KR101024201B1 - auto assembling appartus of memory card switch - Google Patents

Abstract

The present invention relates to an automatic assembly device for a memory card switch, the automatic assembly device for a memory card switch according to the present invention is a device for assembling the switch in the sliding portion formed on the lower plate of the memory card, the lower plate feeder; A lower plate aligning unit for aligning the lower plate moving along the first guide rail of the lower plate feeder; A lower plate supply unit which intermittently supplies the aligned lower plate to a predetermined position; Switch feeder; A switch alignment unit for aligning the switch moving along the second guide rail of the switch feeder; A switch supply unit for intermittently supplying the aligned switches to a predetermined position; And a pressurizing part for pressing the lower plate supplied from the lower plate supply part and one side of the switch supplied from the switch supply part to couple the sliding part and the switch.

Thereby, by automating the entire assembly process, there is provided an automatic assembly device of a memory card switch that can stabilize productivity, increase daily work volume, improve productivity, and eliminate eye strain of an operator.

Memory Card, SD Card, Feeder, Alignment, Pressurization, Assembly

Description

Automatic assembling appartus of memory card switch

The present invention relates to an automatic assembling apparatus of a memory card switch, and more particularly, a micro size switch which is used as a locking means for protecting a file stored in a memory card and reciprocally slides on one side of a memory card. The present invention relates to an assembling apparatus of a memory card switch that can reduce manufacturing costs, improve product productivity, and contribute to stabilization of quality by automatically assembling.

In general, the demand for portable storage devices is rapidly increasing due to the spread of portable digital devices such as digital cameras, digital camcorders, and MP3 players. Currently, portable storage devices include flash memory based storage devices and micro drives, which are magneto-optical storage devices. The above-mentioned portable storage devices of the flash memory series may be classified into compact flash, smart media, multimedia cards, secure digital memory cards, and memory sticks. In particular, as described above, portable storage of the flash memory series Among the devices, SD memory card is expected to be a market leading portable storage device because it has superior performance compared to other products such as data transfer rate.

1 is a view illustrating a housing of a typical SD card. Referring to FIG. 1, a flash memory is mounted on a circuit board (not shown), and the circuit board (not shown) is a bottom plate (B). After being mounted in the mounting groove BG, the upper side of the lower plate B is closed by the upper plate F. At this time, the upper plate (F) and the lower plate (B) is bonded to the edge portion by ultrasonic fusion. And a sliding portion (BS) is formed on the side of the upper plate (F) or the lower plate (B) is provided with a switch (S) for manipulating the position in a sliding manner for write protection and release. In addition, a through-hole BH is formed at one end of the lower plate B to expose the connection terminal formed on the circuit board (not shown), so that the connection terminal can contact the socket of the external device. At this time, the small size (fine) switch (S) is subjected to a process that the operator is coupled to the sliding portion (BS) of the lower plate (B) through the manual operation.

However, the process of assembling the switch to the sliding portion of the lower plate through the manual work is the most difficult in the SD card manufacturing process, there was a problem that the productivity depends on the condition and skill of the operator. In addition, there is an urgent need for automation because it is an iterative process that must achieve daily workload through a fixed number of workers. In addition, since the switch coupled to the sliding part of the lower plate is minute in size, it is difficult for the worker to hold and assemble it by hand. The fatigue of the worker's eyes is accumulating.

Therefore, an object of the present invention is to solve such a conventional problem, by automating the process of assembling the switch to the sliding portion of the lower plate, it is possible to stabilize the productivity, increase the daily workload, and improve the productivity An automatic assembly device for a memory card switch is provided.

In addition, in assembling a fine size switch, it is possible to eliminate the eyestrain of the operator, and to provide an automatic assembly device for a memory card switch to improve the work efficiency.

