BE1027853B1 - Conveyor belt system with roller support for a conveyor belt as well as process and use - Google Patents

Abstract

The invention relates to a conveyor belt system (10) with carrier roller support, in particular for the transport of bulk materials, having at least one conveyor belt (11), a plurality of carrier roller units (13) attached to the conveyor belt and moving with the conveyor belt, and a support structure (15) for the support roller units, the conveyor belt system being set up for hanging the conveyor belt by means of the support roller units running along in / on the support structure; wherein the support structure (15) along the longitudinal extension (x) of the conveyor belt has at least one rigid or at least largely rigid guide device (16; 17) on both sides for guiding the carrier roller units, the respective carrier roller unit in such a way to one / the edge region of the conveyor belt (11) is coupled that the respective support roller unit is arranged at a predefinable angle (?) relative to the transverse alignment of the respective edge area of the conveyor belt, and that the respective edge area of the conveyor belt is arranged at a predefinable distance (y11) from the corresponding guide device (16).

Description

Conveyor belt system with roller support for a conveyor belt as well as process and use Description:

TECHNICAL FIELD The invention relates to a device and a method for supporting and aligning a conveyor belt in a conveyor belt system with roller support, in particular when transporting bulk goods, the alignment of the conveyor belt hanging in a support structure by means of a plurality of roller units attached to the conveyor belt and moving with the conveyor belt he follows. In particular, the invention relates to a device and a method according to the features of the respective independent or co-ordinate claim.

BACKGROUND For the ground-based conveyance of materials such as bulk goods, on the one hand belt conveyor systems with stationary support rollers are used, on the other hand systems with rails or cables / ropes on which the support rollers run with the conveyor belt are also used. In many applications, the stationary support rollers cause comparatively high, disadvantageous running resistances, in particular due to contact forces, friction, conveyor belt deformation, rolling work. Particularly high running resistances are due in particular to high loads and strong belt slack. Depending on the degree of trough, the running resistance is between 2 and 4 percent (standard trough) or between 4 and 6 percent (hose belt), in each case in relation to the total mass to be moved. Another disadvantage of stationary bearing rollers is the high maintenance outlay on the respective bearing roller on site. This maintenance effort can be disadvantageous, especially with a conveyor belt length of several hundred meters or in rough terrain, and a cost disadvantage that should not be underestimated in terms of the service life of the system.

Conveyor belt systems with cables / ropes can ensure low running resistances, but are more likely to be special solutions for special applications, not least because of the comparatively high expense in terms of tensioning devices, suspension cable costs and the need for specific specialist knowledge. In addition, it does not seem to be possible in a simple manner by means of carrying ropes to be able to set the degree of a trough or the cross-sectional profile of the conveyor belt as precisely as possible. Conveyor belt systems with rails or similar largely rigid guide devices can thus be regarded as a kind of compromise between these two technologies mentioned above, because they offer the advantage of low running resistance and make it possible to use tried and tested system components. In addition, the transverse distance between the guide devices can be set comparatively precisely, in particular for the purpose of influencing the cross-sectional profile of the conveyor belt.

The two publications RU 2182551 C1 and RU 2182109 C2 each describe a coupling between the conveyor belt and the support rollers and the design of the support rollers specifically as a pair of rollers (double roller), which is guided above and below along a guide rail or a pipe or a rope. According to the prior art, it has therefore proven to be advantageous to secure the support rollers on the respective guide device by means of double rollers. The carrier rollers are coupled to the conveyor belt with a hook or a fastening bracket (fastening strip) at a respective fastening point. However, dual roles are not always preferred; in particular, double rollers can also have the following disadvantages: complex adjustment of the relative position of the individual rollers relative to one another; comparatively high running resistance; Lateral support with lateral offset (due to the space requirement for a double pulley running on both sides of the rope or the rail), which creates bending moments.

Based on this state of development, there is an interest or need for a conveyor belt system or a method for guiding a conveyor belt and for transporting material, which means that with advantageous device-related properties with regard to costs, maintenance effort and running resistance

Advantages in terms of variability and accuracy when arranging and aligning the conveyor belt can be ensured.

DESCRIPTION OF THE INVENTION The object of the invention is to provide a device and a method with the features described at the outset, with which a conveyor belt can be suspended in a flexible and operationally reliable manner. In particular, the task is also to design a coupling or coupling between the conveyor belt and the support structure in a reliable and sustainable manner, in particular for the most flexible possible arrangement of the conveyor belt depending on the application or load, in particular for the most variable possible use of the conveyor belt in different orientations, in particular with different orientations or adjustable trough.

This object is achieved by a device and a method according to the independent patent claims. Advantageous exemplary embodiments are listed in the subclaims.

