专利摘要:
1452800 Machine tool control of dimensions CROSS CO 18 March 1974 [16 May 1973] 11916/74 Heading B3B [Also in Division G3] The position of a tool, e.g. in a boring machine is continuously adjusted in accordance with the dimensional error in a workpiece, measured after the workpiece has been machined. As shown the error at 30, measured, e.g. using air gauge, is an analogue signal dependent upon the magnitude and direction of the error, which is sampled, memorized on a capacitor 40 and compared in machine tool logic 48 with preset error limits. If the error is within these limits, a tool position adjusting motor 54 is energized in a forward or reverse direction, according to the direction of the error, so that the error is eliminated in the next workpieee. If the error is outside the limits for a given number, e.g. three workpieces, motor 54 is energized, the system thus compensating for progressive tool wear but does not respond to isolated errors for example, due to material hardness. The logic 48 is inhibited unless the tool is in a non-working position, under manual control or within preset tool adjustment limits as set by limit switch 70. Potentiometer 62, also driven by the tool adjusting motor 54, provides a signal dependent upon the tool adjustment made, that is fed back to machine logic 48 to be compared with the desired tool position change. Details of the tool adjustment are given (see Division B3).
公开号:SU793364A3
申请号:SU742024402
申请日:1974-05-15
公开日:1980-12-30
发明作者:Лайонелл Чиновет Лоуренс;Отто Теч Курт
申请人:Дзе Кросс Компани (Фирма);
IPC主号:
专利说明:

(54) POSITION REGULATORY SYSTEM The invention relates to a tool position adjustment system and is intended to compensate for the wear of the tool of a metal cutting machine. The known tool position control system, which contains the mechanism for adjusting tool movements, the unit for measuring the deviation of the actual part size from the specified one and the counter for the number of deviations exceeding the upper and lower specified limits of the control zone. A disadvantage of the known control system is the high accuracy when machining the part due to the impossibility of a small tool rewrite. in the control zone bounded by the upper and lower limits. The goal of the proposed tool position control system is to improve the accuracy of machining parts. . The proposed tool position control system, which contains the mechanism for adjusting the tool movements, the unit measuring the deviations of the actual size of the tool from the given part and the counter of the number of deviations exceeding the upper and lower specified limits of the control zone, is equipped with a block for compensating the deviations of the part dimensions in the control zone, connected by its input to the output of the measuring unit, and output to the mechanism of sub-adjustment movements of the tool. FIG. Figure 1 shows schematically a preferred embodiment of a tool position adjustment system according to the invention in combination with a size sensor, a boring machine and a conveyor, each of which cooperates with several blanks located in the conveyor j in FIG. 2 is a block diagram of the system in FIG. 3 - logical device for automatic instrument setting; in fig. 4 shows a preferred embodiment of the tool setting mechanism of the tool wear compensation system; in fig. 5 is a section A-A in FIG. 4; in fig. 6 - limiting the device arrangement of the adjustment movement mechanism. Section BB in FIG. 4,.
Wear compensation system for a horizontal boring machine 1 (see figure 1); contains a control unit 2 which is associated with a tool setting mechanism 3 and a size sensor 4. The tool position control system and the boring machine 1 are connected to the conveyor 5, which moves the workpieces b between a variety of positions, three of which are depicted
in fig. 1. The boring machine 1 has a boring bar 7, on which an adjustable cutter or tool is mounted, and which rotates with the cutter 8 when a cylindrical bore is bored in the workpieces 6. After the boring, the billet is moved to an intermediate position in which the workpiece remains stationary during the next boring operation . Before the subsequent boring operation, the workpiece b is moved to the position in which the sensor 4 of size measures the diameter of the hole in the workpiece b by inserting the measuring head 9 into this hole. For example, the sensor 4 of size and measuring head 9 can be pneumatic-type devices measuring the difference between the actual hole size of the workpiece and the nominal size. Preferably, the size sensor 4 inserts an analog signal into the circuit 10, the magnitude of which shows the deviation of the size of the workpiece opening from the nominal and the direction of this deviation. The control unit 2 outputs to the circuit 11 a control signal which, through the cutter adjustment mechanism 3, moves the cutter 8 and receives a feedback signal through the circuit 12, which displays the actual movement created by the cutter adjustment mechanism 3.
