RU2599236C2 - Apparatus and method for introducing objects into smoking article - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: apparatus for introducing objects into a continuous flow of material comprises: a reservoir for providing objects; a rotating transfer wheel for transporting and delivering objects to an insertion unit for introducing object into a continuous flow of material; a transfer chamber for transferring objects to transfer wheel, transfer chamber being arranged between reservoir and transfer wheel. Rotating transfer wheel is provided with recesses where objects can be transferred and retained through application of suction until they are delivered to insertion unit.

EFFECT: rotating transfer wheel comprises a suction inlet arranged in centre of rotating transfer wheel so as to provide suction through centre of rotating wheel and comprises fluidic connections for providing fluidic communication between suction inlet and recesses.

20 cl, 8 dwg

Description

The present invention relates to a device and method for introducing objects into a continuous stream of material. For example, objects may be capsules that are to be introduced into a continuous stream of filter material in the manufacture of a filter component of a smoking article.

Smoking articles, such as cigarettes, are usually rod-shaped and include a column of smoking material, such as a tobacco bag. The tobacco bag is usually surrounded by a paper wrapper to form the so-called “tobacco rod”. In filter cigarettes, a cylindrical filter element is combined end-to-end with a tobacco rod. For example, the filter element may comprise cellulose acetate filter fiber material. The filter media may be wrapped with paper material known as ficella. The filter element is usually attached to one end of the tobacco rod using a wrapping material known as “mouthpiece paper”.

Various proposed methods for modifying the organoleptic characteristics of smoke include the introduction of additional elements into the filter as a means to add additional aroma to the mainstream smoke in a smoking article. For example, it was proposed in the manufacture of filter elements to introduce objects, such as capsules, into the filter material.

Various methods and devices have been proposed for incorporating such objects into the filter material in the manufacture of filter elements for smoking articles. One such device is described, for example, in WO-A-2010/055120. The device according to WO-A-2010/055120 has a reservoir containing objects. The tank enters the transfer chamber, in which objects circulate during operation. Objects circulating in the transmission chamber move along the peripheral surface of the rotatable transmission wheel. The transmission wheel has recesses (pockets) in its peripheral surface, and objects are inserted and held in the recesses by suction supplied to the recesses. When the transmission wheel rotates, objects are transported to the insertion site, where they will be released from the transmission wheel and introduced into the continuous stream of filter material.

There is a continuing need for mass production of filters, and the manufacture of such filters should be as efficient and reliable as possible. This means that there is a need for a device that reliably places an object in a filter element.

In accordance with the present invention, a device and method for introducing objects into a continuous stream of material. Moreover, in the following description, only embodiments are presented in which objects are inserted into the filter material, the invention also containing cases where the objects are inserted into other parts of the smoking article, for example, into a tobacco rod or into a filter cavity.

The device in accordance with the invention comprises a reservoir for accommodating a plurality of objects, a rotatable transmitting wheel for transporting objects, a unit for introducing objects into a continuous flow of material, and a transmitting chamber for transmitting objects to a rotatable transmitting wheel. The transfer chamber is located between the reservoir and the rotatable transfer wheel. The rotatable transmission wheel is provided with recesses in which objects can be transported and in which objects can be held by means of a suction application. The objects are held in the recesses until the objects are delivered from the rotary transmitting wheel to the site for introducing objects into the continuous flow of material. The rotatable transmission wheel comprises a suction inlet located in the center of the rotatable wheel in such a way as to provide suction through the center of the rotatable wheel. The rotatable transmission wheel further comprises fluid connections between the suction inlet and the recesses.

A “fluid communication connection” means any connection or part of a connection capable of transferring suction or overpressure from a suction port or center of a rotatable transmission wheel to recesses in the transmission wheel.

In accordance with the invention, an object refers to any single element that can be processed using the device and method in accordance with the invention. Preferably, the object is a substantially spherical object. Preferably, the substantially spherical object has a diameter of from about 0.5 mm to about 6.5 mm, more preferably the substantially spherical object has a diameter of from about 2.5 mm to about 4.0 mm. Preferably, the substantially spherical object is a capsule. Preferably, the capsule contains liquid. Preferably, the liquid contains a flavor, for example menthol. Preferably, the capsule is crushable, that is, so that the capsule can release its contents when sufficient crushing force is applied to it. When handling such objects, it is especially important to be careful not to release the liquid in capsules during the manufacturing process.

The location of the suction inlet in the center of the rotatable transmission wheel and the fluid communication connection between the suction inlet and the recesses makes it easy to apply suction in one place (in the centrally located suction inlet, at least along the axis of rotation rotatable transmitting wheel). The suction is then “distributed” by fluid communication connections to individual recesses of the rotatable transmission wheel. This is a simple and reliable solution from a structural point of view, in particular when compared with devices known from the prior art. As will become apparent from the embodiments described below, this constructive approach leads to the development of various embodiments, simple from a structural point of view. At the same time, these embodiments have high reliability, in particular at high speed of the transmission wheel, which makes the device according to the invention particularly efficient.

