KR101562352B1 - Apparatus for feeding spring with being separated - Google Patents

Abstract

The present invention provides an apparatus to feed a spring which is separated. The apparatus comprises: a bowl unit having a body which generates vibration, and a spiral track installed in an upper surface of the body; an injection unit having an injection port exposed to the outside through the spiral track, injecting air to a spring placed on the spiral track through the injection port; and a limiting unit formed to cover an upper side of the injection port, limiting a flight range of the spring when the spring flies up by the means of air.

Description

[0001] APPARATUS FOR FEEDING SPRING WITH BEING SEPARATED [0002]

The present invention relates to an apparatus for separately supplying a spring.

Generally, a feeder is used to feed the spring to the assembly table. This feeder applies a spring to the center and causes the spring to be fed to the assembly table while moving along a path provided at the edge.

However, when the springs are overlapped and tangled, the springs can not be normally divided and moved. In this case, even if the operation of the feeder is made strong, the engagement of the springs can not be released.

At this time, it is inevitable that the spring must be disengaged by the human hand. As a result, the operation rate is lowered, labor costs are increased, and the like.

Japanese Patent Application Laid-Open No. 2000-034015 (2000.02.02)

It is an object of the present invention to provide an apparatus for separately supplying a spring, which can solve the problem that the springs can not be fed one by one due to the tangled joints, through the configuration of the feeder itself.

According to an aspect of the present invention, there is provided an apparatus for separating and supplying a spring, comprising: a bowl unit having a body for generating vibration and a spiral track provided on an upper surface of the body; An ejection unit having an ejection port exposed to the outside through the spiral track and configured to eject air to the spring located in the spiral track through the ejection port; And a limiting unit which is formed to surround the upper side of the jetting port and limits the flying range of the spring when the air is blown by the air.

Here, the helical track may include a sliding hill starting from the nozzle following the nozzle, extending along the advancing direction of the spring, and having the highest portion after the nozzle.

Here, the sliding hill may have an inclined surface that forms an acute angle with respect to the traveling direction of the spring.

Here, the injection port may be installed in the body so as to be parallel to the inclined surface.

Here, the spiral track may include a partition wall that forms a plurality of lanes along a width direction that intersects with a traveling direction of the spring.

Here, the bowl unit may include: a linear track arranged to correspond to any one of the plurality of lanes; And a guide member formed to be inclined toward the linear track corresponding to the rest of the plurality of lanes and to guide the spring discharged from the remainder to the linear track.

Here, the restriction unit may include: a cover formed to surround the injection port; And a rotating plate rotatably coupled to the inner surface of the cover and positioned to be rotated by air injected from the jetting port.

Here, the cover may include a discharge hole for discharging the air ejected from the ejection orifice.

According to the apparatus for separating and supplying the spring according to the present invention configured as described above, it is possible to solve the problem that the springs are tangled with each other and can not be properly supplied through the configuration of the supply device itself.

Thereby, it is possible to solve the problem of the decrease in the operation rate of the supply device due to the problem of the tangling of the spring and the problem of the additional input of the attraction force.

1 is a perspective view showing an apparatus 100 for separating and supplying a spring according to an embodiment of the present invention.
2 is a plan view showing an apparatus 200 for separately supplying a spring according to another embodiment of the present invention.
Fig. 3 is a cross-sectional view taken along line III-III in Fig. 2. Fig.
4 is a conceptual cross-sectional view showing a state before the injection unit 230 is activated in the restriction unit 250 of FIG.
5 is a conceptual cross-sectional view showing the state in which the injection unit 230 is in operation in the restriction unit 250 of FIG.
FIG. 6 is a conceptual cross-sectional view showing the state after the injection unit 230 is activated in the restriction unit 250 of FIG.

Hereinafter, an apparatus for separating and supplying a spring according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings. In the present specification, the same or similar reference numerals are given to different embodiments in the same or similar configurations.

1 is a perspective view showing an apparatus 100 for separating and supplying a spring according to an embodiment of the present invention.

