RU2759456C2 - Device and feeding method intended for feeding spherical objects in tobacco industry equipment - Google Patents

Abstract

FIELD: tobacco industry.SUBSTANCE: feeding device for feeding spherical objects (3) for use in the tobacco industry is proposed, containing mass accumulation chamber (2, 2’) intended for storing set of spherical objects (3), and at least one single-layer chamber (10, 10’) located under mass accumulation chamber (2, 2’) and connected to mass accumulation chamber (2, 2’) so that spherical objects (3) can move from mass accumulation chamber (2, 2’) to single-layer chamber (10, 10’). Single-layer chamber (10, 10’) contains outlet (15) having set of outlet channels (16) for releasing spherical objects (3) into a receiving device. At least one roller (17, 18) is located next to outlet channel (16), while surface (17A, 18A) of the circumference of roller (17, 18) forms a wall of outlet channel (16). The feeding device additionally comprises cylindrical rotating element (9, 9’) located under mass accumulation chamber (2, 2’) in a junction area of mass accumulation chamber (2, 2’) and single-layer chamber (10, 10’), while side surface (9A) of cylindrical rotating element (9, 9’) forms a wall for directing the flow of spherical objects (3) from mass accumulation chamber (2, 2’) to single-layer chamber (10, 10’).EFFECT: in the proposed feeding device for feeding spherical objects, the movement of spherical objects between mass accumulation chamber (2, 2’) and single-layer chamber (10, 10’) is optimized.11 cl, 5 dwg

Description

TECHNICAL FIELD OF THE INVENTION

The present invention relates to a feeding device for feeding spherical objects used in the tobacco industry, and to a method for feeding spherical objects in equipment of the tobacco industry.

BACKGROUND OF THE INVENTION

The products of the tobacco industry may contain flavoring capsules. For example, the capsules can be placed in cigarette filters and smokers, before or during smoking, can crush the capsule with their fingers to release the flavor. The capsules can be placed in a filter material. Known cigarettes with two capsules placed in a mouthpiece in a filter material, and the two capsules can be crushed both separately and together at the same time. Known cigarette holders are made of two or more different filter segments, where the capsules can be placed in the space between the segments.

The capsules are delivered to a feeding device for feeding the capsules into the filter material, usually in a mass flow, i.e. they are poured into a bulk container. The capsules are transferred from the bulk container to a device that places them one after the other in the filter material. Capsules taken from a bulk container must be transferred to a device that handles individual capsules or a stream of individual capsules.

US Patent Application US2007068540A1 discloses a device in which capsules are received from a bulk container and transferred to a single layer chamber. From one layer of capsules, the capsules are received by means of the seats of the feed wheel, and the result is a stream of individual capsules moving in a circular path. From the feed wheel, the capsules are transferred onto a belt of filter material.

International patent application WO2005032286A2 discloses a device in which capsules are received from a rotating container by means of negative pressure and transferred into the seats of a feed wheel.

International patent application WO2011083405A1 discloses a device in which separate streams of capsules are formed from a rotating chamber of a mass accumulation, while the streams move in horizontal channels, and the channels rotate together with the chamber of a mass accumulation.

In US patent US7757835B2 a device is disclosed in which the flows of the capsules move at a certain angle.

Thus, there is a need for a device capable of efficiently transforming a mass of capsules into a single stream or multiple separate streams of capsules. In particular, there is a need to provide such a device that could be used to feed a device like that presented in US patent application US2013181003B2.

In the present disclosure, capsules are also referred to as spherical objects.

SUMMARY OF THE INVENTION

Disclosed is a feeding device for feeding spherical objects for use in the tobacco industry, comprising: a mass storage chamber for storing a plurality of spherical objects; at least one single-layer chamber located below the mass gathering chamber and connected to the mass gathering chamber so that spherical objects can move from the mass-gathering chamber to a single-layer chamber, wherein the single-layer chamber comprises an outlet having a plurality of outlet channels for discharging spherical objects into receiving device; at least one roller adjacent to the outlet, the circumferential surface of the roller defining the wall of the outlet. The feeding device additionally contains a cylindrical rotating element located under the mass accumulation chamber in the area of junction of the mass accumulation chamber and the single-layer chamber, while the lateral surface of the cylindrical rotating element forms a wall for directing the flow of spherical objects from the mass accumulation chamber to the single-layer chamber.

The cylindrical rotating element can be located tangentially to the wall of the bottom of the mass gathering chamber.

The cylindrical rotating element can be located tangentially to the single-layer chamber.

The single layer chamber can be positioned vertically.

