CN109916258A - Shift fork detection error assessment method - Google Patents

Abstract

Shift fork detection error assessment method, belongs to part error detection field, in order to solve the problems, such as comprehensive shift fork detection error evaluation, including manipulation bore dia evaluation；Control bore dia or radius evaluation；Two hole center size assessments；Operation hole upper surface planarity assessment, effect are that by comprehensive shift fork detection error evaluation.

Description

Shift fork detection error assessment method

Technical field

The present invention, which relates to, belongs to part error detection field, is related to a kind of shift fork detection error assessment method.

Background technique

Lathe shift fork class part is mainly used for machine tool control mechanism, changes lathe shifting slide gear position, realizes lathe speed change, Or engagement and release mechanism for controlling clutch, realize machine tool motion component laterally or longitudinally feed motion.Shift fork is usual It is made of the hole (operation hole) being assemblied in manipulation shaft parts and the half bore (control hole) being assemblied in control shaft parts, mainly Technical requirements have manipulation bore dia and deviation, control bore dia (or radius) and deviation, operation hole and control hole center ruler Very little and deviation, operation hole upper and lower end face depth of parallelism etc..

Lathe shift fork class part geometry size and Form and position error detection at present is primarily present low (the mechanical gauge inspection of detection accuracy Survey or detection indirectly), detection efficiency low (artificial detection or individual error detection), poor universality (a kind of size can only be detected Shift fork part) the problems such as.Since the control hole of shift fork class part is half bore, and the initial position of different shift fork half bore is different, The angle of half bore is different, and half bore to operation hole center requires difference, gives the center half bore dia (or radius) He Liangkong The detection of size brings larger difficulty.Traditional two hole center distance size detection is to measure size chain by solution, according to what is required Two hole center distance size and two pore radius sizes calculate bus bar sizes in two holes, measure bus bar sizes in two holes, judge two holes Whether in the range of requiring, this error judgement method can generate fake reject to center carpenters square cun, need to carry out fake reject into one Step detection, is a kind of Indirect Detecting Method, detection trouble, and detection accuracy is low.Poor universality is the detection of lathe shift fork mismachining tolerance Another restrict point, a set of detection device is only used for a kind of manipulation bore dia, controls in bore dia, operation hole and control hole Heart status requirement and the shift fork of size, manipulation hole end surface and control hole face height difference detect, any one ginseng in five parameters Several changes requires to design, produce and assemble another set of detection device.

Summary of the invention

In order to solve the problems, such as comprehensive shift fork detection error evaluation, the following technical solutions are proposed: a kind of shift fork by the present invention Detection error assessment method, including manipulation bore dia evaluation；Control bore dia or radius evaluation；Two hole center sizes are commented It is fixed；Operation hole upper surface planarity assessment.

Effective: the present invention can comprehensively acquire demand data to measuring point data acquisition device, thus, for demand Data, can be for operation hole, control bore dia evaluation, especially can be to two hole center size assessments, also, integrates Realize operation hole upper surface planarity assessment so that for shift fork detection error evaluate it is more acurrate and comprehensive.

Detailed description of the invention

Fig. 1 is 1 part drawing of lathe shift fork.

Fig. 2 is 2 part drawing of lathe shift fork.

Fig. 3 is 3 part drawing of lathe shift fork.

Fig. 4 is lathe shift fork class part comprehensive detection device main view.

Fig. 5 is lathe shift fork class part comprehensive detection device top view.

Fig. 6 is lathe shift fork class part comprehensive detection device side view.

Fig. 7 is lathe shift fork class part comprehensive detection device three-dimensional figure.

Fig. 8 is right Measuring plate part three-dimensional figure.

Fig. 9 is end slipway block part three-dimensional figure.

Figure 10 is transverse slipway block part three-dimensional figure.

Figure 11 is base part three-dimensional figure.

Figure 12 is lathe shift fork class part control hole positioning surface height adjustment schematic diagram.

Figure 13 is detection device respectively to movement schematic diagram.

Figure 14 is operation hole and control hole measuring point value arrangement map.

Figure 15 is operation hole upper surface measuring point value arrangement map.

Figure 16 is asymmetric control hole mounting means figure.

Figure 17 is lathe shift fork class part synthetic test program operation forms figure.

Figure 18 is lathe shift fork class part geometry size and Form and position error rate the process figure.

Figure 19 is Flatness error evaluation program operation forms figure.

Figure 20 is Flatness error evaluation flow chart.

Wherein: 1. bottom plates, 2. left Measuring plates, 3. left bevel gear wheels, 4. left bevel pinions, 5. left measuring claws, 6. left dislocations Sensor, 7. main measurement bays, 8. main measurement beams, 9. main measuring units, 10. status of a sovereign displacement sensors, 11. shift fork class parts, 12 right positions Displacement sensor, 13. right measuring claws, 14. right bevel gear wheels, 15. right bevel pinions, 16. right Measuring plates, 17. end slipway blocks, 18. transverse slipway block, 19. moving pins, 20. screw rods, 21. sleeves, 22. angled-lift splits, 23. springs, 24. nuts, 25. lead screws, 26. Handwheel.

Specific embodiment

Embodiment 1:Defect is detected for existing lathe shift fork class part geometry size and Form and position error, the present embodiment discloses It is a kind of for detecting the general comprehensive detection device of various sizes of lathe shift fork class part.It can be suitable for different manipulations Bore dia, different control bore dias, different operation holes and the requirement of control hole center and size, manipulation hole end surface and control hole The contour or not contour lathe shift fork class piece test in end face, versatility are good；It is detected using high accuracy displacement sensor, is directly examined Element to be measured is surveyed, measuring points placement is reasonable, and size and error evaluation method are reasonable, and detection accuracy is high；More sizes and error-detecting, Generating date, testing result real-time display, detection efficiency are high.

