JPH06179103A - Turning tool - Google Patents

Abstract

PURPOSE:To enable boring of a deep hole and prolong the service life of a blade edge by preventing a turning tool, especially a boring bar, from chattering in cutting. CONSTITUTION:A turning tool comprises a holder main body 10, a support means 18 which is installed between a space with a weight 12 stored in a hollow section of it and supports the weight 12 apart from the internal surface of the hollow section, a change means 34 to change the support location of it, and a control means 28 to control the change means 34. The control means 28 can operate the change means 34 based on vibration generated at the tool edge which is detected by a sensor 26 or by an operator visually or audibly, and can set the natural frequency of the weight 12 properly according to chattering.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a turning tool, and more particularly to a tool for suppressing chatter vibration of a holder body.

[0002]

2. Description of the Related Art FIG. 4 shows a conventional example of a turning tool called a boring bar used for cutting a cylinder bore or the like. The boring bar is composed of a holder main body 2 attached to a chuck of a machine tool and a head 4 provided at the tip of the holder main body 2, and a cutting blade 6 such as a throwaway tip is provided at the tip of the head 4.
Is provided. The holder main body 2 is formed of a highly rigid cemented carbide to prevent bending and chattering, while the head 4 is formed of a material such as steel in consideration of workability.

FIG. 5 shows another conventional example of a boring bar. The holder main body 10 of the boring bar is formed in a hollow shape, and the inside of the holder main body 10 is filled with grease and oil, and the weight 1 is supported by these.
2 are housed. In this bowling bar,
The vibration of the holder body 10 is canceled by the inertial force of the weight 12 to obtain a vibration damping effect. Further, the movement of the weight 12 is braked by a filler 14 such as grease. The head 10 is removably attached to the holder body 10, and a seal 16 is provided on the fitting surface of the head body 10 to prevent the filler 14 from leaking.

[0004]

However, the above-mentioned conventional tool has a problem that the cemented carbide as the material of the holder body is expensive and has poor workability. Also,
However high the rigidity of cemented carbide is, it is inevitable that it has a specific natural frequency, and there is a problem that a sufficient chatter suppressing effect cannot be obtained depending on the cutting conditions.

Even in the case of other conventional tools, the damping effect of the weight 12 is effective only within a specific frequency range. In this case as well, the damping effect is ensured by flexibly responding to cutting conditions. The problem is that it is difficult to maintain. Therefore, there is a problem that it is difficult to efficiently perform deep hole machining (inner surface machining of a hole having a certain depth or more with respect to the outer diameter of the holder body) regardless of which of the conventional tools is used. . The present invention has been made in view of the above circumstances, and an object thereof is to provide a turning tool capable of exhibiting an optimum vibration damping effect in accordance with various cutting conditions.

[0006]

To achieve the above object, the invention of claim 1 provides a turning tool comprising a head to which a blade is attached and a holder body supported by a machine tool. A hollow portion provided inside, a weight accommodated in the hollow portion, and a support means provided between the weight and the holder body to support the weight at a distance from the inner surface of the holder body. , A changing means for changing the supporting position of the supporting means, and a control means for controlling the changing means. According to a second aspect of the present invention, in the first aspect, the control means is configured to be controlled by a detection signal of a sensor that detects vibration of the blade edge or the head. According to a third aspect of the present invention, in the first aspect, the supporting means is a rod-shaped member that connects the holder body and the weight, and a plurality of the changing means are provided between the holder body and the weight. It is configured to operate selectively.

[0007]

According to the above construction, the supporting position of the weight by the supporting means is changed by the operation of the changing means, and the natural vibration period of the weight is changed. Therefore, the weight vibrates in the opposite phase to the holder, and the chatter is offset. Further, the vibration of the blade edge is detected by the sensor, and the control means operates the changing means based on the vibration to automatically select the natural vibration cycle of the weight.

[0008]

Embodiments of the present invention will be described below with reference to the drawings. In the figure, the same parts as those in the conventional example are designated by the same reference numerals to simplify the description. First, the principle of the damping action of the weight 12 will be described using the model tool shown in FIG.
In FIG. 1, a hole 16 is formed in the center of the weight 12, and a supporting means 18 for supporting the weight 12 on the holder body 10 is inserted into the hole 16 and the tip thereof is fixed to a fixing point 20 (illustration). In the case of, the weight 12 is fixed to the weight 12 at the center of gravity of the weight). The supporting means 18 is an elastic body that is deformed by the acceleration acting on the weight 12, and the other end is fixed to the head 4. Reference numeral 22 is a viscous fluid sealed in the holder main body 10, and reference numeral 24 is a sealing material that seals between the head 4 and the holder main body 10 to prevent leakage of the viscous fluid.

