KR970011107B1 - Centering method and apparatus of fixed part in double core - Google Patents

Abstract

Disclosed is an apparatus and a method to center a component to be fixed between two sides. The apparatus comprises a location decider(10), an elevating operator(20) and a measurer(30). The location decider(10) decides location of a body at which the component is installed, and fixes the location. The elevating operator(20) elevates under the component and inserts fixers(3) to the component. The measurer(30) centers the fixers(3) between each inner side of the component. Thereby, the centering is performed with accuracy and convenience.

Description

Centering method and device of parts fixed at center of both sides

1 is an exemplary view showing a conventional centering method.

2 is a process chart of the centering method of the present invention.

3 is a front view of the centering device of the present invention.

Figure 4 is a side view of the centering device of the present invention.

5 is an enlarged sectional view of part “A” of FIG.

6 is an enlarged cross-sectional view of part “B” of FIG.

7 is a detailed view showing a measurement process of the present invention.

* Explanation of symbols for main parts of the drawings

1: main body 2: counterpart

3: fixed part 10: positioning part

20: lifting and lowering operation unit 30: measuring unit

The present invention relates to a centering method and apparatus for enabling easy and accurate centering of a part fixedly installed at a center between two inner surfaces of an arbitrary part or a product.

In general, a fixed jig is usually used to assemble two parts accurately by centering them.

However, the centering method using the fixing jig as described above is based on the premise that the dimensions of each component are constant. If the change of the dimensions of each component is not constant and the difference is large, accurate centering operation is impossible.

Therefore, in recent years, the centering method has been proposed in view of the above problems of the conventional centering method. This centering method is a 2D actuator (hereinafter referred to as "fixed part") installed in an actuator (hereinafter referred to as "relative part") of a magneto optical disk drive (MODD) as shown in FIG. It is an example of how to center the.

In such a centering method, first, the fixed part 3 in which both outer surfaces are formed in parallel is inserted through the opening of the counterpart 2 in which both inner surfaces oppose in parallel. At this time, gaps L are formed on both sides of the counterpart 2. When the fixing part 3 is inserted into the mating part 2 in this manner, the thickness gauge (G) provided for each thickness is symmetrically matched with the gap L formed on both sides of the fixing part 3. Insert it to measure the dimensions and calculate the center to set the center of the fixed part (3).

However, since the centering method of these parts has to be measured by inserting the gauges provided for each thickness and opposing each side of the gap, it takes a lot of measurement time and several gauges provided for each thickness are mixed or lost in the measuring process. There is a concern. In addition, in the process of inserting the gauge in the gap between the two sides there is a problem in contact with the parts adhered to the inner surface of the mating component and the outer surface of the fixed component impairs the function of the component.

Therefore, the conventional component centering method is not only cumbersome for work, but also has a defect in deterioration of workability and productivity efficiency. In addition, it causes defects and deterioration of the product due to damage to the components generated in the measurement process, as well as accuracy of the centering work. There was a defect such as lack.

Accordingly, the present invention has been made in view of the above-described conventional defects, and an object thereof is to provide a method and an apparatus for centering a component which is fixed at both centers to easily and accurately perform the centering operation of the component.

Technical means of the present invention for achieving this object includes a positioning means for positioning and fixing the counterpart parts; Lifting means for lifting up and down to the center of the counterpart fixed to the positioning means to insert a fixed part between both inner surfaces of the counterpart; It is characterized in that the measuring means is connected to the lower portion of the elevating means and configured to set in the center of both inner surfaces of the counterpart while moving the fixed parts inserted between both inner surfaces of the counterpart to the left and right.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings. 2 is a process diagram of the centering method of the present invention, FIG. 3 is a front view of the centering device of the present invention, and FIG. 4 is a side view of the centering device of the present invention.

