RU2009764C1 - Method of automatic orientation of actuating member of numerically controlled machine - Google Patents

Abstract

FIELD: test equipment. SUBSTANCE: method of automatic contact-free measurements and orientation of actuating member of numerical controlled machines concludes in measuring position of vertex of non-rotary actuating member or point which most distant from axis of rotation either support edge of rotating actuating member is measured relatively other members of measuring system which are disposed in specific manner in coordinate system of numerical programmed controlled machine. Measuring system has flat radiation beam directed onto the receiver. This beam has specific dimensions and disposition and it is used for orienting actuating member relatively measuring system by means of shifting the beam in the beginning of measurements in perpendicular to the beam till the beam crosses vertex or other character point of the actuating member. Subsequent measurements are carried out in the plane of this flat beam or in the plane to be parallel to it. EFFECT: improved precision; improved reliability. 8 dwg

Description

 The invention relates to a control and measuring technique and can be used for automatic non-contact settings, adjustments, measurements, assessing the state of executive bodies (IO) and the accuracy of their position (orientation) in space in metal-cutting machines, robots, control, transport and folding, building, assembly, road and other machines and devices with a system of numerical program control (CNC).

 There is a method of orientation in space and measurement of a non-rotating executive body of CNC machines, which consists in moving the executive body under control of the control system according to a pre-selected one taking into account a preliminary estimate of its size of a broken path from an arbitrary point, but attached to the coordinate system of the control system of the machine, sequentially for each from the coordinate axes relative to which the executive body is oriented to a specific point in space in which the multi-axis and contact indicator, which includes, when orienting and measuring the executive body on each of the coordinate axes, the operation of touching the top of a non-rotating executive body (its extreme) point along this coordinate) with the contact indicator; the formation of a signal fixing this moment, and its transmission to the control system of the machine (in order to increase the determination of the position of the vertex of the executive body in space, the above operations can be performed repeatedly at successively reduced speeds); issuing from the control system command to stop the executive body and its implementation; fixing in the control system memory the coordinates of the top of the executive body, evaluating the control system of the path traveled by the top of the executive body from the starting point to contact with the contact indicator; comparing it with the help of a control system with a predetermined or initial value obtained earlier, an estimate of the size of the executive body and its changes compared to the previous measurement; making decisions on the possibility of using the executive body, based on its condition; changing, if necessary, the value of movements of the executive body specified in the control program in this coordinate; transition to orientation in space and measurement of the executive body along the next coordinate axis or completion of the measurement cycle.

 The disadvantages of the method are its low accuracy, performance, reliability, the high complexity of the preparation and its implementation.

 A known method for automatically positioning the base surfaces of the product relative to the axis of the spindle of the CNC machine, which automates the process of determining the coordinates of the base surfaces of the product relative to the axis of the spindle of the machine.

 The disadvantages of the method are the limited scope, the rather high complexity, the inability to orient the table in a plane parallel to the axis of the spindle, measuring the dimensions of the parts.

 A known method of automatic control of the process of setting the coordinates of the executive body of a CNC machine.

 The disadvantages of the method are the limited scope, the rather high complexity of the positioning of the executive body, the complexity of the process of setting the coordinates of the IO, the inability to measure the size of the IO.

 Known methods for controlling the wear of a cutting tool on CNC machines, containing a measuring head mounted on the machine. A cutter with a reference reflective area periodically comes into contact with the head, while a light beam is fed through the light guides to the area, and the photodiodes evaluate the intensity of the reflected beam. As the tool wears out, the distance between the reflecting pad and the photodiodes changes, the intensity of the reflected beam also changes, which makes it possible to estimate the tool wear along one coordinate axis.

 The disadvantages of the devices are the rather high laboriousness of measurements, the limited possibilities in terms of size, shape of the tool, the number of coordinates by which the tool can be oriented in space, in the field of application, the likelihood of a decrease in accuracy due to contamination and mechanical damage to the elements of the head and reflective area, etc. e. low reliability.

 The prototype of the proposed method is a method and apparatus for measuring a tool on a metalworking machine [1]. A method of measuring a tool mounted in a spindle of a metalworking machine is that the transverse feed of the tool is performed using laser radiation and, at the moment of interruption or idling of the beam, the position of the tool support is measured. The control is carried out, in particular, with the aim of measuring and comparing the tool before and after the implementation of the work process.

 The disadvantages of the method is that measurements without preliminary measurements and orientations can be performed only along one coordinate axis for a simple optical form, for example, a planar one, since there is no automatic orientation of the emitter relative to the laser beam.

