KR20200052695A - Parts manufacturing apparatus and parts manufacturing system including the same - Google Patents

Abstract

The present invention relates to a component manufacturing apparatus including: a main body; a first moving member relatively movable with respect to the main body in a Z direction; a second moving member relatively movable with respect to the first moving member in an inclination direction having a predetermined inclination angle with respect to the Z direction; a first transfer unit for transferring the first moving member in the Z direction with respect to the main body; a second transfer unit for transferring the second moving member in the inclination direction with respect to the first moving member; and a processing unit coupled to one end of the second moving member to process a component, wherein the processing unit is movable in a Y direction perpendicular to the Z direction when transferred in the inclination direction. According to the present invention, a precise Y-axis position calibration with respect to the processing unit is individually performed by the second transfer unit unlike the conventional press bonding apparatus having only the transfer unit corresponding to the first transfer unit, and the second transfer unit and the second moving member are maximally erected while extending along the inclination angle, so that a width of an installation space in the Y direction is reduced.

Description

Parts manufacturing apparatus and parts manufacturing system including the same {Parts manufacturing apparatus and parts manufacturing system including the same}

The present invention relates to a device for manufacturing a component, in particular, it is possible to individually perform precise Y-axis position correction for a processing unit by a second transfer unit, wherein the second transfer unit and the second moving member are extended along an inclination angle. Since it can be erected as much as possible, it relates to a component manufacturing apparatus in which the width in the Y direction of the installation space can be reduced.

In the process of manufacturing the LCD panel used for various TVs, a TFT (thin film transistor) and a color filter (CF) are respectively produced, and a 'bonding' process is performed to combine the TFT and the color filter into one. After completing the 'scribe' process of cutting the bonded panel to fit the screen of the TV or mobile device, and injecting the liquid crystal, after completing the 'module' process, the final LCD panel is born.

Here, the 'module' process, which is performed after TFT, CF, and the panel that has been completed through liquid crystal injection, is largely composed of three processes. First, the panel is cleaned cleanly, and the second step is a process of attaching a polarizing plate to the top and bottom of the panel. , The third is the OLB (Outer Leader Bonder) process for attaching driver ICs and PCBs.

As the device used in the above OLB process, there is a pressure bonding device disclosed in Korean Patent Publication (Publication No. 10-2010-0110501, Publication Date October 13, 2010).

The conventional pressure bonding device, in order to achieve the assembly of the parts, the mounting head 20, the mounting head 20, the lifting member is capable of holding the mounting part 120, the mating part 110, the mounting part 120, and ascending and descending, at least Mounting parts after the transfer unit 30 capable of independently transporting one or more of the mounted heads 20 and the raised mount heads 20 move the mounting parts 120 in the X-axis direction to the mounting position of the parts (120) and the inspection camera 50 for measuring the precise position of the mating component 110 to which the component is to be attached, the stage 10 capable of transferring the mating component 110 in the Y-axis direction to the mounting location, the mount head ( 20) When attaching the holding part (120) held by the mating part (110), the mountable LM guide (upward 40) and the mount head (20) guide the ascending and descending movement to support the attachment of the part. 190), of the rising and falling movement of the mount head Z-axis motor 150 that generates power, and ball skews 160 that generate upward and downward movement of the mount head 20 by converting rotational movement of the Z-axis motor into linear movement, and upward and downward of the mount head 20 It is formed of a cylinder 170 that applies a set pressure when assembling the mounting part 120 to the mating part 110 through movement.

However, the conventional pressure bonding apparatus is mounted when the plurality of mount heads 20 are used at the same time because Y-axis position correction is performed by the stage 10 collectively moving the counterpart 110 in the Y-axis direction. There is a problem that it is not possible to individually perform precise Y-axis position correction for all of the plurality of mounting parts 120 having different positions.

