WO2005098267A1 - Power transmission chain - Google Patents

Abstract

A power transmission chain (1) whose links (2) respectively comprise two opposite lateral parts (3), wherein at least one of the links is provided with at least one flight connecting said lateral parts. In order to receive high forces and to be suitable for high process speeds with flat chain links, the invention is characterized in that the ratio of the width to the height of the lateral parts (3) is greater than/ the same as 1:4, the articulated connections of adjacent links (2) are embodied as articulated elements (13) which act as a bridge for said links and which are deformable when the chain is deviated, and the links (2) respectively comprise front surface sides (2a) which face adjacent links (2) and which extend continuously along the entire width of the lateral parts (3), acting as stop surfaces (14,15).

Description

 Power supply chain

The invention relates to an energy guide chain for guiding hoses, cables or the like with a plurality of links which are each articulated to one another by means of articulated connections and each have two opposite side parts with inner and outer side surfaces, at least some of the links connecting at least one of the side parts of a link Have cross bar, so that through the side parts and the cross bars of the chain, a chain interior with a cable guide channel is provided, the links further having paired abutment surfaces to limit the pivoting angle of adjacent links against each other.

Such energy chains are used to guide hoses, cables or the like between two consumers, at least one of which is movable. In certain applications, particularly flat chain links are desirable, for example if a large number of cables, hoses or lines arranged next to one another are to be fed to a consumer in a single-layer arrangement, or if the spatial conditions so require. At the same time, however, some of the links can have a very large width and / or high travel speeds of the energy chain are desirable, so that the chain as a whole is exposed to great forces. Due to the flat links, which must strike each other and absorb forces when the chain is deflected, the possible uses of the chain are limited.

The invention is therefore based on the object To create an energy chain that can be exposed to high forces and travel speeds even with very flat links and that can be operated safely and reliably.

The problem is solved by an energy chain, in which the ratio of the width to the height of the side parts of the links is greater than / equal to 1: 4 and the link connections of adjacent links are bridged as adjacent links and are deformable when the chain is deflected, and wherein the Links each have adjacent faces facing the adjacent links, which extend continuously over the entire width of the side parts without step-like structures and- ^{• function} as stop faces.

Because the articulated connections are designed as deformable articulated elements that bridge the adjacent links and preferably extend in the longitudinal direction of the chain, the articulated elements can absorb high loads even at very low heights, while at the same time otherwise known pin-and-tenon joints that are used with very flat links and high forces have proven to be no longer appropriate. Furthermore, the wide links above and / or below the articulated connections can provide large stop surfaces for the links, so that the links can absorb high forces despite their height, in particular when the chain is moved into its extended position. The term “above” is understood here and in the following to refer to the links of the upper run, so that the “upper narrow surface” of the links faces away from the opposite run and the “lower narrow surface” of the links faces the respective opposite run the end faces of the side parts facing the respectively adjacent links are designed to be continuous over their entire width, so that the side parts come into abutment with one another over their entire width Stop surfaces no offset, in particular step offset and are preferably flat, optionally also arched. In particular, the opposite side parts overlapping areas can be dispensed with, whose extension in the chain longitudinal direction is greater than / equal to H or corresponds to half the width of the side parts. The combination of the above-mentioned features thus provides an energy guide chain which can absorb high forces even with very flat links, which enables both comparatively wide chain links and high chain travel speeds. The links can easily have a height of less than 2 to 3 cm, for example a height of less than / equal to 1.5 cm or approximately 1 cm or less.

In particular, areas that overlap laterally with one another may be missing on the links, which overlap with one another over the entire or over more than half or more than a quarter of the pivoting angle of the links, so that the links are guided, so to speak, solely through the articulated connection, the inventive design the chain has proven particularly smooth.

In particular, the ratio of the width to the height of the side parts can be less than or equal to 1: 3, for example approximately 1: 2 or less.