In the above model tool, the holder body 1
The holder body 10 can be damped by causing the natural frequency ω _{1 of} 0 and the natural frequency ω ₂ of the weight 12 that performs the vibration damping action to coincide with each other and vibrating the weight 12 in a phase opposite to that of the holder body 10. it can.

The above ω ₁ is given by the following equation. ω ₁ = (K / M) ^1/2 K = 3E ₁ I ₁ / L ³ = 3E ₁ πD ⁴ / 64L ³ However, E ₁ is the Young's modulus of the holder body 10, D ₁ is the outer diameter of the holder body 10, M is the weight of the holder body 10, and K is the spring constant of the holder body 10. Therefore, I ₁ is the second moment of area of the holder body 10 when it is assumed to be solid. Note that the holder body 10 is actually composed of a hollow portion and a solid portion, but here it is assumed to be solid for simplicity. The above ω ₂ is given by the following equation. ω ₂ = (k / m) ^1/2 k = 3E ₂ I ₂ / L ₁ ³ = 3E ₂ πd ⁴ / 64L ₁ ³ where E ₂ is the Young's modulus of the supporting means 16 and d ₂ is outside the supporting means 18. The diameter and m are the weight of the weight 12. Therefore, I ₂ is the second moment of area of the supporting means 18.

In the present application, by adjusting the length L of the supporting means, the natural frequency ω ₂ of the weight 12 is set to a value as close as possible to the natural frequency of the holder body 10 to perform the vibration damping action.

2 and 3 show an embodiment of the present invention. Reference numeral 26 is a sensor. This sensor 26
Is an acceleration sensor, for example, which converts acceleration generated due to vibration during cutting generated in the cutting edge 6 (or the entire head 4) into an electric signal.

The detection signal of the sensor 26 is input to the controller 28. The output of the controller 28 is supplied to the driving means 32 to 36. These drive means 32 to 36 are means such as a piezoelectric element or a magnetostrictive element for converting a drive current into a mechanical displacement, and the displacement direction thereof is set in the radial direction of the holder body 10. One end of the driving means is fixed in the head 4, and the other end is provided with a clamp portion 38 having a recess corresponding to the outer circumference of the supporting means 18. Further, the radial distance between the clamp portion 38 of each drive means 32 to 36 and the support means 18 corresponds to the deflection of the weight 12 in the range of the angle θ, and gradually increases as it approaches the weight 12. Is set (for example, the driving means 32)
~ 36 by setting the stroke of itself).

In the embodiment shown in FIG. 2, the supporting means 1 is used.
Threaded portions are provided at both ends of 8, respectively, one of which is screwed into the head 4 and the other of which is screwed into the weight 12.

Further, the distance between the weight 12 and the base end portion of the supporting means 18 and the driving means 32 to 36 is set to L ₀ , L ₁ , L ₂ and L ₃ , respectively, as shown in the figure.

A viscous fluid 22 such as silicone oil is contained in the holder body 10 in the same manner as in the conventional example so as to perform a damping function against the vibration of the weight 12. Reference numeral 24 is a sealing material for sealing between the head 4 and the holder body 10 to prevent the viscous fluid 22 from leaking.

Next, the operation of the boring bar of the present invention will be described together with the control contents of the controller 28. The boring bar is used for cutting the inner circumference of the cylinder bore. When turning by applying the cutting edge 6 to the surface to be cut,
Vibration associated with processing is generated in the cutting edge 6. This vibration is detected by the sensor 26, converted into an electric signal, and supplied to the controller 28. The controller 28 controls the drive signal to the drive means 32 to 36 by the input electric signal.

The controller 28, for example, recognizes the frequency of the chatter detection signal supplied from the sensor 26, compares the frequency with a plurality of frequencies set and stored in advance, and is closest to one of the set frequencies. To select the length of the pendulum to set the weight 12 to the natural frequency,
A drive current is supplied to each drive means 32-36. That is, when all the driving means 32 to 36 are turned off, the vibration radius of the weight 12 becomes L ₀ , and the supporting means 18 are supported on the clamp portion 38 by sequentially and selectively operating the weights 32, 34 and 36.
By supporting the intermediate portion of the above, L ₁ , L ₂ , and L ₃ are obtained, and the natural frequency is sequentially increased.