That is, when the mount heads 20 are sequentially lowered one by one in the Z-axis direction without simultaneously transferring the plurality of mount heads 20 to the component assembly position, the stage 10 performs precise Y-axis transfer for each mount each time. There is a problem that needs to be done. Here, whenever the stage 10 is transferred, the backup 40 should descend to prevent interference with each other, and when the mount head 20 descends in the Z-axis direction to the attachment position, the counterpart 110 In order to support the problem occurs that must rise again each time.

Therefore, the conventional pressure bonding device, the backup 40 lowering time, the stage Y-direction transfer time, the re-rising time of the backup 40, the dropping time of the mound head 20, the waiting time for attaching parts, the mounting head 20 re-raising time As it consumes more, as a result, precision assembly may be possible, but the productivity is reduced by about 1 / (total number of mount heads) because the mounting parts 120 must be sequentially assembled to the counterpart 110. This method is limited to rapid mass production of LCD panels.

The present invention has been devised to solve the above problems, and its purpose is to fabricate parts with an improved structure so that precise Y-axis position correction for a processing unit can be individually performed and the Y-direction width of the installation space can be reduced. This is to provide a device.

In order to achieve the above object, a component manufacturing apparatus according to the present invention includes: a main body; A first moving member capable of moving relative to the main body along the Z direction; A second moving member capable of moving relative to the first moving member along an inclined direction having a predetermined inclination angle with respect to the Z direction; A first transfer unit capable of transferring the first moving member with respect to the body along the Z direction; A second transfer unit capable of transferring the second moving member along the inclined direction with respect to the first moving member; It is coupled to one end of the second moving member, a processing unit capable of processing a part; including, the processing unit is moved along the inclined direction, thereby moving along the Y direction perpendicular to the Z direction It is characterized by being able to.

Here, it is preferable that the processing unit may be individually moved in the Z direction or the Y direction, and may be simultaneously moved in the Z direction and the Y direction.

Here, the first moving member is formed of a triangle having the inclination angle as an interior, and the second moving member is preferably moved relative to the inclined surface of the first moving member.

Here, the first transfer unit, the first motor; A first ball screw that converts the rotational motion of the first motor into a linear motion; And a first guide guiding the first moving member along the Z direction, wherein the second transfer unit includes: a second motor; A second ball screw that converts the rotational motion of the second motor into a linear motion; It is preferable to include; a second guide for guiding the second moving member along the inclined direction.

Here, the main body, as a member extending in the vertical direction along the Z direction, a first vertical member including a protrusion formed convexly in the form of "]"; A second vertical member formed in a shape corresponding to the first vertical member and elongated vertically along the Z direction; A groove portion concavely formed in the second vertical member in a shape corresponding to the protrusion; It is preferable that the cover member having a cross section of a shape corresponding to the shape of the through hole; and a through hole formed in the form of "] between the protrusion and the groove.

Here, it may be to include a rotating device capable of rotating the processing unit about a central axis of rotation parallel to the Z direction.

Here, as a device that can be mounted by transferring the mounting part to the assembly position on the counterpart, the processing unit is mounted on the second moving member and may include a mount head capable of holding the mounting part. have.

Here, it is preferable to include a pressing device capable of moving the mount head so that the mounting part can be in close contact with the counterpart at a predetermined pressure.

Here, the pressing device preferably includes a pneumatic cylinder that can move the mount head along the Z direction.

A component manufacturing system for achieving another object of the present invention is a component manufacturing system including a plurality of the component manufacturing devices, wherein the component manufacturing device is perpendicular to the Z direction and at the same time perpendicular to the Y direction. It characterized in that it comprises a third transfer unit that can be individually transported.

Here, it is preferable that the counterpart includes a fourth transfer unit capable of transferring at least one of the X direction, the Y direction, and the Z direction.

