JPS5944164B2 - Cutting tool adjustment method and device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a cutting tool, particularly a method for adjusting the position of a cutting edge of a cutting tool in which a cutting blade is fixed to a shaft and the distance from the center of the shaft can be adjusted. and improvements to the equipment used therein.

When cutting the inner surface of a hole, a so-called boring bar with a cutting blade fixed to the tip of the shaft with a set screw is used, but it is extremely difficult to drill an accurate hole using this boring bar. It required complicated work.

In other words, when attaching a boring bar to the main shaft of a polling machine and performing cutting, first determine the position of the tip of the cutting blade that protrudes from the boring bar (the distance that the cutting blade protrudes in the radial direction from the center of the boring bar). The size of the hole is determined to be smaller than a predetermined size, and the size of the hole obtained by cutting is measured in this state.The position of the cutting blade is readjusted based on the hole size, and the hole is finished cut again.

In this case, if there is an error in the dimensions of the hole, it is necessary to adjust the position of the cutting blade many times, which is complicated.

On the other hand, machine tools such as polling machines are automated using electronic equipment, are extremely sophisticated, and are quite expensive devices.

For this reason, it has become an important issue to increase the operating rate as much as possible, and devices that automatically feed tools have come to be adopted as a means of increasing the operating rate.

However, before storing the cutting tool in this device, it is necessary to adjust the position of the cutting tool with respect to the axis according to the size of the hole to be drilled in the workpiece.

A so-called presetter is used as a device for preparing a cutting tool, but when this presetter is used, the following problems arise in adjusting the cutting tool.

In other words, if there is a misalignment between the center of the main spindle of the machine tool and the center of the tool mounting part at the tip of this main spindle, and if a cutting tool is mounted on the tool mounting part of the main spindle that has this error, the cutting tool will This results in a misalignment between the cutting edge and the center of the spindle by the amount of the error.

On the other hand, there is also an error in the main axis of the presetter for adjusting the cutting tool, and adjustments must be made in consideration of this error.

When adjusting a cutting tool with a conventional presetter, errors on the presetter side are often ignored, and for this reason, the center of the cutting tool attached to the machine tool and the center of the machine tool's main axis are This deviation results in a machining error.

Specifically, the inherent accuracy of the tool mounting part of the spindle of a machine tool is determined by fitting a test rod into the tool mounting part and measuring the runout at the tip of this test rod (approximately 300 mm from the tip of the spindle). It has a value of 0.010 to 0.025, and this value differs depending on the individual machine tool.

On the other hand, the main spindle of a presetter is more accurate than the main spindle of a machine tool, but it also has a different error value depending on the individual device.

The above error in the main axis is amplified at the tip of the cutting tool, but this error i is displayed based on the angle of the rotation direction and the distance from the true center of the axis.

Now, as mentioned above, the main axis of the machine tool and the main axis of the presetter each have errors, and since these errors have directionality, it is necessary to adjust the position of the cutting blade of the cutting tool with the presetter. However, when this cutting tool is actually used to carve the object, a considerable amount of error occurs.
As a result, additional finishing work was often required.

In addition, if the diameter of the hole drilled in the workpiece was smaller than the specified size, there was no problem, but if the hole was large, a situation may arise where the workpiece itself had to be discarded. There is.

The present invention was obtained in order to eliminate the drawbacks of the prior art, and it is possible to accurately grasp errors including the rotational direction and longitudinal position of a cutting tool attached to the main shaft of a machine tool. It is an object of the present invention to provide a cutting tool adjustment method and apparatus that can adjust the position of a cutting blade on a presetter while including this error.

Next, the cutting tool adjustment method of the present invention will be explained.

The present invention is divided into three steps: measurement of errors in the tool mounting portion on the machine tool, measurement of errors in the tool mounting portion on the presetter, and adjustment of the cutting tool edge position.

A Work on machine tools ■, Insert the test rod into the machine tool.

