KR20040075690A - A wire feeder - Google Patents

Abstract

PURPOSE: A wire feeder is provided to feed wires with a constant speed while minimizing noise and improving endurance of the wire feeder by installing a wire feeding in opposition to a link lever. CONSTITUTION: A wire feeder(1) includes an eccentric shaft(5), which is driven by a driving motor and installed in a body(3). A pair of link levers(9,9') are installed at both sides of the eccentric shaft(5). Lower ends of the link levers(9,9') are coupled to the body(3) by means of bolt pins(6). Upper ends of the link levers(9,9') are coupled with a feeding holder(8) by means of bolt pins(6). A coupling hole(10) is formed in one of link levers(9,9'). A cam link(11) is connected to the coupling hole(10) through a connection pin(12). A wire feeding(7') is installed on the body(3) by using a feeding holder(15).

Description

Wire feeder

The present invention relates to a wire feeder that can be applied to a carbon dioxide gas welding machine, a coil spring maker, and the like, and more particularly, to provide a wire feeder that is durable and has no friction noise and can always maintain a constant feeding speed of a wire. It is a good thing.

Wire feeders are used in carbon dioxide (CO2) welding machines, coil spring manufacturers, etc. so that the continuous supply of the wire can be made smoothly.

As shown in FIG. 1, the wire feeder 30 used therein pulls out the output shaft 32 which decelerates and rotates on the front surface of the drive motor 31 to shaft-mount the drive gear 33, thereby driving the drive gear 33. The driven gear 34 is tooth-coupled on both sides of the wire feeder, and the wire feed roller 36 is axially coupled on the driven shaft 35. On both sides of the feed roller 36, a pressure roller 39 is installed on the bracket 38 that rotates about the fixed shaft 37 so as to pressurize the wire 40, and the feed on the coaxial shaft. The combined driving gears 42 which are engaged with the driven gears 34 for rotating the roller 36 are collectively driven. And the contact portion of the both sides of the bracket 38 is configured to be pressed by one fastening handle 43, guide the wire 40 to the inlet / outlet of the feed roller 36 and the pressure roller 39 Or a guide 44 for guiding the wire 40 drawn out therefrom.

The conventional wire feeder 30 has four feed gears 34 and 42 rotated by the driving force of the drive motor 31 to feed the feed roller 36 and the pressure roller 39 which are coaxially coupled. Since it is rotated to supply the wire 40 is inserted through the inlet guide 44 to the outlet guide 44

However, the conventional wire feeder 30 has one fastening handle 43 in a state in which two pressure rollers 39 for pressing the wires 40 on the feed roller 36 are axially installed on a separate bracket 38. It is configured to be fastened to the bar, the pressure deviation of the pressure roller 39 to press the wire 40 on the feed roller 36 is likely to occur, when the pressure deviation of the pressure roller 39 occurs, the feedability is deteriorated This is caused, when the diffusion between the feed roller 36 and the pressure roller 39, the noise is severely generated and when the wire 40 is a phenomenon that the deviation of the wire has been generated a new configuration that can solve this problem Development of wire feeders was required.

The present inventors have devised the present invention to solve all the problems of the conventional wire feeder as described above.

That is, in the present invention, the cam link shaft is installed on the eccentric shaft driven by the drive motor, and one end thereof is coupled with a pair of link levers axially coupled to the main body so that a rotational motion close to equilibrium can be achieved, and both sides are provided. At the top of the link lever, the wire is clamped when the link lever rotates in the wire feeding direction and unclamped when the link lever rotates to the opposite side, so that the wire is always durable at a constant speed without any noise. The present invention has been completed with the technical problem of the present invention to provide a wire feeder to be able to supply.

1 is a front view showing the configuration of a conventional wire feeder

Figure 2 is a front view showing a preferred embodiment of the present invention

Figure 3 is a perspective view of the main portion of the present invention

4 is an exploded perspective view of FIG.

Figure 5 is a cross-sectional configuration of the wire feeding extract applied to the present invention

Figure 6 is a side cross-sectional view showing a steel ball coupling state of the wire feeding

7 is a front configuration view showing another embodiment of the present invention

8 is a front configuration view showing another embodiment of the present invention

9 is a sectional view of the main portion extracted eccentric shaft coupling state of FIG.

