KR101795660B1 - Led lens straight feeder - Google Patents

Abstract

The present invention relates to a straight supply device of a lens for an LED chip. Particularly, since the lens for an LED chip having four legs arranged on a lower surface in a rectangular shape can be arranged and transported identically in one direction. In the straight supply device of the lens for an LED chip of the present invention, a profile portion is protruded from the straight track. The lens is rotated by having the profile portion hold the legs of the moving lens so that the legs of the lens are arranged in a certain direction and moving.

Description

LED LENS STRAIGHT FEEDER < RTI ID = 0.0 >

The present invention relates to a linear feed device for an LED chip lens, and more particularly to a linear feed device for an LED chip lens capable of uniformly arranging and transporting LED chips having four legs arranged in a rectangular shape on a lower surface in one direction will be.

A parts feeder is widely known as a device for adjusting a small component to a predetermined predetermined direction and posture and transferring it to the next process.

The component feeder includes a bowl feeder in which the components move along a circular trajectory and a straight feeder that linearly moves in one direction. The vibration generator is coupled to the bowl feeder and the rectilinear feeder, .

On the other hand, an LED (Light Emitting Diode) used in electronic products is a type of light emitting device that uses a semiconductor that converts electricity into light, and is also referred to as a light emitting diode.

Since the LED chip is smaller than conventional light sources, has a long life span, consumes less power, and has a high response speed, it is used in various fields such as display lamps, numeric display devices, and backlights of various electronic devices.

At this time, the LED chip is mounted on the PCB substrate, and the lens is coupled to the upper side of the substrate to form a lightweight material module. Assembly of such a lens is a part where automation is required to improve productivity.

The lens has a top surface protruding in a dome shape, and a plurality of legs protruding from the bottom surface for assembly.

When the plurality of legs mounted on the lower surface of the lens are arranged at regular intervals, there is no great problem with respect to the directionality of the lens. However, when the plurality of legs have different intervals or the arrangement is different, The orientation and arrangement of the legs formed is important.

When the lower surface of the lens is protruded or the leg is short, it is difficult to align and feed the lens in a certain direction because the length of the leg is hooked on the latching jaw formed on the bowl feeder is short.

Particularly, a lens supply device for continuously transferring a lens in which the legs are arranged in a predetermined direction is continuously transported has not been developed until now, .

Patent Publication No. 10-2013-0000878 Registration No. 10-1641623

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide an LED chip having four legs arranged in a rectangular shape on a lower surface thereof, It is an object of the present invention to provide a straight supply device for a lens for an LED chip which can be easily transported.

In order to accomplish the above object, according to one aspect of the present invention, there is provided a straight supply device for an LED chip lens, which transports a transparent lens having four legs protruding from a lower surface thereof and having a convex dome shape, A straight track having a bottom surface and side walls protruding from both sides of the bottom surface and having a traveling path through which the lens advances in the space between the bottom surface and the side wall; And a drive member mounted on a lower portion of the linear track and moving the lens forward by applying vibration to the linear track to move the lens on the linear track forwardly, The distance between the inside of the first leg and the inside of the second leg, the distance between the inside of the third leg and the inside of the fourth leg are the same first interval The distance between the inside of the first leg and the inside of the fourth leg, the distance between the inside of the second leg and the inside of the third leg is the same, and the first distance is longer than the second distance A guide groove is formed on the bottom surface to move the leg, and a profile portion is formed along the periphery of the guide groove on the bottom surface, Walking is characterized in that so that the legs of the lens array while moving in a predetermined direction by the lens so as to be rotated.

The height of the profile portion is equal to or lower than the leg length.

Wherein the profile portion includes: a first locking protrusion protruding from one side of the guide groove in a direction perpendicular to the moving direction of the lens; A second locking protrusion protruding from one side of the guide groove in a direction perpendicular to a moving direction of the lens, the second locking protrusion being spaced from the rear of the first locking protrusion; A rotation groove formed between the first engaging projection and the second engaging projection; A first guide protrusion formed on the rear of the second locking protrusion; And a second guide protrusion formed elongated on the other side of the guide groove which is opposite to the first engaging protrusion, the second engaging protrusion and the first guide protrusion, And then moves along the first guide protrusion and the second guide protrusion while being arranged in a predetermined direction.