A centering method of a component fixed to both centers of the present invention includes a first step of determining and fixing a position of a counterpart component (2); A second step of clamping the fixed part 3; A third step of inserting the clamped fixed part 3 between both inner surfaces of the mating part 2; A fourth step of moving the inserted fixed part 3 to one side by the spindle of the measuring means, bringing the outer surface of one side into contact with the inner surface of one side of the counterpart, and then setting the measuring means to "0"; The dimension of the clearance 1 formed in one side after moving the fixed part 3 to the other side by the measuring means set to "0" and making the other outer surface of the fixed part 3 contact with the other inner surface of the counterpart 2 Calculating a fifth step; The sixth step is performed by dividing the calculated measured value into two and setting the measuring means to coincide with the center value so as to move and fix the fixed part 3 to the center of both inner surfaces of the counterpart part 2.

In the centering apparatus for performing the centering method of the above components, as shown in FIG. 2 and FIG. 3, the position of the apparatus body 14 in which the counterpart component 2 is mounted on the upper portion of the main body 1 is fixed. The positioning unit 10 is configured to be lifted and lowered to a lower portion directly below the center of the counterpart part 2 fixed to the device body 14 of the positioning unit 10, between both inner surfaces of the counterpart part 2. Lifting operation part 20 for inserting the fixed part (3) is configured, the fixed part (3) connected to the lower part of the lifting operation part 20 and inserted between both inner surfaces of the mating part (2) The measuring unit 30 is configured to be set at both centers of the inner side of the counterpart 2 while moving the right and left), which will be described in more detail as follows.

The positioning unit 10 includes a guide block 12 and a block 13 fixedly installed at a predetermined interval on the base plate 11 on which the through hole 11A is formed, and an axis (a) in the guide block 12. 162 is coupled to the rotary plate 15 is rotated 180 degrees to the left and right by the user's operation, and on one side is detachable device body 14 is mounted, the rotary plate 15 pin ( The pin fixing portion 16 is fixed to the upper side of the block 13 by the combination of the 161, and is positioned on the other base plate 11 of the pin fixing portion 16 to rotate the rotary plate 15. A stopper 17 for blocking is configured.

The lifting and lowering operation part 20 includes a clamp 21 into which the fixed part 3 is inserted, and an auxiliary cylinder for clamping the fixed part 3 inserted into the clamp 21 by suction force by pneumatic pressure ( 22) and an air finger 23, a ball plunger 25 is built in the lower end of the bracket 24 for supporting the air finger 23, one side so that the ball plunger 25 can be in contact with the cloud The lifting and lowering pusher 26 having the inclined surface 261 formed thereon is configured, and the lifting and lowering pusher 26 protrudes outward by a predetermined length so as to be moved forward and backward by pushing and pulling the user. The pusher handle 27 is formed integrally with the 26.

The measuring unit 30 is fixed to the holder (32) on the main base (1A) of the main body 1 and the micro to display the movement amount by moving the spindle 311 back and forth by the user's tumble 312 rotation The meter 31 is configured, and the ball slide unit 33 is configured to move forward and backward with the spindle 311 of the micrometer 31 to move the lifting operation part 20 to the left and right. The connection part 35 which connects the unit 33 and the spindle 311 of the micrometer 31 is comprised.

As shown in FIG. 6, the connection part 35 includes a coupling 34 coupling the shaft 331 of the ball slide unit 33 and the spindle 311 of the micrometer 31. The backlash (BACKLASH) is applied so that the power of the spindle 311 coupled with the shaft 331 of the ball slide unit 33 by the ring 34 can be accurately transmitted to the shaft 331 of the ball slide unit 33. A pair of angular bearings 351 are formed to minimize and face each other in the open direction on the shaft 331, and as a cap 352 for fixing and supporting the angular bearings 351 from the outside. It is composed.

The following describes in detail the operation process and the resulting effects of the centering device of the present invention configured as described above.

First, the mating component 2 is fixed to the machine body 14, and then the machine body 14 is fixed to the rotary plate 15, and then the rotary plate 15 is rotated 180 degrees to block the block 13. The pin 161 is fixed to the upper side.