According to the present invention, an automatic assembly device for a memory card switch for assembling the switch in the sliding portion formed on the lower plate of the memory card, the lower plate feeder for moving the lower plate is introduced along the first guide rail; A lower plate aligning unit for aligning the lower plate moving along the first guide rail; A lower plate supply unit which intermittently supplies the lower plate aligned in the lower plate alignment unit to a predetermined position; A switch feeder for moving the input switch along a second guide rail; A switch alignment unit for aligning the switch moving along the second guide rail; A switch supply unit which intermittently supplies the switches arranged in the switch alignment unit to a predetermined position; It is achieved by the automatic assembly of the memory card switch comprising a; a pressing portion for coupling the sliding portion and the switch by pressing the one side of the switch supplied from the lower plate and the switch supply from the lower plate supply.

Here, the lower plate alignment unit separates the first lower plate alignment unit for moving the lower plate moving along the first guide rail individually and the lower plate that passes through the first lower plate alignment unit into front and rear sides according to the same shape and orientation. It is preferable to include a second lower plate alignment portion for rotating in a predetermined direction.

Here, the lower plate is provided with a through-hole for a connection terminal, and at least one lower plate alignment portion of the first lower plate alignment portion and the second lower plate alignment portion includes a nozzle for injecting air, and the air is injected from the nozzle. It is preferable to change the arrangement position of the through hole in the lower plate.

The switch alignment unit may include a first switch alignment unit for individually moving a switch moving along the second guide rail and a surface coupled to the sliding unit according to the same shape and directionality of the switch passing through the first switch alignment unit. It is preferable to include a second switch alignment unit for separating and separating the position.

Here, at least one of the lower plate feeder and the switch feeder may include a vibration generating device, and the lower plate or switch input may be moved along the first guide rail or the second guide rail by vibration.

Here, at least one of the lower plate supply unit, the switch supply unit, and the pressurizing unit is preferably operated by a piston method.

According to the present invention, by automating the process of assembling the switch in the sliding portion of the lower plate, there is provided an automatic assembly device of a memory card switch that can stabilize the productivity, increase the daily work amount, and improve the productivity. In addition, there is provided an automatic assembly device for a memory card switch that can be mass-produced and reduce manufacturing costs.

In addition, in automatically assembling a fine size switch, there is provided an automatic assembly device for a memory card switch that can eliminate eye strain and improve work efficiency.

In addition, there is provided an automatic assembly device for a memory card switch that can easily be supplied with a lower plate or a switch, and can maintain a constant pressurized state to stabilize an assembly state of a switch.

Prior to the description, in the various embodiments, components having the same configuration will be representatively described in the first embodiment using the same reference numerals, and in other embodiments, different configurations from the first embodiment will be described. do.

Hereinafter, with reference to the accompanying drawings will be described in detail with respect to the automatic assembly of the memory card switch according to the first embodiment of the present invention.

In an embodiment of the present invention, the switch S formed for the prohibition or release of writing is automatically assembled to the sliding part BS formed on the lower plate B side of the SD card as shown in FIG. 1. The automatic assembly of the memory card switch will be described.

2 is a plan view showing an assembly apparatus according to an embodiment of the present invention. Referring to FIG. 2, an automatic assembly device of a memory card switch according to an embodiment of the present invention may include a lower plate feeder 1, The lower plate alignment part 2, the lower plate supply part 3, the switch feeder 4, the switch alignment part 5, the switch supply part 6, and the press part 7 are comprised.

The lower plate feeder 1 is a device which loads the lower plate B of the molded SD card and supplies the aligned lower plate B individually. Inside the lower plate feeder 1, the first guide rail 11 is formed in a spiral shape along an edge thereof to allow the lower plate B to move. Here, the lower plate feeder 1 is provided with a vibration generating device (not shown) so that the lower plate B, which is loaded inside the lower plate feeder 1 through vibration, may be aligned individually while moving along the first guide rail 11. To help.

