Abstract
A method for producing a conduit for a clean room application, comprising electric cables and an elongate flexible sheath which can be moved back and forth so as to form a deflecting bend between two towers, wherein the flexible sheath has a number of parallel receiving portions, each for at least one cable, wherein each receiving portion extends in the manner of a channel in a longitudinal direction from a first end to a second end; the method comprising the steps of providing at least one cable bundle of contiguous cables and providing the flexible sheath, wherein the sheath is prefabricated and the cable bundle is introduced into a receiving portion of the prefabricated sheath, wherein the prefabricated sheath comprises at least one sleeve unit having two interacting closure profiles of a closure in order to close an open state in a dust-tight manner and the cable bundle is inserted into the opened sheath transversely to the longitudinal direction or the prefabricated sheath comprises at least one sleeve unit which is produced so as to be circumferentially closed and the cable bundle is drawn into the closed sleeve unit in the longitudinal direction.
Claims
1-30. (canceled)
31. A method for the production of a line guide for a clean room application, with electric lines and an elongate flexible enclosure which is reciprocatingly displaceable with the formation of a direction-changing arc between two runs, wherein the flexible enclosure has a number of parallel receiving means for at least one respective line, wherein each receiving means extends passage-like in a longitudinal direction from a first end to a second end; the method comprising at least the steps of: providing at least one line bundle of interrelated lines; and providing the flexible enclosure, wherein: the enclosure is prefabricated and the line bundle is introduced into a receiving means of the prefabricated enclosure, wherein the at least one line bundle of interrelated lines includes a wire bundle comprising at least two twisted wires each having its own insulation, wherein the at least one line bundle does not have its own respective outer sheath, and wherein: the prefabricated enclosure comprises at least one enclosure unit having two cooperating closure profiles of a closure for dust-tightly closing an opened state and the line bundles introduced transversely to the longitudinal direction into the opened enclosure; or the prefabricated enclosure includes at least one enclosure unit which is produced peripherally closed and the line bundle is drawn into the closed enclosure unit in the longitudinal direction.
32. The method according to claim 31, wherein the line bundle includes an outward separating layer comprising a slidable material, a material which at its outside includes a fluoropolymer.
33. The method according to claim 32, wherein the outward separating layer is in the form of banding, in particular strips of a PTFE-bearing film or a PTFE-bearing non-woven fabric.
34. The method according to claim 33, wherein the banding has at least one wrapping in opposite directions.
35. The method according to claim 31, wherein: the line bundle includes at least two highly flexible stranded lines, stranded lines with an individual wire diameter<0.1 mm, and/or super-fine stranded lines; and/or that the line bundle includes at least two stranded lines having an insulation comprising a fluoropolymer like for example a PTFE, PFA, PVDF, ETFE, FEP or the like; and/or that the line bundle includes a tension-resistant core element.
36. The method according to claim 31, wherein the line bundle includes a wire bundle comprising at least six layer-stranded or bundle-stranded wires.
37. The method according to claim 31, wherein the opened enclosure is dust-tightly closed after introduction of the line bundles by means of the closure profiles.
38. The method according to claim 31, wherein each enclosure unit is prefabricated and has two fixing strips which are in opposite relationship at both sides and which are in one piece with the enclosure unit, including the step of connecting the prefabricated enclosure units together in parallel to form an enclosure.
39. A line guide for lines like for example cables and/or hoses for a clean room application, comprising an elongate flexible enclosure which is reciprocatingly displaceable with the formation of a direction-changing arc between two runs, and has a plurality of receiving means for at least one respective line, wherein each receiving means extends passage-like in a longitudinal direction from a first end to a second end, wherein the enclosure is separately prefabricated and a respective line bundle is introduced into at least some receiving means, wherein the at least one line bundle of interrelated lines includes a wire bundle comprising at least two twisted wires each having its own insulation, wherein the at least one line bundle does not have its own respective outer sheath, and wherein the enclosure forms the outer sheath of the line bundle.
40. The line guide according to claim 39, wherein each line bundle of interrelated lines includes a wire bundle comprising at least two twisted wires each having their own insulation; and each line bundle does not have its own outer sheath.