When the device body 14, on which the counterpart parts 2 are assembled, is fixed to the rotary plate 15 so as to face downward, the fixed parts 3 to be inserted between both inner surfaces of the counterpart parts 2 are lifted. Inserted into the clamp 21 of the lower operation unit 20 and clamped by the suction force by the pneumatic pressure of the auxiliary cylinder 22 and the air finger 23.

When the fixing part 3 is clamped as described above, when the pusher handle 27 protruding outward is pushed by hand, the lifting and lowering pusher 26 formed integrally with the pusher handle 27 moves forward with the bracket. The ball plunger 25 built in the lower end of the 24 is in contact with the cloud along the inclined surface 261 of the elevating pusher 26. At this time, the lifting and lowering operation part 20 is vertically raised to insert the fixed part 3 clamped to the clamp 21 between both inner surfaces of the mating part 2 fixed to the device body 14.

Through this process, the fixed part 3 inserted between both inner surfaces of the counterpart part 2 is moved left and right again by the user's micrometer 31 manipulation. That is, when the user rotates the dimple 312 of the micrometer 31 fixed to the holder 32 on the main base 1A to one side, the spindle 311 advances and the spindle 311 and the connecting portion ( A fixed part fixed to the clamp 21 connected to the elevating operation unit 20 is connected to the elevating operation unit 20 because the ball slide unit 33 connected to the elevating operation unit 20 is moved to the opposite side. (3) is moved to the left as shown in FIG. 7A so that the left side of the fixed part 3 is in contact with the left inner surface of the mating part 2, and the micrometer 31 is " 0 " Set to.

In this way, when the left side of the fixed part 3 is in close contact with the left inner surface of the mating part 2 and the "0" point is set, the dimple 312 of the micrometer 31 is rotated in the reverse direction to reverse the spindle 311. . At this time, the ball-slide unit 33 fixed to the connecting portion 35 and the lifting and lowering operation part 20 clamping the fixing part 3 are moved to the right, so that the fixing part ( The right side of 3) is brought into contact with the right inner side of the mating part 2.

Thus, the right side of the fixed part 3 is in contact with the right inner surface of this counterpart 2, and the clearance gap 1 formed in the right side of the fixed part 3 measured by the micrometer 31 and the right inner surface of the counterpart 2 is measured. After calculating the value obtained by dividing the size of) into two, the dimple 312 of the micrometer 31 is rotated in the forward direction so as to correspond to the center value divided by the two, so that the spindle 311 is advanced. At this time, the lifting lowering operation part 20 in which the fixed part 3 is clamped is moved to the left side, so that the center of the fixed part 3 exactly matches the center of the mating part 2 as shown in FIG. Done.

As described above, when the center C of the fixed part 3 and the counterpart part 2 coincide with each other, the fixed part 3 is assembled to the counterpart part 2, and then the fixed part is detached from the clamp 21. When the pusher handle 27 is pulled outward and the lifting and lowering pusher 26 is retracted, the clamp 21, the auxiliary cylinder 22, and the bracket 24 of the lifting operation part 20 are simultaneously lowered. Then, the pin 161 of the block 13 is released and the rotary plate 15 is rotated 180 degrees about the shaft 162 of the guide block 12 and placed on the stopper 17.

Subsequently, the device body 14 having the fixed parts 3 assembled at both inner surface centers of the counterpart parts 2 is separated from the rotary plate 15, and then the device body 14 is mounted on the rotary plate 15. Rotation and fixation of 180 degrees and the centering operation by pushing and pulling the pusher handle is repeatedly performed.

