DE1423570C - Automatic gear testing device eliminated from 1188826 - Google Patents

Description

In the main patent 1183 700 is an automatic one Gear testing device, especially for testing and measuring double flank generating errors, concentricity, Pitch errors, tooth thickness errors and tooth gap width errors a on toothed parts, described in which a carriage carrying at least one probe is periodically moved in a straight line towards and away from the test object, with the movement of the slide or probe is displayed and / or registered by a measuring device. The examinee is thereby according to this suggestion by its own power source, preferably non-stop, at low speed driven while at least one is pivotable on the linearly reciprocating slide arranged probe when advancing the slide before reaching the measuring position in a tooth gap of the test specimen is introduced and taken along by the test specimen beyond the measuring position, wherein the probe executes a swivel movement. Means depending on the pivoting movement of the The straight forward and reverse travel of the slide is controlled by the switching means working with a probe. In addition, means are provided through which the probe when the carriage returns to one adjustable angle is pivoted back after its probe tip out of engagement with the toothing of the test item has come.

The probe or several probes inserted into a tooth gap of the test object, which is preferably driven continuously, before the measurement position is reached, are taken into the measurement position by the test object and pivoted further beyond the measurement position. When passing through the measuring position, the measurement is carried out and then the periodic return and subsequent forward movement of the slide is initiated by the probe (s) that continue to pivot. During retrace, the probe is so far rotated in the opposite sense, that ₄ ein'Eingriff is ensured in the next tooth space on the forward stroke of the carriage. The test device .according to the main patent is designed in such a way that on the slide, the movement of which is limited in the direction of the test object by a stop, a special, the pivotable probe carrying measuring slide is arranged, which is supported by a spring with adjustable measuring pressure against the The test specimen is moved and is moved away from the test specimen during the pivoting movement of the probe, which is carried along by the test specimen, which preferably moves continuously, and that the maximal forming of the measuring slide that occurs is measured and registered by the test specimen by means of a preferably capacitive electrical measuring device. The recording of this measuring slide movement results in a cingipolar curve for each measured tooth pitch, and the deviations between adjacent maximum values are a measure of the pitch and pitch errors as well as the tooth thickness and tooth width errors, while the deviation of the extreme values within this series of maximum values is a measure of the represents runout errors.

The device described in Ilauptputunt 1 183 700 is used to test toothed parts by measuring the radial penetration depth of the probe tip (s) formed as a ball, measuring wedge, tooth or tooth segment into the tooth gaps of the test object. In addition, it is common to measure the toothing errors by measuring the deviation in the tangential direction, i.e. from tooth flank to tooth flank or in the direction of the so-called line of action (involute toothing) which is usually less than 20 ° against the tangent.

A known device for this purpose has two measuring tongues which are shared by one device pivoted by equal angular amounts and> can also be moved parallel to one another. One of these measuring tongues is by certain angular amounts around the set angular value against the Freely swiveling pressure of a spring. The movements of this measuring tongue are based on a lever system transfer known measuring or registration devices. When measuring the toothing of a gear the device is set for a standard pressure angle to be selected and so on the tooth put on that a further arranged support tongue for easier handling of the device on the edge to be measured comes into contact with the opposite edge. The measuring surface should be the solid The measuring tongue must not be brought too close to the tooth head. The feeler tongue, that is, the one around a certain one Tongue that can be swiveled angularly, must not yet touch the second tooth when the device is put on. Now the sensing tongue must be moved parallel to the fixed measuring tongue until the The pointer of the measuring device has moved into its zero position. The determined tool division can now be used for the set pressure angle from on the Device arranged spur lines can be read. Of course, there is also the Possibility of specifying the tool division and reading off gear errors on the measuring device. This Measuring and testing device for gearwheels with involute teeth allows measuring and checking of the absolute dimension in any engagement pitch for any pressure angle of 0 to 30 °. The disadvantage of this device is that it requires very long testing times for quantity testing So it should not be used that the measurement result is falsified by the way in which the device is handled can be measured and that with it only meshing divisions, but no pitch circle divisions measured can be.

In another known device for checking the involute and helix angle on wheel teeth A precision feeler is activated by means of a rolling disk, rolling ruler and an indicating or writing precision probe two straight guides held displaceably, one of which runs in the axial direction of the test object and the other is to be pivoted in relation to the helix angle of the test specimen and where by the interaction of a straight tangential movement of the probe head and a rotary movement of the wheel the probe, referred to the wheel, describes a theoretically perfect involute. Any deviations from this theoretical involute are visible to the eye, shows or recorded as deviations from a straight line in the case of writing devices. Apart from this, that with this device also no partial circles can be determined, the device requires the use of a roller disc and roller ruler, in order to enable the precision probe to intervene. Compared to the first device described it has the advantage that the precision probe can be moved by means of a slide, i.e. not measuring

can be influenced by the way the device is handled.

