Supply device for a handling robot arm having at least one joint and hardening mechanism for such a supply device
阅读说明:本技术 用于具有至少一个关节的操作机械臂的供应装置和用于这种供应装置的硬化机构 (Supply device for a handling robot arm having at least one joint and hardening mechanism for such a supply device ) 是由 J·埃利特 M-A·格雷沃 于 2019-03-11 设计创作,主要内容包括:本发明涉及一种供应装置(1),用于尤其是工业机器人(3)的具有至少一个关节的操作机械臂(2),包括柔性管线组(13)和包围管线组(13)的且易曲挠的引导罩(19),通过该管线组能至少基本上沿该操作机械臂(2)给其末端执行器(12)供应至少一种过程介质。根据本发明,设有具有保持装置(15)的硬化机构(14),该保持装置位置固定地布置在所述易曲挠的引导罩(19)上,并且设有至少一个借助该保持装置(15)被保持的硬化件(16,23),在硬化机构(14)启用状态中,该硬化件承受硬化能量,由此该易曲挠的引导罩(19)和进而该管线组(13)借助该硬化件(16,23)被硬化。(The invention relates to a supply device (1) for a handling robot arm (2) having at least one joint, in particular for an industrial robot (3), comprising a flexible line set (13) and a flexible guide hood (19) which surrounds the line set (13) and by means of which an end effector (12) thereof can be supplied with at least one process medium at least substantially along the handling robot arm (2). According to the invention, a hardening mechanism (14) having a holding device (15) is provided, which is arranged in a stationary manner on the flexible guide hood (19), and at least one hardening part (16,23) is provided, which is held by means of the holding device (15), and which, in an activated state of the hardening mechanism (14), is subjected to hardening energy, whereby the flexible guide hood (19) and thus the line set (13) are hardened by means of the hardening part (16, 23).)
1. A supply device (1) for a manipulator arm (2) of an industrial robot (3) having at least one joint, comprising a flexible line set (13) by means of which an end effector (12) thereof can be supplied with at least one process medium at least substantially along the manipulator arm (2), and a flexible guide hood (19) which surrounds the line set (13),
the device is characterized in that a hardening mechanism (14) having a holding device (15) is provided, and at least one hardening element (16,23) is provided, which is held by means of the holding device (15) and is arranged in a stationary manner on the flexible guide hood (19), wherein the hardening element is subjected to hardening energy in an activated state of the hardening mechanism (14), whereby the flexible guide hood (19) and thus the line set (13) are hardened by means of the hardening element (16, 23).
2. Supply device (1) according to claim 1, characterized in that the at least one stiffening element (16) is designed as a flexible hose part (23), the hose wall (24) of which delimits a passage part (25) through which a fluid can flow, which passage part is completely filled with fluid in the activated state, and in that the stiffening element (16,23) is subjected to stiffening energy by the fluid in the passage part (25) being subjected to a stiffening pressure.
3. Supply device (1) according to one of the preceding claims, characterized in that the holding device (15) has at least one stiffening element receptacle (17) arranged parallel to the guide hood (19), by means of which the at least one stiffening element (16,23) is held on the holding device (15).
4. Supply device (1) according to one of the preceding claims, characterized in that the holding device (15) and the guide hood (19) are formed integrally with each other.
5. Supply device (1) according to one of the preceding claims, characterized in that the holding device (15) and the guide hood (19) are each made at least partially of fabric.
6. Supply device (1) according to one of the preceding claims, characterized in that the stiffening means (14) have a flexible protective cover (28) which is formed separately from the guide cover (19) and which encloses the line set (13), the holding device (15), the guide cover (19) and the at least one stiffening element (16,23) together in the protective position.
7. Supply device (1) according to one of the preceding claims, characterized in that the first end (38) of the hardening means (14) is constituted by a connecting unit (39) which can fix the hardening means (14) to the handling robot (2) remote from the end-effector (12).
8. Supply device (1) according to one of the preceding claims, characterized in that the second end (36) of the hardening means (14) is formed by a second connecting unit (37) by means of which the hardening means (14) can be fixed to the handling robot (2) close to the end effector (12).
9. Supply device (1) according to one of the preceding claims, characterized in that the curing means (14) has a sensor device (70) with at least one sensor element (69), by means of which sensor device at least one sensor signal which characterizes the state of the curing means (14) can be supplied to an evaluation unit.
