JP2006159299A - Device implemented for working unitary with measurement - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a device for working unitary with measurement with a cutting tool as a shape measuring probe. <P>SOLUTION: The device 100 for working unitary with measurement is constituted of a high speed tool control unit and a force sensor 150. The high speed tool servo control unit is a mechanism to hold a tool 120 and to control its cutting quantity at high speed and is constituted of a cylindrical piezoelectric element (PZT) 130, a tool holder 122 to hold the tool and a capacity type sensor 140 to measure displacement of the tool 120. It is possible to give the cutting quantity to the tool 120 through the tool holder 122 to hold the tool by the cylindrical piezoelectric element (PZT) 130. An electrostatic capacity type displacement gage concentrically arranged with a piezoelectric element detects displacement of the tool. Additionally, the force sensor 150 is fixed on a base 110 with screws 152, 154. It is possible to load an optional preload on the force sensor by an angle of rotation of the cap screws 152, 154 used for fixing. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a measurement processing integrated apparatus capable of measuring the shape of a processing target while performing processing for creating a shape on a material surface, and more particularly to a measurement processing integrated apparatus suitable for producing a fine pattern on a surface.

  The technology for producing a fine pattern on the surface of a material forms the basis of information technology. This is because a new functional surface can be created by creating a three-dimensional fine shape on the material surface. Optical functions include Fresnel lenses, microprisms, microlens arrays, etc., which are widely applied in the information technology industry. In addition, by distributing fine grooves and protrusions, functions such as correction of light source intensity distribution, antireflection, and prevention of rainbow / moire generation can be added to the display device, and conversion efficiency is improved for solar cells. be able to. In addition, as an improvement of tribological functions, applications such as creating a fine shape in the piston sliding part of the engine and reducing the frictional force by reducing the contact area, and water repellency due to the fine shape as an improvement of the interface function To improve self-cleaning surfaces and improve properties such as heat transfer coefficient, boundary layer flow, bearings, rust prevention, and adhesion. Furthermore, the application is spreading to implants and biosensors in the bio field. An example of the measurement reference plane is a multi-degree-of-freedom position measurement angle grid. The angle grating is a mirror body with a shape in which sine waves are superimposed in the X and Y directions, and its wavelength and amplitude are designed to be tens to hundreds of mm and tens to hundreds of nm, respectively, based on the specifications of the angle sensor that reads the shape. Has been. The processing range of the angle grating is several tens mm to several hundreds mm, and the measurement range is basically limited to this range. Therefore, the angle grating is required to have high shape accuracy over a wide range.

  As a technique for creating these fine patterns, a processing method capable of creating a highly accurate surface shape over a large area in real time is desirable. There are various types of electrical and optical three-dimensional fine shape creation technologies such as an electron beam drawing method, a laser drawing method, and a holographic method. These methods are effective for creating structures with very short spatial wavelengths from micrometer to submicrometer, such as non-reflective surfaces, diffraction gratings, microlens arrays, etc., but for creating complex three-dimensional shapes. Is unsuitable.

  On the other hand, the current ultra-precise cutting / grinding technology can easily perform machining with sub-micrometer-order accuracy or less by advancement of precision motion control and measurement / precision machining tools. A typical example is single point diamond cutting, which is a method of processing a soft metal or the like with a high precision processing machine using a single crystal diamond tool having a very sharp single cutting edge. Since the relative motion trajectory of the tool and the workpiece is transferred to the machining surface shape very accurately without depending on the speed, a precise machining surface can be obtained quickly. This technology has established its position by mass production of precision parts of ductile materials, and there are high expectations for processing and nanomachining of brittle materials. In addition, using tools such as fast tool servo (FTS) and fast tool control (FTC: high-speed tool control), the tool is controlled three-dimensionally precisely and at high speed with respect to the workpiece. However, by giving the cutting amount independently to all points on the processed surface, there is also an advantage that a complicated geometric shape can be created with high shape accuracy and surface roughness. Compared to electrical and optical processing methods, it is difficult to create fine shapes with a spatial wavelength of several micrometers or less with diamond cutting, but for creating spatial wavelengths in the range of tens to hundreds of micrometers. It is an excellent method and is particularly suitable for precise creation of complex three-dimensional fine shapes.