The two rollers can be positioned at the outlet, whereby the circumferential surfaces of the rollers can be adapted to rotate in opposite directions during operation of the apparatus.

The circumferential surface of one roller can form the side wall of two adjacent outlet channels.

During operation of the device, the cylindrical rotating element can be adapted to rotate in the direction in which its contact surface with the spherical objects moves in the direction opposite to the direction of the flow of the spherical objects from the mass storage chamber to the single-layer chamber.

During operation of the device, the cylindrical rotating element can be adapted to rotate in the direction in which its contact surface with the spherical objects moves in the direction corresponding to the direction of flow of the spherical objects from the mass storage chamber to the single-layer chamber.

Also disclosed is a method of supplying spherical objects in tobacco industry equipment from a mass gathering chamber to outlet channels through a single-layer chamber located under the mass gathering chamber. The method includes rotating spherical objects supplied from the mass storage chamber to the single-layer chamber by means of a cylindrical rotating element located at the junction of the mass storage chamber and the single-layer chamber.

The method may include rotating the cylindrical rotating member in a direction in which its contact surface with the spherical objects moves in a direction opposite to the direction of the flow of the spherical objects from the mass cluster chamber to the single-layer chamber.

The method may include rotating the cylindrical rotating member in a direction in which its contact surface with the spherical objects moves in a direction corresponding to the direction of flow of the spherical objects from the mass cluster chamber to the single-layer chamber.

The method may include rotating spherical objects fed from the single layer chamber to the outlet channels by means of rollers located at the inlet of the outlet channels, with the roller circumference surfaces moving in opposite directions.

BRIEF DESCRIPTION OF DRAWINGS

The object of the present invention is presented by means of illustrative embodiments on the drawings, in which:

FIG. 1 shows a feeder for feeding spherical objects.

FIG. 2 is a side view of the device of FIG. 1 without side wall.

FIG. 3 and 4 show the outlet of the dispensing device of FIG. 1.

FIG. 5 shows a feeder with two single-layer chambers.

DETAILED DESCRIPTION OF THE INVENTION

The mass storage chamber 2 for capsules 3 in the feeding device 1 shown in FIG. 1 is in the form of a container open at the top and bottom and containing side walls 4, 5, a front wall 6 and an inclined bottom 7. The front wall 6 and the bottom 7 converge with each other to form an outlet 8 at the bottom 2A of the mass storage chamber 2. In other embodiments, the implementation of the chamber 2 of the mass gathering may also have other shapes.

The capsules 3 can be delivered to the bulk chamber 2 manually, by means of a container, or by means of a typical delivery unit such as a pneumatic delivery unit or a mechanical delivery unit with a capsule conveyor 3, the delivery unit not shown in the drawings.

A cylindrical rotating member 9 is disposed below the bottom 7 along the lower edge 7A of the bottom 7, a drive unit for rotating this member is not shown for clarity. In a preferred embodiment, the cylindrical rotating member rotates in the direction indicated by arrow 9R, which means that it rotates so that its contact surface with the capsules 3 moves in the opposite direction to the direction of the capsule flow from the bulk chamber 2 to the single layer chamber 10. The device also can operate when the cylindrical rotating element 9 rotates in the opposite direction, i.e. when it rotates so that its contact surface with the capsules 3 moves in the same direction as the direction of flow of the capsules from the chamber 2 of the mass accumulation into the single-layer chamber 10. The capsules 3 rotate due to the frictional force between the surface of the capsules 3 and the rotating side surface 9A. The rotation of the capsules 3 facilitates their downward movement, since it at least partially reduces the likelihood of situations in which non-rotating capsules can become blocked between the outlet 8 of the mass chamber and the front wall 11 of the single-layer chamber 10. The axis of rotation X of the cylindrical rotating element 9 is essentially parallel bottom edge 7A. Between the lower edge 7A and the lateral surface 9A of the cylindrical rotating element 9 there is a gap whose width is less than the diameter of the capsule 3. The cylindrical rotating element 9 can be positioned so that its lateral surface 9A is tangential to the inner surface 7B of the bottom 7 and forms a continuation of the bottom 7 The length of the cylindrical rotating member 9 is at least equal to the length of the edge 7A of the bottom 7. The length of the cylindrical rotating member 9 is substantially equal to the length of the outlet 8.