In one embodiment of the device according to the invention, the rotatable transmitting wheel comprises three adjacent discs. The first disk of three disks is a transmission disk containing recesses for receiving objects from a transmission camera. The second disk is a connecting disk containing at least a portion of fluid communication between the suction inlet and recesses. The third disc is a feed disc containing a suction inlet located in the center of the feed disc. The connecting disk is located between the feed disk and the transfer disk. The constructive approach containing the above three disks allows us to essentially separate the functions of an “external suction source in the center of the wheel”, “distribution of suction from the center of the wheel into separate recesses”, and “transportation of objects from the transfer chamber to the introduction site”. Such a separation of functions, as will become apparent in the future, provides further design options.

In one embodiment of the device according to the invention, the suction inlet comprises a receptacle for accommodating a connecting cylinder of the supply path. The connecting cylinder is provided with a bearing, for example a ball bearing or a plain bearing. The bearing allows the rotatable wheel to rotate around the connecting cylinder. This embodiment is an easy way to attach the suction feed line to the wheel. It is only necessary to connect the connecting cylinder to the feed disk. Then the entire rotatable wheel with the feed disk can rotate relative to the bearing, while the feed line is rigidly fixed in the socket.

In yet another embodiment of a device according to the invention, fluid communication connections further comprise transmission disk channels extending in the transmission disk. Each of the channels of the transmitting disk contains a corresponding radial section of the channel, extending essentially in the radial direction from the bottom of the corresponding recess to the corresponding radial innermost end. The corresponding transverse section of the channel extends from the corresponding radial innermost end of the radial section of the channel to the corresponding hole made in the surface of the transmitting disk facing the connecting disk. The corresponding hole and the corresponding cross section of the channel have a cross section that is larger than the cross section of the radial section of the channel. This provides a good “transfer” of suction to the bottom of the corresponding recess. Thus, this makes it possible to reliably suck objects into recesses and hold them in recesses during transportation to the place where the objects should be inserted into the flow of continuous material.

In one specific embodiment of such a device, the holes in the surface of the transmitting disk are located along the activation diameter. The connecting disk comprises a centrally located opening which is in fluid communication with the suction inlet of the feeding disk. The centrally located hole of the connecting disk has a diameter that is smaller than the activation diameter. Accordingly, there is no direct fluid communication between the centrally located opening of the connecting disk and the holes located on the surface of the transmitting disk. The connecting disk further comprises a plurality of connecting channels extending radially from the centrally located opening to at least the activation diameter. Connecting channels are in fluid communication with a circular activation channel. The activation channel is made on the surface of the connecting disk facing the transmitting disk. The activation channel has an open surface facing the transmitting disk. The transmitting disk forms a cover covering the open surface of the activation channel, with the exception of the locations of the holes, the activation channel being in fluid communication with the holes. Thus, the suction can be reliably transmitted from the suction port through the connecting channels to the activation channel and from the activation channel through the holes of the transmission disk and the transmission channels to the bottom of the recesses.

In one variation of this embodiment of the device, the connecting disk contains connecting channels in an amount that is less than the number of holes in the transmitting disk. The connecting channels are made in the surface of the connecting disk facing the feed disk. The connecting channels have an open surface facing the feed disk. The feed disk forms a cover covering the exposed surface of the connecting channels. There are through holes that extend from the connecting channels through the connecting disk to the peripheral activation channel to establish a fluid connection. As an example, the connecting channels extend from the central hole directly in the radial direction (star-shaped) to the activation diameter. Through holes can be made there that connect the connecting channels to the circumferential activation channel on the other side of the connecting disk. This is a simple constructive solution for “distributing” centrally supplied suction to individual openings and from there to the corresponding recesses in the transfer disk.

In an alternative embodiment of the device according to the invention, the holes in the surface of the transmission disk are also located along the activation diameter. The connecting disk comprises a centrally located opening which is in fluid communication with the suction inlet of the feeding disk. The centrally located hole has a diameter that is larger than the activation diameter. Accordingly, the centrally located opening of the connecting disk is directly in fluid communication with the openings of the transmission disk. The centrally located opening of the connecting disk is covered with a feeding disk on one side and a transmitting disk on the other side. This embodiment differs from the above embodiments, since it does not contain connecting channels. Instead, the centrally located opening is directly in fluid communication with the openings of the transmission disc in such a way as to directly transmit suction. Both the feed disk and the transfer disk cover the centrally located opening, so that suction can be reliably transmitted to the holes of the transfer disk. This is an alternative simple constructive solution for “distributing” centrally supplied suction to individual openings and from there to the corresponding recesses in the transfer disk.

Another embodiment of the device according to the invention further comprises means for creating a circulating movement of objects into the transmitting chamber along the circulation path. Part of the circulation path continues along the peripheral surface of the rotatable transmitting wheel in the direction of rotation of the rotatable transmitting wheel. The circulating movement of objects along the peripheral surface of the rotatable transmitting wheel (or the transmitting disk, respectively) helps to ensure that the object is transmitted to each of the recesses of the rotatable transmitting wheel so that there are no empty recesses. In addition, circulation of objects in the transmission chamber prevents clogging of the transmission chamber. Although the speed of the objects can generally vary over a wide range, it is preferable that the speed of the objects on this part of the circulation path extending along the peripheral surface of the rotatable transmission wheel be the same or substantially the same as the speed of the peripheral surface of the rotatable transmission wheel. For example, the speed of objects may differ from the peripheral surface speed of a rotatable transmitting wheel in a range from about 25 percent slower to about 25 percent faster than the peripheral surface speed of a rotatable transmitting wheel. More preferably, the speed of the objects can differ from the peripheral surface speed of the rotatable transmitting wheel in a range from about 10 percent slower to about 10 percent faster than the speed of the peripheral surface of the rotary transmitting wheel (including the case where the speed of the objects and the speed of the peripheral surface of the rotary transmitting the wheels are essentially identical). Usually, when the term “approximately” is used in connection with a specific meaning, it is always implied that it includes the exact meaning.

