KR101823233B1 - Necking can manufacturing equipment - Google Patents

Abstract

The present invention relates to an apparatus for manufacturing a neck can, comprising: a press body; A press lower plate provided on an upper surface of the press main body and having a guide portion extending along the longitudinal direction of the press main body; A press upper plate provided with a working die provided so as to be linearly movable in a vertical direction with respect to the press lower plate; A feed screw disposed in the guide portion and adapted to feed the drawing can via a spiral rotational movement; And driving means for transmitting driving force for linearly moving the press plate in the up-and-down direction.
Accordingly, it is not necessary to construct a separate holder for supporting the drawing-processed can, which can greatly reduce the manufacturing cost of the apparatus and can eliminate the impact noise that hits each other among a plurality of holders, The pollution can be largely reduced and a pleasant working environment can be constructed.

Description

[0001] NECKING CAN MANUFACTURING EQUIPMENT [0002]

The present invention relates to an apparatus for manufacturing a neck can, and more particularly, to an apparatus and method for manufacturing a neck can, which improves operating performance and production efficiency by improving a single power system in which a driving means and a power transmitting means are organically connected, Can be greatly reduced.

Generally, metal cans used as storage containers for beverages are mainly made of aluminum or iron.

Such a metal can is formed by performing a multi-step process such as drawing or ironing on an aluminum plate or an iron plate.

The metal can is divided into an easy open end type can and a bottlenecked can. The metal can with the bottleneck is divided into a neck can, a bottle can, and a neck- in Can (hereinafter referred to as " necking can ").

Such a necking can reduces the opening to allow the plug to be connected to the inlet and neck-in to form a screw.

Hereinafter, an apparatus for manufacturing a neck can according to the prior art will be described with reference to FIG.

As shown in the drawing, the apparatus for manufacturing a neck can according to the prior art includes a press lower plate 10, a press upper plate 20 installed to move up and down in a straight line with respect to the press lower plate 10, A molding unit 21 composed of a plurality of molds mounted on the press plate 20 and a plurality of holders 12 installed to be transferred to the guide 11, And a drive means (40) for driving the press plate (20).

The apparatus for manufacturing a neck can configured as described above allows the drive means (40) to vertically move the presser upper plate (20) so that a mold process can be performed, and the transfer means (30) And to transfer a certain distance to the mold position.

Since the apparatus for manufacturing a neck can according to the related art has to be constructed of a different type of power transmission system in which the driving means 40 and the conveying means 30 are different from each other, There is a problem in that the deviation of the engagement position occurs finely with respect to the operating direction of each means as the time elapses, resulting in continuous product failure.

In addition, since the conveying means 30 repeatedly transmits a large force in order to linearly push the plurality of holders 12 arranged in one direction, the degree of fatigue of the cylinder is greatly increased, The impact noise of the plurality of holders 12 during the pushing action of the conveying means 30 is a major cause of noise pollution in the workplace environment.

Further, in the case of the guide of the apparatus for manufacturing a neck can according to the prior art, there is a limitation in increasing the production speed and the production amount of the product, since the guide of the apparatus for manufacturing neck can according to the prior art is simply composed of a single path of moving the drawing-

Korean Registered Patent No. 1058778 (Aug. 17, 2011)

SUMMARY OF THE INVENTION The present invention has been made in order to solve the problems of the prior art described above, and it is an object of the present invention to improve the operating performance and production efficiency by improving the single power system in which the driving means and the power transmitting means are connected to each other But also to reduce the operating noise of the apparatus significantly.

Another object of the present invention is to provide an apparatus for manufacturing a neck can, which can prevent a defective factor according to a feeding method in which a deviation occurs due to a slight impact and friction between a holder and a holder.

To achieve the above object, a neck can manufacturing apparatus according to the present invention comprises: a press main body; A press lower plate provided on an upper surface of the press main body and having a guide portion extending along the longitudinal direction of the press main body; A press upper plate provided with a working die provided so as to be linearly movable in a vertical direction with respect to the press lower plate; A feed screw disposed in the guide portion and adapted to feed the drawing can via a spiral rotational movement; And driving means for transmitting driving force for linearly moving the press plate in the up-and-down direction.

The drawing processing can is respectively disposed at left and right helical groove positions around the longitudinal direction of the feeding screw, and the drawing processing can is moved in the axial direction as the feeding screw rotates.

And a guide for ejecting and a guide for ejecting are provided at both ends in the longitudinal direction of the guide portion, the guide being branched in both directions with the feed screw interposed therebetween.

