EP2155445A2 - Device for guiding supply tubes/feeders along the structure of an industrial robot - Google Patents

Abstract

The invention relates to a device for guiding supply tubes/feeders (2) along the structure of an industrial robot (1). Said device movably guides the supply tubes/feeders (2) in a device section (3) which encompasses return motion means (10, 11) and is used for longitudinally compensating movements of several robot axes. Starting from a center of rotation (4), the supply tubes/feeders (2) are guided away in a first subsection (5) and are then guided on in a second subsection (6) in a substantially accurate and substantially circular manner and at a substantially constant distance from the center of rotation (4) in such a way that deflections of the supply tubes/feeders (2) in the first subsection (5) remain substantially static even during longitudinal compensation and the supply tubes/feeders (2) can be used at least in part as a spare length in the second subsection (6).

Description

 Device for guiding supply lines along the structure of an industrial robot

The invention relates to a device for guiding supply lines along the structure of an industrial robot. It comprises a device section serving for length compensation for movements of a plurality of robot axes.

State of the art

Industrial robots are regularly used in complex work environments for positioning and / or controlling tools; They are characterized by their special spatial flexibility compared to conventional machines. This flexibility is limited by lines running on the robot structure.

Such lines consist of cables and / or hoses that carry electrical current and / or fluids - such as air and water - and supply, for example, arranged on the robot hand tools and / or measuring devices with energy, cooling and / or data; they are referred to in this document as supply lines. The aforementioned limitations of flexibility are based on two main factors: the limited length compensation and the interference contour of the supply lines. The maximum length compensation limits movements of the axes of the industrial robot. The often considerable, hardly predictable interference contour further restricts the remaining range of motion, depending on the complexity of the work environment and the workpiece.

Previous guide devices for supply lines are regularly arranged along the robot structure. In the area of the robot arm and the robot hand, the supply lines are usually led outside the robot structure in a surrounding protective tube. In this case, various types of supply lines are typically routed.

To guide the supply lines attached to the robot structure holding parts are used. These holding parts regularly have at the robot structure fixed angle plates and arranged on these clamp and trumpet elements, the latter two serve for actually holding and guiding the supply lines; occasionally holding parts are also designed as molded parts.

For length compensation are usually arranged between or after such holding parts length reserves and return means used. The length reserves are regularly formed as contractible, circular loops or slidable, U-shaped loops. As a return means compression springs are used regularly, which usually have a helical structure and regularly surround a surrounding the supply lines protective hose; occasionally also leaf springs are used.

From DE 19817605 Al a guide device is known, which leads supply lines along the structure of an industrial robot to the hand to the front. For length compensation, a circular loop is provided, which is surrounded by a helical compression spring. The length reserve arises because the circular loop can contract; It serves for length compensation for movements of several robot axes. A disadvantage of this device is that the loop must still have the minimum dynamic bending radius in the contracted state, whereby an unfavorable ratio between length compensation and interference contour arises. By remaining rolling movements in the region of the circular loop, the interference contour is also only limited calculable; it can come to a rubbing on the robot swing.

From DE 20112491 U1 a guiding device is known which leads supply lines along the structure of an industrial robot to the hand of the latter to the front. For length compensation, a loop hanging down in the rear region of the robot arm is provided. The length reserve arises because the hanging loop can contract and / or move; It serves for length compensation for movements of several robot axes. A disadvantage of this device are the considerable interference contour above the robot arm and in the region of the hanging loop and remaining rolling movements in the region of the hanging loop.

From DE 10224858 Al a guiding device is known, which leads supply lines along the structure of an industrial robot to the hand to the front. For length compensation a U-shaped loop is provided, which is guided in a round tube with lateral longitudinal opening. The length reserve arises because the approximately U-shaped arc can move in the open region of the round tube section and laterally of this section at approximately constant bending radius along the lateral opening. The arc can run continuously during length compensation with approximately minimum dynamic bending radius. The length reserve is used for length compensation for movements of several robot axes. A disadvantage of this device is that the U-shaped arc itself can not be used as a length reserve, resulting in an unfavorable relationship to the interference contour. The outside of the round tube extending pipe parts are not stabilized; If these pipe parts are longer, rolling movements can occur there.