The first guide rail 11 may be divided into a first supply rail 11a and a first alignment rail 11b. The first supply rail 11a allows the lower plate B loaded in the lower plate feeder 1 to be continuously moved. The first supply rail (11a) is formed in the shape of "L", the bottom portion is formed in the form of a plate protruding upward toward the center from the edge of the lower plate feeder (1). Then, the lower plate B may be continuously moved along the first supply rail 11a while gathering at the corner portion where the bottom portion and the side portion of the first supply rail 11a meet. In the first alignment rail 11b, the lower plate B, which has passed through the first supply rail 11a, is individually moved, and the lower plate B is aligned according to the same shape and direction by the lower plate alignment unit 2 described later. can do. In the first alignment rail (11b), the upper side is inclined toward the edge of the lower plate feeder (1), the first supporting jaw 21 is formed protruding in the lower portion of the side. The protruding first support jaw 21 is advantageously made to match the thickness of the lower plate B.

The lower plate alignment unit 2 may be aligned by rotating the lower plate B formed on the first alignment rail 11b according to the same shape and direction. In an embodiment of the present invention, the lower plate alignment unit 2 rotates the lower plate B moving along the first alignment rail 11b in the above-described first guide rail 11 in a predetermined direction so as to be individually aligned.

The lower plate alignment unit 2 may be divided into a first lower plate alignment unit and a second lower plate alignment unit. The lower plate B is individually moved along the first alignment rail 11b through the first lower plate alignment unit, and the lower plate B is individually moved through the first lower plate alignment unit through the second lower plate alignment unit. Separate and separate the back and rotate the separated bottom plate (B) in a predetermined direction. Then, in the lower plate alignment unit 2, the lower plate B is constantly aligned according to the same shape and directionality, and the aligned lower plate B is moved from the first alignment rail 11b to the lower plate supply unit 3.

In one embodiment of the present invention, the lower plate alignment unit 2 includes a first support jaw 21, a first switch bar 22, a first discharge unit 23, and a first drop unit 24. .

3 is a view schematically illustrating a portion “a” of FIG. 2, and referring to FIG. 3, a first supply rail at a portion where the first supply rail 11a and the first alignment rail 11b are connected to each other. At the end of 11a, a first switch bar 22 protrudes from the bottom of the first supply rail 11a along the moving direction of the lower plate B. As shown in FIG. The protruding first switch bar 22 is formed to be spaced apart from the side portion of the first alignment rail 11b. Then, when the lower plate B moves from the first supply rail 11a to the first alignment rail 11b, the lower plate B is turned over by the first switching bar 22 or the first alignment rail 11b. Is led to the side part. The lower plate B moved to the first alignment rail 11b is leaned on the side portion of the first alignment rail 11b and moved while being supported by the first support jaw 21. When the lower plate B moved from the first supply rail 11a is overlapped, the lower plate B is individually moved along the first alignment rail 11b by the first supporting jaw 21. The overlapping lower plate B falls into the lower plate feeder 1 to be moved along the first supply rail 11a again. Here, when the lower plate B moving the first alignment rail 11b partially overlaps, when the lower plate B moves along the first alignment rail 11b, the first support jaw 21 moves into the lower plate feeder 1. You can fall. The first supporting jaw 21 and the first switch bar 22 serve as the first lower plate alignment unit. In addition, as shown in Figure 3 by installing a nozzle (N) for injecting air at the end of the first supply rail (11a) and injecting air from the nozzle (N) toward the first supply rail (11a), The lower plate B stuck to the first supply rail 11a is disturbed, and the lower plate B moved to the first alignment rail 11b can be easily moved individually.

4 is a view schematically illustrating a portion “b” of FIG. 2. Referring to FIG. 4, a nozzle N for injecting air is installed in the first alignment rail 11b and the nozzle N is attached. In the air to blow the air toward the lower side of the first alignment rail (11b). Then, only the lower plate B with the front face is moved along the first alignment rail 11b, and the lower plate B with the rear face is dropped by the air injected from the nozzle N, and again the first supply rail 11a. To move along. In addition, the nozzle N provided as shown in FIG. 4 may drop the lower plate B, which is partially overlapped and moved. The nozzle N installed as shown in FIG. 4 serves as the first lower plate alignment part in moving the partially overlapped lower plate B individually, and the lower plate B moves along the first alignment rail. It serves as a second lower plate alignment unit in that the front and rear sides are separated.