10. A curing mechanism (14) for a supply device (1) for a manipulator arm (2) with at least one joint, in particular of an industrial robot (3), which is designed according to one of claims 1 to 9, having a flexible line set (13) which can supply its end effector (12) with at least one process medium at least substantially along the manipulator arm (2) and a flexible guide hood (19) which surrounds the line set (13).
Technical Field
The present invention relates to a supply device for a handling robot arm with at least one joint according to the preamble of claim 1. The invention also relates to a stiffening/strengthening mechanism (Versteifungseinrichtung) for such a supply device according to
Background
In modern production plants, in particular in the case of mass production of motor vehicles, use is made of supply devices for industrial robots for mass production. The respective supply device is provided for a manipulator arm, in particular of an industrial robot, having at least one joint and has a flexible line set, by means of which an end effector of the manipulator arm can be supplied with at least one process medium at least substantially along the manipulator arm. In addition, the supply device has a flexible boot surrounding the line set.
The line set is flexible, i.e. pliable or bendable, and is designed to be deformed by means of the operating robot arm such that the line set at least substantially follows the movement of the operating robot arm in case of its own deformation. The pipeline group has at least one pipeline or a plurality of pipelines concentrated in the pipeline group. The individual lines of the line set can each comprise at least one electrical conductor, at least one fluid conductor and/or further hard, cable and/or flexible elements, so that the end effector can be supplied with the at least one process medium and/or the at least one process medium can be removed from the end effector by means of the line set.
The set of flexible lines extends at least substantially along, e.g. at least substantially parallel to, the handling robot arm. In particular, the line set can extend from the base of the industrial robot or the manipulator arm up to the end effector, in particular from the third axis of motion of the manipulator arm up to the sixth axis of motion, wherein the end effector is arranged in the region of the sixth axis of motion of the manipulator arm or the industrial robot.
In industrial robots, an end effector is the last movement link of a kinematic chain of an industrial robot and can be formed, for example, in the form of a gripper unit, a tool unit (e.g., a welding unit, a riveting unit, a screwing unit, etc.), and/or a sensor unit.
By means of the line set, the end effector can be supplied with at least one process medium, which can be, in particular, electricity, at least one fluid and/or at least one object. Likewise, the at least one process medium can be discharged from the end effector by means of the flexible line set. For this purpose, at least one line of the flexible line set can be designed as an electrically conductive element (e.g. a cable, a wire, etc.), so that sensor electrical signals, welding electrical energy, operating electrical energy, etc. can be supplied along the operating robot by means of the line set or by means of the supply device. Alternatively or additionally, the individual lines of the line set can be designed as fluid conductors, so that coolant, glue, lubricant, water, hydraulic fluid, protective gas, etc. can be conveyed by means of the supply device. It is also common today that at least one line of the line set is designed as a further hard tube, cable and/or hose piece, so that, for example, screws, rivets, welding wire, raw material and the like can be fed through and/or can be guided through the supply device. The flexible boot is a hard or soft tubing in an extended or straight state, and the line set is disposed within the lumen formed thereby such that the longitudinal center axis of the line set coincides with the longitudinal center axis of the boot. Typically, a common boot is constructed of a flexible tube or bellows of plastic material. With the aid of the boot, the individual lines of the line set are bundled in the boot interior to prevent objects adjacent to the operating robot from penetrating or being hooked between the individual lines of the line set and thereby protect the supply device from damage. The boot itself is designed to be pliable or bendable so that the boot at least substantially follows the shape and/or orientation of the line set in the assembled state.
Such conventional supply devices are limited in their flexibility by the material properties of the guide hood in particular, with the result that, for example, retraction systems are provided which can be designed as spring tensioning devices and/or cable tensioning devices. The retraction system ensures that the line set or boot is subjected to substantial mechanical tension to ensure the best possible guidance along the operating robotic arm. Whereby the line set or the feeding device should be prevented from hooking onto an adjacent robot or other object. Further, the retraction system reduces the required extraction length of the supply device line group, for example, when the required extraction length of the line group is shortened by the movement of the operation robot arm.
Retraction systems are particularly complex and prone to failure and are therefore undesirable because non-productive or unapproved operational robot arm stop conditions often result from a malfunction or defect in the retraction system.
In order to avoid the handling of the robot arm during retraction of the line set in conventional supply devices, protective elements have hitherto been provided on the supply device, in particular on the guide hood. They hit the operating arm instead of the guide hood or the supply device when the line set is retracted, so that very severe wear of the guide hood and/or damage to the operating arm caused by the line set hitting should be prevented. In this case, however, very loud frictional and/or impulsive noises occur.