And a power transmitting means for rotating the feeding screw in cooperation with the driving means.

The drive means includes a drive motor, a drive pulley that receives rotation of the drive motor, a drive shaft connected to the drive pulley, a drive cam coupled to the drive shaft and eccentrically rotating, And a lifting and lowering coaxial shaft for vertically and linearly moving the presser upper plate.

Wherein the power transmitting means comprises a rotation cam fixed to an end of the drive shaft and provided with a projecting portion protruding outwardly, an intermittent rotation body rotating at a predetermined angle by a pressing force contacting the projecting portion, A driven gear that rotates in engagement with the power transmission gear, and a connecting member that interconnects the driven gear and the feeding screw.

The intermittent rotating body is composed of a disk-shaped first rotating plate, a second rotating plate, and a plurality of engaging pieces arranged at regular intervals between the first rotating plate and the second rotating plate.

The two conveying screws are arranged in parallel with each other. The driven gears are installed on the left and right sides of the power transmitting gear, respectively, and are connected to the conveying screws, respectively.

The power transmitting means is further provided with a tension adjusting roll for adjusting the tension of the connecting member.

And the feed screw is divided into a predetermined length unit and assembled.

According to the present invention having the above-described structure, it is not necessary to constitute a separate holder for supporting the drawing-processed can by constructing the feeding screw for feeding the drawing-processed can through the spiral rotational motion, It is possible to greatly reduce the unit cost and to eliminate the impact noise that is caused by mutual collision between a plurality of holders, thereby greatly reducing the noise pollution inside the workplace, thereby providing a pleasant working environment.

In addition, according to the structure of the feed screw, there is an effect of preventing a factor of defective according to the feeding method in which a deviation occurs due to a slight impact and friction between the existing holder and the holder.

Further, since the guide portion has two processing lines based on one of the feed screws, the production amount of the drawing-processed can can be doubled as compared with a device of the same class.

In addition, by constituting the power transmitting means for rotating the feeding screw in cooperation with the driving means, it is possible to further improve the operating performance and the production efficiency according to the single power system.

1 is a perspective view showing a neck canning manufacturing apparatus according to the prior art.
2 is a perspective view of a neck can manufacturing apparatus according to an embodiment of the present invention.
3 is a front view of Fig.
FIG. 4 is a perspective view showing the guide part and the feed screw of FIG. 2;
5 is a partially enlarged view showing the driving means of Fig.
6 is a schematic view showing an eccentric rotational motion of the drive cam of FIG.
Fig. 7 is a side view showing the configuration of the power transmitting means of Fig. 2;
Fig. 8 is a perspective view showing the configuration and operation of the power transmitting means in Fig. 7;
Fig. 9 is an exploded perspective view showing a configuration of the intermittent rotation body of Fig. 7;

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to FIGS. 2 to 9 attached hereto.

As shown in the drawings, the neck can manufacturing apparatus of the present invention includes a press main body 100, a press lower plate 200 formed with a guide portion 210 extending along the longitudinal direction of the press main body 100, A pressing upper plate 300 provided with a working metal mold 310 provided so as to linearly move in the up and down direction with respect to the lower plate 200 and a pressing upper plate 300 disposed in the guide portion 210, A driving means 500 for transmitting a driving force for linearly moving the press upper plate 300 in a vertical direction and a driving means 500 for driving the feeding screw 400 in conjunction with the driving means 500. [ And a power transmitting means (600) for rotating the power transmitting means.

First, the press main body 100 is a basic structure for installing the press lower plate 200 and the press upper plate 300, and is formed in a rectangular shape in which a plurality of frames are combined.

The press main body 100 is extended to a predetermined length, and a drive means 500 and a power transmission means 600, which will be described later, are installed on one side and the other side in the longitudinal direction.

A supporting base 110 for stably supporting the driving shaft 530 of the driving unit 500 is installed on the inner bottom surface of the press main body 100.

The lower press plate 200 is installed on the upper surface of the press main body 100 and includes a guide part 210 extending along the longitudinal direction of the press main body 100 to guide the movement path of the drawing processing can C, .

In addition, a guide 211 for feeding and a guide 212 for discharging are formed at both ends in the longitudinal direction of the guide portion 210, with the feed screw 400 being interposed therebetween.

In addition, a plurality of upper plate supports 220 are formed on the lower press plate 200 to stably maintain vertical movement of the press plate 300, which will be described later.