  In normal turning, 3 axes of linear motion 2 axis + rotation axis are controlled by a lathe to give a target shape to the work piece. This FTC is one of 2 linear motion axes, piezoelectric element (hereinafter PZT) etc. This technology is controlled by a mechanism with high resolution, rigidity and responsiveness. Although this technology made it possible to create fine patterns with shape accuracy on the order of several tens of nanometers, this technique, which has the feature of controlling tools at high speed unlike normal machining, is still " However, no research has been done to analyze the method itself, such as "what kind of load is applied to the structure" or "the influence of high-speed tool movement". In this way, there is still no design guideline that will be required when constructing a system that creates FTC using FTC in the future. The demand is growing. In addition, force is an important factor in monitoring the machining status. In-process force measurement can be performed, and on-machine measurement information can be fed back to machining to improve machining accuracy. It becomes possible. Further, by using this force information, it is possible to determine the contact position between the tool and the workpiece, which is difficult at the time of micromachining. Furthermore, tool wear, which is important during micromachining, can be measured from the output of the force sensor.

  On the other hand, research and technology development related to on-machine shape measurement of ultra-precision machined surfaces, in which the surface shape created on the machine is measured on the machine and correction processing is performed based on the shape data, are actively conducted. However, in these on-machine measurements, various displacement sensors are mounted on the processing machine for shape measurement, and there is a problem that the positions of the processing points and the shape measurement points do not match. For this reason, on-machine shape measurement information cannot be accurately fed back to correction processing, and nano-processing of complicated free-form surfaces cannot be realized. In addition, an on-machine measurement processing integrated evaluation apparatus using fine processing utilizing almost the same principle as that of an atomic force microscope (AFM) has been realized in Japan and overseas. This solves the problem that the position of the machining point and the shape measurement point do not match, but because the rigidity as a processing machine is very low, it can not be applied to ultra-precision cutting that requires high-rigidity machining is the current situation.

  The object of the present invention is to combine ultra-precise turning and high-speed tool control to create a three-dimensional shape with nanometer accuracy, and use the cutting tool as a shape measurement probe as it is. It is to provide an integrated measuring and processing apparatus capable of measuring with nanometer accuracy and correcting the shape measurement point with the diamond tool based on the shape data.

In order to achieve the above object, the present invention includes an actuator that drives a tool, a tool holder that is coupled to the actuator and holds the tool, and a displacement sensor that is disposed coaxially with the actuator and measures the displacement of the tool. This is an integrated measuring and processing apparatus in which a force sensor for measuring a force applied to a tool is integrally formed and the tool is used as a shape measuring probe.
An integrated measuring and processing apparatus, a drive circuit for driving the actuator, a signal generating means for applying a signal to the tool to move a tool by the actuator, the force sensor, Detecting means for detecting a signal from the displacement sensor, outputting a signal for vibrating the tool from the signal generating means, and the detecting means detects the same vibration as the vibration applied to the tool from the force sensor. In some cases, the measurement / machining system includes a control means for detecting the displacement at this time as the object contact of the tool. Since the contact position can be measured accurately, it is possible to measure the minute wear of the tool and the origin position of the tool tip when the tool is replaced.
The measurement / processing system includes scanning means for moving the measurement processing integrated device relative to the object, and the control means controls the signal generating means and the scanning means to control the surface of the object. While scanning, the tool can be moved by a signal from the signal generating means to perform predetermined processing on the surface of the object. The machining force during machining can also be measured based on the force sensor signal detected by the detection means.
The control means uses the detection means and the signal generation means to perform feedback for driving the tool so as to apply a constant force to the object, scan the object, and apply a constant force. It is also possible to measure the output from the displacement sensor at that time. Thereby, the surface shape of the object can be measured. At this time, when the shape of the object is known, the shape of the tool can be measured.