The ratio of the width to the height of the links can be greater than / equal to 2: 1, in particular greater than / equal to 3: 1 or greater than / equal to 4: 1 to 5: 1.

The ratio of the width to the height of the stop surfaces (in particular the stop surfaces acting in the extended position) can be greater than / equal to 1: 2, in particular greater than / equal to 3/8, particularly preferably greater than / equal to 3/4. Due to the large width of the side parts, it is advantageous if they have recesses within their cross-sectional contour which are open to the inner and / or outer, preferably only to the outer side surface of the side parts and whose depth is greater than / equal to 50% or greater than / equal to 75% corresponds to the side section width. The extent of the recesses is essentially limited only by the resulting stability of the links.

The recesses are preferably delimited by a closed, peripheral edge. Regardless of this or at the same time, the recesses can be at least partially or completely delimited from the joint elements by an edge region, the edge preferably extending over the entire longitudinal extent and preferably also the entire width of the side parts.

In particular, the recesses can only extend above and / or below the respective articulated connections of the links. The joint elements can be guided and held along their extension area over the side parts in the chain longitudinal direction on the upper and / or lower side on corresponding guide areas of the side parts. In this case, the guide areas of the side parts, which can be designed in particular as the edge area of the recesses, preferably lie closely and without play on the joint elements, in particular in a press fit. The edge which delimits the recesses and which is arranged above and / or below the joint elements can be made thin in such a way that it extends to the joint element except for a holding area necessary for fixing the joint element. The thickness of this holding area can be less than or equal to three times, twice or once the thickness or diameter of the joint element, for example the height of a flat joint element or hinge. The recesses can be a occupy the largest possible extent, at the same time always ensuring an exact and secure mounting of the joint elements if they extend past the side parts. The thickness of the edge which otherwise surrounds the recess can also be less than / equal to three, twice or one thickness of the joint element.

The joint elements can generally connect two or more links to each other in the longitudinal direction of the chain, the joint elements preferably each being fastened to the respective link in a way that absorbs tensile force. The joint elements preferably extend between the end faces of the adjacent links. The tensile force-absorbing connection of the joint elements to the links can be achieved by undercut areas, which are preferably provided on the links, in particular on the side parts, and are engaged behind by holding areas of the joint elements. Preferably, the articulated elements in the chain longitudinal direction and / or in the chain transverse direction are secured against displacement on the links, in particular on the side parts, and in particular are held in a press fit for this purpose. The regions of the joint elements which are deformed when the chain is deflected preferably extend over more than half, in particular at least approximately the entire width of the side parts, the joint elements preferably not projecting laterally from the side parts and being arranged completely in the cross section of the side parts. The joint elements are preferably designed as plate-like or band-shaped elements. The joint areas between respectively adjacent links can be connected to one another by transition areas that have a smaller width than the formable joint areas. The transition regions preferably extend in guides along the side parts and can be fixed in a position-invariable manner on the top and bottom sides. Furthermore, the joint elements, if they are over several links extend, have a holding area, for example in the form of a cross-sectional widening, on each area facing the adjacent link, thereby ensuring a secure fit of the joint elements. In particular in combination with a comparatively large width of the side parts, a broad configuration of the joint elements is expedient, since the side and / or torsional stability of the chain is largely or exclusively determined by the joint elements. This applies in particular when the links do not have any areas that laterally overlap with one another over all or a larger part, for example more than 75%, of the pivoting angle. If necessary, the joint elements can also be designed as an articulated band arranged on the crossbars and / or undersides of the side parts, which connects several links and can extend continuously over the chain length. The band can be arranged on the side of the crossbars facing or facing away from the chain, or it can be passed through through-openings of the crossbars, which can be slit-like.

The joint elements can thus connect the links to one another in pairs or groups or extend or the entire length of the chain.