41. The line guide according to claim 39, wherein the line bundle includes an outward separating layer comprising a slidable material, a material which at its outside includes a fluoropolymer.
42. The line guide according to claim 40, wherein the outward separating layer is in the form of banding, in particular strips of a PTFE-bearing film or a PTFE-bearing non-woven fabric.
43. The line guide according to claim 41, wherein the banding has at least one wrapping in opposite directions.
44. The line guide according to claim 39, wherein: the line bundle includes at least two highly flexible stranded lines, in particular stranded lines with an individual wire diameter<0.1 mm; and/or super-fine stranded lines; and/or that the line bundle includes at least two stranded lines having an insulation comprising a fluoropolymer like for example a PTFE, PFA, PVDF, ETFE, FEP or the like; and/or that the line bundle includes a tension-resistant core element.
45. The line guide according to claim 39, wherein the line bundle includes a wire bundle comprising at least six layer-stranded or bundle-stranded wires.
46. The method according to claim 31, wherein each line bundle is replaceably introduced into a corresponding receiving means of the prefabricated enclosure.
47. The method according to claim 31, wherein the prefabricated enclosure comprises: a plurality of enclosure units respectively produced with cooperating closure profiles, in particular enclosure units which are extruded in one piece in the opened state; and/or a plurality of enclosure units which are produced peripherally closed, in particular enclosure units extruded in the form of closed profiles, and/or each enclosure unit has two fixing strips which are opposite on both sides and which are in one piece with the enclosure units and by means of which adjacent enclosure units are connected together in parallel, and/or the enclosure comprises enclosure units of flexurally elastic plastic, wherein each enclosure unit is of a cross-section which remains the same in the longitudinal direction.
48. The line guide for a clean room application produced by the method according to claim 31.
49. An enclosure unit of plastic for an elongate flexible enclosure of a line guide, wherein the enclosure unit forms at least one receiving means for guiding at least one line and which extends passage-like in a longitudinal direction from a first end to a second end and has an enclosure wall comprising a flexible plastic, wherein: the enclosure unit includes a first fixing strip at one longitudinal side and a second fixing strip at the other longitudinal side, wherein the fixing strips are designed in mutually matching relationship for forming a releasable connection; and the fixing strips are flexurally stiffer in comparison with the enclosure wall, wherein the fixing strips include in particular a plastic which is harder in comparison with the enclosure wall and/or in particular of a flexurally stiffer design configuration.
50. The enclosure unit according to claim 49, wherein the fixing strips are produced in one piece with the enclosure wall, from a first plastic for the enclosure wall and a harder second plastic for the fixing strips, in particular using a co-extrusion method or by subsequent material-bonded connection of the fixing strips to the enclosure wall.
51. The enclosure unit according to claim 49, wherein it has at least at the outside on the enclosure wall and/or on a fixing strip at least one sliding friction-reducing layer, in particular a layer comprising a third plastic with a lower sliding coefficient in relation to the first and second plastics, wherein the enclosure unit is produced from three different plastics in a tri-extrusion method and/or the third plastic is a polyethylene, in particular a PE-HMW or PE-UHMW.
52. The enclosure unit according to claim 50, wherein the fixing strips are designed in conjugate relationship with male and female cross-sections and the sliding friction-reducing layer is provided at least at the outside of the female fixing strip, and/or the sliding friction-reducing layer covers at least at one side a predominant surface proportion of the outer surface of the enclosure wall, and/or the sliding friction-reducing layer is of a layer thickness which is <20% of the thickness of the enclosure wall.
53. The enclosure unit according to claim 49, wherein the enclosure unit is produced in unitary material fashion from a thermoplastic elastomer (TPE), in particular a TPS, TPU or TPO, from a TPE suitable for production in a hot extrusion method.
54. The enclosure unit according to claim 49, wherein the fixing strips are designed in mutually conjugate relationship in the form of extruded fixing profiles with a cross-section which is continuously the same in the longitudinal direction and they cooperate in interengaging relationship, and/or the fixing strips are of a symmetrical configuration relative to a central plane, in particular relative to the neutral fibre, wherein the first fixing strip and/or the second fixing strip has two symmetrically arranged inclined insertion portions.