According to the invention, the main body; A first moving member capable of moving relative to the main body along the Z direction; A second moving member capable of moving relative to the first moving member along an inclined direction having a predetermined inclination angle with respect to the Z direction; A first transfer unit capable of transferring the first moving member with respect to the body along the Z direction; A second transfer unit capable of transferring the second moving member along the inclined direction with respect to the first moving member; It is coupled to one end of the second moving member, a processing unit capable of processing a part; including, the processing unit is moved along the inclined direction, thereby moving along the Y direction perpendicular to the Z direction Therefore, unlike the conventional pressurizing apparatus having only a transfer unit corresponding to the first transfer unit, precise second Y-axis position correction for the processing unit can be individually performed by the second transfer unit. Since the transfer unit and the second moving member can be erected as far as possible along the inclination angle, there is an effect that the width in the Y direction of the installation space can be reduced.

1 is a perspective view of a component manufacturing apparatus according to a first embodiment of the present invention.
FIG. 2 is a front view of the component manufacturing apparatus shown in FIG. 1.
3 is a view showing a state in which the first moving member of the component manufacturing apparatus shown in FIG. 1 descends along the Z direction.
4 is a view showing a state in which the second moving member of the component manufacturing apparatus shown in FIG. 1 is elevated along the inclined surface of the first moving member.
5 is a view showing a state in which the second moving member of the component manufacturing apparatus shown in FIG. 1 rises along the inclined surface of the first moving member, and at the same time, the first moving member descends along the Z direction.
6 is a view showing a component manufacturing apparatus according to a second embodiment of the present invention.
7 is a view showing a component manufacturing system in which a plurality of component manufacturing apparatuses shown in FIG. 1 are mounted.

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

1 is a perspective view of a component manufacturing apparatus according to an embodiment of the present invention, and FIG. 2 is a front view of the component manufacturing apparatus shown in FIG. 1. 3 is a view showing a state in which the second moving member of the component manufacturing apparatus shown in FIG. 1 descends along the inclined surface of the first moving member.

1 to 3, the component manufacturing apparatus 100 according to the preferred embodiment of the present invention is a component manufacturing apparatus capable of transferring and mounting the mounting component P to the assembly position on the counterpart S , It is often used in the process of manufacturing the LCD panel, the driver IC, which is the mounting part (P), or the PCB, on the panel that is the counterpart (S). The component manufacturing apparatus 100 includes a main body 10, a first moving member 20, a second moving member 30, a processing unit, a first transfer unit 50, a second transfer unit 60, and a pressing device It comprises 70.

The main body 10 is a part that serves as a housing and includes a plurality of metal members.

The main body 10 has a shape extending upward and downward along the Z direction shown in FIG. 1.

The main body 10 may be linearly transferred to the left and right precisely along the X direction shown in FIG. 1 by a third transfer unit 930 to be described later.

In this embodiment, the main body 10 includes a first vertical member 13 and a second vertical member 14.

The first vertical member 13 is a member having a shape extending upward and downward along the Z direction, and includes a protrusion 131 convexly formed in a "]" shape as shown in FIG. 2.

The second vertical member 14 is formed in a shape corresponding to the first vertical member 13, and is a member having a shape extending upward and downward along the Z direction.

The second vertical member 14 is formed with a groove 141 concavely formed in a "" "shape in a shape corresponding to the protrusion 131.

The protrusions 131 and the grooves 141 are spaced apart at predetermined intervals, thereby forming a through hole 11 extending along the X direction in a cross section in the form of "]" between the protrusions 131 and the grooves 141. It is.

The cover member 12 corresponding to the shape of the through hole 11 is disposed in the through hole 11 as shown in FIG. 1.

The cover member 12 is a flat plate member for protecting a magnet (not shown) or the like of the third transfer unit 930 mounted on the second vertical member 14.

In this embodiment, the cover member 12 is coupled to one surface of the third transfer unit 930 to be described later as shown in FIG. 7.