In geometric dimension and Form and position error evaluation, manipulation bore dia, control bore dia (or radius) He Liangkong centre bit Set that size is all made of least square method and minimum area method is directly evaluated, operation hole upper and lower end face parallelism error uses smallest region Domain method evaluation.

In geometric dimension and Form and position error assessment procedure, using VB6.0 programming language, using computer graphics techniques, Realize that detection scheme selection, online data acquisition and processing, data are manually entered and handle, geometric dimension and Form and position error are evaluated With the functions such as graphic plotting.Software interface layout is reasonable, and calling function is direct, easy to operate.

Fig. 1, Fig. 2 and Fig. 3 are the shift fork parts of three kinds of different shapes and size, and it is Φ 30H8mm that shift fork 1, which manipulates bore dia, Control pore radius is R51H10mm, and two hole centers are 90 ± 0.2mm of horizontal direction, and vertical direction is 64 ± 0.2mm, two holes Lower end surface is not contour, difference in height 5mm, and half bore is asymmetric with the two hole lines of centres, and 35 ° of initial angle, angle is 136 °；Shift fork 2 is grasped Vertical hole diameter is Φ 24H7mm, and control pore radius is R25H10mm, away from 84 ± 1.2mm centered on two hole centers, under two holes End face is not contour, difference in height 5.1mm, and half bore is symmetrical with the two hole lines of centres, and angle is 120 °；It is Φ that shift fork 3, which manipulates bore dia, 15H7mm, control bore dia are Φ 27H8mm, and away from 120 ± 0.1mm centered on two hole centers, two hole lower end surfaces are contour, half Hole is symmetrical with the two hole lines of centres, and angle is close to 180 °.In order to effectively work, shift fork half bore angle is generally at 120 °~180 ° Between, the control hole end surface end face close from manipulation hole end surface is known as lower end surface.

As shown in Figure 4, Figure 5, Figure 6 and Figure 7, the detection device is mainly by operation hole measurement disk component, control hole measurement Disk component, slideway block part and main frame member composition.The operation hole measurement disk component is by left Measuring plate 2, left auger tooth Wheel 3, left bevel pinion 4, left measuring claw 5, left position displacement sensor 6 form.The control hole measurement disk component is by right Measuring plate 16, right bevel gear wheel 14, right bevel pinion 15, right measuring claw 13, right displacement sensor 12 form.The slideway block part by End slipway block 17, transverse slipway block 18, moving pin 19, screw rod 20, sleeve 21, angled-lift splits 22, spring 23 form.The master Frame parts is by main measurement bay 7, main measurement beam 8, main measuring unit 9, status of a sovereign displacement sensor 10, nut 24, lead screw 25,26 groups of handwheel At.Fig. 4 horizontal direction is longitudinal (X to), and vertical direction is Z-direction, and Fig. 5 vertical direction is laterally (Y-direction).

Operation hole measurement disk component completes the shift fork positioning and detection of manipulation bore dia in a certain range, operation hole Measuring plate Component is mounted on bottom plate 1 by left Measuring plate 2, and die nut is inserted into the hexagonal of left 4 right end of bevel pinion in left Measuring plate 2 In hole, die nut is rotated, left bevel pinion 4 drives left bevel gear wheel 3 to rotate, and there is planar rectangular spiral shell in left 3 end face of bevel gear wheel Line drives equally distributed four left measuring claws 5 mounted thereto along left 2 end face upper open slot of Measuring plate Measuring plate to the left simultaneously 2 centers are close or exit, and four left measuring claws 5 drive four left position displacement sensors 6, and 2 center of Measuring plate is close to the left or moves back simultaneously Out, four left measuring claw move distances are equal, there is Self-centering Action, and the shift fork that manipulation bore dia in a certain range may be implemented is fixed Position and detection.

Control hole measurement disk component completes the shift fork positioning and detection of control hole diameter in a certain range, control hole Measuring plate Component is mounted on end slipway block 17 by right Measuring plate 16, and die nut is inserted into right bevel pinion 15 in right Measuring plate 16 In the hexagon ring of right end, die nut is rotated, right bevel pinion 15 drives right bevel gear wheel 14 to rotate, right 14 end face of bevel gear wheel There is planar rectangular screw thread, drives equally distributed eight right measuring claws 13 mounted thereto along right 16 end face upper open slot of Measuring plate 16 center of Measuring plate is close to the right or exits simultaneously, and eight right measuring claws 13 drive eight right displacement sensors 12 to survey to the right simultaneously Amount 16 center of disk is close or exits, and eight right measuring claw move distances are equal, have Self-centering Action, may be implemented in a certain range Control the shift fork positioning and detection of bore dia.Although fork controls hole is generally half bore and is even less than half bore, the starting of half bore Position is different, and the angle of half bore is different, so detection device is designed as eight equally distributed displacement sensors, guarantees various shapes The shift fork of shape can detect.

