WO2017080642A1 - Supply line device and robot having such a supply line device - Google Patents

Abstract

The invention relates to a supply line device (16), comprising a first line device flange (17.1), which has at least one first fastening means (18.1), which is designed to fixedly fasten the first line device flange (17.1) to a first link (12.1) of a robot (1), a first circular ring component (19.1), which is supported on the first line device flange (17.1) in such a way that the first circular ring component can be rotated about a first main axis (HA1) and which, together with the first line device flange (17.1), forms a first rotary feed-through (20.1) for transferring line-conducted fluids or electrical energy, a second line device flange (17.2), which has at least one second fastening means (18.2), which is designed to fixedly fasten the second line device flange (17.2) to a second link (12.2) of the robot (1), and a second circular ring component (19.2), which is supported on the second line device flange (17.2) in such a way that the second circular ring component can be rotated about a second main axis (HA2) and which, together with the second line device flange (17.2), forms a second rotary feed-through (20.2) for transferring line-conducted fluids or electrical energy. The invention further relates to an associated robot (1) having such a supply line device (16).

Description

Supply line device and robot with such a supply line device

The invention relates to a supply line device and a robot comprising such a supply line device.

The object of the invention is to provide a supply line device and a robot with such a supply line device, so that electrical energy and / or fluids along the robot arm of the robot can be guided in a secure and reliable manner to a tool attached to the flange of the robot arm.

This object is achieved according to the invention by a supply line device, comprising a first line device flange, which has at least one first attachment means, which is designed for the rigid attachment of the first line device flange to a first link of a robot, a first circular ring component which is attached to the first line link first conduit flange is rotatably supported about a first major axis and forms with the first conduit flange a first rotary union for transmitting conduction fluid or electrical energy, and comprising a second conduit flange having at least one second attachment means adapted to rigidly secure the conduit second conduit member flange is formed on a second member of the robot, a second annular member which is rotatably mounted on the second Leitungsvorrich- tion flange about a second main axis and with the second Leitun gsvorrichtungsflansch forms a second rotary feedthrough for the transmission of conducted fluids and / or electrical energy, and comprising a rigid connecting leg, which the first annular member with the second annular member in an orthogonal len rigidly connects the first annulus component to the second annulus component, wherein the rigid connecting leg has at least one line section which is formed, the fluid introduced from the first Leitungsvorrichtungs- via the first rotary feedthrough in the first annular member and / or the electrical energy in the second To initiate annulus component.

Robots, in particular industrial robots, are working machines which can be equipped with tools for the automatic handling and / or machining of objects and which can be programmed by means of their joints in a plurality of axes of movement, for example with regard to orientation, position and workflow. Robots usually have a robot arm with several automatically or manually adjustable in particular by electrical drives joints (axes) and a programmable robot control that controls the movements of the robot during operation or controls.