As described above, according to the present invention, the counterpart is positioned and fixed, the counterpart is lifted up and down the center of the counterpart fixed to the positioning means, and the fixed parts are inserted between both inner surfaces of the counterpart. The centering operation of the fixed part connected to the lower part of the counterpart is fixed between the inner parts of the counterpart by setting the center of the counterpart of the counterpart while moving the fixed part inserted between the inner parts of the counterpart to the left and right. The centering operation can be easily and accurately performed by calculating the measured value using a meter, and it is possible to solve the damage of the peripheral parts fixedly installed on both inner surfaces of the counterpart parts during the centering work. It will have the effect of increasing the performance and reliability of.

Claims (6)

A first step of determining and fixing the position of the counterpart component; A second step of clamping the fixed part; A third step of inserting the clamped fixed part between both inner surfaces of the mating part; A fourth step of moving the inserted process part to one side by means of the spindle of the measuring means, bringing one side outer surface into surface contact with one side inner surface of the counterpart, and then setting the measuring means to "0"; A fifth step of moving the fixed part to the other side by measuring means set to " 0 " to bring the other outer surface of the fixed part into contact with the other inner surface of the counterpart and calculating the dimension of the gap formed on one side; A sixth step of dividing the calculated measured value into two and setting the measuring means to match the center value to move and fix the fixed part to the center of both inner surfaces of the counterpart part. Centering method. A positioning unit 10 for determining and fixing the position of the device body 14 on which the counterpart 2 is mounted on the upper part of the main body 1; Lifting and lowering to lower and lower portions of the counterpart 2 fixed to the device body 14 of the positioning unit 10 to insert the fixed parts 3 between both inner surfaces of the counterpart 2. An operation unit 20; Measurement to be connected to the lower part of the elevating operation part 20 to set in the center of both inner surfaces of the counterpart parts 2 while moving the fixed parts 3 inserted between both inner surfaces of the counterpart parts 2 to the left and right. Centering device of the parts in the center of both sides, characterized in that it comprises a portion (30). According to claim 2, the positioning unit 10, the guide block 12 and the block 13 is fixed to the base plate 11 at a predetermined interval, the guide block 12 to the axis 162 The rotary plate 15 is rotated 180 degrees left and right, and the device body 14 is detachable on the bottom, and the rotary plate 15 is coupled to the pin 161 to be fixed to the upper side of the block 13. The pin fixing part 16 is configured, and the stopper 17 is positioned on the other base plate 11 of the pin fixing part 16 to stop rotation of the rotary plate 15, and fixed to both centers. Centering equipment for parts. The lifting and lowering operation unit 20 constitutes a clamp 21 into which the fixed part 3 is inserted, and the fixed part 3 inserted into the clamp 21 is sucked by pneumatic pressure. An auxiliary cylinder 22 and an air finger 23 for clamping are configured, and a ball plunger 25 is formed at the lower end of the bracket 24 supporting the upper finger 23, and the ball plunger 25 is clouded. The lifting and lowering pusher 26 is formed with an inclined surface 261 inclined to one side so as to be contacted, and protrudes outwardly by a predetermined length so that the lifting and lowering pusher 26 can be moved forward and backward by pushing and pulling the user. The centering device of the part is fixed to the center of both sides, characterized in that the pusher handle (27) integrally provided in the lifting and lowering pusher (26). The measurement unit 30 according to claim 2, wherein the micrometer 31 is formed on the main base 1A of the main body 1, and moves forward and backward together with the spindle 311 of the micrometer 31. And a ball slide unit 33 for moving the lifting and lowering operation part 20 to which the fixed part 3 is clamped left and right, and the ball slide unit 33 and the spindle 311 of the micrometer 31. Centering device of the part is fixed to the center of both sides, characterized in that the connection portion 35 is configured to connect. The connecting portion 35 is formed with a coupling 34 for coupling the shaft 331 of the ball slide unit 33 and the spindle 311 of the micrometer 31, and the shaft 311. A pair of angular bearings 351 are configured to face each other in an open direction on an angle to each other, and a cap 352 for fixing and supporting the angular bearings 351 from the outside is configured to be fixed to both centers. Centering device for parts.