KR100696721B1 - Vice for fixing to 3demension work goods - Google Patents

Abstract

The present invention relates to a vise for clamping a three-dimensional workpiece formed in three dimensions, and relates to a vise capable of holding various types of three-dimensional workpiece. The present invention, in the vise for firmly fixing the three-dimensional workpiece (1) on the work table (W), the main body plate 272 is fixed on the work table (W), having an opening (272a) in the center and ; Fixing means for detachably fixing the main body plate (272) to the work table (W); A pair of rod-shaped main chucks 274 mounted on both sides of the openings 272a formed in the body plate 272 so as to face each other, and clamping while dividing; And a moving member for moving the pair of main chucks 274 in opposite directions. In the present invention, the teeth formed on the fixed and movable jaws 20 and 40 are formed stepwise, thereby clamping various workpieces.

Workpiece, vise, clamping, gripping, chuck

Description

VICE FOR FIXING TO 3DEMENSION WORK GOODS}

1 is a perspective view of a vise for fixing a three-dimensional workpiece according to an embodiment of the present invention;

Figure 2 is an exploded perspective view showing that the table is coupled to the vise shown in Figure 1,

3 is a cross-sectional view taken along line B-B 'illustrating a state of use of the vise shown in FIG. 1;

4 is a perspective view showing a state of use of the main chuck shown in FIG.

5 is an exploded perspective view illustrating that the auxiliary chuck is coupled to the main chuck shown in FIG. 1;

6 to 10 is a view showing a state of use of the auxiliary chuck shown in FIG.

11 is a side view of the vise for fixing a three-dimensional workpiece according to another embodiment of the present invention;

12 is a plan view of the vise for fixing the three-dimensional workpiece shown in FIG.

13 is an exploded perspective view showing a fixed state of the fixed jaw shown in FIG.

14 is an exploded perspective view showing a fixed state of the moving jaw shown in FIG.

Figure 15 is a side view showing a state in which the fixed jaw and the moving jaw shown in FIG.

<Explanation of symbols for the main parts of the drawings>

10 bed 16: protrusion

20: fixed jaw 24, 44: teeth

30: lead screw 40: moving jaw

46: screw insertion groove 210: table

222: pressure plate 224: fastener

210p: protrusion 272: main plate

274: main chuck 276a: lead screw

276b: Screw pulley 276c: Rotating belt

276d: handle 278: auxiliary chuck

279: Fastening bolt

The present invention relates to a vise for clamping a three-dimensional workpiece formed in three dimensions, and relates to a vise capable of holding various types of three-dimensional workpiece.

Typically, a vise clamps a workpiece with two jaws. At this time, a serration is formed on the surface of the jaw to prevent sliding of the workpiece. Such general vise is classified into manual, electric or hydraulic. However, such manual, electric or hydraulic vise almost all have two encounters as described above.

However, the general vise can virtually clamp only a plate having a rectangular or thick thickness as the serration formed on the surface of the jaw is formed in the shape of an equilateral triangle in cross section. In other words, workpieces with cylindrical or disc-shaped or annular or rounded shapes are virtually impossible to clamp. This is because, due to the shape of the jaws and serrations, the workpiece with round or round is not clamped firmly. Even if clamped, they are easily released from the vise. Therefore, a general vise can be virtually impossible to clamp a workpiece with a round or round. That is, the general vise has a problem in that it is not possible to clamp various types of workpieces.

In addition, a general vice has a problem that the workpiece rises due to the equilateral triangle cross section of the serration when clamping the workpiece. Therefore, the workpiece requiring precision machining is changed in position while floating in the vise, so the bite height of the processing apparatus or the cutting depth of the bite must be set again according to the height of the floated workpiece.

The present invention was created in order to solve the conventional problems as described above, the surface of the jaw is formed in a variety of forms, it is possible to firmly clamp a variety of workpieces formed with squares, plates, disks, cylinders, rounds, etc. In addition, the object of the present invention is to provide a three-dimensional workpiece fixing vise capable of not only horizontally fixing the workpiece on the surface of the vise, but also rotating the jaw to the opposite side.

The present invention for achieving the above object, in the vise for firmly fixing the three-dimensional workpiece (1) on the work table (W), is fixed on the work table (W), the opening 272a in the center A main body plate 272 having; Fixing means for detachably fixing the main body plate (272) to the work table (W); A pair of rod-shaped main chucks 274 mounted on both sides of the openings 272a formed in the body plate 272 so as to face each other, and clamping while dividing; And a moving member for moving the pair of main chucks 274 in opposite directions to each other.

On the other hand, the present invention, in the vise for firmly fixing the three-dimensional workpiece (1) on the work table (W), vertical side fixing plate 12 is formed on each side of the front end, respectively, and the nut hole ( A bed 10 having an upward protrusion 14 formed with 14a); Fixing means for detachably fixing the bed (10) to the work table (W); It is inserted between the pair of side fixing plate 12 formed in the bed 10, and is rotatably fixed by the side fixing plate 12 and the through-bolt 22 penetrating the inner side, and various sizes on one side A fixed jaw 20 in which a plurality of teeth 24 pressing one side of the three-dimensional workpiece 1 having a stepwise shape are formed; A lead screw 30 inserted into the nut hole 14a of the upward protrusion 14 formed in the bed 10 and horizontally reciprocated by a hendle 32 provided on one side thereof; The front end of the lead screw 30 is inserted to one side, and is fixed to the front end of the lead screw 30 by a through bolt 42 penetrating the side, the other side of the three-dimensional workpiece (1) The plurality of pressing teeth 44, the moving jaw 40 is formed in a state corresponding to the teeth 24 of the fixed jaw 20; characterized in that it comprises a.