From DE 102004019838 Al a guide device is known, the supply lines along the structure of an industrial robot by a mounted in the rear of the robot arm molding leads to the front of his hand, which consists of a hollow, flat, cuboid housing part. For length compensation, an approximately U-shaped loop is provided, which is guided in this molded part. The length reserve arises because the approximately U-shaped arc can move at approximately constant bending radius within the molding. The arc can run continuously during length compensation with approximately minimum dynamic bending radius. The length reserve is used for length compensation for movements of several robot axes.

A disadvantage of the device is that the U-shaped arc itself can not be used as a length reserve, resulting in an unfavorable relationship to the interference contour.

From DE 102004028577 Al a guide device is known, the supply lines along the structure of an industrial robot by a mounted in the rear of the robot arm molding leads to the front of his hand, which consists of a front closed, laterally open rear round tube section, in the region of the opening in a hollow, flat, U-shaped housing section passes. For length compensation, an approximately U-shaped loop is provided, which is guided in this molded part. The length reserve is created because the approximately U-shaped arc in the region of the housing section including the laterally open round tube section can move along the lateral longitudinal opening of the round tube section at approximately constant bending radius. Of the During length compensation, the arch can run continuously with approximately the minimum dynamic bending radius. The length reserve is used for length compensation for movements of several robot axes.

A disadvantage of the device is that the approximately U-shaped arc itself can not be used as a length reserve, resulting in an unfavorable relationship to the interference contour.

From DE 20007000 U1 a guiding device is known which leads supply lines along the structure of an industrial robot to the hand of the latter to the front. In the area of the robot hand, it has a winding guide in the form of a double plate. For length compensation, a loop is provided, which is surrounded by a helical compression spring. The length reserve arises because the loop can contract; It serves for length compensation for movements of several robot axes.

A disadvantage of the device is that the loop must still have the minimum dynamic bending radius in the contracted state, whereby an unfavorable ratio between length compensation and interference contour arises. By remaining rolling movements in the loop, the interference contour is limited calculable; it can come to a rubbing on the robot swing.

From JP 62213992 A, a guide device is known, which leads cables along the structure of an industrial robot. It consists of a cylindrical, rotatably mounted drum with a cylindrical interior and lateral opening, which continues the cable extending in the cylindrical interior in a first section through the lateral opening to the outside and then in a second section circular outside along the drum wall. The cylindrical drum is mounted parallel to the axis of rotation of the industrial robot and coupled via a belt directly to the axis of rotation of the industrial robot. The length reserve arises because the cables are wound around the drum, whereby the cable section located in the second section can be used completely as a reserve of length and can run continuously with a minimum dynamic bending radius. The length reserve is used for length compensation for movements of only one robot axis. A disadvantage of the device is that the cables are not exactly guided in the second subsection and are not led away from a fulcrum in the first subsection. This allows the cables to move on the drum and in the cylindrical cavity, which is why in first section dynamic bends occur and the cables, especially in the area of the lateral opening, can be damaged quickly. A further disadvantage is that the device is coupled to its functioning via a belt directly to a robot axis. The device is therefore not suitable for length compensation for movements of multiple robot axes.

With regard to the aforementioned guide devices, two problem factors can be identified which prevent a better ratio of high length compensation, small, predictable interference contour and long life in a length compensating device section:

First, the minimum dynamic bending radius of the supply lines; if it is not reached, this quickly leads to material fatigue, which prevents a long service life. And second, the less precise leadership; it generally leads to moving, unpredictable interfering contours and, especially in the section of the length reserve, to irregular bending strains, so that the minimum dynamic bending radius of the supply lines in this section can only be approximated.

task

The invention has for its object to develop a device for guiding supply lines along the structure of an industrial robot, which compared to previously known Führungsvorachtungen a better ratio of maximum length compensation, minimal, predictable Störkontur and long life in a length compensation for movements of multiple robot axes serving Device section allows.

