DE3839091B4 - Linear motion device - Google Patents

Abstract

Linear motion device,
a) in which a carriage (30) is movable back and forth along a straight line,
b) in which the carriage (30) on outer surfaces (1.1) of a stationary base body (1), this encompassing, is guided,
c) and wherein for guiding the carriage, two parallel steel cylinders (121, 122) are provided on the outside of the base body, which have a common center plane (130)
d ₁ ) in which the guidance of the carriage (30) by means of rollers which are spatially distributed in the carriage happens
d ₂ ) and wherein three rollers are distributed in the longitudinal direction of a steel cylinder in the direction of movement, that one roller (132) between the other two (131, 133) sits,
e ₁ ) and that only three cylindrical rollers (131, 132, 133) integrated in the carriage are guided on each steel cylinder,
e ₂ ) arranged on each of the steel cylinders (121, 122) in the same way, running on either side of the median plane (130),
f ₁ ) and whereby by ...

Description

The The invention relates to a linear motion device, wherein a Sled along a straight line is movable back and forth, and at the carriage on outer surfaces of a rod-shaped Body, embracing this, led is, and being to the leadership of Sliding two parallel steel cylinders with a common center plane Outside provided on the base body are.

The known solution according to DE-OS 3816601 (E1), which enables a compact "linear rod", enough but in their accuracy in terms of long-term, exact position of the sled not extreme requirements. For many applications is also moderate production costs in great demand.

From DE-PS 33 36 496 (E2) a linear motion device is known in which high precision is achieved with enormous effort, if, as in the representative there 6 rolling on three sides 20 . 20a are provided, with each roller so a tensioning roller, which also on an eccentric 24 to store is to come, so that so the surfaces are on stop on the rolling cylinder surfaces.

DE-GM 84 31 504 (E3) shows a guide roller carrier with a slidable on a carriage support member, with a 2-point support for rollers and a third counterpoint, wherein via an arm by means of an eccentric a third roller applied to stop and fixed becomes, so that a "three-point situation" exists. In addition, this utility model teaches only an alternative use of the guide roller carrier according to 1 or 2 , Although the force directions governed there are in a plane (defined by the "three-point position"), which is advantageous over the prior art mentioned there, but by no means does justice to arbitrary (spatial) force application effects.

The US-PS 3436 132 (E4) shows a linear guide which is in its carriage Hemispherical shells for linear movement on two steel cylinders on outer surfaces of a rod-shaped the body having. This solution is less accurate, at least long term.

From US-PS 3,998,497 (E5), an arrangement without basic body is known in which two stationary steel bars 100 a kind of roller with double rollers is moved linearly. On both steel bars 100 each two double rollers carry the trolley. These have four drain points on each bar, so the counter-bearing for the counter-roll must also be 124 be arranged very accurately for backlash between roles and staff.

Here So there are at least five Running points on the steel bar in front.

present The invention is therefore based on the object for an initially described Device to obtain a compact, play-free longitudinal storage, the long-term accurate and inexpensive, and the usual for the inclusion of automation technology forces any spatial direction is stable on the carriage.

These Task is solved with the entirety of the means of claim 1.

The under claims concern further embodiments.

The Drawings show to scale:

1 and 2 two known profiles which are useful in the present invention.

The 3 - 5 show an embodiment of the inven tion, partly in section, as far as necessary for understanding, but in 0.8 times the size

3 a partial section through the middle of a carriage,

4 a longitudinal section perpendicular to the section according to 3 also through the middle of the sled,

5 the extended plan view of a partially opened arrangement according to 3 and 4 :

6 . 7 . 8th show parts of the support body of the carriage in natural size to measure in three views or sections; or cut part.

slice or views are indicated by arrows with Roman numerals, in such a way that the relevant Roman Number corresponding to the figure with the same Arabic numeral.

