JP2012183608A - Machining diameter correction device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a machining diameter correction device that can proceed a hole drilling while feed-backing that a correction of a machining diameter is executed appropriately wherein a configuration of the machining diameter correction device is improved to be simpler so that automation of the hole drilling at the machining diameter is advanced.SOLUTION: The machining diameter correction device 1 to correct a machining diameter A processed by a tip 9 at boring includes: an input unit 11 which is a portion displaced by pressing; an output unit 12 which is displaced by a predetermined stroke S due to a displacement of the input unit 11 by a predetermined stroke L; and a converting mechanism 16 which converts the displacement of the input unit 11 to the displacement of the output unit 12. The device also includes: a pressure sensor 3b which measures a suppress strength F toward the input unit 11; and a controlling unit 4 which preliminarily stores information related to an acceptable value of the suppress strength F towards the input unit 11 and determines whether the suppress strength F measured by the pressure sensor 3b conforms to the acceptable value.

Description

  The present invention relates to a technique of a machining diameter correction apparatus that is an apparatus for correcting a machining diameter by a chip in boring.

Conventionally, when drilling (boring) using a boring device equipped with a drilling tool, the machining diameter changes according to the wear state of the insert. It is necessary to make corrections.
Therefore, various techniques related to a machining diameter correction device for correcting the machining diameter have been developed. For example, the technique is disclosed in Patent Document 1 shown below and is publicly known.

The machining diameter correction device according to the first embodiment disclosed in Patent Document 1 can be a member that supports the chip by the relative movement of the screwing operation of the screw portion formed on the tool holder and the holding nut. The machining diameter is corrected by bending a flexible tool having flexibility.
Further, in the machining diameter correction device according to the second embodiment disclosed in Patent Document 1, the rod that is the member that supports the tip and has the eccentric cam is bent by the rotation operation of the tool holder (slide base). Thus, the machining diameter is corrected.

  Thus, in the conventional machining diameter correction apparatus as disclosed in Patent Document 1, the mechanism for correcting the machining diameter is complicated, and the configuration of the machining diameter correction apparatus is large. Therefore, it has been desired to develop a machining diameter correction apparatus that can correct the machining diameter with a simpler configuration.

Therefore, the processing diameter correction apparatus having a simpler configuration has been developed by the applicant of the present invention.
The machining diameter correction device developed by the applicant of the present application includes a pressing portion, and is configured to correct the machining diameter by displacing the chip by a predetermined correction amount by pressing the pressing portion with a predetermined stroke. Further, a mechanism for displacing the tool holder is utilized as a mechanism for pressing the pressing portion, and the pressing portion is pressed against the pressed portion by the displacement operation of the tool holder.

JP-A-55-131413

The processing diameter correction device proposed by the present applicant has a simple configuration capable of correcting the processing diameter by pressing the pressing portion with a predetermined stroke, but means for confirming whether the correction has been properly performed or not. Therefore, it was possible to determine whether or not the correction amount was appropriate only after measuring the corrected machining diameter.
For this reason, when correction is not performed well (that is, when the pressing portion is not pressed with a predetermined stroke), a workpiece that does not meet the standard is generated, and rework may occur. Therefore, there has been a problem that the correction of the machining diameter cannot be automated as expected.

  The present invention has been made in view of such a problem of the present situation, and in a processing diameter correction device having a simpler configuration, feedback that the correction of the processing diameter has been appropriately performed in order to advance automation of the hole processing. However, an object of the present invention is to provide a machining diameter correction device capable of proceeding with hole machining.

  The problem to be solved by the present invention is as described above. Next, means for solving the problem will be described.

  That is, in claim 1, it is an apparatus for correcting a machining diameter by a chip in boring processing, and an input part which is a part displaced by pressing, and the input part is displaced by a predetermined stroke, A machining diameter correction apparatus comprising: an output unit that is a portion displaced by a predetermined stroke; and a conversion mechanism that converts displacement of the input unit into displacement of the output unit, and measures a pressing force on the input unit. And a control unit for determining whether the pressing force measured by the pressure sensor matches the allowable value, and information related to the allowable value of the pressing force for the input unit is stored in advance. Are further provided.

  As effects of the present invention, the following effects can be obtained.

  According to the first aspect of the present invention, the correction of the machining diameter can be automated in the boring apparatus provided with the machining diameter correcting apparatus having a simpler configuration.

