SK57293A3 - Device for cable line with one guide pipe from thermoplastic - Google Patents

Abstract

A cable guiding device having at least one cable guiding pipe, which has a cable guiding duct with a duct inner wall (which is circular in cross-section and has the pipe internal radius r), and which has sliding ribs which are arranged on the duct inner wall and are formed out of the thermoplastic synthetic material of the synthetic material pipe. The sliding ribs run at a predetermined rotation angle a with respect to the internal circumference. Contact surfaces having the rib contact width b result in a cable guiding pipe, which is arranged in a straight line, with a cable (which is to be inserted) at the contact points between the sliding ribs and the cable sheath of the cable which is to be inserted. The sliding ribs run in a corrugated shape and form reversing regions between sections having a constant rotation angle a. The rib contact width (b), the number (z) of sliding ribs which are distributed equidistantly over the circumference of the duct inner wall, the pipe internal radius (r) and the length LK of the rib contact sections between the reversing regions satisfy the equation Ar = 0.16 b exp(2).z.LK. A defines the contact area of the cable sheath at the intersections with the sliding ribs in the rib contact sections. The angle g, measured in radians, of the pitch of the sliding ribs, measured on the duct inner wall, satisfies the equation g = ra/LK.

Description

Technical field

The invention relates to a cable routing device with at least one thermoplastic guide tube 2 having a guide channel with an inner wall of circular cross section of a given inner radius and sliding ribs arranged on the inner wall of the guide channel and formed of a thermoplastic thermoplastic guide tube which In the case of the inner circumference, they run at a predetermined angle of rotation, whereby in the direct guide tube with the cable drawn in, contact areas of the required width are formed at the points of contact between the sliding ribs and the cable sheath.

BACKGROUND OF THE INVENTION

Such cable routing devices are usually laid in the ground. The cables are introduced into the guide tube or guide tubes additionally. A cable within the scope of the invention refers to a cable commonly used in a messaging technology, particularly in the postal sector, a power line cable, and the like. A single cable or several cables or a bundle of cables may be routed in one guide tube of the cable guide device. Individual cables are single or multi-core and have a sheath made of rubber or plastic. The sliding ribs have a height greater than 0.1 mm, preferably 0.3 to 3 mm. Grooves are provided between the sliding ribs. For clarity of rotation, reference is made to Helix Theory (see Hutte Des Ingenieurs Tashchenbuch I, Theoretische Grundlagen, 28th edition, Ernst & Sohn Berlin, page 157). The helix is then defined as follows: When a line moves continuously perpendicular to the fixed axis and the paths that the fixed point of the line travels are proportional to the angle at which the line is rotated, then every 2 of its points describes a conventional helix. The angles shown at the front are the angles of rotation with respect to the circumferential direction of the straight line. Size refers to a certain length axis axis. Otherwise, the sliding ribs run against the inner wall of the channel with a predetermined pitch. The pitch tangent at one point of the sliding rib is the first derivative of the mathematical equation for the helix that corresponds to the sliding rib at this point. The cable diameters are usually in the range of 10 to 90 mm, for example 10, 28, 35 or 90 mm. Conventional guide tubes of the cable management device according to the invention have an inner diameter in the range of 26 to 200 mm.

The term cable guide device refers, for example, to individual cable guide tubes (see DE 35 29 541 A1), but also to guide tube assemblies (see DE 32 17 401 A1). The guide tube (s) of the cable management device are used to accommodate individual cables or bundles of cables that must be inserted or drawn into the guide tube. In one known embodiment of the cable guide device (DE 35 29 541 A1), the sliding ribs have a constant direction relative to the guide channel axis and in the direction of the guide channel axis. For example, they run helically and along the entire length of the cable guide device with a left-handed or right-handed rotation with the same angle of rotation. The frictional resistance that results from the introduction of the cables or cable bundle into the cable guide with sliding ribs is greatly reduced. This has been proven in many applications and facilitates the insertion and insertion of a cable or cable bundle. For both measures, the term " drawing in " Depending on the design of the cable or cable harness, the alternating action of the cable or cable harness with the sliding ribs can cause disturbances, namely torsional forces acting on the cable or cable harness, causing unwanted or severe braking of the cables. cables. In this case, the cable or cable bundle can almost be knotted on the sliding ribs. These undesirable disturbances can be reduced by arranging the ribs in an alternating direction relative to the axis of the guide channel and in the direction of the axis of the guide channel (DE 40 31 783 A1). Alternating direction means that the direction of rotation of the sliding ribs is different, for example once from left to right and once from right to left. In other words, the angle of rotation is once positive and once negative. In this case, the sliding ribs can also have different pitches in the direction of the axis of the guide channel.

