TOOL HOLDER

Abstract

A tool holder (100) for holding a tool (200) has pressurizing chambers (123a, 123b) provided between a body member inner peripheral surface (111) of a body member (110) and a sleeve outer peripheral surface (122) of a sleeve (120). Grip parts (124a, 124b) are provided between the sleeve outer peripheral surface and a sleeve inner peripheral surface (121) and are elastically deformed radially inward when pressure in the pressurizing chambers is increased. An extended chamber (123d) is defined between the sleeve outer peripheral surface and the body member inner peripheral surface, fluidly communicates with the pressurizing chamber and extends in an axial direction and in a circumferential direction. The extended chamber curtails radially inward elastic deformation of a portion of the body member inner peripheral surface, which corresponds to one of the grip parts, when a pressing force is received on a body member outer peripheral surface (112).

Description

TECHNICAL FIELD

The present invention relates to a tool holder that holds a tool.

BACKGROUND ART

A tool holder that utilizes pressurized fluid to hold a tool is disclosed, for example, in PCT International Publication No. WO 2012-160664 (US 2014/0197607).

The tool holder disclosed in WO 2012-160664 is constituted by a body member and a sleeve that is inserted into an interior space within the body member. The tool holder further has a holding part that holds a tool (specifically, a tool shank part of the tool). The holding part has a pressurizing chamber formed between a body member inner peripheral surface and a sleeve outer peripheral surface, and a thin-walled grip part formed between the pressurizing chamber and a sleeve inner peripheral surface. When the pressure in the pressurizing chamber is increased, the grip part elastically deforms radially inward. As a result, a tool (tool shank part), which has been inserted into a sleeve interior space, is held by the portion of the sleeve inner peripheral surface that corresponds to the grip part.

SUMMARY OF THE INVENTION

A tool holder that utilizes pressurized fluid may be configured, for example, according to a known example that is shown in FIGS. 5 to 7. FIG. 5 is a sectional view of a tool holder 400 that is inserted into a cutting tool support interior space (tool holder insertion space) 300a of a cutting tool support 300. FIG. 6 is an enlarged view in which an essential part of FIG. 5 has been enlarged, and FIG. 7 is a sectional view taken along line in FIG. 5.

The tool holder 400 includes a body member 410 and a sleeve 420. A holding part of the tool holder 400 has pressurizing chambers 423a, 423b and thin-walled grip parts 424a, 424b. The pressurizing chambers 423a, 423b are formed between a sleeve outer peripheral surface 422 (sleeve outer peripheral surface portions 422b, 422d) of the sleeve 420 and a body member inner peripheral surface 411 (body member inner peripheral surface portion 411c) of the body member 410. The grip parts 424a, 424b are formed between the sleeve outer peripheral surface 422 (sleeve outer peripheral surface portions 422b, 422d) and a sleeve inner peripheral surface 421 (sleeve inner peripheral surface portion 421a) of the sleeve 420. A sleeve outer peripheral surface portion 422a, which is formed on a rear end side of the sleeve outer peripheral surface 422, and a sleeve outer peripheral surface portion 422e, which is formed on a front end side of the sleeve outer peripheral surface 422, are brazed to the body member inner peripheral surface 411 (body member inner peripheral surface portion 411c). A tool shank part of a tool 200 is inserted into a tool insertion space formed by a body member interior space 410a and a sleeve interior space 420a. When the pressure in the pressurizing chambers 423a, 423b is increased with the tool shank part inserted into the tool insertion space, the grip parts 424a, 424b are elastically deformed radially inward. As a result, the tool shank part is held by portion(s) of the sleeve inner peripheral surface 421 (sleeve inner peripheral surface portion 421a) that correspond(s) to the grip parts 424a, 424b.

The tool holder 400 is held between fastening screw front end surfaces 305a, 306a of fastening screws 305, 306 and a cutting tool support inner peripheral surface 301.

In recent years, with the use of tools having smaller diameters, a width (wall thickness) in a radial direction of a tool holder is formed smaller. As the width in the radial direction of the tool holder becomes smaller, a tool holder inner peripheral surface becomes more liable to be elastically deformed radially inward when a pressing force for holding the tool holder is applied. When the tool holder inner peripheral surface elastically deforms radially inward, it might become difficult to insert a tool into the tool insertion space, because the inner diameter of the tool insertion space formed by the tool holder inner peripheral surface has decreased.

For example, in the tool holder 400 shown in FIGS. 5 to 7, if the widths (wall thicknesses) in the radial direction of axially extending portions of the body member 410 and the sleeve 420 become smaller, the pressing force of the fastening screws 305, 306 is liable to be transmitted to the sleeve 420 via the body member 410. In this case, a body member outer peripheral surface portion 412c, the body member inner peripheral surface portion 411c, the sleeve outer peripheral surface portions 422a, 422b and the sleeve inner peripheral surface portion 421a elastically deform radially inward as shown by broken lines in FIGS. 6 and 7 (see broken lines 412c1, 411c1, 422a1, 442b1, 421a1). If the amount of the radially inward elastic deformation of the sleeve inner peripheral surface portion 421a is large, the inner diameter of the sleeve interior space 420a that defines the tool insertion space decreases. When the inner diameter of the sleeve interior space 420a decreases, it becomes difficult to insert the tool shank part of the tool 200 into the tool insertion space (sleeve interior space 420a).