The measurement of the engagement pitch t _e , which is possible with both devices, determines the distance between the points of engagement of the flanks on their line of action, i.e. the distance between two points on a straight line that is pivoted from the normal to the center line of the gear by the pressure angle x _0. One of the buttons on devices that work with two probes or tongues is therefore roughly close to the base circle, the other close to the pitch circle on the respective right or left flank. If, on the other hand, the pitch circle division t _{0 is to be} measured, then the pitch arc between two successive right or left flanks or the distance between two points' is to be defined; which lie on a common circular arc around the center point of the gear to be tested approximately in the vicinity of the partial circular arc.

Since the straight line with the _{pressure angle a 0 is} tangent to the base circle of the gear wheel with respect to the normal to the center line, the base circle arc ig between two successive right or left flanks of the gear wheel is also equal to the engagement pitch t _e . Since only the ratio of the individual teeth to one another and not the absolute dimension is used for checking when checking the pitch of gears, the measurement of the base circle pitch t _e , which corresponds to the mesh pitch t _{c, could also be used for checking.} However, the measurement of the engagement pitch t _e with the known devices is not on the base circle - that is, measurement of the base circle pitch t _s . - possible, since they, as far as they work with two probes or tongues, take advantage of the fact that the line connecting the two points to be measured with the _{pressure angle a 0} against the normal to the center line, a common normal to the involutes of the successive right or right. Left flank is. Therefore, these measuring probes or tongues are flat and are shifted until they are in the engagement surface, that is, in the surface tangent to the involute at the engagement point. Of course, this is no longer possible at the base circle of the gears, since the involute toothing ends here and merges into the root circle. In the known checking devices, the errors in the pitch division are always determined, but not the errors in the pitch circle division. .

Normal gears or racks are therefore still required to measure this pitch circle division necessary, or devices that allow the distance between two points approximately on the partial arc to be sampled between two consecutive right or left flanks. In contrast, however to check the meshing pitch, which also applies to large gears on two to three on the diameter distributed places can be made, the pitch circle division must be as uninterrupted as possible can be carried out from tooth to tooth, as this pitch is not a constant of the tool, but rather very much from the manufacturing conditions and method depends. The use of the devices known for checking the division of intervention would be therefore not even then for checking partial circles if possible, whom could be carried out with them in any kind of partial circle divisions, since they are only designed for sporadic measurements on gears. For serial testing of pitch circles, especially on large gears, however, a measuring device is required that allows make continuous measurements, which are also independent of how they are carried out.

With the test device according to the invention, while maintaining the values shown in the main patent fundamental solution to carry out such measurements.

This is achieved in that, as is known per se, on the carriage, which is periodically moved back and forth, two independently against restoring forces, pivotable probes are provided that the Probe when moving the slide towards the test object into two adjacent gaps of the gear to be tested can be introduced beyond the partial circle that on the probes known devices for continuously measuring their pivoting movement are attached and that the angular value of a swiveled-out button when the other button passes through a tuned, Measurement position and thus a certain angular value can be displayed or registered. f "

In the device according to the invention, no normal gears or racks are required, rather, the two probes that are inserted into the by the to-and-fro slide are sufficient Gaps in the test specimen are retracted. A single setting must be made by hand the measurement can be made, namely the parallel displacement of the probes so far that their distance roughly corresponds to the pitch circle division. Are the probes, for example, with known dial gauges connected, their rest position can be around - 20. The probes are retracted into the gaps and if they are taken along by the test item, this value becomes -20 due to the take-away movement and thus gradually reduced by swiveling out the probe, up to theoretically correct division of the test object both dial gauges show zero. If this is not the case, the Position zero of one of the two probes, read off the plus or minus value of the other probe or recorded. At the same time, when one of them crosses zero, it can determine the reading Probe a contact can be closed, which after an adjustable delay the return of the slide causes the probes to disengage from the test object. According to an adjustable Time, the slide automatically moves into the gaps in the test object. The movement of the The test specimen does not have to be synchronized with the to-and-fro movement of the slide as long as it takes place continuously because the same time program is used at the zero crossing of the measuring probe determining the reading expires, these individual time sequences so with each slide movement again concurrently with the movement of the test object. Of course, the amount of swiveling can be the probe can also be measured by an electronic arrangement known per se, with one the probe when a certain measuring position is reached, the display of the pivoting out electronically of the other probe. Such an arrangement has the advantage that the measuring device does not must be monitored, but completely automatically with the preferably !! ceaseless movement

