EP2941577A1

EP2941577A1 - Torque transmission device, actuator, and robot

Info

Publication number: EP2941577A1
Application number: EP14700859.3A
Authority: EP
Inventors: Georg Bachmaier; Marco CYRIACKS; Andreas GÖDECKE; Wolfgang Zöls
Original assignee: Siemens AG
Current assignee: Siemens AG
Priority date: 2013-03-15
Filing date: 2014-01-15
Publication date: 2015-11-11
Also published as: JP2016510864A; JP6395733B2; CN105051407A; CN105051407B; WO2014139702A1; US9841061B2; DE102013204588A1; US20160025150A1; KR20150132509A; KR102151686B1

Abstract

The invention relates to a torque transmission device (3), the stiffness of which can be variably adjusted, to an actuator (1) having such a torque transmission device (3), and to a robot (26). The torque transmission device (3) according to the invention has an inner ring (5), an outer ring (4) that is arranged as to be rotatable to the inner ring (5) from a neutral position (25) in a positive rotational direction (17) or a negative rotational direction (18) to the inner ring, at least one pair of receiving bellows (9, 10), comprising a positive receiving bellows (9) and a negative receiving bellows (10), at least one gas pressure spring (13), and an adjusting unit connected to the at least one gas pressure spring (13). The receiving bellows (9, 10) are arranged between the outer ring (4) and the inner ring (5) in such a way that when the inner ring (5) is rotated in the positive rotational direction (17), the positive receiving bellows (9) can be compressed, and when the inner ring (5) is rotated in the negative rotational direction (18), the negative receiving bellows (10) can be compressed. In addition, the receiving bellows (9, 10) are connected to the at least one gas pressure spring (13) in a fluidically conductive manner.

Description

description

The torque transfer device, actuator, robot The present invention relates to a Drehmomentübertra ^¬ constriction device with a variably adjustable stiffness, an actuator with the torque transfer device and a robot. Robots are increasingly used in direct contact with humans, whether in patient care or in industry. Common to these applications is the increased demand for robot safety. Thus, it must be ruled out that a person will sustain an injury if he is accidentally hit by a moving robot part. Also should in case of errors, be mainly in the field of wearable robotics, ruled that a human joint with excessive forces beauf ^¬ will beat them and thereby contributes injuries. A well-known solution for this is the use of actuators with variable rigidity.

To achieve high positioning accuracy, high mechanical stiffness is desired. A robot moves terteil but quickly, or to be mitvollzogen the movement of a menschli ^¬ chen joint, to achieve high safety a compliant mechanism and consequently a low rigidity is desirable. For the realization of actuators with variable stiffness (short VSA for variable stiffness actuator) two approaches are known.

On the one hand, actuators with high rigidity become one

Force or torque sensor added. By means of a geeigne ^¬ th controller, this allows to simulate a stiffness which is lower than the mechanical. The force sensor measures the force applied to the actuator or the torque lying on ^¬. Depending on the moment the Auslen ^¬ effect is set so that a mechanical spring simulated becomes. The deflection is set proportionally to the applied torque, the proportionality factor corresponding to the virtual spring stiffness. Disadvantage of the approach is the lack of intrinsic safety, as in case of failure, for example, in a failure of the force sensor or the control, the intrinsic, high stiffness of the actuator comes into play.

The second approach is the construction of actuators whose rigidity is made purely mechanically variable. In this case lever systems with a variable force tap are used. An actuator is to be connected, for example via an additional mechanical element, which contains as a central Me ^¬ a spring mechanism. In order to vary the stiffness of the spring, the lever arm of the force tap is adjustable, for example via an electric motor. A disadvantage of this approach is the relatively large space requirement of the Konstrukti ^¬ on.

The present invention has for its object to overcome these disadvantages and to provide an improved actuator with variable stiffness.

This object is achieved with a torque transmission ^¬ device according to claim 1 and an actuator according to claim 10 and a robot according to claim 11. Advantageous developments of the invention are set forth in the dependent claims and described in the description.

The torque transmission device according to the invention with an inner ring, a rotatable from a neutral position in a positive direction of rotation or negative direction to the inner ring outer ring, at least one pair of receiving bellows, comprising a positive receiving bellows and a negative receiving bellows, at least one gas spring and a ner with the at least one Provided gas spring connected adjustment. The Aufnahmebälge are disposed between the Au ^¬ ßenring and the inner ring in such a way that the Positivaufnahmebalg during a rotation of the inner ring in positive direction of rotation is compressible and the negative receiving bellows is compressible in a rotation of the inner ring in the negative direction of rotation. The receiving bellows are also fluidly connected to the at least one gas spring. As fluid is preferably a hydraulic fluid ^¬ set.