It is therefore one non-limiting object of the present teachings to provide techniques that can curtail or reduce the likelihood of a decrease of the inner diameter of the tool insertion space of the tool holder when the force for holding the tool holder is applied.

In one aspect of the present teachings, a tool holder is formed into a tubular shape extending in an axial direction and is held in a state of having been inserted into a tool holder insertion space of a tool holder mounting part.

The tool holder preferably has a tool holder inner peripheral surface that defines a tool insertion space, a tool holder outer peripheral surface and a holding part. The tool holder may be formed (constituted) by (as) one member or a plurality of members. Various methods may be used to hold the tool holder in a cutting tool support that, e.g., rotates the tool holder during a processing operation.

The holding part is a portion of the tool holder that holds a tool (specifically, a tool shank part of the tool). In the present teachings, the holding part preferably has at least one pressurizing chamber and at least one grip part. The pressurizing chamber extends in the axial direction and in a circumferential direction. The grip part is formed between the pressurizing chamber and the tool holder inner peripheral surface and extends in the axial direction and in the circumferential direction. A fluid, which serves as a pressurizing medium, is filled in the pressurizing chamber. For example, oil is filled into the pressurizing chamber. The pressurizing chamber and the grip part are configured such that the grip part is elastically deformable radially inward when the pressure in the pressurizing chamber is increased. For example, the grip part is formed as a thin wall.

The tool holder further has an extended chamber that fluidly communicates with a rear end part of the pressurizing chamber formed on a rear end side of the at least one pressurizing chamber, and extends in the axial direction and in the circumferential direction. The width (wall thickness) in a radial direction of the extended chamber is set smaller than the width (wall thickness) in the radial direction of the pressurizing chamber formed on the rear end side. Further, the width in the radial direction between the extended chamber and the tool holder inner peripheral surface is set larger than the width in the radial direction between the pressurizing chamber formed on the rear end side and the tool holder inner peripheral surface. In an embodiment in which one pressurizing chamber is formed, the rear end part of the pressurizing chamber corresponds to the “rear end part of the pressurizing chamber formed on a rear end side”. Further, the extended chamber is configured such that, in a state in which the tool holder has been inserted into the tool holder insertion space of the tool holder mounting part, radially inward elastic deformation of a portion of the tool holder inner peripheral surface in the radial direction, which portion corresponds to the grip part formed on the rear end side, by a force applied to the tool holder outer peripheral surface is curtailed. For example, the extended chamber width (wall thickness) in the radial direction and the extended chamber length in the axial direction are set such that, when a normal holding force, which is required to perform an operation using the tool, has been applied to the tool holder outer peripheral surface, the inner diameter of the tool insertion space does not become smaller than the outer diameter of the tool shank part of the tool. By providing the extended chamber that fluidly communicates with the rear end part of the pressurizing chamber formed on the rear end side, transmission of the force received on the tool holder outer peripheral surface to the tool holder inner peripheral surface can be curtailed.

In the present teachings, a decrease of the inner diameter of the tool insertion space by the force that holds the tool holder received on the tool holder outer peripheral surface can be curtailed.

In another aspect of the present teachings, the tool holder has a body member and a sleeve.

The body member is formed into a tubular shape extending in the axial direction and has a body member inner peripheral surface that defines an interior space within the body member and a body member outer peripheral surface.

The sleeve is formed into a tubular shape extending in the axial direction and has a sleeve inner peripheral surface that defines an interior space within the sleeve and a sleeve outer peripheral surface. The sleeve outer peripheral surface has a first sleeve outer peripheral surface portion and a second sleeve outer peripheral surface portion that are respectively formed on a rear end side and a front end side in the axial direction and extend in the axial direction and in the circumferential direction. In addition, at least one third sleeve outer peripheral surface portion and a fourth sleeve outer peripheral surface portion are formed between the first sleeve outer peripheral surface portion and the second sleeve outer peripheral surface portion and extend in the axial direction and in the circumferential direction. The fourth sleeve outer peripheral surface portion is connected to a rear end part of the third sleeve outer peripheral surface portion formed on the rear end side of the at least one third sleeve outer peripheral surface portion, and to a front end part of the first sleeve outer peripheral surface portion, and is recessed radially inward more than the first sleeve outer peripheral surface portion and the second sleeve outer peripheral surface portion. The at least one third sleeve outer peripheral surface portion is recessed radially inward more than the fourth sleeve outer peripheral surface portion. In this aspect, the fourth sleeve outer peripheral surface portion is connected to a radially outer portion of the rear end part of the third sleeve outer peripheral surface portion formed on the rear end side.

After the sleeve has been inserted into the body member interior space, the first sleeve outer peripheral surface portion and the second sleeve outer peripheral surface portion are fixed to the body member inner peripheral surface. Various fixing methods may be used to perform this fixing. For example, a brazing method may be used.