As shown in Fig. 8, Fig. 9, Figure 10, Figure 11, Figure 12, slideway block part completes operation hole and control hole difference center And the shift fork detection of size, control hole measurement disk component are located on end slipway block 17 by right Measuring plate 16, right Measuring plate The convex longitudinal direction dovetail guide above spill longitudinal direction dovetail guide and end slipway block 17 below 16 cooperates, and guide rail moves along longitudinal direction Right Measuring plate 16 is moved, X different between operation hole and control hole can be obtained to center size；End slipway block 17 is located at cross The convex transverse direction swallow above spill transverse direction dovetail guide and transverse slipway block 18 on slideway block 18, below end slipway block 17 The cooperation of tail guide rail, transversely guide rail pushes end slipway block 17, can obtain Y-direction center different between operation hole and control hole Size；Transverse slipway block 18 is connect by side vertical female dovetail guide rail with 1 side vertical male dovetail guide rail of pedestal, is rotated Screw rod 20 pushes angled-lift splits 22 to the left, is moved up by slope driving moving pin 19, realizes that transverse slipway block 18, longitudinal direction are sliding Road block 17 and control hole measurement disk component Z-direction move up, and contra rotating screw 20, screw rod 20 moves right, in compressed spring Under the action of 23, angled-lift splits 22 move right, and moving pin 19 moves down, and realize to slideway block 18, end slipway block 17 and control Drilling measurement disk component Z-direction moves down, to adjust the Z-direction position of right Measuring plate 16, makes its positioning surface and fork controls hole Lower end face contact, shift fork are placed steady reliable.

Main frame member completes the detection of shift fork operation hole upper and lower end face parallelism error, and main measurement beam 8 is mounted on main measurement On frame 7, main measuring unit 9 is connect by dovetail guide with main measurement beam, and status of a sovereign displacement sensor 10 is mounted in main measuring unit, main survey Amount set drives main displacement sensor 10 laterally (Y-direction) mobile along main measurement beam, and main measurement bay 7 passes through the silk of front and back two with pedestal 1 Thick stick 25 connects, and rotates the nut 24 of two 25 left ends of lead screw, and lead screw 25 rotates, and drives main measurement bay 7 to vertically move, to drive Status of a sovereign displacement sensor 10 longitudinal (X to) is mobile, completes status of a sovereign displacement sensor and detects in the sampling site of shift fork operation hole upper surface, rotation Handwheel 26 locks main measurement bay 7.

Before detection, each displacement sensing in detection device is adjusted by its standard shift fork part to a batch of shift fork part first Device position, the manipulation bore dia and control bore dia of standard shift fork part take the maximum limit of size of its design size, standard respectively Two hole center sizes of shift fork part take the median size of its design size.It is left that bore dia adjustment is manipulated according to standard shift fork part Four left measuring claw diametrical positions in Measuring plate control bore dia according to standard shift fork part and adjust eight right measurements in right Measuring plate Pawl diametrical position, according to standard shift fork part operation hole and control hole center requires and size, adjusts right Measuring plate longitudinal direction position Set (X to) and lateral position (Y-direction)；After adjusting above-mentioned position, the operation hole of shift fork and control hole lower end surface are inserted in respectively The left position displacement sensor of left measuring claw and the right displacement sensor of right measuring claw move down shift fork along axis until shift fork manipulates Hole lower end surface touches pedestal positioning support face, and fork controls hole lower end surface is hanging at this time, adjusts right Measuring plate vertical direction Position (Z-direction) makes right Measuring plate positioning support face and fork controls hole lower end face contact, each measuring point data of acquisition process.

As shown in figure 13, detection device shares 7 movements, the bidirectional-movement R1 including four left measuring claw radial directions, The bidirectional-movement R2 of eight right measuring claw radial directions, right Measuring plate (pawl) longitudinal movement X1, transverse movement Y1 and vertical direction Move Z1, the status of a sovereign displacement sensor longitudinal movement X2 and transverse movement Y2.

As shown in figure 14, detection device installs four displacement sensors in left Measuring plate, uniformly distributed in 90 °, measuring point 1, 2,3,4, eight displacement sensors are installed in right Measuring plate, measuring point 5,6,7,8,9,10,11 and 12 uniformly distributed in 45 °, this 12 transducer probe assemblies read detection data, calculate the center operation hole diameter control bore dia (or radius) He Liangkong ruler It is very little.As shown in figure 15, main measurement sensor can be moved with X to Y-direction, read I, II, III, IV, V section of operation hole upper surface Upper n data.Definition: the disc constructed by left Measuring plate, the direction of X-axis forward direction and the intersection point of circumference are measuring point 1, measuring point 1 90 ° of arrangement measuring points 2 are circumferentially rotated counterclockwise, and measuring point 2 circumferentially rotates 90 ° of arrangement measuring points 3,3 inverse time of measuring point counterclockwise Needle circumferentially rotates 90 ° of arrangement measuring points 4；The disc constructed by right Measuring plate, the direction of X-axis forward direction and the intersection point of circumference are Measuring point 5, measuring point 5 circumferentially rotate 45 ° of arrangement measuring points 6 counterclockwise, and measuring point 6 circumferentially rotates 45 ° of arrangement measuring points counterclockwise 7, circumferentially 45 arrangement measuring point 8 of rotation °, measuring point 8 circumferentially rotate 45 ° of arrangement measuring points 9 counterclockwise, survey measuring point 7 counterclockwise Point 9 circumferentially rotates 45 ° of arrangement measuring points 10 counterclockwise, and measuring point 10 circumferentially rotates 45 ° of arrangement measuring points 11, measuring point counterclockwise 11 circumferentially rotate 45 ° of arrangement measuring points 12 counterclockwise, and measuring point corresponding position installs respective sensor 1-12, are sensor by a left side The section of the disc of Measuring plate construction, Y direction and manipulation hole end surface is III section, is arranged I section in the left side of II section line Face, in the right side of IV section line V section of arrangement.