FIG. 2 shows in more detail the control unit 2 and the tool setting mechanism 3, with the latter circled in dotted lines. The control unit 2 of the circuit 10 is supplied with the error signal from the sensor 4 of size and the circuit 13 with the reference signal from the same sensor. When the switch 14 is closed, the analogous error signal, supplied through the circuit 10, is applied to the capacitor 15 and charges it through the resistor 16 to a voltage indicating the error of the hole size measured by the size sensor 4. The switch 14 is controlled in accordance with the working position of the measuring head 9 in the hole of the preform b, as a result of which the size of the hole is read at the corresponding point in time. The capacitor capacitor 15 capacitor 15 capacitor is supplied to the amplifier.
17 and further into circuit 18. The error signal in circuit 18 and the reference signal in circuit 13 are fed to the logic unit of automatic tuning of instrument 19, which responds to the difference between the error signal in circuit 18 and the reference signal in circuit 13 and issues the corresponding commands in circuit 20 and 21 to the gearmotor 22, which, for example, can be driven clockwise in response to the signal in chain 20 when the hole is smaller than the nominal size in order to increase the radial outreach of the tool, and counter-clockwise in response to the signal n o chain 21 when the hole is larger than nominal in order to reduce the radial outreach of the tool. Gear motor 22 has an output shaft 23, which is connected to gear gear 24, which in turn is connected to a pneumatic chuck 25. The magnitude of the angular displacement of the shaft 23 of the gear motor, and therefore the pneumatic chuck 25, is measured by a circular potentiometer 26, a shaft 27 connected to the engine 22. A circular potentiometer 26 outputs to the circuit 28 an output signal to the logic device for automatically tuning the tool 19 for comparison with a control signal in circuit 20 or 21, resulting in a complete change eschenie tool can strictly and precisely controlled. The display unit 29 receives a signal arriving along the circuit 28, which represents the actual amount of movement of the tool, and provides visual information about the actual position of the tool. The tool setting mechanism 3 is also equipped with a safety device.
30 stroke limitation associated with pneumatic chuck 25, shaft
31 and contains limit switches
32 and 33, driven by a cam 34 mounted on the shaft 31, to obtain information on when the tool is at the limits of the adjustment range. This information is provided
through the circuit of the limit switch 32- to the corresponding indicator, for example, lamp 35. The output signal of the safety limiter is also outputted to the logic device for automatically tuning the instrument 19 via circuit 36. The logic device for autotuning the instrument 19 also sends a signal for manual adjustment via a voltage source 38 for supplying a negative voltage across a circuit 39, a positive voltage across a circuit 40, and an adjustable voltage of a third circuit 41. From the input 42, an enable signal is also provided, which is generated from only when the bushing bar and the thigh are in the position corresponding to the cutter setting. From the input 42, the decisive signal is sent to the clock button 43, the return button 44 and the movement button 45. Against the clockwise direction, which, in turn, pass the signal from input 4, respectively, to analog logic circuits And 46, 47 and 48, and through circuit 37 to the logic device 19 of the automatic tool tuning, when the corresponding button is closed and on During the course of 42, an enabling signal appears. Accordingly, a negative voltage from the source 38 appears in the circuit 37, when the enabling signal appears at the input 42 and the clockwise movement button 43 closes, a positive signal from the circuit 40 In circuit 37, when the enable signal is fed to input 42 and the movement button 45 is closed counterclockwise, and a predetermined potential 41 of the circuit 41 appears in circuit 37 when the enable signal is applied to input 42 and the button 44 closes. automatic on For example, tool 19 responds to negative and positive voltages of circuits 39, 40, and 41 as error signals to drive cartridge 25 in a clockwise or anti-clockwise direction, respectively. The return button is used to bring the cutter to a predetermined position, which can be set by adjusting the variable potential of the circuit 41, and is preferably in the starting position after installing a new cutter. From the foregoing it is clear that both the automatic setting of the cutter is ensured by means of the cutter setting mechanism 23, and manual adjustment by using the buttons 43, 44 and 45. In addition, these settings are made only at the moment when the cutter is in corresponding position due to the introduction of interlocks created by the switch 14 and the permissive voltage at the input 42. The signal from the circuit 18, see fig. 3J, which represents the deviation of the hole size from the nominal size, is fed to an upper limit comparator 49 and a lower limit comparator 50. A high voltage reference voltage, e.g. 3.5 V, is also applied to the high limit comparator from the high voltage reference voltage generator 51. and a reference to the voltage of the low limit, e.g. 2.5 V, from the generator 52 of the reference voltage of the lower limit. The upper limit comparator, when the signal in the circuit 18 exceeds the reference voltage of the upper limit, outputs to the circuit 53 an output signal indicating that a too large aperture has been measured, while the lower limit device has an output signal indicating