Because of the respective weights of the retraction system and the protective element, the weight of the supply device is often very high, and therefore the weight of the supply device is taken into account in the movement trajectory planning or process trajectory planning. Since the supply device is fixedly mounted on the handling robot arm or the industrial robot, the supply device will be moved by means of the handling robot arm during the work performed by the handling robot arm. This results in a very complex movement path or process planning for operating the robot arm. Also because of the weight of the retraction system or guard, the energy requirements for operating a robot arm or an industrial robot are high.
The flexibility of the boot or the supply device may cause: parts of the supply device undesirably collide with the handling robot arm, in particular when the handling robot arm is accelerated suddenly, which represents a high load for the handling robot arm or the industrial robot. The service life of the handling robot arm may be significantly shortened, for example, as a result. The impact of the protection may cause damage to the handling arm, and the service life of the handling arm is thereby further shortened.
Disclosure of Invention
The object of the invention is to improve such a conventional supply device in such a way that the operating robot arm equipped with it can be operated with high energy efficiency, low expenditure and long-lasting durability. According to the invention, this object is achieved by a supply device having the features of claim 1. In addition, this object is achieved by a stiffening mechanism according to
In order to further develop a supply device of the type mentioned in the preamble of claim 1 in such a way that the operating robot arm equipped therewith can be operated with a high energy efficiency, with little outlay and with a long-lasting duration, according to the invention a stiffening mechanism is provided with a holding device which is arranged in a stationary manner on a flexible guide hood. In addition, according to the invention, at least one stiffening element is provided which is held by means of a holding device and which, in the activated state of the stiffening mechanism, is subjected to stiffening energy, as a result of which the flexible guide boot and thus the line set are stiffened by means of the stiffening element.
In other words, the supply device of the invention has the hardening mechanism, which in turn has the holding device. For example, the holding device and the guide hood can be connected to one another by means of adhesive bonding, welding or the like, so that the stiffening element and the guide hood, which are held or can be held by means of the holding device, cannot move relative to one another.
The hardening mechanism can be brought into the activated state, for example, because of a control signal that can be provided wirelessly and/or wired to the hardening mechanism by a control unit, in particular a control unit of a manipulator or an industrial robot. In a similar manner, the hardening mechanism can be brought into a deactivated state, in which the hardening energy is not supplied to the hardening member, or the hardening energy can be at least partially discharged from the hardening member.
In the rest state, for example in a deactivated state of the stiffening mechanism, the stiffening element may be at least substantially pliable or arranged in a first shape characterizing the rest state of the stiffening mechanism. For example, it is conceivable for the stiffening element to contain or be at least partially made of a shape memory alloy. A member composed of a shape memory alloy (FGL member) has a cold-state shape at an initial temperature, and is reversibly deformable to a hot-state shape different from the cold-state shape by heating to a temperature higher than the initial temperature. That is, a FGL member having a hot shape, for example heated by means of an electric current, may be (in turn) deformed to a cold shape by cooling to at least substantially the initial temperature.
Accordingly, the curing energy can be, for example, electrical energy or voltage, heat, pressure or the like, which is/is to be provided or supplied to the curing member in the activated state of the curing mechanism. The shape memory alloy-containing hardened piece is less susceptible to flexing and/or is arranged or arrangeable in a shape that is characteristic of the activated state than the idle state or the deactivated state, for example, because of hardening electrical energy.
In particular, hardening means that in the hardened state or activated state the respective directions of the actual longitudinal centroid axis (neutral axis) of the hardened piece and the imaginary longitudinal center line coincide more closely with each other than in the rest state or deactivated state. In other words, in the activated state, the hardening energy on the hardening member strives to cause its longitudinal shaped axis to be arranged at least substantially parallel to an imaginary longitudinal central straight line. In other words, the supply device holding the line set can be given rigidity by means of the stiffening mechanism via the stiffening element and via the holding device, so that in the activated state, without the use of a separate retraction system, the required withdrawal length of the line set can be adjusted solely by the movement of the operating robot.
Unlike conventional supply devices, the retraction system and the protective element can be dispensed with by the supply device according to the invention, whereby the supply device is designed to be extremely weight-efficient. The handling robot arm or industrial robot equipped with the supply device can thus work very energy-efficient. The supply device also effectively prevents the supply device, in particular the line set, from undesirably hooking onto adjacent robot cells or objects.
Furthermore, the weight-efficient supply device has very little influence on the process trajectory for operating the robot arm, so that the movement trajectory planning or the process planning can be carried out with little expenditure, since the respective weight of the retraction system or the protective element is not taken into account in the movement trajectory planning.
