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Title:
A DEVICE FOR RELATIVE MOVEMENT OF TWO ELEMENTS
Document Type and Number:
WIPO Patent Application WO/1997/033725
Kind Code:
A1
Abstract:
A device for relative movement of two elements (1, 2) comprises at least two first links (8, 9), which are connected relative to a first (1) of the elements via hinges (10, 11) and which are pivotable in substantially parallel planes relative to the first element (1) under influence of at least one first power-exerting member (12). At least two second links (14, 15), which are connected relative to a second (2) of the elements via hinges (16, 17), are pivotable in substantially parallel planes relative to the second element under influence of at least one second power-exerting member (18). The two first links (8, 9) form a first four-hinges system (FS1). The two second links (14, 15) form a second four-hinges system (FS2). These two four-hinges systems are coupled in series to each other between the first and second elements (1, 2).

Inventors:
BROGAARDH TORGNY (SE)
Application Number:
PCT/SE1997/000433
Publication Date:
September 18, 1997
Filing Date:
March 14, 1997
Export Citation:
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Assignee:
ASEA BROWN BOVERI (SE)
BROGAARDH TORGNY (SE)
International Classes:
B25J11/00; B25J9/10; B25J17/00; F16H21/46; (IPC1-7): B25J9/10
Foreign References:
GB2060556A1981-05-07
DE2938767C21983-12-08
US4329110A1982-05-11
US4756655A1988-07-12
FR2572981A11986-05-16
US5237887A1993-08-24
US5386741A1995-02-07
US5419674A1995-05-30
Other References:
DERWENT'S ABSTRACT, No. 91-279632/38, Week 9138; & SU,A,1 602 732, (EREV POLY), 30 October 1990.
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Claims:
Claims
1. A device for relative movement of two elements (1, 2) said device comprising articulated links interconnecting the elements and at least two powerexerting members to exert power for the relative movement of the elements, character¬ ized in that it comprises at least two first links (8, 9) connected relative to a first (1) of the elements via hinges (10, 11), said first links being pivotable in substantially parallel planes relative to the first element (1) under in¬ fluence of at least a first (12) of the powerexerting members, that the device comprises at least two second links (14, 15) connected relative to a second (2) of the elements via hinges (16, 17), said second links being pivotable in substantially parallel planes relative to the second element under influence of at least a second (18) of the power exerting members, that said at least two first links (8, 9) form a first fourhinges system (FSl), that said at least two second links (14, 15) form a second fourhinges system (FS2) and that these two fourhinges systems are coupled in series to each other between the first and second elements.
2. A device according to claim 1, characterized in that said at least two first links (8, 9) and said at least two second links (14, 15) are pairwise hingedly connected to each other.
3. A device according to claim 1 or 2, characterized in that at least one third link (13) interconnects pivotably at least one of the following: (a) the two first links (8, 9) and (b) the two second links (14, 15).
4. A device according to claim 3, charaπtPri wA in that the first and third links (8, 9, 13) and the first element form a first articulated fourlinks system.
5. A device according to claim 3 or 4, characterized in that the second and third links (14, 15, 13) and the second element (2) form a second articulated fourlinks system.
6. A device according to claim 4 and 5, charac er!zed in that the third link (13) is common to the two articulated fourlinks systems.
7. A device according to any preceding claim, characterized in that the first and second fourhinges systems (FSl, FS2) form parallelograms.
8. A device according to any preceding claim, characterized in that at least one third powerexerting member (26) is ar ranged to move the first element (1) relative to a base member (27).
9. A device according to any of claims 12 and 8, character ±zeΔ in that the first (12) and a fourth (25) of the power exerting members are adapted to exert such influence on a respective one of the first links (8a, 9a) which causes pivoting relative to the first element (1), and that the first links are arranged to be independently pivotable, whereby a mutual relation between the first and second elements (1, 2) as far as inclination is concerned is variable by one or both of the following: (a) pivoting of only one of the first links and (b) pivoting of both links with an angular difference.
10. A device according to any of claims 18, characterized in that the first element (1) is formed by two parts (IzA, IzB; laA, laB; laA, laB), which are hingedly connected to each other, that a fourth (25z; 25a, 25a) of the power exerting members is arranged to pivot a first (lzb; laB; laB) of the parts relative to a second (IzA; laA; laA) of the parts, that the first part forms a constituent of the first fourhinges system (FSl) since it is hingedly con¬ nected to the two first links (8z, 9z; 8a, 9a; 8a, 9a).
11. A device according to any preceding claim, characterized in that said at least one first powerexerting member (12) comprises a stationary portion connected relative to the first element and a movable portion connected to one of the first links and being arranged to cause this link to pivot relative to the first element.
12. A device according to any preceding claim, characterized in that two third links (13A, 13B) are provided, that a first (13A) of the third links interconnects the two first links (8n, 9n), that a second (13B) of the third links interconnects the second links (14n, 15n) and that the first and second of the third links are connected to each other.
13. A device according to any preceding claim, characterized in that the hinges in the first fourhinges system (FSl) form hinge axes, which are mutually substantially parallel, and that the hinges in the second fourhinges system (FS2) form hinge axes, which are mutually substantially parallel.
14. A device according to claim 12 or 13, characterized in that the first (13A) and second (13B) of the third links are connected to each other in an angled relation.
15. A device according to claim 13 and 14, characterized in that the hinge axes in the first fourhinges system (FSl) are substantially parallel to the hinge axes in the second fourhinges system (FS2).
16. A device according to claim 13 and 14, characterized in that the hinge axes in the first fourhinges system (FSl) extend at an angle to the hinge axes in the second four hinges system (FS2) .
17. A device according to claim 12, characterized in that the first (13A) and second (13B) of the third links are rigidly connected to each other.
18. A device according to any preceding claim with exception of claims 9 and 10, characterized in that the first (13Ap) and the second (13Bp) of the third links are mutually pivotable by means of a fourth powerexerting member (25p) for the purpose of changing the mutual orientation of the first and second elements as far as inclination is con¬ cerned.
19. A device according to any preceding claim, characterized in that the second powerexerting member (18) is connected relative to the first element (1) and acts on the second fourhinges system (FS2) via at least one link arm (21).
20. A device according to claim 19, characterigad in that the second powerexerting member (18) comprises at least one stationary portion rigidly connected relative to the first element (1) and a portion (22) movable relative to the stationary portion, said movable portion having one degree of freedom relative to the stationary portion, and that the movable portion is connected to the second fourhinges system via the link arm (21).
21. A device according to claim 20, characterized in that the second powerexerting member (18) is formed by a rotary means, the stator of which forms said stationary portion and the rotor of which forms the movable portion, that an arm (22) is connected to the movable portion and secured against rotation relative thereto, and that said arm is hingedly connected to the link arm (21).
22. A device according to claim 9, 10 or 18, characterized in that the second element (2a) comprises at least two working members (7aA, 7aB) provided in a spaced relation on the second element so as to obtain different positions on inclination of the second element relative to the first element.
23. A device according to claim 8, characterized in that the first element (1) is either of the following: (a) arranged on and (b) forms a constituent of a carrier (28) movable by means of the third powerexerting member.
24. A device according to claim 23, characterized in that the carrier is pivotable (28, 28b, 28e, 28f, 28m).
25. A device according to claim 23 and 24, characterized in that the carrier (28b) is designed as a third fourhinges system (FS3) forming a connection between the first four hinges system (FSl) and the base member (27b).
26. A device according to claim 23, characterized in that the carrier (28c, 28d) is displacably movable in a substan¬ tially straight path of movement.
27. A device according to any of claims 8 and 2326, charac¬ terized in that the carrier (28) is movable for displacement of the first element (1) and, accordingly, also the second element (2) and the two fourhinges systems (FSl, FS2) in a direction at an angle to planes, in which one or both of the following are pivotable: (a) the first links (8, 9) and (b) the second links (14, 15).
28. A device according to any of claims 8, 23, 24, 25 and 27 characterized in that the pivot axis (36f, 36m) of the carrier (28f, 28m) relative to the base member (27) is located substantially opposite to the first and second powerexerting members (12f, 18f; 12m, 18m).
29. A device according to any preceding claim, characterized in that a carrying arrangement (38) for a working member is hingedly connected to the second element, that the carrying arrangement is rotatable relative to the second element by means of a fifth powerexerting member (40), which is arranged on the first element (1) and is adapted to actuate the carrying arrangement via at least one link arm (41).
30. A device according to claim 29, characterized in that the working member (7g) is rotatably provided on the carry¬ ing arrangement (38) .
31. A device according to any preceding claim, a rotatable working member being arranged on the second element (2), char cterized in that a sixth powerexerting member (44) for rotating the working member (7h) is arranged on the first (lh) element and connected to an axle (45) arranged on the second element via a link arm arrangement (46), and that the axle is arranged to be imparted a rotational movement producing rotation of the working member (7h) on pivoting of the link arm arrangement.
32. A device according to claims 2931, char c er!zed in that the axle (45) is arranged on one of the following; (a) on the carrying arrangement (38), (b) on the second element (2).
33. A device according to claim 29, characterized in that on the second element (2i) there is arranged a first rotation axle (45i), which is adapted to be put into rotation by the link arm arrangement (46i) and which is arranged to put one of (a) the carrying arrangement (38i) and (b) a carrying member (49) of the carrying arrangement into rotation.
34. A device according to claim 33, characterized in that the carrying member (49) is rotatable about a second axis of rotation and that the first and second axes of rotation are in engagement via an angular transmission (47i).
35. A device according to any of claims 29 and 3234, characterized in that the carrying arrangement (38i) is formed by an articulated fourlinks system (FS4), in which the carrying member (49) forms one of the links.
36. A device according to any of claims 134, character! ed in that a fourth fourhinges system (FS4) is coupled to the second fourhinges system (FS2) so that the first, second and fourth fourhinges systems are in series with each other.
37. A device according to claim 36, characterized in that the fourth fourhinges system (FS4) is pivotable in planes extending at an angle to planes of pivoting of the second fourhinges system (FS2).
38. A device according to claim 36, characterized in that the fourth fourhinges system (FS4) is movable by means of a seventh powerexerting member (52) arranged on the first element (IK) and at least one link arm (53) between the seventh power member and the fourth fourhinges system.
39. A device according to claim 24, characterized in that the first and second powerexerting members (12m, 18m) are arranged on the carrier (28m) in the form of rotary motors each having a stator connected to the carrier and a rotor (56, 57) arranged to cause the first and second links respectively to pivot, that the rotors of the rotary motors are arranged to put, via first transmissions (58, 59), substantially parallel drive axles (60, 61) into rotation. that each of these drive axles is drivingly connected, via a respective angular gear (62, 63), to one (9m) of the first links and a link arm (22m) respectively connected to the second fourhinges system (FS2).
40. A device according to claim 39, characterized in that the drive axles (60, 61) are substantially coaxial to each other and to the pivot axle (36m) of the carrier (28m).
41. A device according to claim 39 or 40, characterized in that one of the drive axles (61) extend through the other drive axle (60), which is designed as a tubular axle.
42. A device according to any preceding claim, char c er!zed in that a transmission arrangement (65) is adapted to transmit movement from a rotatable drive member (66) on the first element to a rotable, driven member (69) on the second element, and that the transmission arrangement comprises transmission members (6972) extending along a link assembly comprising a first link (8m) and a second link (14m).
43. A device according to claim 42, characterized in that the transmission members comprises levers (6971), which comprise two arms and which are rotatably arranged at the hinges of the first and second links relative to each other and the first and second elements about axes parallel to the hinges of the links, said transmission members also compris¬ ing pairs of link arms (72) extending between the levers, rotation of a lever (70) arranged on the first element by means of the drive member causing rotation of that lever, which forms the driven member (69) and is arranged on the second element, with the assistance of the link arms (72) and intermediate lever(s) (71).
44. A device according to claim 42, characterized in that the transmission members comprise diverting members (7375) rotatably arranged at the hinges of the first and second links relative to each other and to the first and second elements about axes parallel to the hinges of the links, said transmission members also comprising loops of traction forcetransmitting elements (76, 77) laid about said divert¬ ing members, a diverting member (73) arranged at the first element forming the drive member and a diverting member (75) arranged at the other element forming the driven member.
45. A device according to claim 36, characterized in that two fourth fourhinges systems (FS4) are coupled parallel to each other and that each of these systems carry a working member.
46. A device according to claim 45, characterjzed in that the two fourth fourhinges system are mechanically coupled (78) to each other for common movement.
47. A device according to any preceding claim, characterized in that two sets (86) of parallelograms (FSl, FS2), which are coupled in series, are coupled substantially perpendicu¬ larly to each other, that each of the sets comprises the first and second elements (lx, 2x; ly, 2y), that the first elements (lx; ly) are pivotably connected to a base member (27x, 27y) about respective pivot axes (87, 87y) extending substantially perpendicularly to each other, that the pivot axis (87, 87y) between the first element (lx, ly) in each of the sets and the base member is directed substantially parallel to planes of pivoting of the parallelograms in this set, that a carrying arrangement (38x, 38y) is hingedly connected to both of the second elements (2x, 2y) about substantially perpendicular axes (88, 88y) substantially parallel to the pivot axes (87, 87y) between the first elements and the base member.
48. A device according to claim 47, character!zed in that a respective first powerexerting member (12x, 12y) is ar¬ ranged on each of the first elements (lx, ly) for pivoting one of the links (9x, 9y) which are connected to said first element, said links being included in the respective sets of parallelograms, and that a second powerexerting member (18x, 18y) is adapted to pivot an arm (22x, 22y), to which there is connected a link arm (21x, 21y) which is pivotably connected to the second parallelogram system (FS2) .
49. A device according to claim 47, characterized in that on the base member (27x, 27y) there are arranged three power exerting eighth members (90), which are coupled, via link arms (89) pivotable in nonparallel planes, to the carrying arrangement (38x, 38y) for positioning the same relative to the base member.
50. A device according to any preceding claim, characterized in that the transmission arrangement for power transmission from a drive member (92) on the first element (1) to a driven member (7) on the second element (2) comprises axles (93) extending substantially parallel to the links in the parallelogramshaped first and second fourhinges systems (FSl, FS2), said axles (93) being interconnected by means of one or both of (a) cardan joints (94, 95) and (b) angular gears (97).
51. A device according to any of claims 146 and 50, charac¬ terized in that the first element (16) is pivotably con nected to a base member (276) about a first pivot axis (108), that a ninth powerexerting member (109) is adapted to pivot the first element (16) and, accordingly, the first and second fourhinges system (FSl and FS2) and the second element (26) about the pivot axis, that a carrying arrange ment (110) is pivotably connected to the second element (26) about a second pivot axis (111) directed substantially parallel to the first pivot axis (108), and that a tenth powerexerting member (114) is adapted to pivot the carrying arrangement (110) about the second pivot axis (111).
52. A device according to any of the preceding claims, characterized in that it is formed by an industrial robot, the second element (2) of which is intended to carry, directly or indirectly via a carrying arrangement, a working member (7).
Description:
A device for relative movement of two elements

