Abstract:
A device for checking the accuracy of coordinate positioning apparatus which includes a support, a head and components for measuring the coordinate position of the head relative to the support. The device comprises a bar, a connecting member movably securable to the support, a first universal pivot for supporting the bar at one end on the connecting member, a second universal pivot adapted for establishing a universal pivotable connection between the other end of the bar and the head, and a switch for producing a signal responsive to the head attaining a predetermined location in a coordinate field of the apparatus.

Description:
This invention is for an improvement relating to coordinate positioning apparatus and, more specifically, for a method of and device for checking the accuracy of such apparatus. 
     BACKGROUND OF THE INVENTION 
     It is usually required to determine the accuracy of coordinate positioning apparatus, for example coordinate measuring machines, and manual methods exist for doing so. For example, it is known to provide a test bar, operate the machine to measure the length of the bar in different locations of the bar in the coordinate field, and compare the possibly different results obtained at said different locations thereby to establish a measure of the accuracy of the apparatus. The bar itself has to be placed manually into the respective said positions, use being made of a frame or the line to support the bar in those positions. It is an object of this invention to provide a method of and device for checking coordinate positioning apparatus automatically or substantially automatically. 
     SUMMARY OF THE INVENTION 
     According to this invention there is provided a method of checking the accuracy of orthogonal coordinate positioning apparatus, the apparatus comprising a support, a head supported for three-dimensional movement relative to the support, and continually operative measuring means for measuring the position of the head in terms of three orthogonal coordinates; the method comprising providing a test bar, universally pivotally connecting the bar at its one end to the support and at its other end to the head, automatically and sequentially moving the head through a plurality of test locations situated about the connection of the bar to the support, the bar undergoing a corresponding angular movement by virtue of its connection to the head, and at each said location measuring the coordinate position of the head as determined by the length of the bar between said ends thereof. 
     The method according to this invention avoids the need to position the test bar manually and in this way reduces or avoids the difficulties of the known method. 
     Also according to this invention there is provided a device for checking coordinate positioning apparatus having a support, a head supported for three-dimensional movement relative to the support, and means for measuring the coordinate position of the head; the device comprising a bar, a mounting removeably securable to the support of the apparatus, first pivot means for supporting the bar at one end thereof for universal pivotal motion on said mounting, second pivot means provided at the other end of the bar and adapted for establishing a universal pivotal connection between said other end of the bar and the head of the machine, and means for producing a signal responsive to the head attaining a predetermined location in the coordinate field of the machine. 
     The device is intended for carrying out the method according to this invention, and said signal is used to effect the reading of said continually operative means for measuring the coordinate position of the head. 
    
    
     BRIEF DESCRIPTION OF DRAWINGS 
     In the accompanying drawings: 
     FIG. 1 is an elevation of a coordinate measuring machine and a checking device therefor. 
     FIG. 2 is an enlarged detail of FIG. 1 
     FIG. 3 is a view in the direction of the arrow III in FIG. 2. 
     FIG. 4 is a view similar to FIG. 1 in diagrammatic form. 
     FIG. 5 is a plan view of FIG. 4. 
     FIG. 6 is a flow diagram of a computer program. 
    