In addition, the supply device has little impact and/or rubbing effect on the operation mechanical arm; ideally, said impact and/or wear effects are completely avoided. Thereby, the handling robot arm can work particularly durably.
In addition, the impact noise caused by the protective element in conventional supply devices is eliminated, so that the handling robot or the supply device according to the invention can operate with little noise.
In general, when a manipulator arm or an industrial robot equipped with a supply device is operated, a very low cost investment is generated due to the supply device.
The hardening mechanism of the supply device can have a connection, by means of which the at least one hardening element can be supplied with hardening energy. It is particularly preferred that an energy supply device, not shown in detail here, which generates and/or supplies hardening energy can be connected reversibly, without tools, to the hardening element via the connecting element in a manner conducting the hardening energy.
It has proven to be particularly advantageous if the at least one stiffening element is formed as a flexible tube whose tube wall delimits a channel element through which a fluid can flow, the channel element being completely filled with the fluid in the activated state, and the stiffening element being subjected to stiffening energy by applying a stiffening pressure to the fluid in the channel element. In particular, the hose part or the channel part can be fluid-tight at one end, for example with a fluid-tight end, so that the hose part and the fluid-tight end together delimit a pressure chamber. In particular the material of the hose part may comprise silicone, i.e. the hose part may be at least partly made of silicone. The silicone tubing so formed allows for very small bend radii without adversely affecting or limiting the functionality of the supply device. This ensures a very reliable function or a very reliable operation of the supply device or of the handling robot arm or industrial robot equipped with it. Furthermore, silicone hose parts are less susceptible to bending damage, so that the risk of damage to the supply device due to a small bending radius or due to squeezing is low.
The inner circumferential surface of the hose wall or of the hose part delimits a channel part, which is designed as a rigid tube or hose. That is to say that the hose piece has an at least substantially circular cross-section along its longitudinal extension, at least in the activated state. Accordingly, the hose part can be designed in the shape of a circular cylinder. While the hose piece may have a cross section in the rest state different from the circular cylindrical shape, in particular be pliable or particularly bendable.
The fluid may be a liquid (e.g., oil, water, etc.) and/or a gas. This is particularly advantageous since, in industrial plants and in particular processing plants, such process fluids are originally available for operating industrial plants, in particular handling robot arms. It is also advantageous in this case that electrical energy for operating or supplying the hardening element can be dispensed with, so that, as a result, no electrical fields can occur which could undesirably influence adjacent data signal lines and/or sensor signal lines in the line set.
Preferably, the fluid is constituted in the form of air, and the hardening energy is designed as energy that can be used to exert pressure on the air. In other words, the increase in pressure in the air provided in the channel element causes an increase in the hardening energy, so that when the air pressure in the hose element increases, a hardening and/or further hardening of the hardening element and thus of the line set is achieved.
Air as a process fluid is not only very simple to use in industrial installations, but also has only a small, in particular never lasting, damaging effect, for example, on adjacent installation components, processing installation floors, etc., in the event of a leakage failure of the hardening mechanism. Furthermore, unlike liquids, in particular when changing the stiffening element, there is no need to remove, for example empty, the liquid from the stiffening element or even the entire stiffening mechanism. Likewise, the curing element or the curing device can be emptied or filled with fluid when it is put back into use.
In the case of the use of air, in particular compressed air, in the curing member, the curing member and thus the curing means can be pneumatically controlled and/or adjusted. The hardening energy can be supplied steplessly to the hardening member, in particular because it can be adjusted by air pressure, so that a plurality of different respective hardening states can be formed, for example, between "very rigid" and "particularly flexible", in particular according to the requirements, for example, depending on the course of the movement of the manipulator arm. Because of the adjustment, a fixedly set pressure can be provided to the hardening element statically during the entire process run. Alternatively or additionally, because of the adjustment, a plurality of respectively different pressures can be provided to the hardening member dynamically, for example according to the respective process step. The air pressure control or regulation can be incorporated into the control of the manipulator arm or the industrial robot, so that the manipulator arm and the supply device can be mutually jointly controlled, in particular, by means of the same control unit.