Referring to this figure, an apparatus 100 for separating and feeding a spring may have a bowl unit 110, a spray unit 130, and a restriction unit 150.

Bowl unit 110 is a generally ovoid bowl-like configuration. Specifically, the bowl unit 110 may have a body 111, a spiral track 113, and a straight track 115.

The body 111 may be formed in a generally cylindrical shape. Thereby, the upper surface of the body 111 is formed into a substantially circular shape. A spring S is received on the upper surface of the body 111. The body 111 may have a vibration generator that generates vibration. The spiral track 113 extends spirally at the edge of the upper surface of the body 111. [ The spiral track 113 starts at the same height as the upper surface of the body 111 and gradually protrudes from the upper surface of the body 111. At the end of the spiral track 113, a straight track 115 is formed.

The injection unit 130 is installed on the body 111 and is configured to inject air toward the spring S. [ Specifically, the injection unit 130 may have an air tank 131, a pipe 133, and an injection port 235 (see FIG. 3) . The air tank 131 is a cylinder for storing air, specifically compressed air. The piping 133 connects the air tank 131 and the injection port 235 to form a flow path for allowing air to flow from the air tank 131 to the injection port 235. The injection port 235 extends through the body 111 and is exposed to the outside of the body 111 through the spiral track 113.

The limiting unit 150 is configured to wrap the upper side of the jetting port 235 so that the spring S does not fly out of the spiral track 113 and fly. The restriction unit 150 may include a cover 151 disposed on the upper side of the injection port 235. [ The cover 151 has a width corresponding to the width of the spiral track 113 and extends in an arcuate shape corresponding to the extension of the spiral track 113. A discharge hole 152 is formed in the cover 151 in correspondence with the air injection direction in the injection port 235.

According to this construction, the spring S located on the upper surface of the body 111 is subjected to a centrifugal force by the vibration of the body 111. Thereby, the spring S is transferred to the spiral track 113 and also moved to the side of the bottom edge of the body 111 along the spiral track 113. [

This spring S reaches the area corresponding to the jetting port 235 and the cover 151 during movement. Then, when air is injected from the injection port 235 by the operation of the injection unit 130, the spring S is blown by the force of the air. However, since the flight is restricted by the cover 151, the spring S drops again onto the spiral track 113. [ In this process, the tangled springs can be separated from each other by the impact caused by the collision with the cover 151 or the spiral track 113. The air injected from the injection port 235 is discharged to the outside of the cover 151 through the discharge hole 152.

In addition to the above embodiment, another embodiment for allowing the spring S to be more completely separated will be described with reference to Figs. 2 to 6. Fig.

3 is a cross-sectional view taken along line III-III in FIG. 2, and FIG. 4 is a cross-sectional view taken along line II-II in FIG. 2, Sectional view showing a state before the injection unit 230 is activated in the restriction unit 250. [

Referring to these drawings, a device 200 for separately feeding a spring is substantially similar to the prior art device 100, but has a configuration (such as a sliding hill 213b) associated with the spiral track 213, (Rotary plate 253, etc.) relating to the present invention is added.

Specifically, the apparatus 200 for separately supplying the springs includes a body unit 210, a spray unit 230, and a restriction unit 250.

The body unit 210 further includes a guide member 217 in addition to the body 211, the spiral track 213 and the straight track 215 similar to the previous embodiment. Here, the guide member 217 is installed in front of the linear track 215 to guide the spring S discharged from the lane L, which does not correspond to the linear track 215, to the linear track 215.

The spiral track 213 may have a partition 213a extending in a section substantially corresponding to the cover 251 and a sliding hill 213b. The partition wall 213a is for forming a plurality of lanes L in the direction perpendicular to the moving direction of the spring S, that is, along the width direction of the spiral track 213. [ Each lane L is formed so that the springs S can pass one by one. The sliding hill 213b starts after the jetting port 235 and extends along the traveling direction of the spring S. [ The sliding hill 213b has the highest portion after the jetting port 235 and may have a shape gradually lowered along the advancing direction of the spring S. [ The inclined surface 213c facing the jetting port 235 of the sliding hill 213b may form an acute angle with the advancing direction of the spring S. [

The injection unit 230 may have an air tank 231, a pipe 233, and an injection port 235, similarly to the previous embodiment. At this time, the jetting direction of the air at the jetting port 235 may be oriented parallel to the inclined surface 213c, corresponding to the inclination of the inclined surface 213c.