The tool holder inner peripheral surface is formed by the body member inner peripheral surface and the sleeve inner peripheral surface. The tool holder outer peripheral surface is formed by the body member outer peripheral surface. The at least one pressurizing chamber is formed by the at least one third sleeve outer peripheral surface portion of the sleeve outer peripheral surface and the body member inner peripheral surface. The at least one grip part is formed by the at least one third sleeve outer peripheral surface portion of the sleeve outer peripheral surface and the sleeve inner peripheral surface. In addition, the extended chamber is formed by the fourth sleeve outer peripheral surface portion of the sleeve outer peripheral surface and the body member inner peripheral surface.

In this aspect, the tool holder can be easily manufactured.

In tool holders according to one or more aspects of the present teachings, it is possible to reduce the likelihood of a decrease of the inner diameter of the tool insertion space of the tool holder when force is applied to hold the tool holder.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a sectional view showing a tool holder according to an embodiment of the present teachings, in a state mounted in a cutting tool support.

FIG. 2 is a sectional view of the tool holder according to the embodiment of the present teachings.

FIG. 3 is an enlarged view in which an essential part of FIG. 1 has been enlarged.

FIG. 4 is a sectional view taken along line IV-IV in FIG. 1.

FIG. 5 is a sectional view showing a known example of a tool holder in a state mounted in a cutting tool support.

FIG. 6 is an enlarged view in which an essential part of FIG. 5 has been enlarged.

FIG. 7 is a sectional view taken along line in FIG. 5.

DETAILED DESCRIPTION

The following detailed description is merely intended to teach a person skilled in the art further details for practicing preferred aspects of the present invention and the technical scope of the present invention is not limited by the description in detailed description and determined based on the description of claims. Combinations of features and steps disclosed within the following detailed description may not be necessary to practice the invention in the broadest sense, and are instead taught merely to particularly describe some representative examples of the present invention which are given in the detailed description with reference to the accompanying drawings.

A representative embodiment of the present teachings is now described with reference to the drawings.

In this specification, the extending direction of a tool holder mounting part (cutting tool support) and the extending direction of a tool holder (body member, sleeve) mounted in the tool holder mounting part (left-right direction in FIGS. 1 to 3, i.e. the extension direction of center line P) is defined as an “axial direction”. Further, in a cross section orthogonal to the axial direction (i.e. the extension direction of the center line P), a direction along a circle around the center line P is defined as a “circumferential direction”, and a direction of a line passing through the center line P is defined as a “radial direction”. Along the axial direction, the side on which the tool holder is inserted into a tool holder insertion space of the tool holder mounting part and the side on which a tool is inserted into a tool insertion space of the tool holder (the side shown by an arrow A (right side) in FIGS. 1 to 3, 5 and 6) is defined as a “front end side”, and the side opposite to the front end side (the side shown by an arrow B (left side) in FIGS. 1 to 3, 5 and 6) is defined as a “rear end side”.

A tool holder according to an embodiment of the present teachings will now be described with reference to FIGS. 1 to 4. In this embodiment, a tool holder that is mounted in a cutting tool support is described.

FIG. 1 is a sectional view of a tool holder 100 of this embodiment, in a state mounted in a cutting tool support 300. FIG. 2 is a sectional view of the tool holder 100 of this embodiment. FIG. 3 is an enlarged view in which an essential part of the tool holder 100 in FIG. 1 has been enlarged. FIG. 4 is a sectional view taken along line IV-IV in FIG. 1.

The cutting tool support 300 in which the tool holder 100 of this embodiment is mounted is first described.

The cutting tool support 300 has a cutting tool support inner peripheral surface 301, a cutting tool support outer peripheral surface 302 and a cutting tool support front end surface 300A.

A cutting tool support interior space 300a extending in the axial direction is defined by the cutting tool support inner peripheral surface 301. The cutting tool support interior space 300a has an opening that opens to the cutting tool support front end surface 300A. The tool holder 100 is inserted into the cutting tool support interior space 300a via the opening.

The cutting tool support 300 further has holes 303, 304 extending in the radial direction between the cutting tool support inner peripheral surface 301 and the cutting tool support outer peripheral surface 302. The holes 303 and 304 respectively have openings 303a and 304a that open to the cutting tool support inner peripheral surface 301. Fastening screws 305 and 306 are respectively inserted into the holes 303 and 304 so as to be movable in the radial direction. The fastening screws 305, 306 are capable of projecting radially inward through the openings 303a, 304a more than (beyond) the cutting tool support inner peripheral surface 301.

When mounting the tool holder 100 in the cutting tool support 300, in the state that the tool holder 100 has been inserted into the cutting tool support interior space 300a, the fastening screws 305, 306 are moved (screwed) radially inward. The tool holder 100 is then pressed radially inward by fastening screw front end surfaces 305a, 306a abutting on the tool holder 100. Thus, the tool holder 100 is held between the fastening screw front end surfaces 305a, 306a on one diametric side and the cutting tool support inner peripheral surface 301 on the diametrically-opposite side.

In this embodiment, the cutting tool support 300 corresponds to a “tool holder mounting part” of the present teachings, the cutting tool support inner peripheral surface 301 corresponds to a “tool holder mounting part inner peripheral surface” of the present teachings, the cutting tool support outer peripheral surface 302 corresponds to a “tool holder mounting part outer peripheral surface” of the present teachings, and the cutting tool support front end surface 300A corresponds to a “tool holder mounting part front end surface” of the present teachings. In addition, the cutting tool support interior space 300a corresponds to a “tool holder mounting part interior space” or a “tool holder insertion space” of the present teachings.