The upper press plate 300 is spaced apart from the lower press plate 200 so as to be linearly movable in the up and down direction and is movable in the vertical direction with respect to the lower plate press 200, And performs a linear motion in the up and down direction so that the neck can be machined to the upper portion.

To this end, the press plate 300 is provided with a plurality of processing molds 310 for advancing the neck canning step by step.

Meanwhile, the feeding screw 400 is disposed in the guide part 210 and elongates along the longitudinal direction, and serves to feed the drawing processing can C in the axial direction through a spiral rotational motion do.

The drawing screw 400 according to the present invention is disposed at the positions of the right and left helical grooves 401 around the longitudinal direction. Accordingly, the drawing processing can (C) moves in the axial direction as the feeding screw (400) rotates. Further, the guide part 210 according to the configuration of the conveying screw 400 can be divided into two areas.

The guide portion 210 can be divided into two regions without forming a separate partition plate for the guide portion 210. [

Further, the conveying screw 400 transmits a rotary pressing force for directly moving the drawing processing can C in a linear direction, thereby separating the drawing processing can (C) It is possible to greatly reduce the manufacturing cost of the apparatus and to eliminate the impact noise caused by mutual collision between a plurality of holders, thereby greatly reducing the noise pollution inside the workplace, thereby enabling a pleasant working environment It is effective.

In addition, the feeding screw 400 may have an assembly structure that is divided and assembled in units of a predetermined length.

This is to make installation and maintenance of the conveying screw 400 more efficient.

The feed screw 400 is preferably made of a metal material, but is not limited thereto. The feed screw 400 may be formed by injection molding using a plastic synthetic resin.

The driving unit 500 is installed at one side of the press main body 100 and transmits driving force for driving the press top plate 300.

The driving unit 500 includes a driving motor 510, a driving pulley 520 that receives the driving force of the driving motor 510 and a driving shaft 530 connected to the driving pulley 520, A driving cam 540 coupled to the driving shaft 530 to eccentrically rotate and a lifting and lowering shaft 550 connected to the driving cam 540 to vertically move the presser upper plate 300 .

That is, when the driving force of the driving motor 510 rotates the driving pulley 520, the driving shaft 530 connected to the driving pulley 520 rotates. At this time, the driving cam 540 coupled to the driving shaft 530 is circularly moved in the elevation direction when viewed from the axial direction as the coupling is performed at the eccentric position rather than the center. Therefore, the lifting / lowering coaxial shaft 550 connected to the driving cam 540 is lifted and lowered in the vertical direction according to the height difference of the turning radius of the driving cam 540.

The driving cam 540 and the lifting / lowering coaxial shaft 550 have coupling protrusions 551 formed on both sides of the lifting / lowering coaxial shaft 550 so as to firmly hold the coupling state between the driving cam 540 and the lifting / And the engaging groove 541 for receiving the engaging protrusion 551 is formed in the driving cam 540.

In addition, a bearing (not shown) may be additionally provided between the engaging projection 551 and the engaging groove 541 to minimize the rotational friction.

A threaded portion 550a is formed on one side of the lifting / lowering coaxial shaft 550 in the longitudinal direction thereof to adjust the height of the press plate.

The driving means 500 may be a pressure cylinder which can directly press the upper plate 300 to move the presser plate 300 without moving the driving motor 510, the driving pulley 520 and the driving shaft 530 The apparatus can be manufactured using the apparatus of FIG.

The power transmitting means 600 is provided on the other side of the press main body 100 to rotate the feeding screw 400 in cooperation with the driving means 500.

That is, the power transmitting means 600 transmits the power for rotating the feeding screw 400 through the driving shaft 530 of the driving means 500.

In other words, the power transmitting means 600 receives the power from the driving shaft 530 and does not rotate the feeding screw 400 using a separate driving force generating means (cylinder, motor, etc.) The screw 400 is rotated.

However, the power transmitting means 600 may be constructed of a motor that can directly rotate the feeding screw 400 when the driving means 500 described above is manufactured using a pressure cylinder.

More specifically, the power transmission unit 600 includes a rotation cam 610 fixed to an end of the drive shaft 530 and having a protrusion 611 protruding outward, A power transmission gear 630 fixed to the intermittent rotating body 620 and a driven gear 640 rotated by engaging with the power transmission gear 630. [ And a connecting member 650 for interconnecting the driven gear 640 and the feed screw 400.