The limiting unit 250 may have a cover 251 and a discharge hole 252 and further a rotating plate 253 similarly to the previous embodiment. One end of the rotary plate 253 is rotatably coupled to the inner surface of the cover 251 through the hinge portion 253a. The free end of the rotary plate 253 is located in the first half of the ejection opening 235 and is arranged to be influenced by the air ejected from the ejection opening 235.

The separation process of the spring S by such a configuration will be described with reference to FIGS. 5 and 6. FIG.

5 is a conceptual cross-sectional view showing the state in which the injection unit 230 is in operation in the restriction unit 250 of FIG.

Referring to this figure, as the air is injected at the ejection opening 235, the spring S jumps out of the spiral track 213. At this time, the spring S may ascend in the air on the inclined surface 213c of the sliding hill 213b.

In this process, the air or the spring S collides with the free end side of the rotary plate 253. As a result, the rotary plate 253 is rotated in the upward direction U about the hinge portion 253a. Thereby, the rotary plate 253 does not prevent the spring S from being sprung upward.

The spring (S) springing into the air hits the inner surface of the cover (251). The spring S that strikes the cover 251 falls toward the spiral track 213 due to gravity. At this time, the air injected from the injection port 235 flows out through the discharge hole 252.

FIG. 6 is a conceptual cross-sectional view showing the state after the injection unit 230 is activated in the restriction unit 250 of FIG.

Referring to this drawing, the dropped spring S falls on any one of the plurality of lanes L formed by the partition 213a. At this time, the spring S falling on the partition 213a will enter the left or right lane L of the partition 213a. Thereby, even if the springs S are redundantly dropped in the same area, they can be separated by lanes L without being tangled with each other again.

The spring S is quickly moved out of the area covered by the cover 251 with the sliding hill 213b as the spring S drops onto the sliding hill 213b. Thereby, the possibility that the spring S can not get out of the cover 251 and is tangled with the falling spring S can be lowered.

Further, the rotary plate 253 is rotated in the downward direction D to prevent the spring S from falling behind the sliding hill 213b.

The apparatus for separately supplying the spring as described above is not limited to the configuration and the operation manner of the embodiments described above. The embodiments may be configured so that all or some of the embodiments may be selectively combined so that various modifications may be made.

100,200: Separate supply of spring
110, 210: Body unit 130, 230:
150, 250:

Claims (8)

A bowl unit having a body for generating vibration and a spiral track provided on an upper surface of the body; An ejection unit having an ejection port exposed to the outside through the spiral track and configured to eject air to the spring located in the spiral track through the ejection port; And a restriction unit which is formed to surround an upper side of the injection port and limits a flying range of the spring when the spring is blown by the air,
Wherein the spiral track includes a partition wall forming a plurality of lanes along a width direction intersecting with a traveling direction of the spring,
Wherein the bowl unit comprises: a straight track arranged to correspond to any one of the plurality of lanes; And a guide member formed to be inclined toward the straight track corresponding to the rest of the plurality of lanes and to guide the spring discharged from the remainder to the linear track.
The method according to claim 1,
The spiral track
And a sliding hill starting from the nozzle opening and extending along the advancing direction of the spring, the sliding hill having the highest portion after the nozzle opening.
3. The method of claim 2,
In the sliding hill,
And an inclined surface which forms an acute angle with the advancing direction of the spring.
The method of claim 3,
The jetting port
And a spring provided on the body so as to be parallel to the inclined surface.
delete delete The method according to claim 1,
The restricting unit,
A cover formed to surround the injection port; And
And a rotating plate rotatably coupled to an inner surface of the cover and positioned to be rotated by air injected from the jetting port.
8. The method of claim 7,
The cover
And a discharge hole for discharging the air ejected from the ejection port.

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