises a scraping element in a form of a compressed air nozzle.

14. The cleaning unit according to claim 1, further comprising: a feeding unit for arranging, in a spaced relationship, rod-like elements in a train on a wrapper placed on a garniture belt; a supplying unit for supplying a loose material into compartments between the rod-like elements; a garniture unit for wrapping the wrapper around the rod-like elements and the loose material to form a continuous filter rod; and a cutting head for cutting the continuous rod into multi-segment filter rods.

15. A method for cleaning a train of rod-like elements during production of filter rods in a tobacco industry machine, wherein the tobacco industry machine is configured to process a moving train of rod-like elements separated by compartments and partially wrapped with a wrapper, wherein the compartments are filled with a loose material forming segments of the loose material, the method comprising: removing contaminations of the loose material in a cleaning zone by moving covering elements to positions in which the covering elements at least partially cover the compartments filled with the loose material between the rod-like elements during the movement of the train in a vicinity of a cleaning element, wherein the covering elements in part of their track of movement are moved in parallel to the direction of movement of the rod-like elements; and limiting uncontrolled displacement of the contaminations from the cleaning zone by providing an outlet partition at an outlet of the cleaning zone, above the train of rod-like elements, the outlet partition comprising a passage, through which the covering elements pass.

Description

BRIEF DESCRIPTION OF FIGURES

[0026] The present invention is shown by means of example embodiments in a drawing, in which:

[0027] FIGS. 1 and 2 show fragments of examples of continuous multi-segment rods;

[0028] FIG. 3 shows an example of a multi-segment rod;

[0029] FIG. 4 shows schematically a fragment of a machine for producing multi-segment filter rods;

[0030] FIG. 5 shows a fragment of a machine for producing multi-segment filter rods in a front view;

[0031] FIG. 6 shows a fragment of a machine for producing multi-segment filter rods in a top view;

[0032] FIG. 7 shows a cross-section A-A from FIG. 5 through a compartment with loose material in a train of rod-like elements;

[0033] FIG. 8 shows a cross-section C-C from FIG. 5 through the rod-like element and a suction nozzle;

[0034] FIG. 9 shows a cross-section B-B from FIG. 5 through the rod-like element in the train of rod-like elements;

[0035] FIG. 10 shows an embodiment of a cleaning element in a form of two compressed air nozzles;

[0036] FIG. 11 shows an embodiment in which the compressed air nozzle passes through the suction nozzle;

[0037] FIG. 12 shows a cross-section D-D from FIG. 5 through the rod-like element in the train of rod-like elements.

[0038] FIG. 13 shows a fragment of a machine for producing multi-segment filter rods in a top view.

DETAILED DESCRIPTION

[0039] FIGS. 1 and 2 show fragments of examples of continuous multi-segment rods CR1 and CR2 formed from trains of rod-like elements (segments) S1, S2 and SC respectively, prepared during production, formed by the unit according to the invention, wherein the segments are wrapped in a wrapper 101. The segments S1 and S2 have a solid shape, typically cylindrical, whereas the segment SC is formed from a loose material 102 which is located between the segments S1 and S1 or between the segments S1 and S2. The presented continuous rods are cut into multi-segment rods. FIG. 3 shows an example of a multi-segment rod R2 produced from the continuous multi-segment rod CR2.

[0040] FIG. 4 shows schematically a fragment of a machine for producing multi-segment filter rods. The machine comprises a feeding unit 1, which is configured to arrange the rod-like elements S1 and S2 as a train ST1, wherein the rod-like elements S1 and S2 are transported in a substantially preset spaced relationship. The rod-like elements S1 and S2 are fed onto a garniture belt 5. A wrapper, such as a wrapping paper, is fed on a transporter of the garniture belt 5 and the elements S1 and S2 are placed on the wrapper 101. Above the moving train ST1 there is located a filling unit 103 for supplying the loose material 102, for example activated charcoal, in order to form the segment SC. Lifted edges of the wrapper 101 and front surfaces of the elements S1 and S2 form compartments 105, into which the loose material 102 is fed from the filling unit 103. The train ST2 of the rod-like elements S1, S2 and SC that moves on the garniture belt 5 belt is wrapped in the wrapper 101 by a garniture unit 6, wherein the edges of the wrapper 101 are lifted on a distance where loose material is filled and cleaned. The garniture belt 5 typically forms a part of the garniture unit 6. Next to the filling unit 103 there is located a cleaning unit 104 for removing contamination of loose material from the rod-like elements i.e. particles of the loose material which fall onto the surface of the rod-like elements S1 and S2 in the preceding step, i.e. when the loose material is supplied from the filling unit 103. The produced continuous rod CR is transported further and, after the wrapper 101 is glued in the garniture unit 6, it is cut by a cutting head 8 into individual multi-segment rods R.