As an approach, the greatest possible elimination of the above-mentioned problem factors, in particular a largely exact guidance and a partial exclusion of dynamic bends in favor of static bends in a length compensation for movements of multiple robot axes serving device section is selected. With this approach, a departure from conventional configurations of the length reserve is connected as a contractible, circular loop or displaceable, U-shaped loop. According to the invention, the object is achieved by a device for guiding supply lines (2) along the structure of an industrial robot (1) which has the supply lines (2) in a device section (3) with return means (10, 11) serving for length compensation for movements of a plurality of robot axes. movable leads, wherein the supply lines (2) in a first part section (5) away from a pivot point (4) and then in a second section (6) substantially exactly, substantially circular and substantially at a constant distance to the pivot point ( 4) are continued so that bends of the supply lines (2) in the first section (5) remain substantially static even when length compensation, the supply lines (2) in the second section (6) can serve at least partially as a length reserve. The inventive device may be formed as an integral part of an industrial robot or as an attachment of an industrial robot. The length compensating serving device portion with return means may consist of further sections. The return means may at least partially consist of springs whose spring force preferably acts along the direction of movement of the supply lines in the second section. The device is particularly suitable for length compensation for movements of such robot axes, which are arranged in the region of a robot arm and a robot hand. The guidance in the second subsection makes it possible to guide supply lines in the first subsection with an approximately minimal static bending radius, as a result of which the interference contour, which accompanies at least a certain length compensation, is significantly reduced, depending on the nature of the supply lines. Even an exact tour in the first section is then readily possible. As a result of the guidance which is approximately exact in the second subsection, the supply lines in the second subsection can be guided with improved utilization of the minimum dynamic bending radius in comparison with prior art devices which serve the length compensation for movements of several robot axes, whereby the interference contour at least accompanying a certain length compensation continues reduced.

From this starting point, the device according to the invention can be optimized for specific fields of application as follows: If it primarily comes down to a high length compensation, for example, the second section substantially circular over an angle of more than 360 degrees, for example about 720 degrees, in two identical arranged on the other approximately circular loops, and / or be performed with a much higher than the minimum dynamic bending radius. If it primarily comes down to a small interference contour, for example, the second portion may extend substantially circular over an angle of less than 360 degrees, for example over only 90 degrees, with a minimum dynamic bending radius. If it is primarily a long life, the second section can run with much higher than the minimum dynamic bending radius.

Due to the favorable output ratio of length compensation, interference contour and life also variants are possible, which improve all three aspects compared to previously known guide devices.

In an alternative embodiment, the supply lines (2) are led away from a pivot point (4) in a first section (5) and then continued in a second section (6) exactly, circularly and at a constant distance from the pivot point (4). that bends of the supply lines (2) remain static in the first section (5) even when length compensation.

With such a guide, the advantages of the guiding principle according to the invention are not only substantially but completely utilized.

In an alternative embodiment, the supply lines (2) in the first section (5) are guided in the region of the pivot point (4) in the plane through which the arc of the second section (6) extends.

The guide in the fulcrum can be realized, for example, by a holding part, which is designed to be rotatable and fixed to the supply lines. By the aforementioned embodiment, a torsion of the supply lines in the region of the first section can be avoided. If the circular arc in the second subsection extends over an angle with many degrees, further disruptive dynamic bends can occur on the side of the fulcrum point facing away from the first subsection. The aforementioned embodiment is particularly suitable for cases in which only a small length compensation is required and / or a torsion of the supply lines is very problematic. In an alternative embodiment, the supply lines (2) in the first section (5) in the region of the pivot point (4) guided approximately perpendicular to that plane through which the arc of the second section (6).

The guide in the fulcrum can be realized, for example, by a holding part, which is designed to be immovable and leads the supply lines rotatably. By the aforementioned embodiment, the occurrence of further dynamic bends on the side facing away from the first portion of the pivot point can be avoided. Runs the arc in the second section over an angle with many degrees, a considerable torsion of the supply lines can occur; the torsion can be attenuated by distributing it over as long as possible a portion of the supply lines, for example by the supply lines are guided in a rotatable manner over the longest possible distance on the side of the pivot point facing away from the first section.

The aforementioned embodiment is particularly suitable for cases in which a high length compensation is required and / or a torsion of the supply lines is not very problematic.

In an alternative embodiment, the supply lines (2) in the second section (6) in a protective tube (8) through a molded part (13) which in the second section (6) has an opening (17) through which the supply lines (2 ) in the first section (5) are also performed during length compensation.