Another embodiment of the device according to the invention further comprises a return element. The return element is located in the transmitting chamber on a curved portion of the side wall of the transmitting chamber. The curved section of the side wall and the return element are located at the end of that part of the circulation path that extends along the peripheral surface of the rotatable transmission wheel. In particular, the return element is designed so that the return element and the curved portion of the side wall are changed to the opposite direction of movement of objects in the transmitting chamber. Thus, the return element further improves the circulating movement of objects in the transmission chamber.

In one embodiment of such a device, the return element has a teardrop shape. The teardrop-shaped return element comprises a vertex, two substantially straight lateral surfaces and a curved portion connecting the lateral surfaces. The vertex is facing inside the transmitting chamber. It faces the inside of the transfer chamber in such a way that the side surface of the teardrop-shaped element facing the peripheral surface of the rotatable transfer wheel extends substantially tangentially to the side surface of the rotatable transfer wheel. This can further improve the circulating movement of objects in the transmission chamber. The term “substantially straight side surfaces” encompasses straight side surfaces as well as side surfaces that are slightly curved. The substantially straight side surface facing the transmission wheel preferably has a concave curvature. Preferably, the curvature of the side surface substantially matches the curvature of the transmission wheel, i.e., the curvature of the side surface is concentric with the transmission wheel.

In particular, the straight lateral surface can be designed so that the space between the straight lateral surface and the peripheral surface of the rotatable transmitting wheel will narrow towards the end of that part of the circulation path that extends along the peripheral surface of the rotatable transmitting wheel. This can further facilitate the introduction of objects into the recesses (pockets) of the transmission wheel. However, the space should be narrowed only to such an extent that the objects are not damaged or broken. It is preferred that the constriction be less than about a quarter of the diameter of the capsule.

In yet another embodiment of the device according to the invention, a substantially straight side surface facing the peripheral surface of the rotatable transmitting wheel is located at a predetermined distance from the side surface of the rotatable transmitting wheel. This predetermined distance is selected so that a layer of one to six objects is formed between the substantially lateral surface and the peripheral surface of the rotatable transmission wheel. In particular, the predetermined distance is selected so that a layer of two to four objects is formed between the substantially lateral surface and the peripheral surface of the rotatable transmission wheel. Preferably, the layer has a depth of one object, while the objects overlap each other in the transmission zone.

This option is preferred due to the fact that it further facilitates the introduction of objects into the recesses on the lateral surface of the rotatable transmission wheel, while the object is held in each recess when the corresponding chamber of the rotary transmission wheel leaves the zone of the transmission chamber.

In yet another embodiment of the device according to the invention, the means for creating a circulating movement of objects in the transmission chamber comprises nozzles. These nozzles are located at the end of that part of the circulation path that extends along the peripheral surface of the rotatable transmission wheel. Nozzles are able to create air currents. These air flows, together with either a curved section of the side wall of the transmission chamber, or with a return element, or together with both a curved section of the side wall and the return element, reverse the direction of movement of objects in the transmission chamber. The nozzles further enhance the circulating movement of objects in the transmission chamber.

Another object of the present invention relates to a method for introducing objects into a continuous stream of material. The method includes the steps of:

- providing a reservoir containing a plurality of objects;

- introducing objects from the reservoir into the transmitting chamber located between the reservoir and the rotatable transmitting wheel, while the rotatable transmitting wheel has recesses;

- applying a suction force to the recesses of the rotatable transmitting wheel, while transmitting objects from the transmitting chamber to the recesses of the rotatable transmitting wheel and holding the objects in the recesses;

- transportation of objects held in recesses to the place of introduction, in which the objects are to be introduced into a continuous flow of material; as well as

- introducing objects into a continuous stream of material at the injection site.

The step of applying a suction force to the recesses of the rotatable transfer wheel is by supplying suction through the center of the rotatable transfer wheel through the suction inlet located in the center of the rotatable transfer wheel, and also through fluid communication connections to establish a fluid communication between the suction inlet and recesses.

An embodiment of the method in accordance with the invention further comprises the steps of:

-creation of a circulating movement of objects in the transmission chamber, while on the peripheral surface of the rotatable transmitting wheel, objects move along the circulation path, which continues in the direction of rotation of the rotatable transmitting wheel;

- in the transmission chamber, at the end of the path of circulation of objects along the peripheral surface of the rotatable transmission wheel, providing a return element in order to reverse the direction of movement of objects in the transmission chamber, the return element having a drop-shaped shape containing a vertex, two straight side surfaces and a curved section, connecting the straight side surfaces with the apex, the apex facing the inside of the transmitting chamber so that the lateral surface of the teardrop-shaped element facing the lateral the surface of the rotatable transmitting wheel extends essentially tangentially to the lateral surface of the rotatable transmitting wheel.

