RU2533776C2 - Belt conveyor - Google Patents

Abstract

FIELD: transport.

SUBSTANCE: belt conveyor (1) includes conveyor belt located along transport path and containing a number of elongated support links (4) to support product being transported. The links are oriented across the belt and provided with a number of connecting rods (20) to interconnect links. Each link includes driving element (131) made of magnetic material and driving gear (100) containing electric magnets located along conveyor belt to produce magnetic field for driving force application to driving elements near magnets thus forming linear actuator. The driving gear is located on outer side of curved section.

EFFECT: reduced necessity in conveyor maintenance or repair and belt wear.

25 cl, 9 dwg

Description

The invention relates to a conveyor, in particular, to a conveyor belt intended for transverse bends in the horizontal and vertical plane and, for example, having a lattice structure.

Such conveyor belts are used mainly in the food industry, in particular in the so-called spiral towers, for cooling or heating, raising dough (proofing), etc., in which the conveyor belt is driven from the inside and follows a spiral path.

Such conveyor belts, hereinafter referred to as composite belts, among other things, should be easy to clean, and for this often have a lattice structure. They are assembled from elongated, transversely directed synthetic support parts or links having a zigzag shape, which in the direction of the conveyor belt enter into each other and are connected by rods.

Such composite tapes are used, for example, in a spiral conveyor for circulating products, in particular food products, such as dough products, for a predetermined period of time under given conditions. Such a spiral conveyor contains a frame for forming a spiral path with several turns, or tiers, located one above the other, a composite belt located along a spiral path with the ability to move along it. Inside the spiral path, to bring the link tape into motion by means of friction, a rotating drum is located, to which the side of the tape is adjacent. The peripheral speed of the drum is slightly higher than the speed of movement of the link tape. Therefore, there is some slippage. However, the conveyors in question undergo temperature changes and, in addition, they are also contaminated by products. As a result, the coefficient of friction between the drum and the link tape can take on a different value, which can lead to problems.

In addition, the known spiral conveyor is provided with a rotating drum in the form of a stainless steel pipe. The specified pipe is an expensive element of the spiral conveyor, given the dimensions of the known spiral conveyors, is large, which can lead to problems during transportation or installation of the spiral conveyor.

The objective of the invention is to provide a conveyor of the aforementioned type, which requires less frequent maintenance / repair.

An additional object of the invention is to propose a conveyor of the aforementioned type in which the wear of the conveyor belt is reduced or can be avoided altogether.

SUMMARY OF THE INVENTION

In order to solve at least one of the problems, the invention provides, in accordance with one aspect, a conveyor belt comprising a conveyor belt extending along a transport path comprising a series of elongated support parts, or links, to support transported products that are transverse to the belt and a series of connecting rods for connecting the links to each other, in which the series of links contains a number of leading links, each of which contains a leading element of magnetic material a, and a driving mechanism containing one or more magnets placed along the conveyor belt to create a magnetic field, for applying a driving force to one or more drive parts next to the magnets, in which the transport path contains a bend, next to which is located the driving mechanism.

The conveyor belt in accordance with the invention contains driving links, each of which has a driving element of magnetic material. The movement of the driving links in the conveyor, in particular to bring the conveyor belt into motion, can be influenced by magnetic fields.

The driving means according to the invention comprises one or more magnets arranged along the transport path to create a magnetic field for applying a driving force to the driving links which are provided with magnetic material. Magnetic fields are created along the transport path by one or more magnets in a specific area of application of a driving force to the driving element. The specified section forms a leading path for one or more magnets. Within the indicated driving path, the links are driven.

The influence on the movement of the leading links in the direction of conveyor conveyance can be provided by means of magnetic fields. In the device in accordance with the invention, magnetic fields can also be used to guide the conveyor belt in the direction of bending. The magnets of the driving mechanism, in addition to creating a driving force, can also be applied to apply force to the driving links, which is directed across the transport path. The specified transverse force can be used to guide the links in the direction of bending. In this way, for example, at least at the location of the driving mechanism, the mechanical direction of the conveyor belt in the direction of bending is not necessary, as a result of which the friction of the conveyor belt when moving along the transport path can be reduced.