The distance between the first engaging protrusion and the second engaging protrusion is formed to be larger than the first gap, and the first gap and the second gap are formed to be larger than the protrusion length of the first engaging protrusion.

The first engaging projection is further projected in the second guide projection direction than the second engaging projection.

And the width of the first locking protrusion disposed in the moving direction of the lens is smaller than the second gap.

The first guide projection includes a first inclined portion disposed adjacent to the second engaging projection; And a first rectilinear portion extending from the first inclined portion, the second guide protrusion includes a second inclined portion formed on the opposite side of the first and second locking protrusions; And a second rectilinear portion extending from the second inclined portion, wherein a distance between the first rectilinear portion and the second rectilinear portion is smaller than the first spacing and equal to or larger than the second spacing.

And a cover member coupled to an upper surface of the straight track to cover an upper portion of the traveling path, wherein a height of the profile portion is larger than a distance between a lower surface of the cover member and an upper surface of the lens.

A width adjuster is formed on a sidewall of the straight track, and the width of the travel path is varied by the width adjuster.

Wherein the width adjuster comprises: a slider disposed on the sidewall so as to be movable in a direction perpendicular to the moving direction of the lens; And a fixing member for fixing the slider to the side wall.

The straight track is inclined so that the first guide projection is disposed below the second guide projection.

According to the rectilinear feeding device of the LED chip lens of the present invention as described above, the following effects can be obtained.

When the lens for LED chip having four legs arranged in a rectangular shape on a lower surface is to be moved in one direction, the legs can be arranged in a certain direction and the lens in the same state can be easily transferred to the next process.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a side view of a straight supply device for an LED chip lens according to an embodiment of the present invention;
FIG. 2 is a perspective view of a linear track and a lens of a straight supply device for an LED chip lens according to an embodiment of the present invention,
FIG. 3 is a plan view of the LED chip according to the embodiment of the present invention,
4 is a front view of the LED chip according to the embodiment of the present invention in a state in which the lens is mounted on a straight track of the linear feeding device.
FIG. 5 and FIG. 6 are a process diagram showing a movement path of a lens moving along a straight-ahead track of a linear-feeding device of an LED chip lens according to an embodiment of the present invention.

The linear feed device for the LED chip lens of the present invention feeds the dome-shaped circular LED chip lens 40 in a straight direction in one direction so as to feed the straight-forward track 10, as shown in Figs. 1 to 4, A driving member 20, and a cover member 30. As shown in Fig.

The lens 40 has four legs 41 protruding from the bottom surface thereof and a convex dome-shaped top surface. The lens 40 is made of a transparent material for reflecting and refracting light.

The leg 41 of the lens 40 is composed of a first leg L1 and a second leg L2, a third leg L3 and a fourth leg L4 and is arranged in a rectangular shape.

The distance between the inside of the first leg L1 and the inside of the second leg L2 and the distance between the inside of the third leg L3 and the inside of the fourth leg L4 are the same, Respectively.

The distance between the inside of the first leg L1 and the inside of the fourth leg L4 and the distance between the inside of the second leg L2 and the inside of the third leg L3 are the same D2).

The first gap D1 is longer than the second gap D2 so that the four legs 41 are arranged in a rectangular shape.

The lens 40 is formed as a circular dome as a whole, and the lower surface of the lens 40 may be flat or slightly convexly protruded.

The straight track 10 is composed of a bottom surface 11 and side walls 12 protruding from both sides of the bottom surface 11.

Therefore, the cross section of the straight track 10 is formed in a substantially ┛ ┛ shape.

A traveling path 13 in which the lens 40 moves forward is formed in the linear track 10 between the bottom surface 11 and the side wall 12.

The driving member 20 is mounted on the lower portion of the linear track 10 and vibrates the linear track 10 so that the lens 40 mounted on the linear track 10 is moved forward.

A guide groove 14 is formed on the bottom surface 11 of the linear track 10 to allow the leg 41 to move.

A profile portion 15 is protruded from the bottom surface 11 along the periphery of the guide groove 14.