FIG. 5 is a view schematically illustrating a portion “c” of FIG. 2. Referring to FIG. 5, a nozzle N for injecting air to the first alignment rail 11b is provided, and the nozzle N is provided. In the air to be injected along the moving direction of the lower plate (B). Then, when the through hole BH faces upward in the lower plate B where the front surface is visible, the lower plate where the front surface is visible so that the through hole BH is located on the side of the lower plate B by the air injected from the nozzle N. B) is rotated. The rotated lower plate B is moved along the first alignment rail 11b. Here, the first discharge part 23 and the first drop part 24 are formed in the side portion of the first alignment rail 11b in front of the nozzle N along the moving direction of the lower plate B. Then, when the lower plate B with the rear surface passing therethrough, the lower plate B is caused to fall to the first discharge part 23 by the air injected from the nozzle N. In addition, when the lower plate B is not rotated by the nozzle N among the lower plates B with the front surface visible, the lower plate B is allowed to fall through the first dropping portion 24 so that the front surface is visible and the through hole is located at the side. Only the bottom plate B is allowed to pass. As illustrated in FIG. 5, the nozzle N, the first discharge unit 23, and the first dropping unit 24 serve as the second lower plate alignment unit.

FIG. 6 is a view schematically illustrating a portion “d” of FIG. 2. Referring to FIG. 6, a nozzle N for injecting air is provided to the first alignment rail 11b, and the nozzle N is provided. In the air to blow the air toward the upper side of the first alignment rail (11b). Then, the front surface is visible and the through hole BH is moved to a state in which the through hole BH is positioned so that the through hole BH is positioned above the lower plate B. Here, the through hole BH of the lower plate B moving by installing a plurality of nozzles N may be positioned above the lower plate B. The lower plate B, in which the through-hole BH is positioned at the top and the front surface is visible, is moved to the lower plate supply part 3. Here, by supplying a nozzle (N) for injecting air toward the lower plate supply portion 3 in the first alignment rail (11b) it can facilitate the supply of the aligned lower plate (B). The nozzle N installed as described above may drop the lower plate B having a predetermined shape and direction into the lower plate feeder 1.

The lower plate supply unit 3 intermittently supplies the lower plate B aligned through the lower plate alignment unit 2 to a predetermined position.

10 is a view illustrating an operation state of a lower plate supply unit according to an embodiment of the present invention. Referring to FIG. 10, the lower plate supply unit 3 includes a third alignment rail 31 and a lower plate pusher 32. The first pusher driving unit 33 is configured. The third sorting rail 31 is connected to the first sorting rail 11b to sequentially stack the lower plates B aligned. The lower plate pusher 32 moves the lower plate B listed in the third alignment rail 31 by the first pusher driving unit 33 to the pressing unit 7 intermittently. At this time, the lower plate pusher 32 moves only one lower plate B listed on the third alignment rail 31, and the lower plate pusher 32 moves on the lower plate at the third alignment rail 31 while the lower plate B is moving. It closes the path | route which B moves, and prevents the lower board B from moving repeatedly. The first pusher driving unit 33 allows the lower plate pusher 32 to reciprocate while reciprocating by a piston method. The first pusher driving unit 33 may be configured to reciprocate the lower plate pusher 32. The lower plate B moved to the pressing portion 7 is seated on the lower plate positioning position BP.

The switch feeder 4 is a device in which the molded switch S is loaded, and the stacked switches S are individually supplied and aligned. The second guide rail 42 is formed in a spiral shape along the edge of the switch feeder 4 so that the switch S can move individually. Here, the switch feeder 4 is provided with a vibration generating device (not shown) so that the switch S mounted in the switch feeder 4 through the vibration may be aligned with each other while moving along the second guide rail 42. To help.