According to the invention, this object is achieved in particular by a conveyor belt system with carrier roller support, in particular for the transport of bulk materials, having at least one conveyor belt, in particular a circumferential conveyor belt, a plurality of carrier roller units attached to the conveyor belt and moving with the conveyor belt, as well as a support structure for the carrier roller units, the conveyor belt system being set up for hanging the conveyor belt by means of the idler roller units in / on the support structure, in particular without any contact between the running surfaces of the conveyor roller units and the conveyor belt; wherein the support structure along the longitudinal extension of the conveyor belt has at least one rigid or at least largely rigid guide device on both sides for guiding the carrier roller units, in particular comprising at least one longitudinally guiding tube, the respective carrier roller unit being coupled or coupled to an edge region of the conveyor belt in such a way that the respective support roller unit is arranged in the intended arrangement or alignment of the loaded or unloaded conveyor belt at a predefined / predefinable angle relative to the transverse alignment of the respective edge area of the conveyor belt or its extension plane in the transverse direction, in relation to a / the cross-sectional plane orthogonal to the longitudinal extension of the conveyor belt (in particular predefinable transverse inclination), and that the respective edge area of the conveyor belt is arranged at a predefinable distance (in particular transverse distance) from the corresponding guide device. On the one hand, this enables a large number of device-related advantages with regard to the entire system; on the other hand, the alignment and arrangement of the conveyor belt can be carried out in a comparatively exact manner. The coupling according to the invention between the support roller unit and the conveyor belt thus also enables a tubular configuration of the cross-sectional profile (in particular for the transport of dangerous goods) in a variable and practical manner, in particular by adapting the transverse spacing of the guide devices to one another.

The present invention is also based on the concept of influencing the arrangement and alignment of the edge area or the opposite edge areas of the conveyor belt via the coupling between the conveyor belt and the support roller unit. Advantageously, the coupling does not connect directly to the edge of the edge area, but a little further inside, i.e. with a transverse distance of e.g. 5 to 10 percent (exposed edge area). The exposed edge area created in this way can be used, in particular, when a tubular cross-sectional profile is desired, to compensate for positional tolerances and vibrations, so that the conveyor belt can be sealed largely tightly with good reliability even with different loads.

In this context, “largely rigid” is to be understood as a guide device that is largely non-deformable even in a non-pretensioned state or, at least when used as intended, should not be elastically or plastically deformed. Accordingly, ropes or cables according to the present definition are not considered to be “largely rigid”, especially since ropes yield to a transverse load as soon as a pre-tension is no longer sufficient.

According to one embodiment, the conveyor belt system is set up to guide the support roller units on two at least approximately parallel movement paths,

wherein the movement paths are defined by the guide devices and extend on both sides of the conveyor belt to the side of the conveyor belt and optionally at least in sections also above (on the top) of the conveyor belt.

According to one embodiment, the guide devices define a span in the transverse direction for a respective longitudinal section, over which span the conveyed goods are held or stretched by means of the guide devices, the opposite guide devices having a predefined transverse coordinate for defining the span.

In this way, a span in the transverse direction can also be predefined comparatively precisely.

According to one embodiment, the support roller units are / are guided by means of the guide devices in such a way that the cross-sectional area of the conveyor belt receiving the material is / remains contact-free, at least partially between the guide devices and at least in sections, in particular apart from reversal points, at least partially below the guide devices.

In this way, the running resistance can be further minimized.

According to one embodiment, in a respective specific longitudinal position of the conveyor belt, at least one pair of support roller units is arranged on the two sides of the conveyor belt opposite one another.

The support roller units can be designed as support roller units coupled to the conveyor belt in an exposed manner.

The conveyor belt system can provide a coupling to the conveyor belt for each support roller unit, which coupling defines a fastening area with a plurality of fastening points, the fastening points being distributed both in the vertical direction and in the longitudinal direction over the fastening area, in particular in pairs, for example four, six, eight , ten or twelve attachment points.

Last but not least, this also allows the introduction of force or

Force transmission on the conveyor belt can be optimized, especially in the largest possible area.

This also helps align the conveyor belt as precisely as possible.

The support roller units do not have to be arranged exactly opposite one another.

For some applications it can be advantageous if the opposite support roller units are arranged with an offset in the longitudinal direction, wherein the longitudinal offset can be quite large, in particular up to half the longitudinal spacing of the support rollers on the respective side of the conveyor belt. This longitudinal offset provides the advantage, particularly when the conveyor belt is heavily loaded, that sagging can be minimized. The conveyor belt system can provide a coupling to the conveyor belt for each support roller unit, which has several coupling elements articulated to one another in a segment-like manner (in particular tab elements) and, by means of the coupling elements, defines a fastening area with a plurality of fastening points, in particular both in the longitudinal direction and in vertical direction. The respective support roller unit can in particular be coupled to the conveyor belt by means of a strap, in particular in a fastening point with a predefined relative orientation, without a pivot bearing.

Preferably, only a single support roller or a pair of opposite support rollers arranged on both sides of the conveyor belt is coupled to the conveyor belt at a respective longitudinal position of the conveyor belt, in particular by means of a tab. Here, the conveyor belt system can provide a coupling to the conveyor belt for each support roller unit, which coupling is set up for a predefinable angular alignment of the edge of the conveyor belt by means of the coupling. For example, the respective support roller unit is coupled to the conveyor belt by means of a tab, the tab having a plate-like section in the fastening area on the conveyor belt and at least in the fastening area being preferably made in one piece, rigid or material-elastic. Optionally, segmentation can also take place, in particular in the longitudinal direction, in particular if the fastening area is to have a comparatively large longitudinal extent.