The torque transmission device according to the invention advantageously has very compact dimensions and, with the almost incompressible hydraulic fluid, is capable of very high

Represent stiffnesses. The hydraulic power transmission advantageously also has a high internal damping, the egg ^¬ gene vibrations of the system are greatly over-damped and occur only at high frequencies. Thus, the frequency response of the system up to high frequencies is linear, which brings a good rule ^¬ availability of the torque transmission device with it

In an advantageous embodiment of the torque transmission device according to the invention, the at least one gas spring on a hermetically sealed gas pressure chamber and a protruding into the gas pressure chamber transfer bellows and projecting into the gas pressure chamber Verstellbalg. The receiving bellows are fluid-conductively connected to the transfer bellows and the adjusting unit is fluid-conductively connected to the adjustment bellows.

This is realized in a simple manner an adjustable, compact and durable gas spring. In a further advantageous embodiment of the torque transmission device according to the invention, the adjustment unit comprises a reservoir and a pump. The pump is in particular a piezo pump. In addition, the piezo pumps can be equipped with a non-return valve, which is self-opening in the event of a fault (normally open).

With the reservoir and the pump, a hydraulic adjusting unit is provided with simple and inexpensive components. Semi asked. The piezo pump advantageously takes up a small space and works effectively. With the check valve, the rigidity of the torque transmitting device in case of failure, for example, upon failure of the power supply or the control signal automatically reduced to the minimum, the safe state of the system is ^¬ represents: The system is therefore intrinsically safe.

In a further advantageous embodiment of the torque transmission device according to the invention, the torque transmission device has two gas pressure springs connected to the adjustment unit. It is at least fluidly connected to a Po ^¬ sitivaufnahmebalg with one of the two gas-pressure springs and the at least one Negativaufnahmebalg with the other of the two gas compression springs.

This is the receiving bellows for both the Kompressionsbe ^¬ movement and for the expansion movement in each case a Gasdruckfe ^¬ ready. It can be advantageous to influence both pressure phases and tension phases of the bellows.

In a further advantageous embodiment of the torque transmission device according to the invention the adjusting unit per gas spring comprises a separate pump.

The gas springs can thus be set independently. The rigidity of the torque transmission device is thus advantageously different depending on the direction of ^¬ interpretable and variable. The pressure phases can be interpreted differently than the tension phases.

In a further advantageous embodiment of the torque transmission device according to the invention, the torque transmission device comprises two pairs of intake bellows.

Thus, the introduction of force can be better distributed. The individual bellows are thus lower loads exposed. In addition, the leadership of the inner ring is improved without additional ^¬ Liche supporting elements.

In a further advantageous embodiment of the torque transmission device according to the invention, at least one of the bellows is a metal bellows.

Metal bellows are extremely robust, even at high temperatures and under the influence of aggressive environmental conditions. This gives the torque transmission device longevity and safety.

In a further advantageous embodiment of the torque transmission device according to the invention, the torque transmission device essentially has the shape of a cylinder with a circular base area.

Thus, the torque transmission device is provided with a shape that can be well attached to the shape of a conventional servo motor. The servomotor and the torque ^¬ transmission device take together only little more space than the servo motor alone.

Thus, the torque transmission device according to the invention is preferably integrated in all its embodiments in an actuator which has a servo motor in addition to the torque transmission device. The servomotor comprises a rotor and a stator. The stator of the servomotor according to the invention with the outer ring or the inner ring of the torque transmitting device rotatably connected.

This advantageously provides an actuator with variable rigidity. The advantages of the torque transmission device according to the invention are attributable to the actuator as an assembly.

The actuator according to the invention is preferably tegriert in a robot in ^¬. The actuator is with a mechanical unit of the Robot force transmitting or torque transmis ^¬ ing connected.

The mechanical unit of the robot can be operated with different stiffnesses due to the actuator according to the invention. Thus, the robot offers a high level of security, especially in direct contact with people.

Embodiments of the invention will be explained in more detail with reference to the drawings and the description below. Show it :

FIG. 1 shows a robot according to the invention; FIG. 2 shows an actuator according to the invention; and

Figures 3 to 5 a torque transmission device of the actuator according to the invention in various embodiments.