The opening of the molding may extend along the direction of movement of the supply lines in the second section. The molded part and protective tube may have a uniform cross-section, wherein the protective tube preferably has no corresponding opening. By this configuration, the supply lines are protected at the same time and accurately managed. The molding and protective tube may have a circular or non-circular - for example, cuboid - cross-section. A non-circular cross-section of the molded part and the protective tube is advantageous insofar as the protective tube can not rotate about its own axis in this case, whereby a whole bundle of supply lines can be performed without problems in a very largely exactly constant distance from the pivot point. A longitudinal opening of the molding is preferably directed at least approximately in the direction of the pivot point. The molded part may have further openings. This can be advantageous, for example, if mobility and / or exact guidance of the protective tube in the second subsection are supported by rollers connected to the protective tube, or if the molded article itself has one or more rotationally movable components.

In an alternative embodiment, the supply lines (2) in the second subsection (6) are guided in a power transmission chain (9) through a molded part (13) which has an opening (17) in the second subsection (6), through which the supply lines (2 ) in the first section (5) are also performed during length compensation. The leadership of the supply lines in a power transmission chain is particularly advantageous because of the resilience of the energy chain and the simple feasibility of a strain relief.

The opening of the molding may extend along the direction of movement of the supply lines in the second section. The molded part and the energy guiding chain can have a uniform cross section, wherein the energy guiding chain does not necessarily have a corresponding opening. By this configuration, the supply lines are protected at the same time and accurately managed. The molded part and the energy guiding chain can have a circular or non-circular cross-section, for example cuboid. A non-circular cross section of the molded part and the energy guiding chain is advantageous insofar as the energy guiding chain can not rotate about its own axis, whereby a whole bundle of supply lines can be guided in a very largely exactly constant distance to the fulcrum. A longitudinal opening of the molding is preferably directed at least approximately in the direction of the pivot point. The molded part may have further openings. This may be advantageous, for example, if mobility and / or exact guidance of the energy guiding chain in the second subsection are supported by rollers connected to the energy guiding chain, or if the molded part itself has one or more rotatable components

In an alternative embodiment, one or more compression springs (10) serve as return means.

For example, coil springs can serve as compression springs. Compression springs can be used without problems in the area of a length compensation required anyway. derliche Teilabschnitts - for example between protective hose and molding - are attached. As a result, the overall interference contour can be kept low. In a preferred variant protectors (12) are mounted in the region of the compression springs, through which the protective tube is movably guided; As a result, the wear on the protective tube, compression spring and molded part is reduced.

Druckfedera have a residual length in the compressed state, so that when mounted between protective hose and molding not the whole of the compression spring surrounded area of the supply lines can serve as a length reserve.

In an alternative embodiment, a torsion spring (11) serves as a return means whose axis of rotation extends through the pivot point (4) and whose rotational force acts along the arc of the second section (6).

As a torsion spring, for example, serve a leg spring.

When using a torsion spring as the return means the rest length problem described above for compression springs does not occur. By attaching the return means in the region of a required anyway for the length compensation section, the overall interference contour can be kept low.

In an alternative embodiment, the supply lines (2) following the second section (6) in a third section (7) straight and substantially exactly continued.

The third section is not necessarily part of the length compensation serving device portion of the device according to the invention.

The above-mentioned guidance in the third section can - apart from the straight course - correspond to those in the second section; it serves primarily to prevent rolling movements in the further course of the supply lines. Further advantages are associated with the aforementioned guide in particular when the return means consists of one or more compression springs. Because these can then - with appropriate design - are also compressed in this section, so that with sufficient length of the third section, the entire second section can serve as a length reserve.

In an alternative embodiment, the supply lines (2) in the third section (7) guided by a molded part (14), the protective tubes (8) and / or energy guiding chains (9) can drive different cross-section exactly.

Due to the aforementioned embodiment, it is possible, in particular, to optimize the guidance of the supply lines in protective tubes and / or energy guiding chains with regard to different requirements in the second and third sections. For example, the guide in the second section in a despite the tight bending radius highly resilient energy supply chain cuboid cross-section can be done in the third section, however, in a less resilient and much cheaper protective sleeve circular cross-section.