The robot may be a so-called articulated robot whose robot arm has a base frame as a member on which a carousel is rotatably mounted as a following member about a vertical axis and rotationally driven by a first drive motor. On the carousel, a rocker can be mounted as a further member pivotable about a second horizontal axis up and down and rotatably driven by a second drive motor. The rocker carries an arm boom, which is pivotally mounted about a third horizontal axis up and down and rotatably driven by a third drive motor. On the arm boom whose base arm forms a further member, a fourth axis may be provided, which extends in the longitudinal extension of the arm arm and a fourth drive motor, a robot hand, which forms a forearm of the arm arm and is another member rotatably drives. From the robot hand can be a first Leg and a second leg fork-shaped forward. The two legs carry a bearing for a free end of the robot hand, which forms a penultimate member. The bearing defines a fifth axis of the robot arm about which the robot hand can be pivotally moved by means of a fifth drive motor. In addition, the robot ^¬ hand has a sixth axis in order to drive a mounting flange, which forms a last link rotatably by means of a sixth drive motor can. Each of the joints may be formed as a hinge. Each link is configured to transfer forces and moments, which in particular are transferred from a gripper or tool, which is handled by the robot, in particular, via a tool mounting flange of the robot arm into the robot arm, ie into its structure, from a joint to a following joint forward. In addition, forces and moments which originate from the self-weight force of the robot arm, must be forwarded into the base frame of the robot arm. Each member of the robot arm has to at least one structural part, which is designed to absorb these forces and moments and forward. In general, such a structural part is hollow and can for example consist of a metal casting or a welded steel construction, which may have, for example, pipe sections. Each member is connected via one of the joints with an immediately following member of the robot arm, in particular rotatably connected. For this purpose, the respective joint may have a pivot bearing. Each rotary bearing may be associated with a sealing arrangement, such as a radial shaft sealing ring. At each joint or each pivot bearing a separate drive motor, such as an electric motor, in particular a servomotor, be coupled with drivable drive control automatically driven. The drives are generally controlled by a robot controller Robot controlled. The robot control allows the joints to be automated by means of the drives in accordance with a robot program or to be drive-controlled in a hand-held mode of the robot in order to change the configuration of the robot arm. Under one configuration, the amount of current, each Achswinkelstellungen is the Ge ^¬ joints of the robot arm understood.

Even if the members of the robot arm are formed as hollow structural parts, within which electrical energy

and / or fluids could be concealed, it may be appropriate or even necessary, for example, due to the design of the joints, the construction of gears and the arrangement of the drive motors, the electrical energy and / or the fluids outside the limbs or outside of the hollow structural parts to guide one or more relevant joints around to a tool attached to the flange of the robot arm.

In known types, however, a flexible supply line conducting the electrical energy and / or the fluids then runs largely unprotected and freely suspended outside the robot arm. Such a free-hanging arrangement of a flexible supply line has a high wear and represents a not exactly predeterminable interference contour of the robot arm. By the invention, a rigid connecting leg is provided, which the first circular ring component with the second annular component in an orthogonal orientation of the first circular component to second annular component rigidly connecting and idem the rigid connecting leg has at least one line portion which is formed, the fluid introduced from the first Leitungsvorrichtungsflansch on the first rotary feedthrough in the first annular member and / or to introduce the electrical energy into the second annular component, a safe, low-wear supply line is created, which occupies a precisely predetermined arrangement and position in space, so that the interference contour of the robot arm is clearly predetermined and possibly also maintenance measures on the supply line Simple way, ie without being able to carry out elaborate disassembly measures on the robot arm. By means of the supply line device according to the invention a costly installation of supply lines within the members of the robot arm can be saved. Moreover, the supply line device of the present invention, which is routed outside the members of the robot arm, can not undesirably strike and rub against members of the robot arm during movement of the robot arm, whereby the durability of the cable routing can be significantly increased.

The fluids supplied by means of the supply line device to a tool of the robot may be gaseous fluids, such as compressed air, or they may be liquid fluids, such as water or oil. The supply line device may not have a single line or it may have two or more individual lines. Several individual lines can be combined to form a trunk group.

As an alternative or in addition to such fluids, electrical energy can also be conducted to a tool of the robot by means of the supply line device. The electrical energy can be passed through a single electrical line, two or more individual electrical lines or a wiring harness or a trunk group. The electrical energy can be used to supply movable working devices of the tool. Alternatively or additionally, the electrical energy but also only for Serving signal transmission, for example, for the transmission of signals, information and / or measured value, which originate from sensors or transducers of the tool. Each supply line, whether for fluid or for electrical energy, can optionally be designed for forward transport to the tool and / or return transport from the tool.

Each Leitungsvorrichtungsflansch can be formed by a circular disc-shaped flange body. Each Leitungsvorrichtungsflansch may have a receptacle for the respective circular ring component. The receptacle can be designed to completely receive the respective annular component. In the receptacle, one or more bearings, in particular slide bearings or roller bearings may be arranged, by means of which the respective annular component is rotatably mounted on the Leitungsvorrich- tungsflansch or rotatably in the Leitungsvorrichtungsflansch.