The advantages of the process embodiments are identical to those already mentioned above of the corresponding embodiments of the device according to the present invention.

Other preferred objects will become apparent from the following description of embodiments of the device and method according to the invention using the drawings, in which:

Figure 1 shows a perspective view of an embodiment of the main components of the device according to the invention;

Figure 2 shows a view of the front panel of the device of Figure 1, while some additional details are presented,

Figure 3 shows an enlarged cross-sectional view of a central portion of an embodiment of a rotatable transmission wheel comprising a feed disk, a connecting disk, and a transmission disk with a connecting cylinder of a central feeding path connected to a socket of the feeding disk;

Figure 4 shows a view with a spatial separation of the details of the embodiment of the rotatable transmitting wheel, which presents some details of the transmitting disk and the connecting disk;

5 shows a first embodiment of a connecting disk of a rotatable transmission wheel in front of the transmission disk;

Figure 6 shows a second embodiment of a connecting disk of a rotatable transmission wheel in front of the transmission disk;

7 shows a third embodiment of a connecting disk of a rotatable transmitting wheel in front of the transmitting disk; and

On Fig shows a detail of the transmitting chamber with a return element located therein, which serves to reverse the flow of objects through the transmitting chamber.

Figure 1 presents a perspective view of an embodiment of the main components of the device in accordance with the invention, shown in the assembled state, and Figure 2 shows a front view of this embodiment, revealing some additional details. As can be seen from figure 1 and figure 2, the device contains a reservoir 1, in which there are objects, such as capsules or balls, to be introduced into a continuous stream of material. The opaque front panel 10 of the tank 1 can be seen in FIG. 1, while in FIG. 2 the front panel 10 is transparent, so that additional details of the device are visible.

As can be seen in FIG. 2, the device further comprises a transmitting chamber 2, which is located between the reservoir 1 and the rotatable transmitting wheel 3. The return element 20 having a teardrop shape is located in the transmitting chamber 2. The return element 20 helps to reverse the movement of the capsules around the periphery of the rotatable transmission wheel 3 in the transmission chamber 20, as will be described in more detail below.

Several nozzles 100 are located in the front wall 10. Overpressure or suction can be applied with the nozzles 100 to create a circulating movement of the capsules in the transfer chamber 2, as shown in FIG. 2 by the arrows in the transfer chamber 2, as well as to facilitate movement capsules to a rotatable transmission wheel. A transfer chamber 2 is formed between the rear wall 11 and the front wall 10. The depth of the transfer chamber 2 between the front wall 10 and the rear wall 11 is such that only one layer of capsules can be formed. As an example, the depth (“thickness”) of the transfer chamber 2 may range from about 110 percent to about 120 percent of the outer dimensions of the capsules or balls. In the rear wall 11, additional nozzles (not shown) can be arranged, occupying a position similar to the position of the nozzles 100 in the front wall 10. Through these additional nozzles, excess pressure or suction can be applied in the same way as through the nozzles 100 to create a circulating the movement of the capsules in the transfer chamber 2, as well as to help the movement of the capsules to the peripheral surface of the rotatable transmitting wheel 3. During the movement of the capsules in the direction and on the peripheral surface of the rotatable transmitting wheel and 3 capsules are sucked into recesses punched into the peripheral surface of the rotatable transfer wheel 3 (recesses are not visible in Figures 1 and 2). This is done by applying suction through the bottom of the individual recesses in order to suck one capsule into each recess where the capsule is held until the capsule is introduced into a continuous stream of material, for example, into a filter tow. This capsule injection is performed by a device for introducing capsules into a continuous stream of material. A device for introducing capsules into a filter tow is not shown in the drawings and may be a conventional device well known in the art. For example, a suitable device for introducing capsules into a continuous stream of filter tow is shown in FIGS. 10-12 of WO 2010/055120 and is described in detail in the corresponding part of its description. Accordingly, the description associated with this device for introducing capsules into a continuous stream of filter material is incorporated herein by reference. As can be seen in WO 201/055120, the capsules are introduced into the continuous flow of the filter tow when the corresponding recess of the rotatable transmission wheel is in its lowest position.

Figure 3 shows an enlarged cross-sectional view of a central portion of an embodiment of a rotatable transmitting wheel 3. The rotatable transmitting wheel 3 comprises a feed disk 30, a connecting disk 31 and a transmission disk 32. The connecting cylinder 40 of the central feeding path 4 is connected to the socket 300 of the feeding disk 30 Socket 300 forms a suction inlet and is adapted to accommodate a connecting cylinder 40. The connecting cylinder 40 is provided with a ball bearing 400. The ball bearing 400 allows the rotatable the transmission wheel 3 rotate relative to the connecting cylinder 40 with the central suction supply to the rotary wheel 3 through the supply path 4. The sealing ring 301 is located in the groove 302 made in the disk 30 to surround the innermost end of the connecting cylinder 40, so that the suction supplied through the path 4 and through the connecting cylinder 40, acts through the Central hole 310, made in the connecting disk 31. The connecting disk 31 “distributes” the suction radially outward to the channels of the transmitting ska done in the transfer disk 32. These channels of the transfer disk lead to the bottom of the corresponding recesses in which the balls are held.