Next, the tool holder 100 of this embodiment is described. The tool holder 100 of this embodiment is constituted by a body member 110 and a sleeve 120. The body member 110 and the sleeve 120 are formed of an elastically deformable metal, for example, steel.

The body member 110 is formed in a tubular shape extending in the axial direction.

The body member 110 has a body member inner peripheral surface 111, a body member outer peripheral surface 112, a body member front end surface 110A and a body member rear end surface 110B. A body member interior space 110a extending in the axial direction is defined by the body member inner peripheral surface 111.

The body member inner peripheral surface 111 has body member inner peripheral surface portions 111a to 111c.

The body member inner peripheral surface portions 111a and 111c extend in the axial direction and have a circular shape. The inner diameter of the body member inner peripheral surface portion 111c is larger than the inner diameter of the body member inner peripheral surface portion 111a. The body member inner peripheral surface portion 111b extends in the radial direction. The body member inner peripheral surface portion 111b is a stepped surface connecting the body member inner peripheral surface portions 111a and 111c.

The body member outer peripheral surface 112 has body member outer peripheral surface portions 112a to 112d.

The body member outer peripheral surface portion 112a extends in the axial direction and has a circular shape. The body member outer peripheral surface portion 112c is a notched surface formed by notching the body member outer peripheral surface portion 112a and extends in the axial direction (see FIG. 4). The body member outer peripheral surface portion 112c is a flat surface configured such that the fastening screw front end surfaces 305a, 306a of the fastening screws 305, 306 can abut thereon. The tool holder 100 is mounted in the cutting tool support 300 by pressing the body member outer peripheral surface portion 112c radially inward using the fastening screw front end surfaces 305a, 306a.

The body member outer peripheral surface portion 112b extends in the radial direction. The body member outer peripheral surface portion 112d is a notched surface formed by notching the body member outer peripheral surface portion 112b. A flange 113 extending in the radial direction is formed by the body member outer peripheral surface portions 112b and 112d and the body member front end surface 110A. The insertion position of the tool holder 100 in the cutting tool support interior space 300a is governed by the flange 113.

The flange 113 of the body member 110 has holes 114, 116. Each of the holes 114, 116 has openings that open to the body member inner peripheral surface 111 (body member inner peripheral surface portion 111c) and extend in the radial direction.

A screw (pressurizing screw) 115 for adjusting the pressure in pressurizing chambers 123a, 123b (described below) is disposed within the hole 114. A screw 117 is disposed within the hole 116 via a steel ball 118. The hole 116 is used to charge pressurizing medium into the pressurizing chambers 123a, 123b or to discharge pressurizing medium from the pressurizing chambers 123a, 123b.

The sleeve 120 is formed in a tubular shape extending in the axial direction.

The sleeve 120 has a sleeve inner peripheral surface 121, a sleeve outer peripheral surface 122, a sleeve front end surface 120A and a sleeve rear end surface 120B. A sleeve interior space 120a extending in the axial direction is defined by the sleeve inner peripheral surface 121.

The sleeve inner peripheral surface 121 has sleeve inner peripheral surface portions 121a to 121c. The sleeve inner peripheral surface portions 121a and 121c extend in the axial direction and have a circular shape. The inner diameter D2 of the sleeve inner peripheral surface portion 121c is smaller than the inner diameter D1 of the sleeve inner peripheral surface portion 121a (see FIG. 3). The sleeve inner peripheral surface portion 121b is a stepped surface connecting the sleeve inner peripheral surface portions 121a and 121c. The sleeve inner peripheral surface portion 121b is formed at a boundary portion (rear end portion of grip part 124a) between sleeve outer peripheral surface portions 122b and 122c (described below). A groove 125, through which a cooling medium for cooling a tool 200 passes, is spirally (helically) formed in the sleeve inner peripheral surface portion 121c. The shape of the groove 125 is not limited to a spiral (helical) shape.

The sleeve outer peripheral surface 122 has sleeve outer peripheral surface portions 122a to 122f, the cross sections of which are formed as circular shapes.

The sleeve outer peripheral surface portion 122a is formed on a rear end side (on (toward) the side shown (indicated) by arrow B in FIG. 2) of the sleeve outer peripheral surface 122, and the sleeve outer peripheral surface portion 122f is formed on a front end side (on (toward) the side shown (indicated) by arrow A in FIG. 2) of the sleeve outer peripheral surface 122. The sleeve outer peripheral surface portions 122a and 122f have the same outer diameter and extend in the axial direction and the circumferential direction.