of the test object shows the deviation from the theoretical pitch circle division whenever one of the The probe travels through the specific measuring position. It can also be used for the simplest of large gears Be measured in a manner that is completely automatic after the first setting. The swiveling out of the probe to change an associated one is expediently Capacity used and the change in capacity of the two individual capacities in a manner known per se each assigned to a resonant circuit. The oscillating circuits themselves can of course also have a fixed frequency be superimposed so that the resulting beats can be heard or recorded. The electrical impulse triggered when the measuring position is reached can also be used to after an adjustable delay time, the return and subsequent forward travel of the slide closes control or switch on a program switch that switches on the one causing the forward and reverse movement Electric motor and its direction of rotation reversal makes.

For the periodic back and forth movement of the slide is in this design of the test device an electric motor is provided for tangential measurement, which drives the slide via a pinion and one with the Slide connected rack drives, as shown in a further additional patent 1188 826 for Main patent 1 183 700 has been described and placed under protection. Switching on the electric motor and its direction of rotation is reversed here, however, via the switching device and its disconnection via a circuit breaker using contactors. So much for the periodic movement of the slide With the help of an electric motor, pinion and rack, it has also been proven here that the rack with the interposition of a compression spring with the - is connected to the carriage that the Toothed rack after the end of the forward travel of the slide, which is limited by a stop can perform a further feed movement and that connected to the rack of the circuit breaker in such a way is that it is opened during this feed movement. To regulate the speed of movement of the slide, the speed of the electric motor is expediently adjustable.

In the, embodiment of the device with two swiveling probes for tangcntiale measurement must the Mcasstasteispitzcn with the return of the The carriage must be swiveled so far that they cingicifen into the next tooth gaps as they advance. Fs suffices in this case for each of the two Mefitastcr unites: A restraint spring is to be provided, which guides the button to a certain starting position. By coordinating the travel speeds the test specimen and the slide manage to move the probe tips into the next tooth gaps feel free. The new zupiüfciidni ZaImflunken then take the Meßtasterspitzeii under as a result of the non-stop movement of the test object Tensioning the ankle clamps with. Instead of the aforementioned capacitively working measuring mechanism can just as well use an inductively working Mcßwcik will. The capacitors are then replaced by induction coils of variable induction. Fs it was said that the measurement results evaluated by the measuring mechanism were registered. As well The measurement results can also be displayed as individual values or in the form of audio frequencies made audible and, if necessary, recorded. Finally, the obtained Use measured values as a control variable for an automatic controller through which, for example, the an a gear cutting tool of a gear cutting machine in operation are continuously corrected so that the workpiece generated does not interfere with the tool and ■

ίο subject to machine errors in the generating machine is.

In the drawing is an embodiment of the

Subject of the invention shown, namely shows F i g. 1 is a plan view of an embodiment of the test device and

F i g. 2 shows a cross section along the line II-II of Fig.l.

In the F i g. 1 and 2 show an embodiment of the subject matter of the invention. For the measurement

In addition, two probes 80 and 81 are provided, which are shown as a gear ^ in adjacent tooth gaps Test specimen 83 intervene and the tooth flanks delimiting the tooth gaps on the same side Teeth. The distance from tooth flank to tooth flank is measured using the mutual Angular position of the two probes 80 and 81.

The testing device has a base plate 84 on which a slide 86 is mounted in roller guides 85 so as to be longitudinally displaceable. This slide is moved towards and away from the test object 83 with the aid of an electric motor 87 with the interposition of a toothed rack 88 which is driven via a pinion 89 of the motor 87. In its foremost position, the carriage 86 strikes a delimitation strip 90 arranged on the front edge of the base plate 84. On the slide 86 are cross slides 91 and

92 arranged with the help of threaded spindles

93 and 94 can be set in their mutual distance from one another and can be fixed on the carriage 86 by means of locking screws 95 and 96. Each of these cross members 91 and 92 carries a measuring probe 80 and 81 which can be pivoted about a vertical axis 97 and 98. A capacitor plate 99 and 100 is firmly connected to the pivotable measuring, blasphemous 80 and 81, each of which is connected to one on the associated Oucrschlitlcn 91 and 92 fixed capacitor plates 101 and 102 each form a capacitor 99/101 and 100/102 . Change probes 80 and 81 when swiveling

Accordingly, the distances between the condensate sheets vary and thus the capacities of the two Capacitors.