As shown in Fig. 1, a machine tool 1 generally has two drive keys 3 in the tool mounting part 2 of the spindle.
The key groove 3a of the test rod 4 is fitted into the key groove 3a of the test rod 4, and the test rod 4 is inserted into the tool mounting portion 2 and fixed.

As shown in FIG. 2, the test rod 4 has a measuring part 41, an angle scale plate attachment part 42, and a tapered part 43, and an angle scale plate 44 is fixed to the angle scale plate attachment part 42 with screws 45. ing.

2. Now, by rotating the main shaft of the machine tool 1 to which the test rod 4 is fitted, the maximum position and direction of deflection of the measuring portion 41 of the test rod 4 and its value are measured using the dial gauge 5.

Next, the position of this maximum deflection is set to zero on the angle scale plate 44.

After that, the deflection of the test rod 4 is again 5Q from the reference plane A.
Measurements are taken at both point B at a distance of mm and point C at a distance of 300 mm, and the value and direction of the deflection are determined and recorded.

The measuring part 41 of the test stick 4 against the key is caused by the above operation.
The direction of the deflection is determined.

That is, the center of the tool mounting portion of the main shaft of the machine tool is off to the position of the angle formed by the zero of the angle scale plate as measured from the key 3.

B Measurement of error in the tool mounting part of the presetter There is also runout in the tool mounting part of the main shaft of the presetter, but since this is machined with quite high precision, the value is smaller than that of a machine tool. .

Measure the error of the tool attachment part of the main shaft of the presetter using almost the same procedure as in step A above, measure the maximum runout value and its direction, and place a reference mark on the end face of the main shaft of the presetter in that direction. put.

Work on the C presetter As shown in Figures 2 and 3, the main shaft 6 of the presetter
The keyed ring 7 shown in FIG. 4 is fitted into the tool mounting portion 61 of the tool.

The key ring 7 has one key 7 in a part of the ring part 71.
2 is provided protrudingly, and can be fixed to the tool mounting portion 61 with a set screw 73.

■First, without fixing the key ring 7 to the tool mounting part 61,
Be able to move freely.

2. Insert the test rod 4 with the angle scale plate 44 attached into the main shaft 6 of the presetter.

3. Turn the test rod 4 to align the zero mark (reference mark) on the presetter with the zero on the angle scale plate 44.

At this time, the keyed ring 7 is also rotated at the same time.

As mentioned above, the zero mark of the angle scale plate 44 is fixed on the test rod 4 in the direction where the runout of the machine tool is maximum, and the test rod 4 is set at the zero mark of the main shaft 6 of the presetter at the said angle. By matching the zero marks on the scale plate 44, the directions of the maximum deflection of the test rod 4 can be made to match.

4 Next, clamp the test rod 4.

5. Next, fix the city screw 73 of the key attachment ring 7, in which the key 72 is fitted into the keyway 3a of the test rod 4, to the tool attachment portion 61.

6. Finally, remove the test rod 4 from the main shaft 6 of the presetter.

The above-mentioned operations 1 to 6 are for reproducing the direction of runout specific to the machine tool on the bridle lever, and are based on the direction of the key 72 of the key attachment ring 7 and the reference provided on the tool attachment part 2 of the machine tool 1. This means that the direction of key 3 matches.

With the operation A, the amount of misalignment of the tool mounting portion 2 of the machine tool 1 has been determined by half, and with the operation B, the amount of misalignment of the tool mounting portion 61 of the presetter has been determined. C
By aligning the misalignment directions of the tool mounting portions of the machine tool and the presetter through this operation, subsequent adjustment of the cutting tool edge position becomes easy.

D Adjustment of the cutting tool Place the rod of the cutting tool on the main shaft 6 of the presetter, check the position of the key 72 on the keyed ring 7, and insert the key 72 into the key groove.
Loosen the set screw attached to the rod, measure and adjust the position of the cutting blade, and fix the set screw in the specified position.

As mentioned above, when the direction of the maximum runout of the tool mounting part of the machine tool and the direction of the maximum runout of the tool mounting part of the presetter are matched, the value of the runout of both is calculated by '770 and the runout of the rod is calculated. This will result in

Therefore, the position of the cutting blade may be determined by taking this added runout value into consideration.