The attachment means may be, for example, screws which connect the conduit flange to the respective member of the robot. The respective fastening means can accordingly be a releasable fastening means. The attachment means may in particular be designed such that the respective conduit flange can be manually fastened to the respective member of the robot with conventional hand tools, without the robot or the robot arm having to be partially or completely disassembled. In that regard, the entire Leitungsvorrichtungsflansch be designed for subsequent attachment to a functional robot arm. The entire Leitungsvorrichtungs- flange can also for later, in particular complete disassembly of the robot arm releasably attached to the robot arm. be attached. Each Leitungsvorrichtungsflansch can be made for example of metal, especially steel, or aluminum. Alternatively, any line device flange may also be made of plastic, in particular fiber-reinforced plastic.

The annulus member may be configured to be completely received in the respective conduit flange. Each annular component can accordingly be rotatably mounted in the Leitungsvorrichtungsflansch by means of one or more bearings, in particular plain bearings or rolling bearings.

Each rotary feedthrough is designed to transfer line-guided fluids and / or electrical energy from the respective line device flange to the associated circular ring component or from the associated circular ring component to the respective line device flange. Each rotary union must be designed accordingly, in spite of the rotatable mobility of the conduit flange and

Circular component against each other, the fluid in question leak-free and / or the electrical energy trouble-free, in particular without interruption to transfer. In the case of electrical energy, for example, such a rotary leadthrough can be a sliding contact known to the person skilled in the art. Such sliding contact can be a known

 Slip ring and a per se known brush. Such a rotary union may, in the case of fluids, provide a sealed transition between a stationary body such as the conduit flange and a rotating body such as the annulus component. Such a rotary feedthrough for fluids may be single-flow, i. single-channel or multi-flow, i. be formed multi-channel. In the case of fluids, therefore, such a rotary feedthrough can, as it were, form a hydraulic sliding contact or hydraulic slip ring.

The connecting leg forms on the one hand a strut, which the first circular ring component with the second circular ring component On the other hand, the connecting leg forms at least one conduit section for transporting fluid and / or electrical energy to the fluid introduced from the first conduit device flange into the first annular member via the first rotary union introducing the electrical energy into the second annular component or returning the fluid returned from the second conduit flange via the second rotary union to the second annular component and / or the electrical energy back into the first annular component.

The first rotary feedthrough can at least a first

Sliding contact, which is adapted to transmit electrical energy from the first Leitungsvorrichtungsflansch on the first annular member and / or the second rotary union may comprise at least a second sliding contact, which is adapted to transfer electrical energy from the second annular member to the second Leitungsvorrich- supply flange ,

Appropriately, the first rotary feedthrough and the second rotary feedthrough are similar. However, in principle, the first rotary feedthrough be designed differently or configured, as the second rotary feedthrough.

An inventive sliding contact may have a known slip ring and a per se, known brush. Each rotary feedthrough can, depending on the application, ie depending on the type of tool to be supplied, either have only a single sliding contact that contacts only a single electrical line or two or more sliding contact can be provided to contact two or more electrical lines can , So can several Sliding contacts are formed by multiple pairs of slip rings and brushes. The brushes can be formed in a conventional manner, for example, by carbon contacts or spring contacts, for example made of copper or silvered or gold-plated metals.

The first rotary union may include at least one annular channel configured to transfer fluid from the first conduit flange to the first annular component and / or the second rotary union may include at least one annular channel formed to receive the fluid from the second annular component to transfer the second pipe flange. Any such rotary feedthrough for fluids may, depending on the application, i. Depending on the nature of the tool to be supplied, either have only a single annular channel, which forwards only a single fluid or two or more annular channels can be provided to forward two or more fluids.