In an alternative embodiment, the supply lines (2) in the first section (5) and second section (6) are guided continuously within a substantially closed mold part (15).

By the leadership within a largely closed molding the supply lines are protected in particular from chips, dirt and dust.

In an alternative embodiment, the supply lines (2) in the first subsection (5) and in the second subsection (6) and in the third section (7) are guided continuously within a largely closed molding (16).

By the leadership within a largely closed molding the supply lines are protected in particular from chips, dirt and dust.

In an alternative embodiment, at least one molded part (13, 14, 15, 16) designed hinged.

Due to the hinged configuration supply lines and / or wearing parts are easily accessible. In a variant, the mold parts (13, 14) are designed such that arise when unfolding asymmetric parts. In this way it can be ensured that in the case of a lateral attachment to the robot arm, the supply lines do not simply fall to the floor after the mold part / moldings have been unfolded, but must instead be removed selectively, for example, upwards.

The drawings, FIGS. 1 to 15, show, by way of example, various embodiments of the invention. Device according to the invention.

1 and 2 show an embodiment of the device section (3) according to the invention, which serves for length compensation for movements of several robot axes, in which the supply lines (2) in the first section (5) are guided in that plane in the region of the pivot point (4) through which the arc of the second section (6) extends, and in which the supply lines (2) in the second section (6) are guided in a protective tube (8) of circular cross-section through a shaped part (13) of circular cross-section, one along the Movement direction of the supply lines (2) in the second section (6) extending opening (17) through which the supply lines (2) in the first section (5) are guided during the length compensation, wherein the guide in the pivot point (4) by a holding part is realized, which is firmly connected to the supply lines and designed itself rotatable and is. In drawing 1, a position with unused length reserve is shown; Drawing 2 shows a position with almost completely used length reserve.

FIG. 3 and FIG. 4 show an embodiment of the device section (3) according to the invention for length compensation for movements of several robot axes, in which the supply lines (2) in the first section (5) in the area of the pivot point (4) are approximately perpendicular to that plane through which the arc of the second section (6) passes, and in which the supply lines (2) in the second section (6) are guided in a protective tube (8) of circular cross-section through a shaped part (13) of circular cross-section, the one along the direction of movement of the supply lines (2) in the second section (6) extending opening (17) through which the supply lines (2) in the first section (5) are also performed during length compensation, wherein the guide in the pivot point (4) a holding part is realized, which is rotatably connected to the supply lines and is itself designed not rotatable. In drawing 3, a position with unused length reserve is shown; Drawing 4 shows a position with almost completely used length reserve.

Fig. 5 shows an embodiment of the return means as a combination of three compression springs (10) which are mounted around a protective tube (8), in turn, the supply lines (2) surrounds, and the protectors (12) boundaries, which are also mounted around this protective tube (8).

Fig. 6 shows an embodiment of the return means as a torsion spring (11) which surrounds the supply lines (2) partially directly, and the axis of rotation through the pivot point (4).

7 shows an embodiment of the device section (3) according to the invention, serving for length compensation for movements of several robot axes, in which the supply lines (2) in the first section (5) are guided approximately perpendicularly to the plane in the area of the pivot point (4) the arc of the second section (6) extends, and in which the supply lines (2) in the second section (6) are guided in a protective tube (8) of circular cross-section through a shaped part (13) of circular cross-section, one along the direction of movement of Supply lines (2) in the second section (6) extending opening (17) through which the supply lines (2) in the first section (5) can also be performed during length compensation, and in which the supply lines (2) following the second section (6) in a third section (7) straight and substantially exactly in a protective tube (8) circular cross-section through a molded part (14) are guided circular cross-section, which has along the direction of movement of the supply lines (2) in the third section (7) extending opening (17), and in which the guide realized in the pivot point (4) by a holding part is, which is connected in a rotatable manner with the supply lines and itself not rotatable, and in which a torsion spring (11) whose axis of rotation passes through the pivot point (4), serves as the return means, and in which the supply lines (2) via the first section (5) and the second section (6) and the third section (7) are guided continuously within a closed mold part (16) which is designed to be hinged. The drawing depicts a position with unused length reserve.

