KR20220082280A - Lathe chuck - Google Patents

Abstract

The present invention relates to a lathe chuck, which is rotatably coupled to a main shaft and has an insertion hole 111 for inserting a material in the center of the front surface of the chuck body 110 and the front surface of the chuck body 110 radially. A plurality of jaw guide grooves 113 formed in a vertical direction toward the center of rotation and a plurality of jaw guide grooves 113 formed on the front surface of the chuck body 110 are slidably assembled and moved in the direction of the insertion hole 111 . The jaw 130 for fastening and fixing the material located in the insertion hole 111, and a reinforcing flange 150 that is coupled to the side of the jaw 130 and fills the space between the jaw 130 and the jaw 130. include The present invention has the advantage of preventing the problem that plastic chips generated during lathe processing of plastics are wound around the jaws like a long skein of thread because the jaws are coupled with the reinforcing flanges so that there is no protruding part of the jaws.

Description

Lathe chuck {LATHE CHUCK}

The present invention relates to a lathe chuck, and more particularly, to a lathe chuck for fixing a material during lathe processing.

Lathe machining is a cutting process in which a material is fixed to a lathe chuck and the lathe chuck rotates, and a rotating tool cuts the material fixed to the lathe chuck. Lathe processing is mainly used to make cylindrical products, and typically there are shafts, screws, and nuts used for power transmission.

1 is a perspective view showing a conventional lathe chuck.

As shown in FIG. 1 , in the lathe chuck 10 , a jaw 13 installed on the chuck body 11 fixes the material. The jaws 13 are divided into 2 jaws, 3 jaws, etc. according to the number of jaws 13, and the material is fixed through a clamping action that moves differently or moves the same. The jaw 13 shown in Fig. 1 is a three jaw performing a clamping action in which the three jaws move at the same time.

The materials for lathe processing are metal and plastic, and engineering plastics are widely used for plastics. Engineering plastics are strong against heat and impact, and have excellent heat resistance, abrasion resistance, and elasticity, so they can be widely used as industrial and structural materials.

In particular, in recent years, as weight reduction has become an important issue in vehicles for reasons of fuel efficiency, etc., the use of engineering plastics using the light and strong characteristics of plastics by replacing metals is increasing.

However, when plastic is processed on a lathe, an air flow is generated in the direction of the arrow shown in FIG. 1 , so that the plastic chip is dried like a long skein on the protruding jaw. In high-speed operation, metal chips are broken and fall down, but plastic chips are strongly wound around the jaws 13 due to the characteristics of the material. When the plastic chip is wound around the jaws 13 , the jaws are distorted and the center may be misaligned. In addition, since the general plastic chip is weak to heat, a problem of melting and sticking to the jaws 13 may occur.

As a prior art, Laid-Open Patent Publication No. 2013-0038011 discloses a chip penetration prevention device for preventing chips generated when processing a material through an automatic lathe from penetrating into the chuck.

However, in the prior art, since the chip penetration prevention device blocks the hole formed in the center of the chuck, there is a problem in that it is impossible to process a long rod by blocking the hole into which the material is inserted.

In addition, in the prior art, even if the chip penetration prevention device is installed, the protruding portion of the jaws still remains, so that there may be a problem in that the plastic chips are wound around the protruding portions of the jaws during lathe processing of plastics.

Publication No. 2013-0038011 (published on April 17, 2013)

An object of the present invention is to prevent the problem of plastic chips being wound around the jaws like long skeins when lathe processing of plastics, and it is possible to process a long rod by not blocking the hole into which the material is inserted, and the force to fix the material by the jaw It is to provide a lathe chuck that is stably maintained.

According to a feature of the present invention for achieving the above object, the present invention is a chuck body that is rotatably coupled to a headstock and has an insertion hole for inserting a material in the center of the front, and a front surface of the chuck body. It is slidably assembled into a plurality of jaw guide grooves formed radially and having a vertical direction toward the center of rotation and the jaw guide grooves formed on the front surface of the chuck body, and moves in the direction of the insertion hole to fasten and fix the material located in the insertion hole. and a reinforcing flange coupled to a side of the jaw and filling a space between the jaw and the jaw.

The front face of the reinforcing flange is flush with the front face of the jaw.

The reinforcing flange has a sectoral shape, and the outer periphery of the reinforcing flange forms the same height as the outer periphery of the jaw.

The reinforcing flange is coupled to the side surface of the jaw and assembled to the jaw guide groove in an integrated state.