The sleeve outer peripheral surface portions 122c and 122e are formed between the sleeve outer peripheral surface portions 122a and 122f and extend in the axial direction and the circumferential direction. The sleeve outer peripheral surface portion 122e is formed on the rear end side relative to the sleeve outer peripheral surface portion 122f, and the sleeve outer peripheral surface portion 122c is formed on the rear end side relative to the sleeve outer peripheral surface portion 122e. The outer diameter [D2+2×M2] (see FIG. 3) of the sleeve outer peripheral surface portions 122c and 122e is set smaller than the outer diameter [D1+2×M1+2×N1] (see FIG. 3) of the sleeve outer peripheral surface portions 122a and 122f Thus, the sleeve outer peripheral surface portions 122c and 122e are formed as recessed surfaces that are recessed radially inward more than the sleeve outer peripheral surface portions 122a and 122f It is noted that stepped surfaces are formed on both ends in the axial direction (front end side and rear end side) of the sleeve outer peripheral surface portions 122c and 122e.

The sleeve outer peripheral surface portion 122d is formed between the sleeve outer peripheral surface portions 122c and 122e and extends in the axial direction and in the circumferential direction. The outer diameter of the sleeve outer peripheral surface portion 122d is set such that the pressurizing medium can pass through a communication passage 123c (described below) that fluidly connects the pressurizing chambers 123a and 123b. In this embodiment, the outer diameter of the sleeve outer peripheral surface portion 122d is smaller than the outer diameter of the sleeve outer peripheral surface portions 122a and 122f and is larger than the outer diameter of the sleeve outer peripheral surface portions 122c and 122e.

The sleeve outer peripheral surface portion 122b is formed between the sleeve outer peripheral surface portions 122c and 122a and extends in the axial direction and the circumferential direction. The outer diameter of the sleeve outer peripheral surface portion 122b is set smaller than the outer diameter [D1+2×M1+2×N1] of the sleeve outer peripheral surface portion 122a and larger than the outer diameter [D2+2×M2] of the sleeve outer peripheral surface portion 122c. Thus, the sleeve outer peripheral surface portion 122b is formed radially outward relative to the sleeve outer peripheral surface portion 122c on the rear end side relative to the sleeve outer peripheral surface portion 122c.

Thin-walled grip parts 124a and 124b, which are elastically deformable in the radial direction, are respectively formed between the sleeve outer peripheral surface portions 122c, 122e and the sleeve inner peripheral surface 121 (sleeve inner peripheral surface portion 121c). In FIG. 3, M2 shows (indicates) the width (wall thickness) of the grip parts 124a and 124b in the radial direction.

In this embodiment, the sleeve outer peripheral surface portion 122a corresponds to a “first outer peripheral surface portion” or a “first sleeve outer peripheral surface portion” of the present teachings, and the sleeve outer peripheral surface portion 122f corresponds to a “second outer peripheral surface portion” or a “second sleeve outer peripheral surface portion” of the present teachings. The sleeve outer peripheral surface portions 122c, 122e correspond to an “at least one third outer peripheral surface portion” or an “at least one third sleeve outer peripheral surface portion” of the present teachings. The sleeve outer peripheral surface portion 122c corresponds to a “third outer peripheral surface portion formed on the rear end side” or a “third sleeve outer peripheral surface portion formed on the rear end side” of the present teachings, and the sleeve outer peripheral surface portion 122b corresponds to a “fourth outer peripheral surface portion” or a “fourth sleeve outer peripheral surface portion” of the present teachings.

The sleeve 120 is inserted into the body member interior space 110a until the sleeve rear end surface 120B abuts on the body member inner peripheral surface portion 111b. The holes 114 and 116 are configured to fluidly communicate with one of the pressurizing chambers (in this embodiment, the pressurizing chamber 123b) when the sleeve rear end surface 120B abuts on the body member inner peripheral surface portion 111b.

The sleeve 120 is then fixed to the body member 110. In this embodiment, the sleeve rear end surface 120B is brazed to the body member inner peripheral surface portion 111b, and the sleeve outer peripheral surface portions 122a and 122f are brazed to the body member inner peripheral surface portion 111c.

Thus, an enclosed region into which the pressurizing medium is charged is formed between the sleeve outer peripheral surface 122 and the body member inner peripheral surface 111. Specifically, the pressurizing chambers 123a and 123b are respectively formed between the sleeve outer peripheral surface portions 122c and 122e and the body member inner peripheral surface portion 111c. The pressurizing chamber 123a is formed on the rear end side relative to the pressurizing chamber 123b.

In FIG. 3, N2 shows (indicates) the width of the pressurizing chambers 123a and 123b in the radial direction. M2 shows (indicates) the width (wall thickness) of the grip parts 124a and 124b in the radial direction.

Further, the communication passage 123c that fluidly communicates with the pressurizing chambers 123a and 123b is formed between the sleeve outer peripheral surface portion 122d and the body member inner peripheral surface portion 111c.

In addition, an extended chamber 123d is formed between the sleeve outer peripheral surface portion 122b and the body member inner peripheral surface portion 111c and extends in the axial direction and in the circumferential direction on the rear end side relative to the pressurizing chamber 123a. The extended chamber 123d fluidly communicates with the pressurizing chamber 123a at a radially outer portion of a rear end part of the pressurizing chamber 123a.