The schematic diagram which shows the whole structure of the processing diameter correction apparatus which concerns on one Embodiment of this invention, (a) The cross-sectional schematic diagram in a Y-axis direction (side view), (b) The schematic diagram in a X-axis direction (front view). The schematic diagram which shows the correction condition of the process diameter by a process diameter correction apparatus, (a) The schematic diagram which shows a normal correction condition, (b) The schematic diagram which shows an abnormal correction condition. The flowchart which shows the correction method by the processing diameter correction apparatus which concerns on one Embodiment of this invention. The schematic diagram which shows the detection condition of the pressing force by a pressure sensor.

Next, embodiments of the invention will be described.
First, a machining diameter correction apparatus according to an embodiment of the present invention will be described with reference to FIGS. 1 and 2.
As shown in FIG. 1, a machining diameter correction device 1 according to an embodiment of the present invention is used in a boring device (not shown) which is a device for performing machining (boring) on a metal material. The apparatus includes a correction unit 2, a pressed unit 3, a control unit 4 and the like.

The correction unit 2 is used by being disposed between a tool 7 that is a tool for boring and a main shaft 8 that is a shaft part for holding the tool 7.
That is, as shown in FIG. 1, the correction unit 2 of the machining diameter correction apparatus 1 is held by the main shaft 8, and the tool 7 is held by the correction unit 2.

One end of the main shaft 8 is rotatably supported by a displacement device (not shown) of the boring device and is rotationally driven by a rotation driving device (not shown) such as a motor of the boring device. . Further, the main shaft 8 includes a holding portion 8a serving as a chuck mechanism for holding the machining diameter correction device 1 (or the tool 7 directly) at the other end.
Further, the main shaft 8 is configured to be displaceable in each direction of the X axis, the Y axis, and the Z axis shown in FIGS. 1A and 1B by a displacement device (not shown).

The tool 7 is a rotary tool including a tip (cutting blade) 9, and includes a base portion 7 a that is a portion having a shape that can be held by the machining diameter correction device 1 and a shaft portion 7 b that is a portion for holding the tip 9. I have. In the tool 7, the base 7a and the shaft 7b have a common axis. The tip 9 projects from the tip of the shaft 7b toward the radially outer side.
Further, an intermediate portion in the axial center direction of the base portion 7a and the shaft portion 7b is provided with a flange portion 7c which is a portion whose diameter is increased as compared with the base portion 7a and the shaft portion 7b.

The tool 7 is configured such that the base 7 a is held by the correction unit 2, so that the axes of the base 7 a and the shaft 7 b substantially coincide with the axis P of the main shaft 8. Is rotated about the axis P as the axis.
For this reason, it is set as the structure which sets the process diameter A (namely, A = 2R) by the tool 7 by changing the distance R with respect to the axial center P of the front-end | tip part 9a of the chip | tip 9. FIG.

The correction part 2 constituting the machining diameter correction apparatus 1 is an apparatus that can adjust the inclination of the shaft part 7 b with respect to the axis P of the tool 7. And a case 15 or the like.
The correction unit 2 is integrally fixed to the main shaft 8 by holding the holding unit 13 by the holding unit 8a of the main shaft 8, and as the main shaft 8 is displaced, FIGS. It can be displaced in each of the X-axis, Y-axis, and Z-axis directions shown therein, and is rotated around the axis P as the axis when the main shaft 8 rotates.

The input unit 11 includes a pressing unit 11a that can be pressed in a direction orthogonal to the axis P. When the pressing unit 11a is pressed, a correction operation instruction to the correction unit 2 is input. Moreover, the pressing part 11a can be displaced by a predetermined stroke by being pressed.
In the following description, an operation of pressing the pressing portion 11a and displacing the pressing portion 11a with a predetermined stroke L is referred to as a pressing operation.

The output portion 12 is inserted into a support hole 14a that is a substantially cylindrical gap formed inside the main body portion 14 covered with the case 15, and the support hole 14a causes the support hole 14a to move in the axial direction of the support hole 14a. It is supported so that it can be displaced.
The support hole 14a is formed so that its axial direction is substantially parallel to the axial center P, and the output portion 12 can be displaced substantially parallel to the axial center P.

  Further, the main body portion 14 is formed with a split portion 14b which is a cut portion in a direction orthogonal to the axis P. For this reason, the main-body part 14 can be deform | transformed so that the cut shape of the split part 14b may become a substantially fan shape by using the fulcrum part 14c formed in the site | part with the deepest cut of the split part 14b as a fulcrum.

