The present invention relates to a robot arm for industrial robots, and to be more specific, it relates to a precise regulation of an angular relationship in one or several joints in the robot arm.
There are currently no suitable arrangements for adjustment of robot arms in order to be able, through exact measurement of the angular relationship in one or several of the joints of the robot arm, to make an exact adjustment of the outer end of the robot arm, that is, its working point. It has instead been necessary to depend on being able to control the gear or other driving system that achieves turning of the joint, based on a defined initial condition, such that the working point adopts the desired position. There is no possibility of verifying the setting at a particular joint.
The aim of the present invention, therefore, is to achieve a robot arm in which it is possible to measure exactly the angular relationship in one or several joints of the robot arm in order to be able to make an exact adjustment of its working point, and to be able to verify the angular relationship in a particular joint.
The above aim is achieved with a robot arm for industrial robots, comprising one or several jointed arms that are mutually connected to each other by means of rotary joints, and a jointed arm connected to a base, where an angle transducer is arranged in the rotary joint in order to measure exactly the angular relationship between the jointed arms or between the jointed arm and the base, in order to make possible adjustment of the robot arm into the desired angular position.
According to claim 2, the angle transducer comprises a first disk, the rotor, with circularly arranged and radially directed receiver electrodes and a second disk, the stator, equipped with circularly arranged and radially directed transmitter electrodes arranged at the same radius as the receiver electrodes and with a fixed separation between the receiver electrodes and the transmitter electrodes on the two disks, whereby the disks are arranged coaxially and rotatable relative to each other, and the disks are further separated by a thin air-gap that makes possible a capacitive or an inductive coupling between the electrode systems on the receiver disk and the transmitter disk, whereby the transmitter electrodes are each supplied with an alternating voltage with different phases for neighbouring electrodes, whereby the number of supply phases, Φ, is greater than two, and the separation of transmitter electrodes=the separation of receiver electrodes/Φ, and where the transmitter electrodes of the stator are geometrically arranged such that errors in their geometry relative to the geometry of the receiver electrodes produces equal but opposite error signals in the receiver electrodes of the rotor.
An angle transducer of the type described above is the subject of a separate patent application that is being submitted simultaneously with the present one, and a description of current angle transducers and the problems that are associated with them is presented in the separate application, as is a more detailed description of the theory behind these angle transducers.
The invention will now be described with the aid of a non-limiting embodiment, illustrated in the attached drawings, in which
a shows a side view of the electrodes according to
Thus
The working point 2 can adopt freely chosen positions 2, 2a, 2b, 2c, etc., through different angles of the rotary joints. In the case shown in
A complete rotor disk 4 for use in an angular transducer for a robot arm according to the invention is shown in FIG. 2.
One of the properties of capacitive measurement systems designed according to the Swedish patent 7714010-1 is that of directly and with high precision being able to determine the magnitude of a relative angular rotation that is less than the separation of the receiver electrodes, which in the example below is 1/81 parts of a revolution. On the other hand, no information is obtained about which of the receiver electrode separations (in the example this is which of the 81 possible separations) is the current one. The transducer is, therefore, equipped with a second angular measurement system with a receiver electrode separation of 360°, i.e. one complete revolution. This second system, known as the “coarse measurement system” only serves to determine which of the 81 receiver electrode separations in the example is the current one.
The outer receiver electrodes 5 and 5′ thus form together with the corresponding electrodes 6 on the stator disk 7, the high-resolution angular measurement system, while the inner receiver electrodes 5c and 5c′ form, together with the corresponding electrodes 6′ on the stator disk 7, the coarse measurement system, which determines the angular position within the revolution of 360°.
The disk is coated with a conducting coating that is preferably constituted by a thin rolled copper foil. The black lines show insulating lines that can be achieved by means of, for example, photolithographic etching.
The lines 8, 9 in
In one possible embodiment, the angular separation between the rotor electrodes can be chosen such that 81 electrodes are present around one complete revolution, 360°.
In order to increase further the strength of the signal received, and, in particular, with the aim of reducing the sensitivity of the transducer for external sources of disturbance that produce alternating electrical fields that can be collected by the electrodes 5 of the rotor disk, the rotor disk is equipped with a second system of rotor electrodes 5′,
This second set of electrodes 5′ is also in electrical connection in the same way as the first set of, electrodes 5 through a thin strip of conducting material 11 being left behind below the electrodes.