The shape (width in the radial direction and length in the axial direction) of the extended chamber 123d is set such that the inner diameter of the tool insertion space (sleeve interior space 120a) does not become smaller than the outer diameter of a tool shank part of the tool 200 when a normal holding force (radially inward pressing force), which is required to perform an operation using the tool 200, is applied to a tool holder outer peripheral surface (body member outer peripheral surface portion 112c). Particularly, the inner diameter of the sleeve inner peripheral surface portion 121a is set so that it does not become difficult to insert the tool shank part into the sleeve interior space 120a.

In FIG. 3, N1 shows (indicates) the width of the extended chamber 123d in the radial direction. In addition, M1 shows (indicates) the width (wall thickness) in the radial direction between the sleeve outer peripheral surface portion 122b and the sleeve inner peripheral surface portion 121a.

In this embodiment, a “tool holder” of the present teachings is constituted by the body member 110 and the sleeve 120. A “tool holder inner peripheral surface” of the present teachings is formed by the body member inner peripheral surface 111 (body member inner peripheral surface portion 111a) and the sleeve inner peripheral surface 121 (sleeve inner peripheral surface portions 121a to 121c). A “tool holder outer peripheral surface” of the present teachings is formed by the body member outer peripheral surface 112. A “tool holder interior space” or a “tool insertion space” of the present teachings is formed by the body member interior space 110a and the sleeve interior space 120a.

The pressurizing medium is filled into the pressurizing chambers 123a, 123b, the communication passage 123c and the extended chamber 123d. In this embodiment, oil is filled.

More specifically, while holding the tool 200 (tool shank part) that has been inserted into the sleeve interior space 120a (tool insertion space), the pressure in the pressurizing chambers 123a, 123b is increased by manipulating the pressurizing screw 115. As a result, the grip parts 124a, 124b elastically deform radially inward, so that the tool 200 (tool shank part) is held by a portion or portions of the sleeve inner peripheral surface 121 (sleeve inner peripheral surface portion 121c) that correspond(s) to the grip parts 124a, 124b.

When inserting the tool 200 into the sleeve interior space 120a (tool insertion space) or withdrawing the tool 200 from the sleeve interior space 120a (tool insertion space), the pressure in the pressurizing chambers 123a, 123b is reduced by manipulating the pressurizing screw 115. As a result, the shape of the grip parts 124a, 124b returns to the normal state.

In the tool holder 400 shown in FIGS. 5 to 7, if the width (wall thickness) in the radial direction (width of the body member 410 and the sleeve 420 in the radial direction) is set large, insertion of a tool (tool shank part) into the tool insertion space (sleeve interior space 420a) is not liable to become difficult. In other words, even if a tool holder outer peripheral surface (body member outer peripheral surface portion 412c) is pressed radially inward by the fastening screw front end surfaces 305a, 306a of the fastening screws 305, 306, the pressing force is less liable to be transmitted to a tool holder inner peripheral surface (sleeve inner peripheral surface portion 421a). Thus, the tool holder inner peripheral surface (sleeve inner peripheral surface portion 421a) is not liable to elastically deform radially inward, and insertion of the tool shank part into the sleeve interior space 420a is not liable to become difficult due to a decrease of the inner diameter of the sleeve interior space 420a.

On the other hand, in the tool holder 400 shown in FIGS. 5 to 7, if the width (wall thickness) in the radial direction (width of the body member 410 and the sleeve 420 in the radial direction) is set small, insertion of the tool (tool shank part) into the tool insertion space (sleeve interior space 420a) is liable to become difficult. In other words, the pressing force received on the tool holder outer peripheral surface (body member outer peripheral surface portion 412c) is liable to be transmitted to the tool holder inner peripheral surface (sleeve inner peripheral surface portion 421a). In this case, the body member outer peripheral surface portion 412c, the body member inner peripheral surface portion 411c, the sleeve outer peripheral surface portions 422a, 422b and the sleeve inner peripheral surface portion 421a will elastically deform radially inward, as shown in broken lines in FIGS. 6 and 7, by the force applied to the body member outer peripheral surface portion 412c. Accordingly, the inner diameter of the sleeve interior space 420a that forms the tool insertion space is liable to decrease and insertion of the tool shank part into the sleeve interior space 420a is liable to become difficult.

In contrast, in the tool holder 100 of this embodiment, in case the width (wall thickness) in the radial direction (width of the body member 110 and the sleeve 120 in the radial direction) is set small, the body member outer peripheral surface 112 (body member outer peripheral surface portion 112c) and the body member inner peripheral surface 111 (body member inner peripheral surface portion 111c) are liable to elastically deform radially inward when the body member outer peripheral surface 112 (body member outer peripheral surface portion 112c) is pressed radially inward by the fastening screw front end surfaces 305a, 306a of the fastening screws 305, 306. For example, the body member outer peripheral surface portion 112c and the body member inner peripheral surface portion 111c are liable to elastically deform from the state shown in solid lines in FIGS. 3 and 4 to the state shown in broken lines (see 112c1, 111c1).