FIELD OF THE INVENTION AND PRIOR ART

This invention is related to a device for relative movement of two elements, said device comprising articulated links interconnecting the elements and at least two power-exerting members for exerting power for the relative movement of the elements.

The relative movement of the two elements has the purpose to position them mutually in an aimed manner by means of the power-exerting members. More specifically, the device according to the invention is intended to form a manipulator or robot. The second of the elements is intended to carry, directly or indirectly via a carrying arrangement, a working member to carry out the function intended, e.g. pick¬ ing/placing, packing and palletising. However, it is re¬ marked that the working member may be designed to execute also other working operations than those just mentioned.

Conventional robots are based upon an arm-like system of pivotable links, which at their extreme ends comprise power- exerting members for pivoting/rotating links/working members located further out on the arm. The provision of power- exerting members at the extreme end of pivot arms involves high loads and inertia, which impose restrictions with respect to possible accelerations and speeds and accuracy with respect to path. Other robot types are known but have turned out to be less successful, either by deficient performance with regard to accuracy and speed or a high cost. In the US patent 4 976 582 there is described, for ex-

ample, a robot, where three power-exerting members are arranged on a first element in triangular distribution. These members are connected to a movable element via three link devices coupled in parallel, likewise in triangular distribution, said link devices being hingedly connected to the associated pivot arm and to the movable element respec¬ tively by means of articulation joints providing two and not more than two degrees of freedom. In reality, each of the link devices comprises two parallel links coupled to a respective pivot arm and the movable element in a hinged manner while forming parallelograms. A disadvantage of this known type of robot is that it is difficult, as a conse¬ quence of the three-dimensional arm system, to place closely adjacent in a plurality. Even if the known robot may be made very fast and accurate for common purposes, it is less suitable for special adaptation for specific work tasks. For instance, it is sometimes required to achieve very rapid movements in two dimensions perpendicular to each other, whereas the requirements with regard to performance as far as other degrees of freedom are concerned may be modest. The known robot may not be adjusted to such circumstances. By its symmetrical structure, the known robot also becomes relatively restricted as far as work area adaptation is concerned.