Furthermore, a conversion mechanism 16 that is a mechanism for converting a pressing force in a direction orthogonal to the axis P with respect to the pressing portion 11 a into a stress in a direction parallel to the axis P is provided in the main body 14.
The conversion mechanism 16 in the present embodiment is configured by a hydraulic cylinder 16a, and is configured to convert the direction of the stress by an inclined portion 16b that is a surface inclined with respect to the axis P formed in the hydraulic cylinder 16a.

  The output part 12 is in contact with the inclined part 16b, and when the hydraulic cylinder 16a is displaced in a direction orthogonal to the axis P, the output part 12 is pressed in a direction substantially parallel to the axis P by the inclined part 16b (this book). In the embodiment, when the hydraulic cylinder 16a is displaced upward in FIG. 1, the output portion 12 is pressed toward the flange portion 7c of the tool 7). And it is set as the structure which displaces the output part 12 in the direction substantially parallel to the axial center P along the support hole 14a.

When the output portion 12 is displaced in a direction approaching the flange portion 7c of the tool 7 substantially parallel to the axis P, the output portion 12 presses the locking portion 14d formed at the end portion of the support hole 14a. .
At this time, since the main body part 14 is deformed so that the cut shape of the split part 14b becomes a substantially fan shape, the end face 14e of the main body part 14 can press the flange part 7c of the adjacent tool 7.

In this way, the output unit 12 outputs in a manner in which the flange 7c is pressed in a direction substantially parallel to the axis P with the end surface 14e in accordance with an instruction for the correction operation to the input unit 11, and the output of the output unit 12 Accordingly, the inclination of the shaft portion 7b with respect to the axis P is changed.
Then, by changing the inclination of the shaft portion 7b with respect to the axis P, the distance R (that is, the machining diameter A by the tip 9) of the tip 9 with respect to the axis P of the tip 9a is corrected.

That is, in the correction unit 2, the output unit 12 is displaced by a predetermined stroke S in a direction parallel to the axis P and approaching the flange 7 c by a pressing operation on the pressing unit 11 a. Yes.
The displacement of the output unit 12 due to the pushing operation of the pressing unit 11a is held by a holding mechanism (not shown) (for example, a ratchet mechanism), and the displacement of the output unit 12 is held even when the pressing to the pressing unit 11a is released. It is said.
On the other hand, when the displacement amount of the pressing portion 11a is less than the predetermined stroke L, when the pressing on the pressing portion 11a is released, the displacement of the output portion 12 is restored to the position before the pressing portion 11a is pressed. It is configured.

Further, in the processing diameter correcting device 1, every time the pressing portion 11a is displaced at a predetermined stroke L, the displacement of the output portion 12 is changed stepwise by the predetermined stroke S, and the pressing operation of the input portion 11 is performed. The inclination of the shaft portion 7b can be changed stepwise according to the number of times.
Accordingly, the correction amount of the tip 9 (that is, the change amount of the distance R with respect to the axis P of the tip end portion 9a, hereinafter referred to as the correction amount ΔR) is changed depending on the number of times the pushing operation is performed on the pressing portion 11a. be able to.

  In addition, although not shown in the present embodiment, an input unit, an output unit, a conversion mechanism, and the like are additionally provided in the main body of the machining diameter correction device, and a shaft of the axis P is formed by two output units. By adopting a configuration that presses each point that is point-symmetric with respect to the axis P when viewed from the center direction, it is possible to adjust the chip correction amount ΔR in the direction of increasing or decreasing the machining diameter. .

Further, the machining diameter correcting apparatus 1 includes a pressed portion 3 having a pressed member 3a, a pressure sensor 3b, a base member 3c, and the like, and a control unit 4 as shown in FIG.
The pressed part 3 is a part for pressing the pressing part 11a of the input part 11 in the correction part 2, and is disposed at a position that does not hinder the boring processing by the tool 7 within the movable range of the pressing part 11a by the main shaft 8. ing.

  The member 3a to be pressed is a convex portion having a shape that can be inserted into the input unit 11, and one end of the pressed member 3a is in contact with the pressing unit 11a and the other end is supported by the pressure sensor 3b supported by the base member 3c. Abutted.

The pressure sensor 3b is a sensor for detecting a pressing force F acting on the pressed member 3a, and for example, a strain gauge can be employed.
Further, the measurement result of the pressing force F by the pressure sensor 3 b is configured to be input to the control unit 4.