Such a rotary union may, in the case of fluids, provide a sealed transition between a stationary body such as the conduit flange and a rotating body such as the annulus component. Such a rotary feedthrough for fluids may be single-flow, i. single-channel or multi-flow, i. be formed multi-channel. In the case of fluids, therefore, such a rotary feedthrough can, as it were, form a hydraulic sliding contact or hydraulic slip ring.

The annular channel can be delimited by a first annular groove formed in the first conduit flange or in the second conduit flange and a second annular groove formed in the first annular component or in the second annular component, wherein the two annular grooves th by means of at least one seal fluid-tight and against each other are rotatably sealed.

Thus, for example, one of the respective annular component facing end wall of the respective Leitungsvorrichtungs- flange having the first annular groove and the associated annular member in turn have a Leitungsvorrichtungs- the flange facing end wall, which carries the second annular groove on a diameter which is identical to the diameter of the first annular groove , Is in the installed position, the end wall of the circular ring component flush on the end wall of the Leitungsvorrichtungsflansches, then lie the first annular groove and the second annular groove flush with each other and thereby limit from two opposite sides of the annular channel. A possibly occurring gap between the end wall of the circular ring component and the end wall of the conduit flange may be sealed by means of at least one seal, such as an O-ring. The seal or the 0-ring can also be grease-lubricated.

The first line device flange may have an annular first receiving channel in which the first annular component is rotatably mounted and / or the second line device flange may have an annular second receiving channel in which the second annular component is rotatably mounted. The annular receiving channel may have a rectangular or square cross-section. The receiving channel may have a bottom wall, an inner peripheral wall, and an outer circumferential wall, wherein the bottom wall, the inner peripheral wall, and the outer peripheral wall define the annular member from three sides. The first annular component may be rotatably supported by at least one first rolling bearing in the first receiving channel of the first Leitungsvorrichtungsflansches and / or the second annular member may be rotatably supported by at least one second rolling bearing in the second receiving channel of the second Leitungsvorrichtungsflansches.

Instead of rolling bearings may optionally also slide bearings are used. Whether rolling bearing or plain bearing, the rigid connecting leg may be stored via the first annular member and the second annular member at the first conduit flange and at the second conduit flange. For this purpose, a fixed bearing and a support bearing can be provided either in the first Leitungsvorrichtungsflansch or in the second Leitungsvorrichtungs-. Alternatively, the fixed bearing may be provided in one conduit flange and the support bearing in the other conduit flange.

The first circular ring component may have a first inner end wall facing the first line device flange, on which the first rotary feedthrough is formed

and / or the second annular component may have a second inner end wall facing the second conduit flange, on which the second rotary leadthrough is formed.

The first annular component may have a first outer jacket wall on which the first rotary leadthrough is formed, and / or the second annular component may have a second outer jacket wall on which the second rotary leadthrough is formed.

The first annulus member may have a first outer end wall facing away from the first conduit flange, on which a first leg end of the rigid connecting leg is fixed and the second annular member may have a second outer end wall facing away from the second Leitungsvorrichtungsflansch, at which a second

Leg end of the rigid connecting leg is attached.

The rigid connecting leg can be formed by a solid component, in which a first line section in the form of a hollow channel for guiding a fluid is introduced.

A rigid connecting leg can be understood to mean a component which is at least substantially dimensionally stable. This means that the connecting leg has no appreciable flexibility, which is a significant, i. would allow visible deformation. Accordingly, the rigid connecting leg can be made of metal, in particular steel or aluminum. The connecting leg can be a cast part insofar. Alternatively, if appropriate, the rigid connecting leg can also be designed as a plastic component, for example, made of a particular fiber-reinforced plastic. Accordingly, the connecting leg may possibly be a plastic injection-molded part.

The rigid connecting leg may have a cavity in which at least one electrical line is laid, in particular an electrical line is laid, which leads the electrical energy from the first sliding contact to the second sliding contact.