Therefore, when the component manufacturing apparatus 100 is transferred in the X direction by the third transfer unit 930, the first vertical member 13 and the second vertical member 14 are attached to the cover member 12. It can reciprocate along the X direction without contact.

The first moving member 20 is a metal member capable of relatively linear reciprocating movement along the Z direction with respect to the main body 10.

In this embodiment, the first moving member 20 is formed in a right triangle having a predetermined inclination angle α based on the Z direction as a triangular interior. Here, the inclination angle α may be selected as a value exceeding 0 degrees and less than 180 degrees in consideration of the surrounding situation, and has a value of about 20 degrees in this embodiment.

When the inclination angle α of the first moving member 20 is 90 degrees, the first moving member 20 may have a rectangular shape.

The first moving member 20 is provided with an inclined surface 21 having the inclination angle α with respect to the Z direction.

The first moving member 20 is arranged in an inverted triangle shape so that the inclined surface 21 faces downward in the Z direction, as shown in FIG. 1.

The second movable member 30 is a metal member disposed on the inclined surface 21 of the first movable member 20, and the inclined direction parallel to the inclined surface 21 of the first movable member 20 is Accordingly, the first movable member 20 is a member capable of relatively linear reciprocating movement.

In this embodiment, the second moving member 30 is a rod-shaped metal member extending long along the inclined direction.

The processing unit is a device capable of processing the counterpart S, and means a variety of devices that are not limited in the processing method, such as a laser processing unit, a silicon coating unit, a component assembly unit, and a component mounting unit.

The processing unit is a broad processing unit that includes processing of the parts themselves and assembly between the parts.

In this embodiment, the processing unit includes a mount head 40 that can be mounted by transferring the mounting component P to an assembly position on the counterpart S.

The mount head 40 is a device capable of gripping the mounting component P, and is mounted on the lower end of the second moving member 30.

The mount head 40 may grip the mounting component P in various ways, such as vacuum adsorption, magnetic adsorption, and physical pressurization.

The first transfer unit 50 is a device capable of precisely transferring the first moving member 20 up and down along the Z direction with respect to the main body 10, and is coupled to the main body 10. .

In this embodiment, the first transfer unit 50 includes a first motor 51, a first ball skew 52 and a first guide 53.

The first motor 51 is a motor that generates rotational force by electricity and is fixed to the main body 10.

The first ball skew 52 is an apparatus for converting the rotational motion of the first motor 51 into a linear motion in the Z direction, and its configuration and operating principle are well known to those skilled in the art, so detailed descriptions thereof will be omitted.

The first guide 53 is a guide that guides the first moving member 20 along the Z direction.

In this embodiment, the first guide 53 includes a generally used LM Guide (Linear Motion Guide). Since the LM guide is well known to those skilled in the art, its configuration and operation principle are omitted.

The second transfer unit 60 is a device capable of relatively linearly transferring the second moving member 30 along the inclined direction with respect to the first moving member 20.

In the present embodiment, the second transfer unit 60 is arranged in an upright state in a state parallel to the longitudinal direction of the second moving member 30.

In the present embodiment, the second transfer unit 60 includes a second motor 61, a second ball skew 62, and a second guide 63.

The second motor 61 is a motor that generates rotational force by electricity and is fixed to the first moving member 20.

The second motor 61 is preferably arranged to be as close as possible within a predetermined distance to the first transfer unit 50, as shown in FIG.

The second ball skew 62 is a device for converting the rotational motion of the second motor 61 into a linear motion in the inclined direction, and its configuration and operation principle are well known to those skilled in the art, so a detailed description thereof will be omitted. .

The second guide 63 is a guide that guides the second moving member 20 along the inclined direction.

In this embodiment, the second guide 63 includes an LM guide (Linear Motion Guide) that is generally widely used. Since the LM guide is well known to those skilled in the art, its configuration and operation principle are omitted.