[0041] FIG. 5 shows an enlarged view of a fragment of a machine for producing filter rods. The train ST1 of rod-like elements S1, S2 passes through a filing zone Z1 for feeding the loose material, and next as a train ST2 of the rod-like elements comprising also the loose material, passes through a cleaning zone Z2 and through a garniture zone Z3 for forming a continuous filter rod.

[0042] FIG. 5 presents consecutive steps of a process of feeding the loose material 102 to the compartments 105 in the filling zone Z1, wherein the filling unit 103 for supplying the loose material may be constructed in a way as disclosed in the PCT application WO2016139198 (in the name of the present applicant) or according to other prior art embodiments, such as disclosed in U.S. Pat. Nos. 3,545,345, 3,623,404, DE1432720B2, EP0568278B1. FIG. 5 shows only examples of pockets 103A of the filling unit 103.

[0043] The cleaning unit 104, located next to the filling unit 103, is equipped with covering elements 10 mounted on a chain transporter 15, shown in FIG. 6, which is equipped with two chain wheels 16. The covering elements 10 may have a form of elements as disclosed in PCT application WO2016139198 (in the name of the present applicant). The covering elements 10 on a fragment of their moving trajectory move linearly in parallel to the displacement direction T, which is the direction of movement of the train ST1, ST2 of the rod-like elements, wherein additionally on a certain distance, they move vertically, transversally to the direction of displacement T in order to approach the compartment 105 filled with the loose material 102, which can be realized by means of a plain linear bearing, while the figure does not show a mechanism for realization of this movement. A downwards movement is indicated by an arrow F, an upwards movement is indicated by an arrow G, and a movement along the train ST2 is indicated by an arrow H. FIG. 7 shows the covering element 10 having a thin-walled covering part 10A, which covers the compartment 105.

[0044] In the presented solution, above the track of movement of the train ST2, there is located a cleaning element in the presented embodiment having a form of at least one brush 11, 11, for sweeping the contaminations, in a form of the loose material 102, away from the surface of segments S1, S2. Therefore, the brush 11, 11 is a contaminations sweeping element. As shown in FIG. 8 a cleaning part 11A (bristles) of the brush 11, 11 touches the side surface of the element S2 (in the presented step of movement of the covering element 10). The number of brushes 11, 11 in the cleaning zone Z2 may be provided according to the needs. Above the train ST1 of the segments, there is located a suction nozzle 12 which may have a plurality of openings or one longitudinal opening located in parallel to the train ST1 just above elements S1, S2 such that the covering parts 10A of the covering elements 10 can move below the nozzle 12, as shown in FIG. 9.

[0045] The cleaning element may also have a form of a compressed air nozzle, which removes contaminations of the side surface of the elements S1, S2, by blowing them out. FIG. 10 shows two compressed air nozzles 17 and 18, which are directed towards recesses formed by the side surfaces of the rod-like elements S1 and S2 and the wrapper 101. The compressed air nozzles 17 and 18 may be directed perpendicularly to the direction of movement of the rod-like elements, or at an angle a with respect to this direction as shown in FIG. 5, wherein preferably the angle a is in the range from 30 to 60, and for example is equal to 45. FIG. 11 shows another embodiment, wherein the compressed air nozzle 19 passes through the suction nozzle 12. Similarly the compressed air nozzle 19 is directed towards the recess between the element S1, S2 and the wrapper 101. Locating the outlet of the compressed air nozzle 19 within the inlet of the suction nozzle 12 (in principle within the inlet of the suction element) causes additional air turbulences, which enhance lifting of the contaminations from the surface of the rod-like elements S1, S2.

[0046] The cleaning element may have a form of an element made of soft plastic covering an edge for removing the contaminations. The plastic cleaning element may be fixed or may be rotatable.

[0047] The train ST2 leaving the cleaning zone Z2 is prepared for forming the continuous filter rod CR from the train, which is realized in the garniture zone Z3. In the garniture zone Z3 there is a glue nozzle 13 and guiding elements (not shown in the drawing for clarity, but known from the prior art) for bending the edges of the wrapper in order to join these edges and glue them in order to form a continuous filter rod.