In the case of a holding device having at least one stiffening element receptacle arranged parallel to the guide hood, maintenance or repair of the supply device is simple, and the at least one stiffening element can be held on the holding device by means of the stiffening element receptacle. For example, the stiffening element holder can be designed as a further tube part, the inner circumference of which delimits a receiving space, so that the stiffening element can be arranged in the receiving space and can be held therein. In particular, the stiffening element in the form of a hose element can be inserted into the stiffening element receptacle in such a way that the respective longitudinal center axes of the stiffening element receptacle and of the stiffening element coincide. If the stiffener is inserted into the stiffener receptacle, the stiffener is arranged parallel to the guide sleeve and thus parallel to the line set and is held in position.
This is particularly advantageous, since in the case of maintenance and/or repair, the at least one stiffening element can be removed very easily from the stiffening element receptacle, or another stiffening element, for example a new stiffening element, can be inserted very easily into the stiffening element receptacle. The downtime of the supply device and thus of the handling robot arm due to defects can thus be designed to be very short. Accordingly, considerations are made in particular about the concept of new, very advantageous service policies.
It is conceivable that the hose part and the holding device, in particular the stiffening part receptacle, are each formed by an elongate, cut-to-length element (customarily known in spoken language as "sold in meters"). This makes it possible to produce a large number of different supply device designs with little outlay. Since the length and/or diameter of the supply device, in particular of the line set or of the individual lines of the line set, can be adjusted very simply by selecting a correspondingly designed, length-adjustable element.
The supply device particularly preferably has a plurality of hardening elements and a plurality of corresponding hardening element receptacles/supports, so that a very reliable hardening of the line set is achieved. The number of the hardening parts or hardening part receptacles to be used in the supply device can be correlated in particular with the radial diameter of the line set or the radial diameter of the guide hood. For example, for small guide hood diameters, three stiffeners arranged parallel to the line set may suffice, while for larger guide hood diameters four, five, six, seven or more stiffeners and a correspondingly large number of stiffener receptacles may be used.
When the holder and the guide hood are formed integrally with each other, they can be produced in a simple manner. As already described, the guide hood and the holding device can each comprise at least one hose piece, wherein the two hose pieces can be co-extruded with one another, for example. This ensures very reliably that the holding device and the guide hood are arranged in close proximity to one another in terms of position.
It has also proved to be advantageous if the holding device and the guide hood, respectively, are at least partially made of fabric. In other words, the material of the holding device and/or the material of the guide hood may comprise and/or be at least partially made of a fabric, respectively. The fabric may have a knit, a woven fabric, a mesh (e.g., a knitted fabric), and/or a web fabric depending on the type of fabric.
In particular, the holding device and the guide hood can be produced in one piece with each other in a simple and/or low-cost manner, since the guide hood and the holding device or the stiffening element receptacle are produced from a textile fabric by means of hemming stitching, quilting or the like. In addition, the textile holding device and the textile guide hood are each designed in particular to be bendable or pliable, so that the textile holding device and the textile guide hood can each be placed in particular in a tight manner against the line set. The fabric also has a very thin material thickness, so that the supply device can be manufactured in a very compact and/or space-efficient manner using the holding device made of fabric and the guide hood made of fabric.
In the supply device, it can be provided that the curing device has a flexible protective cover which is formed separately from the guide cover and which, in the protective position, encloses the line set, the holding device, the guide cover and the at least one curing element together. Particularly preferably, the protective cover can be made at least partially of fabric. The protective cap forms a hard-and/or soft-tubular protective chamber in the protective position, through which the element provided in the protective cap extends, so that the protective cap separates the supply device element provided in the protective chamber from the environment surrounding the supply device. The supply device can slide with little resistance on the surface of the handling robot arm by means of the protective cover, so that rubbing and further damage of the handling robot arm and/or the supply device is very effectively avoided.
A further advantage is that the protective cover exerts a very good protective effect on the line set by cooperating with the retaining means provided therein, since the deformation zone is created by the protective cover spaced from the line set by the retaining means. When the protective cover strikes against an object, in particular during operation of the manipulator arm or the industrial robot, which is correspondingly impacted, the protective cover can be deformed in the deformation zone without damage to the line assembly, so that the line assembly is well protected against direct impact.
Furthermore, the guide or protective cover or the guide and protective cover can be adapted to various requirements, such as heat, moisture, dry, cold, chemical-containing environments, etc., by the design of the respective fabric (e.g. type and/or material of raw material, yarn and fiber, type of construction and perhaps the reprocessing of the fabric, such as coating, exhaust dyeing, etc.). The supply device can thus be used very flexibly and can be adapted to different requirements with very low outlay.