The present invention is an integrated measuring and processing apparatus that enables force measurement by focusing on force and incorporating a high-rigidity and high-sensitivity force sensor into an apparatus equipped with a high-speed tool control unit (FTC). By using this device. In addition to being able to measure in-process what force is applied when creating a three-dimensional fine pattern, it is possible to detect the contact position between a tool and a workpiece and detect minute wear of the tool. In addition, by controlling so that the output of the force sensor is constant, the shape can be measured with the same apparatus.
By using a measuring and processing integrated device,
1) The contact position between the tool and the workpiece can be detected 2) The machining force can be measured in-process 3) The minute wear of the tool can be measured 4) The origin position of the tip of the tool can be measured 5) The machining state can be monitored 6 ) The machining surface shape can be measured with the same tool. 7) The tool tip shape can be measured.

Embodiments of the present invention will be described with reference to the drawings.
<Configuration of measurement processing integrated device>
FIG. 1 shows an outline of an integrated measuring and processing apparatus according to an embodiment of the present invention. The apparatus 100 comprises a high speed tool control unit and a force sensor 150. The high-speed tool servo control unit is a mechanism for holding the tool 120 and controlling the cutting amount at high speed. The cylindrical piezoelectric element (PZT) 130 as an actuator, the tool holder 122 for holding the tool, and the tool 120 It is comprised from the capacitive sensor 140 which measures a displacement. A cutting amount can be given to the tool 120 through the tool holder 122 that holds the tool by the cylindrical piezoelectric element (PZT) 130 having high rigidity and excellent responsiveness.
A piezoelectric element (PZT) 130 used as an actuator exhibits nonlinear voltage-displacement characteristics. One cause is hysteresis, which is a phenomenon in which the response of displacement to voltage is not linear, and does not match when the voltage rises and falls. Another is creep, which is a phenomenon in which the displacement changes slowly with time even if a constant voltage is applied to maintain a constant position. For this reason, it is necessary to detect the position of the tool and perform feedback control.

A capacitive displacement meter 140 arranged concentrically with the piezoelectric element detects the displacement of the cap, that is, the displacement of the tool. By configuring the servo system using this signal as a feedback signal, hysteresis, creep, and the like of PZT can be compensated, and the tool cutting depth can be controlled with high accuracy.
The force sensor 150 is fixed to the base 110 with screws 152 and 154. An arbitrary preload can be applied to the force sensor by the rotation angle of the cap screws 152 and 154 used for fixing.
In order to process the surface of the sample 160 with such an integrated measuring and processing apparatus 100, it is placed on a scanning device (not shown) that can scan in the XY directions relatively, and processing is performed while scanning the surface of the sample. By doing so, a fine pattern can be created.

<Contact judgment>
Now, in order to determine an accurate cutting depth (Z direction) when processing a fine pattern, it is necessary to accurately determine the contact point between the tool and the workpiece. In normal machining, the contact between the tool and the workpiece is determined by visual observation or by observing a machining mark formed on the workpiece surface with an optical microscope. However, when processing a fine pattern, since the tool tip and the cutting depth are small, the processing trace is very small, and there is a problem that it cannot be observed visually or with an optical microscope. In the present invention, the contact determination can be performed using the control / measurement system of the integrated measuring and processing apparatus as shown in FIG.
In the control / measurement system of FIG. 2, the drive voltage from the PZT drive circuit 173 brings the tool 120 close to the sample 160 while vibrating the tool 120 with a minute amplitude on the order of nm. This minute vibration is caused by a sine wave from the function generator 172. The signal for approaching is applied to the PZT from the personal computer system 180 through the D / A board 184 together with the sine wave by the adder circuit 174. An output from the capacitive sensor 140 indicating the displacement of the tool 120 is input to the personal computer system 180 via the A / D board 182. When the AC output of the force sensor 150 is read by the lock-in amplifier 175 and the same frequency as the vibration of the tool 120 is detected, the personal computer system 180 determines that the contact has occurred. Since only the driving frequency component is detected with high sensitivity by the force sensor 150 and the lock-in amplifier 175, the position of the contact point can be detected with high sensitivity. Although not shown, the personal computer system 180 also performs movement control in the XY direction of the measurement processing integrated apparatus 100 using an XY scanning apparatus.