8 shows an embodiment of the device section (3) according to the invention, which serves for length compensation for movements of a plurality of robot axes, in which the supply lines (2) in the first section (5) are guided approximately perpendicularly to the plane in the area of the pivot point (4) in which the arc of the second section (6) runs, and in which the supply lines (2) in the second section (6) are in an energy supply chain (9) of cuboidal cross section through a shaped part (13) are guided parallelepiped cross-section, the two along the direction of movement of the supply lines (2) in the second section (6) extending openings (17) through which the supply lines (2) in the first section (5) can also be performed during the length compensation, and in which the supply lines (2) following the second section (6) in a third section (7) are straight and substantially exactly continued by a molding (14) a protective tube (8) circular cross-section and a power supply chain (9) parallelepiped cross-section exactly, and in which the guide is realized in the fulcrum (4) by a holding part, which connected in a rotatable manner with the supply lines and even designed not rotatable is, and in which a torsion spring (11) whose axis of rotation passes through the pivot point (4), as a return beam is used, and in which the supply lines (2) over the first section (5) and the second section (6) and the third section (7) are guided continuously within a closed mold part (16) which is designed to be hinged. The drawing depicts a position with unused length reserve.

9 shows an embodiment of the device section (3) according to the invention serving for length compensation for movements of several robot axes, in which the supply lines (2) in the first section (5) are guided approximately perpendicularly to the plane in the area of the pivot point (4) the arc of the second section (6) extends, and in which the supply lines (2) in the second section (6) are guided in a protective tube (8) of circular cross-section through a shaped part (13) of circular cross-section, one along the direction of movement of Supply lines (2) in the second section (6) extending opening (17) through which the supply lines (2) in the first section (5) can also be performed during length compensation, and in which the guide in the pivot point (4) by a Holding part is realized, which is connected in a rotatable manner with the supply lines and even not rotatably mounted altet is, and in the three in the second section (6) within the molding (13) between four protective sleeves (8) surrounding protectors (12) mounted compression springs (10) serve as a return means, and in which the supply lines (2) via the first section (5) and the second section (6) are guided continuously within a closed mold part (15) which is configured hinged. The drawing forms a position with uncon- used length reserve from.

10 shows an embodiment of the device section (3) according to the invention serving for length compensation for movements of several robot axes, in which the supply lines (2) in the first section (5) are guided approximately perpendicularly to the plane in the area of the pivot point (4) the arc of the second section (6) extends, and in which the supply lines (2) in the second section (6) are guided in a protective tube (8) of circular cross-section through a shaped part (13) of circular cross-section, one along the direction of movement of Supply lines (2) in the second section (6) extending opening (17) through which the supply lines (2) in the first section (5) can also be performed during length compensation, and in which the guide in the pivot point (4) by a Holding part is realized, which is connected in a rotatable manner with the supply lines and even not rotatable and in which a torsion spring (11) whose axis of rotation passes through the fulcrum (4) serves as a return means, and in which the supply lines (2) through the first portion (5) and the second portion (6) throughout within a closed mold part (15) are guided, which is configured hinged. The drawing depicts a position with unused length reserve.

Fig. IIa and Fig. IIb show an embodiment of the invention, the length compensation for movements of multiple robot axes Voπichtungsab section (3), in which the supply lines (2) in the first section (5) in the region of the pivot point (4) approximately perpendicular to that Are guided level through which the arc of the second section (6), and in which the supply lines (2) in the second section (6) in a protective tube (8) of circular cross-section through a partially rotatably ausgestaltetes shaped part (13) of circular cross-section in which the supply lines (2) following the second section (6) in a third section (7) are guided straight and substantially exactly in a protective tube (8) of circular cross-section through a shaped part (14) of circular cross-section, the one along the direction of movement of the supply lines (2) in the third section (7) extending Ö Opening (17), and in which a torsion spring (11) whose axis of rotation passes through the pivot point (4), serves as a return means, and in which the supply lines (2) over the first section (5) and the second portion (6) and the third portion (7) are guided continuously within a closed mold part (16) which is designed to be foldable. The drawings depict a position with unused length reserve.