In a development of the invention, the protective hood can have a closure unit which can be reversibly adjusted between an open position and a protective position, wherein in the open position the protective hood is opened in the direction of its longitudinal extent; in the protective position, the protective hood is closed in the longitudinal extension thereof. For this purpose, the closure unit can have, for example, at least one adhesive button which is simple to handle and is error-free and which can advantageously be applied to the protective cover made of fabric, for example can be sewn together with the protective cover body during the production of the protective cover.
In this way, it is possible to replace the worn-out protective cap directly, in particular simply or with little outlay, as required, if the protective cap is damaged and/or worn out or if the supply device is to be adapted to changing requirements. Whereby the supply device can operate very efficiently.
Furthermore, the replacement (i.e. the handling) of the protective cap takes a short time, since the protective cap can be brought into the open position without, for this purpose, having to disengage one end of the supply device, for example, from the end effector. The time saving in handling the protective cover results in little unproductive downtime of the supply device and thus of the handling robot arm or industrial robot.
In order to design the movement path plan and/or the process movement plan of the manipulator arm or of the industrial robot in a simple and cost-effective manner, the first end of the curing means can be formed by a connecting unit, by means of which the curing means can be fixed or fixed on the manipulator arm remote from the end effector. That is, the hardening mechanism can be fixed, for example, at its base or first axis of motion, for example, in a third axis of motion region or another axis of motion region of the handling robot arm or of the industrial robot by means of the connecting unit.
In particular, the connection unit may have a ball joint to allow relative movement between the stiffening mechanism head and the manipulator arm. This results in a clearly advantageous flexibility or mobility of the supply device in connection with the handling of the robot arm. Thereby it is ensured that the first end of the hardening mechanism follows the movement of the manipulator arm very flexibly. Disadvantageous clamping of the feeding device is effectively prevented and the movement of the feeding device itself, for example caused by objects moving or conveyed through the line set, is not transmitted to the handling robot via the rigid connection. Accordingly, the manipulator arm can be moved or controlled very precisely, which is reflected in a very simple movement path planning.
Provision can be made for the connecting piece to be integrated into the connecting unit. For example, the connecting element can be a threaded bore into which the supply line of the energy supply device can be inserted, for example screwed, by means of a screw connection. The threaded hole may be integrally formed in the body of the connection unit, e.g. drilled therein. Thus, no structural space has to be provided for a separately formed connecting piece which can supply hardening energy to the supply device. The supply device is therefore to be produced very compactly and/or space-efficiently.
The connecting unit may have a distribution unit which connects the at least one hardening element to the connecting element in a conductive hardening energy manner. In particular, when a plurality of curing members or a plurality of curing member receptacles are used, the individual curing members can be supplied or supplied with the curing energy via a common connecting element.
In a further development, the stiffening means can comprise a reversibly and nondestructively separable fastening means, by means of which the connecting unit and the protective covering can be detachably fastened together, and a first fastening part of the fastening means is arranged on the connecting unit and a second fastening part of the fastening means, which corresponds to the first fastening part, is arranged on the protective covering. Thus, it is advantageously possible to ensure that: the protective cap is held in a fixed position on the connection unit without sliding along the longitudinal center axis of the protective cap or of the line set, for example, in order to prevent the protective effect of the protective cap from being weaker than when the protective cap is held in place correctly.
The fastening device can have, for example, a further adhesive button, the first adhesive button element (for example a felt strip) of which can advantageously be attached to the textile protective cover, for example, can be sewn to the protective cover body during production. In this case, a further adhesive fastening element (e.g. a hook tape) is correspondingly arranged on the connection unit, for example, adhesively bonded thereto.
The second end of the curing means can be formed by a second connecting unit, by means of which the curing means can be fastened to the handling robot arm close to the end effector. It is thereby ensured that the second end of the stiffening mechanism follows the movement of the manipulator arm more flexibly. In addition, disadvantageous clamping of the supply device is further prevented, and the self-movement of the supply device is not transmitted to the handling robot, in particular the end effector, via a rigid connection. Therefore, with a manipulator arm or an industrial robot equipped with a supply device, a reproducible manipulator arm movement path and/or process movement can be achieved very reliably.
In particular, it is preferred that the first connecting means and the second connecting means are each formed at least substantially identically as identical components or structures. This results in a very efficient and inexpensive production of the supply device, since the first and second connection units can be produced according to a common construction plan. If the connecting element is integrated into the connecting unit, the integral formation or drilling of the threaded bore can be dispensed with simply during the production of the end-effector-side connecting unit. Alternatively, a closure element can be provided for sealing the threaded bore on the end effector side, whereby the threaded bore can be closed in a fluid-tight manner by means of a threaded connection.