<Measurement of tool wear>
Now, it is necessary to use a sharp tool for fine pattern processing. Therefore, the minute wear of the tool becomes a big problem. However, tool microscopes cannot measure tool wear due to insufficient resolution. FIG. 3 shows the measurement of minute wear of the tool in the integrated measuring and processing apparatus of the present invention.
The contact position between the tool 120 and the standard sample 162 can be detected by installing the standard sample 162 whose position is fixed and detecting the contact point between the tool and the workpiece by the control / measurement system described above. As shown in FIGS. 3A and 3B, before and after machining a workpiece using a tool, the contact position of each tool and a standard sample is detected by a displacement sensor 140 of a capacitive sensor, and the personal computer system 180 is used. Record. The change in the contact position becomes the wear amount d of the tool (see FIG. 3C).
Further, by performing in-process measurement of the machining force when machining a workpiece with the force sensor 150 of the integrated measuring and processing apparatus, damage such as tool chipping can be detected in real time.

<Tool origin position>
Further, when the tool is replaced, there arises a problem that the origin position of the tool tip is shifted due to an attachment error or individual difference in tool dimensions.
4 shows how to determine the origin position by a method of detecting the contact position between the tool and the sample 160 (see FIG. 2) in the same manner as in FIG. 3 when the tool is replaced. As shown in FIGS. 4A and 4B, before and after machining a workpiece using a tool, the contact position between the tool and the standard sample is detected and recorded in the personal computer system 180. The origin position of the tool tip can be determined from the information (see FIG. 4C).

<Processing shape measurement>
The principle of a method for measuring a machined surface fine shape by the measurement / processing integrated device 100 will be described with reference to FIG. In FIG. 4, the processed surface of the sample 160 is processed with, for example, an XY sine wave, and has a wavelength of 50 μm and an amplitude of 100 nm. Further, the elastic deformation region of the processed surface is within 0.1 nm in this case.
By using a machining probe (single crystal diamond tool) as a measurement probe on the machine as it is and applying a voltage from the PZT drive circuit 173 to the PZT 130, the tool 120 is made to approach the sample 160 stepwise while being vibrated minutely. The personal computer system 180 detects the contact between the probe 120 and the sample 160 in the elastic deformation region by the force sensor 150 and applies the voltage from the PZT drive circuit 173 so that the contact force from the force sensor 150 becomes constant. By performing feedback control, scanning in the X direction is performed while controlling the position of the tool in the Z direction at high speed. At this time, the movement trajectory of the tool by the displacement sensor 140 of the capacitance sensor becomes the shape measurement result. A three-dimensional surface shape is created with high accuracy on the order of nanometers by modifying the measurement points based on this measurement data.

<Tool tip shape measurement>
When machining a free-form surface shape, the tip shape of the tool may greatly affect the machining accuracy. In order to improve the machining accuracy, it is necessary to measure the tip shape of the tool and to correct the machining data. As shown in FIG. 6, the shape of a reference sample (for example, a reference sample sphere) 164 having a very high shape accuracy or a known shape error is scanned with the measurement processing integrated device in the same manner as the shape measurement described above. By measuring, the shape of the tool tip can be obtained from the output of the obtained device.
FIGS. 6A, 6B, and 6C show an example in which the apparatus is scanned along the Y direction and the tool tip shape of the YZ section is measured. The tool tip shape of the cross section can be measured. Further, the three-dimensional shape of the tool tip shape can be measured by scanning in the XY plane.
In addition, by performing the same measurement before and after machining, it is possible to see a change in the tool tip shape due to wear or the like.