In general, the rigid connecting leg can be formed in one piece, in two parts or in several parts. In the case that the rigid connecting leg has a cavity, in the case of a two-part or multi-part design, a parting plane can run through the cavity, so that the cavity is accessible when taken apart two-piece or multi-part connecting leg, for example, to move electrical lines in the cavity, or to perform maintenance. The object is also achieved by a robot comprising a robot controller and a robot arm having a plurality of links connected by links, one of the links forming an intermediate member rotatable via a first pivot with a first link disposed in the kinematic chain of the robotic arm upstream of the link is rotatably connected via a second pivot with a downstream in the kinematic chain of the robot arm of the intermediate member second member, wherein the axis of rotation of the first pivot orthogonal to the axis of rotation of the second pivot joint is aligned and the robot arm bridging the intermediate member supply line device, after a or more of the embodiments as described in the invention. The joints of the robot arm are automated by drive motors of the robot coupled to the joints in accordance with a robot program executed by the robot controller, or drive-controlled in a hand-held mode of the robot to change the configuration of the robot arm.

The first member may be formed by an arm arm of the robotic arm with the first conduit flange of the supply conduit device attached to this arm boom and the second member may be formed by a flange of the robotic arm with the second conduit flange of the utility conduit attached to that flange.

A concrete embodiment of the invention is described in the following description with reference to the attached Figures explained in more detail. Concrete features of this exemplary embodiment, irrespective of the specific context in which they are mentioned, if appropriate also considered individually or in further combinations, represent general features of the invention.

a perspective view of an exemplary robot with a robot arm and a robot controller; an enlarged partial view of the robot of Figure 1 in the region of the fifth and sixth axis of the robot hand with an exemplary schematic embodiment of a supply line according to the invention orrichtung; a sectional view through the area of the fifth and sixth axis of the robot hand of Figure 2 with the exemplary schematic embodiment of the supply line device according to the invention. and an enlarged partial sectional view through the supply line device according to the invention in the region of one of the rotary feedthroughs.

FIG. 1 shows a robot 1 having a robot arm 2 and a robot controller 13. In the case of the present exemplary embodiment, the robot arm 2 comprises a plurality of links 12 arranged one after the other and connected by means of joints 11. The links 12 are in particular a frame 3 and a relative to the frame 3 about a vertical axis AI rotatably mounted carousel 4. Further members of the robot arm 2 are in the case of the present embodiment, a rocker arm 5, an arm boom 6 and a preferably multi-axis robot hand 7 with a flange 8 as executed Fastening device 15 for attaching an end effector, not shown, ie tool. The rocker 5 is pivotally mounted at the lower end, for example on a swing bearing head not shown on the carousel 4 about a preferably horizontal axis of rotation A2. At the upper end of the rocker 5 turn the arm arm 6 is pivotally mounted about a likewise preferably horizontal axis A3. This end carries the robot hand 7 with its preferably three axes of rotation A4, A5, A6.

In the case of the present exemplary embodiment, the arm extension 6 has a first housing component 9 mounted pivotably on the rocker 5. A second housing component 10 of a second member 12 of the arm extension 6 is rotatably mounted about the axis A4 on the first housing component 9 of a first member 12.

The robot 1 accordingly comprises a robot controller 13 and a robot arm 2 having a plurality of joints 11 connected by links 12, which are automated by drive motors of the robot 1 coupled to the joints 11 in accordance with a robot program executed by the robot controller 13 or in a manual mode of the robot 1 are drive-controlled in order to change the configuration of the robot arm 2, wherein of the links 12 forms an intermediate member 12.3, which via a first pivot 11.1 with a in the kinematic chain of the robot arm 2 the intermediate member 12.3 upstream first member 12.1 is rotatably connected and that via a second pivot 11.2 with a in the kinematic chain of the robot arm 2 the Zwi link 12.3 downstream second member 12.2 is rotatably connected, wherein the axis of rotation of the first pivot joint

11.1 (HAI) orthogonal to the axis of rotation of the second hinge

11.2 (HA2) is aligned. 2 shows the robot arm 2 in the region of his hand, which is equipped with a supply line device 16 according to the invention bridging the intermediate element 12.3.