The second guide rail 42 may be divided into a second supply rail 42a and a second alignment rail 42b. The second supply rail 42a allows the switch S loaded in the switch feeder 4 to be continuously discharged. The second supply rail 42a is formed in the shape of "L", and the bottom portion is formed in the form of a plate protruding upward toward the center from the edge of the switch feeder 4. Then, the switch S may be continuously moved along the second supply rail 42a while gathering at the corner portion where the bottom portion and the side portion of the second supply rail 42a meet. In the second alignment rail 42b, the switches S passing through the second supply rail 42a are moved individually, and the switches S are aligned in the same shape and direction by the switch alignment unit 5 described later. can do.

The second alignment rail 42b allows the switch S passing through the second supply rail 42a to be individually moved. The upper side of the second alignment rail 42b is inclined toward the edge of the switch feeder 4, and the second supporting jaw 51 is formed to protrude from the lower side of the side portion. The protruding second support jaw 51 is made to coincide with the width of the switch S (the width of the surface coupled to the sliding part BS of the lower plate B or the short axis direction of the switch S corresponding thereto). It is advantageous.

The switch alignment unit 5 may be aligned by rotating the switch S formed on the second alignment rail 42b according to the same shape and direction. In one embodiment of the present invention, the switch alignment unit 5 rotates the switch S moving along the second alignment rail 42b among the above-described second guide rails 42 in a predetermined direction to align them individually.

The switch alignment unit 5 may be divided into a first switch alignment unit and a second switch alignment unit. The switch S is individually moved along the second alignment rail 42b through the first switch alignment unit, and the switch S is individually moved through the first switch alignment unit through the second switch alignment unit. Rotate in the direction or separate to separate the surface coupled to the sliding portion (BS) of the lower plate (B). Then, in the switch alignment unit 5, the switch S is constantly aligned according to the same shape and directionality, and the aligned switch S is moved from the second alignment rail 42b to the switch supply unit 6.

In one embodiment of the present invention, the switch alignment unit 5 includes a second support jaw 51, a second switch bar 52, a second discharge unit 53, and a second drop unit 54. .

FIG. 7 is a schematic view of part “e” of FIG. 2. Referring to FIG. 7, since the size of the switch S is small, the second supply rail 42 is provided at the end of the second supply rail 42a. The switch S is collected toward the corner portion of the 42a, and the switch S is individually moved to the second alignment rail 42b. Here, the switches S which are not moved to the second alignment rail 42b are dropped and moved again through the first supply rail 11a. The switch S moved to the second alignment rail 42b is individually moved without being overlapped by the second support jaw 51, and it is advantageous to be moved while leaning against the side portion of the second alignment rail 42b. Do. Here, the switch S for moving the second alignment rail 42b may be partially overlapped, but separated by vibration or dropped by the second support jaw 51 while moving the second alignment rail 42b. The switch S may be moved individually.

A switch bar such as the first switch bar 22 (see FIG. 3) described above may be installed at the end of the second supply rail 42a to reduce the amount of the switch S falling randomly. The second supporting jaw 51 serves as the first switch alignment unit.

Although not shown, a nozzle N for injecting air may be provided on the second supply rail 42a. Then, by injecting air from the nozzle N toward the second supply rail 42a, the switch S stuck on the second supply rail 42a is disturbed and moved to the second alignment rail 42b. The switch S can be easily moved individually.

