DE1018632B - Device for checking the involute shape of tooth flanks of tapered gears - Google Patents

Description

Device for checking the involute shape of tooth flanks of tapered gears The invention relates to a device for checking the involute shape of tapered tooth edges Gears and is characterized by the fact that a probe tip that tests the tooth flank in a plane through a surface line of the base cone of the gear on an arc of a circle is guided around the tip of the cone and a control device when rotating the test object the probe tip is moved by the angle a w = a a # X sin v, if a is the distance between the stylus tip and the cone tip, w is the central angle belonging to the arc and v is half the cone angle. As will be shown later, the stylus will then be used or its carrier is guided exactly on a Kegetradevolvente. With the known involute testing devices for bevel gears, the stylus is only on an approximation curve of the bevel gear involute moved so that the test results are only approximately correct. The device the invention is therefore characterized by its strictly exact test results of the known devices.

In the case of the present device, it is known per se in involute devices Way of rolling sectors and rolling lines made use of the are connected by ribbons.

The device after. the invention is characterized in that a the tooth flank testing probe tip 24 in a plane through a surface line of the The basic cone of the toothed raldes 1 'is guided on an arc around the conical tip C and ien control device 8, 11, 13, 16, 19 upon rotation of the test item 1 to the Angle u the probe tip 24 around the arc ci. # = = ci. u sm sin v moves when ci the distance between the probe tip 24 and the cone tip C is the one belonging to this arc Central angle and v is half the cone angle.

The control device is expediently for forming the variable w from a first and a second rolling sector, a first and a second ruler, of which the first rolls on the first rolling sector and the second on the second rolling sector and each of which can be moved in the direction of its axis, as well as a disc, which is connected to the ends of the two rulers, whereby the first rolling sector for rotation through the angle u is in rotary connection with the test object and the second Rolling sector together with the ruler rolling on it for setting the size v about a first axis parallel to the first ruler and the extension of the axis of rotation of the first pitch sector in the tip of the base cone, both and around a second axis perpendicular to the first axis and around the cone point the angle to is rotatable and wherein the disc connected to the ends of the rulers about an axis parallel to the axis of rotation of the first rolling sector and the first axis of rotation of the second rolling sector is rotatable cutting. So the test specimen is turned around the angle u. rotated, then the second rolling sector rotates around its second axis of rotation the angle w. If the stylus is connected to this second rolling sector, then he also performs a rotation by the angle w. Advantageously, the second Rolling sector a guide and measuring means for adjusting the distance of the probe tip from the point of the cone. If the probe tip is at the distance a from the tip of the cone set, then the stylus moves, as requested, when turning the Test specimen around the angle u around the arc ci. w.

For precise setting of the angle of rotation of the second rolling sector its first axis of rotation are expediently provided with special setting angles. SiIit With the help of these means, half the cone angle v is introduced into the e control device.

To bring the stylus tip into contact with a tooth flank. without To have to adjust the entire control device, the guidance is advantageous by the rotation of the second rolling sector by the angle im rotatable about its second axis.

Special measuring equipment and locking means are useful for the definition a certain angle of rotation of the guide provided. Is the device designed in such a way that that the probe tip always rests on the surface to be tested, and are special Means are provided which deflect the probe tip when the tooth flank shape deviates register of the nominal form. then the direction of deflection of the probe tip is appropriate adjustable. This has the disadvantage that lead helical bevel gears affect the direction of deflection can always be placed perpendicular to the tooth direction.

In order to also have circular-arc toothed bevel gears (Gleason arc-toothing) to be able to examine will the fulcrum of the guide --on the second Rolling sector designed to be adjustable in two dimensions.

In the drawing, an embodiment of the invention is shown, 1 shows a sketch to explain the mode of operation of the invention, Fig. 2 shows a device in perspective, Figs. 3 to 5 sketches for explanation the operating mode of the device according to FIG. 2, FIG. 6 a part of FIG. 2 in a modified form Execution.