Referring to the accompanying drawings for fixing the three-dimensional workpiece according to the present invention with reference to the accompanying drawings as follows, Figure 1 is a perspective view of a three-dimensional workpiece fixing vise according to an embodiment of the present invention, Figure 2 1 is an exploded perspective view showing that the table is coupled to the vise shown in FIG. 1, and FIG. 3 is a cross-sectional view taken along line B-B 'illustrating a state of use of the vise shown in FIG. And, Figure 4 is a perspective view showing the state of use of the main chuck shown in Figure 1, Figure 5 is an exploded perspective view showing that the auxiliary chuck is coupled to the main chuck shown in Figure 1, Figures 6 to 10 5 is a view showing a state of use of the auxiliary chuck shown in FIG.

As shown in FIG. 1, the vise according to one embodiment is a flat vise 270 having a plate shape. This flat vise 270, as shown, a plate-shaped body plate 272; Fixing means for detachably fixing the main body plate 272 to the work table W; A pair of main chucks 274 and; It includes a moving member.

The body plate 272 has a rectangular opening 272a at the center, as shown. The main body plate 272 is left by the opening 272a so that only the edge portion remains as shown.

As shown, the fixing means forms a through hole 272h in the body plate 272, passes through the fastening bolt B through the through hole 272h, and fastens the work plate W to the body plate 272. ) Is fixed to the work table (W) or configured to detach. Of course, it is obvious that the fastening holes Wh to which the fastening bolts B are fastened to the work table W. Therefore, the body plate 272 can be installed on the workbench W as needed by the fastening bolt B.

As shown in the drawing, the pair of main chucks 274 are inserted into the openings 272a of the main body plate 272 and embedded in opposite sides of the openings 272a. The pair of main chucks 274 clamp the three-dimensional workpiece 1 or the table 210 to be described later while collecting and dividing the inside of the opening 272a by the moving member described above.

The moving member moves the pair of main chucks 274 in opposite directions to each other. As shown in FIG. 1, the movable member includes a pair of lead screws 276a penetrating a pair of main chucks 274 in a screwed state; A pair of screw pulleys 276b respectively mounted on the pair of lead screws 276a; A rotating belt 276c wound around the pair of screw pulleys 276b; And a handle 276d integrally mounted to the pair of lead screws 276a.

Here, as shown in the drawing, the pair of lead screws 276a is inserted into the bracket 272b which is integrally formed on the lower surface of the body plate 272 to form a body with the body plate 272. The pair of lead screws 276a penetrates through the pair of main chucks 274 while being parallel to each other while being spaced apart from each other. The pair of lead screws 276a have threads formed in opposite directions so that the pair of lead chucks 274 move together with the handle 276d to move the pair of main chucks 274 in opposite directions. Of course, it is obvious that the main chuck 274 should be formed with a female threaded hole engaged with the thread of the lead screw 276a. Therefore, the main chuck 274 carries out the summation in the opening 272a of the main body plate 272 by the lead screw 276a.

At this time, the screw pulley 276b and the rotating belt 276c rotate by the rotation of the lead screw 276a. Therefore, the pair of lead screws 276a moves the main chuck 274 while rotating in different directions.

On the other hand, one side edge of the upper surface of the pair of the main chuck 274 described above, as shown in the lower end of Figure 1, the holding projection 274a having a length along the axial direction of the main chuck 274 facing do. Therefore, the pair of main chucks 274 can hold the plate-shaped three-dimensional workpiece 1 or the table 210 described later by using the gripping protrusions 274a.

At this time, the flat vice 270 in which the gripping protrusions 274a are formed on the main chuck 274 has a plate-like table 210 as shown in FIG. 2; A pressure plate 222; Fastener 224; further comprises.

Here, the table 210 is formed to have a width corresponding to the opening 272a of the body plate 272 as shown, and integrally has the protrusion 210p inside the lower edge as shown in FIG. . It also has a plurality of fastening holes 212 as shown. The table 210 is inserted into the opening 272a of the body plate 272 and then placed on the main chuck 274. At this time, the protrusion 210p of the table 210 is gripped by the gripping protrusion 274a of the main chuck 274. Accordingly, the table 210 is clamped to the main chuck 274 when the main chuck 274 joins.

The pressure plate 222 has a plurality of bolt holes 212 as shown in FIG. 2. The fastener 224 described above is inserted into the bolt hole 212 of the pressure plate 222. Here, the fastener 224 is a mood wrench bolt. Such a pressure plate 222 and the fastener 224 may be called a jig 220.

As shown in FIG. 3, the pressure plate 222 is disposed above the three-dimensional workpiece 1 having a plate shape or a quadrangular shape seated on the table 210. And, as shown in the fastener 224, through the pressure plate 222 is fastened to the fastening hole 212 of the table 210, the three-dimensional workpiece (1) is pressed. Thus, the three-dimensional workpiece 1 is fixed on the table 210.