55. The enclosure unit according to claim 49, wherein the fixing profiles are of such a configuration that in comparison with the connection of mutually matching fixing strips in the connecting direction they are releasable only with a markedly higher application of force in opposite relationship to the connecting direction or are releasable only in the longitudinal direction, wherein the fixing strips are of a cross-section with a barb function.
56. The enclosure unit according to claim 49, wherein each receiving means has two cooperating closure strips of a closure, that extend in the longitudinal direction, for dust-tight closure of an opened state in which a line can be introduced into or removed from one of the receiving means transversely relative to the longitudinal direction.
57. The enclosure unit according to claim 49, wherein the fixing strips are adapted to be connected together in a connecting direction transversely relative to the longitudinal direction in order to releasably fix together a plurality of enclosure units with mutually matching fixing strips by connection of the fixing strips in the connecting direction transversely relative to the longitudinal direction.
58. The enclosure unit according to claim 55, wherein the closure strips are closable and openable respectively by a force substantially perpendicular to the connecting direction of the fixing strips.
59. The enclosure unit according to 49, wherein it forms precisely one tubular receiving means for separate guidance of at least one respective line.
Description
BRIEF DESCRIPTION OF THE DRAWINGS
[0074] Further details and advantages of the invention will be apparent without limitation on the generality of the foregoing from the description hereinafter of preferred embodiments by way of example with reference to the accompanying drawings in which:
[0075] FIGS. 1A-1B show a first embodiment by way of example of a displaceable line protective guide having a flexible enclosure, as a partial view of an end region, partly broken-way (FIG. 1A) and a typical arrangement of a line protective guide or line guide device as a diagrammatic side view,
[0076] FIG. 2 shows a stranding of for example four individual wires to form a line bundle comprising interrelated lines,
[0077] FIG. 3 shows a banding by wrapping in opposite directions of the stranded individual wires of FIG. 2 for producing a line bundle without its own outer sheath,
[0078] FIG. 4 diagrammatically shows the method step of drawing a line bundle as shown in FIG. 3 into an enclosure unit which is prefabricated in a closed condition for the production of an enclosure for a dust-tight dynamic line guide,
[0079] FIGS. 5A-5B show as alternative method steps lateral insertion of a line bundle as shown in FIG. 3 into an openable enclosure unit (FIG. 5B), the closed state of by way of example two enclosure units which were subsequently connected together for producing an enclosure for dust-tight dynamic line guidance, at the same time FIGS. 5A-5B show a preferred variant of an openable or closable prefabricated enclosure unit,
[0080] FIG. 6 is a purely diagrammatic perspective view of an enclosure produced in accordance with the principle shown in FIG. 4 or FIGS. 5A-5B respectively,
[0081] FIGS. 7A-7C show a preferred variant of an enclosure unit prefabricated in a closed condition (as a so-called individual pod),
[0082] FIGS. 8A-8C show variants of enclosure units with sliding friction-reducing layers at different regions of the outside,
[0083] FIGS. 9A-9D show a further embodiment with an enclosure unit having a plurality of receiving means and releasably connected together by lateral fixing profiles,
[0084] FIGS. 10A-10D show a particularly preferred embodiment with an enclosure unit having a plurality of receiving means which can be individually filled, and preferred cross-sections of associated functional regions, and
[0085] FIGS. 11-12 show further embodiments as variants in relation to FIGS. 10A-10D.