FIG. 8 is a view schematically illustrating a portion “f” of FIG. 2, and referring to FIG. 8, a second switch extending upward from the second support jaw 51 on the second alignment rail 42b. Bar 52 is formed. The second switch bar 52 is spaced apart from the side portion of the second alignment rail 42b. Then, the switch S of which the longitudinal direction of the switch S and the moving direction of the switch S are vertical among the switches S moving along the second alignment rail by the second switching bar 52 is rotated to switch The longitudinal direction of the switch S can coincide with the moving direction of the switch S, and the switch S whose longitudinal direction and the moving direction coincide with the switch S rotates about an axis in the longitudinal direction of the switch S. You can. At this time, the switch S, which is vertically overlapped with the moving direction of the switch S, can be separated and moved individually. The switches S dropped to the switch feeder 4 while passing through the second switch bar 52 are again moved through the second supply rail 42a. The second switch bar 52 may serve as the first switch alignment unit in moving the switch S individually, or may act as the second switch alignment unit in rotating the switch S.

FIG. 9 is a view schematically illustrating a portion “g” of FIG. 2. Referring to FIG. 9, a support part 55 is formed on the second support jaw 51 and one side of the support part 55. In the second support jaw 51 to form a second discharge portion 53, the second side of the second alignment rail (42b) on the other side of the support portion 55 forms a second drop portion (54). Then, the switch S passing through the second switch bar 52 moves along the second supporting jaw 51, and rotates about the longitudinal axis of the switch S while passing through the supporting part 55. Can be. The switch S to be combined with the aligned bottom plate B is passed through the supporting part 55, and the remaining switches S are rotated by the supporting part 55 while being coupled with the aligned lower plate B. The shape and directionality of S) may pass through, and the switch S that does not match may fall through the second discharge part 53 and the second drop part 54. In particular, the switch S which is moved while the longitudinal direction and the moving direction of the switch S is perpendicular is dropped through the first falling part 24. The switch S passing through the supporting part 55 is aligned to face the surface coupled with the sliding part BS of the aligned lower plate B and is moved to the switch supply part 6. The dropped switches S are moved along the second supply rail 42a again in the switch feeder 4. The supporting part 55, the second discharge part 53, and the second falling part 54 serve as the second switch alignment part.

The switch supply unit 6 sequentially supplies the switches S arranged through the switch alignment unit 5 to a predetermined position.

11 is a view illustrating an operating state of a switch supply unit according to an embodiment of the present invention. Referring to FIG. 11, the switch supply unit 6 includes a fourth alignment rail 61 and a switch pusher 62. The second pusher driving unit 63 is configured. The fourth sorting rail 61 is connected to the second sorting rail 42b to sequentially stack the switches S arranged in order. The switch pusher 62 moves the switches S listed in the fourth alignment rail 61 by the second pusher driving unit 63 to the pressing unit 7 intermittently. At this time, the switch pusher 62 moves only one switch S listed on the fourth alignment rail 61, and the switch pusher 62 switches on the fourth alignment rail 61 while the switch S is moving. The path S moves is closed to prevent the switch S from moving in duplicate. The second pusher driving unit 63 allows the switch pusher 62 to reciprocate while reciprocating by a piston method. The second pusher drive section 63 only needs to be able to reciprocate the switch pusher 62. The switch S moved to the pressing portion 7 is seated in the switch positioning portion SP.

The pressurizing unit 7 is a lower plate (B) supplied from the lower plate supply unit 3 and the switch (S) supplied from the switch supply unit 6 is positioned at a predetermined position, and the lower plate (B) positioned at one side and The switch S is pressed to allow the sliding portion BS and the switch S of the lower plate B to be coupled.

12 is a view showing an operating state of the pressing unit according to an embodiment of the present invention. Referring to FIG. 12, the pressing unit 7 includes a lower determination position unit BP and a switch positioning unit SP. It is configured to include a pressure pusher 71 and the third pusher driving unit (72). The lower plate positioning position BP is seated on the lower plate B moved by the lower plate pusher 32 from the lower plate supply unit 3. In addition, the switch S is mounted on the switch S, which is moved by the switch pusher 62 from the switch supply part 6. The lower plate (B) and the switch (S) seated in this way is to face the engaging surface of the sliding portion (BS) and the switch (S) of the lower plate (B). The pressure pusher 71 presses the lower plate B and the switch S positioned at one side by the third pusher driving unit 72 so that the switch S is coupled to the sliding part BS of the lower plate B. do. In an embodiment of the present invention, the switch S is positioned below the sliding portion BS of the lower plate B, and the pressure pusher 71 presses the lower plate B from the upper side of the switch S. . The third pusher driving unit 72 allows the pressure pusher 71 to reciprocate while reciprocating by a piston method. The third pusher driving unit 72 only needs to be able to reciprocate the pressure pusher 71.