At this time, as shown in the body plate 272, it is necessary to form a fastening hole 212 to which the fastener 224 is fastened. Thus, when the fastening hole 212 is formed in the main body plate 272, the press plate 222 can also be arrange | positioned on the main body plate 272. FIG. That is, by using the pressure plate 222 and the fastener 224, it is also possible to fix the three-dimensional workpiece (1) seated on the body plate (272).

Here, reference numeral 226 of FIG. 3 is a support for providing a horizontal to the pressure plate 222. This, support 226 is a boltless wrench bolt, as shown in Figure 3, the lower end is seated on the table 210, to provide a horizontal to the pressure plate 222.

On the other hand, the three-dimensional workpiece 1 of the plate is clamped to the main chuck 272 in the same manner as the table 210 described above. That is, when formed in the plate shape of the three-dimensional workpiece 1, the three-dimensional workpiece 1 is disposed on the main chuck 272, and then clamped by the gripping protrusion 274a of the main chuck 272.

On the other hand, in the pair of main chucks 274 described above, trapezoidal grooves N1 taking trapezoidal planes are formed as shown in FIG. At this time, the trapezoidal groove (N1) is formed to face each other on one side of the main chuck 274 facing each other, as shown. The trapezoidal groove N1 grips the three-dimensional workpiece 1 in the form of a square hexahedron having a small size, as shown in the joining of the main chuck 274. In particular, the trapezoidal groove (N1) is formed to a length that can correspond to the body of the not shown clamshell phone. Accordingly, the trapezoidal groove N1 can easily hold the mobile phone. At this time, the rounded corner of the mobile phone is gripped at the bent portion formed at both ends of the trapezoidal groove (N1), therefore, the main chuck 274 can firmly grip the mobile phone by the trapezoidal groove (N1).

Here, FIG. 4 shows that the main chuck 274 grips the three-dimensional workpiece 1 having a rectangular parallelepiped shape by using a portion where the trapezoidal groove N1 is not formed. That is, the main chuck 274 may grip the three-dimensional workpiece 1 having a rectangular hexahedron shape to a portion where the trapezoidal groove N1 is not formed.

In addition, the one side surface formed in the pair of main chuck 274, notch groove (N2) as shown in FIG. At this time, the notch groove N2 is formed vertically as shown. The notch groove N2 grips the cylindrical three-dimensional workpiece 1 vertically as shown in FIG. 4 while forming a planar rhombus shape when the main chuck 274 is joined. Here, the cylindrical three-dimensional workpiece 1 shown may be, for example, a painting.

On the other hand, as shown in Figure 5, the upper surface of the main chuck 274, the rod-shaped auxiliary chuck 278 is fixed in a stacked state. The auxiliary chuck 278 is fixed to the main chuck 278 using a pair of fastening bolts 279 as shown. The fastening bolt 279 penetrates both ends of the auxiliary chuck 278 vertically and is fastened to the main chuck 274. Accordingly, the auxiliary chuck is detachably fixed to the main chuck 274. Accordingly, the auxiliary chuck 278 may be detachably attached to the main chuck 274 as necessary. Of course, it is apparent that the auxiliary chuck 278 and the main chuck 274 should have a through hole 279a and a screw hole 274h as shown, through which the fastening bolt 279 is penetrated and fastened.

Here, the reference numeral LH in the drawing shown at one end of the auxiliary chuck 278 is a bolt long hole to be described later. Such a bolt long hole (LH) is a through hole through which the fastening bolt 279 passes. As shown, the auxiliary chuck 278 may be formed by forming bolt long holes LH and through holes 279a at both ends. Alternatively, only the through holes 279a may be formed at both ends. Alternatively, only the bolt long holes LH may be formed at both ends.

The auxiliary chuck 278 moves to the same body as the main chuck 274 when the auxiliary chuck 278 is mounted to the main chuck 274 by the fastening bolt 279. That is, the auxiliary chuck 278 is divided and collected in the same manner as the main chuck 274 by the fastening bolt 279.

)을 갖는다. 이러한, 사잇각(

)은 예각의 범위로 형성하는 것이 바람직하고, 75°내지 85°의 각도 이내로 형성하는 보다 바람직하며, 80°로 형성하는 것이 가장바람직하다. 여기서, 사잇각(

)은 도면의 상단에 확대 도시된 바와 같이 단턱(S1)의 바닥면 및 측벽을 수평 및 경사형성하여 형성한다. 단턱(S1)은 메인척(274)의 조우시, 도면의 하단에 확대 도시(보조척의 종단면도)된 바와 같이 사각육면체 형태의 3차원공작물(1)을 파지한다. 이때, 단턱(S1)은 측벽이 경사를 취함에 따라, 파지되는 3차원공작물(1)이 상부로 부상하는 것을 방지한다. 이는, 단턱(S1)이 예각범위의 사잇각(

)을 갖기때문이다.As shown in FIG. 5, the upper edge of one side of the auxiliary chuck 278 has a length along the axial direction of the auxiliary chuck 278, and a step S1 for holding the three-dimensional workpiece 1 having a rectangular hexahedron shape. ) To face each other. At this time, the step (S1) is enlarged, as shown on the side angle (

Has Such a square angle (

) Is preferably formed in the range of an acute angle, more preferably formed within an angle of 75 ° to 85 °, and most preferably formed at 80 °. Where the angle (