The respective support roller unit can be coupled to the conveyor belt, for example, by means of a strap, which in cross section forms an angle profile with one or two angles each in the range of 20 to 50 degrees, in particular two opposing angles, which ensure a transverse offset with parallel fastening sections.

According to one embodiment, the support roller units are / are fastened to the conveyor belt in a predefined angular alignment relative to the conveyor belt cross-sectional plane and are guided over or along the guide devices by means of the conveyor belt, in particular also at a reversal point around a drum, that one of the support roller units the support force exerted by the guide devices is introduced into the support structure at an angle between 10 and 45 degrees (in particular angle around the longitudinal axis; in particular angle with respect to the alignment of the lateral edge region of the conveyor belt). In this way, not least, an advantageous relative arrangement of support rollers, guide rails / tubes and the conveyor belt can also be ensured, in particular also at deflection points in the case of a circumferentially guided conveyor belt.

The support roller units can be fastened to the conveyor belt in a predefined angular orientation relative to the conveyor belt cross-sectional plane in such a way that the sections of the conveyor belt coupled to the support roller units form a roof angle in the range of 30 to 90 degrees. For example, the respective support roller unit is coupled to the conveyor belt by means of a bracket, which in cross section forms an angle profile with one or two angles in the range of 20 to 50 degrees, in particular two opposing angles, which ensure a transverse offset with parallel mounting sections.

According to one embodiment, the respective support roller unit is fastened to the conveyor belt by means of a tab, the tab being fastened at a distance from the edge of the conveyor belt, in particular at a distance greater than 5 or 10% of the width of the conveyor belt. This transverse distance also promotes a compensation effect for an exposed edge area, in particular when a tubular cross-sectional profile is desired. The respective support roller unit can, for example, be fastened to the conveyor belt by means of a strap in such a way that an exposed edge section or collar is formed between the fastening point and the edge of the conveyor belt.

According to one embodiment, the respective support roller unit is fastened by means of a tab on the outside of an underside or outside of the conveyor belt, the tab resting flat against the conveyor belt, in particular exclusively on the outside on the underside. An external fastening promotes not only advantageous variability with regard to the trough or hose-like arrangement, but also with regard to the deflection of a circumferential conveyor belt. The respective support roller unit can be coupled to the conveyor belt by means of a strap, the strap being arranged and designed either on the outside with an angular offset inwards or on the outside with an angular offset inwards (in particular in each case angular offset in the range of 20 to 45 °). The angular offset can be selected depending on the desired trough or can be optimized with regard to a hose arrangement. It has been shown that the tab or the coupling preferably has one of the following geometries in cross section: two essentially flat surface sections at an angle to one another (tab with inner angle or outer angle; angle inward or outward depending on the desired trough or hose arrangement) , or three essentially flat surface sections, two of which are oriented essentially parallel to one another and the connecting surface section is oriented at an angle to both and ensures a transverse offset through the angular offset (bracket with double-angle profile). The conveyor belt system is in particular also set up to exert an inwardly directed transverse force on the respective edge area of the conveyor belt, in particular by means of the support roller units or by means of their coupling or tabs.

According to one embodiment, the respective support roller is fastened by means of a tab on the outside of an underside of the conveyor belt, the tab having fingers or extensions or tab elements or segments that are articulated relative to one another and with which the tabs are spaced apart from one another individually in the longitudinal direction Attachment points is attached to the conveyor belt. This also makes it possible to minimize stresses and wear at the fastening point, in particular in the case of a comparatively large fastening area.

According to one embodiment, the respective guide device has at least one tubular profile, in particular with a round or circular cross-sectional profile, for guiding the support roller units. The support roller units can be pulled into / onto the guide devices by means of the transverse tension ensured in the conveyor belt in the conveyor belt system transversely to the longitudinal / conveying direction. The support structure or the guide devices can define at least one U-profile for guiding and arranging the support roller units. The guide devices and the support roller units can be geometrically coordinated with one another and arranged relative to one another in such a way that self-centering of the support roller units takes place. The respective support roller unit can comprise removable sliding or roller elements, in particular in the form of guide elements or rollers. In this way, a specific optimization can also take place for each application.

At least one of the guide devices can have a safety device, in particular in the form of a safety rail, which is designed and arranged (in particular in an arrangement opposite and above a tubular profile of the guide device) that the freedom of movement of the respective support roller unit is predefined laterally and / or in the vertical direction or is at least limited.

The respective support roller unit can be guided in an arrangement between at least two pipe profiles of the respective guide device, the support roller units being supported on a lower one of the pipe profiles and guided along an upper one of the pipe profiles, if the support roller unit is properly aligned relative to the upper pipe profile, preferably without contact ( i.e. without contact with the upper pipe profile).