1 / 2 show suitable profiles for the invention, 2 However, one shows in relation to in 1 often better suitable profile, since it is used as a vertical support; has greater bending and torsional rigidity. In 2 is a designed as extruded aluminum section bar with rectangular cross-section body 1 shown whose profile in its outer dimension by the broadsides 11 . 13 and the narrow sides 12 . 14 is determined. In the middle of each side is a groove 6 . 7 . 8th . 9 that are inside in a cavity 2 . 3 . 4 . 5 after a certain groove depth 15 . 16 widened. These extensions 2 to 5 in the rod form a continuous recess, which is much wider than the continuous grooves 6 to 9 in the side centers. These recesses are rectangular or semicircular or oval etc.

The Exterior surfaces of the Profilstabes are preferably for better lubricity anodized or other measures for one smooth surface on. Furthermore should this surface for a minimal Friction coefficients be hard plastic.

The extruded profile rod is now used in any length, for example 30 or 200 or 300 cm) as the main body 1 for a linear position bar. Above and below the groove 6 glides in a horizontally lying conveyor belt 19 with reciprocating parts 17 . 18 , It will be at the ends of the rod over the same pulleys 51 and same supporting roles 52 deflected and brought by the latter in such a position that it is on the surface 11 on both sides of the groove 6 slides in the longitudinal direction and in the underlying cavity 2 runs back. The height position of the band parts 17 . 18 is determined by the position of the diverting and supporting role.

The conveyor belt 19 on the broadside 11 slides, is on a, generally U-shaped profiled, rail-like slide 30 attached symmetrically to the inside, which is on the broad side 11 moving along it at a small distance of a few millimeters, but embracing the staff on its narrow sides 12 . 14 to be led. This sled 30 forms on its closed outer surface of the U itself a worktop 33 or has there additionally one with a base plate 35 screwed worktop 33 on, on the other elements can be attached. It is important that this worktop can be moved very easily along the bar to any point and so gradually takes specific, accurate positions. For this purpose, the further outer deflection roll 51 , each designed as a stepper motor electric motor for driving. For short distances, it may be sufficient to have a drive on one roller at one end of the rod.

The base plate is square or rectangular with two to the center line 100 symmetrically lying slots 77 . 78 in the the ends of the band 19 be threaded. The base plate has rounded inlets 75 . 76 ' over which the tape is fed. A wedge-shaped or cone-shaped clamping piece 74 is by counter screws 73 so drawn against these curves that the ends of the band 19 thus be clamped in the base plate. The tension is measured and adjusted at the belt ends during assembly, and at this particular tension, the counter screw becomes 73 tightened so that they are the wedge or cone piece 74 against the curves 75 . 76 stuck. Thus, the tape is detected for a certain longitudinal tension and at the same time is the base plate 35 and with it the whole sledge 30 with the circulating conveyor belt 19 firmly connected, so that it is inevitably transported with the tape movement.

In the middle area, ie approximately on both sides of the section plane III-III, are fastening screws 185 the the base plate 35 and the worktop 33 firmly connect with each other.

3 shows the two steel cylinders 121 . 122 , which are practically formed as hard waves of the same diameter.

While to the left cylinder 121 three ball-bearing castors 131 . 132 . 133 belong is on the right cylinder 122 a variant indicated which does not fall under the present claims. The execution as left is in the present invention also in the right cylinder 122 intended.

The cylinders are made by rhombus nuts 111 , their screws 112 are completely embedded in these steel cylinder transversely, at the end of the grooves 3 and 5 fastened from the inside and so partially embedded in the grooves. On the steel cylinders 121 . 122 each run the three rollers 131 to 133 , Through their geometric axes goes a common median plane 130 , and on both sides of this median plane left and right each BEZW. two rollers, which are simply designed in the present embodiment as a ball bearing whose solid inner rings via pins 181 . 182 . 183 in the thighs 36 and 37 the slide carrier are held.

These three rollers per steel cylinder on both sides of the median plane, are distributed in the direction of movement that the one roll 132 for force balancing between the other two rollers 131 . 133 , and conveniently below, sits. This arrangement results in an excellent stable and, above all, in terms of assembly cost option, since this three-point support with the roll-off points 171 . 172 . 173 does not have to have a game.

In addition, a long-term high Präzisionspositian is guaranteed for the slide, so that it may possibly even perform work that previously did not seem possible. The thigh 36 . 37 are firmly on the support plate over their length between any two of the three rollers 35 screwed ( 151 ), and this is your side with the worktop 33 screwed.