In the figure 1 an inventive robot 26 is exemplified. The robot 26 according to the invention has an actuator 1 which is connected with a mechanism unit 27 frictionally Bezie ^¬ hung as to transmit torque. By an operation of the actuator 1, the mechanical unit 27 is changeable in its Po ^¬ position. The mechanical unit 27 is designed in such a way to convert the movement generated by the actuator 1. The mechanical unit 27 can perform, for example, a rotational movement, a translatory movement or a combination of two movements.

In FIG. 2, the actuator 1 according to the invention is sketched by way of example. The actuator 1 has a servomotor 2 and a torque transmission device 3. The servomotor 2 comprises a rotor 21 and a stator 22. The rotor 21 is mounted rotatably on the stator 22 on a rotation axis 23. The stator 22 may be disposed around the rotor 21, in this way it is shown in FIG. The rotor 21 may also be arranged around the stator 22 around. For the purposes of the present invention, the stator 22 is the supporting element and the rotor 21 is the movable element. The stator 22 is rotatably connected according to the invention with the torque transmitting device 3.

According to the invention, the torque transmission device 3 comprises an inner ring 5 and an outer ring 4 arranged around the inner ring 4. The outer ring 4 and the inner ring 5 are arranged concentrically to the axis of rotation 23. The outer ring 4 is rotatable relative to the inner ring 5 on the axis of rotation 23 by a certain angle of rotation. In the example shown in Figure 1, the inner ring 5 of the Drehmomentübertra ^¬ constriction device 3 is firmly clamped and the stator 22 of the servomotor 2 is attached to transmit torque to the outer race 4 of the constriction device Drehmomentübertra ^¬. 3 A torque decrease 20 can thus take place on the rotor 21. It is also possible that the outer ring 4 of the torque transmitting device 3 is firmly clamped and the stator 22 of the servo motor 2 with the inner ring 5 of the torque transmission ^¬ device 3 is rotatably connected.

The torque transmission device 3 is sketched in FIGS. 2 to 4 by way of example in various design variants. The Drehmomentübertragungsvor ^¬ direction 3 according to the invention comprises in addition to the outer ring 4 and the inner ring 5 at least a pair of receiving bellows 9, 10, a gas ^¬ pressure spring 13, an adjustment and fluid lines 16. In Figures 2 to 4, the inner ring 5 of the torque transmission device according to the invention 3 each shown in a neutral position 25. The inner ring 5 can ^rotate against the outer ring 4 in a positive direction of rotation 17 or in a negative direction of rotation 18.

The outer ring 4 has at least two formations 24. Each formation 24 protrudes into a recess 7 of the inner ring 5. The formations 24 are located at each At least one impetus 6. At each recess 7, the inner ring 5 on a the abutment 6 opposite to a region 8 on. Between the support 8 of the inner ring 5 and the abutment 6 of the outer ring 4 each one of the receiving bellows 9, 10 is arranged. The receiving bellows 9, 10 are each attached at least to the support 8. For the purposes of the present ^¬ the invention may also be a hydraulic cylinder or the like a bellows, in particular the bellows of metal. The at least one pair Aufnahmebälge 9, 10 comprises a Po ^¬ sitivaufnahmebalg 9 and a Negativaufnahmebalg 10. Sin ^¬ ne of the present invention, the Positivaufnahmebalg 9 being arranged in such a way that it at a change of In ^¬ nenrings 5 out of the neutral position 25 in positive direction of rotation 17 is compressed. Of the Negativaufnahmebalg 10 it is arranged according to the invention ^¬ in such a way that it is compressed at a Än ^¬ alteration of the inner ring 5 from the neutral position 25 in the negative direction 18th The Aufnahmebälge 9, 10 are according to the invention with a fluid, in particular with a hydraulic fluid, such as ^¬ example, silicone oil or glycerine. About the fluid lines 16, the receiving bellows 9, 10 with the at least one gas ^¬ pressure spring 13 fluidly connected.

The at least one gas spring 13 according to the invention comprises egg ^¬ NEN hermetically sealed, filled with a fluid gas pressure chamber 28th The fluid is in particular a gas and can be under an overpressure of 2 bar to 10 bar. In the gas pressure chamber 28 projecting two in particular opposite ^¬ positioned bellows 14, 15 are arranged. A Übertra ^¬ gungsbalg 14 and a Verstellbalg 15. The Übertragungsbalg 14 is fluidically connected via fluid lines 16 with at least one Aufnahmebalg 9, 10th The Verstellbalg 15 is via fluid conduits 16 fluidly with the adjustment ver ^¬ prevented. The adjusting unit according to the invention comprises at least one Pum ^¬ pe 12, in particular a piezo pump 12 and a reservoir 11 in which a fluid, in particular a hydraulic fluid is vorhaltbar on.

