DE402676C - Lathe for the production of bodies with an angular cross-section - Google Patents

Description

GERMAN EMPIRE

ISSUED
ON SEPTEMBER 20, 1924

REICH PATENT OFFICE

PATENT LETTERING

CLASS 49a GROUP

Ludvig Kamras in Budapest

Lathes are already known with which bodies of polygonal cross-section are turned can be. However, these banks have the disadvantage that with them with flat side surfaces limited body after a predetermined plan cannot be rotated. In contrast, forms the subject the invention a lathe, with which limited by flat side surfaces and a polygonal Cross-section possessing body can be rotated according to a predetermined plan. At the same time, of course, with these Benches normal lathe work and thread cutting can be done.

In the drawing, an embodiment of the subject matter of the invention is shown, and although show

Fig. Ι a part of the longitudinal section of the lathe partially in view,

ao Fig. 2 a cross section of the lathe with partial view,

Fig. 3 is a front view of the lathe, Fig. 4 is a side view and the
Fig. 5 to 13 individual parts.

If a point is assumed on one side of a square rotating around its center point, which during the rotation of the square can only move back and forth on a straight line passing through the center point, the point will describe a path which is the same as that Difference between the radius of the circle circumscribed around the square and that of the inscribed circle. In other words, the distance covered by the point is equal to the height χ of a segment of a circle whose chord forms one side of the square and whose arc is part of the circumscribed circle (Fig. 10).

If the straight line ao connecting the point with the center point (Fig. 13) is now extended and a point b is assumed on the extension and this point is thought to be rigidly connected to the point a , it will make the same alternative movement as the point a, if the Point b lies on a disk B , which rotates at the same speed as the square A and when the point of rotation of this disk lies at a distance from point b which is equal to the radius of the inscribed circle on A. If you hold a pencil at point b would attach, he would draw on disk B a square congruent with square A , whose circumscribed and inscribed circle would of course also be congruent with that of square A. However, square A can also deviate from the speed of disk B. Speed, e.g. B. with twice as high speed, that is, while the square A makes one revolution, the disk B makes half a revolution, the point on the straight line ao four times its alternative movement and four corners on the half-turn disk power.

So if the disk B moves with a velocity ν and the square A with a

Speed V ₁ - ι · 25 υ turns, we get a pentagon on disk B , at V ₁ = 1 · 5 ν a hexagon, at ^ ₁ = 2 ν an octagon etc. The lathe according to the invention is based on the above principle , the square A representing the disc 5 shown in Fig. 8, on which an almost square groove 6 is provided. The above-mentioned pencil located at point δ of the disk is represented by the knife clamped in the support 2 shown in FIGS. 1 and 2. The constant distance a, b is ensured by the support 3, on the side of which lies against the disk a roller that fits into the groove 6 of the disk 5 is attached (Fig. 12), which provides the same services as point a of the square A. The disk B represents the object to be machined clamped between the centers of the lathe. The support 3 thus constantly performs a reciprocating movement, which causes the already mentioned role that protrudes into the groove 6 of the rotating disk 5. The supports located on support 3 also make the same movement.

The supports 4, 3, 2 are arranged on the bed 1 of the lathe, the disk 5 of Fig. 8 rests in a bearing disk 5 ', which lies in the support 4 (see Fig. Χ and 12). Helical springs act on the bearing washer 5 from two sides (Fig. 12). The support 4 can be moved on the bed 1 and of course takes the supports 3 and 2 and the disc 5 with it. A spindle 7 is attached to the lower side of the disk 5 (Figs. 1, 2 and 8), at the lower end of which a bevel gear 8 is wedged, in which a bevel gear 9 engages. The bevel gear 9 connected to the bevel gear 8 by means of a bracket 10 is arranged displaceably on a shaft 11 which at its other end carries tin bevel gear 12 in which the shaft 11 is displaceable. The bevel gear 12 engages in a bevel gear 13 which is arranged displaceably on a shaft 14 connected to a belt pulley. A four-sided pyramid 15 is arranged on the spindle 7 and is fastened to the end of a sleeve 16 drawn onto the spindle 17 (FIG. 9) in such a way that the pyramid 15 can rotate on the sleeve 16. The pyramid 15 rotates by means of the wedge 15 'with the spindle 7 and can move at the same time on the spindle 7 in the axial direction (Fig. 9). A worm wheel 17 is arranged below the pyramid 15 on the sleeve 16 (FIGS. 1 and 2), the bore of which is provided with a screw thread and which is driven by a worm 18. The outside of the sleeve 16 is provided with a screw thread that fits into the inner screw thread of the worm wheel, by means of which the worm wheel 17 raises or lowers the sleeve 16 together with the pyramid 15 in the bearing 19, the sleeve 16 with its flat thread like a smooth shaft in the bearing 19 moves in a vertical direction. Their rotation is prevented by a wedge located in the bearing 19 which engages in a keyway in the sleeve 16. The worm wheel can only make a rotating movement; its vertical movement is prevented by pins 17 ' ηο on the right and left, which engage in a circular groove in the worm wheel 17 (Figs. 1 and 2). The spindle 7 driving the disk 5 and the device driving the pyramid 15 are arranged in a frame 20, 21. The worm 18 is driven by a shaft 22 (Fig. 2), which is axially displaceable but non-rotatable with the worm. The gear 23 arranged at the end of the shaft 22 is connected to a crank 24 by means of a gear transmission (FIGS. 2 and 3). In the frame 25, which is used to support the guide 20 'and is fastened to the support 4 at the bottom, spindles 26, 27 provided with right and left threads are rotatably arranged (Figs. 2, 5, 6, 7) Crank 28 driven gear 29 (Fig. 3) the gears 30, 31 transmit the rotation to the spindles 26, 27. On the spindles 26, 27, brackets 32, designed as screw nuts, in which the pyramid 15 contacting rollers 34, 35 are mounted. A toothed wheel arranged at the end of the shaft 29 'of the toothed wheel 29 is connected to the toothed wheels located on the shaft of the crank 24, this crankshaft passing through a vertical plate 36 of the support. The shaft of the crank 28 also passes through this plate, its gears with the shaft. 22 related. On the front part of the lathe bed 1 there is a rack 37 used to move the table by hand (Figs. 2 and 3), which can be switched to the spindle 38 causing the automatic drive by means of a suitable gear transmission. The lead screw 39, known per se, is also arranged on the front part of the lathe (Fig. 3). At the left-hand end the gears 40 used for cutting the various threads are arranged (Fig. 3), which are connected to the main shaft 41 by means of the gear ratio 42, whereby they are operated by means of the shift arm 43, the countershaft 44, the bevel gears 45, 46 and the Switching arm 47 can be switched to the spindle 38 moving the support or to the thread cutting spindle 39 during normal cutting. Behind the gears 40 is a row of similar gears 48 (Fig. 4), which are used when four-, five-, six- or octagonal transverse

