KR102674858B1 - Smart jig for workpiece processing - Google Patents

Abstract

The present invention relates to a smart jig for processing workpieces, comprising: a jig body (10) fixed to the upper part of a table capable of moving in multiple axes provided in a machine tool; A first fixing part (20) installed in the left and right directions on the jig body (10) to pressurize and secure the left and right sides of the workpiece; A second fixing part (30) installed on the jig body (10) in the front and rear direction to pressurize and secure the front and rear surfaces of the workpiece; Includes.
According to the present invention, the exact centers of various types of workpieces of different sizes such as width, length, and height are automatically and accurately aligned and fixed quickly, easily, and firmly, thereby greatly improving the processing precision of the workpiece. As fixing is done automatically, unmanned automation of various types of workpiece processing is possible, greatly improving productivity and production efficiency in processing small quantities of various types of workpieces, and the cost of workpiece processing can be greatly reduced by reducing labor costs through unmanned automation. There is.

Description

Smart jig for workpiece processing}

The present invention relates to a smart jig for processing workpieces, and more specifically, when fixing a workpiece for processing, the exact center of the workpiece is automatically and precisely aligned regardless of the size of the workpiece, allowing it to be fixed quickly, easily, and firmly. This is about a smart jig for workpiece processing.

A die or mold generally refers to a tool or mold that processes and molds materials to produce products by using the properties of materials such as plasticity, malleability, and fluidity, and mass produces products of the same standard. It is manufactured to

Therefore, molds are an essential tool for mass production of products in almost all industrial fields such as automobiles, mobile phones, semiconductors, displays, home appliances, and household goods, and are a key element that determines the quality and design of finished products.

In general, molds are manufactured for each product, and each mold is required depending on the shape, shape, and specifications of the product. As the number of types of products increases, the number of molds required also increases.

The raw material of a typical mold, that is, the workpiece, is a lump of metal. To manufacture a mold, the workpiece is fixed and then the workpiece is cut or the surface is processed using various machine tools depending on the design of the mold.

However, when the size of the workpiece to be processed varies depending on the design of the mold, the fixing (clamping) position of the workpiece held by the jig also changes, so the worker must manually fix the workpiece one by one, which reduces productivity and processing precision. There is a disadvantage that becomes a factor.

In particular, in the case of unskilled people, it takes a lot of time to fix the workpiece in the correct position during the process of manually fixing the workpiece, which not only results in a decrease in product productivity, but also reduces the productivity of the product by fixing the workpiece in the jig, processing it, and processing the finished workpiece. After discharging the workpiece, in the process of repeatedly fixing the new workpiece to the jig, if the workpiece is not fixed in the correct position of the jig due to lack of concentration due to the worker's fatigue or lack of skills due to inexperience, the workpiece There was also the problem of an increase in the incidence of defective products as the processing precision decreased significantly.

Problems like the above can occur not only in machining centers, but also in other machine tools such as CNC lathes.

Registered Utility Model Publication No. 20-0478870

In order to solve the conventional shortcomings as described above, the purpose of the present invention is to provide a smart jig for processing workpieces that automatically and accurately aligns the exact center of the workpiece regardless of the size of the workpiece to quickly, easily, and securely fix it. do.

In order to achieve the above-mentioned purpose, the smart jig for processing workpieces of the present invention,

A jig body (10) fixed to the upper part of a table capable of moving in multiple axes provided in a machine tool;

A first fixing part (20) installed in the left and right directions on the jig body (10) to pressurize and fix the left and right sides of the workpiece;

A second fixing part (30) installed on the jig body (10) in the front and rear direction to pressurize and secure the front and rear surfaces of the workpiece; Includes.

In one embodiment, the jig body 10 is,

A horizontal body portion 101 formed in the left and right directions so that the first fixing portion 20 is installed;

A vertical body portion 102 formed in the front-back direction so that the second fixing portion 30 is installed; It is characterized by including.

In one embodiment, the first fixing part 20,

A first shaft 201 installed to slide in the left and right directions on the jig body 10;

A first driving means (202) that provides power to slide the first shaft (201);

A first fixing block 203 that is fixed to one end of the first shaft 201 and presses and fixes one side of the workpiece;

A second fixing block 204 is installed to slide on the upper side of the other end of the first shaft 201 symmetrically to the first fixing block 203 and presses and fixes the other side of the workpiece;

A first power transmission means (205) transmitting power to the second fixed block (204) in a direction opposite to the sliding direction of the first shaft (201); It is characterized by including.