As a result, when the second transfer unit 60 is operated, the second movement member 30 is transferred along the inclined direction, so the Z-direction position movement and the Y-direction position movement of the second movement member 30 are interlocked with each other ( coupling).

Here, the Z-direction position movement amount and the Y-direction position movement amount of the second moving member 30 are determined according to the value of the inclination angle α. That is, assuming that the second moving member 30 is transported along the inclined direction by a certain distance L, the amount of movement of the position of the second moving member 30 in the Y direction is L * sin (α). The position movement amount in the Z direction of the second moving member 30 is L * cos (α).

Therefore, as the inclination angle α increases, the amount of position movement in the Y direction of the second moving member 30 increases and the amount of position movement in the Z direction decreases. Conversely, as the inclination angle α decreases, the second 2 The amount of movement in the Y direction of the moving member 30 decreases and the amount of movement in the Z direction increases.

The pressurizing device 70 is a pressurizing device capable of bringing the mounting part P into close contact with the counterpart S at a predetermined pressure, and a device capable of finely lowering the mount head 40 in the Z direction. to be.

In this embodiment, the pressing device 70 includes a pneumatic cylinder capable of moving the mount head 40 up and down in the Z direction.

As shown in FIG. 2, the pressing device 70 has an upper end connected to the lower end of the first ball skew 52 and a lower end connected to the upper end of the first moving member 20.

Therefore, when the hydraulic cylinder of the pressing device 70 operates in the extending direction, the mount head 40 may descend along the Z direction, and when the hydraulic cylinder of the pressing device 70 operates in the contracting direction The mount head 40 may rise along the Z direction.

Hereinafter, an example of a method of using the component manufacturing apparatus 100 having the above-described configuration will be described.

First, when the second transfer unit 60 and the pressing device 70 do not operate, when the first transfer unit 50 is operated, the first moving member 20 as shown in FIG. 3 ) Can go up and down linearly along the Z direction. At this time, the mounting parts P are individually precisely moved along the Z direction.

Conversely, when the first transfer unit 50 and the pressing device 70 do not operate, when the second transfer unit 60 is operated, the second moving member 30 as shown in FIG. 4 ) May be linearly elevated along the inclined direction. At this time, the mounting part P is moved only along the inclined direction, thereby simultaneously moving in the Z direction and the Y direction. Here, the amount of movement in the Z direction and the amount of movement in the Y direction of the mounting component P are determined according to the value of the inclination angle α.

Meanwhile, when the first transfer unit 50 and the second transfer unit 60 are operated in a state in which the pressing device 70 is not operated, the mount head 40 does not elevate in the Z direction, but only It is also possible to straight forward and backward only in the Y direction.

For example, while lowering the first moving member 20 in the Z direction by the first transfer unit 50, the second moving member 30 in the Z direction by the same distance by the second transfer unit 60 As shown in FIG. 5, the mount head 40 does not elevate in the Z direction, but moves linearly to the left only along the Y direction.

Conversely, while raising the first moving member 20 in the Z direction by the first transfer unit 50, the second moving member 30 by the same distance by the second transfer unit 60 in the Z direction When descending to, the mount head 40 does not elevate in the Z direction, but moves linearly to the right only along the Y direction.

As a result, the mount head 40 may move individually and independently in the Z direction or the Y direction, and may also move simultaneously in the Z direction and the Y direction.

The component manufacturing apparatus 100 having the above-described configuration includes: a main body 10; A first moving member 20 capable of moving relative to the main body 10 along a Z direction; A second moving member 30 capable of moving relative to the first moving member 20 along an inclined direction having a predetermined inclination angle α with respect to the Z direction; A first transfer unit 50 capable of transferring the first moving member 20 with respect to the main body 10 along the Z direction; A second transfer unit 60 capable of transferring the second moving member 30 along the inclined direction with respect to the first moving member 20; It is coupled to one end of the second moving member 30, a processing unit capable of processing a part; including, the processing unit is mounted head 40, by being transported along the inclined direction, the Z direction Since it can move along the Y direction perpendicular to, the mount head 40 is provided by the second transfer unit 60, unlike the conventional press-fitting device having only the transfer unit corresponding to the first transfer unit 50 Since the precise Y-axis position correction can be individually performed, the second transfer unit 60 and the second moving member 30 can be erected as much as possible along the inclination angle α, so that the installation space There is an advantage that the width in the Y direction can be reduced.