) Is formed by horizontally and inclining the bottom and sidewalls of the step S1 as shown in an enlarged view at the top of the figure. The step S1 grips the three-dimensional workpiece 1 in the form of a square hexahedron as shown in an enlarged view (a longitudinal cross-sectional view of the auxiliary chuck) at the bottom of the drawing when the main chuck 274 is encountered. At this time, the step S1 prevents the three-dimensional workpiece 1 to be held upward as the sidewall is inclined. That is, the step (S1) is the angle of the acute angle range (

Because)

As shown in FIG. 5, an undercutting groove S2 having a length along the axial direction of the auxiliary chuck 278 is formed at a lower end of one side of the pair of auxiliary chucks 278. Undercutting groove (S2) is formed to have a horizontal and inclined one side and the other side as shown enlarged at the bottom of the figure. At this time, one side is the bottom surface of the undercut groove (S2), the other side is the upper surface of the undercut groove (S2). As such, the reason why the one side and the other side are formed horizontally and inclined is that, when the undercut groove S2 is enlarged when the main chuck 274 is joined, the three-dimensional workpiece 1 having a semicircular cross section is formed. To grasp. Here, the three-dimensional workpiece 1 having a semicircular cross section may be, for example, a bag portion of a spoon, that is, a handle.

Here, when the above-described bolt long hole (LH) and the through hole (279a) is formed in each of the one end and the other end of the pair of auxiliary chuck 278, the pair of fastening bolts 279 is After inserting into the bolt long hole LH and the through hole 279a, respectively, it is fastened to the fastening hole 274h of the main chuck 274. Subsequently, the fastening bolt 279 inserted into the bolt long hole LH is slightly loosened and made into an unlocked state. As shown in FIG. 6, one end of the pair of auxiliary chucks 278 is opened to both sides. At this time, one end of the auxiliary chuck 278 is uniaxially rotated about the fastening bolt 279 fastened to the through hole 279a of the other end while being guided by the bolt long hole LH around the fastening bolt 279. do. Accordingly, the pair of auxiliary chucks 278 are opened while taking the shape of a trapezoid in plane, as shown in FIG. 6. Thus, when one end of the auxiliary chuck 278 is opened, the fastening bolt 279 inserted into the bolt long hole (LH) is locked. Thus, the auxiliary chuck 278 remains open.

As such, as the auxiliary chuck 278 maintains its open state, the auxiliary chuck 278 may grip the planar trapezoidal three-dimensional workpiece 1 as shown in FIG. 6. At this time, the planar three-dimensional workpiece 1 in trapezoidal shape is crushed by the above-described step S1 formed in the auxiliary chuck 278. Here, the planar three-dimensional workpiece 1 of the trapezoidal shape may be, for example, chopsticks.

As shown in FIG. 5, a pair of auxiliary chucks 278 may be formed with ribbon-shaped ribbon grooves S3 having a length in the width direction of the auxiliary chuck 278. As shown in FIG. 7, the ribbon groove S3 is formed by communicating the large groove portion S3-1 and the small groove portion S3-2 having an approximately triangular shape with each other. The ribbon groove S3 grips the disk-shaped or annular three-dimensional workpiece 1 as shown in the joining of the main chuck 274. At this time, the disk-shaped or annular three-dimensional workpiece (1) may be, for example, an earring or a ring.

Here, in the case of holding the illustrated earrings in the ribbon groove (S3), the hook-shaped hook is disposed inside the ribbon groove (S3) as shown. The illustrated figure shows that the earring body is disposed in the large groove portion S3-1, and the hook is disposed in the small groove portion S3-2. At this time, the large groove portion (S3-1) is used when the diameter of the disk-shaped three-dimensional workpiece (1) is large, the small groove portion (S3-2) is used when the diameter is small. Of course, in the case of using the small groove portion S3-2, the auxiliary chuck 278 is separated from the main chuck 274 and then rotated to be mounted on the main chuck 274 again.

As shown in FIG. 8, triangular grooves S4 having a triangular shape are opposed to the lower surfaces of the pair of auxiliary chucks 278. When the triangular groove S4 is joined to the main chuck 274, the triangular groove S4 grips the disk-shaped or annular three-dimensional workpiece 1 as shown in an enlarged view (a plan view of the auxiliary chuck) in the drawing. At this time, the disk-shaped or annular three-dimensional workpiece (1) may be, for example, the earring or ring described above.

On the other hand, as shown in Figure 8 on the other side of the auxiliary chuck 278, an arc-shaped round slit (S5) is formed facing along the axial direction of the auxiliary chuck 278. As shown in the drawing, the round slit S5 is preferably formed in the protruding block 278a extending on the other side of the auxiliary chuck 278. However, alternatively, the protruding block 278a may be omitted and formed directly on the other side of the auxiliary chuck 278.

The round slit S5 grips the plate-shaped three-dimensional workpiece 1 having an arc-shaped curvature, as shown in FIG. 9, when the main chuck 274 is joined. Here, the plate-shaped three-dimensional workpiece 1 having an arc-shaped curvature may be, for example, a bracelet. The bracelet is inserted and gripped in the round slit S5, as shown enlarged in FIG. In this case, reference numeral S5 ′ in the enlarged view is an auxiliary round slit for holding a portion of the bracelet when the bracelet is formed long as shown. That is, a long bracelet is partly gripped by the round slit S5, and the other part is gripped by the auxiliary round slit S5 '.