DETAILED DESCRIPTION
[0086] FIGS. 1A-1B diagrammatically show a first embodiment of a reciprocable line protective guide for lines (not shown). It has an elongate flexible enclosure 100 composed of a plurality of individual enclosure units 101 made from plastic. Each enclosure unit 101 is produced from flexible soft-elastic plastic, in particular a thermoplastic, for example PE, PU, TPU, PTFE, expanded PTFE, PP or the like. Over its length each enclosure unit 101 is of a cross-section which remains the same throughout (FIG. 1B) perpendicularly to the longitudinal direction L. The enclosure unit 101 can be for example inexpensively produced in the form of an extrusion in a suitable plastic extrusion process and can be cut to an appropriate length, for example from about 100 mm to about 1500 mm. The structurally identical enclosure units 101 form in the interior thereof a substantially cylindrical receiving means 102 for protective guidance of a line and for that purpose are of a tubular configuration with wall regions 103 which are of thin gauge in relation to the cross-section of the receiving means 102. The receiving means 102 of the flexible enclosure are spatially separated from each other so that no abrasion can occur between lines which are guided in parallel therein.
[0087] FIG. 1A further shows one of two end clamping devices 130 having two clamping portions 131, 132, between which all enclosure units 101 of the enclosure 100 together with lines (not shown) guided therein are dust-tightly closed off at the end and in the axial direction, for example by clamping screws. The clamping devices 130 can at the same time also provide for tensile stress relief of the lines (not shown) and can be of a per se known structural configuration, for example similarly to the teaching of DE 10 2012 100 290 B4 incorporated herein in that respect.
[0088] FIG. 1A shows one of two support chains 135, which is accommodated in the receiving means 102 of the two laterally outer enclosure units 101 and comprises individual chain links. Optional support chains 135 on the one hand can predetermine the minimum permissible radius of the direction-changing arc 4 (FIG. 8) to protect the chain from kinking and on the other hand by means of abutments for the chain links in the straight position can increase the self-supporting length of the enclosure 100 in the moveable run, for example in the upper run 1 (FIG. 8).
[0089] FIG. 1B diagrammatically shows a configuration of a dynamic line guide with dust-tight enclosure 100, for example according to FIG. 1A, forming a moveable upper run 1 and a stationary lower run 3. Between them the enclosure 100 forms a direction-changing arc 4 of predetermined bending radius about a notional axis A. The direction-changing arc 4 travels over a distance relative to a stationary connection 5 when the upper run 1 is displaced with the moveable connection 7. Any spatial position can be involved here however, the enclosure 100 can also move vertically or laterally. The two ends of the enclosure 100 are dust-tightly closed, for example with clamping devices as shown in FIG. 1A. The enclosure 100 is overall of a hose-like configuration and is sufficiently flexible, inter alia by virtue of a suitable configuration and/or by a suitable choice of material, to allow reversible flexible curvature of the direction-changing arc 4 with the application of a small amount of applied force, and to follow the travel movement of the moveable connection 7 with the lowest possible resistance.
[0090] FIGS. 9A-9D diagrammatically show an enclosure 900 made up from a plurality of individual enclosure units 901. The enclosure units 901 each form one or more receiving means 902. In contrast to FIGS. 1 to 6 the enclosure units 901 are closed in the longitudinal direction L and in the peripheral direction, that is to say they have an enclosure wall 903 extending without any interruption around the one or more receiving means 902. The enclosure wall 903 is for example in the form of a tube, a hose or the like, with an approximately lens-shaped or double-pointed oval shape cross-section, or also of an oval, elongatedly round or round cross-section. Preferably the lens-shaped cross-section shown in FIGS. 9A-9D is used to provide the receiving means 902. It can be formed in particular from two identical circle segments which are fitted together at their chords symmetrically relative to the neutral fibre. That cross-sectional shape reduces folding, that is to say abrasive wear in the direction-changing arc. The enclosure units 901 are at least predominantly produced from flexible, permanently elastically flexible plastic, in particular being extruded, for example comprising expanded PTFE.
[0091] Enclosure units 901 as shown in FIGS. 9A-9D cannot be non-destructively opened, that is to say lines have to be passed therethrough axially or in the longitudinal direction, unlike the situation in FIGS. 1-6. Unwanted escape of particles during maintenance operations can however thereby be reliably prevented. A simplification in maintenance and expandability is achieved with the enclosure units 901 without a closure function at the receiving means 902, solely by the concept of the fixing function or the functional regions 920, 921 cooperating for parallel fixing of individual enclosure units 901. In that respect each enclosure unit 901 can for example have an associated line strand in order to renew a line strand prefabricated with plugs or the like independently of a differing line strand by means of the replacement of an enclosure unit 901.