Testing principle:

1. manipulating bore dia, the control center bore dia (or radius) He Liangkong size detection principle

For symmetrical expression shift fork shown in Fig. 2 and Fig. 3, the measuring point that works is 1,2,3,4,8,9,10.For asymmetric shown in Fig. 1 There are two types of design requirement, a kind of requirement guarantee two hole center distance L, a kind of requirements for formula shift fork, operation hole and control hole center Guarantee between two holes X to the size Ly of Lx and Y-direction.

As shown in figure 16, there are three types of laying method A, B, C in the detection device, A scheme is Fig. 1 asymmetric shift fork Left measuring claw is inserted in standard shift fork part operation hole lower end surface, and operation hole center is O1, adjusts longitudinal position of right measuring claw center O2 Set, obtain the X of O1O2 to distance Lx be 90mm, to 0-0 line below the right measuring claw center O2 of (-) adjustment lateral position, obtain The Y-direction distance Ly of O1O2 is 64mm, and the measuring point of control hole half bore is 6,7,8 and 9；B scheme is right measuring claw center O2 in 0-0 line On, by shift fork two hole center distance 110.4355mm adjusts the lengthwise position of O2, obtains the X of O1O2 to distance 110.4355mm, The measuring point of control hole half bore is 7,8 and 9；C scheme is to adjust the lengthwise position of right measuring claw center O2, obtain the X of O1O2 to away from It is 64mm from Lx, to the lateral position of 0-0 line top (+) the right measuring claw center O2 of adjustment, the Y-direction distance Ly for obtaining O1O2 is 90mm, the measuring point of control hole half bore are 8,9,10 and 11.It is different from control hole center that the detection device meets operation hole on part Design size require detection, if part drawing (Fig. 1) is required of operation hole and control hole center X-direction size, with side Case A；If part drawing (Fig. 1) is required of operation hole and control hole center line connecting direction size, option b is used；If part drawing (Fig. 1) is required of operation hole and control hole center Y-direction size, with scheme C.

2. the operation hole upper and lower end face depth of parallelism surveys principle

As shown in figure 15, main displacement sensors X is to mobile with Y-direction, read operation hole upper surface I, II,

III, n data on IV, V section.

Error evaluation method:

1. manipulating bore dia, the control center bore dia (or radius) He Liangkong size assessment

As shown in Figure 17 and Figure 18, bore dia is manipulated, the control center bore dia (or radius) He Liangkong size is adopted It is directly evaluated with least square method.With least square method fitting operation hole circle, central coordinate of circle (a is obtained₁, b1), diameter d₁, according to Known designs require judge whether manipulation bore dia is qualified；With least square method fitting control hole circle, central coordinate of circle (a is obtained₂, b₂), diameter d₂(radius r₂), require judge whether control bore dia is qualified according to Known designs；If symmetrical shift fork or non-right Title formula shift fork is by two hole center distance requirement center or that asymmetric shift fork is detected by B scheme installation in Figure 16, two holes Center away fromIf size Ly requirement of the asymmetric shift fork by X between two holes to Lx and Y-direction Center, then, and L_x=a₂-a₁, L_y=| b₂-b₁|。

If measuring point 1,2 ... the measurement decrement of 12 displacement sensors is Δ_i, i=1,2 ... 12, due to each measuring point displacement Sensor is returned to zero by the standard shift fork part of dimension series production, so 1,2,3,4 measuring point radius initial values are maximum pole Limit radius R_1max, 5,6 ... 12 measuring point radius initial values are greatest limit radius R_2max, operation hole central coordinate of circle is (x₀₁,y₀₁), control Drilling central coordinate of circle is (x₀₂,y₀₂), each measuring point coordinate is (x_i,y_i), each measuring point and x-axis forward direction angle are θ_i, measuring point number is n, Then operation hole any point coordinate are as follows:

x_i=x₀₁+(R_1max-Δ_i)·cosθ_i, i=1,2,3,4 (1)

y_i=y₀₁+(R_1max-Δ_i)·sinθ_i, i=1,2,3,4 (2)

Control hole any point coordinate are as follows:

x_i=x₀₂+(R_2max-Δ_i)·cosθ_i, i=5,6 ... 12 (3)

y_i=y₀₂+(R_2max-Δ_i)·sinθ_i, i=5,6 ... 12 (4)

Two bore dias (radius) and center are solved away from and judging whether the size closes with least square method fitting circle formula Lattice, operation hole is identical with control hole calculation method, and least square method fitting circule method solves fitting circle central coordinate of circle (a, b) and radius R method is as follows:

X1=∑ x_i, y1=∑ y_i,

X1y1=∑ x_iy_i,

It enables:

C=nx2-x1², d=nx1y1-x1y1, e=nx3+nx1y2- (x2+y2) x1

G=ny2-y1², h=nx2y1+ny3- (x2+y2) y1

Ta=(hd-eg)/(cg-dd), tb=(hc-ed)/(dd-cg)

Tc=- (tax1+tby1+x2+y2)/n

Then fitting circle central coordinate of circle (a, b): a=-ta/2, b=-tb/2

It is fitted radius of circle r:Wherein c, d, e, g, h, ta, tb, tc are intermediate change Amount.

Since control hole is half bore, measuring point 5,6 ... 12 is not all participation measurements, and different shift fork half bore initial angles It is all different with half bore angle, needs to judge and record which measuring point participates in work, and evaluate according to corresponding measuring point.