That is, when the rotation cam 610 fixed to the end of the driving shaft 530 is rotated, the protrusion 611 formed on the outer side of the rotation cam 610 is inserted into the intermittent rotation body 620 ) Through a contact pressure that intermittently interferes. For example, during one rotation of the rotation cam 610, the intermittent rotation body 620 rotates 1/4 of the circumferential direction.

This is to maintain the spiral turn ratio of the feeding screw at a constant level in accordance with the rising / falling speed of the press upper plate 300.

The rotation of the power transmission gear 630 is transmitted to the driven gear 640 engaged with the power transmission gear 640. The power transmission gear 630 is rotated together with the power transmission gear 630, And the driven gear 640 rotates the feeding screw 400 through the configuration of the connecting member 650.

The intermittent rotating body 620 includes a disk-shaped first rotating plate 621 and a second rotating plate 622 and a plurality of engaging pieces (not shown) disposed equidistantly between the first rotating plate 621 and the second rotating plate 622 623).

The rotating cam 610 and the intermittent rotating body 620 can be formed in a plurality of configurations according to the size or rotation speed of the driving shaft 530.

Further, a tension adjusting roll 660 for adjusting the tension of the connecting member 650 is additionally formed in the power transmitting means 600. [

The connecting member 650 may be manufactured as a chain type in which a plurality of link members are connected or a belt type in which a gear portion is formed on the inner circumferential surface.

The driven gears 640 are installed on the left and right sides of the power transmission gear 630, respectively. The driven gears 640 are disposed on the left and right sides of the power transmission gear 630, Respectively, of the screw.

According to the present invention configured as described above, it is necessary to constitute the feed screw 400 for feeding the drawing processing can C through the spiral rotational movement, so that it is necessary to construct a separate holder for supporting the drawing processing can (C) It is possible to greatly reduce the manufacturing cost of the apparatus and to eliminate the impact noise that may be caused by mutual collision between a plurality of holders. Therefore, it is possible to greatly reduce the noise pollution inside the workplace, thereby providing a pleasant workplace environment.

Further, since the power transmitting means 600 for rotating the feeding screw 400 in conjunction with the driving means 500 is constituted, it is possible to further improve the operating performance and the production efficiency according to the single power system .

100: press body 200: press bottom plate
210: guide portion 211: guide for insertion
212: guide for discharging 300: press plate
400: Feed screw 500: Driving means
600: Power transmission means

Claims (10)

A press body;
A press lower plate provided on an upper surface of the press main body and having a guide portion extending along the longitudinal direction of the press main body;
A press upper plate provided with a working die provided so as to be linearly movable in a vertical direction with respect to the press lower plate;
A feed screw disposed in the guide portion and adapted to feed the drawing can via a spiral rotational movement;
A drive shaft connected to the drive pulley; a drive shaft connected to the drive shaft; and a drive shaft connected to the drive shaft to rotate eccentrically A driving cam, and driving means connected to the driving cam, the driving means comprising a lifting and lowering coaxial shaft for vertically moving the presser upper plate; And
And a power transmitting means for rotating the feeding screw in cooperation with the driving means,
Wherein the power transmitting means comprises a rotation cam fixed to an end of the drive shaft and provided with a projecting portion protruding outwardly, an intermittent rotation body rotating at a predetermined angle by a pressing force contacting the projecting portion, A driven gear which rotates in engagement with the power transmission gear, and a connecting member which interconnects the driven gear and the feed screw.
The method according to claim 1,
Wherein the drawing processing can is respectively disposed at left and right helical groove positions around the longitudinal direction of the feeding screw and the drawing processing can is moved in the axial direction as the feeding screw rotates .
3. The method of claim 2,
Wherein a guide for feeding and a guide for discharging are formed at both ends in the longitudinal direction of the guide portion with the feed screw being interposed therebetween in both directions.
delete delete delete The method according to claim 1,
Wherein the intermittent rotating body comprises a disk-shaped first rotating plate, a second rotating plate, and a plurality of engaging pieces arranged at equal intervals between the first rotating plate and the second rotating plate.
The method according to claim 1,
Wherein the two feeding screws are arranged in parallel with each other,
Wherein the driven gears are installed on the left and right sides of the power transmission gear, respectively, and are respectively connected to the feed screw.
The method according to claim 1,
Wherein the power transmitting means is further provided with a tension adjusting roll for adjusting the tension of the connecting member.
4. The method according to any one of claims 1 to 3,
Wherein the conveying screw comprises an assembly structure in which the conveying screw is divided and assembled in units of a predetermined length.

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