to the circuit 54 that was measured too small hole. If a signal is output to the circuit 53, indicating that an upper limit has occurred, and this signal is fed to the AND 55 circuit simultaneously with the supply to the AND circuit 56 of a signal indicating that the cutter is in the tuning position, i.e. that the boring bar is in the designated position, and the cutter setting element is centered with the cutter setting cartridge 25, the signal is fed to the upper limit counter 58, which counts the unit with its counting register. If three consecutive signals are sent to counter 58 indicating an upper limit for three consecutive measurements, then counter 58 outputs to the circuit 59 an output signal indicating this circumstance. Similarly, if the output signal is present in circuit 54 simultaneously with the presence of a tuning moment signal in circuit 56, a signal is output across circuit 60 to the counter of the lower limit 61, which is counted in the counting register. If the lower limit counter 61 has three consecutive signals on circuit 60, then it outputs an output signal on circuit 62, indicating this circumstance. The output signal of the upper limit counter 58 over circuit 59 is applied to the circuit. And 63, to which, in addition, a signal of tuning momentum is applied along circuit 64, Circuit AND 63, when signals are present in circuits 59 and 64, outputs an output signal across circuit 65, which is fed to one of the inputs of circuit AND 66. 66 through circuit 67, a signal is also received that is received from the signal in circuit 36 and is, in particular, synchronized with respect to the signal in circuit 36 so that its presence indicates that the instrument setting does not occur within the limits of what indicates the open position of the limit switches 32 and 33. When the signals coincide in An nx 65 and 67 circuit AND 66 outputs to the circuit 68 an output signal that goes to the next circuit AND 69. To the circuit 69 and circuit 70, the signal is given when the manual tuning is not performed using the manual tuning device, and this circuit the output signal to the circuit 71 when the signals in chains 68 and 70 coincide. The lower limit counter 61 causes the output signal to AND circuit 72, to which the tuning torque signal is received via circuit 64, as a result of which this circuit outputs the output signal to the output circuit 73 when the output signal coincides with the counter 61 n the upper limit and the signal of tuning in circuit 64. Through circuit 73, the signal is fed to circuit 74, to which also signal 67 does not come back to its original position, with the result that the output signal is output to circuit 75 when both signals are present in the circuit 67 and 73. For circuit 75, the signal enters AND circuit 76, to which the circuit 70 also sends a signal of no manual tuning and this circuit outputs to circuit 77 an output signal when the signals in chains 75 and 70 coincide. signals in chains 71 and 77 indicate that: 1) three sequences were measured GOVERNMENTAL openings, each of which is respectively greater than the reference upper limit or less than the reference lower limit; 2) the tool is in the position of the corresponding setting; 3) the instrument is within the setting range; and 4) the manual adjustment device does not work. Signals in chains 71 and 77 are enabling signals that allow the cutter to be moved to an appropriate amount for the purpose of correcting the difference between the diameter of the last measured hole and the nominal diameter. Along the circuits 53 and 54, the signals mapping the upper and lower limits, respectively, are fed to the circuit AND 80, which outputs the signal to the circuit 79, when the signal in circuit 18, which represents the deviation: the last measured hole does not go out for the upper or the lower limit. Chain 79 sends a signal to AND 80, which also receives a tuning signal via chain 64, which results in a signal to chain 8 when the signals in chains 79 and 64 match. The output signal is fed through circuit 81 to circuit 82, which also receives a signal through circuit 67, indicating that there is no overshoot of the tuning range /, as a result, a signal is output to circuit 83 when the signals in circuits 81 and 67 match. to which a signal is also sent along circuit 70, indicating that there is no ru on the instrument setting, and which outputs to the circuit 84 when the signals in chains 83 and 70 match. The signal in circuit 84 is the enable signal for setting the pick of the center of each hole measurement, when the hole size is between the upper and lower limits, the reference voltages of the sources 51 and 52. Suppose that the opening of the last measured workpiece is between the respective limits determined by the reference voltages of the upper and lower limits, while the enable signal on target 84 delivers to the AND circuit 85 rotating clockwise and the AND circuit 86 rotating counterclockwise. A signal in the circuit 18, representing the deviation of the size of the hole in the workpiece, is supplied to the amplifier 87 via the circuit 88. To the servo amplifier 87 through the circuit. 