Before the start of the measurement, the two cross- sections 91 and 92 are set to a distance corresponding to the tooth pitch and the test piece 83 is brought into the measuring unit. Then, depending on the angular position of the two probes SO and 81, there is a very specific capacitance for the two capacitors 99/101 and 100/102.

Go ity value. The McßlastcrSI is used to determine the Mcßposition, since the test object 83 is to be moved continuously in the direction of the arrow 82 even in the present abundance. In the measurement the capacitor 100/102 gives a very specific capacitance

zitiitswerl, and the electrical measuring device described below ensures that at the moment when the capacitor 100/102 reaches this thus determined capacitance, the

7 8

then existing capacitance value of the capacitor recorded or recorded by means of a recorder

99/101 is switched to the measuring mechanism. Subsequently loudspeaker made audible, if necessary for

This is done with the help of the recording on tape described below.

Switching the carriage 86 with the help of the motor 87 The relay has the property that it is after a

and the rack 88 is retracted and drops again at an arbitrarily selectable time and thus

closing again towards the front into the measuring position. Display devices from the measuring device for the

brings, whereby the tips of the two probes 80 separates the capacitance value of the capacitor 99/101,

and 81 in the next tooth gaps of the next. Simultaneously with the relay is a second relay

the moving test specimen 83 intervene, which has been switched by the movement, the following properties

movement of the test object in the direction of arrow 82 to the system ίο is seated:

get to the tooth flanks and finally from the- This second relay speaks only after a broom Tooth flanks are taken along, whereby the correct delay time, z. B. half a pair of two Probe 80 and 81 announce the same direction on the received impulse, and it falls Perform swivel movement. During this loading after an arbitrarily adjustable period of movement process, the capacity value of the 15 itself changes again. The delay time of this relay Capacitor 100/102 until it is dimensioned in such a way that it is the one to be actuated by it, Capacitance value, which characterizes the measuring position, only initiates the switching process after the measurement reached, and only at this moment is it carried out and the first relay dropped again Capacitance value of the capacitor 99/101 on that is. It is switched on by the second relay electrical measuring mechanism switched. 20 third relay, the solenoid of which has a

The measuring pressure with which the tips of the two switches are connected to a voltage, whereby in

Probe 80 and 81 on the tooth flanks to rest in the same way as described above, the elec-

kofnmen, is determined by a restraint motor87 each via the contacts 107 in that one

springs 103 and 104, which also ensure that the direction of rotation is switched on.

the retraction of the slide 86 requires the sideways movement of the slide 86. There-

When the probes 80 and 81 are pivoted into a starting point, the first moves relative to the slide

position are returned, so that they are movable in the lead 86 and via a compression spring 108 against

of the slide 86 in the next tooth gaps the slide 86 supported rack from the test

of the moving test object can intervene. ling 83 away. This starts with the

The circuit of the measuring device and the switch 109 connected to the switching rack are closed device for the periodic movement of the slide 86 and then the slide 86 machined away from the test object as follows. In the course of the panning path. As soon as the second relay after a certain movement of the two probes 80 and 81 will drop again at the moment, so will that of this one next in an oscillating circuit the current capacitance relay operated switch in the circuit of the magnet change of the capacitor 100/102, which is opened by the coil of the third relay, so that this Pivoting movement of the probe 81 is caused, relay drops out, whereby the previously closed converted into a frequency and opened in a mixed contacts. But at the same time stage with one of another oscillating circuit, the other contacts are closed and thereby the supplied arbitrarily adjustable fixed frequency to the direction of rotation of the motor 87 reversed, since the superimposed on a superposition frequency, in a 40 mechanical, actuated by the rack 88 Amplifier amplified and then closed in a measuring switch 109. The carriage 86 is Value converter in current and voltage values as a result of the reversal of the direction of rotation of the motor 87 changed. At the moment when the condenser moves forward again into the measuring position where it is Sator 100/102 hits the previously determined capacitance value on the limiting strip 90 and to has achieved d. H. the moment the 45 comes to a standstill. The running motor 87 be measuring position but the toothed rack 88 still moves away from the continuously moving one The test item has been reached, continues from the direction just now, thereby reducing the direction of the rack described measuring device, a switching pulse is opened on connected switches and the motor 87 is silent Relay given, which is set briefly to the capacitance. To regulate the engine speed and value of the measuring capacitor 99/101 to the actual 50 thus the speed with which the carriage 86 Measuring mechanism switches. To evaluate the capacity is moved, the motor 87 is in its speed Change of what can be controlled by the swivel movement of the measuring device, which can be done by a potentiometer tasters 80 continuously variable capacitance value.