2. operation hole upper surface Flatness error evaluation

Operation hole upper surface flatness error is using status of a sovereign displacement sensor in I, II, III, IV, V section of operation hole upper surface Upper n detection data calculates, and operation hole upper surface flatness is fitted datum plane using least square method, establishes plane regression side Journey realizes upper surface Flatness error evaluation.Least square method fit Plane method is as follows:

If Point Coordinates P (xi, yi, zi) in plane, n point, fit Plane equation: Z=AX+BY+C asks A, B, C, Least square method fit Plane T:

If:Xy=∑ x_iy_i, x1=∑ x_i,Y1=∑ y_i,

Xz=∑ x_iz_i, yz=∑ y_iz_i, z1=∑ z_i

Then formula (5) is write as:

Fit Plane equation coefficient:

Then fit Plane equation are as follows: Z=AX+BY+C (7)

Wherein Δ, Δ x, Δ y, Δ z are intermediate variable.

Arbitrary point Fitting Coordinate System Pn (xi, yi, zin) in fit Plane is found out by equation 7

Find out the Z-direction difference fzi=zi-zin of each measurement point P and match point Pn

Then flatness error f=max (fzi)-min (fzi)

3. the operation hole upper and lower end face depth of parallelism is evaluated

The operation hole upper and lower end face depth of parallelism is evaluated using minimum area method, operation hole lower end surface is benchmark face and is ideal base Quasi- face finds out the maximum difference of status of a sovereign displacement sensor n detection data on I, II, III, IV, V section of operation hole upper surface, As operation hole upper and lower end face parallelism error.

Figure 17 is lathe shift fork class part synthetic test program operation forms figure, and Figure 18 is lathe shift fork class part geometry ruler Very little and Form and position error rate the process figure gives specific deterministic process, and determines that result is shown.And Figure 19, Figure 20 are pair The procedural representation and result of the Flatness error evaluation method are shown.

Embodiment 2:A kind of lathe shift fork class part comprehensive detection device mainly measures disk component, control hole by operation hole Disk component, slideway block part and main frame member composition are measured, the shift fork that operation hole measurement disk component is used to manipulate bore dia is fixed Position and detection, control hole measurement disk component is used to control the shift fork positioning of bore dia and detection, slideway block part are used for operation hole The detection of the shift fork of centers different with control hole and size, main frame member are missed for the shift fork operation hole upper and lower end face depth of parallelism Difference detection.

The described operation hole measurement disk component by left Measuring plate 2, left bevel gear wheel 3, left bevel pinion 4, left measuring claw 5, Left position displacement sensor 6 forms；Left Measuring plate 2 is mounted on bottom plate 1, and left bevel gear wheel 3, left bevel pinion 4 are mounted on left Measuring plate 2 In, left bevel pinion 4 has driving hole, the radial teeth of the dish-shaped bevel gear of left 4 circumferential surface of bevel pinion and left 3 back side of bevel gear wheel Wheel engagement, left 3 front of bevel gear wheel have circumferentially distributed planar circular rectangular thread, and several measuring claws uniformly divide in disk Cloth, the screw thread of measuring claw lower end surface are engaged with the positive planar circular rectangular thread of left bevel gear wheel 3, have barrier between measuring claw The guiding mechanism that measuring claw circumferentially moves, guiding mechanism and left 2 integrally connected of Measuring plate so that each measuring claw in radial direction Xiang Yuan The center of circle of plane is close to or far from the circumferential surface of each measuring claw on the outside installs displacement sensor, and the left measuring claw 5 has four It is a, drive displacement sensor to the center of circle of disk close to or far to realize to sensor in the direction (diameter from measuring claw To) movement.

The control hole measurement disk component is by right Measuring plate 16, right bevel gear wheel 14, right bevel pinion 15, right measuring claw 13, right displacement sensor 12 forms, and right Measuring plate 16 is mounted on end slipway block 17, right bevel gear wheel 14, right bevel pinion 15 are mounted in right Measuring plate 16, and right bevel pinion 15 has driving hole, the dish-shaped bevel gear of right 15 circumferential surface of bevel pinion and the right side The radial gear at 14 back side of bevel gear wheel engages, and right 14 front of bevel gear wheel has circumferentially distributed planar circular rectangular thread, Several measuring claws are uniformly distributed in disk, the screw thread of measuring claw lower end surface and the positive planar circular rectangle of right bevel gear wheel 14 Screw thread engages, and the guiding mechanism that there is barrier measuring claw circumferentially to move between measuring claw, guiding mechanism integrally connects with right Measuring plate 16 It connects, so that each measuring claw is in radial direction and to the center of circle of disk close to or far from the circumferential surface of each measuring claw on the outside installs displacement Sensor, the right measuring claw 13 have eight, drive displacement sensor close or remote to the center of circle of disk from measuring claw From to realize to sensor the direction (radial direction) movement.

The slideway block part by end slipway block 17, transverse slipway block 18, moving pin 19, screw rod 20, sleeve 21, tiltedly Sliding block 22, spring 23 form；Right Measuring plate 16 has spill longitudinal direction dovetail guide below, and end slipway block 17 has convex above Longitudinal dovetail guide, the two cooperation so that right Measuring plate 16 can end slipway block 17 guide rail along longitudinal sliding motion；It is vertical There is spill transverse direction dovetail guide, transverse slipway block 18 has convex transverse direction dovetail guide, the two above below to slideway block 17 Cooperation so that end slipway block 17 can transverse slipway block 18 guide rail along sliding laterally；18 lateral surface of transverse slipway block With plummet female dovetail guide rail, pedestal medial surface has plummet male dovetail guide rail, and the two cooperates so that transverse slipway block 18 can slide in the guide rail of pedestal along plummet direction；Angled-lift splits 22 are located at the lower section of transverse slipway block 18, and transverse slipway Below block 18 between the lateral inclination face of angled-lift splits 22, below this and inclined surface is supported by moving pin 19, the cunning Motion block is located in the lateral sleeve 21 below pedestal, the front end of angled-lift splits 22 entered laterally inside sleeve 21, with sleeve Connected between 21 walls by spring 23, the lateral end of angled-lift splits 22 is threadedly coupled with screw rod 20.It is rotated by screw rod 20 to angled-lift splits 22 Into deep-controlled inside sleeve 21, and enter by angled-lift splits 22 change of the depth inside sleeve 21, and described in causing The different height face in the lateral inclination face of angled-lift splits 22 is contacted with moving pin 19, and controls the vertically movable of moving pin 19, with To the vertically movable direction of transverse slipway block 18 and distance controlling.