The jaw is formed of a metal material, and the reinforcing flange is formed of an engineering plastic material.

and fastening means for coupling the reinforcing flange to the side surfaces of the jaws, wherein the fastening means includes first and second fixing holes formed at intervals on the side surfaces of the jaws, and penetrating through the reinforcing flange, the reinforcing flange A first fastening hole and a second fastening hole communicating with the first and second fastening holes, respectively, and the first fastening hole through the first fastening hole and the second fastening through the second fastening hole Includes a fastening bolt fastened to the hole.

The first fastening hole and the second fastening hole include a stepped surface dividing the space into two spaces having different inner diameters, and the head of the fastening bolt is located on the step surface so that the fastening bolt is not exposed to the outside of the reinforcing flange. does not

The reinforcing flange coupled to the side of the jaw moves integrally with the jaw and does not block the insertion hole of the chuck body.

The reinforcing flanges are respectively coupled to one side and the other side of the jaw and fill a space between the jaw and the jaw.

The reinforcing flange coupled to one side of the jaw and the reinforcing flange coupled to the other side of the jaw are symmetrical.

In the present invention, since reinforcing flanges are coupled to both sides of the jaw to fill the space between the jaws installed radially on the chuck body, the protruding portion of the jaws is eliminated, so that the plastic chips generated during lathe processing of plastics are like long skeins on the jaws. A cold can help prevent problems.

In addition, in the present invention, since the reinforcing flange is integrally coupled to both sides of the jaw and moves together with the jaw, the insertion hole formed in the chuck body is not blocked, so that when machining a long rod, the rod can be inserted into the insertion hole of the chuck body and processed have. Therefore, the present invention has the effect of securing the processing precision of the material by accurately and fixing the material by maintaining the force of the jaws to fix the material stably.

1 is a perspective view showing a conventional lathe chuck.
2 is a perspective view showing a lathe chuck according to an embodiment of the present invention.
3 is a perspective view showing a state in which a rod-shaped material is fixed to a lathe chuck according to an embodiment of the present invention.
4 is a perspective view showing the fastening means of the lathe chuck according to an embodiment of the present invention from the front.
5 is a front view showing a state in which reinforcing flanges are coupled to both sides of the jaw according to an embodiment of the present invention.
6 is a front view showing the operation of the jaw according to the embodiment of the present invention.
7 is a front view showing a state in which reinforcing flanges are coupled to both sides of the jaw according to another embodiment of the present invention.
8 is a front view showing a state in which reinforcing flanges are coupled to both sides of the jaws assembled to the chuck body according to another embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a perspective view showing a lathe chuck according to an embodiment of the present invention, and FIG. 3 is a perspective view showing a state in which a rod-shaped material is fixed to the lathe chuck according to an embodiment of the present invention.

2 and 3 , the lathe chuck 100 includes a chuck body 110 , a jaw 130 , and a reinforcing flange 150 . The chuck body 110 is formed in a cylindrical shape, the main shaft diameter formed at the rear is rotatably coupled to the headstock 1, and an insertion hole 111 into which the material m can be inserted is formed in the center of the front surface.

The material (m) is a material for machining a workpiece or lathe. Lathe machining refers to cutting performed on a lathe, and includes, for example, cylindrical cutting, hole drilling, cutting, face cutting, screw cutting, and the like. The insertion hole 111 in the chuck body 110 is for stably fixing the rod-shaped material m by inserting it.

The headstock 1 transmits the power of the electric motor to the chuck body 110 so that the chuck body 110 can rotate. The headstock 1 has a built-in headstock, and the lathe chuck 100 is fixed to the headstock to fix the material m. The headstock 1 includes a converter for adjusting the rotation speed and the feed speed of the headstock.

A jaw guide groove 113 is formed on the front surface of the chuck body 110 . The jaw guide groove 113 is radially formed on the front surface of the chuck body 110 and has a vertical direction toward the center of rotation. In the embodiment, since the jaw 130 has three jaws, three jaw guide grooves 113 are formed.

The jaw 130 is a part for fixing the material m to the chuck body 110 . The jaw 130 may be formed in the shape of a square bar, and the tip may be formed to be rounded. The jaw 130 may be prepared in various sizes and shapes according to the type of material to be processed, and may be assembled to the chuck body 110 by selecting a size and shape corresponding to the material.

The jaws 130 are slidably assembled in the jaw guide grooves 113 formed on the front surface of the chuck body 110 . The jaws 130 assembled to the chuck body 110 move in the direction of the insertion hole 111 by the operation of a cylinder provided in the chuck body 110 to fasten and fix the material located in the insertion hole 111 . The cylinder can be operated by hydraulic or pneumatic pressure, and by adjusting the tightening pressure of the jaw 130 according to the shape or material of the material, it is possible to prevent the material from being deformed and separated. In addition, the lathe chuck 100 precisely centers the material m by interlocking a plurality of radially installed jaws 130 .