Surprisingly, in this embodiment and in the design of the cable routing device, no more disturbing torsional forces are exerted on the cable to be pulled in or inserted, or on the cable harness to be pulled in or retracted. The resulting forces resulting from the alternating frictional interaction of the cable or cable harness with the sliding ribs no longer increase the distorting twisting of the cable or cable harness, and are even completely eliminated according to the embodiment. Nothing less is necessary when the cable or cable bundle is pulled into the guide channel by unrecognizable linear pulling forces, by means of which it is necessary to overcome, so to speak, the linear frictional resistance in the longitudinal direction of the guide channel. The relevant equipment must be available. This also applies if, in the known embodiment, in a special case, the sliding ribs run serpentine without special guidance and shaping (DE 40 31 783 A1, FIGS. 1, 4 and 5).

SUMMARY OF THE INVENTION The object of the invention is to provide a device for guiding the above-mentioned type such that the pulling forces are extremely small under all conditions, even when the cable guiding device is clogged.

SUMMARY OF THE INVENTION

A cable routing device having at least one thermoplastic guide tube 2 having a guide channel with an inner wall of circular cross section of a given inner radius and sliding ribs arranged on the inner wall of the guide channel and formed of a thermoplastic thermoplastic guide tube which, relative to The inner circumference runs at a predetermined angle of rotation, and in the direct guide tube with the cable drawn in at the points of contact between the sliding ribs and the cable sheath the contact surfaces of the required width are formed according to the invention.

1) the sliding ribs run in a wave-like manner and form reversing regions between the constant-angle sections;

2) the contact rib width (b), the number (z) of the ribs equidistantly distributed around the circumference of the inner wall of the channel, the inner radius (r) of the guide tube and the length (Lk) of the contact portion of the ribs between the return regions

Ar = 0,16 b ² of L _K , where A is the contact area of the cable sheath at the intersections with the sliding ribs in the contact parts of the sliding ribs and has a size between 4,5 and 32 mm ² ,

3) angle of inclination (g) of sliding ribs, measuring in arc measure on the inner wall of the channel complies with the equation

V g = ra / Lk and lies in the range of 0.001 to 1.2 rad, in the range of 12 to 100 mm and Lk is in the range of 500 and the cable to be inserted has an outside radius in the range of the predetermined angle of rotation with channel between the return regions.

where r is up to 10000 mm to 45 mm. while doing so

The object of the invention is furthermore to provide a method of drawing cables into the guide tubes according to the invention, the principle being that the drawing speed of the cable to be introduced is selected such that the contact surfaces are melted by frictional heat and a friction state is created.

The reversing regions of the glide ribs, which extend in the depressed state of the inner wall of the channel into the sinusoidal plane, are the highest peaks of the wave peaks and the deepest points of the waveforms of the sinusoidal waves respectively. The return regions are then always at the tipping point. The feature that the sliding ribs run in a wavy manner and have reversible areas between the constant angle sections is known per se. However, in the region of the wave peaks or the lower wave peaks, it is possible to insert sections of the sliding ribs, also extending in the direction of the jacket lines of the inner wall of the channel, which form relatively long return regions. The contact surfaces of the cable sheath with individual sliding ribs have, in plan view, a more or less rhombic shape whose geometry is determined by the width of the contact rib surface, i.e. the width of the sliding ribs at the point of contact on the cable sheath and the sliding ribs. For further clarification, reference is made to the description of FIG. 1 in the exemplary embodiments.

The invention is based on the finding that, in the case of guide tubes designed and dimensioned as described above, the cables lead to a considerable reduction in the pulling forces, when such a measure is taken that dry friction is replaced in the event of impermissibly large pulling forces in connection with the pulling. a friction which almost approximates the lubrication friction, which, as is known, has considerably less friction coefficients than dry friction. However, no special lubricant is used for this purpose according to the invention. According to the invention, in the cable pulling method, preferably the speed of pulling and / or pushing in the cable or cable bundle is such that a local temperature increase occurs on the contact surfaces, which surprisingly reduces the frictional resistance. Preferably, the drawing-in is carried out so. that the contact surfaces are melted by the frictional heat and a melting-close state is created by the resulting melt. This option has not yet been noticed.