-In Fig. 1 cm is spatially shown cone 1 along a surface line 2 cut open from the base circle point A of the cone to its tip C, the surface of the cone is settled to line B-C, where B is again on the base circle. Of the The point is on a spherical surface with the center point in C and the radius Hiked 4-C into the room to point P. If one sees the curve d-P as on the tooth flank of a bevel gear lying on, then can with a stylus, which when rotating of the test specimen around the central angle 1 of the bevel gear that belongs to the arch, 4-B 3 runs through the curve from A to P with the radius r, the tooth flank shape is precisely checked will. It does not matter whether the plane P CB is moved and the cone itself remains fixed or whether the plane P C B is assumed to be fixed and the cone is rotated about its axis by the angle it. In the latter case the stylus can be moved in the plane P CB to follow the curve A-P, by only pointing at the intersection of curve A-P with plane P B C got to. The stylus describes a curve in the plane P C B during this scanning process with the equation r # u, i.e. an involute belonging to the radius r of the basic 3.

A device with such a tracking is shown in FIG. The bevel gear to be tested 1 is attached to a mandrel 4, which in turn in tips 5 and 6 rotatably about an axis D-D.

The rotation of the bevel gear 1 'is via a driver 7 on a Transferring rolling sector 8 rotatable about the same axis D-D. The rolling sector 8 transmits its rotational movement by means of belts 9 and 10 on a ruler 11, which by virtue of a not drawn guide is only displaceable in the direction of its axis. The end 11 of the ruler has a ball bearing 12 which rolls on a disk 13. Around To ensure a positive movement, the disc 13 is spring-loaded Ball bearing 14 pressed against bearing 12. The pin 13 is about an axis E-E rotatable. The axis E-E is parallel to the axis D-D and has the same distance from the ruler 11 as the axis D-D, the rotational movement of the disc 13 is via a ball bearing 15, which is spring-loaded onto the disk 13 in the same way as the ball bearing 12 is transferred to a ruler 16. The ruler 16 is not indicated Guide displaceable in the direction of its axis. By means of bands 17 and 18, as is connected to a rolling sector 19.

The Wälzskeotr 19 is on the one hand pivotable about an axis F-F, wherein this axis is parallel to the ruler 11 and through the cone tip C of the base cone goes, and on the other hand rotatable about an axis G-G, which at point C perpendicular to the axis F-F stands.

The rotary movement of the rolling sector 19 about the axis G-G is through the Ruler 16 initiated. The rotation around the axis F-F becomes an adjustment by hand of half the cone angle v made.

The size of this Dre, hhewegu, ng can be determined by means of a microscope 20 can be read on a scale 21.

The movement about the axis F-F does that connected to the rolling sector 19 Ruler 16 with. A guide is pivotable about the axis G-G on the rolling sector 19 22 is provided, in which by means of a measuring spindle 23 of the stylus 24 together with a Means for recording the movement of the stylus 24 as a function of the Angle of rotation lt of the bevel gear 1 'is displaceable. The probe tip 24 is in one Slit 25 out so that they only ausü.ilren in the direction of this slot can. The direction of the slot 25 can be adjusted by means of a scale 28, for example perpendicular to the tooth direction. The pivoting of the guide 22 relative to the rolling sector 19 can be read off on a pitch circle 27 of the pitch sector 19 by means of a microscope 26 will.

The operation of the device is as follows.

The rolling sector 29 is pivoted about the cone angle v and in this Clamped position. Then the distance between the probe tip is determined by means of the measuring spindle 23 24 set from the cone tip C to a.

Finally, the slot 25 is set perpendicular to the tooth direction. As can be seen from Fig. 3, when turning the Kefgelardes 1 'and thus the Rolling sector 8 by the angle lt the disk 13 by an angle lZl in the position 13 ' panned. Is the radius of the rolling sector r1. then the ball bearing 12 has this Pivoting a displacement path r lt covered. Is the distance of the ruler 16 from the plane through the axes of rotation D-D and E-E equals x, then shifts with this pivoting of the disc 13, the rod 16 by an amount y. Because the ruler 16 from its position in which it lies with the axis F-F in a horizontal line to the angle 90 ° -v is pivoted according to FIG. 4, which is a side view of the Disk 13 represents b # sin v = z when b is the distance of the ruler 16 from the axis F-F is. According to FIG. 3, it also follows that y = x # u, which is a shift quantity N b # b sin v gives.

Fig. 5 shows a schematic representation of the rolling sector in plan view. If the ruler 16 is shifted by the amount there, the rolling sector 19 is in the axis G-C pivoted by the angle w. The angle to results in w = l / b = lt sin v. In doing so, the stylus 24 moves on the arc of a circle, as requested at the beginning by C with a by the amount a # w = a # u # sin v If r is the base circle radius belonging to the route of the basic cone, then a = r / sinv, and a w w = r r zr in the tangential plane Developed bevel gear volumes, as promoted at the beginning.