 The objectives of the invention are to increase the accuracy and productivity of automatic measurement processes and orientation in the space of the executive body of a CNC machine, expanding the functionality of these processes.

 This is achieved by the fact that the spatial orientation and measurement of the executive body of CNC machines is carried out by determining the position in space of the vertex of the executive body sequentially for each of the coordinate axes along which the orientation and measurements are made, followed by automatic correction if necessary using the control system of the machine with taking into account the results obtained, the management program of the executive body using a measuring system formed by a complex of sources and receivers directional radiation controlled from the control system of the machine and coordinated with respect to it in space, for which the non-contact method is used when moving under control of the control system of the machine an executive body that has arbitrary shape and dimensions unknown from the beginning of measurement from any point in space parallel to the coordinate relative to the control system axis perpendicular to the radiation beam along the shortest path to the intersection of the top of the executive body at the beginning of measurements with a flat radiation beam, position married in the same plane with other beams of radiation of the measuring system or parallel to them, with subsequent fixation of the moment of crossing the control system of the machine by the signal from the radiation receiver, to which the flat beam of radiation is directed, by assessing the control system of the machine of the path traveled by the executive body from the starting point of measurement to this point as well as the size, condition of the executive body and the position of its vertex in the initial position before measuring the position on a given coordinate axis, by repeating these operations under the control of the control system ins for orientation and executive measurements on the remaining coordinate axes.

 In FIG. 1 is a functional diagram of the implementation of the proposed method for the case of measurement and orientation of a non-rotating executive body (IO) of a CNC machine along one coordinate axis; in FIG. 4-8 - application of the method.

 A radiation beam is used, directed from the radiation source 1 to the receiver 2 perpendicular to the given coordinate axis and located at a known distance from the coordinate origin of the CNC machine. The top of the IO must be in the same plane with the radiation beam, which ensures their intersection when the IO moves perpendicular to the beam.

 When moving the IO, whose axis position relative to the coordinate origin of the CNC machine is known, perpendicular to the radiation beam (parallel to the X axis), the top of the IO will intersect the radiation beam. Depending on the required measurement accuracy, two methods are possible for fixing the exit of the AIS vertex to a certain point in space when it encounters a radiation beam: by a signal from a radiation receiver when the radiation beam is completely blocked by the AIS apex; by a signal from the radiation receiver when the radiation intensity decreases below a threshold value when the radiation beam is partially blocked by the tip of the IR.

 The second method has higher accuracy capabilities.

 The electrical signal arising at the receiver 2 through the amplifier 4 enters the control unit 5 input signals. The central processor (CPU) 6 detects the incoming signal and gives the command to the drive control unit 7 to stop the movement of the IO along the given coordinate axis from the drive 8. After stopping the IO, the CPU 6 calculates the path traveled by the IO until its peak meets the radiation beam, the distance from the axis IO to its peak or characteristic point (the methodology for such a calculation is shown below and explained in Figs. 2 and 3), compares the results with the valid ones stored in the memory unit 9 of the CNC system (CNC), and makes adjustments to the program if necessary further work of the machine with CNC.

 Then, in accordance with the measurement program, the CPU 6 through the block 10 of the output signals gives a command to turn off the radiation sources if the measurement cycle is completed, or to switch to measurements on other coordinate axes.

 The command to start the measurement cycle can be given by the operator from the display panel 11, which then displays information about the measurement results, or CPU 6 automatically, after the machine has completed a certain number of operating cycles. Blocks 5, 6, 7, 8, 9, 10, 11 are included in the control system 12 of the machine.

 In FIG. 2 and 3 show diagrams of measuring the distance from an axis or a given point to the top of a non-rotating IO (Fig. 2) and the radius of a rotating IO (Fig. 3) along one coordinate axis (X) using this method.

When the IE moves until its peak or other characteristic point meets the radiation beam, its axis passes the path L ₂ from an arbitrary point O ₁ with known coordinates to the point O ₂ . The CPU 6 (Fig. 1) determines this path and the distance L ₁ from the point O ₁ to the radiation beam in a certain way located in the coordinate system of the CNC machine. The desired size L ₃ (Fig. 2) or R (Fig. 2) the CPU IO finds as the difference between the values of L ₁ and L ₂ .

 Consider an example of measurements and orientation in space along the three coordinate axes of a non-rotating IO. Such a task may arise when setting up and adjusting some lathes, robots, instrumentation and other CNC machines.