FIG. 4 shows a schematic exploded view of an embodiment of a rotatable transmission wheel 3 comprising a feed disk 30, a connecting disk 31 and a transmission disk 32. While the feeding disk 30 is shown only schematically, FIG. 4 shows some details of the connecting the disk 31 and the transfer disk 32. In particular, in FIG. 4, the transfer disk 32 contains recesses 320 into which the capsules are sucked from the transfer chamber 2. The capsules are held in the recesses 320 when they are transported to the cc device feeding capsules into a continuous stream of filter tow. From the bottom of the corresponding recess 320 extends the channel 321 of the transmitting disk. The transmission disk channel 321 comprises a radial channel portion 322 that extends in a radial direction toward the innermost end. From this innermost end of the radial channel portion 322, the transverse channel portion 323 extends to an opening 324 made in a surface 325 of the transmission disk 32 facing the connecting disk 31. The holes 324 are arranged circularly on the activation diameter 326.

In the following, additional details in FIG. 4 will be explained with reference to an embodiment of the connecting disk 31 shown in FIG. 5. The connecting disk 31 contains centrally located holes 310 (see FIG. 5) having an inner diameter 311 (see also FIG. 5), which is smaller than the activation diameter 326. Accordingly, the centrally located opening 310 is not directly in fluid communication with the opening 324 of the transmission disc 32. The plurality of connecting channels 312 extend radially outward from the centrally located opening 310 (see FIG. 5) to the activation diameter 326 (see FIG. 4) or slightly further outward of diameter 326 activation. The connecting channels 312 are made on the surface of the connecting disk 31 facing the feeding disk 30. The connecting channels 312 have an open surface facing the feeding disk 30. When mounting, the feeding disk 30 covers the connecting channels 312 and closes the open surface 312 of the connecting channels so as to form essentially fluid tight channels.

On the surface facing the transmitting disk 32, the connecting disk 31 contains a peripheral activation channel 314. The activation channel 314 is located on the activation diameter 326 and has an open surface facing the transmitting disk 32. The activation channel 314 made on the surface facing the transmitting disk 32, as well as the connecting channels 312 made on the surface facing the feeding disk 30, are connected with through holes 313. During installation, the transmitting disk 32 covers the open surface of the circumferential activation channel 314 with the exception of the locations of the holes 324.

Thus, the fluid connection between the suction inlet and the recesses 320 is through a centrally located opening 310, connecting channels 312, through holes 313, activation channel 314, openings 324 and transmission channel 321.

FIG. 6 shows a second embodiment of the connecting disk 34. This embodiment of the connecting disk 34 is somewhat similar to the embodiment of the connecting disk 31 shown in FIG. The connecting disk 34 has a centrally located hole 340, the inner diameter of 341 of which is smaller than the diameter of the activation 326 (see Figure 4). The connecting disk 34 contains connecting channels 342, which are wider than the connecting channels 312 of the disk 31. The connecting channels 342 also have an open surface facing the feed disk 30 (not shown in FIG. 6). During installation, the supply disk 30 covers the channels 342 and closes the open surface of the connecting channel 342, so that essentially fluid tight channels are formed. Through holes 343 are designed to connect the connecting channels 342 and the activation channel. The activation channel is not shown in Fig.6, but it is made as shown in Fig.4. Some of the openings 324 of the transmitting disk 32 are visible through the through holes 343 of the connecting disk 34. The suction is transmitted in the same manner as in the embodiment shown in FIG. 5 and described above with respect to FIG. 4 and FIG. 5, therefore, here it is again not described.

FIG. 7 shows a third embodiment of the connecting disk 35. In this embodiment of the connecting disk 35, the centrally located hole 350 has an inner diameter that is larger than the activation diameter 326 (see FIG. 4). Accordingly, in this embodiment of the connecting disk 35, there are no connecting channels. 7, the openings 324 of the transmission disk 32 are visible. During installation, the centrally located opening 350 is covered on one side by the supply disk 30 and on the other hand by the transmission disk 32, which is substantially leakproof. Thus, the suction supplied through the centrally located opening 350 is directly transmitted to the openings 324 and from there through the transmission channels 321 to the recesses 320 (see also FIG. 4).

Fig. 8 is a detail of the transfer chamber 2, showing the return element 20 in more detail. The return element 20 is located in the transfer chamber 2 at the end of that part of the capsule circulation path that extends along the peripheral surface of the rotatable transfer wheel 3. The return element 20 has a teardrop shape, comprising a vertex 200, two side surfaces 201, and a curved portion 202 connecting the two side surfaces 201. The top 200 faces the inside of the transfer chamber 2. This side surface 201, which faces the peripheral the surface of the rotatable transmitting wheel 3 extends essentially tangentially to the circumferential surface of the transmitting wheel 3 so as to allow the capsules to flow around the return element 20. Thus, the return element 20 contributes to reversing the direction of movement of the capsules in the transfer chamber 2.