of the capacitor 99/101 is a similar circuit As already mentioned at the beginning, those of provided as for the evaluation of the capacitance measuring probe swiveled sideways to the test object 83 change of capacitor 100/102. The one on the 80/81 during the return movement of the carriage 86 The pivoting movement of the probe 80 is continuously moved by the restraint springs 103 and 104 into the extensible area Capacitance value of the capacitor 99/101 brought back the initial position and grabbed with their is converted into a frequency in an oscillating circuit. in a mixing stage with an adjustable, 60 position in the next tooth gaps of the in a further oscillating circuit generated fixed frequency further moving test specimen, so that in the sequence superimposed to a superimposition frequency, the described way the measurement processes for the individual closing amplified in an amplifier and automatically lined up in a row of tooth pitches, a transducer for current and voltage. The details to be protected result values converted. These current and voltage characteristics from the claims. Notes about it at the moment when the measurement is made from the details shown in the drawings position has been reached and the relay has been actuated should only serve for better explanation, it is bilist, indicated on a measuring instrument or by no part of the invention.

'. . ■ '109 635/28

The embodiment described is only one example of how the inventive concept is implemented can be. The invention also includes everything within the capabilities of a person skilled in the art lying further embodiments in which the in the claims expressed The basic idea of the invention is used constructively.

Claims (7)

Patent claims: 1.Automatically working gear testing device, especially for testing and measuring double flank generating errors, Runout, pitch, tooth thickness errors and tooth gap width errors toothed parts, with at least one probe carrying, periodically on the test, ling sledge moved in a straight line towards and away from it, with the movement of the slide or probe is displayed and / or registered by a measuring device, and in which the test object driven by its own power source, preferably non-stop, at low speed is pivotable while at least one on the linearly reciprocating slide arranged probe during the advance of the slide before reaching the measuring position in a Tooth gap of the test specimen introduced and taken along by the test specimen beyond the measuring position is, the probe executes a pivoting movement, and in the switching means are provided through which the straight forward and reverse travel of the carriage as a function is controlled by the pivoting movement of the probe, as well as means by which the The probe is swiveled back by an adjustable angle when the slide is reversing, after its probe tip has come out of engagement with the toothing of the test object, after Patent I 183700, characterized in that that on the periodically reciprocating carriage (86), as is known per se, two measuring probes (80, 81) which can be pivoted independently of one another against restoring forces are provided, that the measuring probes (80, 81) during the movement of the slide to be guided towards the test object (83) (86) in two adjacent gaps of the gear to be tested (83) up to the pitch circle can also be introduced that on the probes (80, 81) known devices for continuous measurement of their pivoting movement are attached and that the angular value of a swiveled out button (80, 81) when the other button (81, 80) passes through a certain one Measurement position and thus a certain angular value can be displayed or registered. 2. Testing device according to claim 1, characterized in that the device known per se for measuring the pivoting movement of the probes (80, 81) is an electronic arrangement. 3. Test device according to claim 2, characterized in that when the measuring position is reached triggered electronic pulse in a known manner according to an adjustable Delay time controls the return and subsequent advance of the carriage (86). 4. Test device according to claim 3, characterized in that the electronic Impuls_ein. ^{known per se, the switching on of the 4} 'electric motor (87) causing the forward and reverse movement and the program switching mechanism controlling its direction of rotation is switched on. 5. A test device according to claim 2, characterized in that the probes (80, 81) are connected to a capacitor of variable capacitance (99, 100; 101, 102) that changes in capacitance influence the frequency of each resonant circuit in a manner known per se and that the resulting frequencies are a measure of the swiveling out of the probe. 6. Testing device according to claim 5, characterized in that with each of the two pivotable measuring probes (80, 81) a capacitor plate (99, 100) is fixedly connected and that the movable capacitor plates (99, 100) each have a fixed capacitor plate (101 , 102) is arranged. 7. Testing device according to claim 1, characterized in that a restraining force applying restraining spring (103, 104) is attached to each of the two pivotable buttons (80, 81). 1 sheet of drawings