By using this measurement processing integrated device 100, the problem that the position of the shape measurement point does not coincide with the position of the tool processing point, that is, the shape measurement information cannot be accurately corrected and fed back, and nano-processing of a complex free-form surface cannot be realized. Can be solved.
Unlike conventional atomic force microscopes (AFMs), this method uses a high-speed tool control device capable of ultra-precision diamond turning, so the rigidity of the processing machine is not reduced and high-rigidity machining is required. It is thought that it can be applied to ultra-precision cutting.

<Rigidity of measurement integrated device>
The rigidity and natural vibration frequency of the entire measurement processing integrated device 100 are calculated. A specific configuration of the calculation apparatus is shown in FIG. FIG. 7A is a plan view seen from above, and FIG. 7B is a side view seen from the side.
The structure shown in FIG. 7 is a parallel measurement system that emphasizes high rigidity and responsiveness, and a spring-mass system modeled as shown in FIG. Each part was regarded as an elastic body, and modeling was attempted with the rigidity of PZT as k _p , the rigidity of the parallel system support as k _t , the rigidity of the impact plate as k _c , and the rigidity of the force sensor as k _s .

When a measuring force is applied to the measuring point, in the structure as shown in FIG. 7, the PZT 130, parallel system support (PZT fixing jig) 138, impact plate 156, and force sensor 150 are each directed in the direction of the processing point. Reaction force. The measuring force generated in the tool 120 is received by the PZT 130 and then divided into the parallel system support 138 and the force sensor 150. The force detected by the force sensor 150 depends on the ratio of the stiffness value to the parallel system support 138. When the rigidity of the entire system is calculated according to FIG.

When equation (1) is applied based on the stiffness values of each part of the apparatus, the stiffness value as a processing machine is 480 N / mm, and the resonance frequency is 3400 Hz. These numbers are summarized in Table 1.

In addition, when the measurement processing integrated apparatus is used as a parallel measurement system, there is a problem that the force detected by the force sensor becomes a component of the measurement force. This component force depends on the rigidity of the impact plate-force sensor and the parallel support. If the rigidity of the parallel support portions is excessively increased in order to improve the resonance frequency of the apparatus, the component force of the processing force detected by the force sensor is reduced, which causes a negative effect on force measurement. The stiffness value of the parallel support part selected in this study is 570 N / mm, and the stiffness value of the impact plate-force sensor is 360 N / mm. Therefore, it is calculated that the force detected by the force sensor is 25% of the machining force applied to the apparatus.
Thus, since it is known in advance that the measurement amount detected in real time during machining by the force sensor is 25% of the actual machining force, the actual machining force can also be calculated. In this way, the actual machining force can be grasped in-process.

<Vibration of measurement processing integrated device>
The integrated measuring and processing apparatus creates a three-dimensional shape by controlling the tool at high speed using PZT during sample cutting. When the tool is driven, if it resonates at the natural vibration frequency of the device, the control is not performed accurately, and the correct depth of cut cannot be given. This frequency characteristic is an important factor for determining the conditions of the number of control points for the spindle rotation speed and the cutting amount change during machining. In addition, when the natural vibration frequency of the measurement and processing integrated device is low, the processing speed becomes slow and the processing time is significantly increased. Therefore, a measurement system as shown in FIG. 9 was assembled, and the frequency characteristics of the apparatus were examined.
As shown in FIG. 9, an FFT analyzer 210 was used to measure the frequency response of the measurement and processing integrated device 100. The FFT analyzer 210 includes a digital spectrum analyzer 212 and a function generator 214. A white signal is output from the function generator 214, and one is input to the PZT driving circuit 173 and the other is input to the A channel of the digital spectrum analyzer 212. The response of PZT to which the white signal is applied is measured by the capacitance sensor 230, and the response is input to the B channel of the digital spectrum analyzer 212. From the two channel information, the response performance of the system (device) is calculated, and the gain and phase are digitized. The information is recorded by a personal computer via the GPIB interface board 220.