The lateral surface 201 of the return member 20 facing the peripheral surface of the rotatable transmitting wheel 3 is located at a predetermined distance 204 from the peripheral surface of the rotatable transmitting wheel 3. The predetermined distance 204 is selected so that between the lateral surface 201 and the peripheral surface of the rotatable transmitting wheel 3 can be formed a layer of one to six capsules. In particular, a predetermined distance 204 may be selected so that a layer of two to four capsules forms between the side surface 201 and the peripheral surface of the rotatable transmission wheel 3. You can also see that the return element 20 can be made in such a way that the space between the side surface 201 and the peripheral surface of the rotatable transmission wheel 3 is slightly narrowed. The space narrows toward the end of that part of the circulation path that extends along the peripheral surface of the rotatable transmission wheel 3. This may cause slight pressure on the capsules as they move along the circulation path. This slight pressure can facilitate the insertion of the capsule into the recesses 320 of the rotatable transmission wheel 3. Nevertheless, the constriction must be chosen so that the small "pressure" produced due to the constriction cannot damage or break the capsules or balls.

In addition, at the end of the capsule circulation path, one or more nozzles 203 can be located on the peripheral surface of the rotatable transmitting wheel 3 (or the transfer disk 32, respectively). The nozzles 203 are capable of transmitting air flows reversing the movement of the capsules in the transfer chamber 2 together either with a curved side wall of the transfer chamber 2, or together with a return element 20, or together with both a curved side wall and a return element 20, as shown by the arrows depicted in Fig. 8.

During operation, the tank 1 is filled with capsules, which fall under the influence of gravity into the transmitting chamber 2 in the lower part of the tank 1 (see Figure 1). A circulating movement of the capsules is generated in the transfer chamber 2, as shown by the arrows in FIG. 2. Capsules move along the peripheral surface of the rotatable transmitting wheel 3. Each of the recesses 320 is filled with a capsule due to the suction applied to the bottom of the corresponding recess 320. Those capsules that have not been sucked into the recess 320 are returned along the circulation path shown by arrows in FIG. 2 using the return element 20 and the nozzle 203. Those capsules that are sucked into the recess 320 are transported by a rotatable transmitting wheel 3 to a device for introducing encapsulated balls into a continuous stream of filter material. In this position, the capsules are released from the recesses 320 and introduced into the filter material, as described in detail in WO-A-2010/055120. With further rotation of the rotatable transmitting wheel 3, the empty recess 320 again reaches the zone of the transfer chamber 2, where again the capsule is sucked into the recess 320, as described above.

Capsules move along the peripheral surface of the rotatable transmitting wheel 3 at a speed that is identical or substantially identical to the speed of the peripheral surface of the rotatable transmitting wheel 3. In particular, the speed of the capsule along the peripheral surface of the rotatable transmitting wheel 3 is in the range from 25 percent slower to 25 percent faster than the speed of the peripheral surface of the rotatable transmitting wheel 3. More preferably, the speed of the capsule is in the range of 10 percent slow less than 10 percent faster than the speed of the peripheral surface of the rotatable transmitting wheel 3. The speed of movement of the capsules, which is identical or substantially identical to the speed of the peripheral surface of the rotatable transmitting wheel 3, is preferred since it further improves the transfer of the capsule from the transfer chamber 2 to the recesses 320 rotatable transmitting wheel 3 due to the significant synchronization of the speed of the capsule and the speed of the transmitting wheel.

Claims (20)