In this illustrated embodiment, the first member 12.1 is formed by the arm bracket 6, wherein a first Leitungsvorrichtungsflansch 17.1 of the supply line device 16 is attached to this arm boom 6 and the second member 12.2 formed by the flange 8, wherein a second Leitungsvorrichtungsflansch 17.2 of the supply line device 16 at this Flange 8 is attached. As is shown in more detail in particular in FIGS. 2 to 4, the supply line device 16 has the first line device flange 17. 1, which has at least one first fastening element 18. 1, which is designed to rigidly fasten the first line device flange 17. 1 to the first element 12. The supply line device 16 also has a first circular ring component 19.1, which is rotatably mounted on the first line device flange 17.1 about a first main axis HAI and forms with the first line device flange 17.1 a first rotary feedthrough 20.1 for the transmission of conducted fluids or electrical energy. The supply line device 16 also has the second line device flange 17.2, which has at least one second attachment means 18.2, which is designed for the rigid attachment of the second line device flange 17.2 to the second element 12.2. The supply line device 16 also has a second circular ring component 19. 2, which on the second Leitungsvorrichtungsflansch 17.2 to a second

Main axis HA2 is rotatably mounted and forms with the second Leitungsvorrichtungsflansches 17.2 a second rotary feedthrough 20.2 for the transmission of conducted fluids and / or electrical energy. The supply line device 16 also has a rigid connecting leg 21, which rigidly connects the first circular ring component 19.1 to the second circular ring component 19.2 in an orthogonal orientation from the first circular ring component 19.1 to the second circular component 19.2, wherein the rigid connecting leg 21 has at least one line segment 22 which is formed to introduce the fluid introduced from the first line device flange 17.1 via the first rotary feedthrough 20.1 into the first circular ring component 19.1 and / or the electrical energy into the second circular ring component 19.2.

In the case of the present exemplary embodiment, the first rotary feedthrough 20.1 has, in particular, four first sliding contacts 23, which are designed to transmit electrical energy from the first line device flange 17.1 to the first circular ring component 19.1. Similarly, the second rotary feedthrough 20.2 in an analogous manner to four second sliding contacts 24 which are adapted to transfer electrical energy from the second annular member 19.2 to the second Leitungsvorrichtungsflansch 17.2.

At the same time, the first rotary feedthrough 20.1 has in particular two annular channels 25, which are designed to transfer a fluid from the first line device flange 17.1 to the first circular ring component 19.1. In the case of the present exemplary embodiment, the second rotary feedthrough 20.2 also has two annular channels 25, which are designed to transfer the fluid from the second annular component 19.2 to the second line device flange 17.2. The annular channel 25 becomes in the case of the present embodiment of one in the first Leitungsvorrichtungsflansch

17.1 or in the second Leitungsvorrichtungsflansch 17.2 formed first annular groove 25a and one in the first annular component 19.1 and in the second annular component

19.2 formed second annular groove 25b, wherein the two annular grooves 25a, 25b by means of at least one seal 32, which is formed in the case of the present embodiment of 0- rings, fluid-tight and against each other rotatably sealed.

The first Leitungsvorrichtungsflansch 17.1 has an annular first receiving channel 26.1, in which the first circular ring member 19.1 is rotatably mounted and the second Leitungsvorrichtungsflansch 17.2 has a similar annular second receiving channel 26.2, in which the second circular ring member 19.2 is rotatably mounted.