The cross-section of the sliding ribs is practically arbitrary within predetermined limits. According to the invention, the numerical parameters are chosen such that the friction state as with lubrication can be achieved continuously and easily when the cable routing device is made of a conventional thermoplastic and when the cables have a conventional sheath and also a usual weight per length unit. Although this possibility exists according to the invention, it is nevertheless within the scope of the invention that lubricating means can be arranged between the sliding ribs in the grooves. However, this is not necessary. Cable sheaths may be provided with a coating which acts as a glidant. It is understood that in the cable management device according to the invention the absolute magnitude of the pulling forces increases in proportion to the length of the cable management device. This is also true when friction of the sliding ribs, or more precisely of their ridges, occurs as described above according to the method described above. It is also within the scope of the invention how slowly and carefully the cables need to be pulled in order to avoid and avoid the formation of friction as a lubricant.

Although arbitrary, i

The cross-section of the sliding ribs may be practically advantageous in such a way that the inner wall of the channel between adjacent sliding ribs has the shape of a groove concave to the channel which extends on both sides into the sliding rib ridge.

The cable guide device according to the invention can have guide tubes of usual diameter and of different shapes, which have different meanings. The parameters of the different versions of the guide tubes are given in the following table:

marking of guide tubes external shape parameters a

32 (x2, 0) 50 (× 4.6) 110 (x6,3) 225 (xl2,8 outer diameter in mm 32, 0 50, 0 110.0 225, 0 wall thickness in mm 3, 0 4, 6 6, 3 12, 8 internal diameter mm 26, 0 40, 8 97, 4 199, 4 number of glides ribs 26 40 40 82 sliding distance reb i er 3, 14 3, 20 7, 65 7, 65 angle of rotation in ° 180 180 180 180 touch width mm 0, 1 0, 1 0, 1 0, 1 length of touch parts of ribs in mm 1275 2000 4775 9775 length of connecting sections in mm 2 2 2 2

in

In particular, there are further possibilities for the cable routing device according to the invention. The rotation angle can generally be in the range of 45 ° to 340 °, preferably about 130 °. An optimum embodiment in many applications is where the contact width (b) of the sliding ribs equidistantly positioned inside the radius (r), the angle (a) of the sliding rib contact points satisfy the rib equation, the number (z) of sliding on the inner channel wall, rotation and length ( Lk) between return areas

Ar = 0.16 b ² of (0.0003

Lk ² )

1/2

If connecting sections are provided between the constant angle pivot sections in the guide tube of the cable routing device according to the invention, particularly advantageous results in terms of pulling forces can be obtained by designing lengthwise connecting sections (Lv) between the constant pivot sections (a) ), in which the sliding ribs continue parallel to the axis of the guide tube, the contact width (b) of the sliding ribs, the number (z) of the sliding ribs equidistantly positioned on the inner channel wall, inner radius (r), angle of rotation (a) and length (Lk) ) the contact points of the sliding ribs between the return regions and the length (Lv) of the connecting sections satisfy the equation

Ar = 0.16 b ² z (0.0003 r ² and ³ + Lk ² ) ^1/2 + 4Lvbr.

BRIEF DESCRIPTION OF THE DRAWINGS

BRIEF DESCRIPTION OF THE DRAWINGS The invention will now be illustrated by way of example with reference to the accompanying drawings, in which: FIG. 1 is a schematic perspective view of an inner channel wall with a circular cross section of a guide tube with geometric symbols belonging to the features of the invention; FIG. 2 illustrates graphically the notion of contact surface.

Fig. 3 shows a depicted inner wall of a channel with sliding ribs according to the invention and the cable indicated; FIG. 4 shows a longitudinal section of the guide tube according to the invention with a cable in great detail and FIG. 5 is a large sectional view in detail of a guide tube according to the invention.

ť r. Embodiments of the invention

The inner channel wall 7, circular in cross-section and shown in FIG. 1 belongs to a cable guide tube 2 which forms part of the cable guide device according to the invention. In FIG. 1 shows the inner radius r of the curvature of the inner wall 7. Sliding ribs 3 are shown in simple lines on the inner wall 7 of the channel, which run relative to the inner circumference with a predetermined angle and rotation.