A single layer chamber 10 is attached to a mass cluster chamber 2. The front wall 11 of the single-layer chamber 10 forms a continuation of the front wall 6 of the chamber 2 of the mass accumulation, while the length of the single-layer chamber 10 is equal to the length of the outlet 8 of the chamber 2 of the mass accumulation. The other wall 12 of the single-layer chamber 10 is spaced from the front wall 11 by a distance slightly greater than the diameter of the capsule 3, thus allowing the capsules 3 to be subjected to gravity in the single-layer chamber 10. In the upper part 10A of the single-layer chamber 10, the inner wall surface 12A 12 is preferably tangential to the lateral surface 9A of the cylindrical rotating member 9. Preferably, the single layer chamber 10 is vertical, but it can also be tilted to slow the sliding of the capsules and improve the uniformity of the capsule flow. The side walls 13 and 14 of the single-layer chamber 10 are substantially parallel to each other and can also converge or diverge in a downward direction.

The lower part 10B of the single-layer chamber 10 has an outlet 15 in the form of a plurality of outlet channels 16. Two rollers 17, 18 are provided at the inlet 16E of the outlet 16, with the circumferential surfaces 17A, 18A forming the walls of the outlet 16. Inlet 16E the outlet 16 is defined by surfaces 17A, 18A and surfaces 11A and 12A of walls 11 and 12 (FIG. 2). The rollers 17, 18 are pivotally mounted, with the roller drive not shown for clarity. As shown in FIG. 1 and FIG. 3, the rollers 17, 18 rotate in the same directions 17R and 18R, so that the circumferential surfaces 17A, 18A move in opposite directions relative to the inlet 16E of the outlet 16. Therefore, when the capsules 3 are above the rollers 17, 18, some of them will are moved or pushed out by one of the rollers (the surface of the circumference of which moves in the direction of the inlet of the outlet) towards the inlet, and the rest of the capsules will be moved or pushed out by the second roller (the surface of the circumference of which moves in the direction opposite to the inlet of the outlet) in the opposite direction outlet - this prevents the capsules 3 from blocking and ensures good flow conditions for the capsules 3 from the single-layer chamber 10 to the outlet channels 16. Rollers from successive pairs of rollers 18 and 17 ', 17' and 18 ', 18' and 17 '', 17 ' 'and 18' 'rotate in a similar manner. The channels and rollers are arranged so that one roller 18, 17 ', 18', 17 '' interacts with two outlet channels 16, i.e. the circumferential surface of one roller forms the wall of one channel and an adjacent channel. Splitters 19 (shown in Fig. 4) may be located between the rollers of adjacent outlet channels to guide the capsules 3 towards specific outlet channels 16.

FIG. 5 shows another embodiment of the feeding device 1 'having twice the efficiency of the feeding device 1 shown in FIG. 1. The feeding device 1 'has a mass accumulation chamber 2' having side walls 4, 5, a front wall 6 and a rear wall 6 ', and a bottom 7' which contains two surfaces 7B and 7B '. The chamber 2 'of the mass gathering is connected to two single-layer chambers 10 and 10'. The first cylindrical rotating element 9 is located in the area of connection of the chamber 2 'of the mass accumulation with the single-layer chamber 10, and the second cylindrical rotating element 9' is located in the area of connection of the chamber 2 of the mass accumulation 'with the single-layer chamber 10'. The feeding device 1 ', viewed from above, occupies the same area as the feeding device 1 in FIG. 1, but it allows you to deliver twice as many capsules.

In yet another embodiment, a single cylindrical rotating member 9 may be used located at the junction of the mass chamber 2 'with the single-layer chamber 10, tangentially to surface 7B, and at the junction of the mass chamber 2' with the single-layer chamber 10 ', tangentially to surface 7B '.

Capsules 3, after pouring into the chamber 2, 2 'of the mass accumulation, fill the chamber, but only to a small extent move to the single-layer chamber 10, 10', since the high coefficient of friction between the capsules prevents their free flow into the single-layer chamber, leading to the fact that the capsules remain above the inlet to the single layer chamber, forming small arches. The beginning of rotation of the cylindrical rotating element 9, 9 ', while its lateral surface 9A forms a fragment of the bottom of the chamber of the mass accumulation, leads to the fact that the capsules begin to rotate relative to the cylindrical rotating element 9, 9' and relative to other capsules 3. This arrangement of the cylindrical the rotating element is preferred since the capsules do not have the ability to block each other at the inlet of the single layer chamber 10, 10 'during operation of the device.

The device according to the present document can be further expanded to obtain the desired number of outlet channels, depending on the efficiency of the receiving device. For example, one chamber of a mass gathering can be connected to several single-layer chambers. In addition, the single-layer chamber, together with the channel (or channels) and the rotating element (or rotating elements), can form a module that can be attached to improve the previously created device. In addition, when the single-layer chamber has a plurality of outlets, some of the outlets may be blocked so as to accommodate the efficiency of the delivery device to the reception efficiency of the cooperating devices.