SUMMARY OF THE INVENTION

This invention aims at devising routes to provide motion de¬ vices which may be realised by means of relatively simple structural solutions but which nevertheless make it possible to achieve very rapid and precise movements in at least two directions perpendicular to each other.

A secondary purpose of the invention is to provide possi- bilities for a modularized structure in the sense that the

device should be easily adaptable to work tasks with differ¬ ent degree of complication.

A tertiary object of the invention is to enable use of comparatively simple and well tried hinge constructions in the device.

The primary object of the invention is achieved in that the device according to the invention comprises at least two first links connected relative to a first of the elements via hinges, said links being pivotable in substantially parallel planes relative to the first element under influ¬ ence of at least one first of the power-exerting members, that it comprises at least two second links, which are connected relative to a second of the elements via hinges and which are pivotable in substantially parallel planes relative to the second element under influence of at least a second of the power-exerting members, and that the at least two first links form a first four-hinges system, that the at least two second links form a second four-hinges system and these two four-hinges systems are coupled in series to each other between the first and second elements.

In this way a double four-hinges structure is achieved with very rapid movement performance in the plane of pivoting of the four-hinges systems.

In a preferred embodiment of the invention, the four-hinges systems form parallelograms, which means that a constant orientation of a work member carried directly or indirectly by the second element may be achieved with only two axes.

The secondary object above is according to the invention achieved in that it provides, in its most genuine form with the two four-hinges systems, freedom of movement in two substantially perpendicular directions and then may be

completed with further freedoms of movement according to circumstances.

The use of four-hinges systems of the defined kind results in simple hinges which only have to provide a single degree of freedom, i.e. pure pivoting.

The solution according to the invention makes it possible to achieve a larger working area in two dimensions perpendicu- lar to each other than it is possible to achieve with the robot according to US 4 976 582.

A plurality of preferable developments of the invention are defined in the rest of the claims. These developments and advantages in connection with the invention are dealt with more closely in the following description.

BRIEF DESCRIPTION OF THE DRAWINGS

With reference to the enclosed drawings a more specific description of embodiment examples of the invention follows hereunder.

In the drawings;

Fig 1 is a plan view illustrating a work task for the robot according to the invention;

Fig 2 is a more detailed side view;

Fig 3 is a diagrammatical side view illustrating the device according to the invention in a simple form;

Fig 4 is a view similar to Fig 3 but illustrating possibili- ties of modification;

Fig 5 is a view illustrating the device according to Fig 4 in an upwardly pivoted condition;

Fig 6 is a view similar to Fig 5 with the device pivoted to- wards the opposite direction, the four-hinges structure according to Fig 3 being illustrated;

Fig 7 is a view similar to Fig 4 of a modified embodiment involving possibility for tilting with respect to the second element;

Fig 8 is a view illustrating the device according to Fig 7 in alternative position;

Fig 9 is a diagrammatical view illustrating the device according to Figs 7 and 8 in work;

Fig 10 is a view from above illustrating how several robots according to the invention may be placed close to each other;

Figs 11-13 are views illustrating embodiments forming alternatives to the one in Fig 10;

Fig 14 is a perspective view illustrating an embodiment of a robot according to the invention;

Fig 15 is a perspective view of a modification of the embodiment according to Fig 14;

Fig 16 is a diagrammatical side view of a robot having a pivotable carrying arrangement for a working member provided on the second element;

Fig 17 is a detailed view illustrating a transmission applicable to, for instance, the robot according to Fig 16;

Fig 18 is a diagrammatical view illustrating an application of the transmission illustrated in Fig 17;

Fig 19 is a perspective view of an alternative robot embodi¬ ment;

Fig 20 is a schematic view from the side of a robot embodi¬ ment;

Fig 21 is a partial detailed view illustrating the more specific embodiment of the robot according to Fig 20;

Fig 22 is a diagrammatical view of an alternative four- hinges system structure;

Fig 23 is a perspective view of a robot application substan¬ tially similar to Fig 22;

Fig 24 is a view of a modification of the robot according to Fig 23;

Fig 25 is a side view of a transmission for a robot, for in¬ stance according to Figs 20 and 21;

Fig 26 is a detailed view in an enlarged scale and in a position rotated 90° relative to Fig 25;

Fig 27 is a view similar to Fig 25 of an alternative trans- mission;

Fig 28 is a detailed view of the transmission according to Fig 27;

Fig 29 is a side view of an alternative robot embodiment;

Fig 30 is a view from below of the embodiment according to Fig 29;

Fig 31 is a side view of a further robot embodiment;

Fig 32 is a view of the robot according to Fig 31 viewed from the right;

Fig 33 is a detailed view of an alternative embodiment;

Fig 34 is a side view of an alternative robot embodiment;

Fig 35 is a side view of a further alternative;

Fig 36 is a view in a "false" perspective of a robot embodi¬ ment with lateral stabilization and three four-hinges systems coupled in series;

Fig 37 is a view, as well in "false" perspective, of an alternative embodiment with lateral stabilization;

Fig 38 is a diagrammatical perspective view of an alterna¬ tive robot embodiment;

Fig 39 is a side view of a further alternative;

Fig 40 is a view of the embodiment according to Fig 39 in a changed position;

Fig 41 is perspective view of an alternative robot embodi¬ ment;

Fig 42 is a view similar to Fig 42 but with a certain modification;

Figs 43 and 44 are diagrammatical views in different posi¬ tions of an embodiment similar to Figs 41 and 42;

Figs 45 and 46 are perspective views of a further robot embodiment in two somewhat differing positions;

Figs 47 and 48 are views illustrating an embodiment for tilting of the second element;

Figs 49 and 50 are diagrammatical views of two alternative four-hinges system structures;

Fig 51 is a view illustrating a cardan transmission;

Fig 52 is a view illustrating a transmission of cardan and angular gear type;

Fig 53 is a view of a modified embodiment similar to the one in Fig 23;

Fig 54 is a view of a modified embodiment similar to the one in Fig 24; and

Fig 55 is a view of a modified embodiment somewhat similar to the one in Fig 41.

DETAILED DESCRIPTION OF A PREFERRED EMBODIMENT

In order to simplify the understanding, the same reference characters with addition of letters specific to the embodi¬ ments have been used in the following with respect to different embodiments for similar or corresponding compo¬ nents.

In Fig 1 two perpendicularly moving conveyors 1 and 2 respectively are illustrated in order to exemplify a possi-

ble work task for the robot structure according to the invention. Components 3 are moved on the conveyor 1 whereas components 5 are moved on the transversely moving conveyor 2. As indicated with the dashed arrows in Fig 1, the compo- nents 5 are intended to be placed upon the components 3. The conveyor 2 extends above the conveyor 1.

Thus, the conveyor 1 moves in the direction X whereas the conveyor 2 moves in the direction Y. It is understandable that high performance is required in X- and Z-direction in the illustrated case, whereas the requirements with regard to performance in Y-direction are modest.

In Fig 2 it is illustrated that the components 3 on the conveyor 1 could have the character of containers, on which components 5 are to be placed. This component 5 is in the example conceived to have the character of a lid or other restriction to be placed on top, e.g. foil sheets to placed on e.g. food packings, a lid being placed thereon after- wards. These foil sheets 5 are supplied by means of a magasine 6, from which the foil sheets may be fetched obliquely from below. For this purpose a work member 7 of the robot should be capable of extending obliquely upwardly so as to engage the sheet. Then the working member 7 should be rotatable about the Y-axis. In order to correct possible misalignments between the components 3 and 5, the working member 7 may also have to be rotated about the Z-axis (r z in Fig 1).

The device according to the invention is illustrated in a highly basic character in Fig 3. The device comprises a diagrammatically indicated first element 1 and a second element 2 carrying the working member 7. In the case de¬ scribed with guidance of Fig 2, the working member 7 is thought to consist of a suction gripping means to grip the foil sheets 5 but vastly different designs of the working

member are possible, e.g. as tools for tasks such as weld¬ ing, cutting, water cutting, glueing, burr-removing, grind¬ ing etc.

The device according to Fig 3 comprises two first links 8, 9, which via hinges 10, 11 are connected to the first element 1. The links 8, 9 are pivotable in substantially parallel planes relative to the element 1 under influence of a first power-exerting member 12.

The device comprises two second links 14, 15, which are connected to the element 2 via hinges 16, 17. The links 14, 15 are pivotable in substantially parallel planes relative to the element 2 under influence of a second 18 of the power-exerting members.