The reinforcing flange 150 is coupled to the side of the jaw 130 to fill the space between the jaw 130 and the adjacent jaw 130 . In the embodiment, the reinforcing flange 150 is coupled to both sides of the jaw 130 in a wing shape. When the reinforcing flange 150 is coupled to only one side of the jaw 130 , the reinforcing flange 150 may fill the space between the jaw 130 and the jaw 130 , but when the chuck body 110 rotates, the reinforcing flange The force pulling the jaws 130 is applied only in one direction to which 150 is coupled, so that the centering of the jaws 130 may be distorted.

Therefore, the reinforcing flange 150 is coupled to both sides of the jaw 130 so that the force applied to the jaw 130 during rotation is uniformly generated from both sides. When the force (eg, centrifugal force) pulling the jaws 130 is uniformly generated from both sides when the chuck body 110 rotates, the centering of the jaws 130 is not distorted.

In a state in which the reinforcing flange 150 is coupled to the jaw 130 , the front surface of the reinforcing flange 150 forms the same plane as the front surface of the jaw 130 . In addition, the reinforcing flange 150 is formed in a sectoral shape, and the outer periphery of the sectoral shape forms the same height as the outer periphery of the jaw 130 . In addition, the reinforcing flange 150 is coupled to the side surface of the jaw 130 and slidably assembled in the jaw guide groove 113 in an integrated state.

When the front surface of the reinforcing flange 150 forms the same plane as the front surface of the jaw 130 and the outer periphery of the reinforcing flange 150 forms the same height as the outer periphery of the jaw 130, the protruding portion of the jaw 130 is As it disappears, the air flow as shown in FIG. 1 is prevented, and the problem that the plastic chip is wound around the jaws 130 does not occur.

3 and 4 show that there is a gap between the reinforcing flanges 150 when the jaws 130 coupled with the reinforcing flange 150 are assembled to the chuck body 110, but the reinforcing flanges 150 are in close contact with each other to reinforce It is preferable that there is no play between the flanges 150 .

Since the reinforcing flange 150 is integrally coupled to both sides of the jaw 130 and moves integrally when the jaw 130 moves, there is no play between the reinforcing flanges 150 when the jaw 130 fixes the material m. Adhering is effective in preventing the plastic chips from being wound. However, when the spacing between the reinforcing flanges 150 is small compared to the thickness of the plastic chip, the reinforcing flanges 150 may be spaced apart from each other by a certain portion.

The reinforcing flange 150 does not block the insertion hole (reference numeral 111 in FIG. 6 ) formed in the chuck body 110 . This makes it possible to insert and process the rod into the insertion hole 111 of the chuck body 110 when processing the long rod-shaped material, so that the jaw 130 has a stable force for fixing the material m. is maintained and the material can be fixed accurately and strongly. If the jaw 130 does not accurately and strongly fix the material m, the processing precision of the material m is greatly affected.

The jaw 130 is formed of a metal material, and the reinforcing flange 150 is formed of an engineering plastic material. Since engineering plastic is lighter than metal and does not significantly increase the weight of the lathe chuck 100 , it does not significantly affect the high-speed rotation of the jaw 130 .

It includes fastening means for coupling the reinforcing flange 150 to both sides of the jaw 130 .

4 is a perspective view showing the fastening means of the lathe chuck according to an embodiment of the present invention from the front, and FIG. 5 is a front view showing a state in which reinforcing flanges are coupled to both sides of the jaw according to the embodiment of the present invention.

4 and 5 , the fastening means includes first fastening holes 131 and 134 and second fixing holes 133 and 135 formed on both sides of the jaw 130 and a first fastening formed in the reinforcing flange 150 . It includes a hole 151 , a second fastening hole 152 , and a fastening bolt 161 .

The first fixing holes 131 and 134 and the second fixing holes 133 and 135 are formed symmetrically on both sides of the jaw 130 at a distance from each other. The first fastening hole 151 and the second fastening hole 152 are formed to pass through the reinforcing flange 150 and communicate with the first fixing holes 131 and 134 and the second fixing holes 133 and 135 . The fastening bolt 161 is fastened to the first fastening hole 151 and the first fastening holes 131 and 134 and the second fastening hole 152 and the second fastening holes 133 and 135 to engage the reinforcing flange 150 (130). fasten on

The first fastening hole 151 and the second fastening hole 152 include step surfaces 151a and 152a divided into two spaces having different inner diameters. The fastening bolt 161 for fixing the reinforcing flange 150 to the jaw 130 is not exposed to the outside of the reinforcing flange 150 because the head is located on the stepped surfaces 151a and 152a. When the fastening bolts 161 do not protrude to the outside of the reinforcing flange 150 , adjacent reinforcing flanges 150 may be in close contact with each other.