However, in the tool holder 100 of this embodiment, the extended chamber 123d is formed to fluidly communicate with the pressurizing chamber 123a formed on the rear end side at the radially outer portion of the rear end part of the pressurizing chamber 123a (at position H1 in FIG. 3) and to extend rearward from the pressurizing chamber 123a in the axial direction and in the circumferential direction. Thus, the grip part 124a is separated from the sleeve outer peripheral surface portion 122a, which is fixed to the body member inner peripheral surface portion 111c, by the length of the extended chamber 123d (sleeve outer peripheral surface portion 122b) in the axial direction. The length of the extended chamber 123d (sleeve outer peripheral surface portion 122b) in the axial direction corresponds to the distance between the position H1 of the rear end part of the outer peripheral surface portion 122c and the position H2 of the front end part of the sleeve outer peripheral surface portion 122a in the axial direction.

The width M1 between the sleeve outer peripheral surface portion 122b and the sleeve inner peripheral surface portion 121a in the radial direction is set larger than the width M2 (of the grip parts 124a and 124b) between the sleeve outer peripheral surface portions 122c, 122e and the sleeve inner peripheral surface portion 121c in the radial direction (M1>M2) (see FIG. 3).

Due to the existence of the extended chamber 123d that fluidly communicates with a rear end part of the pressurizing chamber 123a formed on the rear end side and the existence of a portion having a width larger than that of the grip part 124a formed on the rear end side, transmission of force, which is applied to the body member outer peripheral surface 112 (body member outer peripheral surface portion 112c), to the sleeve inner peripheral surface portion 121a is curtailed. Specifically, although the sleeve outer peripheral surface portions 122a, 122b is liable to be elastically deform from the state shown in solid lines in FIGS. 3 and 4 to the state shown in broken lines (122a1, 122b1), radially inward elastic deformation of the sleeve inner peripheral surface portion 121c (particularly, a portion corresponding to the rear end part of the grip part 124a) is curtailed.

In this embodiment, the stepped sleeve inner peripheral surface portion 121b is formed at a portion corresponding to the boundary portion (rear end portion of the grip part 124a) between the sleeve outer peripheral surface portions 122b and 122c. Thus, the sleeve inner peripheral surface portion 121a is formed on the rear end side relative to the sleeve inner peripheral surface portion 121c formed at a portion corresponding to the grip part 124a and has an inner diameter D1 larger than the inner diameter D2 of the sleeve inner peripheral surface portion 121c.

With this configuration, even if the sleeve inner peripheral surface portion 121a has elastically deformed radially inward along with the radially inward elastic deformation of the sleeve outer peripheral surface portion 122b, a decrease of the inner diameter of the sleeve interior space 120a can be curtailed.

Thus, in the tool holder 100 of this embodiment, a decrease of the inner diameter of the sleeve interior space 120a (tool insertion space) due to the force that holds the tool holder 100 (force received on the tool holder outer peripheral surface) can be curtailed, and difficulties with the insertion of the tool 200 (tool shank part) into the sleeve interior space 120a (tool insertion space) can be prevented.

The present teachings are not limited to the above-described embodiment, but rather, may be added to, changed, replaced with alternatives or otherwise modified.

The structures of the body member and the sleeve are not limited to those described in the embodiment.

In this embodiment, although the tool holder is formed by two members (body member and sleeve), it may be formed by one member or three or more members.

In this embodiment, although the holding part is formed by two pressurizing chambers and two grip parts, it may just be formed by at least one pressurizing chamber and at least one grip part. In case the holding part is formed by one pressurizing chamber and one grip part, the one pressurizing chamber and the one grip part correspond respectively to the “pressurizing chamber formed on the rear end side of the at least one pressurizing chamber” and the “grip part formed on the rear end side of the at least one grip part” of the present teachings.

In this embodiment, although the sleeve inner peripheral surface portion 121a having a larger inner diameter is formed on the rear end side, the sleeve inner peripheral surface portion 121a may be omitted.

The tool holder mounting part that mounts the tool holder is not limited to the cutting tool support.

The method of holding the tool holder is not limited to pressing the tool holder radially inward with a fastening screw or fastening screws.

The method of adjusting the pressure in the pressurizing chamber is not limited to adjustment using a pressurizing screw.

In this embodiment, although the extended chamber is formed to fluidly communicate with the rear end part of the pressurizing chamber formed on the rear end side and extend rearward because the front end part of the tool holder is not liable to elastically deform, in case the front end part of the tool holder is liable to elastically deform, an extended chamber may be formed to fluidly communicate with a front end part of the pressurizing chamber formed on the front end side and extend frontward. In this case, an extended chamber can be formed on the front end side in the same manner as the extended chamber formed on the rear end side.