Preferably, the joint elements are offset relative to half the height of the links in the direction of the narrow side of the links facing the opposite strand and at the same time spaced in height from the transverse webs, i.e. staggered towards the inside of the chain. The joint elements are preferably arranged approximately at approximately 1/5 to approximately 1/3 of the height of the links.

The joint elements are preferably designed as elastically deformable links which can be deformed when the chain is deflected while exerting a restoring force. Furthermore, the joint elements are preferably designed as separate components, which are non-detachably or preferably releasably attached to the links or side parts, for example by a positive and / or non-positive and / or material connection. The joint elements on the one hand and the side parts or links on the other hand can thus consist of different materials, in particular plastic materials.

The side parts preferably have end-side recesses which are provided above and / or below the joint connections and extend as far as the joint connections, the recesses being able in each case to widen in the direction of the joint connections. The recesses can each extend over the entire width of the side parts, possibly also only over the width of the respective articulated connections. The recesses make it possible, in particular, to change the position of regions of the joint elements deformed when the chain is deflected.

The stop surfaces that come into contact with one another when the chain is deflected, and thus define the radius of curvature of the chain, can extend obliquely to the longitudinal direction of the chain in relation to the extended position of the chain. This preferably applies to the two stop surfaces of a link or a side part, each of which faces the link in front or behind in the chain direction. The stop surfaces can be spaced from the articulated connection in relation to the height of the links and pass into a recessed area, the stop surfaces preferably also not having a step offset here and / or extending over the entire width of the links. Despite the deformation of the joint elements when the chain is deflected, the deformed area having a certain extent in the longitudinal direction of the chain, the corresponding stop surfaces of adjacent links can always Strike against each other exactly aligned. The recessed area can spring back by one or more times the thickness or the diameter of the joint areas of the joint elements.

The mutually facing end regions of the stop surfaces, which come into contact with one another when the chain is deflected, are preferably spaced apart from one another in the extended position of the chain. Preferably, alternatively or simultaneously, the end faces that come into contact with one another in the extended position of the chain are each arranged at least approximately perpendicular to the longitudinal direction of the chain. The stop surfaces can end at a distance, in particular, from the hinge elements. The distances mentioned can each independently be 1, 2 or more times the strength or diameter of the joint elements or, for example, greater than / equal to 2%, greater than / equal to 5% or greater than / equal to 10% of the diameter of the joint elements in the deflection area certain section of the circle.

Furthermore, the links are preferably rigid in relation to the stresses on the chain when used as intended. Furthermore, the at least one cross bar connecting the opposite side parts of a link is preferably connected in one piece to the side parts. The crossbar is further arranged - possibly independently of this - on the lower region of the side parts and is essentially or exactly flush with the adjacent narrow side of the side parts. Another crossbar of the links can be releasably attachable to the links or side parts thereof, in particular by positive and / or non-positive connections, in particular by latching connections. The links are preferably essentially rigid with respect to the manipulations required for fastening the crossbars, so that any elastically deformable locking means are provided on the crossbars. At least some or all of the crossbars of the chain are preferably connected to one another on at least one narrow side of the links, for example the top of the links facing away from the opposite strand, by at least one variable-length element, which is fixed to the crossbars in a force-absorbing manner. Such variable-length elements are preferably arranged at the two ends of the crossbars. The elements variable in length can be provided, for example, by arc-shaped or loop-shaped regions which connect the respective transverse webs to one another. The elements or areas are preferably formed in one piece on the transverse webs. This initially enables easier handling of the crossbars when they are attached to the links, since several or all crossbars of the chain are combined to form a strand-like component and the crossbars are already pre-oriented with respect to their desired position on the links. If necessary, the elements can also have an intrinsic extensibility in the manner of rubber-elastic elements, but preferably a change in length occurs due to a change in shape of the elements.