[0092] Each enclosure unit 901 as shown in FIG. 9A-9D has functional regions 920, 921 which are diametrally opposite at both sides and which either are produced in one piece with the closed enclosure wall 903 or are subsequently connected thereto, the functional regions extending continuously in the longitudinal direction L. The functional regions 920, 921 each have as the fixing strip a fixing profile and/or a fixing bar for releasable connection by positively locking and/or force-locking engagement. The functional regions 920, 921 are designed to cooperate for release or fitment as required of an enclosure unit 901 to or from an adjoining enclosure unit 901. A suitable design configuration is described hereinafter with reference to FIGS. 10A-10D.
[0093] FIGS. 9B-9D show by way of example two connected enclosure units 901, a first enclosure unit 901 forming three receiving means 902. In FIG. 9B a second enclosure unit 901 also has three receiving means 902. In FIG. 9C the second enclosure unit 901 has two receiving means 902 while in FIG. 9D there is one receiving means 902. A different number of receiving means 902 which are formed by an enclosure unit 901 permits adaptation of an enclosure unit 901 to a line strand (not shown), in particular to the number of lines (not shown) within a line strand (not shown). Thus a configuration according to requirements of enclosure units 901 with an adapted number of receiving means 902 within an enclosure 900 makes it possible for an individual line strand (not shown) to be replaced as needed by the replacement of an enclosure unit 901.
[0094] It is possible to use for example fixing profiles as functional regions 920, 921 which are of a cross-section that remains the same in the longitudinal direction to permit extrusion. The functional regions 920, 921 here also extend in a strip form in a plane in opposite relationship at two sides along the enclosure wall 903. The fixing strips of the functional regions 920, 921 are designed in the manner of a press closure with interengaging fixing profiles, similarly for example to press-closure bags. The functional regions 920, 921 here cooperate for fixing, possibly also with a separate fixing bar as in FIG. 2, which connects the fixing profiles or fixing bars respectively.
[0095] Preferably the functional regions 920, 921 are produced in one piece with the enclosure walls 903 in an extrusion process, either using a unitary material or from different plastics, for example with a flexible but stronger or harder plastic for the functional regions 920, 921. The functional regions 920, 921 can be produced separately, for example by extrusion or injection moulding, and can be integrally connected to the remaining profile of the enclosure unit 901, for example being welded continuously in the longitudinal direction by a suitable procedure. Preferably for that purpose the enclosure wall 903 and the functional regions 920, 921 are made from a thermoplastic material.
[0096] FIGS. 10A-10D show a particularly preferred further example of an enclosure unit 1001 representing a variant of the principle shown in FIGS. 4A-4D. In this case too the enclosure unit 1001 is made from flexible bendable plastic, preferably being extruded, and has a plurality of, for example three, receiving means 1002 for lines 6 in the closed state (FIG. 10B). In that case the enclosure unit 1001 for each receiving means 1002 has its own respective dedicated or associated functional region 1010 which is in the form of a closure, here in particular in the form of a strip-like closure bar with two engagement profiles or closure profiles which engage into each other in conjugate relationship, namely a hook profile 1011 which can engage into a claw profile 1012. The hook profile 1011 and the claw profile 1012 are respectively provided with at least one undercut configuration, preferably two symmetrical undercut configurations, and engage into each other with a barb-like function, that is to say they are relatively easy to close or connect but are to be released only with the application of a markedly higher force.
[0097] In addition at both opposite narrow sides the enclosure unit 1001 also has a respective functional region 1020 and 1021 serving for modular fixing of a plurality of enclosure units 1001 with correspondingly structurally identical functional regions 1020 and 1021 in a position laterally in mutually juxtaposed relationship or at a support device (see FIG. 3A). The fixing strips or bands 1020, 1021 are here too in the form of a claw profile 1022 and a hook profile 1025 respectively, similarly or structurally identical to the closure functional regions 1010.