In one embodiment, the first driving means 202 uses an actuator.

In one embodiment, the first fixed block 203 is,

A locking protrusion (203a) that protrudes from the lower inner surface and onto which the workpiece is seated;

A slide groove portion (203b) formed on the bottom surface to correspond to the slide protrusion of the jig body (10); It is characterized by including.

In one embodiment, an oil groove (203c) is further provided on the inner surface of the slide groove portion (203b).

In one embodiment, the first power transmission means 205 is,

A first rack gear (205a) formed on the upper surface of the other end of the first shaft (201);

a second rack gear (205b) formed symmetrically to the first rack gear (205a) on the bottom of the second fixed block (204);

A first pinion gear (205c) installed to mesh between the first rack gear (205a) and the second rack gear (205b) to reverse the operating direction of the first shaft (201) and transmit it to the second fixed block (204). ; It is characterized by including.

In one embodiment, the second fixing part 30 is,

A second shaft 301 installed to slide in the front-back direction on the jig body 10;

A second driving means (302) that provides power to slide the second shaft (301);

A first fixing clamp 303 that is fixed to one end of the second shaft 301 and presses and secures one side of the workpiece;

a second fixing clamp 304 that is slidably installed on the upper side of the other end of the second shaft 301 and presses and secures the other side of the workpiece;

A second power transmission means (305) transmitting power to the second fixing clamp (304) in a direction opposite to the sliding direction of the second shaft (301); It is characterized by including.

In one embodiment, the second driving means 302 uses an actuator.

In one embodiment, the first fixing clamp 303 is characterized in that it is a rod body.

In one embodiment, the second fixing clamp 304 is characterized in that it is a rod body.

In one embodiment, the second power transmission means 305 is,

a third rack gear (305a) formed on the upper surface of the other end of the second shaft (301);

a fourth rack gear (305b) formed symmetrically to the third rack gear (305a) at the bottom of the second fixing clamp (304);

A second pinion gear (305c) installed to mesh between the third rack gear (305a) and the fourth rack gear (305b) to reverse the operating direction of the second shaft (301) and transmit it to the second fixing clamp (304). ; It is characterized by including.

In one embodiment, the second fixing part 30 is,

A stopper means (306) for limiting the sliding distance of the second fixing clamp (304); It is characterized by further comprising:

In one embodiment, the stopper means 306,

A long groove (306a) formed at a predetermined length along the longitudinal direction of the second fixing clamp (304) at the top of the second fixing clamp (304);

A stopper (306b) installed on the upper part of the jig body (10) to enable position adjustment, the lower end of which is inserted into the long groove (306a); It is characterized by including.

In one embodiment, the jig body 10 is,

A vertical body portion 102 rotatably installed on the horizontal body portion 101;

Rotating means 104 installed at the lower part of the horizontal body 101 to rotate the vertical body 102 at a predetermined angle; It is characterized by including.

The present invention not only greatly improves the machining precision of the workpiece by automatically and accurately aligning the exact centers of various types of workpieces of different sizes such as width, length, and height, and fixing them quickly, easily, and firmly, but also fixes the workpiece. By doing this automatically, unmanned automation of various types of workpiece processing is possible, greatly improving productivity and production efficiency in processing small quantities of various types of workpieces, and has the effect of significantly lowering the cost of workpiece processing by reducing labor costs through unmanned automation. there is.

1 is a perspective view according to a preferred embodiment of the smart jig for processing workpieces of the present invention.
Figure 2 is a plan view according to a preferred embodiment of the smart jig for processing workpieces of the present invention.
Figure 3 is a front cross-sectional view according to a preferred embodiment of the smart jig for workpiece processing of the present invention.
Figure 4 is a bottom perspective view of the first fixed block according to a preferred embodiment of the smart jig for workpiece processing of the present invention.
Figure 5 is a cross-sectional illustration showing the workpiece fixing state of the first fixing part according to a preferred embodiment of the smart jig for workpiece processing of the present invention.
Figure 6 is a side cross-sectional view according to a preferred embodiment of the smart jig for workpiece processing of the present invention.
Figure 7 is a cross-sectional illustration showing the workpiece fixing state of the second fixing part according to a preferred embodiment of the smart jig for workpiece processing of the present invention.
Figure 8 is a cross-sectional illustration showing a rotation means according to another embodiment of the smart jig for processing workpieces of the present invention.
Figure 9 is a plan view according to another embodiment of the smart jig for processing workpieces of the present invention.