The parts 35 . 36 . 37 and 33 can screw holes for high-precision dowels in the bolted state 153 obtained, so that the mounting plate and the support body 35 to 37 have an exact position to each other after assembly. Between the plane 130 and the rotation planes e ₁ , e _{2 of} the rollers are the angles ε ₁ , ε2 drawn, which are generally symmetrical to the plane 130 lie, ie ε ₁ = ε ₂ and the axes of the steel cylinder cut to length. The roll angle ε ₁ , ε ₂ can be designed, for example, with a large weight load on the tool carrier, so that the angle to the tool carrier becomes greater, ie ε ₁ > ε ₂ . Conveniently, the two outer ball bearings are rollers 131 . 132 to provide on the side to the workpiece carrier, and the lower third counter-roller 132 would then only for more precise guidance, provided without much burden. (In general, as in the embodiment of the 3 , a symmetrical arrangement of the roll angle (ε ₁ = ε ₂ ) to the plane 130 suffice.) The profile body has a groove here 2 in which the tape is running. About her is for the returning tape no recess in the profile, but a recess 119 in the support plate 35 ,

The whole linear motion is thus performed on three Laufröllen (via ball bearings), with sufficient parallelism of the steel cylinder takes place a smooth, highly accurate guidance. The parallelism of the two steel cylinders, which are at least partially embedded in opposite grooves of the profiled body, but there allows automatic. such a degree of parallelism as it has the accuracy of the body just. Due to the fact that the whole Schlit unrolls on the steel cylinders, the tape can top in the small recess 119 of the sled 30 find room, so that the necessary clearance between the base profile and the support body 35 to 37 can be made small.

The fastening bolts 181 . 182 . 183 in the thighs 36 and 37 have fixed inner rings for the rollers.

When very long rods are needed, it is advantageous to use a toothed belt as the conveyor belt whose teeth are narrower than the band and thus only in the middle of the band on its inside in the groove 6 slide, giving the tape an additional guide. The toothing itself serves for more exact positioning or to avoid slippage and unnecessary friction.

The Pulleys are mounted in units at the ends of the rod and encapsulated. Coaxial drive shafts protrude perpendicular to the orbital plane out of these capsules on which motors can be placed. The Control of the belt drive and stepper motor takes place in the usual way Wise.

In the Umlenkschalen that have plug-in mounting positive projections for cavities of the bar profile and form the capsule or a deflection box with the cover are centrally symmetrically arranged recesses with stepped floors and a wall and side blocks 96 and a cover available. The pulley 51 and the supporting role 52 are in linear direction in bearings that are in the blocks 96 are each arranged, distanced, wherein the deflection roller on the drive side still has an additional recess, wherein a drive shaft runs.

If the conveyor belt 19 has an internal toothing, the deflection roller 51 because of the arranged on its circumference teeth in diameter slightly larger, while the pulley 52 can be reduced in diameter. To the conveyor belt 19 to run with a curvature as small as possible, the radius of the pulley should 51 and the radius of the minor role 52 together with the distance of their axes perpendicular to the tape transport plane about the height of the groove 6 comply with the necessary safety distances because of streaks, etc. must be observed. Likewise, the pulley should 51 including the circulating band 19 except for the necessary clearances against the rear wall 99 the shell are brought close, and the supporting role 52 should be from the frontal ends of the main body 1 keep a small distance.

The above-mentioned distance of the axle centers from 51 and 52 is by the distance of the outer surface 11 to the cavity 2 in the rod-shaped body 1 certainly.

If the conveyor belt 19 By its nature, a particularly large curvature endurance for life, the centers of the pulley 51 and the supporting role 52 be moved towards each other in the bar direction, because then a larger wrap angle of the belt on the pulley 51 gives and thus the slip resistance of the belt on the pulley 51 is increased, which may be particularly advantageous if no internal toothing is provided there.