The main frame member is by main measurement bay 7, main measurement beam 8, main measuring unit 9, status of a sovereign displacement sensor 10, nut 24, lead screw 25, handwheel 26 form；Main measurement bay 7 is two brackets, is erected at 1 two sides of bottom plate, and the bracket of each side and bottom plate 1 Lead screw 25 thereon connects, so that lead screw 25 is laterally along the movement of lead screw 25, two brackets are by main measurement beam 8 in longitudinal direction It connects, there is convex longitudinal direction dovetail guide below main measurement beam 8, main measuring unit 9 has spill longitudinal direction dovetail guide, main displacement Sensor 10 is mounted in main measuring unit 9 and is suspended on the chassis and operation hole measurement disk component, control hole measurement pan portion The top of part.Nut 24 is installed in one end of lead screw 25, is controlled with rotating to lead screw 25.

A kind of comprehensive measuring point data acquisition method of lathe shift fork class part, includes the following steps:

Step 1 adjusts each displacement sensor position in detection device by standard shift fork part to a batch of shift fork part Set: the manipulation bore dia and control bore dia of standard shift fork part take the maximum limit of size of its design size, standard shift fork respectively Two hole center sizes of part take the median size of its design size；Bore dia, which is manipulated, according to standard shift fork part adjusts left measurement The diametrical position of four left measuring claws in disk controls bore dia according to standard shift fork part and adjusts eight right measuring claws in right Measuring plate Diametrical position；According to standard shift fork part operation hole and control hole center requires and size, adjusts right Measuring plate longitudinal direction position It sets and lateral position；

The left position displacement sensor of the left measuring claw of step 2 is packed by the operation hole of shift fork, the right displacement sensing of right measuring claw Device is packed by the control hole of shift fork, moves down shift fork along axis until shift fork operation hole lower end surface touches pedestal positioning support Face, and fork controls hole lower end surface is hanging, adjusts the position of right Measuring plate vertical direction, makes right Measuring plate positioning support face and dials The lower end face contact for pitching control hole, acquires and handles each measuring point data；

Step 3 detection device acquisition measuring point data shares 7 movements, two-way including four left measuring claw radial directions Movement, the bidirectional-movement of eight right measuring claw radial directions, right Measuring plate longitudinal movement, transverse movement and vertical direction movement, The longitudinal movement of status of a sovereign displacement sensor and transverse movement；Detection device installs four displacement sensors in left Measuring plate, in 90 ° Cloth, measuring point 1,2,3,4 install eight displacement sensors in right Measuring plate, uniformly distributed in 45 °, measuring point 5,6,7,8,9,10, 11 and 12, this 12 displacement sensor gauge heads read detection data, calculate operation hole diameter control pore radius and two hole centers Position dimension, main measurement sensor read the n on I, II, III, IV, V section of operation hole upper surface in horizontal and vertical movement A data.

Definition: the disc constructed by left Measuring plate, the direction of X-axis forward direction and the intersection point of circumference are measuring point 1, and measuring point 1 is inverse Hour hands circumferentially rotate 90 ° of arrangement measuring points 2, and measuring point 2 circumferentially rotates 90 ° of arrangement measuring points 3 counterclockwise, and measuring point 3 is counterclockwise Circumferentially rotate 90 ° of arrangement measuring points 4；The disc constructed by right Measuring plate, the direction of X-axis forward direction and the intersection point of circumference are to survey Point 5, measuring point 5 circumferentially rotate 45 ° of arrangement measuring points 6 counterclockwise, and measuring point 6 circumferentially rotates 45 ° of arrangement measuring points 7 counterclockwise, Circumferentially 45 arrangement measuring point 8 of rotation °, measuring point 8 circumferentially rotate 45 ° of arrangement measuring points 9, measuring point 9 to measuring point 7 counterclockwise counterclockwise 45 ° of arrangement measuring points 10 are circumferentially rotated counterclockwise, and measuring point 10 circumferentially rotates 45 ° of arrangement measuring points 11, measuring point 11 counterclockwise 45 ° of arrangement measuring points 12 are circumferentially rotated counterclockwise, and measuring point corresponding position installs respective sensor 1-12, is sensor by left survey Measure disk construction disc, Y direction and manipulation hole end surface section be III section, II section line left side arrange I section, In the right side of IV section line V section of arrangement.

A kind of control hole installation method of asymmetric shift fork detection, has following three kinds of installation methods:

The detection device meets the detection that the design size that operation hole is different from control hole center on part requires, if zero Part figure (Fig. 1) is required of operation hole and control hole center X-direction size, uses option A；If part drawing (Fig. 1) is required of Operation hole and control hole center line connecting direction size, use option b；If part drawing (Fig. 1) is required of operation hole and control hole Center Y-direction size, with scheme C.