The profile portion 15 is configured to allow the legs 41 of the lens 40 to move so that the lens 40 is rotated by the moving path 13, So as to be moved.

The height X4 of the profile portion 15 is equal to or lower than the length X3 of the leg 41 as shown in FIG.

Preferably, the height X4 of the profile portion 15 is formed to be slightly smaller than the length X3 of the legs 41. [

Therefore, the leg 41 of the lens 40 moves while contacting the bottom surface 11, and the height of the profile portion 15 is less than the length X3 of the leg 41 The lower surface of the lens 40 is moved away from the upper surface of the profile portion 15.

The profile portion 15 as described above has a first locking protrusion 15a, a second locking protrusion 15b, a rotation groove 15c, a first guide protrusion 15d and a second guide protrusion 15e ).

The first locking protrusion 15a protrudes from one side of the guide groove 14 to the other side of the guide groove 14 perpendicular to the moving direction of the lens 40. [

The second locking protrusion 15b is formed to be spaced apart from the first locking protrusion 15a at the rear of the first locking protrusion 15a so that the movement of the lens 40 from one side of the guide groove 14 And is protruded in the other direction of the guide groove 14 which is perpendicular to the direction of the guide groove 14.

The rotation grooves 15c are formed between the first locking protrusions 15a and the second locking protrusions 15b which are spaced apart from each other.

That is, the first locking protrusions 15a and the second locking protrusions 15b are separated from each other by the rotation grooves 15c.

The first engaging projection 15a and the second engaging projection 15b are formed to be inclined forward toward the direction in which the lens 40 is incident.

The first guide protrusion 15d is formed to be long in the longitudinal direction of the straight track 10 from the rear of the second locking protrusion 15b.

The second guide protrusion 15e extends from the other side of the guide groove 14 opposite to the first engaging protrusion 15a, the second engaging protrusion 15b and the first guide protrusion 15d, As shown in Fig.

The leg portion 41 of the lens 40 moving in the moving path 13 is guided to the first engaging projection 15a and / or the second engaging projection 15b by the profile portion 15 as described above. And then moves rearward along the first guide protrusion 15d and the second guide protrusion 15e while being arranged in a predetermined direction.

In the present invention, the second interval D2, which is the distance between the legs 41 of the lens 40, is narrower than the first distance D1 so as to be directed in the front-rear direction of the rectilinear track 10 To move backward.

To this end, the distance X1 between the first locking protrusion 15a and the second locking protrusion 15b is formed to be larger than the first gap D1 having a wide gap.

In addition, the first distance D1 and the second distance D2 are formed to be larger than the protruding length of the first latching protrusion 15a.

The legs 41 of the lens 40 disposed adjacent to the first guide protrusion 15d can be moved in a state in which the first gap D1 of the lens 40 is arranged to move rearward, The second spacing D2 of the lens 40 can be arranged to be rearward while rotating while moving on both the first and second locking projections 15a and 15b.

In a state in which the second gap D2 of the lens 40 is slightly inclined while moving rearward, the legs 41 of the lens 40 disposed adjacent to the first guide projection 15d Is engaged with the second locking protrusion 15b in a state where the first locking protrusion 15a is engaged with the first locking protrusion 15a and the other leg 41 is inserted into the rotation groove 15c, 40 may be arranged to face rearward.

The first engaging projection 15a is further projected in the direction of the second guide projection 15e than the second engaging projection 15b.

Accordingly, the lens 40 can be rotated more easily and the rotated state can be maintained.

The width of the first engaging projection 15a arranged in the moving direction of the lens 40 is smaller than the second distance D2.

Accordingly, even if the legs 41 of the lens 40 are arranged in any direction, the lens 40 can be easily rotated so that the second gap D2 is disposed rearward.

The first guide protrusion 15d includes a first inclined portion 15d1 disposed adjacent to the second engaging protrusion 15b and a first rectilinear portion 15d2 extending from the first inclined portion 15d1, .

The second guide projection 15e includes a second inclined portion 15e1 formed on the opposite side of the first engaging projection 15a and the second engaging projection 15b and a second inclined portion 15e1 extending from the second inclined portion 15e1 And a second rectilinear section 15e2 formed thereon.