According to one embodiment, the respective support roller unit has a diameter of at least a factor of 1.5 of the diameter of the guide device (in particular of a / the tubular profile of the guide device), preferably at least a factor of 2.0, especially at least a factor of 2.5. The respective support roller unit can have a double-cone profile in cross section. The respective support roller unit can have two mutually inclined

Have support roller elements (roller elements), in particular in a relative arrangement with double-cone geometry. In this way, not least, the alignment of the support roller unit can also be influenced or optimized, in particular with regard to centering on the guide device. A double-cone geometry can ensure an advantageously symmetrical two-point contact on the guide device; this can also exclude or at least minimize adverse sliding and friction effects.

According to one exemplary embodiment, the transverse spacing of the guide devices running opposite one another on the side of the conveyor belt along the conveyor path is in the range from 50 to 120 percent of the width of the conveyor belt. In this range of variation, a tubular arrangement of the conveyor belt can advantageously be optimized.

According to one embodiment, the transverse spacing of the guide devices running opposite one another on the side of the conveyor belt is at least in sections in the range of 5 to 50 percent of the width of the conveyor belt. As a result, the edge areas of the conveyor belt can be placed against one another and a hose-like cross-sectional profile can be set for the conveyor belt. The couplings between the respective support roller unit and the conveyor belt can also ensure a desired alignment of the edge area of the conveyor belt, in particular a completely closed arrangement (sealing arrangement, in particular also for the transport of dangerous goods).

According to one exemplary embodiment, the conveyor belt is guided around a drum at least two points, the rollers being guided on a radius of curvature at least approximately corresponding to the radius of the drum. Effect: The conveyor belt or conveyor belt is pulled largely flat in the transverse direction in the area of the deflection or over the section of the drum, whereby the transverse tension can be specified by means of the position of the support roller units or the corresponding sections of guide tubes or rails. This enables operating parameters of the conveyor belt to be set in a simple constructive manner.

According to one embodiment, the support roller units are moved exclusively by means of the conveyor belt. The support roller units can be designed to be passive in a driveless manner.

According to one exemplary embodiment, the guide devices on both sides are connected to one another via cross struts and are coupled to one another in a segmented manner in the longitudinal direction or are connected to one another in a segmented manner. In this way, stabilized longitudinal models can be provided by means of cross struts, with the cross strut being able to be adapted to the respective application and the masses to be moved. The guide devices on both sides can, for example, each be formed from individual longitudinal sections that are modularly coupled to one another by means of longitudinal couplings, at least in the longitudinal direction with an expansion / movement tolerance. This also enables compensation in the longitudinal direction.

According to one exemplary embodiment, the conveyor belt system is constructed in the longitudinal direction from a multiplicity of support modules which each provide the support structure in the respective longitudinal section. In addition to advantageously compact assembly units, modularity in the longitudinal direction also enables the length to be adapted for a particular application. According to one embodiment, the support structure comprises centering tensioning elements which each couple adjacent segments or modules of the support structure to one another in the longitudinal direction. This also promotes scalability over particularly long lengths (several hundred meters or even kilometers). The support structure can furthermore comprise compensation elements which couple individual segments of the support structure that are adjacent in the longitudinal direction and are set up to compensate for tensile / compressive stresses in the guide devices along the conveying path.

The above-mentioned object is also achieved according to the invention in particular by a method for arranging a conveyor belt in a conveyor belt system with roller support, in particular when transporting bulk materials, in particular in a conveyor belt system described above, the conveyor belt being fastened to the conveyor belt by means of a plurality of and with the Conveyor belt moving idler units is arranged and aligned relative to a support structure for the idler units, namely relative to rigid or at least largely rigid guide devices running on both sides of the conveyor belt, the conveyor belt being arranged and aligned by means of the idler units by the idler units at a predefinable angle relative to the transverse alignment of the respective edge area of the conveyor belt are coupled to the conveyor belt and at a predefinable distance to the corresponding guide device.

This results in the aforementioned advantages.

According to one embodiment, on the respective support roller unit by means of a tab on the outside of an underside or

On the outside of the conveyor belt, a force is transmitted to the conveyor belt, in particular an inwardly directed transverse force.

In particular, this also provides advantages in the case of a tubular arrangement, in particular with regard to sealing and closing the material to be conveyed (partitioning off from the surroundings). On the respective support roller unit, either an inward angular offset or an outward angular offset can be set by means of a bracket (in particular an angular offset in the range from 20 to 45 ° in each case). According to one embodiment, the respective support roller unit is / is coupled to the respective guide device by means of a single support roller, in particular with a roller diameter of at least a factor of 1.5 of the diameter of the guide device, preferably at least a factor of 2.0, especially at least a factor of 2.5. Last but not least, this can also ensure advantageous running properties.

According to one embodiment, the conveyor belt is guided circumferentially, the conveyor belt optionally being troughed or arranged with a closed hose cross-section, in particular with a transverse spacing of the guide devices running opposite one another on the side of the conveyor belt along the conveyor path in the range of 40 to 90 percent of the width of the conveyor belt (trough) or in the range of 5 to 40 percent of the width of the conveyor belt

(Hose cut). Via the transverse distance, in connection with the couplings and the predefinable angular arrangement of the edge areas of the conveyor belt, the cross-sectional geometry can be predefined in a comparatively exact manner.