The two links 8, 9 form a first four-hinges system FS1 whereas the second links 14, 15 form a second four-hinges system FS2. The two four-hinges systems are coupled in series with each other between the first and second elements 1, 2.

The expression "coupled in series" means here that the four- hinges system FS2 is carried by the four-hinges system FS1 spaced from the hinges 10, 11 thereof such that the four- hinges system FS2 will be movable by means of the four- hinges system FS1.

In the example the first two links 8, 9 and the two second links 14, 15 are pairwise hingedly connected directly to each other via hinges 19, 20.

At least a third link 13 connects the links 8, 9 and 14, 15 respectively. More specifically, the link 13 is hingedly connected to the links via the hinges 19, 20. Thus, the link

13 is common to the four-hinges systems FS1 and FS2. This

means that the first links 8, 9, the third link 13 and the element 1 form a first articulated four-links system. The second links 14, 15, the link 13 and the element 2 form a second articulated four-links system. Hereinafter, the designations FSl and FS2 will replacably be used for the ex¬ pressions four-hinges system and four-links system. As will be described more closely with assistance of Fig 7, the expression four-hinges system comprises, however, that it may lack a link included in a four-links system.

The four-hinges systems FSl and FS2 form parallelograms, which means that constancy with regard to the mutual orien¬ tation of the elements 1 and 2 will be maintained independ¬ ently of the positions of pivoting of the links 8, 9 and 14, 15.

The hinges 10, 11, 19, 20 in the first four-hinges system FSl form mutually substantially parallel hinge axes. Like¬ wise, the hinges 16, 17 and 19, 20 in the second four-hinges system FS2 form mutually substantially parallel hinge axes. The hinges are simple pivot hinges having to present a single degree of freedom.

The hinge axes in the two four-hinges systems FSl and FS2 are substantially parallel to each other in Fig 3.

The second power-exerting member 12 comprises a stationary portion connected relative to the first element 1 and a movable portion connected to one of the first links, namely the one denoted 9, said movable portion being arranged to cause the link 9 to pivot relative to element 1. The member 12 may in practice have widely different constitution. For example, it could consist of a member having a variable length and acting between points on the element 1 and link 9 in order to generate a torque about hinge 11. Another possible and in this case preferred embodiment consists in

designing the member 12 as a rotary means having a stator and a rotor, the stator being connected to the element 1 whereas the rotor is connected to the link 9. The means 12 could of course just as well act pivoting on the link 8.

Independently of the specific design of the means 12, the same should be adapted such that it maintains, in an inac¬ tive state, a pivoting position adjusted for an associated link 9 such that this pivoting position only is changed upon positive driving of means 12.

The second power-exerting member 18 is connected relative to the first element 1 and acts on the second four-hinges system FS2 via at least one link arm 21. The member 18 comprises a stationary portion rigidly connected relative to element 1 and a portion movable relative to the stationary portion, said movable portion having to present only one de¬ gree of freedom relative to the stationary portion. This movable portion is connected to the four-hinges system FS2 via the link arm 21. It is preferred that the member 18 is formed by a rotary means, the stator of which forms the stationary portion and the rotor of which forms the movable portion. An arm 22 is connected to the movable portion and secured against rotation relative thereto. This arm is via a hinge 23 connected to the link arm 21, which in its turn is connected to the element 2 via a hinge 24, although the link arm 21 just as well could be connected to any of the links 14, 15. Since the four-hinges systems FSl and FS2 in this case are pivotable in parallel planes, it is sufficient that the hinges 23 and 24 have one single degree of freedom and form hinge axes parallel with the axes of the four-hinges systems.

The structure described with assistance of Fig 3 may be ad- justed in the XZ-plane with high speed and precision by an adequate control of the two power members 12, 18 so that in

this way the position of the working member 7 in the XZ- plane may be controlled.

It is pointed out that in the disposition according to Fig 3 the arm 22 and the link arm 21 must be able to pass at the side of the four-hinges systems FSl and FS2.

In Fig 4 a robot structure is illustrated which deviates from the one shown in Fig 3 in that the four-hinges systems FSl and FS2 and the arm 22/link arm 21 are angled away from each other. It is in this connection pointed out that the angle between the arm 22 and the link arm 21 must not, of course, be equally large as the angle between the respective pairs of link arms 8, 9; 14, 15 in the four-hinges systems FSl and FS2; it is the four-hinges systems which define the relative position between the elements 1 and 2 as far as parallelism/mutual orientation is concerned. Thus, the arm 22 and link arm 21 serve only to skew the four-hinges system FS2 in order to vary the position of the working member 7 in Z-direction.

Alternative locations of the third link 13 are illustrated with dashed lines in Fig 4. Thus, the link 13 may not have to interconnect the hinges 19, 20 although this at times may be preferable.

It is illustrated in Fig 5 that the robot according to Fig 4 may be pivoted upwardly in one direction into a rather high position. It is pointed out that a corresponding high position also may be achieved in the opposite direction if the links are placed in an adequate three-dimensional order. Such a raised position in opposite direction is illustrated in Fig 6, said position being achievable by means of the four-hinges composition shown in Fig 4 in combination with angular movement of the arm 22/link arm 21.

An alternative embodiment suitable for enabling the rotation about the Y-axis described with assistance of Fig 2 is illustrated in Fig 7. This rotation is indicated with rY. In the embodiment according to Fig 7, the four-hinges systems FSl and FS2 are, as before, at hand but the difference is that the first links 8a and 9a are arranged to be pivotable independently of each other. For this purpose the embodiment comprises, as before, a power-exerting member 12a to pivot the link 9a but also a fourth power-exerting member 25 adapted to pivot the link 8a. Thus, by pivoting only one of the links 8a and 9a or both of them with an angular differ¬ ence, the mutual relation between the first and second elements la and 2a as far as inclination is concerned may be varied. This appears more closely by a comparison with the position illustrated in Fig 8. Thus, the element 2a will, as a consequence of this variation of inclination, be rotated about the axis Y and this rotational movement may be used in a manner which is described with assistance of Fig 2.

A further way of gaining advantage of the possibility to in¬ cline the element 2 relative to the element 1 in a varying degree is illustrated in Fig 9. The second element is illustrated with 2a in Fig 9 and it is shown in four differ¬ ent positions. More specifically, the second element 2a comprises at least two working members 7aA, 7aB arranged in a spaced manner on the element 2a in order to obtain that the working members assume different positions on inclina¬ tion of the element 2a relative to the first element la, which is not shown in Fig 9. This can be used so that the working members 7aA and 7aB as indicated in Fig 9 may be al- ternatingly caused to grip a component 5 and deposit the same on another component 3 movable along the conveyor 1. There are suitably two magasines or stacks of components 5 available since this reduces the cycle time for the opera- tion in question. Apart from the inclination of the second

element 2a, the working members 7aA and 7aB are moved in the X- and Z-directions.

So far it has been diagrammatically assumed that the element 1 is intended to be stationary. However, the element 1 is, in practice, at least in some embodiments, intended to be movable per se by means of a third power-exerting member 26 (see Fig 10) in relation to a base member 27.

Robot structures of the nature described with assistance of Figs 3-7 are in the following designated as R2, where the number stands for the number of axes of movement of the robot (apart from the previously discussed rotational movements about Y- and Z-axis).

It appears from Fig 10 that R2-robots are placed on carriers 28 movable by means of power-exerting members 26. The first element 1 of the R2-robot is in reality intended to be attached to the carrier 28 or form a constituent thereof. A carrier 28 is pivotable by means of the power-exerting member. More specifically, the carrier 28 has the character of an arm protruding from the base member 27. Several such arms 28A-C are orientated in parallel and they carry robots R2A-C respectively. The robots are located with their respective planes orientated substantially parallel, which makes it possible to achieve a high degree of packing. The power members 26A-C in Fig 10 may be of an arbitrary type but are here conceived to consist of rotary means having stators secured to the base member 27 and rotors secured to the carrier arms 28. For the rest, it is illustrated in Fig 10 that the working member 7 on the various robots R2 is thought to be rotatable about the Z-axis.

It is illustrated in Fig 11 that the carrier 28b does not have the shape of a pivoting arm but instead is designed as a third four-hinges system FS3. This forms a connection

between the R2-robot and the base member 27b. This four- hinges system 28b is suitably a parallelogram and the robot R2 is suitably attached to the parallelogram link 29 turned away from the base member 27b. As before, it is preferably the first element 1 of the R2-robot which is secured to the link 29. Furthermore, it appears from Fig 11 that several third four-hinges systems may be placed closely adjacent to each other.