[0048] Filling the chamber 105 with the loose material 102 from the pocket 103A may result in that not the whole amount of loose material is transferred to the chamber 105. A portion of particles, which have certain velocity, may rebound from the rod-like elements S1, S2 or from the wrapper 101, and subsequently fall onto the surface of the elements S1, S2, wherein the falling of the particles of the loose material 102 may occur in any location, for example just before gluing of the edges of the wrapper.

[0049] Cleaning the contaminations of the loose material in the cleaning unit 104 by means of the cleaning element 11, 11 and the suction nozzle 12 may result in removal of most of the contaminations. However, there is a risk that some contaminations are lifted above the elements S1, S2 but not received by the suction nozzle 12. Therefore, there is a risk that these contaminations will fall further away on the elements S1, S2 or will get in between the edges of the wrapper which will be glued together with the contamination between these surfaces. In order to eliminate the risk of uncontrollable displacement of the contaminations between the filling unit 103, the cleaning unit 104 and the garniture unit 6, partitions 14, 124, 34, 44, 54 are provided and arranged above the moving train of segments. Due to the fact that the zones of operation of the units may differ from the area occupied by the units themselves, the problem of contaminations displacement may be defined as uncontrollable displacement of the contaminations between the filling zone Z1, the cleaning zone Z2 and the garniture zone Z3 for forming the rod.

[0050] In the presented solution there is a significantly high risk of contaminations displacement between the cleaning zone Z2 and the garniture zone Z3, because not all particles of the loose material which are lifted by the cleaning element can be received by the suction nozzle 12. These particles may fall again on the rod-like elements S1, S2. The outlet partition 34, located on the side of the garniture zone Z3 (at the outlet from the cleaning zone Z2), is intended to limit the uncontrolled displacement of the particles of the loose material from the cleaning zone Z2 to the garniture zone Z3. The inlet partition 24 is located on the side of the filling zone Z1 (at the inlet to the cleaning zone Z2) and is intended to limit the uncontrolled displacement of the particles of the material from the filling zone Z1 to the cleaning zone Z2. The outlet partition 34 and the inlet partition 24 may be similar to each other. The outlet partition 34 and the inlet partition 24 may be formed as a single part or as multipart partitions. FIG. 7 shows an exemplary embodiment in which the inlet partition 24 is a two-part partition consisting of parts 24A and 24B. Between the parts 24A and 24B there is a passage 25, through which the covering elements 10 may pass. Similarly, FIG. 8 shows an embodiment in which the outlet partition 34 is also a two-part partition and consists of parts 34A and 34B. Between the parts 34A and 34B there is located a passage 35, through which the covering elements 10 may pass. In the embodiment shown in FIG. 5, the inlet partition 24 is located in front of the brush 11 and the outlet partition 34 is located behind the brush 11. In another embodiment, the brushes 11, 11 can be located in the passages 25, 35. As a result, the passage 25, 35 is effectively narrowed in such a way that there is only space for the passage of the covering element 10. The partitions 24, 34 may have surfaces arranged obliquely (at an acute angle) with respect to the direction of the movement T of the train ST2, owing to which particles of the contaminations may be rejected aside, outside the track of movement of the train of the rod-like elements. The partitions 24, 34 may be flat or arched shaped. In FIG. 13 the inlet partition 24 is flat and arranged askew while the outlet partition 34 is arched and arranged askew. The end partition 44 is located at the inlet to the garniture zone, just in front of the glue nozzle 13 in the region where the edges of the wrapper 101 are bent towards each other before gluing them. In the lower edge of the end partition 44 there is a notch 20 for receiving the edge of the wrapper 101, as shown in FIG. 12. In order to prevent the displacement of the contaminations to the garniture zone Z3 for forming the continuous filter rod CR there is provided a shield partition 54 (indicated by dashed line in FIG. 6), the main surface of which is located in parallel to the direction of the movement of the train ST2, i.e. horizontal. The shield layer 54 prevents the contaminations displacement to the segments S1, S2 just before the initialization of the process of wrapping the wrapper 101. The presented embodiment utilizes an initial partition 14 at the outlet of the filling zone Z1, between the filling zone Z2 and the cleaning zone Z2, which is intended to protect from the displacement of the contaminations outside the filling unit 103 in the direction of the cleaning unit 104.