The first fastening hole 151 is formed to pass through the radius and the radius of the reinforcing flange 150 to communicate with the first fixing holes 131 and 134 of the jaw 130 , and the second fastening hole 152 is the reinforcing flange 150 . ) is formed to penetrate the circumference and radius of the jaw 130 and communicates with the second fixing holes 132 and 135 of the jaw 130 .

As shown in FIG. 5 , the reinforcing flange 150 coupled to one side of the jaw 130 includes a first fastening hole 151 formed to penetrate the radius and radius of the reinforcing flange 150 and one side of the jaw 130 . The fastening bolt 161 is fastened to the first fixing hole 131 of ) is fixed in such a way that the fastening bolt 161 is fastened.

In addition, the reinforcing flange 150 coupled to the other side of the jaw 130 includes a first fastening hole 151 formed to pass through the radius and radius of the reinforcing flange 150 and a first fixing hole on the other side of the jaw 130 ( A fastening bolt 161 is fastened to 134 , and a fastening bolt 161 is formed in the second fastening hole 135 of the second fastening hole 135 of the jaw 130 and the second fastening hole 152 formed to pass through the circumference and the radius in the reinforcing flange 150 . ) is fixed in such a way that it is fastened.

At this time, the fastening bolts 161 fastened to the first fastening hole 151 and the first fastening holes 131 and 134 and the fastening bolts 161 fastened to the second fastening hole 152 and the second fastening holes 132 and 135 are The head is positioned on the stepped surfaces 151a and 152a of the first fastening hole 151 and the second fastening hole 152 and is not exposed to the outside.

6 is a front view showing an operation of a jaw according to an embodiment of the present invention.

As shown in FIG. 6 , the reinforcing flanges 150 coupled to both sides of the jaw 130 move integrally with the jaw 130 and do not block the insertion hole 111 of the chuck body 110 . This makes it possible to insert and process the rod into the insertion hole 111 of the chuck body 110 during processing of the long rod, so that the jaw 130 can stably tighten and fix the material.

The jaw 130 assembled to the chuck body 110 may move in the direction of the insertion hole 111 by the operation of the cylinder to fasten and fix the material located in the insertion hole 111 . In addition, the jaw 130 moves in a direction away from the center when the processing of the material is completed.

The reinforcing flange 150 is coupled to one side and the other side of the jaw 130 , respectively, and fills a space between the jaw 130 and the jaw 130 when assembled to the chuck body 110 . The reinforcing flange 150 coupled to one side of the jaw 130 and the reinforcing flange 150 coupled to the other side of the jaw 130 have a symmetrical shape.

When the jaw 130 to which the reinforcing flange 150 is coupled is assembled to the chuck body 110, the reinforcing flange 150 is disposed between the jaws 130 and has a cylindrical shape as a whole, so that the portion protruding from the jaw 130 is there will be no

The plurality of jaws 130 assembled to the chuck body 110 may move in the same manner to perform a tightening action for fixing the material. At this time, the front end of the reinforcing flange 150 may have a shape located on the rear side compared to the front end of the jaw 130 so that only the jaw 130 can perform the tightening action of the material.

In the lathe chuck 100, it is preferable that the maximum gap between the jaws 130 used for fixing the material is moved and opened is larger than the outer diameter of the material, and the jaws 130 may be selectively employed depending on the material to be processed.

In addition, a reinforcing flange 150 corresponding to the size and shape of the jaw 130 may be provided. The reinforcing flange 150 is coupled to the jaw 130, and the front surface forms the same plane as the front surface of the jaw 130, is formed in a sector shape, and the outer periphery of the sector shape is the same height as the outer periphery of the jaw 130. to form

7 is a front view showing that reinforcing flanges are coupled to both sides of the jaw according to another embodiment of the present invention, and FIG. 8 is a reinforcing flange coupled to both sides of the jaw assembled to the chuck body according to another embodiment of the present invention. This is the front view of what it looked like.

In the embodiment, the reinforcing flange 150 is formed in a sector shape. The reinforcing flange 150 of the embodiment is in a state coupled to both sides of the jaw 130 , the tip of which is positioned at the rear compared to the tip of the jaw 130 .