The elements variable in length can be deformed when the chain is deflected while exerting a restoring force. If, for example, the transverse webs of the links facing away from the opposite strand are connected to one another by elements that are variable in length, the elements that are variable in length are elongated in the deflection area of the chain. By exerting a restoring force, the properties of the chain can be changed when it is deflected, in addition or as an alternative to a restoring force exerted by the joint elements, which can be of importance particularly in the case of very flat links.

Furthermore, the variable-length elements in a Deflect the chain from the chain cross section in the direction of the storage surface of the chain, so that the chain is damped when it is deposited on a surface.

Furthermore, the chain according to the invention can have a comparatively small deflection radius, the joint element being able to be arranged at a distance from the respective lower crosspiece. The lower crossbars of the links can be arranged adjacent to the lower narrow sides, so that no significant stop areas are provided below the crossbars or between the crossbar and the lower narrow side of the side parts - and thus the chain cross section can be optimally used. The ratio of the upper side parts of the links, which face away from the opposite strand, to the deflection radius defined by the joint elements can be less than / equal to 5, preferably less than / equal to 4, in particular approximately 3.

The inner radius of the chain in the deflection area is preferably less than / equal to 1.75 times, preferably less than / equal to 1.5 times the height of the links or corresponds approximately to the height of the links.

The invention is described below by way of example and explained by way of example with reference to the figures. Show it:

FIG. 1 shows a side view of a chain according to the invention,

FIG. 2 shows an end view of a link of the chain according to FIG. 1,

FIG. 3 shows a top view of a chain according to FIG. 1.

The energy chain 1 according to the invention according to Figures 1 to 3 has a plurality of articulated to each other Links 2, each consisting of two opposite side parts 3 and two transverse webs 4 connecting them to each other, it not necessarily being necessary for each of the links to be provided with two transverse webs. The chain thus provides a channel 5 for guiding lines or the like. According to FIG. 1, the chain is deposited with the formation of an upper run 6, a deflection area 7 and a lower run 8. The side parts 3 of the links each have inner and outer side surfaces 9, 10 and essentially vertical upper and lower narrow sides 11, 12, which define the height of the links. Joint elements 13 are arranged between the narrow sides 11, 12 and at a height from the transverse webs, in the exemplary embodiment arranged at about a third of the height of the links, which articulate the adjacent links with one another. The pivoting angle of the links in the extended position of the chain is limited by stop faces 14 of the side parts arranged on the end faces 2a, the pivoting angle in the deflection area of the chain by end stop faces 15. The stop faces 14, 15 extend continuously over the entire width of the side parts and are also each formed as flat surfaces. According to the exemplary embodiment, the joint elements are arranged approximately at a third of the height of the links and are thus spaced apart from the transverse webs, so that the stop surfaces 15 acting in the deflection area can also take up a sufficiently large area. The lower crosspieces 4a are integrally formed on the side parts and are essentially or exactly flush with the lower narrow side 11 of the links.

According to the exemplary embodiment, the ratio of the width to the height of the links is approximately 5.6, the ratio of the width to the height of the side parts of the links is approximately 1: 2. The ratio of the width to the height of the stop surfaces 14 interacting in the extended position of the chain is approximately 3: 4. The ratio of Link height to the outer diameter of the chain in the deflection area is approx. 1: 3, the ratio of the height of the links to the diameter of the deflection area formed by the joint elements or the vertical distance of the joint elements from the upper run and lower run is approx. 1: 2. The inner radius of the chain in the deflection area corresponds to 1.5 times the link height.

As a result, a chain with comparatively flat links is provided, which has high stability and smooth running, the links being able to take up a large width.

Due to the very wide side parts, these have recesses 16, 17 to save weight, which are only open on one side to the outside of the links and extend to a wall thickness of the side part inside that is necessary for the stability of the links, so that the inner side surface of the side parts is not broken. According to the exemplary embodiment, the depth of the recesses thus corresponds to approximately 80% of the width of the side parts. The recesses are each delimited by a circumferential, closed edge 18, 19, the edge optionally also having openings. The edges 18, 19 have a constant wall thickness, without this being always necessary. The wall thickness of the edges 18, 19 can be approximately the thickness of the joint elements 13, i.e. H. whose extension along the height of the limbs correspond. The thickness of the edge also corresponds to less than half the width of the side parts, for example approximately a quarter or less of the same.