Further, the control unit 4 can calculate a necessary correction amount based on the measurement result of the machining diameter. Further, the controller 4 sets the required number of times of pressing against the pressing portion 11a based on the required correction amount obtained.
For example, if the correction amount ΔR of the chip 9 when the pressing portion 11a is displaced once with a predetermined stroke L is 1 μm, and the required correction amount is 5 μm, the required number of pressings on the pressing portion 11a Can be set to 5 times.

  And in the processing diameter correction apparatus 1, as shown to Fig.2 (a), the correction | amendment part 2 is inserted in the state which inserted the to-be-pressed member 3a in the input part 11, and pressed the to-be-pressed member 3a on the press part 11a. It is set as the structure which implement | achieves pushing operation of the press part 11a by displacing to Z-axis direction downward.

By the way, in the processing diameter correcting apparatus 1 having such a configuration, even if the pressing operation is intended to be performed a predetermined number of times, if the pressing operation is not appropriate each time, a desired correction amount is given to the chip 9. There is a problem that can not be.
For example, as shown in FIG. 2 (b), the pressed portion 3 is in an inclined posture such that the entire other end of the pressed portion 3 is not in contact with the base member 3c. If the pressing portion 11a is pressed by the pressed portion 3 and is displaced with the predetermined stroke L, the displacement U of the pressing portion 11a is less than the predetermined stroke L. Accordingly, the displacement amount of the output unit 12 becomes a stroke V less than the predetermined stroke S, and the machining diameter A cannot be appropriately corrected.

For this reason, the measurement result of the pressing force F by the pressure sensor 3b is input to the control unit 4, and information related to the pressing force F when the pressing operation is normally performed (allowable value of the pressing force F). The configuration is stored in advance.
In the machining diameter correction apparatus 1, the control unit 4 compares the measurement result of the pressing force F with information related to the pressing force F when the pressing operation is normally performed, so that the pressing operation is normally performed. It is made to determine whether or not.

Next, a machining diameter correction method by the machining diameter correction apparatus according to an embodiment of the present invention will be described with reference to FIGS.
When the machining diameter is corrected using the machining diameter correction apparatus 1 according to the embodiment of the present invention, first, as shown in FIG. (STEP-1).

  Next, the processing diameter A of the hole 20a is measured (STEP-2). For example, the measurement of the processing diameter A with respect to the hole 20a here can be performed by an operator using a caliper or the like.

Next, the determination based on the measured diameter A of the hole 20a is performed (STEP-3).
Specifically, the operator inputs the measured processing diameter A of the hole 20a to the control unit 4, and the control unit 4 causes the processing diameter A of the hole 20a to fall within an error range of a desired processing diameter. It is determined whether or not there is. The error range of the desired machining diameter is a value range in which the machining radius error value can be automatically corrected by the machining diameter correction device 1.

  If the measured machining diameter A of the hole 20a is within the error range, the next necessary correction amount is calculated (STEP-4), and the process proceeds to a correction operation based on the correction amount obtained by the calculation. To do.

  Moreover, in the processing diameter correction apparatus 1, the control part 4 sets the required frequency | count of a press with respect to the press part 11a based on the required correction amount calculated | required by calculation.

  The calculation of the necessary correction amount does not have to be performed every time the hole 20a is processed (for example, every time). For example, an error with respect to a desired processing diameter is continuously three times within an allowable range that does not require correction. It may be set so that the correction operation is performed by calculating the correction amount when it exceeds. Thereby, shortening of processing time can be aimed at.

  On the other hand, if the measured diameter A of the hole 20a is not within the error range, it is difficult to continue the automatic correction. Therefore, the boring device is stopped and the boring process is stopped for confirmation by the operator. (STEP-12).

In the correction operation for the chip 9 in the machining diameter correction device 1, first, the number of presses calculated by the control unit 4 is set for a displacement device (not shown) (STEP-5).
Further, the required amount of movement of the main shaft 8 is calculated by the control unit 4 from the arrangement of the main shaft 8 and the pressed member 3a (STEP-6).
Then, the main shaft 8 is displaced to a predetermined correction position, and the main shaft 8 is displaced downward with a predetermined stroke L in the Z-axis direction with reference to the position where the pressing portion 11a contacts the pressed member 3a at the correction position ( (STEP-7).
Thereby, the pressing part 11a can be displaced by the predetermined stroke L by the pressed member 3a.