According to the invention, the aforementioned object is also achieved in particular by using a coupling between individual support roller units and a conveyor belt for the suspended arrangement of the conveyor belt in / on a support structure on two rigid or at least largely rigid guide devices of a conveyor belt system, in particular in a conveyor belt system described above, wherein the Conveyor belt is arranged and aligned by means of the couplings and the support roller units by coupling the support roller units to the conveyor belt at a predefinable angle relative to the transverse alignment of the respective edge region of the conveyor belt and at a predefinable distance from the corresponding guide device. This results in the aforementioned advantages.

DESCRIPTION OF THE FIGURES Further features and advantages of the invention emerge from the description of at least one exemplary embodiment with reference to the drawings, as well as from the drawings themselves. In this case, FIGS. 1A, 1B show, in a sectional side view (in the longitudinal direction) and in a detailed view, components of a conveyor belt system according to an exemplary embodiment ; 2, 5 each in a side view (in the transverse direction) further components of a conveyor belt system according to exemplary embodiments; 3, 6, 9 each in a sectional side view (in the longitudinal direction) components of a conveyor belt system according to exemplary embodiments, each at a deflection point in a circulating conveyor belt; 4A, 4B, 4C, 4D in sectional side views (in the longitudinal direction) and in a detailed view of components of a conveyor belt system in accordance with further exemplary embodiments with an arrangement of load and slack side one above the other;

7A, 7B, in a sectional side view (in the longitudinal direction) and in a detailed view, each component of a conveyor belt system according to a further exemplary embodiment, with a tubular cross-sectional geometry of the conveyor belt; 8 shows, in a side view (in the longitudinal direction), further components of a conveyor belt system according to an exemplary embodiment with parallel guidance of the load and slack strand; 10A, 10B, 10C each in a side view (in the transverse direction) in different variants of a coupling between a support roller unit and the conveyor belt according to exemplary embodiments; 11A, 11B, in a side view and in a top view, a longitudinal coupling between individual segments or modules of a guide device of a conveyor belt system according to exemplary embodiments;

DETAILED DESCRIPTION OF THE FIGURES In the case of reference symbols that are not explicitly described with reference to an individual figure, reference is made to the other figures. For the sake of easier understanding, the figures are first described together with reference to all reference symbols. Details or special features shown in the respective figures are described individually. A conveyor belt system 10 comprises at least one conveyor belt 11 for conveying or transporting material 1 or bulk material, which in the loaded state has a load strand 11a (loaded belt section) and which also has a return strand 11b when it is circumferentially guided. A revolving conveyor belt 11 is deflected, for example, via a deflection drum 12. The deflection drum can also include a drive for the conveyor belt system. Optionally, at least one counterweight is also provided to ensure a minimum belt pretension. The conveyor belt 11 is suspended from a support structure 15 by means of support roller units 13. The support roller units 13 each have: a roller with two mutually aligned conical roller elements 13.1, and optionally also one or two guide edges 13.2, and optionally also one or more guide rollers 13.3, and optionally also an encompassing support roller housing 13.4. The support roller units 13 are each coupled to the conveyor belt by means of a coupling 14. The couplings 14 each comprise at least one tab 14a or a similar largely rigid connecting element. The respective coupling 14 preferably has a plurality of fastening segments or elements 14.1, which are connected to one another so as to be movable about at least one axis via joints or axes 14.2.

The support structure 15 comprises in particular: two opposing guide devices 16 or two further opposing guide devices (return when the conveyor belt is rotating); Guide / safety rails, in particular round bars, tubes or tube profiles 17; at least one cross brace 19. Depending on the desired arrangement and alignment of the conveyor belt, the support roller units are arranged on the guide devices 16 at a predefined / predefinable transverse inclination angle a (angle about the longitudinal axis x). Optionally, one or more guide rollers 13.3 can assist in setting the angle a (FIGS. 6, 7A). The support structure 15 optionally comprises in particular: a support structure 15.1 for further guide devices; one or more securing guide units

16.1; at least one side support 18. The support structure 15 or the entire conveyor belt system 10 can be of modular construction, namely in that support modules 20 are / are coupled to one another in the longitudinal direction. A respective support module 20 has in particular: at least one frame or carrier 21; Longitudinal struts 22; at least one floor support 23. x, y and z denote the longitudinal, transverse and vertical directions.

A more specific description follows with reference to some of the figures. 1A illustrates in particular a transverse distance y11. 1A also illustrates an arrangement of the guide rails on a tangent T, which in the fastening area of the support roller flanges (strap fastening area) rests in cross section on the downwardly curved outside of the conveyor belt. It has been shown that this arrangement enables advantageous load introduction and force transmission, as well as load distribution and smoothness, in particular with a troughed cross-sectional geometry.

FIG. 1B particularly illustrates an angle a14 formed by the coupling 14.

2 shows a single support module 20, the two illustrated guide devices 16 each being able to be coupled to guide devices 16 of an adjacent module by means of longitudinal couplings 16.2. In FIG. 2 it can be seen that each coupling or tab 14 provides a multiplicity of fastening points P which are arranged over a certain flat fastening area and ensure a comparatively large-area contact with the conveyor belt. This favors the introduction of force and an aligning effect for aligning the edge area of the conveyor belt. In comparison, FIG. 5 also shows a securing guide unit 16.1, in particular in an arrangement according to FIG. 4B.