12 shows an embodiment of the device section (3) according to the invention, which serves for length compensation for movements of several robot axes, in which the supply lines (2) in the first section (5) are guided approximately perpendicularly to the plane in the area of the pivot point (4) the arc of the second section (6) extends, and in which the supply lines (2) in the second section (6) in an energy guide chain (9) cuboidal cross section through a molded part (13) are guided cuboidal cross section, the two along the direction of movement of Supply lines (2) in the second section (6) extending openings (17), wherein the supply lines (2) in the first section (5) and the length compensation through one of these openings (17) are passed through, and in which the supply lines (2 ) following the second section (6) in a third section (7) straight and substantially be continued exactly by a molding (14), which can perform a protective tube (8) circular cross-section and an energy guide chain (9) cuboid cross-section exactly, and in which the guide is realized in the pivot point (4) by a holding part, in a rotatable manner connected to the supply lines and is itself designed not rotatable, and in which in the third section (7) within the molding (14) between two protective sleeves (8) surrounding protectors (12) mounted compression spring (10) serves as the return means, and in in that the supply lines (2) are guided continuously through the first subsection (5) and the second subsection (6) and the third section (7) within a closed molded part (16) which is designed to be foldable. The drawing depicts a position with unused length reserve.

FIGS. 13, 14 and 15 show the attachment of one embodiment of the device section (3) according to the invention, which serves for length compensation for movements of several robot axes, along the structure of the industrial robot (1). LIST OF REFERENCE NUMBERS

1. industrial robot

2. Supply lines

3. Device section for length compensation for movements of several robot axes

4. pivot point

5. First section

6th second section

7. Third section

8. Protective hose

9. Energy chain

10. compression spring

11. Torsion spring

12. Protector

13. molding second section

14. molding third section

15. molding first and second sections

16. molding first and second sections and third section

17th opening

Claims

claims

A device for guiding supply lines (2) along the structure of an industrial robot (1), the supply lines (2) in a the length compensation for movements of multiple robot axes serving device section (3) with return means (10, 11) movably, characterized in that the supply lines (2) are led away from a pivot point (4) in a first subsection (5) and then substantially exactly, substantially circularly and substantially at a constant distance from the pivot point (4) in a second subsection (6). be continued so that bends of the supply lines (2) in the first section (5) remain substantially static even when length compensation and the supply lines (2) in the second section (6) can serve at least partially as a length reserve.

2. Apparatus according to claim 1, characterized in that the supply lines (2) in the first part section (5) in the region of the pivot point (4) are guided in that plane through which the arc of the second section (6).

3. A device according to claim 1, characterized in that the supply lines (2) in the first section (5) in the region of the pivot point (4) are guided approximately perpendicular to that plane through which the arc of the second section (6).

4. Device according to one of claims 1 to 3, characterized in that the supply lines (2) in the second section (6) in a protective tube (8) through a molded part (13) are guided, in the second section (6) has an opening (17) through which the supply lines (2) in the first section (5) are also guided during length compensation.

5. Device according to one of claims 1 to 3, characterized in that the supply lines (2) in the second section (6) in a power transmission chain (9) through a molded part (13) are guided, in the second section (6) has an opening (17) through which the supply lines (2) in the first section (5) are also guided during length compensation.

6. Device according to one of claims 1 to 5, characterized in that one or more compression springs (10) serve as a return means.

7. Device according to one of claims 1 to 5, characterized in that a torsion spring (11) serves as a return means whose axis of rotation through the pivot point (4) and whose rotational force acts along the arc of the second portion (6).

8. Device according to one of claims 1 to 7, characterized in that the supply lines (2) following the second section (6) in a third section (7) are continued straight and substantially exactly.

9. Apparatus according to claim 8, characterized in that the supply lines (2) in the third section (7) by a molded part (14) are guided, the protective tubes (8) and / or energy guiding chains (9) can perform different cross-section exactly.

10. Device according to one of claims 1 to 9, characterized in that the supply lines (2) in the first section (5) and second section (6) are guided continuously within a substantially closed mold part (15).

11. Device according to one of claims 8 or 9, characterized in that the supply lines (2) over the first portion (5) and the second portion (6) and the third portion (7) continuously within a substantially closed mold part (16) be guided.

12. Industrial robot with a device according to one of claims 1 to 11.