By means of the scale 27 and the micrometer 23, the respective The position of the probe tip 24 on the rolling sector 19 can be specified in polar coordinates, whereby in a different way the bevel gear involute developed in said tangential plane are described katln.

In order to have a circular arc-shaped tooth line (Gleson curved toothing) To be able to carry out an examination. is the pivot point of the guide 22 on the rolling sector 19 advantageously movable. This shift can, for example, by means of gauge blocks be effected.

Fig. 6 shows an embodiment in which the axis of rotation G'-G ' the guide 22 on the rolling sector 19 can be changed in their position relative to the axis G-G can. A mandrel 60 is provided on the rolling sector 19 for this purpose iii the axis G-G, and the guide 22 has a mandrel in its axis of rotation G'-G ' 63 on. A bar 62 is also attached to the rolling sector 19. Through a teaching 64 the distance between the two mandrels 60 and 63 is set and another Teaching 65 the distance between the mandrel 63 and the bar 62. This is the position of the axis of rotation G'-G 'precisely defined on the rolling sector 19. Form the ends of gauges 64 and 65 a bearing for the mandrel 63.

The guide 22 can be rotated with the mandrel 63 in the jigs. Instead of the gauge 64 and the dome 60, a second bar, which then perpendicular to the bar 62 is provided, and the mandrel 63 is then adjusted by a gauge in its distance from this second bar.

Gauge blocks can be used here instead of the gauges.

Claims (8)

PATENT CLAIM: 1. Device for checking the involute shape of tooth flanks Equal gears, characterized by the fact that a tip that tests the tooth flank (24) fn a plane through a surface line of the base cone of the gear (1 ') an arc around the tip of the cone (C) and a control device (8, 11, 13, 16, 19) when the test object (1 ') is rotated by the angle u, the probe tip (24) around the arc a ci. w = a ci. u sin v moves when a is the distance between the probe tip (24) of the point of the cone (C), w is the central angle belonging to this arc and v half the cone angle. 2. Apparatus according to claim 1, characterized in that the control device to form the size w from a first (8) and a second rolling sector (19), einvem first (11) and a second ruler (16), the first of which (11) on the first rolling sector (8) and the second (16) unrolls on the second rolling sector (19) and each of which in Fixed in the direction of its axis and a disc (13) which with the ends of the two rulers (11 and 16) is connected that the first rolling sector (8) is in rotary connection for rotation about the Winkelu with the test item (1 ') and the second rolling sector (19) together with the ruler (16) rolling on it for adjustment of size v about a first axis (F-F) parallel to the first ruler (11) and the extension intersecting the axis of rotation (D-D) of the first pitch sector (8) in the tip of the base cone both all and by the angle w about a second axis (G-G) perpendicular to the first Axis (F-F) and the cone tip (C) can be rotated to the point, and that with the ends the rulers (11 and 16) connected disc (13) about an axis (E-E) parallel to Axis of rotation (D-D) of the first rolling sector and the first axis of rotation (F-F) of the second Waelz sector is cutting rotatable. 3. Apparatus according to claim 2, characterized in that the second Rolling sector (19) a guide (22) and measuring means (23) for the distance, setting (A) the probe tip (24) from the cone tip (C). 4. Apparatus according to claim 2, characterized by means (20, 21) for the exact setting of the angle of rotation v of the second rolling sector (19) around its first Rotation axis (F-F). 5. Apparatus according to claim 3, characterized in that the guide (22) regardless of the rotation of the second rolling sector (19) by w about its second Axis (0-0) is rotatable. 6. Apparatus according to claim 5, characterized by measuring means (26) and Locking means for setting a certain angle of rotation of the guide. 7. Apparatus according to claim 1, wherein the probe tip on the to be tested Surface and means are in front of which a deflection of the probe tip If the tooth flanks deviate from the target shape, register the shape, which is indicated by it, that the deflection of the probe tip (24) is adjustable. 8. Apparatus according to claim 3, characterized in that the guide (22) is rotatable about an axis perpendicular to the second rolling sector (19) and that means are provided to the position of the axis of rotation on the second rolling sector as desired to be able to adjust.