It is illustrated in Fig 12 that the carrier 28c is displa- cably movable in a substantially straight direction of movement (arrow 30). The robot R2 is attached to the carrier 28c, which is movable along a path of movement 31. This consists in the example of a cog way, with which a gearwheel 32 present on the carrier 28 engages drivingly. On the carrier 28c, which accordingly has the character of a carriage, there is arranged a drive motor 33 capable of putting in rotation an axle 34 provided with a gearwheel 32 via a gear. A further axle 35 provided with gearwheels 32 is arranged on the carrier 28c and also the second axle may, if desired, be driven by means of the drive motor 33.

Fig 13 illustrates a variant of an embodiment already described with assistance of Fig 11, wherein a carrier 28d for the robot R2 is designed as a four-hinges system forming a connection between the robot R2 and the base member 27d. A motor 26d serves for pivoting the four-hinges system 28d and thereby movement of the robot R2. Also here two robots R2 are illustrated as disposed at the sides of each other. Alternative positions for the four-hinges systems are indi¬ cated with dashed lines. The four-hinges systems are formed by parallelograms for parallel movement of the robots R2.

In Fig 14 a carrier 28e for a robot R2 is illustrated designed as a pivoting arm. The pivoting arm 28e is pivota¬ ble about an axis 36 relative to a base member 27e by means

of a power-exerting member in the form of a rotary motor 26e. As previously described, there are two power-exerting members 12e and 18e to operate the working member 7e of the robot about two axes, i.e. in the plane XZ. The carrier 28e functions by its mobility to move the two-axes robot R2 in Y-direction. The first element le may here be said to form a constituent of the carrier 28e. The working member 27e may be rotatable about the Z-axis by means of a power-exerting member 37 arranged on the second element 2e. For instance, the power member 37 may be formed by a rotary motor.

In Fig 15 a variant relative to the embodiment according to Fig 14 is illustrated. The pivoting arm 28f is here compara¬ tively short and may be said to be formed by the first element If. The pivot axis of the arm 28f is denoted 36f. In this embodiment the two power-exerting members 12f and 18f are arranged relatively close to the pivot axis 36f, since loads at a distance therefrom tend to require high torques of the power member 26f and create important inertia, which involves problems with respect to speed and precision. It is, more specifically, preferred, that the members 12f and 18f are located with their axes of rotation substantially co-axial and so that they substantially intersect a recti¬ linear extension of the pivoting axis 36f. Thus, the link 9f and the arm 22f are located such that their pivoting axes are substantially co-axial.

It may be established in the embodiments described before, the power-exerting members arranged for pivoting of the four-hinges systems FSl and FS2 have always been illustrated as arranged on the first element le, which is favourable with regard to load since these power-exerting members normally are comparatively heavy and could cause problems as far as acceleration, speed and precision are concerned should they be arranged more or less far out in the link arm structure.

In Fig 16 an embodiment is illustrated where on the second element 2g a carrying arrangement 38 for a working member 7g is hingedly connected. The pivot axis of the carrying arrangement 38 relative to the element 2g is denoted 39. The pivot axis coincides in the embodiment with the hinge axis between the link arm 21g and the element 2g, which, of course, is not necessary.

The carrying arrangement 38 is pivotable relative to the second element 2g by means of a fifth power-exerting member 40, which is arranged on the first element lg, which here forms a carrier, which is pivotable or rotatable about an axis 36. By operating the power-exerting member 40, the orientation of the working member 7g relative to element 2g may, accordingly, be varied as desired. The power-exerting member 40 is arranged on the first element lg and acts on the carrying arrangement 38 via at least one link arm 41. The member 40 comprises a stationary portion connected to the element lg and a movable portion actuating, via an arm 42, the link arm 41. The hinges between the link arm 41 and the arm 42, between the link arm 41 and the carrying ar¬ rangement 38 and between the stationary and movable portions of the power member 40 only need to have one degree of freedom for pivoting in planes parallel to the plane of pivoting of the four-hinges systems.

The working member 7g is in the example intended to be rotatable about an axis 43 relative to the carrying arrange- ment 38. Thus, a five-axes robot is achieved. For rotating the working member 7g, a rotary motor may be provided on the carrying arrangement 38. However, since this increases the load at the extreme end of the robot, this is not favourable when the demands with respect to speed and precision are high. Instead, the solution illustrated in Fig 17 may be used. There it is diagrammatically illustrated that a sixth

power-exerting member 44 is arranged on the first element lh. This member 44 is connected to an axis 45. On applica¬ tion of the embodiment according to Fig 17 on the embodiment according to Fig 16, the axis 45 is supposed to be jour- nailed in the carrying arrangement 38h. A connection between the power-exerting member 44 and the axis 45 is established by means of a link arm arrangement generally denoted 46. When the member 44 is operated, the axis 45 is caused to ro¬ tate. It would be possible to design the working member 7h directly on the axis 45. However, in the example it is pre¬ ferred that there is a transmission 47 between the axis 45 and the working member 7h. This transmission is here de¬ signed as a step-up transmission. For the rest, the trans¬ mission 47 may have the character of an angular gear as indicated in Fig 17. This angular gear is formed by bevelled gearwheels arranged on the axis 45 and an axis of the working member 7h respectively.

The power-exerting member 44 has a stationary portion connected to the element lh and a movable portion rigidly connected to an arm 48, which by means of at least one and in the embodiment two link arms included in the arrangement 46 is connected to the axis 45.

In case there would not be any pivotable carrying arrange¬ ment 38 on the second element 2g in Fig 16, the device illustrated in Fig 17 for rotating the working member 7h could be provided on the second element 2g instead of on the carrying arrangement 38.

It is diagraromatically illustrated in Fig 18 that a device similar to the one in Fig 17 could be used to put a carrying arrangement 38i, formed by means of an articulated four- links system, in the example a parallelogram which is journalled on the second element 2i by means of two arms, into rotation. The working member 7i is arranged to be put

into motion by means of the carrying arrangement 38i, the four-hinges system suitably being movable in a way which will be described more closely with assistance of Fig 19. The link arm arrangement 46i is connected to an axis 45i, which by means of a bearing 48 is supported on the element 2i. The axis 45 drives, via a transmission 47i, a carrying member 49 contained in the carrying arrangement 38i. More specifically, the carrying member 49 forms a link in the four-links system. The transmission 47i is in the example an angular transmission. A counter-weight 50 balances forces of gravitation and influence eminating from the carrying arrangement 38i and its working member.

In Fig 19 it is illlustrated that a carrying arrangement 38k of a four-links type is connected to the second element 2k. More specifically, a link 51 in the four-links system is rigidly connected to the element 2k.

The four-links systems FSl and FS2 included in the robot provide, in the example, for movement in the XZ-plane illustrated. The four-hinges system 38k on the other hand is pivotable in the XY-plane, i.e. perpendicularly to the plane of pivoting of, in the example, the two four-hinges systems FSl and FS2. Expressed in other words, the four-hinges system 38k is coupled to the four-hinges system FS2 so that the systems FSl, FS2 and FS4 are in series with each other although the coupling between the systems FS2 and FS4 is an¬ gled about the X-axis 90° and, besides, rotated substan¬ tially 90° about the Z-axis.

The four-hinges system FS4 is suitably caused to pivot in the XY-plane by means of a seventh power-exerting member 52 arranged on the element Ik and at least one link arm 53 between the power member 52 and the four-hinges system FS4. The power member 52 comprises also here a stationary portion rigidly connected to the element Ik and a movable portion

connected to an arm 54, which in its turn actuates FS4 via the link arm 53. The arm 54 and the movable portion of member 52 have, in the example, a single degree of freedom, namely a pure pivoting movement, relative to element Ik whereas the link arm 53 is coupled to the arm 54 and FS4 via hinges comprising two degrees of freedom.

In Figs 20 and 21 a robot is illustrated, which comprises four-hinges systems FSl and FS2 and a first element lm. It is diagrammatically illustrated in Fig 20 that the element lm forms a carrier rotatable about an axis 36m relative to a base member 27m. The first and second power-exerting members 12m and 18m are arranged on the carrier lm in the form of rotary motors each having a stator connected to the carrier and a rotor 56 and 57 respectively (see also Fig 21) ar¬ ranged to cause the links in the four-hinges systems FSl and FS2 to pivot.

It appears more closely from Fig 21 that the rotors 56, 57 are arranged to put, via first transmissions 58 and 59 respectively, for instance gearwheel transmissions, substan¬ tially parallel drive axles 60 and 61 respectively into ro¬ tation. One 60 of these axles is drivingly connected to a link 9m included in the four-hinges system FSl via an angular gear 62. The axle 61 is drivingly connected to the arm 22m by means of an angular gear 63.