The vibration of the cutting edge 6 can be canceled by vibrating the weight 12 at the same frequency as the chatter and in the opposite phase.

Further, the driving means 32 to 36 may be made to perform not only the supporting-releasing operation for supporting the supporting means 18 but also a positive vibration action, in this case, the controller 28. At drive means 32-36
The amplitude and phase of the vibration may be adjusted.
For example, it is possible to set the optimum value by adjusting the control gain and phase of the controller while actually cutting and obtaining the correction value that minimizes the vibration. Further, for known cutting conditions, the vibration suppressing function can be immediately exerted by setting the correction value recorded in advance. The correction of the gain and the phase is mainly performed to correct the time delay or the like that occurs depending on the viscosity of the viscous fluid 22 and the mass of the entire tool. Further, the gain correction is performed in the damping direction according to not only the absolute value of the vibration detected by the sensor 26 but also the magnitude of the differential value (whether the vibration is in the damping state or in the increasing direction), for example. In this case, a smaller gain is selected, and in the increasing direction, a larger gain is selected.

The specific construction of the driving means 32 to 36 is not limited to one that operates electrically, but may be one that operates by fluid pressure.

The control means does not automatically select the natural frequency of the weight by the vibration detected by the sensor, but any driving means is operated by the vibration visually or audibly recognized by the worker. It may be a method of determining whether or not.

Needless to say, the specific configuration of the present invention, such as the driving direction of the driving means, the supporting position of the supporting means, the supporting direction, or the control method of the control means, is not limited to the above-mentioned embodiments.

[0024]

As is apparent from the above description, the present invention is
In a turning tool including a head to which a blade is attached and a holder body supported by a machine tool, a hollow portion provided in the holder body, a weight housed in the hollow portion, the weight, and the weight Support means provided between the holder body and supporting the weight at a distance from the inner surface of the holder body, changing means for changing the support position of the supporting means, and control means for controlling the changing means. Therefore, the position of the weight supported by the supporting means is changed by the action of the changing means, and the natural vibration period of the weight is changed. Therefore, the weight vibrates in the opposite phase to the holder, and the chatter is offset.

Detection of Vibration of Blade Edge by Sensor The vibration of the blade edge is detected by the sensor, and the control means operates the changing means based on the detected vibration to automatically select the natural vibration cycle of the weight. Therefore, it is possible to cancel the chatter that occurs at various frequencies depending on the cutting conditions, etc., by vibrating the weight at an appropriate cycle, effectively suppressing chatter during cutting and enabling deep hole drilling. Further, the life of the cutting edge can be extended as much as possible, and further, the effect of improving the roughness of the cutting surface and reducing the noise during processing can be obtained.

[Brief description of drawings]

FIG. 1 is a vertical sectional view of a model tool according to a first embodiment of the present invention.

FIG. 2 is a vertical sectional view of a tool according to the first embodiment.

3 is a view of the tool of FIG. 2 taken along the line III-III.

FIG. 4 is a vertical sectional view of a conventional example of a boring bar.

FIG. 5 is a vertical cross-sectional view of another conventional example of a boring bar.

[Explanation of symbols]

 4 Head 6 Cutting Blade 10 Holder Body 12 Weight 18 Supporting Means 26 Sensor 28 Controller 32 Driving Means 34 Driving Means 36 Driving Means

Claims (3)

[Claims] 1. A turning tool including a head to which a blade is attached and a holder body supported by a machine tool, wherein a hollow portion provided in the holder body and a weight accommodated in the hollow portion. A supporting means provided between the weight and the holder main body for supporting the weight at a distance from the inner surface of the holder main body, a changing means for changing the supporting position of the supporting means, and the changing means. A turning tool comprising a control means for controlling. 2. The turning tool according to claim 1, wherein the control means is controlled by a detection signal of a sensor that detects vibration of the cutting edge or the head. 3. The supporting means is a rod-shaped member that connects the holder main body and the weight, and the changing means is
The turning tool according to claim 1, wherein a plurality of holders are provided between the holder body and the weight to operate selectively.