[0098] FIGS. 10C-10D show diagrammatically enlarged cross-sectional views of the hook profile 1011 and the claw profile 1012 which of structurally identical configuration can also be used for the closure functional regions 1020 and 1021. The hook profile 1011 and the claw profile 1012 are of a cross-section which remains the same throughout in the longitudinal direction (perpendicular to the plane of FIGS. 10C-10D) and are in the form of flexible strips or bands which are bendable about the axis A in the direction-changing arc 4 (FIG. 4). The hook profile 1011 is in the form of a symmetrical double-hook profile with respect to the neutral fibre N, for example as shown here being of an arrowhead shape, a mushroom shape or the like, and has respective corresponding rear undercut configurations or undercuts. The rear sides 1027 can extend rearwardly inclinedly at an angle with respect to the plane of symmetry and the connecting direction to enhance the action as a barb and to reliably prevent unwanted release. The claw profile 1012 is of a corresponding cross-section symmetrically with respect to the neutral fibre N. The claw profile 1012 has an inner receiving means with a matching cross-section in matching or conjugate relationship with the hook profile 1011, wherein the receiving means can be of an undersize to achieve a force-locking connection. Around that receiving means the claw profile 1012 forms two claw-like bars or strips which engage behind the hook profile 1011 like a jaw and hold it fast. Other forms of a hook profile 1011 and a claw profile 1012 respectively can also be considered, in particular as in the case of toothless zip fasteners, in particular sliding or press closures made of plastic. The foregoing structure can be appropriately used for the fixing functional regions 1020, 1021. Zip fasteners 1010 or 1020, 1021 with interengaging parts which are of a substantially uniform cross-section over their entire length and which are operated without a slider as that construction can be easily implemented using an extrusion process are preferred.
[0099] An arrangement of the closure functional regions 1010 and fixing functional regions 1020 and 1021 at the level of the neutral fibre N as shown in FIGS. 10A-10D is particularly advantageous. The neutral fibre N, also referred to as the zero line, is the layer in the cross-section, whose length does not change upon bending, in particular upon displacement of the direction-changing arc 4 (FIG. 8), that is to say the layer which maintains a constant dimension in the longitudinal direction upon curvature.
[0100] The closure functional regions 1010 and fixing functional regions 1020 and 1021 can be produced with a unitary material with the walls of the receiving means 1002 or can be produced from a comparatively flexurally stiffer plastic, for example using an extrusion process, for example to enhance the stability of the connections and the enclosure unit 1001 overall.
[0101] FIG. 11 shows a modification with an enclosure unit 1101 in which the fixing functional regions 1120 and 1121 are designed in accordance with the principle shown in FIGS. 10A-10D. In contrast the closure functional regions 1110 are in the form of double-hook engagement profiles based on the principle shown in FIGS. 4A-4C. It is to be noted in that respect that the view in FIGS. 4A-4C is not true to scale as the closure functional regions 410 are shown there on a greatly enlarged scale. Typically the functional regions 1010, 1020 and 1021 or 1110, 1120 and 1121 respectively are of a structural height in cross-section in the millimeter range, for example from 1.5 mm to about 3 mm
[0102] FIG. 12 in turn shows a modification in relation to FIGS. 10A-10D with the substantial difference that each enclosure unit 1201 of FIG. 12 forms precisely one receiving means which is individually openable and closable. Besides a corresponding closure functional region 1210, with a hook profile 1212 and a claw profile 1211 similarly to FIGS. 10A-10D, on each receiving means in FIG. 12 each individual receiving means also has at both sides at each narrow side its own fixing profile, for example a claw profile 1211 and a hook profile 1212.
[0103] Coming back to FIGS. 2-6 a preferred production method for a flat ribbon line is now proposed, which can be used as a line guide for a clean room application as shown in FIGS. 1A-C.