According to the exemplary embodiment, the two strands of side parts which form the chain are each assigned an articulated element 13 which extends over the entire length of the chain. The joint element has elastically deformable regions 20 which extend between the end faces of adjacent links and when deflected exert a restoring force on the links on the chain. These "joint sections" are connected to one another by holding areas 21 to form a continuous strand, the holding areas 21 having a smaller width than that of the deformable areas 20, for example half the width or less. The holding areas furthermore have at least one, in the exemplary embodiment two of them spaced fastening areas 21a, which are formed here as thickened portions and each permit tensile force-absorbing fastening of the joint elements are provided at the level of the holding areas by the edges of the recesses 16, 17. It goes without saying that, alternatively or additionally, suitable form-locking means such as snap-in connections between the articulated elements ten and the side parts. According to the exemplary embodiment, the joint regions and the holding regions of the joint elements have different strengths.

Furthermore, the side parts are provided with a recess extending above and below the joint elements 13 in the form of an indentation 22, which has its greatest extension in the chain longitudinal direction at the level of the joint elements and also extends over the entire width of the side parts. In combination with the stop surfaces 15, recessed areas 23 are hereby formed on the end faces of the side parts. As a result, the mutually adjacent end regions of the abutment surfaces 15 of mutually adjacent members are spaced apart, for example by more than a quarter or approximately half the width of the side parts. Furthermore, the end regions 15a of the stop surfaces and also the stop surfaces 14 of the links are spaced from the joint elements 13 in relation to the height of the side parts. The Stop surfaces 15 run obliquely to the chain longitudinal direction, the angle being different from 90 ° and, according to the exemplary embodiment, being approximately 60 °.

The further stop surfaces 14, which cooperate in the extended position of the chain, run essentially perpendicular to the longitudinal direction of the chain. The ratio of the stop surfaces acting in the deflection area of the chain to the stop surface acting in the extended position is less than 1: 1, for example less than / equal to 0.8: 1, according to the exemplary embodiment approximately 1: 2.

Furthermore, the cross webs 25 of the links facing away from the opposite run, ie the “upper” cross webs of the upper run, are detachable, in particular by latching connections 27, attached to the links and each connected by position-changing elements 26. These elements 26 are integral with the The elements are curved or loop-shaped, as a result of which the cross bars of the chain are permanently connected to one another, but can nevertheless be at a variable distance from one another, as is necessary when the chain is transferred to its deflection area, since the cross bars are not in the It is understood that the shape of the variable-length regions is not limited to the shape shown and that these can also be angular, zigzag-shaped or in some other way. Furthermore, the variable-length elements 26 are designed such that they are at Redirecting the chain over d The link cross-section must protrude outwards so that the chain can be dampened. Furthermore, the length-variable elements 26 can exert a restoring force on the chain when the chain is deflected, in which it is stretched or pulled apart with respect to the arrangement in the extended position of the chain, so that at the same time the travel properties of the chain are advantageously influenced. Power supply chain

LIST OF REFERENCE SIGNS LIST chain Glieda end face side part crossbar channel upper run deflection area lower run, 10 side surface1, 12 narrow side3 joint element4, 15 stop surface5a stop surface area6, 17 recess8, 19 edge0 deformable joint area1 holding area1a fastening area2 indentation5 crossbar6 length-adjustable element7 snap-in connections