89 a signal is also supplied from the change detector 90, the voltage level in which is initially equal to three volts, i.e. the signal level indicating the desired size of the workpiece. The servo amplifier compares the signals in chains 88 and 89 and outputs the output signal to circuit 91, when the signal in circuit 88 indicates that the last measured hole has a reduced size, and to circuit 92, when the signal in circuit 88 indicates that the last measured hole has an increased size. If the last measured orifice has a reduced size, then the coincidence of the signals in chains 91 and 84 according to the AND 85 circuit will result in the appearance in circuit 93 of an output signal that is applied to clock activator 94 in a clockwise direction, in turn, in turn, output a signal to the circuit 20 for rotation of the gear motor 22 clockwise in order to increase the tool protrusion relative to the boring bar and increase the size of the hole in the next machined part by the amount needed to bring it to the required size. In other words, the tool is adjusted in proportion to the error in one step. If the processed part had an increased size and / therefore, the servo amplifier 87 would output the output signal to the circuit 92, the AND circuit would simultaneously receive signals through the circuits 84 and 92, as a result of which the output signal of this circuit would be fed to the pathogen 96 counterclockwise rotation, which, in turn, would give a signal along circuit 21 to gearmotor 22 to create rotation of this gearmotor counterclockwise in order to reduce the tool travel relative to the drill rod and thereby reduce the size of the hole ti next treated part. When adjusting the cutter by turning the gear motor either clockwise or counterclockwise, the potentiometer 26 generates a live communication signal through the circuit 28, which enters the change detector 90. The change detector detects a change in the voltage value of the potentiometer and generates a signal along the circuit 89 to display this change. As the tool position changes, the signal in circuit 89 approaches the control signal in circuit 88. When servo amplifier 87 detects that signals in circuits 88 and 89 are equal, the output signal in circuit 91 or 92, which causes this change, disappears. The circuit 13 to the change detector 90 receives a reference voltage, to which the detector reacts so that, after a certain time has passed after moving the potentiometer that outputs the output signal to the circuit 28, the output voltage in the circuit 89 of the change detector becomes again three volts and, thus, restoring the initial conditions for the next instrument setting. When measuring a hole that goes beyond the upper or lower limit, no signal is provided to circuit 84, as explained. After measuring the three holes coming out either for the upper or for the lower limit, as explained, the signal is output to the circuit 71 or 77, respectively, and it goes to the corresponding AND 97 or 98 circuit. When the output signal of the rotation signal clockwise from the servo amplifier along circuit 91 and the signal along circuit 71, circuit 97 on circuit 99 provides a signal to clockwise exciter 94, the output of which in circuit 20 causes the tool to move by clockwise rotation as described. When the output signal is turned counterclockwise from the servo amplifier along circuit 92 and the signal via circuit 77 to the circuit 98, the circuit 98 also outputs the output signal to the actuator 96 counterclockwise, the output of which in circuit 21 provides the instrument setting by rotating counter-clockwise, as explained. The upper and lower limits of the size of the hole of the workpiece 6, established by means of reference voltage generators of the upper 51 and lower 52 limits, respectively, are chosen in such a way that they are completely between the upper and lower tolerances of the workpiece 6. If necessary, upper tolerance comparators and lower tolerance comparators are provided in combination with upper tolerance reference voltage generators and lower tolerance reference voltage generators, similar to blocks 49, 50.51 and 52, respectively, to which an output signal is applied along circuit 18 to determine the moment when the blank of the workpiece leaves the tolerance field. The control unit can be adapted to stop the boring machine 1 upon detection of the machined part beyond the tolerances. Mechanism 3, see FIG. 4-b) comprises a central rotational shaft 101 with portions 102, 103, 104 and 105 of different diameters, which may be an assembly structure consisting of several coaxial parts connected together. Part 105: is preferably one of these parts, and contains the collet chucks 106, slightly bent away from the center and having slots along the axis that allow the clamps 106 to be compressed towards the center. The collet chuck 107 of the collet chuck is mounted coaxially with the shaft portion 101 and moves relative to the latter in the axial direction to compress the latches 106 as it moves downward relative to the cartridge portion 105. The sleeve has an outer flange 108 that is in close contact with the surrounding cylindrical wall 109 and the inner cylindrical wall 110 by means of seals 111 and 112. The flange 108 divides the chamber formed by the walls 109 and 110 into opposite parts, into which through the channels 113 and 114, compressed air is supplied at certain times. Obviously, with a decrease in pressure in channel 114 and an increase in pressure in channel 113, the flange 108 and the sleeve 107 associated with it will be fed down and bend inside the latches 106 of the cartridge section 105. When the pressure in the channel 113 decreases and the pressure in the channel 114 increases, the sleeve 107 will be fed upwardly with respect to the cartridge section 105, allowing the locks 106 to extend outward. The shaft 101 and the liner assembly 107 are mounted with rotation in bearings 115 and 116. The shaft 101 (see FIG. 5) is rotated through a gear 24 comprising a worm gear 117 mounted on the shaft 101 and a screw to 118 mounted on a transverse a shaft 119. A shaft 119 is driven into rotation by a motor 22 with a gear reducer through an appropriate clutch. The feedback potentiometer 26 is driven by the shaft 119.