cuts should be rotated, with the setting on different gears immediately is accomplished with the arm 49. When turning any polygonal cross-section you can At the end of the lathe, gears that are not shown in the drawing are still to be put on are illustrated.

The individual components work together as follows:

The spindle 7 is driven by the shaft 14 by means of the gears 8, 9, 12, 13 (Fig. 3). At the same time, the wedged with the shaft spindle 7 disc 5 rotates, which by means of the in its groove 6 engaging role the support 3 moves back and forth, the clamped in the support Messer makes the same movement. Since the pyramid 15 is mounted on the spindle 7 is that it can move in the longitudinal direction 3er spindle, so it will raise or lower when the worm 18 through the with the shaft 22 by means of gears in Connected crank is turned to the right or left. The pyramid 15 lifts or lowers because the worm 18 only moves the worm wheel 17 horizontally Can rotate because the worm wheel through the pins 17 'to a movement in a other direction is prevented. As already mentioned, the outer surface of the sleeve 16 is with provided with a flat thread, in the hole in the worm wheel 17 located Thread fits into it. But since the spindle 7 can rotate freely in the sleeve and the Flange of the sleeve 16 can also rotate in the pyramid 15 (Fig. 3) and the Pyramid can only move along the spindle, the pyramid will move when rotating the crank 24 raise or lower.

The frame 20, 21 (Fig. 1, 2) can be in the guide 20 'of the frame 25 against the action of the bearing on the disc bearing 5' Move the springs (Fig. 12). The brackets 32, 32 can also be located on the guide 20 ' move so that the rollers 34, 35 mounted in the brackets by means of the screws 26, 27 of the Pyramid 15 can be approached or removed from this, in such a way that, if one roll moves away from the pyramid, the other draws closer. So if the crank 28 rotated (Fig. 2 and 3), so are by means of the with the located at the end of the shaft 28 Gear wheels connected shaft 29 ', the screw spindles 30, 31 brought into rotation and in this way the rollers including the brackets 32, 32 are moved.

The lathe can produce: i. Objects with a square cross-section, which is equal to the square formed by the center line of the groove 6 of the disk 5; 2. Objects with a larger or smaller square cross-section than this;

3. Objects with a polygonal cross-section, where the height y of the circle segment between the square 6 on the disk 5 and the circumscribed circle is equal to the height y _{x of} the circle segment between the polygon and the circle circumscribed around it (Fig. 11);

4, Larger or smaller cross-sections than that in Fig. Ix.

ι and 2. In this case, the pyramid is 15 by means of the crank 24, the worm 18, the worm wheel 17 and the sleeve r6 along the shaft spindle 7 moved so that it does not touch the rollers 34, 35 at all. Will now the lathe is set in motion, the support 3 is moved under the action of the in the groove 6 of the disc engaging role together with the support 2 holding the knife in the Cover a distance back and forth across the bench, which is the same as the difference between the radii of the circumscribed and inscribed circle of square 6, d. H. is the same as the height of the circle segment. The bearing 5 ′ of the disk 5 is fastened in the support 4. During the movement caused by the disc, the knife will Process the clamped object so that its cross-section corresponds to the square 6 will be congruent square.