The curing means of the supply device may have a guide means with at least one guide, whereby the line set, the holding device, the guide hood and the at least one curing member may be guided together on the handling robot. The guide can be fixed in position on the handling robot, for example screwed thereto. In addition, the guide can be designed in particular in the form of a circular cylinder, so that the line set, the holding device, the guide hood and/or the at least one stiffening element can extend through the guide. In this case, the longitudinal center axis of the guide and the longitudinal center axis common to the line set, the holding device, the boot and/or the at least one stiffener can coincide with one another. The inner circumferential surface of the guide element can be designed, for example, to be smooth, so that the supply device part extending through the guide element can slide along it with little resistance.
In other words, the guide means or the guide element allows a movement, for example a displacement, of the feeder part enclosed by the guide element along its longitudinal extension. While the guide means or the guide element prevents the parts of the supply device enclosed by the guide element from shifting radially, for example, along the supply device.
Furthermore, the protective cap arranged in the protective position can be guided at the handling robot by means of the guide mechanism, wherein the protective cap advantageously forms a supply device sliding surface corresponding to the inner circumferential surface of the guide, so that supply device components enclosed by the protective cap can slide along the inner circumferential surface of the guide with less resistance by the protective cap.
In order to further take into account the concept of a new advantageous service strategy, the curing means can have a sensor device with at least one sensor element, by means of which the evaluation unit can be supplied with at least one sensor signal which characterizes the state of the curing means. The at least one sensor element may in particular each have at least one pressure sensor, temperature sensor, strain gauge, resistance, optical sensor, capacitive sensor, etc. In this case, it is particularly conceivable for the sensor element to be integrated into the material of the supply device. When the protective cover is made of or comprises a textile, the sensor element may comprise a sensor processed into the textile. In this case, in particular, sensor fibers (sensors which are formed very flat and are possibly arranged between two textile layers of the textile) or the like which are woven into the textile can be considered. In other words, the fabric that may be used to at least partially make the protective cover may be a so-called "smart fabric".
The temperature, pressure, degree of wear, etc. of the supply device can be detected, in particular, by means of at least one sensor element of the sensor device. It is particularly interesting to detect the degree of wear of the parts of the supply device, in particular of the protective cover, which are subject to severe wear. The sensor signals which characterize the respective state of the stiffening mechanism can be provided, for example transmitted, to the sensor device wirelessly, for example via WLAN (wireless local area network), bluetooth (data transmission by means of radio technology), NFC (near field communication by means of electromagnetic induction), etc., and/or wired.
Thus, considerations regarding "industrial 4.0" are especially to be considered. The data and/or parameters of the supply device can be provided in a very simple manner to a user operating the robot arm or the industrial robot. In other words, the monitoring of the process data by the user is ensured with little expenditure. It is particularly advantageous that wear phenomena, functional faults and/or defects encountered can thereby be provided (e.g. displayed) to the user. This allows for a very timely ordering of spare parts, especially also before the operation of the robot arm or the supply device is stopped due to a malfunction or defect. This further results in a very short repair time.
The invention also relates to a hardening mechanism for a supply device according to the invention for a manipulator arm, in particular an industrial robot, having at least one joint, having a flexible line set by means of which at least one process medium can be supplied to its end-effector at least substantially along the manipulator arm, and having a flexible guide hood surrounding the line set.
The hardening mechanism according to the invention is based on the idea that existing handling robots or industrial robots or their respective supply devices are equipped with the hardening mechanism. The manipulator arm or industrial robot equipped with the stiffening mechanism can thus be operated with high energy efficiency, with little expenditure and/or with long-lasting endurance. The expenditure to be invested for this purpose is low, since no new handling robot arm/industrial robot is purchased, but rather only a hardening mechanism has to be provided in order to obtain the advantages described in connection with the supply device according to the invention.
The design of the stiffening means, in particular of the coupling unit, can be designed such that the stiffening means to be produced can be produced according to the size and/or weight class of the robot or manipulator arm to be equipped with the stiffening means. The stiffening means can be constructed in modular form, so that, for example, different numbers of stiffening elements are used depending on the weight class.