3 illustrates, in particular, a span y16 set by means of the guide devices 16 or by means of pipes 17. In comparison, FIG. 6 shows a variant for the cross-sectional geometry, which is also advantageous in particular in combination with guide rollers 13.3, in particular in an arrangement or configuration according to FIG. 4C. In Fig. 9, a further variant for the frame in the deflection area is illustrated, which is particularly advantageous in combination with a support roller unit 13 with only one guide roller 13.3 and with a guide edge 13.2.

4A, 4B and 4C show variants with and without guide rollers 13.3 and with or without a safety unit 16.1 and with and without a housing 13.4. Depending on the load, the size of the conveyor belt and the alignment and course of the frame 15, the appropriate configuration can be selected in each individual case.

A transverse offset d14 of a bracket 14 with a double-angle profile is illustrated in FIG. 4D. This type of double angle profile is suitable for all three configurations according to FIGS. 4A, 4B and 4C.

7A shows the support structure 15 for a teardrop-shaped arrangement of the conveyor belt 11. For reasons of space in particular, the loaded belt section (left) and the unloaded section (right) are arranged next to one another, that is to say not one above the other. FIG. 8 shows a stand 20 (or modular tower) suitable for this, on which the two strip sections are arranged hanging on both sides. FIG. 7B illustrates the angle a14 formed in particular for a largely closed cross-sectional geometry of the conveyor belt 11 by the coupling 14 (here outwards, in contrast to FIG. 1B).

7A illustrates an overlap region 11.1 or an overlap.

The edge area of the conveyor belt is exposed in that the fastening tab 14 is overlapped upwards or outwards. Depending on the definition, the overlap area can also include the section to which the tab 14 is attached.

It can be seen from FIG. 7A that by means of the couplings 14 an inwardly directed transverse force Fy is exerted on the exposed edge regions of the conveyor belt. In other words: thanks to the angular design of the tabs, the conveyor belt can be arranged completely closed, so that dangerous goods can also be transported in a comparatively reliable manner. The tabs of the couplings 14 of opposite support roller units 13 are arranged at a roof angle β of approximately 30-40 °, and the conveyor belt also assumes this roof angle in the corresponding transverse section.

From FIGS. 7A, 7B it can be seen that for the hose or teardrop-shaped cross-sectional geometry of the conveyor belt, a fastening position of the support rollers on the conveyor belt in a range of approx. 5 ... 10% of the conveyor belt width from the respective edge is preferred. Last but not least, this also favors a complete closing of the conveyor belt (especially for dangerous goods). A web 15.2 of the support structure 15 can be seen both in FIGS. 1A, 3, 4 and in FIGS. 7A, 9, in particular aligned in the plane of rotation of the support rollers. The alignment of the respective web also provides advantages in that only a few bending moments arise. The forces can be passed on with the direction of action in the alignment of the web, in particular also at deflection points.

10A, 10B, 10C also illustrate, in particular, a fastening area xz14 with a horizontal fastening section x14 (in particular with a minimum extension in the longitudinal direction x) and a vertical fastening section z14 (in particular with a minimum extension in the height direction z for at least two fastening points P).

10A shows a variant for the coupling 14 in which several segments

14.1 are provided, which are optionally decoupled from one another in the longitudinal direction x, in particular in the form of flat stiffeners for the flexible material of the conveyor belt. This can also promote force transmission over a large area. 10B shows a comparable embodiment with three segments 14.1, which in this case are coupled to one another by means of hinges. This can ensure the introduction of force in a large fastening area without the flexibility of the band 11 being particularly disadvantageously impaired. The additional joint indicated in FIG. 10C between the uppermost segment of the tab and the further segments below can enable an angle tolerance in the range of a few degrees around a horizontal axis. This joint can optionally be provided if the transverse inclination of the bracket is predefined, but should nevertheless be variable in a small angular range. In this respect, Fig. 10C describes a variant by means of which the upper part of the flap (the one with a roller) can move in a movement-tolerant manner on the lower part (the one attached to the belt) over a movement axis oriented along the conveyor belt, in particular by e.g.

To reduce lateral forces in the rollers when deflecting.

This angle tolerance can, for example, be limited to a few degrees, in particular to align the edge area by means of the tab or

To be able to predefine the coupling.

In the case of the variants shown in FIGS. 10A, 10B, 10C, hinges can be used, in particular with pivot axes in the area of the dash-dot lines.

A comparatively large connecting surface (fastening section) to the conveyor belt can be created by means of the hinges.

At the same time, bending of the tab, in particular when wrapping the conveyor belt around a deflection or drive drum, can also be avoided.

11A illustrates exemplary longitudinal couplings 16.2 for connecting modular guide devices.

The longitudinal couplings 16.2 are described with reference to a tubular cross section of the guide devices 16 by way of example.