And the component manufacturing apparatus 100, the mount head 40 is configured to be able to move individually in the Z-direction or the Y-direction, and is also configured to simultaneously move in the Z-direction and the Y-direction. When a plurality of parts are mounted on the component manufacturing system 900 shown in, unlike the prior art in which the Y-axis position correction is performed by the stage moving the relative parts in the Y-axis direction collectively, a plurality of mounting parts having different assembly positions ( P) It has the advantage of being able to perform precise Y-axis position correction for all at the same time individually.

In addition, the component manufacturing apparatus 100, the first moving member 20 is formed of a triangle having the inclination angle (α) as an inner cabinet, the second moving member 30, the first moving member ( Since the relative position moves along the inclined surface 21 of 20), when the position of the second moving member 30 moves in the inclined direction, the vibration of the second moving member 30 is small, so that there is an advantage of precise transfer.

In addition, the component manufacturing apparatus 100 includes a pressing device 70 capable of moving the mount head 40 so that the mounting component P can be brought into close contact with the counterpart S at a predetermined pressure. , There is an advantage that can be attached to each other at an appropriate pressure without damaging the mounting component (P) and the mating component (S).

In addition, the component manufacturing apparatus 100, since the pressing device 70 includes a pneumatic cylinder capable of moving the mount head 40 along the Z direction, the mounting position of the pressing device 70 is selected This is relatively free, and has the advantage of being easy to move the mount head 40 up and down precisely in the Z direction.

And the parts manufacturing apparatus 100, the first transfer unit 50, the first motor 51; A first ball screw (52) for converting the rotational motion of the first motor (51) into a linear motion; It includes; a first guide 53 for guiding the first moving member 20 along the Z direction; the second transfer unit 60 includes: a second motor 61; A second ball screw 62 that converts the rotational motion of the second motor 61 into a linear motion; Since it includes; a second guide (63) for guiding the second moving member 30 along the inclined direction, the advantage of easy precision transfer of the first moving member 20 and the second moving member 30 There is this.

In addition, the component manufacturing apparatus 100, the main body 10 is a first vertical member including a protrusion 131 convexly formed in a "]" form as a member extending in the vertical direction long and vertical along the Z direction (13); A second vertical member 14 formed in a shape corresponding to the first vertical member 13 and elongated vertically along the Z direction; A groove 141 formed in the second vertical member 14 to be concave in the form of "] in a shape corresponding to the protrusion 131; A cover member 12 having a cross section having a shape corresponding to the shape of the through hole 11, including; through hole 11 formed in a "]" shape between the protrusion 131 and the groove 141 Since it can be disposed inside the through hole 11, the Y-direction thickness of the first vertical member 13 can be increased to increase the structural strength of the first vertical member 13, and the first Since the guide 53 can be disposed to the right of the Y direction as much as possible, the Y-direction position of the mount head 40 can be maintained in the same way as the conventional pressure bonding device. That is, after removing the device corresponding to the component manufacturing apparatus 100 from the conventional press bonding apparatus, there is an advantage that the conventional press bonding apparatus can be simply modified by mounting the component manufacturing apparatus 100.

Meanwhile, FIG. 6 shows a component manufacturing apparatus 200 that is a second embodiment of the present invention. The component manufacturing apparatus 200 has the same configuration and effect as the component manufacturing apparatus 100 described above, so that the differences between the two will be described below.

The component manufacturing apparatus 200 further includes a rotating device 41 capable of rotating the mount head 40 about a rotation central axis parallel to the Z direction.