Drawings
Further advantages, features and details of the invention emerge from the following description of a preferred embodiment and from the figures of the drawing. The features and feature combinations mentioned in the description and those mentioned in the following description of the figures and/or shown in the figures individually can be used not only in the respectively specified combination but also in other combinations or individually without departing from the scope of the invention, wherein:
Figure 1 shows a schematic top view of a supply device for operating a robot arm;
FIG. 2 shows a schematic side view of a supply device for operating a robotic arm;
FIG. 3 shows a perspective view of the holding device and the stiffening element;
FIG. 4 shows a schematic view of a stiffener;
FIG. 5 shows a schematic view of the rigidizer in an activated state;
fig. 6 shows a perspective view of the protective cover;
FIG. 7 shows a perspective view of the assembled connection unit;
fig. 8 shows the individual elements of the connection unit, parts of which are shown in perspective and in cross-section;
fig. 9 shows a perspective view of an industrial robot equipped with a supply device.
In the figures, identical or functionally identical components are provided with the same reference symbols.
Detailed Description
Fig. 1 shows a supply device 1 for operating a
In order to design the handling
Fig. 3 shows the holding device 15 and the stiffening element 16 in a perspective representation. The holding device 15 has in this case five stiffening element receptacles 17 arranged along the outer circumferential surface 18 of the guide hood 19. In this case, the longitudinal center axis 20 of the guide hood 19 and the respective longitudinal center axis 21 of the respective stiffener receptacle 17 extend parallel to one another. Furthermore, five stiffener receptacles 17 are at least substantially evenly distributed along the outer circumferential surface 18 at the outer circumferential surface 18.
In the present example, the guide hood 19 and the stiffening element receptacle 17 are formed integrally with one another, so that the stiffening element receptacle 17 and the guide hood 19 are arranged or held against one another in a rotationally fixed manner. It is particularly preferred that the stiffener receptacle 17 and the guide hood 19 are made of the same fabric. In other words, the guide hood 19 and the stiffening element receptacle 17 are formed integrally with one another.
The inner circumferential surface of the guide cover 19 forms an accommodation chamber through which the
Although only one stiffening member 16 is shown in fig. 3, it should be understood that five stiffening members 16 are used in this example. It is also easily conceivable that the number of stiffeners 16 to be used is defined by a natural integer other than five. For example, one curing member 16 or three, four, six, seven, eight, etc. curing members 16 may be employed in the supply device 1 or the
Each of the curing members 16 can be inserted or plugged into a respective receiving chamber defined by the inner circumferential surface of each of the curing member receptacles 17. In this case, the inner circumferential surface of each hardening member receptacle 17 and the respective outer circumferential surface of the hardening member 16 are desirably in close proximity to each other. As a result, each hardening element 16 is held in a stationary manner in the respective hardening element receptacle 17, such that a longitudinal center axis 22 of the hardening element 16 coincides with a longitudinal center axis 21 of the respective hardening element receptacle 17. Accordingly, the longitudinal center axis 22 of the stiffening element 16 is arranged parallel to the longitudinal center axis 20 of the guide hood 19 as soon as the respective stiffening element 16 is arranged in the respective stiffening element receptacle 17. The stiffening element 16 is designed here as a hose element 23 which is made completely or partially of a synthetic polymer, i.e. silicone.
Fig. 4 shows the stiffening part 16 or the hose part 23 in a schematic view. The hose wall 24 of the hose member 23 forms a channel member 25, which can be flowed through by a fluid and/or can be filled with a fluid. Fig. 4 shows the hose part 23 or the stiffening element 16 in the deactivated state of the stiffening means 14, in which the stiffening element 16 or the hose part 23 is arranged according to a first shape which characterizes the deactivated state of the stiffening means 14. For example, the stiffeners 16 may be flexible or particularly bendable, so that the stiffeners 16 arranged in the respective stiffener receptacles 17 follow the shape or course of the
Fig. 5, in turn, schematically shows the stiffening element 16 in an activated state of the
It is particularly preferred that the hardening energy acts on the hardening element 16 by means of compressed air arranged in the channel element 25, so that the hardening element 16 is or will be adjusted by said compressed air to a condition which is characteristic of the activated state of the hardening
Fig. 6 shows a perspective view of the
The inner
As can be seen from an overview of fig. 1, 2 and 6, the outer
The supply device 1 has a
When a part of the line set 13 is moved into the
In order to hold the
A connecting
The connecting
Fig. 8 shows the individual elements of the
The
The sealing
The sealing
By means of the respective stiffening element-
In order to achieve a very secure seating and/or to achieve a high sealing action between the
The
Unlike the
Referring again to fig. 1 and 2, a
Fig. 9 shows an
The curing
- 上一篇:一种医用注射器针头装配设备
- 下一篇:用于监测机械手的供应系统的方法