However, the reinforcing flange 150 ′ of another embodiment is coupled to both sides of the jaw 130 to form a sector-shaped body. The reinforcing flange 150 ′ forms a curved surface in which the distal end 150a ′ is connected to the distal end 130a of the jaw 130 , thereby performing a tightening action of fixing the material together with the jaw 130 .

The embodiment has the advantage of easy manufacture because the shape of the reinforcing flange 150 is a sectoral shape in which both sides are symmetrical. And, in another embodiment, since the shape in which the reinforcing flange 150 is coupled to the jaw 130 is a sectoral shape, the manufacture of the reinforcing flange 150 is cumbersome compared to the embodiment, but the jaw 130 and the reinforcing flange 150 are the material. As the clamping action of the material is performed together, the material can be fixed more stably.

In addition, in another embodiment, since the jaw 130 and the reinforcing flange 150 ′ have a structure in which the material is fixed without play, plastic chips are introduced into the insertion hole 111 of the chuck body 110 during lathe processing of plastic. can be prevented

In another embodiment, only the shape of the tip 150a' of the reinforcing flange 150 is different from the embodiment, and the rest of the configuration is the same.

Since the above-described lathe chuck 100 combines the reinforcing flanges with the jaws so that there is no protruding portion of the jaws, it is possible to prevent the problem of plastic chips being wound around the jaws like a long skein of thread during lathe processing of plastics.

In addition, since the lathe chuck 100 has a structure in which the reinforcing flange 150 is disposed in the gap between the jaws 130 and does not block the insertion hole 111 of the chuck body 110, long rod processing is possible and the jaws ( 130) can be stably maintained by tightening the material.

The above-described lathe chucks 100 and 100' have been described as an example of lathe processing of plastic materials and engineering plastics, but they are applicable to lathe processing of metal materials.

BRIEF DESCRIPTION OF THE DRAWINGS The present invention is disclosed in the drawings and in the specification with preferred embodiments. Here, although specific terms have been used, they are only used for the purpose of describing the present invention, and are not used to limit the meaning or the scope of the present invention described in the claims. Therefore, it will be understood by those skilled in the art that various modifications and equivalent other embodiments of the present invention are possible therefrom. Accordingly, the true technical scope of the present invention should be defined by the technical spirit of the appended claims.

1: headstock 100: lathe chuck
110: chuck body 111: insertion hole
113: encounter guide home 130: encounter
131: first fixing hole 132: second fixing hole
150: reinforcement flange 151: first fastening hole
152: second fastening hole 161: fastening bolt
m: material

Claims (10)

a chuck body rotatably coupled to the headstock and having an insertion hole in the center of the front to insert a material;
a plurality of jaw guide grooves formed radially on the front surface of the chuck body and having a vertical direction toward the center of rotation;
jaws that are slidably assembled in the jaw guide grooves formed on the front surface of the chuck body and move in the direction of the insertion hole to fasten and fix the material located in the insertion hole; and
a reinforcing flange coupled to the side of the jaw to fill the space between the jaw and the jaw;
Lathe chuck comprising a. According to claim 1,
The front surface of the reinforcing flange forms the same plane as the front surface of the jaw. The method of claim 1,
The reinforcing flange has a sectoral shape,
The outer periphery of the reinforcing flange is formed at the same height as the outer periphery of the jaw. According to claim 1,
The reinforcing flange is coupled to the side surface of the jaw and is assembled to the jaw guide groove in an integrated state. According to claim 1,
The jaw is formed of a metal material,
The reinforcing flange is a lathe chuck formed of an engineering plastic material. According to claim 1,
and fastening means for coupling the reinforcing flange to the side surface of the jaw;
The fastening means
a first fixing hole and a second fixing hole formed on the side surfaces of the jaws at intervals;
first and second fastening holes formed to pass through the reinforcing flange and communicating with the first and second fixing holes, respectively; and
a fastening bolt fastened to the first fastening hole through the first fastening hole and fastened to the second fastening hole through the second fastening hole;
Lathe chuck comprising; 7. The method of claim 6,
The first fastening hole and the second fastening hole include a stepped surface dividing the space into two spaces having different inner diameters,
The head of the fastening bolt is located on the step surface so that the fastening bolt is not exposed to the outside of the reinforcing flange. The method of claim 1,
The reinforcing flange coupled to the side of the jaw moves integrally with the jaw and does not block the insertion hole of the chuck body. According to claim 1,
The reinforcing flange is respectively coupled to one side and the other side of the jaw and fills a space between the jaw and the jaw. The method of claim 1,
The reinforcing flange coupled to one side of the jaw and the reinforcing flange coupled to the other side of the jaw are symmetrical.

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