An additional advantage of such a device is that in order to set the driving means and the links in motion, physical contact between them is not necessary. As a result, wear at the expense of the lead means can be limited or even eliminated, as a result of which maintenance / repair is less necessary.

A further advantage of reducing or eliminating wear is to reduce the wear products that make up the source of contamination. This is an advantage, among others, in favor of the use of the conveyor in accordance with the invention, for example, for the food industry, where pollution should be minimized.

In one embodiment, at least the driving links are assembled from a number of elongated modules, which are provided at their longitudinal ends with connecting means that are mutually engaged to tightly connect the modules to each other and form a limited rotary connection in the plane of the tape, in which at least one of the leading link modules comprises a leading element.

Due to the indicated connection of neighboring modules, mutual engagement and mutual displacement and rotation are achieved, and they form a single unit. Thus, in the links there may be an optimal transfer of forces in the transverse direction.

Connecting modules to links before connecting links to each other can be done easily. In addition, the leading link may be provided with at least one module with a leading element. Thus, a number of conveyor belt links can be mounted using two types of modules; a large number of first modules without a leading element and for each leading link of at least one second module including a leading element.

In one embodiment, the lead member is located in the link, preferably in the plane of the link.

In one embodiment, the drive member is located near the end of the link forming the edge of the conveyor belt, where the drive mechanism is located adjacent to the edge of the conveyor belt.

In one embodiment, the drive mechanism is located on the outside of the tape. In this case, the magnets on the driving mechanism are adapted under the application of a deflecting force to the driving links, which is directed essentially across the transport path.

In one embodiment, the belt conveyor comprises one or more magnetic means arranged along the transport path to create a magnetic field for guiding the conveyor belt of at least its driving links along a curved portion. Said magnetic means are preferably arranged in or near the belt on a transport path. Magnetic means may form a guiding device for guiding the conveyor belt over a curved portion.

In one embodiment, the magnetic means comprise electromagnets. As a result, the strength of the magnetic fields can be set to a predetermined value, as a result of which the conveyor can be optimized.

In accordance with a further aspect, the invention provides a conveyor belt comprising a conveyor belt extending along a transport path, comprising a series of elongated supporting parts or links supporting the products to be transported and spaced across the belt, and a series of connecting means for connecting the links to each other, where each of a number of first connecting links contains a leading element of magnetic material, and a leading mechanism containing one or more magnets placed along the conveyor belt to create a magnetic field for applying a driving force to one or more driving elements near the magnets.

Instead of arranging the leading elements of magnetic material on or inside the links, the leading elements are located on or within the connecting means, in which case specially designed links or link parts are not required, and known links that are usually made of synthetic materials can be used .

In one embodiment, the connecting means comprise connecting rods. In one embodiment, the transport path comprises a bend, and the drive mechanism is located in the bend.

In accordance with a further aspect, the invention provides a spiral conveyor comprising a conveyor belt as described above, further comprising:

frame, to maintain a spiral transport path having a first number of turns, or tiers, placed one above the other,

in which a conveyor belt is located and can move along it on a spiral path;

in which the driving mechanism comprises one or more driving devices on a second number of turns, or tiers, located one above the other, where the second number is less than or equal to the first number;

where the spiral conveyor contains a freely rotating support roller, which is located inside the spiral path, and

where the driving mechanism is located on the outside of the spiral path.

Instead of a rotating drum located inside a spiral path in accordance with the prior art, the spiral conveyor in accordance with the invention is provided with a freely rotating support roller, which is located inside the spiral path on the side of the tape, which faces the inner side of the support of the spiral path, in particular, next to the place , where on the outer side of the spiral path is located and is in contact with the outer side of the link tape drive mechanism. Thus, the conveyor belt passes between the support roller on the inner side of the conveying path and the drive mechanism on the outer side of the conveying path. Since the freely rotating support roller in the spiral conveyor in accordance with the invention is used only to support the conveyor belt, and not to bring the conveyor belt into motion due to friction, it can be made lighter and the conveyor belt will practically not slip along the support roller, whose diameter may be less than the inner diameter of the spiral path.

Due to the virtually elimination of slippage between the conveyor belt and the support roller, the link belt will be less susceptible to wear, which can lead to a reduction in contamination due to wear products and / or prolong the life of, in particular, the conveyor belt.