Claims

Energy chain claims

1. Energy guiding chain for guiding hoses, cables or the like with a plurality of respective means of articulated joints pivotally interconnected members having two opposing side portions having inner and outer side surfaces, respectively, wherein at least some of the members of at least one the side portions of a limb ^{"interconnecting} transverse web have, so that through the side parts and the crossbars of the chain a chain interior with a cable guide channel is provided, the links further having pairs that can be brought into contact with one another to limit the pivoting angle of adjacent links, characterized in that the ratio of the Width to the height of the side parts (3) of the links greater than or equal to 1: 4 is that the articulated connections of adjacent links (2) bridging as adjacent links (2) bridging joint elements (13) deformable when the chain (1) is deflected a are carried out, and that the links (2) each have the end faces (2a) facing the adjacent links (2), which extend continuously over the entire width of the side parts (3) and act as stop surfaces (14, 15).

Energy chain according to claim 1, characterized in that the ratio of the width to the height of the links (2) is greater than / equal to 2: 1 or greater than / equal to 4: 1.

Energy chain according to claim 1 or 2, characterized ge kenni chnet that the hinge elements (13) between the upper and lower narrow sides (11, 12) of the side parts (3) are arranged and extend at least partially between the inner and outer side surfaces (9, 10) of the side parts and related to half the height of the links (2) are offset in the direction of the narrow side (11, 12) of the links facing the opposite strand.

4. Energy supply chain according to one of claims 1 to 3, since by ge kenn zei chne t that the side parts (3) of the links within their cross-sectional contour to the inside and / or outside (9, 10) of the side parts open recesses (16, 17), the depth of which corresponds to 50% or more of the width of the side parts.

5. Energy guiding chain according to claim 4, so that the recesses (16, 17) are delimited by a closed peripheral edge (18, 19) and are each only above and / or below the respective articulated connections (13). the limbs extend.

6. Energy guiding chain claim 5, thus indicating that the side parts (3) on both sides of the joint elements (13) are each provided with a recess (16, 17) which, apart from a holding area necessary for fixing the joint element up to extends the joint element.

7. Energy guiding chain according to one of claims 1 to 6, characterized in that the link elements (13) each connect two or more links (2) in the chain longitudinal direction and the link elements (13) on each of the links are attached to absorbing traction.

8. Energy guiding chain according to one of claims 1 to 7, thus indicating that the joint elements (13) are designed as elastically deformable links which are deformable by deflecting the chain (1) while exerting a restoring force.

9. Energy guiding chain according to one of claims 1 to 8, thus indicating that the side parts (3) have end-side recesses (22) which extend above and / or below the articulated connections (13) as far as these.

10. Energy guiding chain according to one of claims 1 to 9, so that ge mark zei chnet that the side parts (3) at least on the side facing the opposite strand at least one at a deflection of the chain as a stop surface (15) acting end face region in The stretched position of the chain extends obliquely to the longitudinal direction of the chain and that the stop surface passes into a recessed area at a distance from the articulated connection (13).

11. Energy guiding chain according to claim 10, characterized in that, in the extended position of the chain (1), the stop areas (15a) adjoining the recessed areas are spaced apart from one another in the chain longitudinal direction.

12. Energy chain according to one of claims 1 to 11, since you rchge ke nn zeic hn et that the end faces in the extended position of the chain (1) abutting abutment surfaces (14) each run at least approximately perpendicular to the chain longitudinal direction and in height end spaced from the joint elements.

13. Energy guiding chain according to one of claims 1 to 12, thus indicating that at least some of the transverse webs (25) are connected to one another on at least one narrow side of the links by variable-length elements (26), each of which absorbs force on the transverse webs (25 ) are set.

14. Energy guiding chain according to claim 13, so that the length-variable elements (26) are deformed when the chain is deflected while exerting a restoring force and / or when the chain (1) is deflected with a support of the chain.

15. Energy guiding chain according to one of claims 1 to 14, since you r c h g e ke nn z e i c hn e t that the inner radius of the chain (1) in the deflection area is less than / equal to the 1.75-f eighth height of the links (2).