The rotating device 41 is mounted between the second moving member 30 and the mount head 40 to thereby perform relative rotational movement between the second moving member 30 and the mount head 40. Occurs. The rotating device 41 may include a rotating motor, a rotating LM guide, or the like.

Since the component manufacturing apparatus 200 further includes the rotating device 41, not only the Y-direction and the Z-direction position movement of the mount head 40, but also the rotational movement around the central axis of rotation parallel to the Z-direction. There is an advantage that can be provided to the mount head 40.

And FIG. 7 shows a component manufacturing system 900 including a plurality of component manufacturing apparatuses 100. The component manufacturing system 900 may be used in an Outer Leader Bonder (OLB) process of attaching a driver IC or PCB as a mounting component (P) on a panel as a counterpart (S) when manufacturing an LCD panel.

The component manufacturing system 900 includes a main body 910, a support member 920, a third transfer unit 930, a top plate 940, and a fourth transfer unit 950.

The main body 910 is provided in a square flat plate shape so as to support the support member 920.

The support member 920 is disposed on the main body 910, and is a member extending upward from the main body 910, and a pair is provided and disposed at two corner portions of the main body 910, respectively.

The third transfer unit 930 is a transfer unit capable of individually transferring each of the component manufacturing apparatuses 100 along the X direction perpendicular to the Z direction and the Y direction.

The third transfer unit 930 is elongated along the X direction, and both ends are supported by the upper ends of the pair of support members 920.

The third transfer unit 930 includes a plurality of linear motors capable of individually transferring the component manufacturing apparatus 100.

The linear motor includes a mover, a stator, an LM guide, and the like, and its configuration and effects are well known to those skilled in the art, so a detailed description thereof will be omitted.

The upper plate 940 is a member that supports and supports the counterpart S horizontally.

The fourth transfer unit 950 is a transfer unit for transferring the top plate 940, and is capable of transferring both the X direction and the Y direction and the Z direction.

Therefore, the relative component S can be freely moved in three axes by the fourth transfer unit 950.

The component manufacturing system 900 is a component manufacturing system including a plurality of the component manufacturing apparatuses 100, wherein the component manufacturing apparatus 100 is perpendicular to the Z direction and at the same time perpendicular to the Y direction. Since it includes a third transfer unit 930 that can be individually transported along, it is possible to independently control the position of each of the component manufacturing apparatus 100 by three-axis transfer of each of the component manufacturing apparatuses 100 There is this.

In addition, since the component manufacturing system 900 includes a fourth transfer unit 950 capable of transferring the counterpart S in both the X direction and the Y direction and the Z direction, the mounting component ( Apart from the transfer of P), there is an advantage in that the relative component S can be precisely three-axis transferred.

In the present embodiment, the first transfer unit 50 and the second transfer unit 60 include a ball screw, but instead of the ball screw, may be configured to include a transfer device such as a pneumatic cylinder, a linear motor, or a geared belt. Of course it is possible.

In this embodiment, although the inclination angle α forms approximately 20 degrees, instead, the case where the inclination angle α forms 90 degrees may be considered, in which case the second transfer unit 60 is Since it is in the form of a cantilever perpendicular to the first transfer unit 50, there is a problem in that space is limited in the Z direction and the Y direction. In addition, when the inclination angle α forms 90 degrees, vibration problems caused by an increase in the inertia force of the second transfer unit 60 when moving in the X direction, problems in motor-related wiring, and the like may occur.

In this embodiment, the second transfer unit 60 is disposed in an upright state in a state parallel to the longitudinal direction of the second moving member 30, but the second transfer unit 60 and the first transfer It is also possible to consider a method of arranging the units 50 in parallel and vertically. In this case, a vertical horizontal power converter, such as a worm wheel gear or a bevel gear, may be mounted at the bottom of the second motor 61 to realize position movement in the Y direction. In this way, the problem of space constraints may be alleviated somewhat, but since a power conversion device (not shown) for converting vertical power to horizontal power needs to be added, there may be a problem in that the feed precision is reduced due to backlash. .