In one embodiment, the support roller and the drive mechanism are located on both sides of the conveyor belt. In one embodiment, the drive mechanism is positioned in such a manner with respect to the support roller that the support roller is able to appropriately absorb the possible radial forces exerted by the drive mechanism on the conveyor belt. In one embodiment, the drive mechanism is located radially with respect to the support roller.

In one embodiment, the driving mechanism for each of the second number of turns located one above the other comprises a driving device for driving the side of the modular conveyor belt that faces the outside of the spiral path. Thus, the forces exerted by the driving mechanism on the modular conveyor belt can be distributed in several places located one above the other along a spiral path.

In one embodiment, the host device is located at least partially above the edge region of the modular conveyor belt. In this embodiment, the conveyor belt is bounded in a vertical direction near the driving member between the spiral path on the lower side and at least a portion of the driving device on the upper side. This limitation ensures that the conveyor belt, at least close to the leading element, cannot be turned up, as a result of which a working connection between the leading element and the conveyor belt is guaranteed.

In one embodiment, the host device extends at least partially below the edge region of the model conveyor belt.

From an additional aspect, the invention provides a spiral conveyor comprising a conveyor belt, as described above, and further comprising: a frame, for supporting a spiral transport path having a first number of turns or tiers placed one above the other,

in which a conveyor belt is located and can move along it on a spiral path;

in which the driving mechanism comprises one or more driving devices on a second number of turns, or tiers, located one above the other, where the second number is less than or equal to the first number;

where the driving mechanism is located on the inside of the spiral path. As already defined above, the movement of the leading links in the direction of conveyor transport can be influenced by magnetic fields, but in addition, the conveyor belt can be directed along a curved section. The magnets on the driving mechanism, not to mention the supply of driving force, can also be designed to apply force to the driving links, a force that is directed almost across the transport path. The specified transverse force can be used to guide the links along a curved section. Preferably, the drive mechanism is located on the inside of the belt, in which case the magnets of the drive mechanism provide a deflecting force, which is directed across the transport path, to the drive links. The drive mechanism on the inside, at least at the location of the drive mechanism, replaces the drive drum or support roller within a spiral path and is able to hold the conveyor belt at a desired radial distance by a force that is directed radially outward. In this way, at least at the location of the drive mechanism, the mechanical direction of the conveyor belt on the inner side of the spiral conveyor may no longer be necessary, as a result of which the friction of the conveyor belt when moving along the transport path can be reduced.

In accordance with a further aspect, the invention provides a drive mechanism for a conveyor belt or spiral conveyor, as described above.

The invention further provides an apparatus for processing products, in particular bakery products, comprising a conveyor belt in accordance with the invention.

The properties and features described in the description and claims and / or shown in the drawings of this application can be used separately if necessary. These individual properties may, in addition, be the subject of a dedicated patent application. This is, in particular, applicable to the features and properties that are described in the subclaims.

Brief Description of the Drawings

The invention is explained on the basis of a number of exemplary embodiments shown in the attached drawings, in which:

figure 1 shows a top view of part of a conveyor belt in accordance with the invention on a curved section of the path;

figure 2 shows a detail of the tape of figure 1;

figure 3 shows a section along III - III in figure 2;

4 shows a view of an embodiment of a spiral conveyor in accordance with the prior art;

figure 5 shows a view of a spiral conveyor in accordance with figure 4 in section;

6 shows a schematic top view of an exemplary embodiment of a spiral conveyor in accordance with the invention;

FIG. 7 shows a schematic side view of an exemplary embodiment of a spiral conveyor in accordance with FIG. 6;

Fig. 8 shows a schematic top view of a second exemplary embodiment of a spiral conveyor in accordance with the invention; and

Fig.9 shows a schematic side view of exemplary embodiments of a spiral conveyor in accordance with Fig.8.

Detailed Description of Drawings

The conveyor belt 1 shown in FIG. 1 corresponds substantially to the conveyor belt according to the European patent application of the applicant 90.202922, and is laid on the guides 3. The belt is mounted from cross-linked links 4 that are connected to each other by connecting rods 20. On the inner radius links 4 can go into a continuous lateral guide 2 (not shown) or be driven by a drive drum.