Below, with reference to the attached drawings, embodiments of the present invention will be described in detail so that those skilled in the art can easily implement the present invention.

Since the description of the present invention is only an example for structural or functional explanation, the scope of the present invention should not be construed as limited by the examples described in the text.

In other words, since the embodiments can be modified in various ways and can have various forms, the scope of rights of the present invention should be understood to include equivalents that can realize the technical idea.

In addition, the purpose or effect presented in the present invention does not mean that a specific embodiment must include all or only such effects, so the scope of the present invention should not be understood as limited thereby.

All terms used in the description of the present invention have the same meaning as generally understood by a person of ordinary skill in the field to which the present invention pertains, unless otherwise defined.

Terms defined in commonly used dictionaries should be interpreted as consistent with the meaning they have in the context of the related technology, and cannot be interpreted as having an ideal or excessively formal meaning unless clearly defined in the present invention.

In addition, terms such as “first” and “second” are only used to distinguish different components, and are not limited by the order of manufacture, and the scope of rights should not be limited by these terms.

Figure 1 is a perspective view according to a preferred embodiment of the smart jig for workpiece processing of the present invention, Figure 2 is a plan view according to a preferred embodiment of the smart jig for workpiece processing of the present invention, and Figure 3 is a preferred embodiment of the smart jig for workpiece processing of the present invention. It is a front cross-sectional view according to an embodiment, Figure 4 is a bottom perspective view of the first fixing block according to a preferred embodiment of the smart jig for workpiece processing of the present invention, and Figure 5 is a first block according to a preferred embodiment of the smart jig for workpiece processing of the present invention. It is an example cross-sectional view showing the workpiece fixation state of the first fixing part, Figure 6 is a side cross-sectional view according to a preferred embodiment of the smart jig for workpiece processing of the present invention, and Figure 7 is a side cross-sectional view according to a preferred embodiment of the smart jig for workpiece processing of the present invention. This is an example cross-sectional view showing the state of fixing the workpiece in the second fixing part.

Description will be made with reference to FIGS. 1 to 7.

The smart jig for workpiece processing of the present invention includes a jig body (10), a first fixing part (20), and a second fixture so that the exact center of the workpiece is automatically and accurately aligned and fixed quickly, easily, and firmly regardless of the workpiece's specifications. Including the government (30).

The jig body 10 is fixed to the upper part of a table capable of moving in a multi-axis direction provided in a machine tool, and includes a horizontal body part 101 formed in the left and right directions so that the first fixing part 20 is installed, and a second fixing part ( 30) includes a vertical body portion 102 formed in the front-back direction to be installed.

It is desirable for the machine tool to be a machining center, but it should be noted in advance that it is not limited thereto.

The horizontal body portion 101 and the vertical body portion 102 are preferably formed to intersect at right angles in a plane.

In one embodiment, the upper ends of the horizontal body portion 101 and the vertical body portion 102 may each be further provided with slide protrusions in the longitudinal direction.

In order to more firmly fix the jig body 10 to the table top, a flat base plate 103 may be further provided at the lower part of the jig body 10.

The first fixing part 20 is installed in the left and right directions on the jig body 10 and includes a first shaft 201, a first driving means 202, and a first fixing block 203 to press and fix the left and right sides of the workpiece. ), a second fixed block 204, and a first power transmission means 205.

The first shaft 201 is installed on the jig body 10 to slide in the left and right directions.

The first shaft 201 is preferably installed horizontally on the horizontal body portion 101 of the jig body 10.

The first driving means 202 provides power to cause the first shaft 201 to slide.

In one embodiment, the first driving means 202 preferably has an actuator installed horizontally on one side of the horizontal body portion 101 of the jig body 10.

The first fixing block 203 is located on the upper side of the horizontal body portion 101 of the jig body 10 and is fixed to one end of the first shaft 201 to press and secure one side of the workpiece. ), and includes a slide groove portion (203b).