1. A device for introducing objects into a continuous stream of material, containing:
- reservoir (1) for a variety of objects;
- a rotatable transmitting wheel (3) for transporting objects to a site for introducing objects into a continuous flow of material;
- a transmitting chamber (2) for transmitting objects to a rotatable transmitting wheel (3), while the transmitting chamber (2) is located between the reservoir (1) and the rotatable transmitting wheel (3),
wherein the rotatable transmitting wheel (3) is provided with recesses (320) into which objects can be transferred, and in which objects can be held by means of a suction application until objects are delivered from the rotatable transmitting wheel (3) to the unit for introducing objects into a continuous stream material
wherein the rotatable transmitting wheel (3) comprises a suction inlet located at the center of the rotatable transmitting wheel (3) so as to provide suction through the center of the rotatable transmitting wheel (3), and also contains fluid communication between the suction inlet and recesses (320),
and while the transmitting wheel (3) contains three adjacent discs (30, 31, 32; 34, 35), while the transmitting disc (32) contains recesses (320) for receiving objects from the transmitting chamber (2), a connecting disk ( 31, 34, 35) contains at least a portion of fluid communication between the suction inlet and recesses (320), and the supply disk (30) comprises a suction inlet located in the center of the supply disk (30), a connecting disk (31, 34, 35) is located between the feeding disk (30) and the transmitting disk (32). 2. The device according to claim 1, in which the suction inlet contains a socket (300) for receiving a connecting cylinder (40) of the inlet path (4) therein, while the connecting cylinder (40) is provided with a bearing (400) that allows the rotatable wheel (3, 30,31,32; 34,35) rotate around the connecting cylinder (40). 3. The device according to claim 1, in which the connection for fluid communication further comprises channels (321) of the transmitting disk, continuing in the transmitting disk (32), each of the channels (321) of the transmitting disk contains a corresponding radial section (322) channel extending radially inward from the bottom of the corresponding recess (320) in the direction of the corresponding radial innermost end and the corresponding transverse section (323) of the channel extending from the corresponding radial innermost end the channel portion (322) to the corresponding hole (324) made on the surface (325) of the transmission disk (32) facing the connecting disk (31, 34, 35), the corresponding hole (324) and the corresponding transverse section (323) channels have a cross section that is larger than the cross section of the radial section (322) of the channel. 4. The device according to p. 2, in which the connection for fluid communication further comprises channels (321) of the transmitting disk, continuing in the transmitting disk (32), each of the channels (321) of the transmitting disk contains a corresponding radial section (322) channel extending radially inward from the bottom of the corresponding recess (320) in the direction of the corresponding radial innermost end and the corresponding transverse section (323) of the channel extending from the corresponding radial innermost end the channel portion (322) to the corresponding hole (324) made on the surface (325) of the transmission disk (32) facing the connecting disk (31, 34, 35), the corresponding hole (324) and the corresponding transverse section (323) channels have a cross section that is larger than the cross section of the radial section (322) of the channel. 5. The device according to claim 3, in which the holes (324) in the surface (325) of the transmitting disk (32) are located on the activation diameter (326), while the connecting disk (31, 34) contains a centrally located hole (310, 340) in fluid communication with the suction inlet of the feed disk (30), the centrally located hole (310, 340) of the connecting disk (31; 34) has a diameter (311, 341) that is smaller than the activation diameter (326), wherein the connecting disk (31, 34) further comprises a plurality of connecting channels (312, 342), creeping radially outward from the centrally located opening (310, 340) to the activation diameter and in fluid communication with the circumferential activation channel (314), the activation channel (314) located along the activation diameter on the surface of the connecting disk facing the transmitting disk ( 32), and the activation channel (314) has an open surface facing the transmitting disk (32), while the transmitting disk (32) forms a lid covering the open surface of the activation channel (314), except for the locations of the holes (324), in which the activation channel (314) is in fluid communication with the openings (324). 6. The device according to claim 4, in which the holes (324) in the surface (325) of the transmitting disk (32) are located on the activation diameter (326), while the connecting disk (31, 34) contains a centrally located hole (310, 340) in fluid communication with the suction inlet of the feed disk (30), the centrally located hole (310, 340) of the connecting disk (31; 34) has a diameter (311, 341) that is smaller than the activation diameter (326), wherein the connecting disk (31, 34) further comprises a plurality of connecting channels (312, 342), creeping radially outward from the centrally located opening (310, 340) to the activation diameter and in fluid communication with the circumferential activation channel (314), the activation channel (314) located along the activation diameter on the surface of the connecting disk facing the transmitting disk ( 32), and the activation channel (314) has an open surface facing the transmitting disk (32), while the transmitting disk (32) forms a lid covering the open surface of the activation channel (314), except for the locations of the holes (324), in which the activation channel (314) is in fluid communication with the openings (324). 7. The device according to claim 5, in which the connecting disk (31, 34) contains connecting channels (312, 342), the number of which is less than the number of holes (324) in the transmitting disk (32), and the connecting channels (312, 342) are made in the surface of the connecting disk (31, 34) facing the feeding disk (30), while the connecting channels (312, 342) have an open surface facing the feeding disk (30), and the feeding disk (30) forms a cover covering the open the surface of the connecting channels (312, 342), while through holes were made (313, 343), sold zhayuschiesya from the connecting channels (312, 342) through a connecting disk (31, 34) in the circular channel (314) activated for establishing fluid communication connecting channels (312, 342) with a circumferential channel (314) activation. 8. The device according to claim 6, in which the connecting disk (31, 34) contains connecting channels (312, 342), the number of which is less than the number of holes (324) in the transmitting disk (32), and the connecting channels (312, 342) are made in the surface of the connecting disk (31, 34) facing the feeding disk (30), while the connecting channels (312, 342) have an open surface facing the feeding disk (30), and the feeding disk (30) forms a cover covering the open the surface of the connecting channels (312, 342), while through