Links 4 have, in general, a zigzag shape with “protrusions” 5 with sinuses 9 located between them and “cavities” 6 with sinuses 8 located between them, while “cavities” 6 are located in the sinuses 9, and “protrusions” 5 are in the sinuses 8 of the next link 4. The “protrusion” 5 and the “depression” 6 of the link are made as a single unit of synthetic material and are connected to each other by housings 7. The “protrusions” 5 are equipped with wide passages 10 for the rod 20, and the “depression” 6 are provided with narrow passages 11 for the rod 20. Between the housing 7 "depression" 6 have a circular cross section, coaxial 11 th passages.

Links 4 include one edge module 4a, one edge module 4b, and one or more, depending on the width of the tape, intermediate modules 4c. The edge module 4a is located on the guide 3. The edge module 4b is also located on the guide 3 and is driven along the guide 2.

Near the end portion 13, the modules 4a and 4b are provided with a lead member 131 of magnetic material. The driving mechanism 100, containing one or more magnets placed along the conveyor belt 1, is designed to generate a magnetic field, forming together with the driving elements 131 a linear motor that generates a driving force acting on one or more driving elements 131.

Modules 4a-4c are connected to each other by locks 14 (see figures 2 and 3). One module, for example, 4c, has dovetail protrusions located along the entire height, which have inclined sides 18 and a surface 19 oriented in the transverse direction, two surfaces 21a, 2lb, oriented in the transverse direction, which are adjacent to the protrusion 15 Another module, for example, 4a, at the opposite end, has a recess 16 having inclined sides 17 and a laterally oriented surface 20, intended respectively to fit snugly onto the protrusions 15, two surfaces 22a, 22b, a landmark laterally drawn in recess 16. After the modules 4a, 4b and 4c are connected, the surfaces 17-18, 21a, 2lb, 22a, 22b and 19-20 are tightly fitted to each other. The connection is located in width (longitudinal direction of the tape) and height over the entire area where the modules are connected to each other.

The modules thus form an easily pliable whole capable of compensating for tensile forces. Due to the dovetail connection, the stiffness of the connection 14 to bend in the horizontal and vertical planes can be greater.

In addition, the passages 11 are directed through the joints 14. After the rods 20 are inserted through the passages 11, they are fixed externally with pins 12 at both ends in portions 13 of the edge modules 4a and 4b. Modules cannot move individually due to the connections between them. Due to the friction fit of the connecting elements of the modules, they can be kept from mutual displacement in the direction perpendicular to the tape. Rod 20 can also prevent movement due to a snug fit in the module.

As an alternative to the edge modules 4a and 4b, which are provided with an end element 131 of magnetic material near the end portion 13, the connecting rods 20, at least near one or both of their ends, can be provided with magnetic material to form a lead element.

Figure 4 shows a spiral conveyor in accordance with the prior art, made in the form of a frame of beams 41 and racks 42. On racks 42, which are arranged in the form of a polygon, holders 43 fixed inward are fixed, which, using a spiral strip 44, form a support for the conveyor belt 45. Inside the spiral path 44, the drum 46 is mounted to rotate around the vertical axis 47 by means of an engine (not shown). The drum 46 is provided with vertical ribs 49 arranged with gaps relative to each other. When the conveyor belt 45 is under appropriate tension, the rotating drum 46 captures the conveyor belt 45. In this case, relative slippage occurs. 5, a known spiral conveyor is shown in section in a plane perpendicular to the vertical axis 47.

6 shows a first embodiment of a spiral conveyor 60 in accordance with the invention. 6 shows a top view perpendicular to the axis of symmetry of the spiral conveyor 60. The spiral conveyor 60 in accordance with the first embodiment includes a frame with beams 61 and racks 62. On the racks 62 are outwardly directed brackets 63, which, using guides arranged on them along a spiral path 64 form a support for the conveyor belt 65.

Inside the spiral path there are several, for example, four, freely rotating support rollers 66, which are a support for the side surface 151 of the modular conveyor belt 65 facing the inside. The support rollers 66 are located on the vertical axes with the possibility of free rotation. Support rollers 66 are connected, for example, on their upper and lower sides with additional rungs (not shown) of the frame.