The locking ledge 203a protrudes from the lower inner surface of the first fixing block 203, so that the workpiece inserted by an input means such as a robot is placed on the locking ledge 203a and is fixed to the lower part of the workpiece. Not only does sufficient space ensure smooth processing of the workpiece, but it also facilitates the discharge of cutting chips generated during the processing of the workpiece.

The slide groove portion 203b is formed on the bottom of the first fixing block 203 to correspond to the slide protrusion formed in the longitudinal direction at the upper end of the horizontal body portion 101 of the jig body 10.

Therefore, when the first fixed block 203 slides, precise sliding is possible.

In one embodiment, an oil groove 203c may be further provided on the inner surface of the slide groove portion 203b.

Therefore, when the first fixed block 203 slides, more precise and stable sliding is possible.

The second fixed block 204 is a horizontal body of the jig body 10 so as to slide on the upper side of the other end of the first shaft 201 symmetrically with the first fixed block 203 with respect to the center of the jig body 10. It is installed in unit 101 and pressurizes and fixes the other side of the workpiece.

The second fixing block 204 preferably has a locking protrusion, a slide groove, and an oil groove in the same way as the first fixing block 203.

The first power transmission means 205 includes a first rack gear 205a and a second rack gear 205b to transmit power to the second fixed block 204 in a direction opposite to the sliding direction of the first shaft 201. , including the first pinion gear 205c.

The first rack gear 205a is formed on the upper surface of the other end of the first shaft 201.

The second rack gear 205b is formed symmetrically with the first rack gear 205a at the bottom of the second fixed block 204.

The first pinion gear (205c) is installed on the jig body (10) to mesh between the first rack gear (205a) and the second rack gear (205b) and reverses the moving direction of the first shaft (201) to secure the second. Transfer to block 204.

In one embodiment, it is desirable to use a spur gear as the first pinion gear 205c, but it is not limited thereto.

Therefore, when the first shaft 201 moves to the left in the drawing by the first driving means 202, the first fixed block 203 moves to the left in the same way as the first shaft 201, and As the direction of power is reversed by the power transmission means 205, the second fixed block 204 moves to the right, which is opposite to the direction of movement of the first fixed block 203. When a workpiece is inserted between the and second fixing blocks 204, both left and right sides of the workpiece are pressurized and fixed by the first fixing block 203 and the second fixing block 204.

That is, when the workpiece is input by an input means such as a robot, the workpiece is placed with the first fixing block 203 and the second fixing block 204 at appropriate intervals corresponding to the horizontal length of the workpiece. When the first fixing block 203 and the second fixing block 204 are stably seated on the locking protrusions 203a, the magnetic gripper of the input means for inserting the workpiece, such as a robot, is separated from the workpiece, and the first fixing block 203 and the second fixing block 204 further pressurizes and secures the left and right sides of the workpiece, thereby enabling solid fixation of the workpiece.

In particular, the first fixed block 203 and the second fixed block 204 are simultaneously moved the same distance and come together, or are simultaneously moved the same distance and are operated symmetrically so that the first fixed block 203 and the second fixed block 203 are moved apart. The workpiece inserted between the fixing blocks 204 is fixed exactly at the center of the first fixing block 203 and the second fixing block 204, thereby improving the precision of the fixing position of the workpiece and the fastening force to the workpiece.

The second fixing part 30 is installed on the upper part of the jig body 10 in the front-back direction and includes a second shaft 301 and a second drive means 302 to press and fix the front and rear surfaces of the workpiece. It includes a first fixing clamp 303, a second fixing clamp 304, and a second power transmission means 305.

The second shaft 301 is installed on the jig body 10 to slide in the front-back direction.

The second shaft 301 is preferably installed horizontally on the vertical body portion 102 of the jig body 10.

The second driving means 302 provides power to cause the second shaft 301 to slide.

In one embodiment, the second driving means 302 is preferably installed horizontally on one side of the vertical body portion 102 of the jig body 10.

The first fixing clamp 303 is located on the upper side of the vertical body portion 102 of the jig body 10 and is fixed to one end of the second shaft 301 to press and secure one side of the workpiece.

In one embodiment, it is preferable that the first fixing clamp 303 be a rod body, but it is not limited thereto.

In the case where the second shaft 301 and the first fixing clamp 303 are installed to be spaced apart at a predetermined interval, a fixing member that secures the second shaft 301 and the first fixing clamp 303 to move integrally is further installed. Of course, it can be provided.