Explanation of symbols used in main part of drawing

1: wire feeder 2: wire drum

3: main body 4: driving motor

5,5 ': eccentric shaft 5a: bearing

6,24: Bolt pin 7,7 ': Wire feeding

8,15: Feeding holder 9, 9 ', 22, 22': Link lever

9a: connecting piece 10: coupling hole

11,11 ': cam link 12: connection pin

13: Wire 14: Fastening means

16: Body 17: Gripper

17a: taper hole 17b: coupling hole

18: Steel holder 18a: Wire feeder

18b: Base 18c: Steel ball inside hole

19: Steel ball 20: Stop ring

21: return spring 22a: engaging stone piece

23: interlocking lever

Figure 2 is a front view showing a preferred embodiment of the present invention, Figure 3 is an exploded perspective view of the main portion of the present invention, Figure 4 is an exploded perspective view of Figure 3, Figure 5 shows a wire-feeding excerpt cross-sectional configuration, etc. applied to the present invention As one, the configuration of the present invention will be described below.

The wire feeder 1 to be provided in the present invention pivotally installs the eccentric shaft 5 driven by the drive motor 4 in the main body 3 on which the wire drum 2 in the wound state is installed on one side.

On both sides of the eccentric shaft (5), the lower end is axially coupled to the main body (3) by a bolt pin (6), and the upper end of the bolt pin is configured to pivot the feeding holder (8) on which the wire feeding (7) is separably fixed. (6) arranging a pair of link levers (9) (9 ') coupled by shaft coupling, at least two coupling holes (10) are formed in one link lever (9), and these coupling holes (10) In one of the) is coupled to the cam link 11 coupled to the eccentric shaft (5) to be supported by a bearing (5a) with a connecting pin (12). The link levers 9 and 9 'may be arranged on one side of the eccentric shaft 5. And the coupling hole 10 may be formed in the form of a long hole.

Then, on the discharge side main body 3 of the wire 13, the feeding holder 15 is fixedly installed by fixing means 14 such as a bolt, and this is independent of the wire feeding to be located at the same center as the wire feeding 7. 7 ') is detachably fixed.

The wire feeding 7, 7 ′ is formed with a tapered hole 17a at the front end of the tubular body 16 as shown in FIGS. 5 to 6, and to the rear thereof (a narrow side of the tapered hole). At least one fixing and fixing of the taper hole 17a of the gripper 17 in which the coupling hole 17b to which the steel ball holder 18 is coupled is located on the wire 13 feeding direction side, and the gripper In the coupling hole (17b) formed in the (17), the wire transfer hole (18a) is penetrated to the center and the supporting jaw (18b) is formed on the outer circumference, and the steel ball inlet hole (18c) at right angles at the front end with the shaft right angle Combining the steel ball holder 18 penetrating in the direction to insert the steel ball 19 is configured to be supported by the stop ring 20 without separation, the return between the support jaw 18c and the gripper 17 of the steel ball holder 18 When the link levers 9 and 9 'are rotated in the feeding direction via the spring 21, the wire 13 is clamped and rotated to the opposite side. So that the clamping.

FIG. 7 is a front sectional view showing another embodiment of the present invention. In the wire feeder 1 as described above, a plurality of wire feedings 7 are provided to supply the wires 13. It is to make this more effective.

That is, the feeding holder 8 is symmetrically configured at both sides of the eccentric shaft 5, and the lower end is axially coupled to the main body 3 by bolt pins 6, and the upper end is detachably fixed to the wire feeding 7. A pair of link levers 9, 9 ', 22 and 22' connected in a state of being coupled to the bolt pin 6 so as to be rotatable, wherein the four link levers 9 and 9 ' At least two coupling holes 10 are formed in one of the link levers 9, 22 and 22 ', and one of the coupling holes 10 has a bearing on the eccentric shaft 5; The cam link 11 coupled to be supported by 5a) is coupled to the connecting pin 12.