A: left measuring claw is packed into standard shift fork part operation hole, and operation hole center is O1, adjusts the vertical of right measuring claw center O2 To position, obtain the X of O1O2 to distance Lx be 90mm, to 0-0 line below the right measuring claw center O2 of (-) adjustment lateral position, The Y-direction distance Ly for obtaining O1O2 is 64mm, and the measuring point of control hole half bore is 6,7,8 and 9；

B: right measuring claw center O2 on 0-0 line, longitudinal position of O2 is adjusted by shift fork two hole center distance 110.4355mm It sets, obtains the X of O1O2 to distance 110.4355mm, the measuring point of control hole half bore is 7,8 and 9；

C: adjusting the lengthwise position of right measuring claw center O2, obtain the X of O1O2 to distance Lx be 64mm, to above 0-0 line (+) adjusts the lateral position of right measuring claw center O2, and the Y-direction distance Ly for obtaining O1O2 is 90mm, and the measuring point of control hole half bore is 8,9,10 and 11.

A kind of shift fork detection error assessment method, including

Manipulate bore dia evaluation；

Control bore dia or radius evaluation；

Two hole center size assessments.

The error evaluation method is evaluated using least square method, with least square method fitting operation hole circle, is justified Heart coordinate (a₁, b1), diameter d₁, require judge whether manipulation bore dia is qualified according to Known designs；It is fitted and is controlled with least square method Drilling circle, obtains central coordinate of circle (a₂,b₂), diameter d₂Or radius r₂, require to judge to control whether bore dia closes according to Known designs Lattice；If symmetrical shift fork or asymmetric shift fork by two hole center distance requirement center or asymmetric shift fork press it is as follows Mode installs detection, two hole center distanceIf asymmetric shift fork press two holes between X to The Lx and size Ly of Y-direction requires center, then, L_x=a₂-a₁, L_y=| b₂-b₁|；

Described installing such as under type is: right measuring claw center O2 is on 0-0 line, by shift fork two hole center distance 110.4355mm adjusts the lengthwise position of O2, obtains the X of O1O2 to distance 110.4355mm, the measuring point of control hole half bore is 7, 8 and 9.

If measuring point 1,2 ... the measurement decrement of 12 displacement sensors is Δ_i, i=1,2 ... 12, each measuring point displacement sensing For device by the standard shift fork part zeroing of current dimension series production to be measured, 1~4 measuring point radius initial value is greatest limit radius R_1max, 5~12 measuring point radius initial values are greatest limit radius R_2max, operation hole central coordinate of circle is (x₀₁,y₀₁), the control hole center of circle Coordinate is (x₀₂,y₀₂), each measuring point coordinate is (x_i,y_i), each measuring point and x-axis forward direction angle are θ_i, measuring point number is n, then operation hole Any point coordinate are as follows:

x_i=x₀₁+(R_1max-Δ_i)·cosθ_i, i=1,2,3,4 (1)

y_i=y₀₁+(R_1max-Δ_i)·sinθ_i, i=1,2,3,4 (2)

Control hole any point coordinate are as follows:

x_i=x₀₂+(R_2max-Δ_i)·cosθ_i, i=5,6 ... 12 (3)

y_i=y₀₂+(R_2max-Δ_i)·sinθ_i, i=5,6 ... 12 (4)

With least square method fitting circle formula solve two bore dias and center away from or two pore radius and center away from and judging Whether the size is qualified, and operation hole is identical with control hole calculation method.Least square method fitting circule method solves fitting circle center of circle seat It marks (a, b) and radius r method is as follows.

X1=∑ x_i, y1=∑ y_i,

X1y1=∑ x_iy_i,

It enables:

C=nx2-x1², d=nx1y1-x1y1, e=nx3+nx1y2- (x2+y2) x1

G=ny2-y1², h=nx2y1+ny3- (x2+y2) y1

Ta=(hd-eg)/(cg-dd), tb=(hc-ed)/(dd-cg)

Tc=- (tax1+tby1+x2+y2)/n

Then fitting circle central coordinate of circle (a, b): a=-ta/2, b=-tb/2

It is fitted radius of circle r:Wherein c, d, e, g, h, ta, tb, tc are intermediate change Amount.

Since control hole is half bore, measuring point 5,6 ... 12 is not all participation measurements, and different shift fork half bore initial angles It is all different with half bore angle, needs to judge and record which measuring point participates in work, and evaluate according to corresponding measuring point.

Upper surface flatness error is using the status of a sovereign displacement sensor n on I, II, III, IV, V section of operation hole upper surface Detection data calculates, and operation hole upper surface flatness is fitted datum plane using least square method, establishes plane regression equation, real Existing upper surface Flatness error evaluation.Least square method fit Plane method is as follows:

If Point Coordinates P (xi, yi, zi) in plane, n point,

Fit Plane equation: Z=AX+BY+C asks A, B, C

Least square method fit Plane T:

If:Xy=∑ x_iy_i, x1=∑ x_i,Y1=∑ y_i,

Xz=∑ x_iz_i, yz=∑ y_iz_i, z1=∑ z_i

Then formula (5) is write as:

Fit Plane equation coefficient:

Then fit Plane equation are as follows: Z=AX+BY+C (7)

Wherein Δ, Δ x, Δ y, Δ z are intermediate variable.

Arbitrary point Fitting Coordinate System Pn (xi, yi, zin) in fit Plane is found out by equation 7

Find out the Z-direction difference fzi=zi-zin of each measurement point P and match point Pn

Then flatness error f=max (fzi)-min (fzi).

Error evaluation method further includes the upper and lower faces parallel measurement of operation hole: evaluating operation hole using minimum area method The upper and lower end face depth of parallelism, operation hole lower end surface is benchmark face and is ideal datum level, finds out status of a sovereign displacement sensor on operation hole The maximum difference of n detection data, as operation hole upper and lower end face parallelism error on I, II, III, IV, V section of end face.

