DE209361C - - Google Patents

Description

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IMPERIAL

PATENT OFFICE.

PATENT LETTERING

- M 209360-CLASS 42 a. GROUP

HERMAN KÜHNER in STUTTGART.

The subject of this invention is a drawing machine which, in addition to the previously known Cycloids draws especially cycloids according to any cyclic basic shape arrangement.

Fig. Ι represents a side view of the machine, set for drawing cycloids according to a hypocyclic basic shape arrangement.
Fig. 2 shows a top view.
On the machine itself, the dormant one

ίο circle represents the fixed bevel gear ι, while the pitch circle marks the bevel gear 2. The cyclic curve at rest is Objectively not visible, but is due to the shaft of the bevel gear 4 with each revolution marked on which cycloid the pitch circle in the form of the bevel gear 4 with attached Drawing organ 5 rolls, either in the same sense of the swing beam movement (Framing movement) by means of bevel gear 17, i.e. epicyclically, or in the opposite direction Sense through bevel gear 16, so hypocyclic.

The screw spindle 37 acts automatically and has the purpose of producing the cycloorthoids.

The intermediate gears 6, 7, 8, 9, 10, 12 are used to change the size ratio of the stationary and the rolling circle.

The drawing machine can also serve as a guilloché machine by serving as a drawing organ a steel or diamond pen is used, as well as a hatching machine by by the wheels 25 and 26 of the apparatus is gradually shifted laterally.

The drawing machine is with the exception of the spur gears 8, 9, 10 and their replacement gears composed of bevel gears, and the bevel gear 1 represents the stationary circle, the center of which is marked on the scale of the frame bars 35 and 36 with 0 mm, and bevel gear 2 is the pitch circle, likewise bevel gear 3 is a stationary and bevel gear 4 to be referred to as the rolling circle. The wheels ι and 3 are screwed immovably. Frame rod 36 and 38 and the upper parallel rod of the pen holder 5 each have one Measuring scale. Wheel 1 is fixed on block 11, which is between parallel bars 13 and 14 and is pushed or screwed sideways, by means of the on the rotary crank 32 attached wheel 25 and the wheel 26 with screw spindle drive 27. The parallel bars 13 and 14 together with the apparatus can be placed on cross bars in blocks 28, 29, 30, 31, which on four feet 18, 19, 20, 21 am Drafting table is screwed to rest, can be adjusted back and forth so that the machine can follow can be moved to all positions in the drawing field.

Likewise, through the four corner blocks 28, 29, 30, 31 fixed by means of screws, the whole apparatus can be adjusted up and down in height. The wheel axle 2 and the wheel axle 4 have a guide below. Axis 4 carries the pen holder 5, which is adjustable in it is.

All cycloids are divided into two main classes, those that arise.

if the rolling circle or rolling wheel moves in the same direction as its oscillating beam, on which it is stored, and since then have been called epicyclic, and in those who arise when the roller wheel is in the opposite sense and direction as its bearing moves and which were called hypocyclic.

The former movement is achieved through

ίο engagement of wheel 7 and the latter movement, ie hypocyclic cycloids, by engaging the wheel 6 for engagement and rolling up Wheel i.

Bevel gears 6 and 7 and spur gear 8 are fixed on the shaft, which is in bearings 46 and 47 by a screw fitted in the shaft groove in one way or another Position is determined so that soon wheel 6, soon wheel 7 rolls on wheel 1.

With the rotary crank 32, the main axis 43 with frame 44 and the one mounted on it Shaft 45 rotated while rolling bevel gear 6 or 7 and with it the Wheel 8 and thereby wheel 9, 10, 12 on the stationary wheel 1. Is the number of idler gears 7, 8, 9, 10, 12 odd, the roller wheel 2 rotates in the opposite direction to the frame 44, i.e. hypocyclic, and with an even number of intermediate gears 8, 9, 10, 12 the same Senses, i.e. epicyclic. The wheel size is usually from wheel 1: 2: 3: 4: 6: 7: 8: 9: 10: 12: 15: 16: 17:25: 26 = 3: 1.5: 2: 0.5: 1: 1: 1: 1: 1: 1: 1: 0.5: 0.5: 3: 1.

Wheel 8 and wheel 4 are interchangeable in any size and require the special Shape of the cycloids according to a special basic shape arrangement.