[0104] FIGS. 2-3 show a plurality of individual wires 20 consisting of highly flexible stranded line of an individual wire diameter<0.08 mm of the individual wires 21 of each strand. The individual wires 20 are stranded in per se known manner, wherein inter alia the pitch length is adapted to the stranded lines. Each strand has its own suitable insulation 22. The stranded structure comprising individual wires 20 (at the right in FIG. 2) is then banded, preferably with a wrapping comprising two bands or strips of a PTFE film 23, which are wound in opposite directions, as shown in FIG. 3 (at the right).
[0105] The resulting line bundle 30 (at the left in FIG. 3) does not have its own outer sheath and can be provided for example by purchase from a cable manufacturer. The procedure for manufacture of such line bundles 30 (at the left in FIG. 3) is known per se but—in a departure from the relevant standards—no outer sheath is deliberately provided here, which typically would be applied to the line bundle 30 by subsequent extrusion. The line bundle can further have components which are not shown here like for example a braid or mesh for screening purposes, a tension-resistant core element and so forth.
[0106] FIG. 4 shows one of two steps for the production of a line guide for a clean room application in accordance with the invention. Referring to FIG. 4 a prefabricated enclosure, here by way of example comprising a plurality of enclosure units 901, as described hereinbefore with reference to FIGS. 9A-9C, is provided. Accordingly the prefabricated enclosure 900 has at least one enclosure unit 901 produced in peripherally closed state, having one or more receiving means 902. In the case of the line unit 901 which is produced in a closed condition the line bundle 30 is drawn into the closed enclosure unit in the longitudinal direction L loosely or with a free space relative to the enclosure walls 903, that is to say it is drawn into the enclosure unit with a pulling wire or a suitable procedure. The enclosure units 901 can then or previously be connected to constitute an enclosure 900 (see FIGS. 9A-9D) so that a line guide having a plurality of electric lines 30 is produced, as diagrammatically shown in FIG. 6.
[0107] Alternatively, as FIGS. 5A-5B show, it is also possible to use an openable and closable enclosure unit 501 having two cooperating closure profiles 511, 512 of a closure. As a modification in relation to FIG. 11 here the arrangement shows a closure 510 with only one interengaging profile bar, other features however are equivalent to FIG. 11.
[0108] The closure 510 serves for dust-tightly closing an opened state in which the enclosure unit 501 can be produced by extrusion.
[0109] In the production method shown in FIGS. 5A-5B a line bundle 30 which is provided as shown in FIGS. 2-3, for example being delivered in that way, is introduced transversely relative to the longitudinal direction into the opened enclosure unit 501 and then the enclosure unit 501 is closed as shown in FIGS. 5A-5B. In that way too a line guide with a plurality of electric lines 30, as diagrammatically shown in FIG. 5B for only two lines 30, can be produced. The enclosure units 501 can then or previously be connected to constitute an enclosure 500 (see FIG. 5B).
[0110] FIGS. 7A-7B show an enlarged view illustrating two variants of the preferred enclosure units 901 used in FIG. 4, in which the peripherally extending enclosure wall 903 is produced in a unitary material with the functional regions 920, 921 for lateral fixing. FIG. 7C shows a variant in which the functional regions 920, 921—formed as described in FIGS. 9-10—are in contrast produced from a different harder plastic than the enclosure wall 903.
[0111] FIGS. 8A-8C show sliding friction-reducing layers comprising a third plastic, in particular a PE-HMW or PE-UHMW, with a lower sliding coefficient in comparison with the first and second plastics (FIG. 7C). That production operation can be effected for example using a tri-extrusion process from three different plastics. In FIG. 8A the sliding friction-reducing layer 801 is provided only externally on the enclosure walls 903.
[0112] In FIG. 8B there is provided a sliding friction-reducing layer 802 in full peripheral relationship also on the functional regions 920, 921 for lateral fixing.
[0113] FIG. 8C shows a variant in relation to FIGS. 5A-5B with a sliding friction-reducing layer 803 which extends almost completely peripherally, but not at the male hook-shaped connectors 521. A further sliding friction-reducing layer, in particular a PE-HMW or PE-UHMW, can also be provided at the inward side of the receiving means (not shown in FIGS. 8A-8C), that is to say at the side of the enclosure walls 503 and 903, that face towards the line 30.