The drive axles 60, 61 are substantially co-axial to each other and to the pivot axis 36m of the carrier 27m. In order to pivot the carrier 28m relative to the base member 27m, there is arranged a power-exerting member 26m, for instance in the form of a rotary motor, which via a transmission causes the axis 36m to rotate.

One 61 of the drive axles extends through the other drive axle 60, which is designed as a tubular axis. In this way a

compact embodiment is achieved with a maximum load centered in the area about the pivot axis 36m of the carrier 28m, which is favourable from the point of view of load.

The axles 60, 61 are journalled relative to the carrier 28m by suitable bearings.

In Fig 22 a variant is illustrated where two third links 13A and 13B are arranged. A first 13A of these links connects the links 8n and 9n whereas the second 13B connects the second links 14n and 15n. The links 13A and 13B are rigidly interconnected as indicated by the cross bar 64. An angled relation, in the example perpendicular, is involved with re¬ spect to the links 13A and 13B. Thus, they constitute in this embodiment not any links relative to each other but only relative to the associated four-hinges systems FSl and FS2. Although in the embodiment the hinge axes in the two four-hinges systems FSl and FS2 are conceived to be parallel to each other, it is well possible that the four-hinges system FS2 with its link 13B is connected in such a relation to the link 13A that the four-hinges system FS2 becomes pivotable in planes forming an angle, for instance a right angle, to planes, in which the four-hinges system FSl pivots. In this connection reference is made to Figs 49 and 50 showing two examples thereof. More specifically, the four-hinges system FSl is pivotable in the XZ-plane in Fig 49 whereas the four-hinges system FS2 is conceived to be pivotable in the YZ-plane. In Fig 50 FSl is pivotable in the XZ-plane whereas FS2 is pivotable in the XY-plane.

In the embodiment according to Fig 22, the power-exerting member 18n is connected to the element In and arranged to actuate the four-hinges system FS2 to pivot in the XZ-plane via the link arm 21n. The member 18n comprises a stationary portion and a movable portion rigidly connected to the arm 22n, which in its turn is connected to the link arm 21n. The

link arm 21n adjoins, in this example, to FS2 in one of its hinge points although this is not a necessity.

The power member 12n actuating on the link 9n effects, accordingly, pivoting of FSl whereas the power member 18n via the link arm 21n effectuates pivoting of FS2. The robot, which accordingly is of two-axes type, provides for movement in the plane XZ.

The robot diagrammatically illustrated in Fig 22 appears somewhat more clearly in perspective in Fig 23, it being, in addition, illustrated that the first element lo forms a carrier, which by means of a power-exerting member 26o is pivotable about an axis parallel to the Z-axis, whereby ac- cordingly the working member 7o of the robot is provided with mobility in the XY-plane.

In Fig 24 a robot embodiment is illustrated which is equal to the one in Fig 23 with the exception that there is not any rigid connection between the third links 13Ap and 13Bp. Instead these links are mutually pivotable by means of a fourth power-exerting member 25p. With the four-hinges system FSl held in stable position by means of the power-ex¬ erting member 12p, the link 13Bp may, accordingly, be pivoted relative to the link 13Ap by means of the power member 25p, a fact which with the link arm 21p locked by means of the power-exerting member 18p involves a possibil¬ ity for varying inclination of the second element 2p and, thus, the working member. By means of the power member 25p the links 13Ap and 13Bp may, on the contrary, be locked mutually so that on pivoting of the four-hinges systems FSl and FS2 the orientation of the second element 2p and the working member always is maintained as a consequence of the parallelogram design of the four-hinges systems.

In Fig 25 transmission arrangement 65 is illustrated. This is conceived to be used with the assembly of links 8m and 14m also appearing from Figs 20 and 21. The hinge of the link 8m relative to carrier 28m is denoted 10m, the hinge between the links 8m and 14m with 19m and the link between the link 14m and the second element 2m, which is not illus¬ trated, is denoted 16m. In Fig 26 the device is illustrated in the area of the hinge 10m from above in Fig 25. As appears from a comparison with Fig 21, the link 8m is not directly coupled to any power exerting member. Accordingly, the hinge axis 10m is not used for pivoting the link 8m but the same is instead freely supported about the axis 10m. On the contrary, there is on the carrier 28m provided a drive member 66 to rotate the axis 10m. The member 66 may for instance consist of a member which in its turn is driven, for instance a gear wheel drivable at an angle by means of a further gear wheel 67 arranged on an axis 68. The axis 68 could be driven by a motor arranged on the carrier 28m. On the second element 2m, which is not illustrated, a rotatably driven member 69 is intended to be arranged. The transmis¬ sion arrangement comprises transmission members extending along the link assembly 8m, 14m. These transmission members comprise levers 70, 71 and 69, which have two arms and which are pivotably arranged at the hinges of the links 8m and 14m relative to each other and relative to the carrier 28m and the second element 2m about axes parallel with the hinges of the links. A pair of link arms 72 extend between these levers so that pivoting of the lever denoted 70 by means of the axis 10m gives rise to pivoting of the lever 69 by means of the link arms 72 and the intermediate lever 71. This pivoting of the lever 69 is used to pivot, for instance, a working member placed on the element 2m. It appears from Fig 26 that the link arms 72 suitably are located on either sides of the respective link 8m and 14m and that the lever 70 is formed by two lever parts 70a and 70b connected to the axis 10m and secured against rotation relative thereto.

The links 8m, 14m from the embodiment according to Figs 20 and 21 are again illustrated in Fig 27. In this embodiment the transmission members comprise diverting members 73-75 arranged at the hinges of the links and being rotatably arranged about axes parallel to the hinge axes of the links. About these diverting members two endless loops of traction force transmitting elements 76 and 77 respectively are laid. It is illustrated in Fig 28 that double diverting members are arranged at the hinge axis between the links 8m and 14m, one of these diverting members being in engagement with one 76 of the traction force transmitting elements and the other with the other 77. By causing the rotatable diverting member 73 at the carrier 28m to rotate, the rotating motion is transferred, via the element 76 and the central diverting members 74, to the second element loop 77 and the outermost diverting member 75. The axis of the latter obtains a rotational movement which may be used, for instance for rotating a working member or executing some other task.

Both variants according to Figs 25-28 involves the advantage that the movement is transmitted to the extreme end of the four-hinges system FS2 from drive motors provided on the carrier 28m, which means a minimum amount of load on the most extended parts of the robot.

Fig 29 illustrates an embodiment which in essential regards is similar to the one in Fig 19. However, the four-hinges system FS4, which is pivotably movable in the XY-plane, is conceived to be pivotable under the influence of a drive member 52q arranged on the element 2q. The embodiment according to Fig 29 is illustrated from below in Fig 30. A counter weight 50q balances the weight of the working member.

A fourth four-hinges system FS4 secured to the element 2r so as to be pivotable relative thereto in the plane YZ is illustrated in Fig 31. Also here a drive member 52r is illustrated as arranged on the element 2r. The orientation of FS4 in Fig 31 means the it becomes pivotable in planes perpendicular to planes, in which FSl and FS2 are present.

Instead of arranging drive members on the element 2 as shown in Figs 29-32, the drive principle, which has already been illustrated in Fig 19, with respect to FS4 may be applied so that the drive member is located on the element lq and lr respectively.

It is illustrated in Fig 33 that two fourth four-hinges systems FS4 are coupled to a second element 2s in parallel. Each of these four-hinges systems FS4 carries a respective working member. The two four-hinges systems are mechanically coupled to each other for common movement as clarified at 78. In order to pivot the four-hinges systems, a drive member 52s may be arranged on the element 2s or, alterna¬ tively, the drive mode illustrated in Fig 19 or 25-28 may be used. The embodiment according to Fig 33 is suitable for a rapid parallel handling of two objects by means of the two working members.

Fig 34 illustrates an embodiment corresponding to the one shown in Fig 22 with exception of the link arm 21t being at¬ tached to the link 14t. The drive member 18t may be arranged to pivot its associated arm 22t and the link arm 21t in either the XZ-plane or the XY-plane.

The embodiment according to Fig 35 corresponds to the one illustrated in Fig 34 with the exception of the angle between the links 13Au and 13Bu having been modified rela- tive to Fig 34. Generally speaking, the angle in question may vary from 0 to 360°.