  At this time, the pressing force F acting on the pressed member 3a is measured by the pressure sensor 3b, and the measurement result is input to the control unit 4 (STEP-8).

Here, it is determined whether or not the predetermined correction operation is normally performed (STEP-9).
As shown in FIG. 2B, the correction operation (predetermined pushing operation) in the machining diameter correction device 1 is such that the displacement position of the spindle 8 by a displacement device (not shown) is displaced or the pressed member 3a is displaced. In this case, since the pressed member 3a does not come into contact with a predetermined position of the input unit 11, even if the main shaft 8 is displaced with a predetermined stroke L by a displacement device (not shown), the output unit 12 has a predetermined stroke S. It may not be displaced.
Therefore, the machining diameter correction apparatus 1 is configured to determine whether or not a predetermined pushing operation is normally performed based on the pressing force F detected by the pressure sensor 3b.

As shown in FIG. 4, the pressing force F detected by the pressure sensor 3b starts to rise from the time t1 when the pressed member 3a and the input unit 11 come into contact with each other, and the downward displacement of the main shaft 8 by a displacement device (not shown) occurs. It rises until the end time t2.
Then, the pressing force F becomes maximum when the downward displacement of the main shaft 8 by the displacement device (not shown) reaches the bottom dead center, and is maintained in this state for a certain time (from time t2 to time t3 in this embodiment). I am doing so.
Then, the pressing force F when it is held for a certain period of time is within a predetermined allowable range as compared with the information related to the pressing force F in the case of a normal pushing operation stored in the control unit 4 in advance. In this case, the pressed member 3a is normally inserted into the input unit 11, and the correction operation is determined to be performed normally.

If such a determination is not performed, the determination as to whether or not the correction operation has been normally performed can be understood only after measuring the machining diameter of the hole 20a after the correction. Therefore, it becomes difficult to automate the correction of the machining diameter.
On the other hand, it is possible to achieve more complete automation by feeding back the quality of the correction operation as in the machining diameter correction apparatus 1 according to the embodiment of the present invention.

Here, when it is determined that the arrangement of the pressed member 3a and the input unit 11 is normal, the pushing operation is performed as many times as necessary (STEP-10).
Thereby, a necessary correction amount is given to the chip 9 and the correction operation is completed.

  Then, the process shifts to boring processing for the next workpiece 20 (STEP-11), and returns to the above-described (STEP-1) to continue boring processing on the workpiece 20 by the boring device.

  On the other hand, if it is determined that the arrangement of the pressed member 3a and the input unit 11 is not normal, it is difficult to continue the automatic correction. Therefore, the boring device is stopped to confirm by the operator, and the boring process is stopped. (STEP-12).

That is, the processing diameter correction device 1 according to an embodiment of the present invention is a device for correcting the processing diameter A by the chip 9 in boring processing, and an input unit 11 that is a portion displaced by pressing, and an input An output unit 12 that is a part that is displaced by a predetermined stroke S when the unit 11 is displaced by a predetermined stroke L, and a conversion mechanism 16 that converts the displacement of the input unit 11 into the displacement of the output unit 12. The pressure sensor 3b for measuring the pressing force F applied to the input unit 11 and the information related to the allowable value of the pressing force F applied to the input unit 11 are stored in advance, and the pressing force F measured by the pressure sensor 3b is stored. Is further provided with a control unit 4 that determines whether or not the value matches an allowable value.
With such a configuration, the correction of the processing diameter A can be automated in the boring device including the processing diameter correction device 1 having a simpler configuration.

DESCRIPTION OF SYMBOLS 1 Processing diameter correction apparatus 2 Correction | amendment part 3 Pressed part 3a Pressed member 3b Pressure sensor 3c Base member 4 Control part 7 Tool 8 Spindle 9 Tip 11 Input part 12 Output part 16 Conversion mechanism

Claims (1)

It is a device for correcting the processing diameter by the tip in boring processing,
An input unit that is a part that is displaced by pressing;
An output part that is a part displaced by a predetermined stroke by displacing the input part with a predetermined stroke; and
A conversion mechanism for converting the displacement of the input unit into the displacement of the output unit;
A machining diameter correction device comprising:
A pressure sensor for measuring a pressing force against the input unit;
Information related to the allowable value of the pressing force with respect to the input unit is stored in advance, and a control unit that determines whether the pressing force measured by the pressure sensor matches the allowable value;
Further comprising
A processing diameter correction apparatus characterized by the above.

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