The preferable specific embodiment of the above, only the invention, but the protection scope of the invention is not It is confined to this, anyone skilled in the art is in the technical scope that the invention discloses, according to the present invention The technical solution of creation and its inventive concept are subject to equivalent substitution or change, should all cover the invention protection scope it It is interior.

Claims (6)

1. a kind of shift fork detection error assessment method, which is characterized in that including

Manipulate bore dia evaluation；

Control bore dia or radius evaluation；

Two hole center size assessments；

Operation hole upper surface planarity assessment.

2. shift fork detection error assessment method as described in claim 1, which is characterized in that the error evaluation method uses Least square method evaluation obtains central coordinate of circle (a with least square method fitting operation hole circle₁, b1), diameter d₁, set according to known Meter requires judge whether manipulation bore dia is qualified；With least square method fitting control hole circle, central coordinate of circle (a is obtained₂,b₂), diameter d₂Or radius r₂, require judge whether control bore dia is qualified according to Known designs；If symmetrical shift fork or asymmetric shift fork By two hole center distance requirement center or asymmetric shift fork as follows install detection, two hole center distanceIf asymmetric shift fork is by X between two holes to the size Ly requirement centre bit of Lx and Y-direction It sets, then, and L_x=a₂-a₁, L_y=| b₂-b₁|；

Described installing such as under type is: right measuring claw center O2 is come on 0-0 line by shift fork two hole center distance 110.4355mm The lengthwise position for adjusting O2 obtains the X of O1O2 to distance 110.4355mm, and the measuring point of control hole half bore is 7,8 and 9.

3. shift fork detection error assessment method as described in claim 1, which is characterized in that set measuring point 1,2 ... 12 displacement sensings The measurement decrement of device is Δ_i, i=1,2 ... 12, the standard that each measuring point displacement sensor is made by current dimension series to be measured The zeroing of shift fork part, 1~4 measuring point radius initial value are greatest limit radius R_1max, 5~12 measuring point radius initial values are greatest limit Radius R_2max, operation hole central coordinate of circle is (x₀₁,y₀₁), control hole central coordinate of circle is (x₀₂,y₀₂), each measuring point coordinate is (x_i,y_i), Each measuring point and x-axis forward direction angle are θ_i, measuring point number is n, then operation hole any point coordinate are as follows:

x_i=x₀₁+(R_1max-Δ_i)·cosθ_i, i=1,2,3,4 (1)

y_i=y₀₁+(R_1max-Δ_i)·sinθ_i, i=1,2,3,4 (2)

Control hole any point coordinate are as follows:

x_i=x₀₂+(R_2max-Δ_i)·cosθ_i, i=5,6 ... 12 (3)

y_i=y₀₂+(R_2max-Δ_i)·sinθ_i, i=5,6 ... 12 (4)

With least square method fitting circle formula solve two bore dias and center away from or two pore radius and center away from and judging the ruler Whether very little qualified, operation hole is identical with control hole calculation method, least square method fitting circule method solve fitting circle central coordinate of circle (a, B) and radius r method is as follows:

X1=∑ x_i

Y1=∑ y_i

X1y1=∑ x_iy_i

It enables:

C=nx2-x1²

D=nx1y1-x1y1

E=nx3+nx1y2- (x2+y2) x1

G=ny2-y1²

H=nx2y1+ny3- (x2+y2) y1

Ta=(hd-eg)/(cg-dd)

Tb=(hc-ed)/(dd-cg)

Tc=- (tax1+tby1+x2+y2)/n

Then fitting circle central coordinate of circle (a, b):

A=-ta/2

B=-tb/2

It is fitted radius of circle r:

Wherein c, d, e, g, h, ta, tb, tc are intermediate variable.

4. shift fork detection error assessment method as claimed in claim 3, which is characterized in that since control hole is half bore, measuring point 5,6 ... 12 be not all to participate in measurement, and different shift fork half bore initial angles and half bore angle is all different, and needs to judge simultaneously It records which measuring point participates in work, and is evaluated according to corresponding measuring point.

5. shift fork detection error assessment method as claimed in claim 3, which is characterized in that operation hole upper surface flatness error Using status of a sovereign displacement sensor, n detection data is calculated on I, II, III, IV, V section of operation hole upper surface, using least square Method is fitted datum plane, establishes plane regression equation, realizes upper surface Flatness error evaluation, least square method fit Plane side Method is as follows:

If Point Coordinates P (xi, yi, zi) in plane, n point is shared,

Fit Plane equation: Z=AX+BY+C asks A, B, C

Least square method fit Plane T:

If:Xy=∑ x_iy_i, x1=∑ x_i,Y1=∑ y_i, xz=∑ x_iz_i, yz=∑ y_iz_i, Z1=∑ z_i

Then formula (5) is write as:

Fit Plane equation coefficient:

Then fit Plane equation are as follows: Z=AX+BY+C (7)

Wherein Δ, Δ x, Δ y, Δ z are intermediate variable.

Arbitrary point Fitting Coordinate System Pn (xi, yi, zin) in fit Plane is found out by equation 7

Find out the Z-direction difference fzi=zi-zin of each measurement point P and match point Pn

Then flatness error f=max (fzi)-min (fzi).

6. shift fork detection error assessment method as claimed in claim 3, which is characterized in that further include the upper and lower end face of operation hole Depth of parallelism measurement: the operation hole upper and lower end face depth of parallelism is evaluated using minimum area method, operation hole lower end surface is benchmark face and is reason Think datum level, the maximum for finding out status of a sovereign displacement sensor n detection data on I, II, III, IV, V section of operation hole upper surface is poor Value, as operation hole upper and lower end face parallelism error.