The distance between the first rectilinear section 15d2 and the second rectilinear section 15e2 is smaller than the first distance D1 and is equal to or slightly larger than the second distance D2.

Therefore, the lens 40 is moved in the first rectilinear section 15d2 and the second rectilinear section 15e2 in a state in which the lens 40 is rotated so that the second gap D2 is directed to the front and rear direction, Can be moved backward while maintaining the state in which the second gap D2 is directed in the forward and backward directions in a stable state without any further rotation.

The cover member 30 is coupled to the upper surface of the straight track 10 to cover the upper portion of the moving path 13. [

The cover member 30 prevents the lens 40 moving along the moving path 13 from being upwardly projected from the profile portion 15 by the vibration generated in the driving member 20 .

4, the height X4 of the profile portion 15 is larger than the distance X2 between the lower surface of the cover member 30 and the upper surface of the lens 40. As shown in FIG.

A width adjusting portion 17 is formed on the side wall 12 of the straight track 10.

The distance of the width of the traveling path 13 is varied by the width adjusting section 17. [

The width adjusting unit 17 includes a slider 17a disposed on the side wall 12 so as to be movable in a direction perpendicular to the moving direction of the lens 40, (Not shown).

The slider 17a is formed with a long hole and the fixing member 17b is formed of a screw or the like and is pressed in a state of being inserted into the long hole so that the slider 17a, 17a to the side wall 12.

When the diameter of the lens 40 is changed by the width adjusting unit 17 as described above, the slider 17a is moved so that the lens 40 is rotated while moving along the profile 15 .

The straight track 10 may be arranged horizontally or may be inclined such that the first guide protrusion 15d is disposed below the second guide protrusion 15e.

As the rectilinear track 10 is inclined as described above, the legs 41 of the lens 40 are more in contact with the first engaging projection 15a and / or the second engaging projection 15b and rotate, The legs 41 can be arranged more easily in one direction when the lens 40 is moved.

Hereinafter, an operation process of the present invention having the above-described configuration will be described.

5, when the narrow second gap D2 is disposed so as to be inclined rearward, for example, the second leg L2 disposed rearward in the drawing is arranged slightly inclined, A case where one leg L1 is disposed above the second leg L2 and the third leg L3 is placed below the second leg L2 will be described.

And the first leg L1 is engaged with the first locking projection 15a.

Then, the lens 40 moves while rotating, and the second leg L2 is brought into contact with the upper surface of the second locking protrusion 15b.

Accordingly, the lens 40 is disposed such that the second gap D2 faces backward.

In this state, when the driving force is continuously applied to the lens 40 by the driving member 20, the leg 41 of the lens 40 is guided by the first guide projection 15d and the second guide And moves rearward along the projection 15e while maintaining the state.

This is because the distance X1 between the first guide protrusion 15d and the second guide protrusion 15e is the distance between the inside of the first leg L1 and the inside of the second leg L2 When the second leg L2 of the lens 40 is brought into contact with the upper surface of the second engaging protrusion 15b, the lens 40 moves without any further rotation.

6, when the large first gap D1 is disposed so as to be inclined rearward, the first legs L1 disposed rearward as shown in the figure are slightly The second leg L2 is disposed lower than the first leg L1 and the fourth leg L4 is disposed in a state of being disposed above the first leg L1 see.

And the fourth leg L4 is engaged with the first locking protrusion 15a.

Then, the lens 40 is moved while rotating, and the first leg L1 is inserted into the rotation groove 15c to be caught by the second locking protrusion 15b.

The lens 40 is rotated around the first leg L1 as the rectilinear force is continuously applied to the lens 40 by the driving member 20 so that the first leg L1 Is moved on the second locking protrusion 15b.

Accordingly, the lens 40 is disposed such that the second gap D2 faces backward.

In this state, when the driving force is continuously applied to the lens 40 by the driving member 20, the leg 41 of the lens 40 is guided by the first guide projection 15d and the second guide And moves rearward along the projection 15e while maintaining the state.

In the case where the legs 41 are arranged differently, as shown in FIG. 5 and FIG. 6, the legs 41 are always rotated and arranged in a predetermined direction.