The first annular component 19.1 is rotatably supported by means of at least one first rolling bearing 27.1 in the first receiving channel 26.1 of the first Leitungsvorrichtungsflansches 17.1 and the second annular member 19.2 is rotatably supported by at least one second roller bearing 27.2 in an analogous manner in the second receiving channel 26.2 of the second Leitungsvorrichtungsflansches 17.2.

The first circular ring component 19.1 has a first inner end wall 17.1 facing the first Leitungsvorrichtungsflansch

28.1, on which the first rotary feedthrough 20.1 is formed. In the same way, the second annular component 19.2 also has a second conduit flange

17.2 facing the second inner end wall 28.2, on which the second rotary feedthrough 20.2 is formed. The first circular ring component 19.1 also has a first outer sheath wall 29.1, on which the first rotary leadthrough 20.1 is formed, and the second circular ring component 19.2 likewise has a second outer sheath wall 29.2, on which the second rotary leadthrough 20.2 is formed.

In addition, the first circular ring component 19.1 has a first outer end wall 30.1 pointing away from the first Leitungsvorrichtungsflansch 17.1, to which a first leg end 21.1 of the rigid connecting leg 21 is fixed and the second annular member 19.2 has a second Leitungsvorrichtungsflansch 17.2 away facing second outer end wall 30.2 on which a second leg end 21.2 of the rigid connecting leg 21 is attached.

In the case of the present exemplary embodiment, the rigid connecting leg 21 is formed by a solid component in which a first line section 22 in the form of a hollow channel 22. 1 for guiding a fluid is introduced. In addition, the rigid connecting leg 21 has a cavity 22. 2, in which at least one electrical line 31 is laid which supplies the electrical energy from the first

Sliding contact 23 leads to the second sliding contact 24.

Claims

claims

Supply line device, having

 - A first Leitungsvorrichtungsflansch (17.1) having at least a first fastening means (18.1), which for the rigid attachment of the first Leitungsvorrichtungsflansches (17.1) to a first member

 (12.1) of a robot (1) is formed,

 - A first annular member (19.1) which is rotatably mounted on the first Leitungsvorrichtungsflansch (17.1) about a first main axis (HAI) and with the first Leitungsvorrichtungsflansch (17.1) a first rotary feedthrough (20.1) for transmitting conducted fluids and / or electrical energy forms,

 - A second Leitungsvorrichtungsflansch (17.2) having at least a second fastening means (18.2), which for the rigid attachment of the second Leitungsvorrichtungsflansches (17.2) to a second member

(12.2) of the robot (1) is formed,

 a second annular component (19.2) which is rotatably mounted on the second Leitungsvorrichtungsflansch (17.2) about a second major axis (HA2) and the second Leitungsvorrichtungsflansch (17.2) a second rotary feedthrough (20.2) for transmitting conducted fluids and / or electrical energy forms, and

a rigid connecting leg (21) which rigidly connects the first annular component (19.1) to the second annular component (19.2) in an orthogonal orientation of the first annular component (19.1) to the second annular component (19.2), the rigid connecting leg (21) at least one Conduction portion (22) which is formed, which from the first Leitungsvorrichtungsflansch (17.1) via the first rotary feedthrough (20.1) into the first circular ring component (19.1) initiated fluid and / or the electrical energy in the second annular component (19.2) to initiate.

Supply line device according to claim 1, characterized in that the first rotary feedthrough (20.1) has at least one first sliding contact (23) which is designed to transfer electrical energy from the first line device flange (17.1) to the first circular ring component (19.1) and / or the second rotary feedthrough (20.2) has at least one second sliding contact (24) which is designed to transmit electrical energy from the second annular component (19.2) to the second conduit flange (17.2).

Supply line device according to claim 1 or 2, characterized in that the first rotary feedthrough (20.1) has at least one annular channel (25) which is formed, a fluid from the first Leitungsvorrichtungsflansch (17.1) on the first annular member

(19.1) and / or the second rotary feedthrough (20.2) has at least one annular channel (25) which is designed to transfer the fluid from the second annular component (19.2) to the second conduit flange (17.2).