In addition, the lower side of the bolt pin 6 coupled to the lower side of the link lever 9 to which the cam link 11 is coupled extends the connecting piece 9a, and the lower side of the side link lever 22 to be symmetrical thereto. Coupling levers 22a are formed on the upper side of the bolt pin 6 to which they are coupled, and two wire feedings 7 are formed by axially coupling an interlocking lever 23 coupled to the bolt pin 24 between these phases. By operating in the opposite direction to each other it is possible to supply the wire (13).

At this time, the distance between the center of the bolt pin 6 on the lower side of the link lever 9 and the center of the bolt pin 24 on the connecting piece 9a on the extension line thereof is formed at the center of the bolt pin 6 on the lower side of the link lever 22 and on the upper side thereof. The distance between the centers of the bolt pins 24 engaged on the engaging stone pieces 22a must always be the same distance.

8 and 9 show another embodiment of the present invention, which illustrates another embodiment in which a plurality of wire feedings 7 are provided in configuring the wire feeder 1.

That is, it is provided with eccentric shafts 5 and 5 'which are symmetrical with each other to be driven by the driving motor 4 in the main body 3, and symmetrical configurations on both sides of the eccentric shafts 5 and 5', respectively. Is axially coupled to the main body 3 with the bolt pin 6, and the upper end thereof is connected to the bolt holder 6 with the bolt pin 6 in a rotatable state so that the feeding holder 8 is detachably fixed. A pair of link levers 9, 9 ', 22, and 22' are disposed, and two link levers symmetrical among the four link levers 9, 9 ', 22 and 22' are arranged. At least two coupling holes 10 are formed in the pairs 9 and 22, and any one of the coupling holes 10 is coupled to the eccentric shaft 5 and 5 'to be supported by the bearing 5a. By linking the links 11 and 11 ′ with the connecting pin 12, the two wire feedings 7 are operated in opposite directions to allow the wire 13 to be fed.

Reference numeral 25 in the figure shows a cable for transferring the wire (13).

The wire feeder 1 of the present invention configured as described above may be used for feeding the wire 13 in equipment such as a carbon dioxide welder or a spring maker, and the wire feeder 1 provided in the present invention may be a wire Insert the wire (13) wound on the drum (2) into the wire feeding (7) (7 ') that is fixedly coupled to the feeding holder (8) (15) and drive the drive motor (4) (13) is fed at a constant speed.

That is, according to the present invention, when the driving motor 4 is driven as described above, the eccentric shaft 5 which is rotated by the driving motor 4 is rotated at high speed, and is axially coupled to the eccentric shaft 5. The cam link 11 converts the rotational motion into a linear motion to rotate the link levers 9 and 9 '.

At this time, the feeding holder 8, which is rotatably coupled to the upper end of both side link levers 9 and 9 'by the bolt pin 6, performs the rotational movement close to the straight line in the state in which the wire feeding 7 is engaged. When the link levers 9 and 9 'are rotated in the feeding direction, the wire 13 is clamped and the wire 13 is fed by the wire feeding 7 configured to be unclamped when rotating to the opposite side. You lose.

The operation thereof will be described in more detail with reference to FIGS. 5 to 6.

As described above, the wire feeding 7 moves left and right according to the rotational movement of the link levers 9 and 9 '.

That is, when the link levers 9 and 9 'are rotated in the feeding direction, a taper in which a steel ball holder 18 including a steel ball 19 coupled to the steel ball holder 18 is formed on the gripper 17. Since the wire 13 is pushed forward while being moved to the narrow side of the ball 17a, the wire 13 wound on the wire drum 2 is released and feeding is performed.

On the contrary, when the link levers 9 and 9 'are rotated to the opposite side in the feeding direction, the steel ball holder 18 including the steel ball 19 coupled to the steel ball holder 18 is moved to the wide side of the tapered hole 17a. By reversing while rolling on the surface of the wire 13 while the wire 13 is unclamped, the feeding speed of the wire 13 can be kept constant at all times without friction noise. At this time, the return spring 21 interposed between the supporting jaw 18b of the steel ball holder 18 and the gripper 17 is in a reduced state, and the steel ball holder when the link levers 9 and 9 'are rotated in the feeding direction. By moving 18 more quickly, the wire 13 is clamped.