The longitudinal couplings 16.2 preferably consist of a pipe centering element which has two cylindrical pins which can be inserted into the two opposite openings of the pipe sections / guide units to be connected with a small sliding gap, and which also has a central cylindrical part that is approximately the same diameter as the outer diameter of the longitudinal pipe.

Furthermore, on both pipe ends to be connected, a flange is fastened to the pipe ends on the side facing away from the track, wherein the flanges can be coupled to one another by means of a screw connection or a spring.

In order to be able to reduce longitudinal stresses in the longitudinal pipes / guide units as a result of ambient temperature changes, the central cylindrical parts of the pipe centering element have a variable width, which e.g. Gap on the running track side of the idlers can be largely closed. By introducing an additional rotary spring, which changes the angular positioning of the pipe centering element depending on the size of the gap between the two pipe halves to be connected, the running wheels can at least approximately smoothly roll over the pipe coupling points. 11B illustrates a wedge-shaped configuration of the central cylindrical part of a pipe centering element of the longitudinal coupling 16.2.

With regard to the preceding figures, the following should also be mentioned for the sake of better clarity: The lines of the supporting structure and of the guide devices used in the figures are sometimes drawn disproportionately thick in the drawings. A contact of the discs of the support rollers or the smaller guide rollers with the guide units or tubular profiles is not provided as standard. In particular, only the double-conical surfaces of the support rollers are in contact with the running rail (tube) of the guide devices.

The fastening or mounting of the support rollers on the conveyor belt or on the support structure are designed in such a way that, both when idling and in the loaded state, only the support rollers mainly contact and transmit force, in particular via double-conical surfaces through two-point contact; other parts of the roller attachment on the conveyor belt (flanges, counter rollers or sliding elements) preferably have no contact, neither with the guide device (pipe rails) nor with the support structure or deflection and drive drums or pipe connecting elements.

The design of the fastening flanges (couplings) on the support rollers or

On the conveyor belt, flange parts can also be vulcanized into the material of the conveyor belt (in particular a rubber layer).

The exemplary embodiments illustrated in the figures described above can be combined with one another with regard to their individual features, unless this is / is not explicitly denied.

LIST OF REFERENCE NUMERALS: 1 material, in particular bulk material 10 conveyor belt system 11 conveyor belt or conveyor belt 11a load strand or loaded belt section in conveying direction 11b empty strand or unloaded belt section counter to conveying direction

11.1 Overlap area or overlap 12 Deflection drum 13 Support roller unit, in particular with a hanging support roller

13.1 conical roller element

13.2 Leading Edge

13.3 Leadership

13.4 encompassing support roller housing 14 coupling, in particular comprising at least one tab 14a tab

14.1 Fastening segment or element

14.2 Joint or axle for segments 15 support structure

15.1 Support structure for additional guide device

15.2 web, in particular aligned in the plane of rotation of the support rollers 16 guide device or further guide device

16.1 securing guide unit

16.2 Longitudinal coupling 17 Guide rail or safety rail, in particular round rod, tube or pipe profile 18 Side support 19 Cross brace 20 Support module 21 Frame or beam 22 Longitudinal brace 23 Floor support d14 Cross offset from tab Fy, inward transverse force

P fastening point T tangent a transverse angle of inclination around the longitudinal axis a14 angle at bracket B roof angle of conveyor belt xz14 fastening area x14 horizontal fastening section (especially in the longitudinal direction) z14 vertical fastening section yii transverse distance y16 span x y, z longitudinal, transverse and height directions

Claims (15)