  FIG. 10 shows the frequency characteristics of this apparatus. In FIG. 10, the gain / phase characteristics of this apparatus are from 100 Hz to 10 kHz. FIG. 10 shows that there are peaks in the vicinity of 2.5 kHz and 5 kHz. It can be said that the peak in the vicinity of 2.5 kHz is close to the calculated natural vibration frequency of the entire apparatus. The reason why the peak was seen at a slightly lower value is considered to be because the part considered as a rigid body when modeling was acting as an elastic body in a minute behavior, or because of insufficient tightening of the cap screw. . However, it can be said that this high natural vibration frequency of 2.5 kHz has a sufficient frequency response as a machining / measurement integrated device, and has achieved high rigidity.

<Processing entity>
FIG. 11 shows a large-area three-dimensional fine shape creation system in which a measurement processing integrated apparatus 100 is installed on an ultra-precision lathe and is subjected to front cutting. The measurement processing integrated device 100 attached to the slide 194 is slid in one direction to process the surface of the workpiece 193 attached to the rotating spindle 195 into a three-dimensional fine shape.
FIG. 12 shows a system in which an on-machine measuring and processing integrated apparatus is installed on an ultra-precision lathe to create a large area three-dimensional fine shape on a cylindrical surface. The surface of the cylindrical workpiece 190 attached to the rotating spindle 192 is processed into a three-dimensional fine shape by the integrated measuring and processing apparatus 100 configured to slide in the axial direction.
11 and FIG. 12, it is possible to create a large area three-dimensional fine shape on a flat surface or a free-form surface.

<Other embodiments>
In the above description, the force sensor in the Z direction of the measurement processing integrated device 100 uses a unidirectional force sensor. Therefore, the attachment position is determined on the same central axis as PZT. However, as shown in FIG. 13, by using the triaxial force sensor 155, for example, a force in the Z direction can be detected even if the triaxial force sensor 155 is attached at a position perpendicular to PZT.

It is a principle diagram of a measurement processing integrated device. It is a block diagram for performing control and measurement of a measurement processing integrated device. It is a figure which shows the measurement of the microabrasion of a tool. It is a figure which shows the measurement of the tool front-end | tip origin at the time of tool replacement. It is a figure which shows the shape measurement by a measurement processing integrated device. It is a figure which shows the tool front-end | tip shape measurement by a measurement processing integrated device. It is a figure which shows the structure of the measurement processing integrated apparatus which measured the rigidity. It is a figure which shows the rigidity calculation model of the apparatus structure of FIG. It is a figure which shows a measurement system when measuring a rigidity characteristic. It is a figure which shows the frequency characteristic of the apparatus structure of FIG. It is the figure which is processing on the plane with the measurement processing integrated type device. It is the figure which is processing on the curved surface by the measurement processing integrated type apparatus. It is a figure which shows other embodiment of a measurement processing integrated device.

Claims (5)

An actuator for driving the tool;
A tool holder coupled to the actuator and holding a tool;
A displacement sensor arranged coaxially with the actuator and measuring the displacement of the tool;
An integrated measuring and processing apparatus using a tool as a shape measuring probe, and a force sensor that measures a force applied to the tool. An integrated measuring and processing apparatus according to claim 1,
And a drive circuit for driving the actuator;
Signal generating means for applying to the drive circuit and generating a signal for moving the tool by the actuator;
Detecting means for detecting signals from the force sensor and the displacement sensor;
When a signal for vibrating the tool is output from the signal generating means, and the detection means detects the same vibration as the vibration applied to the tool from the force sensor, the object contact of the tool is And a control means for detecting displacement. In the measurement and processing system according to claim 2,
Scanning means for moving the measurement processing integrated device relative to the object;
The control means controls the signal generating means and the scanning means, and moves the tool according to a signal from the signal generating means while scanning the surface of the object, and performs predetermined processing on the surface of the object. Measuring and processing system characterized by this. In the measurement and processing system according to claim 3,
A measuring / machining system characterized by measuring a machining force during machining based on a signal of a force sensor detected by the detecting means. In the measurement and processing system according to claim 3,
The control means uses the detection means and the signal generation means to perform feedback for driving the tool so as to apply a constant force to the object, scan the object, and apply a constant force. A measurement / processing system that applies power and measures the output from the displacement sensor at that time.

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