On the other hand, in the present invention, since two or more coupling holes 10 are formed in one link lever 9, when the cam link 11 is coupled to the coupling hole 10 located below, the link levers 9 and 9 are provided. The rotation angle of ') becomes large, and when the cam link 11 is coupled to the coupling hole 10 located on the upper side, the rotation angle of the link levers 9 and 9' becomes smaller, so that the wire 13 It is possible to improve the workability by selectively supplying the feed rate. In addition, when the coupling hole 10 is configured in a long hole shape, the rotation angle of the link levers 9 and 9 'may be adjusted without permission.

And wire feeding (7) (7 ') applied to the present invention can feed the wire 13 of various thicknesses without exchange, wire feeding (7) (7') is detachable to the feeding holder (8) Since it is fixed, by using it as a replacement, the wire 13 of various thicknesses can be more stably fed.

Meanwhile, according to FIG. 7, which is another embodiment of the present invention, a pair of link levers 9, 9 ′, 22, which are axially coupled with bolt pins 6, respectively, are symmetrical to both sides of the eccentric shaft 5. 22 'is arranged to connect one link lever 9 to the eccentric shaft 5 and the cam link 11, and the connecting piece extending from the lower side of the link lever 9 to which the cam link 11 is coupled. (9a) and the link lever (9) (9 ') by axially coupling the interlocking lever (23) coupled by the bolt pin (24) between the engaging projection piece (22a) formed on the upper side of the link lever (22) which is symmetrical thereto. 2) The feed motor 7 is made to feed the wire 13 by operating the two wire feeders 7 coupled to the upper ends of the 22 and 22 'in opposite directions. When driven, the cam link 11 axially coupled to the eccentric shaft 5 converts the rotational movement into a linear movement to rotate the link levers 9 and 9 ', and at this time, The link levers 22 and 22 'are rotated in the opposite directions to the link levers 9 and 9' by the interlocking lever 23, so that the link levers 22 and 22 'are positioned upwards of the link levers 9, 9', 22 and 22 '. The feeding of the wire 13 is made by operating the two wire feeders 7 coupled to each other in opposite directions.

That is, when the link levers 9 and 9 'are rotated to the wire feeding side, the wire feeding 7 which is coupled to the upper end thereof clamps the wire 13, and at this time, the opposite link levers 22 and 22' are clamped. ) Is rotated to the opposite side to the link lever (9) (9 ') by the interlocking lever (23), so that the wire feeding (7) is coupled to the upper end of the link lever (22) (22') unclamping wire It is to be made, the operation of the wire 13 is alternately made of a more stable supply of the wire (13).

8 and 9, the wire 13 may be alternately clamped and supplied by the plurality of wire feedings 7 as described above.

As described above, in the wire feeder 1 of the present invention, the cam link 11 is axially mounted on the eccentric shaft 5 driven by the driving motor 4, and one end thereof is axially mounted on the main body 3. By combining a pair of link levers 9, 9 'coupled to each other, a rotational motion close to equilibrium can be achieved, and a link in the feeding direction of the wire 13 is provided on the upper ends of both link levers 9, 9'. The wire 13 is clamped when the levers 9 and 9 'are rotated, and the wire 13 is unclamped when the lever 9 and 9' are rotated to the opposite side, so that the wire 13 can be fed. Alternatively, a pair of link levers 9, 9 ', 22, and 22' are arranged in a symmetrical configuration on both sides of the eccentric shaft 5 so that a plurality of wire feedings 7 are coupled to each other in opposite directions. By operating, the feeding of the wire 13 can be made, according to the present invention can significantly reduce the operating noise In addition, since the clamping operation is made by the movement of the steel ball 19, it is possible to supply the wire 13 smoothly while the failure rate is remarkably low.

In addition, the cam link 11 may be selectively coupled to the coupling hole 10 formed in the link lever 9, thereby improving workability such as adjusting the supply speed of the wire 13.