Claims (12)

Linear motion device, a) in which a carriage ( 30 ) is movable back and forth along a straight line, b) in which the carriage ( 30 ) on external surfaces ( 1.1 ) of a stationary body ( 1 ), this encompassing, guided, c) and wherein for guiding the carriage two parallel steel cylinder ( 121 . 122 ) are provided on the outside of the main body, which have a common center plane ( 130 ) d ₁ ) in which the guidance of the carriage ( 30 ) by means of rollers which are spatially distributed in the carriage, d _{2 occurs} ) and wherein three rollers in the longitudinal direction of a Steel cylinder are distributed in the direction of movement, that the one roll ( 132 ) between the other two ( 131 . 133 ), e ₁ ) and that in each case only three cylindrical rollers integrated in the carriage ( 131 . 132 . 133 ) are guided on each steel cylinder, e ₂ ) on each of the steel cylinders ( 121 . 122 ) are arranged in the same way, on both sides of the median plane ( 130 running), f ₁ ) and whereby by two rotation planes (e1, e2) of the three rollers ( 131 . 132 . 133 ) with the median plane ( 130 ) on both sides of the median plane two angles (roll angle ε ₁ , ε ₂ ) are formed; by a rotation plane (e1) of two rollers ( 131 . 133 ) at an angle (ε ₁ ) to the median plane ( 130 ), and the other rotation plane (e2) of the third roller ( 132 ) with the median plane ( 130 ) the other angle (ε ₂ ) forms f ₂ ) And wherein the one angle (ε ₁ ) to the tool carrier (slide 30 ) is greater than or equal to the other angle (ε ₂ ). Linear movement device according to claim 1, characterized in that the basic body ( 1 ) of rectangular or square outer contour and folding symmetrical profile is formed as extruded aluminum rod and the steel cylinder in outer surfaces, are embedded in grooves of the profile. Linear movement device according to claim 1 or 2, characterized in that the rotation planes (e ₁ , e ₂ ) rollers ( 131 . 132 . 133 ) through the geometric axis of each steel cylinder and with their fixed axes supported on the carriage. Linear motion device according to one of the preceding Claims, characterized in that each roller a. Having ball bearings, the above its inner ring is held on a fixed axle. Linear movement device according to one of the preceding claims, characterized in that the carriage ( 30 ) has a supporting body in a form encompassing the profile of the body, in particular in the form of a U-shaped profiled rail, wherein the outer surfaces of the U-rail ( 35 . 36 . 37 ) directly or via additional worktops ( 33 ) indirectly, for mounting external work elements. Linear movement device, according to one of claims 1 to 5, characterized in that - at the ends of the rod-shaped base body 1 a flat conveyor belt ( 19 ) via stationary deflection rollers ( 51 ) is deflected so that it is moved in opposite directions in two parallel planes, - and the conveyor belt at its two ends with the carriage 30 is firmly connected. Linear movement device according to one of claims 1 to 6, characterized in that the limbs ( 36 . 37 ) of the U-rail inside each carrying three rollers, which run as possible in a form-fitting manner in opposite grooves of the narrow sides of the body dipping steel cylinders. Linear movement device according to one of the preceding claims, characterized in that in the U-rail of the carriage the strip-shaped legs ( 36 . 37 ) with the base plate ( 35 ) are screwed in the longitudinal direction so that one screw is provided between each pair of rollers. Linear movement device according to claim 8, characterized in that fitting pins ( 153 ) Base plate ( 35 ) with her thighs ( 36 . 37 ) and with the worktop ( 33 ) in their position to each other. Linear movement device according to one of the preceding claims, characterized in that in the basic body ( 1 ) in the middle of a linear motion unit (Pneumatikhubzylinder) for driving the carriage ( 30 ) is provided, wherein the deflected at the ends of the main body conveyor belt ( 19 ) which is guided by a respective seal at each axial end of the linear motion unit, is connected to the Arbeitshubelement the linear motion unit on both sides for bidirectional tensile forces. Linear motion device according to one of the preceding Claims, characterized in that the Carriage on perpendicular to each other side surfaces of the the body guided becomes. Linear motion device according to one of the preceding Claims, characterized in that the Steel cylinder in grooves of the basic body through rhombus slotted stones are attached by the associated Screws are completely embedded in the steel cylinder.