In one preferred embodiment, the signals produced in the electrode fields 5 and 5′ are transferred via through-plated holes 12 and 13,
Four supply signals R,S,T,U are used in the preferred system that is described here. These are displaced in phase relative to each other according to the Swedish patent 7714010-1 as so shown in the following pattern:
The table shows that the supply signals R and T are displaced in phase relative to each other by 180°. In the same way, the supply signals S and U are displaced in phase relative to each other by 180°.
As has been described above, the two sets of rotor electrodes are displaced geometrically by ½ off a rotor electrode separation relative to each other. Since the transmitter electrodes S and U are supplied with voltages that are equal in magnitude and displaced in phase by 180° relative to each other, the signals received in the rotor electrodes 5 and 5′ will be equal in magnitude but of opposite sign. This is illustrated in principle in FIG. 7. The two diagrams show how the amplitude U of the signal received by the receiver electrodes 5 and 5′ of the rotor varies with a relative change of angle α between the rotor and the stator.
The upper diagram shows in principle the amplitude of the signal that is produced in the rotor electrodes 5, while the lower diagram shows the equivalent for the signal that is produced in the rotor electrodes 5′. As the diagram makes clear, the signals that are received from the set 5′ of electrodes constitute a mirror image of the signal in the set 5 of electrodes. This means that it is highly appropriate to apply the two signals each to one input of a differential amplifier as has been mentioned above. In this way, the effect is achieved that the two signals are added, and the resulting output signal from the amplifier has an amplitude that is twice as large. Furthermore, the influence of disturbing signals produced in the receiver electrodes 5 and 5′ due to external electrical alternating fields is in this way reduced using the property of the differential amplifier that depresses signals on its inputs that have the same phase (Common Mode Rejection).
When using robot arm systems containing one or several linked arms, 1, 1c in
When using the invention described here, however, the effects of tilts of the rotor 4 relative to the stator 7,
According to the invention, the electrode systems can be supplemented by one further system,
By placing at least three pairs of electrodes 15, 16 equally spaced around the perimeter of the angle transducer, the radial displacement of the jointed arm 1 can be calculated with the aid of suitable mathematical processing of the amplitude values from the electrodes 15 and 16.
In order to determine an erroneous angle setting according to is
The receiver electrodes 18 each collect a signal from the transmitter electrode 17 by capacitive transmission. The amplitude of the signal received at the electrodes 18 depends on the relative distance between 18 and the transmitter electrode 17. The amplitudes in all electrodes 18 will be equally large in the symmetrical case. In the event of tilt of the jointed arm 1 according to
In the case in which the radial space is of minor significance, it is an alterative to make the transmitter electrode 19 sufficiently broad that the electrodes 15, 16 and 18 can be distributed independently of each other around the perimeter of the angle transducer.
The transmitter electrodes for a capacitive system of the principle described here, 4-phase, must satisfy the condition that the separation between these electrodes must be equal to (the separation of the rotor (receiver) electrodes)/(Φ, i.e. in this case it must be equal to (the separation of the rotor (receiver) electrodes)/4. This means in the example that the separation of the transmitter electrodes must be 1/81*¼, i.e. 1/324 parts of a revolution.
Thus, by permutation of the phase supply electrodes of the stator as is described in the second patent application submitted simultaneously, PCT/SE01/01773, the primary functional separation of ¼ of a rotor electrode separation between subsequent phase supply electrodes, R,S,T,U is maintained.
This is illustrated in
Although the angle transducer for the robot arm eliminates errors in specification of angles that arise from shortcomings in the bearings of the machine element onto which the transducer is mounted, positioning accuracy is still influenced mechanically and geometrically in the overall system by play and wobble in its bearings. Even if the angular position has been correctly read by the angular measurement system, the position of the working point 2,
Such errors can also be measured and compensated for in real-time by adding a further electrode system. Such electrode systems are shown in
The fact that the output signals from each individual plate 15, 16 in
Each individual plate 18 in
Number | Date | Country | Kind |
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0003111-2 | Sep 2000 | SE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/SE01/01774 | 8/20/2001 | WO | 00 | 6/23/2003 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO02/20227 | 3/14/2002 | WO | A |
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20040027139 A1 | Feb 2004 | US |