openings (313, 343) extending from the connecting channels (312, 342) through the connecting disk (31, 34) into the peripheral activation channel (314) to establish fluid communication of the connecting channels (312, 342) with the peripheral channel (314) activation. 9. The device according to claim 3, in which the holes (324) in the surface of the transmitting disk (32) are located along the activation diameter (326), while the connecting disk (35) contains a centrally located hole (350), which is in fluid communication with the suction inlet of the feed disk (30), the centrally located hole (350) having a diameter (351) that is larger than the activation diameter, the centrally located hole (350) of the connecting disk (35) directly communicating with the hole (324) ) of the transmitting disk (32), at this centrally located hole (350) of the connecting disk (35) is covered with a feed disk (30) on the one hand and a transfer disk (32) on the other hand. 10. The device according to claim 4, in which the holes (324) in the surface of the transmitting disk (32) are located along the diameter (326) of activation, while the connecting disk (35) contains a centrally located hole (350), which is in fluid communication with the suction inlet of the feed disk (30), the centrally located hole (350) having a diameter (351) that is larger than the activation diameter, the centrally located hole (350) of the connecting disk (35) directly communicating with the hole (324) ) transfer disk (32), pr This centrally disposed bore (350) of the coupling disk (35) is covered with the feeding disk (30) on one side and the transmission disk (32) on the other side. 11. The device according to any one of paragraphs. 1-10, additionally containing means for creating a circulating movement of objects in the transmission chamber (2) along the circulation path, while part of the circulation path continues along the peripheral surface of the rotatable transmission wheel (3) in the direction of rotation of the rotatable transmission wheel (3). 12. The device according to claim 11, further comprising a return element (20), which is located in the transfer chamber (2) on the curved section of the side wall of the transfer chamber (2), while the curved section of the side wall and the return element (20) are located at the end that part of the circulation path that extends along the peripheral surface of the rotatable transmission wheel (3) so that the return element (20) and the curved section of the side wall reverse the direction of movement of objects in the transmission chamber (2). 13. The device according to p. 12, in which the return element (20) has a teardrop-shaped shape containing a vertex (200), two essentially straight lateral surfaces (201), as well as a curved section (202) connecting essentially straight lateral surfaces (201) with a vertex, with the apex (200) facing the inside of the transmitting chamber (2) so that the lateral surface (201) of the teardrop-shaped element facing the lateral surface of the rotatable transmitting wheel (3) continues substantially tangentially to the lateral surfaces of a rotatable transmission wheel (3). 14. The device according to claim 13, in which the straight side surface (201) facing the peripheral surface of the rotatable transmitting wheel (203) is located at a predetermined distance (204) from the peripheral surface of the rotatable transmitting wheel (3), while the specified distance ( 204) is chosen in such a way that a layer of one to six objects, in particular a layer of two to four objects, is formed between the side surface (201) and the peripheral surface of the rotatable transmission wheel (3). 15. The device according to claim 1, in which the means for creating a circulating movement of the object in the transmission chamber (2) contains nozzles (203) located at the end of that part of the circulation path that continues along the peripheral surface of the rotatable transmission wheel (3), wherein nozzles (203) are able to create air currents, which together with a curved section of the side wall of the transfer chamber (2), or with a return element (20), or together with a curved section of the side wall of the transfer chamber (2), and with the return element ( 20), reverb The direction of movement of objects in the transmitting chamber (2). 16. The device according to p. 12, in which the means for creating a circulating movement of the object in the transmission chamber (2) contain nozzles (203) located at the end of that part of the circulation path that continues along the peripheral surface of the rotatable transmission wheel (3), while nozzles (203) are able to create air currents, which together with a curved section of the side wall of the transfer chamber (2), or with a return element (20), or together with a curved section of the side wall of the transfer chamber (2), and with the return element ( 20), roar siruyut direction of movement of objects in the transmission chamber (2). 17. The device according to claim 13, in which the means for creating a circulating movement of the object in the transmission chamber (2) contains nozzles (203) located at the end of that part of the circulation path that continues along the peripheral surface of the rotatable transmission wheel (3), wherein nozzles (203) are able to create air currents, which together with a curved section of the side wall of the transfer chamber (2), or with a return element (20), or together with a curved section of the side wall of the transfer chamber (2), and with the return element ( 20), roar siruyut direction of movement of objects in the transmission chamber (2). 18. The device according to claim 14, in which the means for creating a circulating movement of the object in the transmission chamber (2) comprise nozzles (203) located at the end of that part of the circulation path that continues along the peripheral surface of the rotatable transmission wheel (3), wherein nozzles (203) are able to create air currents, which together with a curved section of the side wall of the transfer chamber (2), or with a return element (20), or together with a curved section of the side wall of the transfer chamber (2), and with the return element ( 20), roar siruyut direction of movement of objects in the transmission chamber (2). 19. A method of introducing objects into a continuous stream of material, comprising the steps of:
providing a reservoir (1) containing a plurality of objects;
introducing objects from the reservoir (1) into the transmitting chamber (2) located between the reservoir (1) and the rotatable transmitting wheel (3), while the rotatable transmitting wheel (3) has recesses (320);
applying a suction force to the recesses (320) of the rotatable transmitting wheel (3) while transmitting objects from the transmitting chamber (2) to the recesses (320) of the rotatable transmitting wheel (3) and holding the objects in the recesses (320);
transporting objects held in recesses (320) to an injection site where objects are to be introduced into a continuous stream of material;
introducing objects into the continuous flow of material at the injection site, while applying a suction force to the recesses (320) of the rotatable transmitting wheel (3) by applying suction through the center of the rotatable transmitting wheel (3) through the suction inlet located in the center of the rotatable transmitting wheel ( 3), and through fluid communication connections between the suction inlet and the recesses (320),
moreover, the stage of providing the transmitting wheel further includes providing three adjacent disks (30,31,32; 34,35), the transmitting disk (32) containing the recesses (320) for receiving objects from the transmitting chamber (2), the connecting disk (31, 34, 35) containing at least a portion of fluid communication between the suction inlet and recesses (320), and the supply disk (30) containing the suction inlet located in the center of the supply disk (30), the connecting disk (31, 34, 35) is located I am waiting for the feed disk (30) and the transfer disk (32). 20. The method according to p. 19, further comprising the step of creating a circulating movement of objects in the transmission chamber (2) along the circulation path, while part of the circulation path continues along the peripheral surface of the rotatable transmitting wheel (3) in the direction of rotation of the rotatable transmitting wheel (3).

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