Effect and purpose of the pyramid 15. go

Before beginning the description of the pyramid, it is assumed that here in each one Fall the height of the circle segment between that around the square groove 6 of the disk 5 circumscribed circle and one side of this square guide with the height of the Circle segment between the polygon to be rotated and the one circumscribed around it Circle is compared. The comparison is made exclusively on the basis of the segment heights, regardless of how the area enclosed by the groove 6 of the disk 5 is related to the by the sides of the cross-section to be rotated behaves.

By turning the disk 5, the groove 6 with the knife located in the support 2 is turned into an angular object from the object clamped between the tips of the lathe, the square cross-section of which corresponds to that formed by the groove 6 of the disk 5. Without switching on the pyramid, however, neither a larger nor a smaller one can be rotated, since the sides of the rotated square become either concave or convex, depending on whether the circle segment height of the rotated body is smaller or larger than the circle segment height of the groove 6 of the disk 5 (Fig. 14), where square N ₀ would be the square 6 on disk 5, while 2V _{1 is} the square to be rotated with a larger cross-section. As you can see, the sides are convex because the segment height λ; of

The larger square is equal to the segment height of the smaller square N ₀ . It follows that the side of the square, i.e. the chord of the circle segment, bends with the segment height X _2. The opposite of this occurs when the square N _{2 is} rotated (Fig. 14); here the side of the square will be concave, ie the chord of the circle segment will bend in the opposite direction with the circle segment height x _z.

A device is therefore required which, in the given case, adds or subtracts a certain path # g to the circle segment height χ of the square 6 of the disk 5. This aim is achieved pyramid 15. If the glass run N ₀ a square N ₁ with a larger cross-section, ie a square with a greater segment height, are rotated, so must the height of segment IV ₀ a piece of x are added _for χ of the square. This piece x ₂ is obtained by the pyramid in that it is raised so high that its circle segment height is opposite the roller 34 - X ₂ . Then the roller 34 (Fig. 6) is placed on the side of the pyramid so that the point of contact is at the bisection of the side. If now the spindle 7 rotates the pyramid and the roller is stationary, the pyramid 15 must move with the frame 20, 21 on the guide 20 '; consequently the disk 5 with the disk bearing 5 'will also move against the action of the springs (Fig. 12). The disk 5 will make the support 3 a path χ and the pyramid a path x _s , so that the support 3 will cover a path χ + X ₂ = X ₁ , which is equal to the circle segment height of the square to be rotated N _1. If, however, the square N _{2 is to be} produced by means of the guide disk N ₀ , the opposite must be carried out, ie the pyramid must be brought into contact with the roller 35, and the path X ₂ must be subtracted from the path χ (Fig. 14) , ie the pyramid must be lifted so high that its circle segment height compared to the roller 35 = x ₂ . The distance covered will be χ - X ₂ = x ₀ .

3. If you want to turn a body with a polygonal cross-section, the circle segment height y _{x of} which is equal to the circle segment height y of the square 6 (Fig. 11), then the pyramid 15 is first switched off by lowering, and the rollers 34, 35 are moved by means of the screw spindles away from the pyramid. Thereafter, the disk 5 is given a greater speed than that of the workpiece, in such a way that the gears of the arm 49 are switched into the gears of the row of gears 48. This speed must be so many times greater than the number of sides of the square is contained in the number of sides of the polygon. So if you want z. B. to produce a pentagon, hexagon or octagon, the speed of the disc must be 1.25, 1.5 or twice as great as the speed of the work piece.

Namely, if the translation between the disc and the workpiece is greater than ι: i, then the knife will move back and forth several times in relation to the workpiece, and workpieces with a polygonal cross-section are obtained.

4. The same procedure is used for polygons with a larger cross-section and a greater number of sides, ie when making polygons where y _{x is} greater than y (Fig. Ri). Here, however, in addition to the greater speed, there is the greater or lesser distance covered by switching on the pyramid 15. Here, too, without switching on the pyramid, as with the square, concave or convex sides would be obtained, depending on whether the circle segment height of the guide 6 of the disk 5 is smaller or larger than the circle segment height of the polygon to be rotated (A.bb. 14).

The lathe can also be used as an ordinary bench on which to place objects with a circular cross-section can be turned and threads can be cut. In this Case, the pyramid 15 is turned off and the support 3 in the support 4 by means of a cylindrical bolt.

Claims (2)

P ATENT claims: 1. Lathe for the production of bodies with an angular cross-section and a den Support controlling and arranged in it, rotating in a horizontal plane gauge with a square cross-section, thereby characterized in that the vertical spindle (7) of this teaching (5, 6) an up and downwardly displaceable four-sided pyramid (15) that rotates with the spindle (7) carries, which gives the support an additional movement in the transverse direction. 2. Lathe according to claim 1, characterized in that the four-sided pyramid (15) with the spindle (7) and with the gauge (5, 6) attached to it together in horizontal plane in a guide (20 ') is displaceable, and that they each with one of two rollers (34,35) adjustable in the horizontal plane works together. 1 sheet of drawings.