The center distance of the wheel 2 from the main center point (on the scale of the rod 36 visible) is equal to the distance between the center of the rolling circle and the center of the circle at rest, while the distance between the drawing organ 5 and the axis core 2 is the distance between the drawing organ from the center of the rolling circle.

When wheel 6 is set, in the desired case ' ¹ J ₂ ^ hypocycloids and, if wheel 8 is set to size η , ¹ In ^ hypocycloids are drawn here; when drawing epicycloids everything remains, only that wheel 7 is engaged and rolls off wheel 1.

A larger wheel 8 is inserted by moving the intermediate wheel 9 in the groove 41 of the plate 24, which is firmly connected to the frame 44, only so that Wheel 9 engages in wheel 8 and 10 at the same time; the same is done if gear 10 is larger is set to pericycloids.

The screw spindle 37 (which can be repeated in the spindle 40) is theirs Grooved lengthways (Fig. 2 at wheel 12) or milled lengthways on two sides, so that the gear 10 by means of adjusting screw (or bushing constriction on two sides) this Spindle without hindering its displacement and lengthwise screwing around able to turn itself. The nut 48 embraces the spindle and pushes it, as soon as the wheel 10 connected to the spindle rotates, outwards from the main center or back with reverse movement of the main axis 43.

The wheel 10 has a hollow one, the spindle 37 loosely encompassing axis in which the spindle 37 can shift but not rotate, because the set screw or a set nail of wheel 10 across into the groove of the spindle 37 is performed.

The axis is rotatable in the beam 44, but mounted so that it is not axially back and forth moves forward. The nut 48 is divided and can be opened by means of a hinge, in order to be able to switch it on at will for the automatic shifting of the axis 37. With each movement of the main axis 43, the spindle 37 is screwed to the axis 2 and connected drawing organ 5 with attached wheels. The cycloorthoids are created higher order by making the screw connection necessarily proportional to the rotation of the Axes 43 and 2 in addition to such going on.

Likewise, the screw spindle 27 screws proportionally and inevitably to the rotation of the Axes 43 and 2 without objection to the rest of the main movement, the apparatus straight sideways; this allows orthocycloids of a higher order to be drawn. So it can Hypocycloids and epicycloids are also drawn in a cycloorthoid or orthocycloid arrangement In addition, each cycloid can be aggressive due to the proportional screw connection, growing evenly.

The orthocycloids (the rolling of a circle on a straight line) are drawn by: the removable wheel 25 is screwed onto the axle 43 and by turning the crank 32 the whole apparatus through the screw spindle 27, which through the fixed Nut 42 goes, is screwed laterally. The circular lines, which with the drawing organ (used in place of the axis of wheel 2) are proportional by their Sideways dorsal orthocycloids. Depending on whether the crank is turned to the right or left, arise hypocyclic or epicyclic orthocycloids. Their shape depends on the size of the wheel 26, which is exchanged as large as desired, since the axis 43 upwards is extended. A very small wheel 26 has the effect of having a large circle on the Straight lines would roll, and vice versa for large ones. The lengthened and shortened ones

Curves are determined by adjusting the slide block 22 with a drawing organ.

The cycloorthoids (arithmetic spiral, the rolling of a straight line on a circle) are drawn in that shaft 37 as a screw spindle in engagement with the separable, screw nut 48 attached to the frame 44 is brought, and that during the turns of the crank the slide block 22 with drawing organ 5 screwed outwards in a spiral from the main center point will; depending on whether the crank is turned to the right or left, epi- or hypocyclic ones arise Cycloorthoids.

The pericycloids (cycle lines, rolling a larger circle around a smaller one Circle) are drawn after turning off the wheel 25 and the nut 48, by setting of wheel 10 in more than three times the size of wheel 8, and arise, depending on whether wheel 6 or 7 engages, epi- or hypocyclic. Pericycloids.

In the case of the cycloids mentioned above, the drawing organ is always from the wheel axle shaft 2 led or set in the extension of this axis.

Cycloids according to a special cyclic basic shape arrangement are drawn by first using the machine to draw the required basic shape, e.g. ^{B. Basic} ellipse shape ( ¹ Z ₂ part hypocycloid shape),. is set. Wheel 6 rolls on wheel 1, and wheels 8, 9, 10, 12, 6 are the same size, wheel 2 half the size of I. During the revolutions, wheel axle 2 of slide block 22 with frame 38 and 39 moves so that wheel axle 4 the elliptical trajectory runs through.