According to the present invention as described above, when the LED chip lens 40 having four legs 41 arranged in a rectangular shape on the lower surface is to be moved in one direction, the legs 41 are arranged in a certain direction, The lens 40 can be easily transferred to the next process.

The straight supply device for the LED chip lens of the present invention is not limited to the above-described embodiment, but can be variously modified within the scope of the technical idea of the present invention.

The present invention relates to an apparatus and a method for manufacturing the same and a method for manufacturing the same. A first guide projection 15d1 a first guide portion 15d2 a first guide portion 15e a second guide projection 15e1 a second guide portion 15e2 a second guide portion 17a a width adjuster 17a a slider, 17b: fixing member,
20: driving member,
30: cover member,
L4 is a leg, L1 is a first leg, L2 is a second leg, L3 is a third leg, L4 is a fourth leg,
D1: first interval, D2: second interval.
X1: distance between the first engaging protrusion and the second engaging protrusion
X2: distance between the lower surface of the cover member and the upper surface of the lens
X3: Length of leg
X4: height of profile section

Claims (11)

delete delete And a transparent lens having a convex dome shape on an upper surface thereof and having four legs protruded on a lower surface thereof,
A straight track having a bottom surface and side walls protruding from both sides of the bottom surface and having a traveling path through which the lens advances in the space between the bottom surface and the side wall;
And a driving member mounted on a lower portion of the straight track for applying a vibration to the straight track to move the lens mounted on the straight track forward,
The leg of the lens is composed of a first leg, a second leg, a third leg and a fourth leg,
The distance between the inside of the first leg and the inside of the second leg, the distance between the inside of the third leg and the inside of the fourth leg,
The distance between the inside of the first leg and the inside of the fourth leg, the distance between the inside of the second leg and the inside of the third leg,
Wherein the first interval is longer than the second interval,
Wherein a guide groove is formed on the bottom surface to move the leg,
A profile portion protruding from the bottom surface along the periphery of the guide groove,
The height of the profile portion is equal to or lower than the length of the leg,
Wherein the profile portion is configured to move the legs of the lens while being arranged in a predetermined direction by causing the lens to rotate by hooking the legs of the moving lens,
Wherein the profile section comprises:
A first locking protrusion protruding from one side of the guide groove in a direction perpendicular to the moving direction of the lens;
A second locking protrusion protruding from one side of the guide groove in a direction perpendicular to a moving direction of the lens, the second locking protrusion being spaced from the rear of the first locking protrusion;
A rotation groove formed between the first engaging projection and the second engaging projection;
A first guide protrusion formed on the rear of the second locking protrusion;
And a second guide protrusion formed on the other side of the guide groove, which is opposite to the first engaging protrusion, the second engaging protrusion and the first guide protrusion,
Wherein the legs of the moving lens move along the first guide protrusions and the second guide protrusions while being arranged in a predetermined direction after being rotated by being hooked on the first or second locking protrusions. Device. The method of claim 3,
Wherein a distance between the first engaging projection and the second engaging projection is larger than the first distance,
Wherein the first gap and the second gap are formed to be larger than a protrusion length of the first latching protrusion. The method of claim 3,
Wherein the first protrusion protrudes further in the second guide projection direction than the second protrusion protrusion. The method of claim 3,
Wherein a width of the first latching protrusion disposed in a moving direction of the lens is smaller than the second interval. The method of claim 3,
The first guide projection
A first inclined portion disposed adjacent to the second engaging projection;
And a first rectilinear portion extending from the first inclined portion,
The second guide projection
A second inclined portion formed on a side opposite to the first engaging projection and the second engaging projection;
And a second rectilinear portion extending from the second inclined portion,
Wherein the distance between the first rectilinear section and the second rectilinear section is smaller than the first distance and larger than or equal to the second distance. The method of claim 3,
And a cover member coupled to an upper surface of the straight track to cover an upper portion of the moving path,
Wherein the height of the profile portion is larger than the distance between the lower surface of the cover member and the upper surface of the lens. The method of claim 3,
A width adjuster is formed on the side wall of the straight track,
And the distance of the width of the traveling path is varied by the width adjusting unit. delete The method of claim 3,
Wherein the linear track is inclined so that the first guide protrusion is located below the second guide protrusion.

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