The second fixing clamp 304 is a vertical body of the jig body 10 so as to slide on the upper side of the other end of the second shaft 301 symmetrically with the first fixing clamp 303 with respect to the center of the jig body 10. It is installed on the part 102 and pressurizes and fixes the other side of the workpiece.

The second power transmission means 305 includes a third rack gear 305a and a fourth rack gear 305b to transmit power to the second fixing clamp 304 in a direction opposite to the sliding direction of the second shaft 301. , including the second pinion gear 305c.

The third rack gear 305a is formed on the upper surface of the other end of the second shaft 301.

The fourth rack gear 305b is formed symmetrically with the third rack gear 305a at the bottom of the second fixing clamp 304.

The second pinion gear (305c) is installed on the jig body (10) to mesh between the third rack gear (305a) and the fourth rack gear (305b), and reverses the moving direction of the second shaft (301) to secure the second shaft. It is transmitted to the clamp (304).

In one embodiment, it is desirable to use a spur gear as the second pinion gear 305c, but it is not limited thereto.

Therefore, when the second shaft 301 moves to the left in the drawing by the second driving means 302, the first fixing clamp 303 moves to the left in the same way as the second shaft 301, and As the direction of power is reversed by the 2 power transmission means 305, the second fixing clamp 304 moves to the right, which is opposite to the direction of movement of the first fixing clamp 303. When a workpiece is inserted between the first and second fixing clamps 304, both front and back sides of the workpiece are pressurized and fixed by the first fixing clamp 303 and the second fixing clamp 304.

In particular, as the first fixing clamp 303 and the second fixing clamp 304 are simultaneously moved by the same distance and brought together, or simultaneously moved by the same distance and moved symmetrically, the first fixing clamp 303 and the second fixing clamp 304 are moved apart. The workpiece inserted between the fixing clamps 304 is fixed exactly at the center of the first fixing clamp 303 and the second fixing clamp 304, thereby improving the precision of the fixing position of the workpiece and the fastening force to the workpiece.

In addition, the first fixing part 20 pressurizes and fixes the left and right sides of the workpiece, and the second fixing part 30 presses and fixes both front and rear sides of the workpiece, so that the workpiece is not tilted or distorted during the process of fixing it. , the center of the workpiece is automatically and accurately aligned, which not only greatly improves machining precision when machining the workpiece by the machining unit, but also facilitates unmanned automation of the machining work.

In one embodiment, the second fixing part 30 may further include a stopper means 306 that limits the sliding distance of the second fixing clamp 304.

The stopper means 306 includes a long groove 306a and a stopper 306b.

The long groove 306a is formed at the top of the second fixing clamp 304 to a predetermined length along the longitudinal direction of the second fixing clamp 304.

The stopper (306b) is installed on the upper part of the jig body (10) to enable position adjustment, and its lower end is inserted into the long groove (306a).

Therefore, the power of the second driving means 302 is transmitted to the second fixing clamp 304 by the second power transmission means 305, and in the process of performing the sliding operation of the second fixing clamp 304, the jig body 10 Since the lower end of the stopper (306b) fixed to is inserted into the long groove (306a) of the second fixing clamp (304) that slides, the second fixing clamp (304) slides within the length of the long groove (306a). There is no interference with the stopper (306b), but the sliding distance of the second fixing clamp (304) becomes longer than the design distance due to malfunction of the second driving means (302) or damage to the second power transmission means (305). The end of the long groove 306a of the second fixing clamp 304 is caught by the stopper 306b to limit excessive sliding of the second fixing clamp 304, thereby preventing damage to the workpiece due to excessive sliding of the second fixing clamp 304. Breakage or damage can be prevented.

Figure 8 is a cross-sectional illustration showing the rotation means 104 according to another embodiment of the smart jig for processing a workpiece of the present invention, and Figure 9 is an illustration of a plan view according to another embodiment of the smart jig for processing a workpiece of the present invention. .

The description will be made with reference to FIGS. 8 and 9, but detailed descriptions of components overlapping with the above-described embodiments and components having the same reference numerals will be omitted.

In one embodiment, the jig body 10 of the present invention may further include rotation means 104.