through the appropriate coupling and to obtain information about the actual angular displacement of the shaft 101.
A cam 34 is mounted on the shaft section 102 (see Fig. 4.6). Rotating along with the shaft and communicating with the limit switches 32 and 33. The end switches 32 and 33 contain the pushers 120 and 121, which are pressed when the cam 34 is in contact with thrust plates 122 and 123 respectively. The limit switches are set so that the corresponding switch 32 or 33 turns off when the cam 34 is turned relative to the low position 32.4. The limit switches 32 and 33, together with the cam 34, perform the safety-free function, preventing the instrument from exceeding the setting range and thus damaging blanks. This task can also be accomplished by controlling the turn of potentiometer 26 on indicator 29.
The tabs 106 of the collet chuck part 105 are adapted to grip and clamp the cylindrical surface 124 on the tool displacement mechanism 125 for the boring bar 7 and the cutter 8. In this case, the protrusion of the cutter 8 may increase or decrease by rotating the cylindrical surface 124, respectively clockwise or counterclockwise, by appropriate a threaded connection between the shaft supporting the tool holder 126, and a threaded element mounted on the boring bar 7 (as is known in the tool setting technique). To ensure that the cylindrical surface 124 is gripped by collet chucks 106 at an appropriate point in time, an air pressure control device (not shown) is provided which is connected to channels 113 and 114 and synchronized with the control of the gearbox motor 22 along chains 20 and 21. For example, surface 12 will happen at the right moment
by creating air pressure in channel 113 when issuing a tuning time signal through circuit 64 and by creating pressure in channel 114 when the tuning moment signal in circuit 64 disappears.
Thanks to the invention, an adjustment system for compensating tool wear has been obtained, in which a full proportional compensation of tool wear is carried out in one step, faster than with gradual compensation, and in which tool setting can be carried out in either of two directions, resulting in temperature changes will also be compensated. A feature of the invention is that a counting circuit is provided that reacts to rare changes in the measured size in order to compensate for changes in the hardness of the material.
权利要求:
Claims (1)
[1]
Invention Formula
The tool position control system, the sub tool adjustment mechanism, the unit for measuring the deviation of the actual part size from the target and the number of deviations exceeding the upper and lower specified limits of the control zone, which, in order to improve the accuracy of machining, the system is equipped with a compensation unit deviations of the part dimensions in the control zone, connected by its input to the output of the measuring unit, and by the output to the sub-adjustment mechanism of the tool .
Sources of information taken into account in the examination 1. accuracy and reliability of automatic machines and active control devices. Ed. M.S. Nevelson, L., 1968, p. 46-47.
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类似技术:
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同族专利:
公开号 | 公开日
IN141087B|1977-01-15|
JPS5016181A|1975-02-20|
US3914678A|1975-10-21|
FR2230009A1|1974-12-13|
DE2423692B2|1981-01-15|
IT1009922B|1976-12-20|
BR7403993D0|1974-12-24|
CA997177A|1976-09-21|
DE2423692A1|1974-12-05|
GB1452800A|1976-10-13|
引用文献:
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法律状态:
优先权:
申请号 | 申请日 | 专利标题
US360669A|US3914678A|1973-05-16|1973-05-16|Control system for compensating for cutting machine tool wear|
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