Claims (17)

1. A feeder for feeding spherical objects (3) for use in the tobacco industry, comprising: - a chamber (2, 2 ') of a mass accumulation, designed to store a set of spherical objects (3); - at least one single-layer chamber (10, 10 ') located under the chamber (2, 2') of the mass accumulation and connected to the chamber (2, 2 ') of the mass accumulation so that spherical objects (3) can move out of the chamber ( 2, 2 ') mass accumulation into a single-layer chamber (10, 10'), while the single-layer chamber (10, 10 ') contains an outlet (15) having a plurality of outlet channels (16) for the release of spherical objects (3) into the receiving device; - at least one roller (17, 18) located adjacent to the outlet (16), whereby the circumferential surface (17A, 18A) of the roller (17, 18) forms the wall of the outlet (16); - a cylindrical rotating element (9, 9 ') located under the chamber (2, 2') of the mass accumulation in the area of the junction of the chamber (2, 2 ') of the mass accumulation and the single-layer chamber (10, 10'), while the side surface (9A ) of the cylindrical rotating element (9, 9 ') forms a wall for directing the flow of spherical objects (3) from the chamber (2, 2') of the mass accumulation into the single-layer chamber (10, 10 '); characterized in that - a cylindrical rotating element (9, 9 ') is located tangentially to the wall (7B, 7B') of the bottom (7, 7 ') of the chamber (2, 2') of the mass accumulation. 2. A device according to claim 1, characterized in that the cylindrical rotating element (9, 9 ') is located tangentially to the single-layer chamber (10, 10'). 3. A device according to claim 1 or 2, characterized in that the single-layer chamber (10, 10 ') is located vertically. 4. Device according to any one of paragraphs. 1-3, characterized in that two rollers (17, 18) are located at the outlet (16), while the circumferential surfaces of the rollers (17, 18) are adapted to rotate in opposite directions during operation of the device. 5. A device according to claim 4, characterized in that the circumferential surface (17A, 18A) of one roller (17, 18) forms the side wall of two adjacent outlet channels (16, 16 '). 6. The device according to any of the previous paragraphs, characterized in that during operation of the device, the cylindrical rotating element (9, 9 ') is adapted to rotate in the direction in which its contact surface with spherical objects (3) moves in the direction opposite to the direction of flow of the spherical objects (3) from the chamber (2) of the mass cluster to the single-layer chamber (10). 7. Device according to any one of paragraphs. 1-5, characterized in that during operation of the device, the cylindrical rotating element (9, 9 ') is adapted to rotate in the direction in which its contact surface with spherical objects (3) moves in the direction corresponding to the direction of flow of spherical objects (3) from chambers (2) of a mass accumulation into a single-layer chamber (10). 8. A method of feeding spherical objects in tobacco industry equipment from the chamber (2, 2 ') of the mass accumulation to the outlet channels (16) through a single-layer chamber (10, 10') located under the chamber (2, 2 ') of the mass accumulation, characterized in that that spherical objects (3) supplied from the chamber (2, 2 ') of a mass cluster to a single-layer chamber (10, 10') are brought into rotation by means of a cylindrical rotating element (9, 9 ') located under the chamber (2, 2 ') of the mass accumulation in the area of the junction of the chamber (2, 2') of the mass accumulation and the single-layer chamber (10, 10 '), while the cylindrical rotating element (9, 9') is located tangentially to the wall (7B, 7B ') of the bottom ( 7, 7 ') chambers (2, 2') of the mass cluster. 9. The method according to claim 8, characterized in that it comprises rotating the cylindrical rotating element (9, 9 ') in the direction in which its contact surface with the spherical objects (3) moves in the direction opposite to the direction of the flow of the spherical objects (3) from chambers (2) of a mass accumulation into a single-layer chamber (10, 10 '). 10. The method according to claim 8, characterized in that it comprises rotating the cylindrical rotating element (9, 9 ') in the direction in which its contact surface with the spherical objects (3) moves in the direction corresponding to the direction of the flow of the spherical objects (3) from chambers (2) of a mass accumulation into a single-layer chamber (10, 10 '). 11. The method according to any one of claims. 8-10, characterized in that it includes bringing into rotation the spherical objects (3) supplied from the single-layer chamber (10, 10 ') to the outlet channels (16) by means of the rollers (17, 18) located at the inlet of the outlet channels ( 16), while the surfaces of the circumference of the rollers (17, 18) move in opposite directions.

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