That is, the vertical body portion 102 is rotatably installed on the horizontal body portion 101, and the rotation means 104 is installed at the lower part of the horizontal body portion 101 and has a rotation axis formed at the lower end of the vertical body portion 102. By being connected, the vertical body portion 102 can be rotated at a predetermined angle using the rotation means 104.

It is desirable to use a motor capable of forward and reverse rotation and angle adjustment as the rotation means 104, but it is not limited thereto.

Therefore, by rotating the vertical body portion 102 according to the shape of the workpiece, firm fixation in response to changes in the shape of the workpiece is possible.

Although the present invention has been described above with respect to limited embodiments, the scope of the present invention is not limited thereto, and the technical idea of the present invention and the claims below are understood by those skilled in the art in the technical field to which the present invention pertains. Various modifications and improvements made within the scope of equivalent scope will also fall within the scope of the present invention.

A: Workpiece
10: Jig body
101: Garobadibu
102: Vertical body part
103: Base plate
104: Rotating means
20: First fixing part
201: first shaft
202: First driving means
203: First fixed block
203a: Stopper
203b: Slide groove part
203c: Oil groove
204: Second fixed block
205: First power transmission means
205a: first rack gear
205b: Second rack gear
205c: 1st pinion gear
30: Second fixing unit
301: Second shaft
302: Second driving means
303: First fixing clamp
304: Second fixing clamp
305: Second power transmission means
305a: Third rack gear
305b: Fourth rack gear
305c: 2nd pinion gear
306: Stopper means
306a: Janghome
306b: stopper

Claims (5)

A jig body (10) fixed to the upper part of a table capable of moving in multiple axes provided in a machine tool;
A first fixing part (20) installed in the left and right directions on the jig body (10) to simultaneously pressurize and secure both left and right sides of the workpiece;
A second fixing part (30) installed on the jig body (10) in the front-back direction and operating together with the first fixing part (20) to simultaneously pressurize and fix both front and rear sides of the workpiece; Including, the exact center of the workpiece on the plane is automatically aligned and fixed,
The second fixing part 30 is,
A second shaft 301 installed to slide in the front-back direction on the jig body 10;
A second driving means (302) that provides power to slide the second shaft (301);
A first fixing clamp 303 that is fixed to one end of the second shaft 301 and presses and secures one side of the workpiece;
a second fixing clamp 304 that is slidably installed on the upper side of the other end of the second shaft 301 and presses and secures the other side of the workpiece;
A second power transmission means (305) transmitting power to the second fixing clamp (304) in a direction opposite to the sliding direction of the second shaft (301); and,
A stopper means (306) for limiting the sliding distance of the second fixing clamp (304); Including,
The stopper means 306 is,
A long groove (306a) formed at a predetermined length along the longitudinal direction of the second fixing clamp (304) at the top of the second fixing clamp (304);
A stopper (306b) installed on the upper part of the jig body (10) to enable position adjustment, the lower end of which is inserted into the long groove (306a); A smart jig for processing workpieces, comprising:
The method of claim 1, wherein the jig body (10) is,
A horizontal body portion 101 formed in the left and right directions so that the first fixing portion 20 is installed;
A vertical body portion 102 formed in the front-back direction so that the second fixing portion 30 is installed; A smart jig for processing workpieces, comprising:
The method of claim 1, wherein the first fixing part (20) is,
A first shaft 201 installed to slide in the left and right directions on the jig body 10;
A first driving means (202) that provides power to slide the first shaft (201);
A first fixing block 203 that is fixed to one end of the first shaft 201 and presses and fixes one side of the workpiece;
A second fixing block 204 is installed to slide on the upper side of the other end of the first shaft 201 symmetrically to the first fixing block 203 and presses and fixes the other side of the workpiece;
A first power transmission means (205) transmitting power to the second fixed block (204) in a direction opposite to the sliding direction of the first shaft (201); A smart jig for processing workpieces, comprising:
The method of claim 3, wherein the first power transmission means (205) is,
A first rack gear (205a) formed on the upper surface of the other end of the first shaft (201);
a second rack gear (205b) formed symmetrically to the first rack gear (205a) on the bottom of the second fixed block (204);
A first pinion gear (205c) installed to mesh between the first rack gear (205a) and the second rack gear (205b) to reverse the operating direction of the first shaft (201) and transmit it to the second fixed block (204). ; A smart jig for processing workpieces, comprising:
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