The present invention has been described above, but the technical scope of the present invention is not limited to the contents described in the above-described embodiments, and the equivalent configuration modified or changed by a person having ordinary knowledge in the relevant technical field is technical of the present invention. It is clear that it is within the scope of thought.

＊ Explanation of codes for main parts of the drawing
100, 200: parts manufacturing equipment
10: main body
11: through hole
12: cover member
13: first vertical member
14: second vertical member
20: first moving member
21: Slope
30: second moving member
40: mount head
41: rotator
50: first transfer unit
51: first motor
52: first ball skew
53: first guide
60: second transfer unit
61: second motor
62: second ball skew
63: second guide
70: pressurization device
131: protrusion
141: home
900: parts manufacturing system
910: main body
920: support member
930: third transfer unit
940: top
950: fourth transfer unit

Claims (11)

main body;
A first moving member capable of moving relative to the main body along the Z direction;
A second moving member capable of moving relative to the first moving member along an inclined direction having a predetermined inclination angle with respect to the Z direction;
A first transfer unit capable of transferring the first moving member with respect to the body along the Z direction;
A second transfer unit capable of transferring the second moving member along the inclined direction with respect to the first moving member;
It is coupled to one end of the second moving member, a processing unit capable of processing a part; includes,
The processing unit, by being transported along the inclined direction, parts manufacturing apparatus characterized in that it can move in the Y direction perpendicular to the Z direction According to claim 1,
The processing unit, the component manufacturing apparatus characterized in that it can be individually moved in the Z-direction or the Y-direction, and can be simultaneously moved in the Z-direction and the Y-direction According to claim 1,
The first moving member is formed of a triangle having the inclination angle as an interior,
The second moving member, the component manufacturing apparatus characterized in that the relative position movement along the inclined surface of the first moving member According to claim 1,
The first transfer unit includes a first motor; A first ball screw that converts the rotational motion of the first motor into a linear motion; It includes; a first guide for guiding the first moving member along the Z direction;
The second transfer unit includes a second motor; A second ball screw that converts the rotational motion of the second motor into a linear motion; And a second guide guiding the second moving member along the inclined direction. According to claim 1,
The main body,
A member extending in the vertical direction along the Z direction, the first vertical member including a protrusion formed convexly in the form of "]";
A second vertical member formed in a shape corresponding to the first vertical member and elongated vertically along the Z direction;
A groove portion concavely formed in the second vertical member in a shape corresponding to the protrusion;
It includes; through the hole formed in the """form between the protrusion and the groove;
Component manufacturing apparatus characterized in that the cover member having a cross section of a shape corresponding to the shape of the through-hole can be disposed in the through-hole According to claim 1,
And a rotating device capable of rotating the processing unit about a central axis of rotation parallel to the Z direction. According to claim 1,
As a device that can be mounted by transferring the mounting part to the assembly position on the other part,
The processing unit is mounted to the second moving member, the component manufacturing apparatus characterized in that it comprises a mount head capable of gripping the mounting component The method of claim 7,
And a pressing device capable of moving the mount head so that the mounting part can be brought into close contact with the counterpart at a predetermined pressure. The method of claim 8,
The pressing device, parts manufacturing apparatus characterized in that it comprises a pneumatic cylinder that can move the mount head along the Z direction A component manufacturing system comprising a plurality of component manufacturing devices according to any one of claims 1 to 9,
And a third transfer unit capable of individually transferring the component manufacturing apparatus along the X direction perpendicular to the Z direction and perpendicular to the Y direction. The method of claim 10,
And a fourth transfer unit capable of transferring the counterpart relative to at least one of the X-direction, the Y-direction and the Z-direction.

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