 A laser (for example, a helium-neon laser mod. LGN-108, etc.), other light sources in the visible or infrared part of the spectrum, sources of electromagnetic (for example, radio waves), x-ray, ultrasound, and other types of directional radiation. If the laser is used as the emitter, photodiodes (for example, SP-103, FD-141K, etc.), a line of photodiodes (CCD arrays) can serve as a radiation receiver. The latter can be used for flat beams with a width of more than 15 mm. In this line, all photodiodes must work independently, independently of each other, respond to changes in the intensity of the beam incident on each of them. With a beam width of up to 15 mm (this is typical for metal-cutting machines, robots, control and other precision CNC machines), a photodiode with the corresponding diameter of the photodetector surface (for example, FD-141K has a photodetector surface diameter of 14 mm) and a speed of tens of NS (speed FD-141K - 50 NS). Depending on the type of radiation, electromagnetic, ultrasonic, infrared, X-ray, radioactive and other types of radiation can also be used.

 For measuring and orienting the IO along each coordinate axis, one beam of radiation is used, perpendicular to this coordinate axis and located at a certain distance from the coordinate origin of the CNC machine. Each beam of radiation is directed to a respective receiver.

 The methodology for solving the problem for a special CNC lathe using this method is shown in FIG. 4. Here, lasers 1 and photodiodes 2 are used as radiation sources and receivers, respectively. To ensure that the tip of the cutter meets all the rays, the latter lie in the same plane in which the tip of the cutter moves after its measurements and orientation along the Z axis. To increase the accuracy of measurements, this the plane is accepted parallel to the XOY plane of the machine coordinate system, in which the main movements of the cutter are made during the operation of the machine.

 To output the EUT (cutter 3) into the measurement plane, a wide, solid, flat beam (light plane) of width 5 is used. . . 10 mm, sufficient to compensate for the manufacturing error and installation of the cutter 3 along the Y axis. Such a beam is obtained using a laser beam expander 4. A cylindrical lens or pentaprism can be used as such an expander.

 A flat beam can be directed to a photodiode 2 of the appropriate size (Fig. 4) or to a line of photodiodes 5 (Fig. 5) which can be used as a CCD, or to an optical element 6 (Fig. 6), which again converts a flat beam into a cylindrical one and directs it further to photodiode 2. An inverse cylindrical lens or pentaprism can be used as such an element.

 Measurements are performed according to a special program implemented by the control system of the machine.

 Lasers 1 and photodiodes 2 are turned on. Cutter 3 moves from a starting position with known coordinates along the Y axis by a certain distance, approximately to the middle of a plane beam. In this case, the tip of the cutter D is at point A with unknown coordinates, since the cutter was not measured before it was installed on the machine and the position of the tip D along the coordinate axes at the beginning of measurements is unknown. Then the cutter moves along the Z axis to the intersection of its vertex with a flat laser beam at point B.

 By a signal from a photodiode acting independently or in a line of photodiodes onto which a beam blocked by the tip of the cutter fell, the movement of the cutter along the Z axis ceases.

 According to the methods described above, the control evaluates the cutter exit along the Z axis, compares it with the nominal one, makes a decision about the possibility of using the cutter according to this parameter, makes changes to the correction array for the cutter offset along the Z axis if necessary. If the control decides whether use of the cutter, taking into account its departure along the Z axis, measurements continue.

 The cutter moves under the control of the control system along the X axis until the intersection of its vertex at point C with a beam perpendicular to the X axis of the machine coordinate system.

 The corresponding photodiode to which the crossed beam was directed captures this moment, sends a signal to the control system of the machine, and it stops the movement of the cutter in this direction. The control system of the machine performs actions in relation to the departure of the cutter along the X axis. The cutter moves under the control of the control along the Y axis until it meets a laser beam at point O perpendicular to the Y axis.

 According to the signal from the photodiode, on which the crossed beam was directed, the control system of the machine performs actions in relation to the departure of the cutter along the Y axis.

 If the tool is suitable for use, then the working cycle can begin either from the point (O) at which the tool tip arrived at the end of the measurement cycle, or at any other point, since now the coordinates of the tool tip and its reach are known from all coordinate axes and stored in the control system of the machine.

 Turning on and off the elements of the measuring system of the control system of the machine can also be performed sequentially, as measurements are taken along one or another coordinate axis.

 Consider an example of measurements and orientation in space of a non-rotating executive body of a CNC machine along two coordinate axes.

 Such a problem arises, for example, when setting up and adjusting various cutters and some other tools (in particular, for running-in or smoothing parts) on universal CNC lathes. A diagram of the implementation of the proposed method for solving this problem is shown in FIG. 7. Here, helium-neon lasers 1 are used as radiation sources, aimed at photodiodes 2 and 5 (Fig. 7) in such a way that the laser beams are perpendicular to the axes Z and X of the machine, lie in the same vertical plane at a known distance from the origin of the machine .