Fig 36 illustrates very diagrammatically four-hinges systems FSl, FS2 and FS4, where the four-hinges systems FSl and FS2 are conceived to be pivotable in the XZ-plane whereas the four-hinges system FS4 is conceived to be pivotable in the XY-plane. Fig 36 illustrates that FSl may be laterally stabilized by means of a four-hinges system FSA located in a plane perpendicular to the plane of FSl. FSl may bear laterally relative to FSA by means of a support 80 hingedly connected to FSA at 79. The four-hinges system FS2 is stabilized laterally by means of a four-hinges system FSB extending perpendicularly to FS2.

The four-hinges systems FS2 and FS4 are pivotable by means of separate drive members and link arms.

Fig 37 illustrates in a "false" perspective that a robot structure similar to the one in Fig 4 may be stabilized perpendicularly to the plane XZ of the pivoting movement of the four-hinges systems FSl and FS2 by being provided with auxiliary link arms 81 substantially parallel to the links 9v and 15v but moved in parallelism relative thereto in the direction of the Y-axis. Link arms 82 extend between the links 81 and the links 9v and 15v. These link arms 82 extend, accordingly, in the Y-axis. Support rods 83 are connected to the link 13v and the element 2v and support the four-hinges systems FSl and FS2 against the link arms 82 via hinge connections between the latter and the support rods 83.

It is illustrated diagrammatically in Fig 38 that a four- hinges system FSl pivotable in the XZ-plane is coupled in series with a second four-hinges system FS2, the latter four-hinges system being intended to pivot in the Y-direc- tion, possibly somewhat oblique to the Y-axis, as indicated in Fig 38 or otherwise parallel to the Y-direction„ The

four-hinges systems FSl and FS2 are stabilized laterally by means of extra link arms 84 which via cross bars 85 connect the link arms 84 to FSl and FS2 respectively. As can be seen from Fig 38, the link arms 84 may extend obliquely relative to the planes of FSl and FS2 so that rhombic structures, when viewing in the plane of FSl and FS2 respectively, are obtained in order to additionally increase the rigidity perpendicularly to the planes of FSl and FS2 respectively.

Fig 39 illustrates a variant substantially corresponding to Fig 36 with exception of lateral stabilization not being il¬ lustrated in Fig 39. Thus, FSl provides for movement along the Z-axis whereas FS2 provides for freedom of movement in X-direction. Finally, FS4 is conceived to provide for freedom of movement in Y-direction either by pivoting in the plane YZ or in the plane XY. The same four-hinges system structure as in Fig 39 is illustrated in Fig 40 in a some¬ what different position.

Fig 41 illustrates that two sets 86 of straightly series coupled parallelograms each comprising FSl and FS2 are coupled to pivot in planes substantially perpendicular to each other. Each of the sets comprises first and second elements lx and 2x. The first elements lx are pivotably connected to a base member 27x, which in the example has substantially L-shape, about respective pivot axes 87, which extend substantially perpendicularly to each other and in parallel with the respective pivoting planes of the sets 86. A carrying arrangement 38x is hingedly connected to the two second elements 2x about substantially perpendicular axes 88, which are substantially parallel to the pivot axis 87 between the first elements lx and the base member 27x.

On each of the first elements lx there is arranged a respec- tive first power exerting member 12x to pivot one of the links 9x, which are connected to said first element and

which are comprised in the respective parallelogram sets. A second power exerting member 18x is arranged on one of the first elements lx to pivot an arm 22x relative thereto. To this arm a link arm 21x is connected, said link arm being pivotably connected to the second element 2x. Said arm 22x and the link arm 21x are pivotable substantially parallel to the associated parallelogram set 86.

By operating the power members 12x and 18x, the carrying ar- rangement 38, which carries a working member 7x, may now be operated in space as desired in three dimensions. All hinges and pivoting axes described only need to comprise one degree of freedom, i.e. a pure possibility for pivoting, and should be prevented from movement as far as further degrees of freedom are concerned.

The carrying arrangement 38x and the working member 7x may be positioned in space as needed by operating the power mem¬ bers 12x and 18x. The parallelogram sets 86 define the orientation, i.e. inclination in space, of the carrying arrangement 38x and maintains this inclination constant all over the area of movement whereas the arm 22x and link 21x only participate for producing the required operation of the carrying arrangement 38x in space. Thus, it is in total three pivoting axles which in the embodiment according to Fig 41 achieve the required pattern of movement.

In fig 42 a modification is illustrated, in which the power members 12x, 18x, the arm 22x and the link arm 21x have been removed and instead three additional link arm arrangements 89 with associated drive members 90 have been provided to control the movement of the carrying arrangement 38x in space. The drive members 90 are suitably located on the base member 27x. The parallelogram sets 86 control, also here, the orientation as far as constant inclination of the carrying arrangement 38x is concerned.

In Fig 43 there is illustrated highly diagrammatically a view of an alternative to the embodiment according to Fig 41. Also in this case there are two sets 86y of parallelo- grams coupled in series but here these parallelograms FSl and FS2 in each set are angled mutually, which is indicated by the angle α.

The base member 27y is connected to the first elements ly of the parallelogram structures via hinges 87y extending perpendicularly relative to each other and more specifically in X-direction and Z-direction respectively. The carrying arrangement 38y is coupled to the second element 2y via hinges 88y parallel to the respective hinges 87y. The four- hinges systems FSl are pivotable in the respective planes of pivoting by means of power exerting drive members 12y. In addition, there is a drive member 18y, which via a link arm

21y connected to one of the four-hinges systems FS2 to pivot the same.

A somewhat varied position of the device illustrated in Fig 43 is illustrated in Fig 44 for the sake of clarity.

Fig 45 illustrates an embodiment already shown in Fig 35, the four-hinges systems FSl and FS2 in Fig 45 having been, in addition, doubled in Y-direction and provided with braces extending in Y-direction in order to reinforce the paral¬ lelogram assembly to loads in Y-direction. As appears from Fig 45, the double structure in Y-direction may be such that the parallelogram structures viewed perpendicularly to their hinge axes obtain rhombic configurations tapering in a di¬ rection outwardly to the extreme end of the device. Further¬ more, it is indicated in Fig 45 that further stabilizing measures, for instance diagonal braces 91, may be added to establish the required stability, in fig 46 it is illus¬ trated for the sake of clarity a somewhat adjusted position,

in which the four-hinges system FS2 has been pivoted for¬ wardly relative to the position in Fig 45.

Figs 47 and 48 illustrate an embodiment where measures have been taken to adjust the second element 2z into different positions of inclination. For this purpose the first element lz is formed by two parts IzA and IzB, which are hingedly connected to each other. The part IzB forms, as appears from Fig 48, a link in the four-links systems FSl. The part IzA operates primarily as a carrier for the robot structure. The power exerting member 12z already mentioned has a stationary portion rigidly connected to the element part IzA and a movable portion connected to the link 9z. A fourth power ex¬ erting member is denoted 25z and has a stationary portion rigidly connected to the element part IzA and a movable portion connected to the element part IzB.

When ordinary operation according to Fig 47 is intended, the movable portion of the power member 25z is blocked so that the link forming element part IzB permanently is held in the position according to Fig 47. Operation by means of a power member 12z gives, as before, rise to pivoting of the link 9z and, accordingly, pivoting of the parallel link 8z, as a consequence of which the orientation of the second element 2z in parallelism with the link IzB is maintained. When, on the other hand, tilting or inclination of the element 2z is required, the power member 25z is operated such that the link IzB is pivoted relative to IzA and 9z. This gives rise to a corresponding pivoting of the element 2z as a conse- quence of the parallelogram structure.

Fig 51 illustrates that a transmission arrangement for power transmission from a drive member 92 on the first element 1 to a driven member, for instance a working member 7, on the second element 2 comprises axles 93 extending substantially parallel to the links in the parallelogram shaped first and

second four-hinges systems FSl and FS2, said axles being in¬ terconnected by means of at least one cardan joint 94 and connected to the driving member 92 and the driven member 87 via further cardan joints 95. In order to divide the bending angle in the cardan joint transmission between the axles 93 into two parts, the link 13 in Fig 1 is designed so as to involve a parallel spacing of the four-hinges systems FSl and FS2 from each other, the previously mentioned cardan joints 94 and between the same an axle section 96 being present in the border zone between the four-hinges systems and the link 13, which can be considered as a rigid element. Thus, a rotational or pivoting movement may be safely transferred along the parallelogram assembly without need for any splines coupling or similar providing relative displacement, as a consequence of the fact that the axle 93 will be moved in parallelism in correspondence to the links in the parallelogram systems FSl and FS2.