As shown in FIG. 2, the loading part 8 is formed at one side of the pressing part 7 to load the lower plate B to which the switch S is coupled. The lower plate B, to which the switch S is coupled, is pushed by the lower plate B supplied from the lower plate supply part 3 to be separated from the pressurizing part 7 (lower plate positioning position BP) to the loading part 8. Is moved. It is advantageous that the lower plate B moved to the stacking portion 8 be stacked according to the same shape and directionality.

The operation of the first embodiment of the automatic assembly apparatus of the memory card switch described above will now be described.

3 to 12, the lower plate B supplied to the lower plate feeder 1 is moved to the first alignment rail 11b via the first supply rail 11a. The lower plates B moved to the first alignment rails 11b are individually aligned according to the same shape and direction while passing through the lower plate alignment unit 2 described above. The lower plate B which is individually aligned is moved to the lower plate supply part 3, and the lower plate supply part 3 moves the lower plate B intermittently to the lower plate B at the lower plate positioning position BP of the pressurizing part 7. ) Settles down.

In addition, the switch S supplied to the switch feeder 4 is moved to the second alignment rail 42b via the second supply rail 42a. The switches S moved to the second alignment rail 42b are individually aligned according to the same shape and direction so as to correspond to the sliding portion BS of the lower plate B while passing through the switch alignment portion 5 described above. The switches S arranged individually are moved to the switch supply unit 6, and the switch supply unit 6 moves the switch S intermittently to the switch S position of the pressurizing unit 7 at the switch S. Make sure that it is seated.

When both the lower plate B and the switch S are seated on the lower plate positioning position BP and the switch fixing position SP, the engaging surface of the sliding portion BS and the switch S of the lower plate B faces each other. do. In the pressurizing part 7, the presser pusher 71 is moved by the third pusher driving part 72 to press the upper part of the sliding part BS of the lower plate B, thereby switching to the sliding part BS of the lower plate B. Let (S) be combined. Here, the lower portion of the lower positioning portion (BP) may be formed with a clearance adjusting portion (T) having elasticity. The clearance adjusting part T facilitates the coupling between the sliding part BS of the lower plate B and the switch S according to the pressurization of the pressure pusher 71, and the coupling is completed and the pressure pusher 71 returns. At this time, the lower judgment position portion BP can be returned to the original position. The lower plate B to which the switch S is coupled is subsequently pushed by the lower plate B supplied from the lower plate supply unit 3 to be separated from the lower plate positioning position BP of the pressing unit 7, and the lower plate positioning unit The lower plate B separated from the BP is stacked on the stacking portion 8. Although not shown, it is advantageous that the lower plate B to be loaded in the loading section 8 is loaded according to the same shape and orientation. The lower plate B loaded in the stacking unit 8 may be loaded and transported by a predetermined amount by hand, or automatically loaded by a predetermined quantity by applying a known technique.

It is advantageous to supply the lower plate B from the lower plate supply unit 3 to the pressing unit 7 after the coupling of the sliding portion BS and the switch S of the lower plate B in the pressing unit 7 is completed. In addition, the lower plate B, to which the switch S is coupled, is separated from the lower plate positioning position BP according to the supply of the lower plate B, which is subsequently supplied, and thus, the switch S at the switch positioning position SP. It is advantageous to supply the switch S from the switch supply part 6 to the pressurizing part 7 after the is removed.