During a rotational movement of the inner ring 5 relative to the outer ring 4 in the positive direction of rotation 17, the pressure in the positive receiving bellows 9 is increased and a hydraulic fluid located in the positive receiving bellows 9 is passed through the fluid line 16 into the transfer bellows 14 of the at least one gas spring 13. The transfer bellows 14 strives to expan ^¬ NEN. The torque required for the rotational movement in the positive direction of rotation 17 is according to the invention by the pressure in the gas pressure chamber 28 variably adjustable.

During a rotational movement of the inner ring 5 relative to the outer ring 4 in the negative direction of rotation 18, the pressure in the negative receiving bellows 10 is increased and a hydraulic fluid located in the negative receiving bellows 10 is passed through the fluid line 16 into the transfer bellows 14 of the at least one gas spring 13. The transfer bellows 14 strives to expan ^¬ NEN. The torque required for the rotational movement in the negative direction of rotation 18 is variably adjustable according to the invention by the pressure in the gas pressure chamber 28.

The pressure in the gas pressure chamber 28 of the gas spring 13 acts on the transfer bellows 14 and the adjustment bellows 15. The verse ^¬ bellows 15 is designed in such a way that the gas volume in the gas spring 13 is compressible. By means of the pump 12 of the adjusting unit is a fluid, especially a Hyd ^¬ raulikflüssigkeit, zoom in from the reservoir 11 into the Verstellbalg 15 and 15 from the Verstellbalg

pump out. In this way, the rigidity of the gas spring 13 can be adjusted in a wide range.

If the adjusting bellows 15 is completely emptied, then the gas in the gas pressure chamber 28 can have a high volume at a low level Take pressure. The Übertragungsbalg 14 can thus be extended, without the gas pressure in the pressure chamber 28 increases significantly, that is, the gas spring 13 has a low Steifig ^¬ speed in this setting.

If the adjustment bellows 15, however, is filled to its end position, it is shown in FIGS. 3 to 5, so that a slight expansion of the transfer bellows 15 already results in a high pressure increase in the gas pressure chamber 28 and thus a high counterforce on the transfer bellows. The gas pressure ^¬ spring 13 has a high rigidity in this setting.

Since the transfer bellows 14 transmits the pressure of the gas pressure chamber 28 of the gas spring 13 to the receiving bellows 9, 10, and there a moment is built, thus translates the variable ^¬ able stiffness of the gas spring 13 directly into a variable torsion spring characteristic. Thus, according to the invention, the volume of the adjusting bellows 15 can be varied by means of the pump 12, and as a result the torsional rigidity of the torque transmission device 3 according to the invention can be adjusted. This is done within a few seconds or fractions of a second, depending on the design of the power of the pump 12th

The adjustment unit is controlled or regulated by a control unit, not shown here in detail, to which the adjustment unit is connected. In addition, sensors may be arranged in the torque transmission device 3, which detect conditions such as the pressure in at least one of the bellows.

The torque transmission device 3 may additionally

Have support elements. For example, rolling elements between the outer ring 4 and the inner ring 4 may be arranged. The exemplary embodiment of the torque transmission device 3 ^{according to} the invention sketched in FIG. 3 has a single pair of receiving bellows 9, 10 and a Zige gas spring 13. The adjustment unit has a single pump 12.

The receiving bellows 9, 19 are here each attached to the support 8 and are at the abutment 6 loose. The bellows

9, 10 each have a stop 19, which prevents a Ausdeh ^¬ tion of the receiving bellows 9, 10 beyond the level available during the neutral position 25 of the inner ring 5 addition. In the neutral position 25, both receiving bellows 9, 10 have their maximum volume. In a rotation of the inner ring 5 relative to the outer ring 4 from the neutral position 25 out of the receiving bellows 9, 10 is compressed, the other of the receiving bellows

10, 9 maintains its volume. In this compression, the above-described damping by the gas pressure spring 13 takes place. In the opposite direction from the rotation in the neutral position 25, the torque transmission device 3 has no rigidity. A torque can act freely until the neutral position is reached again. The exemplary embodiment of the torque transmission device 3 according to the invention sketched in FIG. 4 has two gas pressure springs 13 in relation to the variant shown in FIG. Each of the gas pressure springs is fluid-conductively connected to one of the receiving bellows 9, 10 of the only pair of receiving bellows here via fluid lines 16.