On the other side of the pair of auxiliary chucks 278, notch slots S6 are formed along the axial direction of the auxiliary chuck 278. At this time, the notch slot S6 has a square angle within an obtuse angle. When the notch slot S6 is joined to the main chuck 274, the cylindrical three-dimensional workpiece 1 is gripped in a horizontal state as illustrated in FIG. 10. Here, the cylindrical three-dimensional workpiece 1 may be, for example, a cylindrical writing implement.

Meanwhile, the protrusion block 278a illustrated in FIG. 8 may be formed in plural on the other side of the auxiliary chuck 278. In this case, the plurality of protruding blocks 278a are formed to be spaced apart as shown. Accordingly, a spaced groove SP is formed between the plurality of protruding blocks 278a. Such a spaced groove SP takes a planar quadrangular shape as shown in FIG. 9 when the main chuck 274 is joined. Therefore, the three-dimensional workpiece 1 may be gripped by using the spacing groove SP.

On the other hand, reference numeral HB of FIG. 2 is a horizontal adjustment bolt for adjusting the horizontal of the table 210. At this time, the horizontal adjustment bolt (HB) is provided, a plurality is provided on the edge of the table 210. The lower end of the horizontal adjustment bolt (HB) is in close contact with the upper surface of the main chuck 274, as shown in Figure 3, when the table 210 is fixed to the main chuck 274. Therefore, when the table 210 is fixed to the main chuck 274 inclined, it is possible to correct the inclination of the table 210 while adjusting the horizontal adjustment bolt (HB).

As described above, the vise for fixing the three-dimensional workpiece according to one embodiment, that is, the flat vise 270 is firmly secured by the main chuck 274 and the auxiliary chuck 278, the three-dimensional workpiece 1 of various forms. Can be gripped.

On the other hand, Figure 11 is a side view of a three-dimensional workpiece fixing vise according to another embodiment of the present invention, Figure 12 is a plan view of the three-dimensional workpiece fixing vise shown in Figure 11, Figure 13 is a fixing shown in Figure 11 An exploded perspective view showing the fixed state of a jaw. And, Figure 14 is an exploded perspective view showing a fixed state of the moving jaw shown in Figure 11, Figure 15 is a side view showing a state in which the fixed jaw and the moving jaw shown in FIG.

As shown in FIG. 11, the three-dimensional workpiece fixing vice according to another embodiment of the present invention includes a bed 10; Fixing means for detachably fixing the bed (10) on a work table (W); A fixed jaw 20; A lead screw 30; It includes a moving jaw (40).

As shown in the bed 10, vertical side fixing plates 12 are formed on both sides of the tip, respectively, and the rear end has an upward protrusion 14 formed with a nut hole 14a. Such a bed 10 is preferably molded into a casting. Here, the lead screw 30, which will be described later, penetrates through the upward protrusion 14 in a screwed state.

As shown in the drawing, the protrusions 16 are formed to extend laterally at both edges of the above-described bed 10 and protrude horizontally, and have through holes 16a; And a fixing bolt (B) fastened to the work table (W) through the through hole (16a) of the protrusion (16). At this time, the protrusions 16 are preferably molded together during the molding of the bed 10.

As shown, the fixing jaw 20 is inserted between the pair of side fixing plates 12 formed in the bed 10 described above. Then, it is fixed between the side fixing plate 12 by the through bolt (22). At this time, the through bolt 22 penetrates the inner side of the side fixing plate 12 and the fixing jaw (20). Of course, such a through bolt 22, as shown in Figure 12 and 13, after passing through the fixing jaw 20 and a pair of side fixing plate 12, it is coupled with the nut. Thus, the fixing jaw 20 is fixed between the side fixing plate 12. This, the fixing jaw 20 is not movable in the side fixing plate (12). In addition, the fixing jaw 20 does not rotate about the through bolt 22 by the anti-rotation pin 26, as shown in FIG. This, the fixing pin 26 is fitted to the fixing jaw 20 through the side fixing plate 12, as shown in FIG. Of course, on one side of the fixed jaw 20 to form a pin hole 20b, as shown, the anti-rotation pin 26 is inserted.

Here, the fixing jaw 20 has a plurality of teeth 24 formed on one side, stepped to press one side of the three-dimensional workpiece (1) having various sizes. Then, the fixing jaw 20 is slightly unlocked by loosening the nut fastened to the through-bolt 22, and when the fixing pin 26 is removed, as shown in Figure 15 to rotate 180 ° do.

As shown in FIG. 11, the lead screw 30 penetrates through the upward protrusion 14 formed in the bed 10. At this time, the nut 14a is provided in the upward protrusion 14. Accordingly, the lead screw 30 is screwed with the nut hole (14a). A handle 32 is provided at one end of the lead screw 30. Therefore, when turning the handle 32, the lead screw 30 is moved horizontally toward the fixing jaw (20). At the end of the lead screw 30, the moving jaw 40 is fixed. When the lead screw 30 rotates, the moving jaw 40 moves. The fixed jaw 20 and the moving jaw 40 clamp the three-dimensional workpiece 1 by dividing by the rotation of the lead screw 30. Or release the clamping.

As shown in FIG. 11, the moving jaw 40 is fitted with the center portion inserted into the front end of the lead screw 30. Then, it is fixed integrally to the tip of the lead screw 30 by the through bolt 42 penetrating the side. At this time, the moving jaw 40 has a plurality of teeth 44 for pressing the other side of the three-dimensional workpiece (1) on one side. The teeth 44 are formed to correspond to the teeth 24 of the fixed jaw 20.