E Computer-specified machine tool spindle tool mounting section and presetter
By inputting the run-out value of the tool attachment part of the spindle, that is, the value of point B at 50 strokes from reference line A and point C at 100 strokes from reference line A using a test rod, into the microcomputer,
The position of the cutting blade of the cutting tool can be easily adjusted on the presetter.

In other words, since the maximum runout values of the machine tool and presetter are known and their directions are matched on the precenter, the amount of runout in the mounting direction and position of the cutting blade is calculated,
Based on this value, determine the value at which the cutting blade protrudes from the cutting rod, finely adjust it to that value, and fix it with a set screw.

In the above explanation, the direction of the maximum runout of the tool mounting part of the machine tool was set as the zero position of the angle scale plate to make the work more convenient, but read an appropriate angle and calculate the runout value at that position. It is also possible to calculate the direction and value of the maximum runout and use this value as data when adjusting the cutting tool in the presetter.

When carrying out the cutting tool adjustment method of the present invention, the characteristics specific to the presetter explained in section B are measured and recorded in advance or entered into a computer, so in reality, there are three types: A, C, and D. Now A, 0. This may be carried out according to steps D and E.

According to the present invention, the direction and value of the maximum runout of the tool mounting portion of the test rod are confirmed using the angle scale plate provided on the test rod using the position of the keyway of the test rod as a reference, and the direction is determined by the presetter. It can be moved onto the tip attachment part of the main shaft.

Therefore, by inserting and fixing a tool into the tool mounting portion of the presetter spindle based on the position of the key on the key mounting ring of the presetter spindle, adjustments can be made just as if the cutting tool had been adjusted on the machine tool. I can do it.

As mentioned above, by checking the direction of the best runout of the tool mounting part of the main spindle of the machine tool on the tool mounting part of the presetter, the adjustment can be realized extremely accurately and easily, which makes it easier to use the adjusted cutting tool. 1'L can immediately drill an accurate hole and can significantly improve the operating rate of the machine tool.

As described above, the present invention uses simple means to determine the center runout of the tool attachment part unique to machine tools, and reproduces this on the presetter to adjust the position of the cutting blade, thereby eliminating adjustment errors due to individual differences. Especially if a computer is used, the adjustment work becomes easier.

Note that the key ring shown has a fixed key, but
The present invention is not limited to this, and any structure may be used as long as the key can be moved in and out of the ring portion (attachment portion) in the radial direction.

[Brief explanation of drawings]

Figure 1 shows the state in which a test rod is attached to the main shaft of a machine tool and the runout value and direction at two positions on the test rod are measured. Figure 2 shows the test rod, angle scale plate, and key. FIG. 3 is a partially cutaway side view showing the relationship between the attached rings, FIG. 3 is a plan view of the test rod etc. in FIG. 2, and FIG. 4 is a perspective view of the keyed ring. 1...Machine tool, 2...Tool mounting part,
3...Key, 4...Test stick, 6...
--- Main shaft of presetter, 7 --- Ring with key, 41 --- Measurement part, 42 --- Angle scale plate mounting part, 44 --- Angle scale plate, 61...
...Presetter tool mounting part.

Claims (1)

[Claims] 1. Check the direction of runout of the tool mounting portion of the main spindle of the machine tool, and match the direction of runout of the tool mounting portion of the main spindle of the presetter with the direction of the runout, and remove the printer tool. A cutting tool adjustment method characterized by adjusting the position of a cutting blade by inserting and fixing the tool into a mounting portion. 2. A measuring part, an angle scale plate rotatable and fixable to the base of the measuring part, a part of the taper fitted to the tool mounting part, and a part provided between the part of the taper and the measuring part. A cutting tool adjustment device comprising a combination of a test rod having a keyway and a keyed ring that can be fixed to a tool mounting portion of a presetter and has a key that fits into the keyway.