Supply line device according to claim 3, characterized in that the annular channel (25) of a in the first Leitungsvorrichtungsflansch (17.1) and in the second Leitungsvorrichtungsflansch (17.2) formed first annular groove (25a) and one in the first annular member (19.1) or in the second annular component

(19.2) formed second annular groove (25b) is limited, wherein the two annular grooves (25a, 25b) by means of at least one seal (32) are sealed fluid-tight and against each other rotatable. Supply line device according to one of claims 1 to 4, characterized in that the first line device flange (17.1) has an annular first receiving channel (26.1) in which the first circular ring component (19.1) is rotatably mounted and / or the second line device flange (17.2) an annular second receiving channel (26.2), in which the second annular component (19.2) is rotatably mounted.

Supply line device according to claim 5, characterized in that the first circular ring component (19.1) by means of at least one first rolling bearing (27.1) in the first receiving channel (26.1) of the first Leitungsvorrichtungsflansches (17.1) is rotatably mounted and / or the second circular ring component (19.2) by means of at least a second rolling bearing (27.2) is rotatably mounted in the second receiving channel (26.2) of the second Leitungsvorrichtungsflansches (17.2).

Supply line device according to one of claims 1 to 6, characterized in that the first circular ring component (19.1) has a first Leitungsvorrichtungs- flange (17.1) facing first inner end wall (28.1) on which the first rotary feedthrough (20.1) is formed and / or the second annular component (19.2) has a second Leitungsvorrichtungsflansch (17.2) facing the second inner end wall (28.2) on which the second rotary feedthrough (20.2) is formed.

Supply line device according to one of claims 1 to 7, characterized in that the first circular ring component (19.1) has a first outer casing wall (29.1) on which the first rotary feedthrough (20.1) is formed and / or the second annular component (19.2) has a second outer jacket wall (29.2) on which the second rotary leadthrough (20.2) is formed.

Supply line device according to one of Claims 1 to 8, characterized in that the first circular ring component (19.1) has a first outer end wall (30.1) pointing away from the first line device flange (17.1), at which a first leg end (21.1) of the rigid connecting leg (21st) ) and / or the second circular ring component (19.2) has a second outer end wall (30.2) pointing away from the second line device flange (17.2), to which a second leg end (21.2) of the rigid connecting leg (21) is fastened.

Supply line device according to one of claims 1 to 9, characterized in that the rigid connecting leg (21) is formed by a solid component, in which a first line section (22) in the form of a hollow channel (22.1) is introduced for guiding a fluid.

Supply line device according to one of claims 1 to 10, characterized in that the rigid connecting leg (21) has a cavity (22.2) in which at least one electrical line (31) is laid, in particular an electrical line (31) is laid, which the electrical energy from the first one

Sliding contact (23) leads to the second sliding contact (24).

A robot comprising a robot controller (13) and a robot arm (2) having a plurality of joints (11) connected by links (12), one of the links (12) being an intermediate member (12.3) connected via a first pivot (11.1) with one in the kinematic chain of the boterarms (2) the intermediate member (12.3) upstream first member (12.1) is rotatably connected and via a second pivot (11.2) with a in the kinematic chain of the robot arm (2) the intermediate member (12.3) downstream second member (12.2) rotatable wherein the axis of rotation of the first rotary joint (11.1) is oriented orthogonally to the axis of rotation of the second rotary joint (11.2) and the robot arm (2) comprises a supply line device (16) according to one of claims 1 to 11 bridging the intermediate element (12.3).

A robot according to claim 12, characterized in that the first member (12.1) is formed by an arm extension (6) of the robot arm (2) and the first conduit device flange (17.1) of the supply conduit device (16) is attached to this arm extension (6) and the second member (12.2) is formed by a flange (8) of the robot arm (2) and the second conduit flange (17.2) of the supply conduit device (16) is attached to this flange (8).