Such a vise according to another embodiment, it is necessary to further comprise a horizontal movement means for horizontally moving the bed 10 on the work table (W). As shown in FIG. 12, the horizontal moving means has a long through-hole 16a of the protruding portion 16 in the form of a long hole, so that the through-hole 16a extends in the longitudinal direction about the fixing bolt B. Therefore, it is configured to move.

In more detail, the fixing bolt (B) fastened to the work table (W) through the protrusion (16) to slightly unlocked state, and then move the bed 10 in the direction to move (bold black arrow on the drawing) Push it up. Accordingly, the bed 10 is moved by the through hole 16a in the form of a long hole. Then, after the movement is completed, lock the fixing bolt (B) again. Then, the bed 10 is again fixed on the work table (W).

On the other hand, the teeth 24 and 44 of the fixed jaw 20 and the moving jaw 40 are formed to have an angle angle θ in the acute angle range on the side as shown in an enlarged view in FIG. In the clamping of the three-dimensional workpiece (1) as shown, it is configured to press the three-dimensional workpiece (1) downward.

These teeth 24 and 44 have horizontal bottom surfaces and inclined sidewalls, as shown enlarged in FIG. 11 by the angle θ. The three-dimensional workpiece 1 is seated on the bottom surface of the teeth 24, 44, as shown in FIG. 11, and then clamped by the sidewall top edge P of the sharply protruding teeth 24, 44. . At this time, the upper edge P of the side walls of the teeth 24 and 44 presses the three-dimensional workpiece 1 downward by the pressing force of the lead screw 30.

In more detail, in order for the fixed and movable jaws 20 and 40 to firmly grip the three-dimensional workpiece 1, the handle 32 of the lead screw 30 should be turned until it is impossible to rotate. As a result, the lead screw 30 continues toward the fixed jaw 20. Thus, the moving jaw 40 holds the three-dimensional workpiece 1 together with the fixed jaw 20 as shown in FIG.

At this time, the upper edges of the side walls of the teeth 24 and 44 of the fixed and movable jaws 20 and 40 press the three-dimensional workpiece 1 on both sides. Thus, when the three-dimensional workpiece 1 is pressed, the teeth 24 and 44 press the three-dimensional workpiece 1 downward due to the inclined sidewalls. Thus, the three-dimensional workpiece 1 does not rise to the top of the fixed and moving jaws 20, 40 when clamping. If the side walls of the teeth 24 and 44 have no inclination and are formed at right angles on the sides, that is, when the angle θ is 90 °, the teeth 24 and 44 of the fixed and moving jaws 20 and 40 are used. Does not pressurize the three-dimensional workpiece (1) downward. This is because the entire sidewalls of the teeth 24, 44 press on the three-dimensional workpiece 1. However, when the inclination is formed on the side walls of the teeth 24 and 44, only the upper side edge P of the side walls of the teeth 24 and 44 presses the three-dimensional workpiece 1, so that the three-dimensional workpiece 1 is pressed downward. do.

Thus, when forming the angle (θ) in the teeth (24, 44), the fixed and moving jaw (20, 40), as well as the square or plate shape, the three-dimensional workpiece (1) formed with a disc, cylinder, or round, etc. Can be clamped This is because the inclination is formed on the side walls of the teeth 24 and 44. This is because the upper edge P of the side wall directly presses the workpiece. That is, because the upper edge of the side wall grips the workpiece in a wedge manner.

However, in the case where the angles θ of the teeth 24 and 44 are formed at 90 ° and the side walls of the teeth 24 and 44 are formed vertically, the three-dimensional workpiece 1 in which a disc, a cylinder, or a round is formed is formed. Cannot be clamped. This is because the outer circumferential surface of the three-dimensional workpiece 1 in which the disc, the cylinder, or the round is formed slides on the side walls of the teeth 24 and 44.

On the other hand, the teeth 24 and 44 of the fixed jaw 20 and the moving jaw 40 are formed to have different heights H when they face each other, so that the teeth 24 and 44 are three-dimensional workpieces (1). It is formed to take the same height (H) with each other by the pressing force generated during the clamping of).

In more detail, when the handle 32 of the lead screw 30 is rotated until it is impossible to rotate, the fixed and moving jaws 20 and 40 clamp the three-dimensional workpiece 1 as shown. The lead screw 30 strongly presses the moving jaw 40. Thus, the moving jaw 40 presses the three-dimensional workpiece 1. At this time, the moving jaw 40 having the cantilever shape as shown in FIG. 11 by the lead screw 30 has a side surface (shown in FIG. 11) with respect to the through bolt 42 on the side by the pressing force. On the side) rotate counterclockwise. Of course, only slightly rotates due to the through bolts 42. Thus, as the moving jaw 40 rotates slightly in the counterclockwise direction, the teeth 44 of the moving jaw 40 have the same height H as the teeth 24 of the fixed jaw 20. However, since the fixing jaw 20 is directly connected to the side fixing plate 12, it does not take the cantilever shape, and thus does not rotate even when a pressing force is applied.

The reason why the moving jaw 40 rotates in the counterclockwise direction is because of the side wall having the inclination of the teeth 44 as described above in the description of the angles θ of the teeth 24 and 44. That is, the moving jaw 40 rotates counterclockwise by the side wall having the inclination of the tooth 44, which presses the three-dimensional workpiece 1 downward when clamping.