DESCRIPTION OF THE NUMERALS

• • 100, 400 tool holder
  • 110, 410 body member
  • 110A, 410A body member front end surface
  • 110 a, 410a body member interior space
  • 111, 411 body member inner peripheral surface
  • 111 a to 111c, 411a to 411c body member inner peripheral surface portion
  • 112 a to 112d, 412a to 412d body member outer peripheral surface portion
  • 113 flange
  • 114 insertion hole
  • 115, 415 screw (pressurizing screw)
  • 116 insertion hole
  • 117, 417 screw (sealing screw)
  • 118 steel ball
  • 120, 420 sleeve
  • 120A, 420A sleeve front end surface
  • 120B, 420B sleeve rear end surface
  • 120 a, 420a sleeve interior space
  • 121, 421 sleeve inner peripheral surface
  • 121 a to 121c, 421a sleeve inner peripheral surface portion
  • 122, 422 sleeve outer peripheral surface
  • 122 a to 122f, 422a to 422e sleeve outer peripheral surface portion
  • 123 a, 123b, 423a, 423b pressurizing chamber
  • 123 c, 423c communication passage
  • 123 d extended chamber
  • 124 a, 124b, 424a, 424b grip part
  • 125 groove
  • 200 tool
  • 300 cutting tool support (tool holder mounting part)
  • 300A cutting tool support front end surface (tool holder mounting part front end surface)
  • 300 a cutting tool support interior space (tool holder mounting part interior space)
  • 301 cutting tool support inner peripheral surface (tool holder mounting part inner peripheral surface)
  • 302 cutting tool support outer peripheral surface (tool holder mounting part outer peripheral surface)
  • 303, 304 hole
  • 303 a, 304a opening
  • 305, 306 fastening screw (fastening member)
  • 305 a, 306a fastening screw front end surface (fastening member front end surface)

Claims

1. A tool holder having a tubular shape extending in an axial direction and configured to be held in a tool holder insertion space of a tool holder mounting part, the tool holder comprising a body member and a sleeve that define a tool holder inner peripheral surface, a tool holder outer peripheral surface, a tool insertion space defined by the tool holder inner peripheral surface, and a holding part configured to hold a tool that has been inserted into the tool insertion space, wherein the holding part:has at least one pressurizing chamber extending in the axial direction and in a circumferential direction and at least one grip part provided between the at least one pressurizing chamber and the tool holder inner peripheral surface and extending in the axial direction and in the circumferential direction,is configured such that the at least one grip part is elastically deformable radially inward by increasing the pressure in the at least one pressurizing chamber, andhas an extended chamber which fluidly communicates with a rear end part of the pressurizing chamber formed on a rear end side of the at least one pressurizing chamber, and extends in the axial direction and in the circumferential direction, andwherein:the body member has a tubular shape extending in the axial direction and includes a body member inner peripheral surface, a body member outer peripheral surface and a body member interior space defined by the body member inner peripheral surface, the body member outer peripheral surface having a body member outer peripheral surface portion extending in the axial direction and a notched surface extending from the body member rear end surface in the axial direction,the sleeve has a tubular shape extending in the axial direction and includes a sleeve inner peripheral surface, a sleeve outer peripheral surface and a sleeve interior space defined by the sleeve inner peripheral surface,the sleeve outer peripheral surface has a first sleeve outer peripheral surface portion and a second sleeve outer peripheral surface portion that are respectively defined on a rear end side and a front end side of the sleeve and extend in the axial direction and in the circumferential direction, and at least one third sleeve outer peripheral surface portion and a fourth sleeve outer peripheral surface portion defined between the first sleeve outer peripheral surface portion and the second sleeve outer peripheral surface portion and extend in the axial direction and in the circumferential direction,the fourth sleeve outer peripheral surface portion is connected to a rear end part of the third sleeve outer peripheral surface portion defined on the rear end side of the at least one third sleeve outer peripheral surface portion, and to a front end part of the first sleeve outer peripheral surface portion, and is recessed radially inward more than the first sleeve outer peripheral surface portion and the second sleeve outer peripheral surface portion,the at least one third sleeve outer peripheral surface portion is recessed radially inward more than the fourth sleeve outer peripheral surface portion,the sleeve inner peripheral surface includes a first sleeve inner peripheral surface portion having a first inner diameter (D2), a second sleeve inner peripheral surface portion having a second inner diameter (D1) that is larger than the first inner diameter (D2), and a stepped sleeve inner peripheral surface portion connecting a rear side of the first sleeve inner peripheral surface portion to a front side of the second sleeve inner peripheral surface portion,the first sleeve outer peripheral surface portion and the second sleeve outer peripheral surface portion are affixed to the body member inner peripheral surface with the sleeve inserted into the body member interior space,the tool holder inner peripheral surface that defines the tool insertion space is formed by the body member inner peripheral surface and the sleeve inner peripheral surface,the tool holder outer peripheral surface is defined by the body member outer peripheral surface,the at least one pressurizing chamber is defined by the at least one third sleeve outer peripheral surface portion of the sleeve outer peripheral surface and the body member inner peripheral surface,the at least one grip part is defined by the at least one third sleeve outer peripheral surface portion of the sleeve outer peripheral surface and the sleeve inner peripheral surface,the extended chamber is defined by the fourth sleeve outer peripheral surface portion of the sleeve outer peripheral surface and the body member inner peripheral surface, andthe extended chamber is configured such that a width in a radial direction of the extended chamber is smaller than a width in the radial direction of the pressurizing chamber formed on the rear end side, and a width in the radial direction between the extended chamber and the tool holder inner peripheral surface is larger than a width in the radial direction between the pressurizing chamber formed on the rear end side and the tool holder inner peripheral surface, and is configured such that, when inserted into the tool holder insertion space of the tool holder mounting part, radially inward elastic deformation of a portion of the tool holder inner peripheral surface, which corresponds to the grip part formed on the rear end side, caused by a force received on the notched surface of the tool holder outer peripheral surface is curtailed.

2. (canceled)