The transmission arrangement is in Fig 51 illustrated as ad- justed for a straight series coupling of parallelogram systems. Fig 52 illustrates parallelogram systems FSl and FS2 being coupled to each other in an angled, in the example a right angled, relation by rigid interconnection of the links 13a and 13b. As in the preceding embodiment, axles 93 and cardan joints 94 are used for power transmission along the parallelogram systems FSl and FS2. In order to bridge the angular displacement between the parallelogram systems FSl and FS2, i.e. the angle between the links 13a and 13b, it is, however, suggested in Fig 52 to resort to an angular gear 97 based on conical gear wheels. Thus, axle pieces 96 are coupled to the axles 93 via the cardan joints 94, said axle pieces 96 supporting the conical gear wheels at their ends turned away from the cardan joints 94.

Fig 53 illustrates an embodiment which can be said to be a modification of the one illustrated in Fig 23, features in

addition having been collected from the embodiment diagram¬ matically illustrated in Fig 20. As can be seen in Fig 53, the first part la which forms a carrier 28a, is rotatably movable relative to a base member 27a by means of a third power exerting member 26a. A first power exerting member 12a is adapted to cause the links 9a and 8a to pivot relative to the carrier 28a. The second power exerting member 18a serves for bringing the links 14a and 15a in the second four-hinges system FS2 to pivot. The power member 18a comprises a stationary portion rigidly connected to the carrier 28a and a movable portion 22a connected to the four-hinges system FS2 via a link arm 21a.

The first element la is formed by two parts laA and laB, which are hingedly connected to each other.

A power exerting member 25a is adapted to pivot the part laB relative to the second part laA. This first part laB forms a constituent of the first four-hinges system FSl in that it is hingedly connected to the two links 8a, 9a. The power member 12a is adapted to pivot the link 9a relative to part laA whereas the link laB is held stationary by means of the power member 25a. The four-hinges system FSl is changed as to its form with a constant orientation in space of the second element 2a. For this purpose, the power member 12a is provided with a stationary portion rigidly connected to the part laA whereas a movable portion of the power member is rigidly connected to the link 9a.

While keeping the link 9a stationary by means of the power member 12a, the power member 25a may be driven to pivot the part laB relative to part laA. Such pivoting changes the form of the four-hinges system FSl so that the inclination of the second element 2a is changed to a desired degree. Also the power member 25 a has a stationary portion rigidly connected to the part laA whereas a movable portion of the

power member is rigidly connected to the part laB. The power members 12a, 25a and 18a are in the example all rotor means of a type previously described.

Fig 54 illustrates an embodiment similar to the embodiment according to Fig 24 but modified relative thereto. As in the preceding embodiment, the first element la comprises two parts ISA and laB hingedly connected to each other. The hinge axis between the same is substantially parallel to the hinge axes in the two four-hinges systems FSl and FS2. A power member 26a serves for pivoting the part laA relative to a base member 27a. A part laB of the first element, said part forming a link in the four-hinges system FSl, is hingedly connected to the link 9a via a hinge 105 and forms a lever with two arms projecting outwardly from this hinge. A power member 25a acts via a link arrangement 106 on one of the arms of the lever, so that the part laB may be pivoted relative to the part laA. Such pivoting changes the inclina¬ tion of the second element 2a in space. In the example it is illustrated that the power member 25a has a stationary portion rigidly connected to the base member 27a and a movable arm like portion 107, which via a link 108 acts on the just mentioned two-arms lever. Since the part laA of the first element is pivotable by means of the power member 26a relative to the base member 27a, the link arrangement 106, which may comprise one or more links, must comprise at least two hinges, for instance ball joints, having at least two degrees of freedom.

The power member 12a acts on the link 9a in the four-hinges system FSl via a link arrangement 102. More specifically, the link 9a is designed as a lever having two arms and being hingedly connected to the part laB about the hinge axis 105. The power member 12a acts on one of the arms of the lever via a link arrangement 102 in order to change the form of the four-hinges system FSl whereas the inclination of the

second element 2a is maintained unchanged, this, however, presupposing that the part 1SB at the same time is not pivoted relative to the part laA. Also the power member 12a has a stationary portion rigidly connected to the base member 27a and a movable portion which via the link arrange¬ ment 102 acts on the link 9a. More specifically, the movable portion has the character of an arm 103, which via a link arm 104 coupled thereto and to the link 9a by means of hinges having at least two degrees of freedom transfers operating forces.

In this case the power member 18a is effective for pivoting the links contained in the four-hinges system FS2 via a somewhat more complex link arrangement 98. This comprises, as before, a link arm 21a connected to the second four- hinges system FS2 but here there are between this link arm 21a and a movable portion 22a of the power member 18a two further links 99, 100, the link 99 of which has the charac¬ ter of a lever with two arms and is hingedly connected to the first four-hinges system FSl via an axis 101, whereas one of the arms in the lever is hingedly connected to link arm 21a while the other is connected to the link 100. This link is in its turn connected to the arm like movable portion 22a of the power member 18a. Since the power member 18a has its stationary portion rigidly connected to the base member 27a, hinge connections having at least two degrees of freedom are required in the link arrangement 98. These link connections are, in the example, present between the link 100 and lever 99 and between the link 100 and the movable portion 22a of the power member 18a.

Fig 55 illustrates an embodiment somewhat similar to the one in Fig 41. Two four-hinges systems FSl and FS2 are coupled in series between first and second elements lo and 26. A power member 125 serves for changing the form of the four- hinges system FSl whereas a power member 185 is arranged on

the first element 16 and acts on the second element via a link arm 216 for changing the form of the four-hinges system FS2. The first element 16 is pivotably connected to the base member 276 about a first pivot axis 108. A power exerting member 109 is arranged to pivot the first element 16 and, accordingly, the first and second four-hinges systems FSl and FS2 and the second element 26 about the pivot axis 108. This power exerting member comprises, in the example, a stationary portion rigidly connected to the base member 276 and a movable portion 112 acting on the second element 26 via a link arm 113. The movable portion 112 of the power member has, preferably, an arm like character. The link arm 113 is connected to the arm 112 and the second element 26 via hinges having at least two degrees of freedom. The power exerting member 109 is arranged to pivot the first element 16 in a plane of pivoting extending at an angle, preferably a substantially right angle, to planes, in which the four- hinges systems FSl and FS2 pivot.

A carrying arrangement 110 is pivotably connected to the element 26 about a second pivot axis 111. This is preferably directed substantially parallel to the first pivot axis 108. A power exerting member 114 is adapted to pivot the carrying arrangement 110 about the pivot axis 111. This power exert- ing member 114 has, suitably, a stationary portion rigidly connected to the base member 276 and a movable portion 115, which via a link arrangement 116 acts on the carrying arrangement 110 for pivoting the same. The link arrangement 116 must comprise at least two hinge connections having at least two degrees of freedom. A working member 76 is con¬ nected to the carrying arrangement 110. In order to main¬ tain a certain given orientation of the carrying arrangement 110 in space, the power members 109 and 114 should, via a suitable computer, be controlled such relative to each other that when the elements 16 and 26 are pivoted about the axis 108 in a certain direction by means of the power member 109,

the carrying arrangement 110 should be pivoted to the same degree but in the opposite direction about the axis 111 by means of the power member 114.

Common to all described embodiments is that a suitable control unit, in particular in the form of a computer, is arranged to control the power exerting members of the various robot embodiments for the purpose of causing the second element 2 or members coupled directly or indirectly thereto to move in desired paths.

POSSIBLE MODIFICATIONS

It is evident that the embodiments of the invention given hereinabove are to be considered as isolated examples, which in several ways may be modified within the scope of the invention as defined in the enclosed claims. Generally speaking, it is pointed out that also other embodiments of series coupling of four hinges systems than those exempli- fied may be used within the framework of the invention and also the number of four-hinges systems coupled in series may be modified according to what is desired in the individual case.

It is pointed out that the variant illustrated in Fig 42 with power exerting members 90 and link arms 89 for opera¬ tion of the carrying member 38x is also applicable in the embodiment described with assistance of Fig 43, in which case the power members denoted 12y and 18y are deleted and instead three link arms 89 are connected hingedly to the carrying member 38y and these link arms are arranged to be actuated by the power exerting members 90 provided on the base member 27y. The members 90 are adapted to pivot the links 89 in non-parallel planes.

With respect to the various transmission arrangements having been described with assistance of a.o. Figs 16- 18, 25-28 and 50-51, it is remarked that they, of course, may be "prolonged" in an analogous manner in more complex link arm structures.

A four-hinges system FS4 such as that in Fig 19 could also be used in the embodiments according to Figs 22-24 and 53-54 in an analogous manner.