    
     DESCRIPTION OF PREFERRED EMBODIMENT 
     A preferred embodiment of the invention will now be described, by way of example, with reference to the above drawings. Refering to FIG. 1, the coordinate measuring machine, denoted 10, comprises a support or table 11 and a head 12 supported by slides 13,14,15 for three-dimensional movement in the directions X,Y,Z of the orthogonal coordinate system. The Y,Y,Z coordinates of the movement are measurable by continually operative opto-electronic scales 16,17,18 and cooperating counters 19,20,21. The slide movement is producable by motors eg. a motor 22 acting on the slide 13 through a belt 23. The motors eg. 22 are controlled by a control system 24 using the output of the counters as feedback. The control system 24 is operable by a program stored in a computer 31 to move the head to any given position within the range of the machine. The machine 10 is known per se and is normally used for measuring workpieces supported on the table 11. 
     A probe 26 (FIG. 2) comprises a housing 27 secured to the head 12 and a stylus 28 extending from the housing and having a spherical sensing element 29. Displacement of the sensing element from a rest position relative to the housing 27 causes separation of contacts 26B,26C provided respectively on the housing 27 and the stylus 28 and constituting a switch 26A in an electric circuit 26D. Separation of the contacts 26B, 26C changes the state of the circuit 26D in the sense of producing a signal 30 (FIG. 1) connected to pass the instantaneous content of the counters 19,20,21 to the computer 31. A spring 28A returns the element 29 to the rest position when the displacing force ceases. The probe 26 is known per se eg. from British Pat. No. 1,445,977. 
     The checking device, denoted 35, comprises a rigid bar 36 supported for universal pivotal motion by a pivot 37 provided at one end of the bar 36. The pivot 37 comprises a spherical head 38 provided at the upper end of a mounting 39 upstanding from and releasably securable to the table 11. The mounting 39 may eg. be secured to the table 11 by releasable clamps (not shown) in the same way as a workpiece to be measured by the machine. The pivot 37 is a kinematic pivot by virtue of three spherical elements 40 secured to the bar 36 to constitute a socket and engaging the head 38 under the weight of the bar 36. The bar 36 is substantially balanced by a counter weight 41. The arrangement is such that the bar 36 can readily be lifted from or placed on to the head 38. The end of the bar 36 adjacent the pivot 37 is defined by the center, 37A, of the spherical head 38. 
     At its other end the bar 36 has secured thereto a spherical abutment 42 and a guide means defined by two parallel rods 43 of cylindrical cross-section, as shown in FIG. 3. The abutment 42 lies essentially transverse to the longitudinal axis, 36A, of the bar 36 and the rods 43 extend parallel to the axis 36A. The stylus 28 is engageable with clearance between the rods 43 and the bar 36 is slightly unbalanced so as to engage the rods 43 on to the sensing element 29 with a light force. The sensing element 29 is movable along the rods 43 eg. between positions shown respectively in full and in broken lines and, as shown, the sensing element 29 is engageable with the abutment 42. At the instant of such an engagement the element 29 is displaced from its said rest position and the probe 26 produces the signal 30. The length of the bar is defined by a distance R, between the center 37A of the pivot 37 and the centre, 29A, of the sensing element 29 when the latter is in engagement with the abutment 42 and when the element 29 is said to be in a test location T. The pivot 45 is said to be at a stand-off location S when the sensing element 29 is clear of the abutment 42, eg. by a distance 44A, though still engaged with the rods 43. In this stand-off location of the pivot 45 there is no generation of the signal 30. The rods 43 constitute lost-motion means allowing relative movement of the element 29 and the pivot 37 between the stand-off and the test locations S,T so that strain between the head 12 and the bar 36 is avoided when moving from one test location to the next and the signal 30 is generated only when the test location itself is attained. The stylus 28 can be released from and engaged between the rods 43 at the free ends thereof. 
     The use of the device 35 will now be described with additional reference to FIGS. 4, 5 which show the element 29 in a first stand-off location S1 adjacent a first test location T1. FIGS. 4, 5 also show an array of other stand-off location S2 . . . Sn and corresponding test locations T2 . . . Tn. The test locations are of course determined by the length of the bar 36 and lie on a notional sphere. Similarly the stand-off locations lie on a sphere of somewhat larger radius than that of the test locations. The coordinate positions of the stand-off locations are defined by the X,Y,Z coordinates of the centre 29A relative to the centre 37A. These coordinates are conveniently pre-determined by manual methods and are listed in the program to be described. 
     By way of a manual initialisation routine, the operator secures the pivot 37 in a selected position on the table 11 and operates the machine to determine the coordinate position of the centre 37A. To this end the operator moves the head 12 to bring the element 29 sequentially into engagement with three points on the head 38 and initiates a program, held in the computer and known per se for determining the position XC,YC,ZC of the centre 37A in the coordinate field of the machine. Next, the operator determines the position of the centre 29A relative to the centre 37A by a procedure, also known per se, taking into account the radii of the head 38 and the element 29. 
     Next, the operator places the bar 36 on to the head 38 and moves the head 12 to engage the stylus between the rods 43 all as shown in FIGS. 1 and 2. The operator then moves the head 12 so that the element 29 approximately has the first stand-off location S1, and he starts the automatic part of the operation which is done on the basis of a program held in the computer 31 and now to be described. 
     The program comprises the following parameters: 
     Definitions: 
     MX=Motorized movement for X axis 
     MY=Motorized movement for Y axis 
     MZ=Motorized movement for Z axis 
     SX=Output of counter 19 
     SY=Output of counter 20 
     SZ=Output of counter 21 
     Constants: 
     n=Maximum number of points T to be measured 
     XC=X co-ordinate of center 37A 
     YC=Y co-ordinate of center 37A 
     ZC=Z co-ordinate of center 37A 
     XS=Array of X co-ordinates of n stand-off positions of center 29A 
     YS=Array of Y co-ordinates of n stand-off positions of center 29A 
     ZS=Array of Z co-ordinates of n stand-off positions of center 29A 
     Variables: 
     INDEX=Serial number (0 to n) of array elements 
     XT=Array of X co-ordinates of n positions of center 29A 
     YT=Array of Y co-ordinates of n positions of center 29A 
     ZT=Array of Z co-ordinates of n positions of center 29A 
     Refering now also to FIG. 6, the program comprises the following steps: 
     100 Start 
     101 Index: =0. Remark: this initializes the index 
     102 Index: =index+1. Remark: this increments the index to a current value 
     103 Move element 29 in a vector to co-ordinates XS(INDEX), YS(INDEX), ZS(INDEX). Remark: this moves the center 29A to the coordinate position of the stand-off location demanded by the current value of the index. 
     104 Move element 29 in a vector towards center 37A until occurrence of signal 30. Remark: this moves the element 29 toward the plate 42 to produce the signal 30. 
     105 XT(Index), YT(Index), ZT(index): =SX,SY,SZ. Remark: this determines the coordinate position of the center 29A at the instant of the signal 30. 
     106 Move probe 29 in a vector to XS(Index, YS(Index), ZS(Index). Remark: this returns the element 29 to the current stand-off position. 
     107 Calculate R (Index). Remark: this calculates the length R of the bar 36 on the basis of 
     
         R=√{}XT(Index)-XC].sup.2 +[YT(Index)-YC].sup.2 +[ZT(Index)-ZC].sup.2 }. 
    
     108 Repeat from 102 until index=n. Remark: this repeats steps 102 to 107 for each of the positions XS,YS,ZS. 
     109 End 
     It will be clear that, in the ideal machine, the values of R would be the same for all test locations T1 to Tn. In an actual machine these values differ and the program may be extended to establish the difference between the highest being a measure of the accuracy of the machine. Another such measure can be established by comparing the values of the X,Y or Z coordinates of all test points which should have identical such values. For example, in FIG. 5 the values of X1 and X8 should be identical but they may differ by a coordinate error, The elevation of such errors is known per se.