On the other hand, the vise according to another embodiment, the moving jaw 40 is rotated by 180 ° about the through bolt 42 described above, so that the moving jaw 40 is fixed to the lead screw 30 described above. It further comprises a rotating means for rotating.

As shown in FIG. 15, the screw insertion groove 46 is formed on one side of the moving jaw 40 located on the opposite side to which the tip of the lead screw 30 is inserted, thereby providing the screw insertion groove 46. The leading end of the lead screw 30 is inserted into the c), so that the moving jaw 40 is rotated and fixed to the lead screw 30 by the through bolts 42. At this time, the through-hole 30a as shown in the enlarged view through which the through bolt 42 penetrates is formed at the tip of the lead screw 30.

Such a rotation means is used when the moving jaw 40 installed as shown in FIG. 11 is turned to the opposite side as shown in FIG. Thus, in order to turn the moving jaw 40 to the opposite side, first remove the through bolt 42 and then turn. Then, after turning the moving jaw 40, the front end of the lead screw 30 is inserted into the screw insertion groove 46, and then passed through the through bolt 42 to the moving jaw 40 and then locked. At this time, the through bolt 42 passes through the through hole 30a of the lead screw 30. Therefore, the tip of the lead screw 30 is fixed in the screw insertion groove 46, the moving jaw 40 is maintained in a reversed state.

At this time, the screw insertion groove 46 is formed to have a taper in the up and down direction on the side, as shown in Figure 15, the moving jaw 40 around the leading end of the lead screw 30, Configure the angle to be adjustable.

In more detail, after loosening the through bolt 42 slightly loosely, the moving jaw 40 is rotated about the through bolt 42 by a desired angle. Then, the through bolts 42 are locked again. Therefore, the moving jaw 40 is adjusted to a desired angle within the taper angle range of the screw insertion groove 46. The taper angle of the screw insertion groove 46 is appropriately within the obtuse angle.

On the other hand, the fixed jaw 20 and the moving jaw 40 further includes a ring holding portion for fixing the disk-shaped or annular three-dimensional workpiece (1). Such, the ring holding portion is enlarged in the upper left of Figure 15, the ring insertion grooves 28, 48 taking a planar triangular shape on one side of the fixed jaw 20 and the moving jaw 40 in an opposite state. When the clamping operation of the fixing and moving jaws 20 and 40 is formed, the ring insertion grooves 28 and 48 are enlarged in the upper right of FIG. 15, and the disk-shaped or annular three-dimensional workpiece 1 is formed. Configure to grip while pressing. Here, the disk-shaped or annular three-dimensional workpiece 1 may be an earring, a coin, a ring, or the like. At this time, the fixed and moving jaws (20, 40) should be installed so that the ring insertion grooves (28, 48) face each other while positioned upwards.

Vise according to another embodiment configured as described above, the fixing bolt (B) through the protrusions 16 of the bed 10 to fasten to the work table (W) as shown in FIG. That is, the bed 10 is fixed to the work table (W). At this time, if you want to move the bed 10 on the work table (W) slightly loosen the fixing bolt (B) slightly, then push the bed (10). Accordingly, the bed 10 is moved by the length of the through hole 16a by the through hole 16a having a long hole shape. Thus, when the bed 10 is moved, lock the fixing bolt (B) again.

Then, while the teeth 24 and 44 of the fixed and movable jaws 20 and 30 are opposed to each other as shown in FIG. 11, the three-dimensional workpiece 1 is turned by turning the handle 32 of the lead screw 30. Clamp At this time, the three-dimensional workpiece (1) may be clamped to any one of the plurality of teeth (24, 44) formed in a step shape depending on the size. Here, the three-dimensional workpiece 1 is a workpiece in which a square, plate, cylinder, round, or the like is formed.

On the contrary, after the fixing and moving jaws 20 and 40 are reversed as shown in FIG. 15, the handle 32 of the lead screw 30 is turned to clamp the plate-shaped or annular three-dimensional workpiece 1.

The above embodiment is merely a description of the preferred embodiment of the present invention, the scope of application of the present invention is not limited to such, and can be changed as appropriate within the scope of the same idea. Accordingly, the shape and structure of each component shown in the embodiments of the present invention can be modified and carried out, and such modifications are naturally belonging to the appended claims.

Vise fixing for the three-dimensional workpiece according to the present invention as described above, the teeth formed in the fixed and moving jaw is formed in a stepped manner, it is possible to clamp the workpiece of various sizes.

As the tooth is formed at an acute angle, the upper edge of the side wall of the tooth grips the surface of the three-dimensional workpiece in a wedge manner and prevents the three-dimensional workpiece from injuring, such as a square, plate, disc, cylinder, round, etc. There is an effect that can be clamped in a horizontal state firmly formed workpieces of various forms.

In addition, since the fixing and moving jaw can be rotated to the opposite side, there is an effect that can be clamped three-dimensional workpiece by using the opposite surface of the fixed and moving jaw.