The view in FIG. 6 shows an additional advantage of the device in accordance with the invention. The frame can be located exactly inside the spiral path. Since there is no need for uprights 62 outside the spiral path, the conveyor belt 65 can be easily mounted on the guides 64 of the spiral path. In one embodiment, the modular tape is disposed on guides 64 of an unsecured spiral path.

The spiral conveyor 60, in accordance with this embodiment, is provided with a drive mechanism in the form of magnets 67, which are mounted on one outward facing side 152 of the modular conveyor belt 65 to interact with the end portions 13 of the conveyor belt. The driving magnets 67 are located radially opposite one of the support rollers 66, as shown in Fig.6.

As shown in FIG. 7, the spiral conveyor 60 may be provided with several drive magnets 67 located one above the other, each of which drives the conveyor belt 65, on one tier.

Fig. 8 shows a second embodiment of a spiral conveyor 80 in accordance with the invention. This embodiment also includes a frame provided with beams 81 and struts 82. On the struts 82, outwardly directed brackets 83 are provided, which are provided with guides 84 to form a spiral support for the conveyor belt 85. At the location of the conveyor belt 85 of the rack 82, located adjacent to the spiral path are provided with freely rotating support rollers 86.

In this embodiment, the freely rotating support rollers 86 do not substantially extend to the full height of the spiral conveyor 80, but have a limited height, providing support for side 251 of the modular conveyor belt 85 facing the inside of the spiral conveyor only at the location of the spiral trajectories. The indicated combination of uprights 82 with support rollers 86 located on them is shown schematically in FIG. 9.

In the second embodiment, as shown in the top view of FIG. 8, the drive mechanism in the form of magnets 87 is located on the inwardly oriented side 251 of the modular conveyor belt 85 for contacting the end portions 13 of the conveyor belt 85.

As shown in FIG. 9, the spiral conveyor 80 is provided with several drive magnets 87 located one above the other, each of which drives the conveyor belt 85 on one tier. In this case, the magnets 87 of the driving mechanism provide an application of a biasing force to the conveyor belt 85, which is directed substantially across the transport path. The drive mechanism 87 on the inside, at least at the location of the drive mechanism, biases the support roller 86 within a spiral path and holds the conveyor belt 85 in the desired radial position due to the force directed radially outward.

The above description is intended to illustrate preferred embodiments of the invention, and not to limit the scope of the invention. Based on the above description, the specialist will understand the options that are within the ideas and essence of the present invention.

For example, a spiral conveyor in accordance with the invention may be provided with several driving mechanisms located on the periphery. In addition, a drive mechanism located adjacent to the first spiral conveyor may drive an additional nearby spiral conveyor.

Claims (25)