In addition, the present invention is to be able to supply the wire more effectively when the plurality of wire feeding 7 is configured to rotate in different directions as shown in FIGS.

Claims (4)

In the wire feeder 1 which continuously feeds the wire 13 on the wire drum 2 which wound the wire 13, The eccentric shaft 5 driven by the drive motor 4 is axially mounted on the main body 3 on which the wire drum 2 is axially mounted. On both sides of the eccentric shaft (5), the lower end is axially coupled to the main body (3) by a bolt pin (6), and the upper end of the feeding pin (8) to which the wire feeding (7) is separably fixed to the bolt pin (6). Arrange a pair of link levers (9) (9 ') coupled by shaft coupling, The coupling link 10 is formed in the one side link lever 9, and the coupling pin 10 has a cam link 11 coupled to the eccentric shaft 5 so as to be supported by the bearing 5a. With the shaft, On the discharge side main body 3 of the wire 13, an independent wire feeding 7 'is detachably fixed to the feeding holder 15 so as to be coaxial with the wire feeding 7, and the link lever 9 is installed in the feeding direction. The wire feeder, characterized in that the wire (13) is clamped when the (9 ') is rotated, and unclamped when rotating to the opposite side. The method of claim 1, Both sides of the eccentric shaft (5) in a symmetrical configuration, each of the lower end is axially coupled to the main body (3) with a bolt pin (6), the upper end of the feeding holder (8) in which the wire feeding (7) is separably fixed Arranging a pair of link levers 9, 9 ', 22, 22' connected in a axially coupled state with the bolt pin 6, One of the four link levers 9, 9 ', 22, and 22' forms a coupling hole 10 so as to be supported by the bearing 5a on the eccentric shaft 5; Combining the combined cam link 11 with the connecting pin 12, On the lower side of the bolt pin 6 coupled to the lower side of the link lever 9 to which the cam link 11 is coupled, a connecting piece 9a extends, and the lower side of the side link lever 22 is symmetrical thereto. A coupling protrusion (22a) is formed on the upper side of the bolt pin (6) to be coupled, and the interlocking lever (23) coupled to the bolt pin (24) between these phases is axially coupled, The distance between the center of the bolt pin 6 below the link lever 9 and the center of the bolt pin 24 on the connecting piece 9a on the extension line thereof, and the center of the bolt pin 6 below the link lever 22 and the upper side thereof. A wire feeder, characterized in that two wire feedings (7) are operated in opposite directions by configuring the same distance between the centers of bolt pins (24) to be coupled on the engaging stone pieces (22a) formed. The method of claim 1, The main body 3 is provided with eccentric shafts 5 and 5 'which are symmetrical with each other to be driven by a drive motor 4, Feeding holders are symmetrically configured on both sides of the eccentric shafts (5) and (5 '), the lower ends of which are axially coupled to the main body (3) by bolt pins (6), and the upper ends of which are detachably fixed. Arrange a pair of link levers 9, 9 ', 22, 22' connected to each other in a state in which (8) is pivotally coupled to the bolt pin 6, Two link levers 9 and 22 which are symmetrical among the four link levers 9, 9 ', 22 and 22' are provided with coupling holes 10 to form eccentric shafts 5 and 5 '. A wire feeder characterized in that the two wire feedings 7 are operated in opposite directions by combining the cam links 11 and 11 'coupled to each other by the bearings 5a with the connecting pins 12. . The method of claim 1, The wire feeding 7, 7 ′ has a tapered hole 17a formed at the tip of the wire 16, and the steel ball holder 18 is coupled to the rear side (a narrow side of the tapered hole). At least one tapered hole 17a of the gripper 17, on which wires are formed, to be positioned at the wire 13 feeding direction side, In the coupling hole 17b formed in the gripper 17, a wire feed hole 18a penetrates to the center and a support jaw 18b is formed on the outer circumference thereof. The steel ball holder 18 which penetrates in the direction perpendicular to the axial direction and incorporates the steel ball 19 is coupled to be supported by the stop ring 20 without being separated, and between the supporting jaw 18c and the gripper 17 of the steel ball holder 18. A wire feeder via a return spring (21).