Claims (24)

delete A main body plate 272 fixed on the work table W and having an opening 272a in the center thereof; Fixing means for detachably fixing the main body plate (272) to the work table (W); A pair of rod-shaped main chucks 274 mounted on both sides of the openings 272a formed in the body plate 272 so as to face each other, and clamping while dividing; In the three-dimensional workpiece fixing vise consisting of a moving member for moving the pair of main chuck 274 in the opposite direction, The fixing means, The through-hole 272h is formed in the main body plate 272, the fastening bolt B passes through the through-hole 272h, and fastened to the work table W, thereby the main body plate 272 is mounted on the work table W. Vise for fixing the three-dimensional workpiece, characterized in that configured to be selectively fixed to or separated. The method of claim 2, At one corner of the upper surface of the pair of main chucks 274, the holding projections 274a having a length along the axial direction of the main chuck 274 face each other, such that the main chuck 274 is a plate-shaped three-dimensional workpiece ( 1) Vise fixing the three-dimensional workpiece, characterized in that configured to grip. The method of claim 3, wherein It is formed in the width corresponding to the opening 272a of the main body plate 272 and inserted into the opening 272a, and fixed to the opening 272a by the main chuck 274, and the three-dimensional workpiece 1 Table 210 having a plurality of fastening holes 212 at the same time it is seated; A pressing plate 222 for pressing the three-dimensional workpiece 1 seated on the table 210 to fix the three-dimensional workpiece 1 on the table 210; And a fastener 224 that penetrates the pressing plate 222 and is fastened to the fastening hole 212 of the table 210 to fix the pressing plate 222 to the table 210. The table 210 is formed in the same body inside the rim of the lower surface, the projection 210p is gripped by the gripping projections (274a) of the main chuck; Vice for fixing three-dimensional workpieces having a. The method of claim 2, On one side of the pair of main chucks 274, trapezoidal grooves N1 having a trapezoidal plane are formed to face each other, and the main chuck 274 is configured to hold a three-dimensional workpiece 1 having a rectangular hexahedron shape. 3D workpiece fixing vise. The method of claim 2, On one side of the pair of main chucks 274, notch grooves N2 having lengths perpendicularly formed to face each other, the main chuck 274 is configured to hold the cylindrical three-dimensional workpiece (1) in a vertical state. Vise for fixing three-dimensional workpieces. The method of claim 2, The moving member, Rotatably fixed to the main body plate 272 to penetrate the pair of main chucks 274 in a screwed state, and the threads are formed in opposite directions to rotate the pair of main chucks 274 opposite to each other. A pair of lead screws 276a moving in the direction; A pair of screw pulleys 276b respectively mounted on the pair of lead screws 276a; A rotating belt 276c wound around the pair of screw pulleys 276b; And a handle (276d) integrally mounted to any one of the pair of lead screws (276a) to rotate the lead screws (276a). The method of claim 2, A pair of rod-shaped auxiliary chucks 278 fixed to the upper surface of the main chuck 274 in a stacked state and holding various types of three-dimensional workpieces 1 by clamping operations of the main chuck 274; A pair of fastening bolts 279 through which both ends of the auxiliary chuck 278 vertically penetrate the main chuck 274 to detachably fix the auxiliary chuck 278 to the main chuck 274; 3D workpiece fixing vise further comprising a. The method of claim 8, On the upper edge of one side of the pair of auxiliary chuck 278, has a length along the axial direction of the auxiliary chuck 278, and the step (S1) for holding the three-dimensional workpiece (1) of the rectangular hexahedron form opposite to ; Side angles formed on the step S1

) Is formed in the range of an acute angle, the three-dimensional workpiece fixing vise, characterized in that configured to prevent the three-dimensional workpiece (1) gripped to the upper step (S1) to rise to the top. The method of claim 8, At the lower end of one side of the pair of auxiliary chucks 278, the length of the auxiliary chuck 278 is along the axial direction, and one side and the other side face an undercutting groove S2 having horizontal and inclined sides, Vice for fixing three-dimensional workpieces, characterized in that the auxiliary chuck 278 is configured to hold the three-dimensional workpiece (1) having a semi-circular cross section. The method of claim 8, One end of the auxiliary chuck 278 forms a bolt long hole LH through which one of the pair of fastening bolts 279 penetrates, and one end of the auxiliary chuck 278 includes the fastening bolt 279 as an axis. Vise for fixing three-dimensional workpieces, characterized in that configured to rotate uniaxially about the other end while receiving the guide of the bolt long (LH). The method of claim 8, On the upper surface of the pair of auxiliary chucks 278, ribbon-shaped ribbon grooves S3 having a length in the width direction of the auxiliary chuck 278 are formed to face each other, such that the auxiliary chuck 278 is disc-shaped or annular three-dimensional. Vise for fixing a three-dimensional workpiece, characterized in that configured to hold the workpiece (1). The method of claim 8, On the lower surface of the pair of auxiliary chucks 278, triangular grooves S4 having a triangular shape are formed to face each other, and the auxiliary chuck 278 is configured to hold a disk-shaped or annular three-dimensional workpiece 1. 3D workpiece fixing vise. The method of claim 8, On the other side of the auxiliary chuck 278, an arc-shaped round slit S5 is formed to face each other along the axial direction of the auxiliary chuck 278 so that the auxiliary chuck 278 has a plate-shaped curvature having an arc-shaped curvature. Vise for fixing three-dimensional workpieces, characterized in that configured to hold the workpiece (1). The method of claim 8, On the other side of the auxiliary chuck 278, a notch slot S6 is formed along the axial direction of the auxiliary chuck 278 so that the auxiliary chuck 278 grips the cylindrical three-dimensional workpiece 1 in a horizontal state. Vise fixing the three-dimensional workpiece, characterized in that configured. delete delete delete delete delete delete delete delete delete

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