With two gas springs 13, the number of gas ^¬ pressure springs 13 corresponds to the number of possible directions of rotation 17, 18. The two gas springs 13 are separately controllable. The adjusting unit comprises two pumps 12 for this purpose. Thus, the receiving bellows 9, 10 can each be influenced not only in a pressure phase but also in a pulling phase. While one of the gas pressure springs 13 accompanies the pressure phase of one receiving bellows 9, 10, at the same time the other of the gas compression springs 13 influences the tension phase of the other receiving bellows 10, 9.

The receiving bellows 9, 10 have no stop 19 here. The receiving bellows 9, 10 are each on both the support. 8 the inner ring 5 and attached to the abutment 6 of the outer ring 4. The positive receiving bellows 9 has its largest Volu ^¬ men in the position of the inner ring 5, in which the Negativauf ^¬ bellows 10 has its smallest volume and vice versa. In particular, both pumps 12 are operable in parallel in such a way that the gas pressure springs 13 each have the same internal rigidity.

In addition to the embodiment shown in the Figure 4 embodiment, the example outlined in Figure 5 exporting ^¬ approximately variant of the inventive torque transmission ^¬ device 3 on two pair of Aufnahmebälge 9, 10th In this case, the two positive receiving bellows 9 are connected in parallel and the two negative receiving bellows 10 are connected in parallel.

Although the invention in detail by the preferred embodiment has been illustrated and described in detail, the invention is not limited ^¬ by the disclosed examples and other variations can be derived therefrom by the skilled artisan without departing from the scope of the invention.

Claims

claims

1. torque transmission device (3) with

an inner ring (5),

one of a neutral position (25) in a positive direction of rotation ^¬ (17) or negative direction of rotation (18) rotatably to the inner ring (5) arranged outer ring (4),

at least one pair of receiving bellows (9, 10), comprising a positive receiving bellows (9) and a negative receiving bellows (10),

at least one gas spring (13) and

an adjusting unit connected to the at least one gas pressure spring (13),

wherein the receiving bellows (9, 10) between the outer ring (4) and the inner ring (5) are arranged in such a way that the positive receiving bellows (9) upon rotation of the inner ring (5) in the positive direction of rotation (17) is compressible and the negative receiving bellows (10) in a negative rotation direction (18) is compressible upon rotation of the inner ring (5) and wherein the receiving bellows (9, 10) with the at least one Gasdruckfe ^¬ (13) are fluidly connected.

2. A torque transmission device (3) according to claim 1, wherein the at least one gas pressure spring (13) has a hermetically sealed gas pressure chamber (28) and a transmission bellows (14) projecting into the gas pressure chamber (28) and an adjusting bellows (15) projecting into the gas pressure chamber (28) ), wherein the recording ^¬ bellows (9, 10) with the Übertragungsbalg (14) are connected in fluid-conducting ver ^¬ and the adjustment with the Verstellbalg (15) is fluidly connected.

3. A torque transmitting device (3) according to claim 2, wherein the adjusting unit comprises a reservoir (11) and a pump (12).

4. torque transmission device (3) according to claim 3, wherein the pump (12) is a piezo pump (12).

5. torque transmission device (3) according to one of claims 1 to 4, wherein the torque transmission device (3) has two associated with the adjusting gas pressure springs (13), wherein the at least one positive receiving bellows (9) with one of the two gas springs (13) and the at least a negative receiving bellows (10) with the other of the two gas ^¬ compression springs (13) is fluidly connected.

6. torque transmission device (3) according to claim 5, wherein the adjusting unit per gas spring (13) has a separate

Pump (12).

7. A torque transmission device (3) according to any one of claims 1 to 6, wherein the torque transmission device (3) has two pairs of receiving bellows (9, 10).

8. torque transmission device (3) according to one of claims 1 to 7, wherein the torque transmission device (3) has substantially the shape of a cylinder with a circular base.

9. torque transmission device (3) according to one of claims 1 to 8, wherein at least one of the bellows (9, 10, 14, 15) is a metal bellows.

10. Actuator (1) with a torque transmission device (3) according to one of the preceding claims and a rotor (21) and a stator (22) having servomotor (2), wherein the stator (22) of the servomotor (2) with the outer ring (4) or the inner ring (5) of the torque transmission device (3) is rotatably connected.

11. Robot (26) with an actuator (1) according to claim 10 and ei ^¬ ner mechanical unit (27), wherein the actuator (1) with the

Mechanic unit (27) is force-transmitting or torque transmis ^¬ ing connected.