In FIG. 2 is a schematic plan view of a sliding rib 3 deployed in a plane on which the waist region 4 of the cable sheath 10 abuts. FIG. 3 shows a detail of the deployment of the inner wall 7 and the cable 5 which has been laid on it, the sheath 10 of which belongs to the strip region 4. FIG. 2 and 3, it can be seen that in the straight guide tube 2 drawn by the cable 5, at the contact points between the sliding ribs 3 and the belt regions 4 of the sheath 10 of the cable 5, a ridge contact surface K of width b. In particular, FIG. 3 also shows that the sliding ribs 3 have a wavy shape. Sliding fins 3 tVoria med2i with constant angle sections 6 and reversing area rotation

7. The width b of the contact surfaces K, the number of sliding ribs 3 equidistantly spaced around the circumference of the inner wall and the channel, the inner radius r and the length Lr of the contact portion of the sliding ribs between the return regions 7 satisfy the equation

Ar = 0.16 b ² of Lk

In FIG. 3, the length of the sections 6 corresponds to the length Lk

The angle of inclination of the sliding ribs 3, measured both of the inner wall and of the channel, which is also compliant with this equation at the arc level indicated in FIG. 1

The ratios given are largely when the inner length Lk is suitable and tested by extensive experiments with a radius r ranging from 12 to 100 mm, ranging from 500 to 10000 mm and the cable to be drawn 5 has an outer radius ranging from 5 to 45 mm. The angle of rotation α can be in the exemplary embodiment and preferably about 180 °.

In FIG. 4 shows an enlarged detail of the longitudinal section approximately in the direction A-A of FIG. 2 with the sliding rib 3 in cross section in the region of the contact surface K of the cable 5 which has been seated. The dots indicate that the sliding rib 3 has melted, i.e. the frictional heat generated when the cable 5 is pulled. 4 illustrates that the formation of the melt 8 results in a state of friction as with the lubricant.

In FIG. 5 it can be seen that the inner wall 7 of the channel between adjacent sliding ribs 3 has the shape of a groove 9, concave to the channel which extends on both sides into the ridge of the sliding ribs 3. The sizes shown are typical for many applications. The height hR is approximately twice the free distance Xf of the sheath 10 of the cable 5 from the bottom of the groove 9 between the sliding ribs 3.

Claims (6)

An apparatus for routing cables with at least one thermoplastic guide tube having a guide channel with an inner wall of circular cross-section with an inner radius (r) and sliding ribs arranged on the inner wall of the guide channel and formed of a thermoplastic thermoplastic guide tube which to the inner circumference, they run at a predetermined pivot angle (a), whereby in the direct guide tube with the cable drawn in contact points between the sliding ribs and the sheath of the lead-in cable, contact surfaces of width (b) are formed, characterized in that the sliding ribs they run in a waveguous manner and form between the constant rotation angle sections, the contact width (b) of the sliding ribs, the number (z) of the sliding ribs equidistantly spaced around the circumference of the inner channel wall, the inner radius (r) of the guide tube and the length (Lk) the sliding ribs between the return regions conform to the equation Ar = 0,16 b ² 2 Lk, where A is the contact area of the cable sheath at the intersections with the sliding ribs in the contacting parts of the sliding ribs and has a size in the range of 4,5 to 32 mm ² , the slope angle (g) the arc measurement on the inner wall of the duct conforms to ¹ equation g = ra / Lk and lies in the range of 0.001 to 1.2 rad, with r in the range of 12 to 100 mm and Lk in the range of 500 to 10000 mm, and the lead-in cable has an outer radius ranging from 5 to 45 mm. Device according to claim 1, characterized in that the inner wall of the channel has, between adjacent sliding ribs, a groove, concave with respect to the channel, which extends on both sides into the ridge of the sliding ribs. Device according to one of claims 1 or 2, characterized in that the angle of rotation (α) is from 45 ° to 340 °, preferably about 180 °. Device according to one of claims 1 to 3, characterized in that the contact width (b) of the sliding ribs, the number (z) of the sliding ribs distributed equidistantly on the inner channel wall, the inner radius (r), the pivot angle (a) and length (Lk) the contact points of the sliding ribs between the return regions conform to the equation Ar = 0.16 b ² of (0.0003 r ² and ² + Lk ² ) ^1/3 Device according to one of Claims 1 to 4, characterized in that connecting sections of length (Lv) are arranged between the constant angle sections (a), in which the sliding ribs extend parallel to the axis of the guide tube, the contact width (b) ) sliding ribs, number (z) of sliding ribs equidistantly positioned on the inner wall of the channel, inner radius (r), angle of rotation (a) and length (Lk) of contact points of sliding ribs between return regions and length (Lv) Ar = 0.16 b ² z (0.0003 r ² and ² + Lk ² ) ^1/3 + 4Lvbr Method for inserting cables into guide tubes according to one of Claims 1 to 5, characterized in that the speed of insertion of the cable to be introduced is selected such that the contact surfaces are melted by frictional heat and a friction condition is created by the melt as a lubricant.