 To compensate for the error of the initial installation of the tool in a vertical plane and to ensure that its tip intersects with the laser beam used to orient and measure the tool along the Z coordinate axis, a thin solid flat laser beam parallel to the machine axis X is used. The width of this beam is chosen to be slightly larger than the error in installing the tool in a vertical plane (about 3... 5 mm). In principle, one could also use a conventional cylindrical laser beam, the diameter of which for helium-neon lasers can be, as is known, within 0.001. . . 50 mm. However, it will not be possible to ensure the necessary measurement accuracy, since such a beam will not be able to ensure the exit of the tool tip to one point along the Z axis.

 A flat beam from the laser 1 is obtained using the expander 4. This beam is directed either to the line of photodiodes, or a separate photodiode 2 of the appropriate width (see Fig. 4), or to the optical element 5 (see Fig. 7), which again turns the flat the beam is cylindrical and then directs it to photodiode 2. As such an element, an inverse cylindrical lens or pentaprism can be used.

 The transformation of a flat beam into a cylindrical one and registration of the moment when one of the rays of the light plane overlaps with the tip of the instrument with one photodiode is designed to increase the measurement accuracy. This is due to the fact that in the line of photodiodes between the photodiodes there is a minimum space that is insensitive to the rays incident on them. Therefore, with a small beam width (up to 15 mm), it is better to use instead of the line of photodiodes a single photodiode having the width of a flat beam (in this case, it should respond not to the complete overlap of the incident beam, but to a change in its illumination below a threshold value) or a circuit, shown in FIG. 7.

 The cycle of the measuring system is similar to that described above in FIG. 1. First, the control system includes sources and receivers of radiation. Then, the tool under control of the control system moves from the initial position, first along the Z axis, to the intersection of its peak D with a flat laser beam at point A, and then parallel to the X axis until the peak intersects the laser beam at point O. The control evaluates the tool offset along each axis, compares it with the original one, makes a decision on the possibility of using this tool, makes, if necessary, changes to the correction array for the tool overhang on each axis.

 Consider an example of measurements and orientation in space along the three coordinate axes of a rotating actuator having a point apex (Fig. 8).

 Such a problem may arise when setting up and adjusting shaped end mills, shaped countersinks, drills, rolling balls and other tools with a point apex whose position relative to the machine coordinate system is not known in advance due to manufacturing and installation errors of the IO.

 The measuring system (Fig. 8) contains three radiation sources 1 (laser), three radiation receivers 2 (photodiodes). To orient the rotating IO 3 along its Z axis, a flat beam of radiation is used, which is created using a beam expander 4 (cylindrical lens or pentaprism), and then again turns into a thin filament beam using device 5 (inverse cylindrical lens or pentaprism). Thin rays lie in one plane, parallel to the plane beam and the coordinate plane of the XOY machine, in which the main movements of the IO or the workpiece are performed.

 The measurement process is as follows. After turning on the lasers and photodiodes, the axis of the IO without its preliminary measurements is moved to a point approximately above the middle of the plane beam, and then, with its continuous rotation, along its axis until the vertex of the IO intersects the plane beam. After the CPU has completed the necessary calculations described above and the decision is made to continue the measurements of the EUT, they are raised up until the working lateral surface of the EUT reaches the plane of arrangement of the thin radiation beams. During continuous rotation, the EUT moves to the intersection with the beam perpendicular to the X axis. After the CPU performs the necessary calculations, the EUT moves to the intersection with the beam perpendicular to the Y axis. When the IO is oriented along the X and Y axes, the order of the IO movements is arbitrary. Rays in the space of the machine can be located so that at the end of the measurement cycle the IO goes to the initial point before work. It also helps to increase the productivity and accuracy of the CNC machine. (56) European patent N 098930, cl. B 23 Q 15/18, publ. 1984.

Claims (1)

 METHOD OF AUTOMATIC ORIENTATION IN THE SPACE OF THE EXECUTIVE AUTHORITY OF THE CNC MACHINE, including the movement of the said organ in turn in the direction of the corresponding coordinate axes until contactless with the elements of the optical reading system having a definite position in the system measured values of movement, characterized in that, in order to increase the accuracy and productivity of the orientation process, The executive body is moved horizontally perpendicularly to an additionally shaped flat beam of radiation parallel to one of the coordinate axes, before intersecting with it, and the measured value of the said movement is used when the executive body is set to a predetermined position in the machine coordinate system.

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