1. A conveyor belt containing
- a conveyor belt located along the transport path, made in the form of a series of elongated links located across the belt, designed to support the transported products, and a series of connecting rods for connecting the support links to each other, with each first link provided with a leading element made of magnetic material ,
- a driving mechanism containing one or more magnets located along the conveyor belt to create a magnetic field that provides a driving force to one or more driving elements located next to the magnet, while the transport path has a curved section, next to which there is a driving mechanism , wherein
- one or more magnets contain electromagnets for generating a magnetic field, forming together with the leading elements a linear motor that creates a driving force acting on one or more leading elements. 2. The belt conveyor according to claim 1, characterized in that at least the first links are mounted from several extended modules, which are provided at their elongated ends with connecting means for mutually tightly connecting the modules to each other, forming in the plane of the belt during rotation limited rotational connection, where at least one of the modules of the first link contains a leading element. 3. The belt conveyor according to one of claims 1 or 2, characterized in that the leading element is located in the link, preferably near the end of the link forming the edge of the conveyor belt. 4. The conveyor belt according to claim 3, characterized in that the drive mechanism is located next to the edge of the conveyor belt. 5. The belt conveyor according to one of claims 1 or 2, characterized in that the drive mechanism is located on the outside of the curved section. 6. The belt conveyor according to one of claims 1 or 2, characterized in that it contains one or more magnetic means located along the transport path to create a magnetic field that moves at least the leading links of the conveyor belt along the curved section. 7. A conveyor belt containing
- a conveyor belt located along the transport path, made in the form of a series of elongated links located across the belt, designed to support the transported products, and a series of connecting rods, for connecting the supporting links to each other, with each first link provided with a leading element made of magnetic material, and
- a driving mechanism containing one or more magnets located along the conveyor belt to create a magnetic field that provides a driving force to one or more driving elements located next to the magnet, while the transport path has a curved section, next to which there is a driving mechanism, but
- the driving mechanism is located on the outside of the curved section. 8. The conveyor belt according to claim 6, characterized in that it contains one or more magnetic means located along the transport path to create a magnetic field that moves at least the leading links of the conveyor belt along the curved section. 9. A conveyor belt containing
- a conveyor belt located along the transport path, made in the form of a series of elongated links located across the belt, designed to support the transported objects, and a series of connecting means, for connecting the support links to each other, each first link provided with a leading element made of magnetic material, and
- a driving mechanism containing one or more magnets located along the conveyor belt to create a magnetic field that provides a driving force to one or more leading elements near the magnets,
- in this case, one or more magnets contain electromagnets for generating a magnetic field, forming together with the driving elements a linear motor that creates a driving force acting on one or more leading elements. 10. The conveyor belt of claim 8, characterized in that the connecting means contain connecting rods. 11. The conveyor belt according to one of claims 9 or 10, characterized in that the transport path includes a curved section and a drive mechanism located in the curved section. 12. The conveyor belt according to claim 11, characterized in that the drive mechanism is located on the outside of the curved section. 13. A conveyor belt containing
- a conveyor belt located along the transport path, made in the form of a series of elongated links located across the belt, designed to support the transported objects, and a series of connecting means, for connecting the support links to each other, each first link provided with a leading element made of magnetic material, and
- a driving mechanism containing one or more magnets located along the conveyor belt to create a magnetic field that provides a driving force to one or more leading elements near the magnets,
- the transport path contains a curved section, and
- the driving mechanism is located on the outside of the curved section. 14. A spiral conveyor comprising a conveyor belt according to one of claims 1 to 13, characterized in that it is equipped with
- a frame for supporting a spiral transport path having a first number of bends or tiers located one above the other, the conveyor belt being located on the spiral transport path with the possibility of moving along it,
- a driving mechanism comprising one or more driving means on a second number of bends or tiers located one above the other, the second number being less than or equal to the first,
- freely rotating support roller located inside the spiral path to form a support on the inside of the conveyor belt, while the drive mechanism is located on the outside of the spiral path. 15. The spiral conveyor according to claim 14, characterized in that the support roller and the drive mechanism are located on both sides of the modular conveyor belt. 16. The spiral conveyor according to claim 14, characterized in that the drive mechanism is located radially opposite the support roller. 17. The spiral conveyor according to one of paragraphs.14, 15 or 16, characterized in that the driving mechanism for each of the second number of bends located one above the other, contains leading means for transmitting drive force to the side of the modular conveyor belt facing the outside spiral trajectory. 18. A spiral conveyor containing a conveyor belt according to one of claims 1 to 13, and characterized in that it contains
- a frame for supporting a spiral transport path having a first number of bends or tiers located one above the other, the conveyor belt being located on the spiral transport path with the possibility of movement along it,
- a driving mechanism comprising one or more driving means on a second number of bends or tiers located one above the other, the second number being less than or equal to the first, while the driving mechanism is located on the inner side of the spiral path. 19. The spiral conveyor according to claim 18, characterized in that the driving mechanism for each of the second number of bends located one above the other contains leading means that enable transmission of drive force to the side of the modular conveyor belt facing the outer side of the spiral path. 20. The spiral conveyor according to claim 19, characterized in that the host device continues, at least partially, above the edge region of the modular conveyor belt. 21. The spiral conveyor according to claim 19, characterized in that the driving means is located at least partially below the edge region of the modular conveyor belt. 22. The spiral conveyor according to claim 15, characterized in that the master device continues at least partially above the edge region of the modular conveyor belt. 23. The spiral conveyor according to claim 17, characterized in that the driving means is located at least partially below the edge region of the modular conveyor belt. 24. The driving mechanism for a belt conveyor or spiral conveyor according to one of the preceding paragraphs. 25. Apparatus for processing products, in particular, bakery products, comprising a conveyor belt according to one of claims 1 to 13.

Images