Determine the distance between the center of the circle and the distance between the drawing organ and the rolling circle the large and small ellipse radius. If you know the size of the ellipse, you have the following setting: Distance of the slide block .22 with axis shaft 2 from the main center and distance of the drawing

45- organs (shaft 4) from axis shaft 2 is equal to the large ellipse radius (in a straight line), while their difference in distance represents the small radius of the ellipse. To this elliptical path describes organ 5 by means of the rotations about wheel axis 4 Unrolling of the wheel 15 on a fixed wheel 3 cycloids; 16 or 17 depending on the wheel For the purpose of movement, epi- or hypocycloids are drawn in the basic shape of an ellipse.

The size is determined by the pen distance 5 from the wheel axle 4.

By engaging gear 7 with the same settings, the base forms are epicyclic arranged.

If wheel 10 is set in three times the size or larger, otherwise 'The same circular setting cycloids are drawn arranged according to the basic ■ cyclic shape.

In the case of a cycloorthoid basic form, the apparatus must first be set to cycloorthoids; the screw nut 48 is tightened around the screw spindle 37 (by means of Adjusting hook eyes or screw); this causes the axle of wheel 2 to turn when the crank is turned guided the spiral path, and around this spiral path describes the drawing organ 5, which is carried in the wheel axle 2, the cycloids in that wheel 2 is moved by wheel 12.

Depending on the gear ratio of the intermediate gears 8, 9, 10, gear 10 rotates more often with a turn of the crank and the wheel shaft 2 screws faster from the center or vice versa, and the different sizes arise.

The epi- and hypocyclic arrangement is regulated by adjusting the wheel 6 or 7. If the basic orthocycloidal shape is desired, the apparatus must first be closed as described Set orthocycloids. The drawing organ 5, which is guided in the axis of the moving wheel 2, drawn the cycloid, namely epicyclic or hypocyclic, depending on the indentation of gear 6 or 7, frame 38 falls and 39 with its wheels out of use.

Concentric curves or circles are drawn by indenting the slide block 22 with the wheel axle 2 directly below the main center of the axle 43, the circular radius is by means of the pen holder, the pin of the wheel axle 2 a distance equal to the desired radius. Cycloids in a concentric curve basic arrangement are drawn by placing the wheel axle 2 with the frame parts 38, 39, 15, i6, 17, 23 and the drawing element in the wheel axle 4 is set. When the crank is turned, the organ draws cycloids around the circular path, depending on the wheel 16 or 17 the wheel 4 moves, epicyclically or hypocyclically.

In general, the wheel size ratio becomes rational or the circumference of the wheels kept in proportion commensurable, so the figures close, in the case of irrational Relation arise the so-called progressive figures without end, for hatching suitable.

The subdivision of the periphery into any parts is done by setting to straight ones Ellipses. Should z. B. the circle would be divided into 20 parts and wheel 2 would be ten Provided teeth, so would be wheel 10 (or 12 as the same size) to set one tooth smaller; this would create ten diameter ellipses (straight lines), which divide the circle into 20 parts.

The screwed wheels ι and 3 can can be replaced by movable ones if they are driven by an intermediate gear from the movable ones Wheel 25 and 2 takes place.

All bevel gears are milled in at an angle, making them the greatest possible replacement is possible.

Claims (2)

Patent claims: I. Drawing apparatus for making cycloorthoids, especially higher order, characterized in that on one of the main shaft (43) set in rotation oscillating beam (44, 35, 36) a Screw spindle (37) with nut (48) is arranged, which is proportional and inevitable with the movement of the main axis of rotation (43) the drawing organ (5) without prejudice to the other cyclical movements in a cycloorthoidal manner shifts. 2. Drawing apparatus according to claim 1, characterized in that the vibrating beam with screw spindle (37) by means of another fixed screw spindle (27) in relation to the main movement determined by gears (26 and 25, 8 and 9) is inevitably shifted laterally in a known manner in order to obtain orthocycloids. 1 sheet of drawings. Berlin CedruCkt In the Reichsdruckerei.