The scope of the present invention is not limited to the above-described embodiment, but may be embodied in various forms of embodiments within the scope of the appended claims. Without departing from the gist of the invention claimed in the claims, it is intended that any person skilled in the art to which the present invention pertains falls within the scope of the claims described in the present invention to various extents which can be modified.

1 is a view showing a housing of a typical SD card,

2 is a plan view showing an assembly apparatus according to an embodiment of the present invention,

FIG. 3 is a schematic view of portion “a” of FIG. 2;

4 is a schematic view of portion “b” of FIG. 2;

FIG. 5 is a schematic view of portion “c” of FIG. 2;

FIG. 6 is a schematic view of portion “d” of FIG. 2;

FIG. 7 is a schematic view of portion “e” of FIG. 2;

FIG. 8 is a schematic view of portion “f” of FIG. 2;

FIG. 9 is a schematic view of portion “g” of FIG. 2;

10 is a view showing an operating state of the lower plate supply unit according to an embodiment of the present invention,

11 is a view showing an operating state of a switch supply unit according to an embodiment of the present invention;

12 is a view showing an operating state of the pressing unit according to an embodiment of the present invention.

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

1: lower feeder 11: first guide rail 11a: first feed rail

11b: first alignment rail 2: lower plate alignment portion 21: the first support jaw

22: first switch bar 23: the first discharge portion 24: the first falling portion

3: lower plate supply part 31: third alignment rail 32: lower plate pusher

33: first pusher supply unit 4: switch feeder 42: second guide rail

42a: 2nd supply rail 42b: 2nd alignment rail 5: Switch alignment part

51: second support jaw 52: second conversion bar 53: second discharge portion

54: second drop portion 55: support portion 6: switch supply portion

61: second alignment rail 62: switch pusher 63: second pusher driving portion

7: Pressing part 71: Pressing pusher 72: Third pusher driving part

8: loading part F: top plate B: bottom plate

S: Switch BS: Sliding part BH: Through hole

BG: Seating groove BP: Lower panel position SP: Switch position

Claims (6)

In the automatic assembly of the memory card switch for assembling the switch in the sliding portion formed on the lower plate of the memory card, A lower plate feeder which moves the lower plate to be supplied along a first guide rail; A lower plate aligning unit for aligning the lower plate moving along the first guide rail; A lower plate supply unit which intermittently supplies the lower plate aligned in the lower plate alignment unit to a predetermined position; A switch feeder for moving the input switch along a second guide rail; A switch alignment unit for aligning the switch moving along the second guide rail; A switch supply unit which intermittently supplies the switches arranged in the switch alignment unit to a predetermined position; And a pressurizing unit for pressing the lower plate supplied from the lower plate supply unit and one side of the switch supplied from the switch supply unit to couple the sliding unit and the switch. The method of claim 1, The lower plate alignment unit separates the first lower plate alignment unit for moving the lower plate moving along the first guide rail individually and the lower plate which passes through the first lower plate alignment unit into front and rear sides according to the same shape and orientation. An automatic assembly device for a memory card switch comprising a second lower determination column portion for rotating in a predetermined direction. The method of claim 2, The lower plate has a through hole for a connection terminal, and at least one of the lower plate alignment portion of the first lower plate alignment portion and the second lower plate alignment portion includes a nozzle for injecting air. And an arrangement position of the through hole in the lower plate by air injected from a nozzle. The method according to claim 1 or 2, The switch alignment unit is a position of a surface coupled to the sliding unit according to the same shape and directionality of the first switch alignment unit for moving the switch moving along the second guide rail individually, and the first switch alignment unit in the same shape and direction Automatic assembly of a memory card switch comprising a second switch alignment to separate the separation. The method of claim 4, wherein At least one of the lower plate feeder and the switch feeder includes a vibration generating device, and the inserted lower plate or the switch is automatically assembled along the first guide rail or the second guide rail by vibration. Device. The method of claim 4, wherein And at least one of the lower plate supply unit, the switch supply unit, and the pressing unit is operated by a piston method.

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