Patent claims: 1. Conveyor belt system (10) with roller support, in particular for the transport of bulk materials, having at least one conveyor belt (11), a plurality of roller units (13) attached to the conveyor belt and moving with the conveyor belt, and a support structure (15) for the roller units , wherein the conveyor belt system is set up for hanging the conveyor belt by means of the idler roller units in / on the support structure, characterized in that the support structure (15) along the longitudinal extension (x) of the conveyor belt on both sides at least one rigid or at least largely rigid guide device (16 ; 17) for guiding the support roller units, the respective support roller unit being coupled to the edge area of the conveyor belt (11) in such a way that the respective support roller unit is arranged at a predefined angle (a) relative to the transverse alignment of the respective edge area of the conveyor belt, and that de r respective edge area of the conveyor belt is arranged at a predefinable distance (y11) from the corresponding guide device (16). 2. Conveyor belt system (10) according to claim 1, wherein the conveyor belt system provides a coupling (14) to the conveyor belt (11) for each support roller unit which defines a fastening area (xz14) with a plurality of fastening points (P), the fastening points both in vertical Direction as well as in the longitudinal direction are arranged distributed over the fastening area, in particular in pairs, for example four, six, eight, ten or twelve fastening points. 3. Conveyor belt system (10) according to one of the preceding claims, wherein the respective support roller unit (13) is coupled to the conveyor belt by means of a tab (14a), in particular in a fastening area (xy14) with a plurality of fastening points with a predefined relative orientation. 4. Conveyor belt system (10) according to one of the preceding claims, wherein at a respective longitudinal position (x) of the conveyor belt (11) only a single support roller or a pair of opposite support rollers arranged on both sides of the conveyor belt is coupled to the conveyor belt, in particular by means of a / the tab (14a); and / or wherein the conveyor belt system provides a coupling to the conveyor belt for each support roller unit, which is set up for a predefinable angular alignment of the edge of the conveyor belt by means of the coupling; and / or wherein the respective support roller unit is coupled to the conveyor belt by means of a bracket (14a) which, in cross section, forms an angle profile with one or two angles in the range of 20 to 50 degrees, in particular two opposing angles, which have a transverse offset with parallel aligned Ensure fastening sections. 5. Conveyor belt system (10) according to one of the preceding claims, wherein the respective support roller unit is fastened by means of a / the tab (14a) on the outside of an underside or outside of the conveyor belt, the tab (14a) lying flat on the conveyor belt, in particular exclusively on the outside the bottom. 6. Conveyor belt system (10) according to one of the preceding claims, wherein the respective support roller unit (13) is coupled to the conveyor belt (11) by means of a / the tab (14a), the tab either outside with an angular offset inwards or outwards with an angular offset to is arranged and designed inside. 7. Conveyor belt system (10) according to one of the preceding claims, wherein the conveyor belt system is set up to exert an inwardly directed transverse force (Fy) on the respective edge area of the conveyor belt (11), in particular by means of the support roller units or by means of their coupling (14) or tabs (14a ). 8. Conveyor belt system (10) according to one of the preceding claims, wherein the respective support roller unit (13) has a diameter of at least a factor of 1.5 of the diameter of the guide device (16, 17), preferably at least a factor of 2.0, particularly at least a factor of 2, 5; and / or wherein the respective support roller unit has a double-cone profile in cross section; and / or wherein the respective = support roller unit has two support roller elements (13.1) aligned inclined to one another, in particular in a relative arrangement with double-cone geometry. 9. Conveyor belt system (10) according to one of the preceding claims, wherein the two-sided guide devices (16) are connected to one another via cross struts (19) and are coupled to one another segmented in the longitudinal direction; and / or wherein the two-sided guide devices (16) are each formed from individual longitudinal sections, which are modularly coupled to one another by means of longitudinal couplings (16.2) at least in the longitudinal direction in an expansion / movement-tolerant manner; and / or wherein the conveyor belt system is constructed in the longitudinal direction from a multiplicity of support modules (20) which each provide the support structure (15) in the respective longitudinal section. 10. Conveyor belt system (10) according to one of the preceding claims, wherein the support structure comprises centering tensioning elements which each couple adjacent segments or modules of the support structure to one another in the longitudinal direction; and / or wherein the support structure comprises compensation elements which couple individual segments of the support structure that are adjacent in the longitudinal direction and are set up to compensate for tensile / compressive stresses in the guide devices (16) along the conveying path. 11. A method for arranging a conveyor belt (11) in a conveyor belt system (10) with roller support, in particular in a conveyor belt system (10) according to any one of the preceding claims, wherein the conveyor belt (11) is attached to the conveyor belt by means of a plurality of conveyor belts that run along with the conveyor belt Support roller units (13) is arranged and aligned relative to a support structure (15) for the support roller units, namely relative to rigid or at least largely rigid guide devices (16; 17) extending on both sides of the conveyor belt (11), characterized in that the conveyor belt (11) is arranged and aligned by means of the support roller units (13) by coupling the support roller units (13) at a predefinable angle (a) relative to the transverse alignment of the respective edge region of the conveyor belt to the conveyor belt and at a predefinable distance (y11) to the corresponding guide device (16). 12. The method according to the preceding method claim, wherein a force (Fy) is transmitted to the conveyor belt, in particular an inward transverse force, on the respective support roller unit (13) by means of a tab (14a) outside on an underside or outside of the conveyor belt; and / or wherein either an inward angular offset (d14) or an outward angular offset is set on the respective support roller unit by means of a tab (14a). 13. The method according to any one of the preceding method claims, wherein the respective support roller unit (13) is / is coupled to the respective guide device (16; 17) by means of a single support roller, in particular with a roller diameter of at least a factor of 1.5 of the diameter of the guide device (17), preferably at least a factor of 2.0, especially at least a factor of 2.5. 14. The method according to any one of the preceding method claims, wherein the conveyor belt (11) is guided circumferentially, and wherein the conveyor belt is optionally troughed or arranged with a closed hose cross-section, in particular with a transverse distance between the side of the conveyor belt and opposite guide devices along the conveyor path in the range of 50 to 120 percent of the width of the conveyor belt or in the range of 5 to 50 percent of the width of the conveyor belt. 15. Use of a coupling (14) between individual support roller units (13) and a conveyor belt (11) for a suspended arrangement of the conveyor belt in / on a support structure (15) on two rigid or at least largely rigid guide devices (16) of a conveyor belt system (10) , in particular in a conveyor belt system (10) according to one of the preceding device claims, wherein the conveyor belt (11) is arranged and aligned by means of the couplings (14) and the support roller units by the support roller units at a predefinable angle (a) relative to the transverse alignment of the respective edge area of the Conveyor belt to the conveyor belt and at a predefinable distance (y11) to the corresponding guide device (16; 17) are coupled.