KR200145829Y1 - A tension regulator of copper wire winding machine - Google Patents

Abstract

The object of the present invention is achieved by providing a tension control device for tensioning the transmission state of a copper wire in a winding machine that manufactures all wire bundles, such as a magnetic generating bundle and an electromagnetic induction generating bundle used in an electric motor or a generator or an image display. Tension control device uses expensive spline grinding rod with guide shaft that guides movement of fixed wheel which is alternately installed on both sides of the wire route of copper wire, and movable wheel which absorbs and absorbs transmission line among movable wheels. Instead, a general polishing rod is used, and a parallel guide of the movable wheel is maintained by a second guide additionally provided in parallel with the guide shaft rod thereof. As a result, the driving of the movable wheel is stabilized and manufacturing cost can be reduced to spread at low cost.

Description

Tension control device of copper wire winding machine

The present invention maintains the transmission tension of the winding machine which manufactures all the wire bundles which are wound in a proper shape by using a template such as a magnetic generating coil, an electromagnetic induction coil, or a deflection yoke coil of an image display CRT tube, that is, a wire path that is sucked to the winding machine side. The present invention relates to a tension control device of a copper wire winding machine that is installed to absorb a wire and buffers a suction state of a copper wire. In particular, the structure is improved to cope with a mechanical element that is easily supplied and supplied without using expensive mechanical elements. It relates to a tension control device of a copper wire winding machine to reduce the cost.

All pre-bundled wires wound in a suitable shape such as a magnetic generating coil, an electromagnetic induction coil, or a deflection yoke coil are wound into a predetermined winding shape according to the purpose of use by using a roughly suitable mold. As shown in FIG. 1, the copper wire 30 released from the bobbin 20 is sucked into the concentrator 50 through the individual tension 40 in the mold 11 provided in the winding machine main body 10 as shown in FIG. 1. The back tension 60 is supplied while maintaining the tension state to achieve the desired winding.

In such a winding machine, the tension of the copper wire supplied to the mold, that is, the individual tension 40 or the back tension 60, etc., which are provided on the path element of the wire in order to maintain tight tension and keep the tension in the wire state without loosening. Tension control device is installed essentially, this tension control device is a very important factor that determines the characteristics of the product by preventing tension loosening or twisting phenomenon of the copper wire as well as maintaining the tension of the transmission line.

Tension control device of such a winding machine has been developed and used to date, for example, in the case of the back tension 60, as shown in FIG. 2 fixed wheels 61 on both sides of the proper position of the transmission line passing through the copper wire 30 ) And the movable wheel 62 are alternately alternately installed, and among these wheels, the movable wheel 62 is elastically and freely installed on the guide shaft rod 63 installed in parallel with the transmission line. It absorbs the suction of the transmission line and maintains the desired tension.

By the way, the movable wheel 62 of the tension adjusting device is installed to be freely movable to the guide shaft bar 63 which is installed in parallel with the transmission line as shown in Figure 3, the movable wheel 62 is the guide shaft bar (63) It is possible to move in the axial length direction, but not to rotate in the cross direction, in other words, the movable wheel 62 is provided with at least two grooves 63A on the outer circumferential surface of the guide shaft bar 63 in the axial length direction. It has the same structure as the spline shaft that maintains equilibrium with the transmission line.

However, the guide shaft rod 63 employed in the tension adjusting device uses a spline grinding rod, which is not easy to manufacture by using the spline grinding rod, and there is only an uneconomic defect that increases the manufacturing cost due to the high cost of materials. However, there were many problems, such as not easy to supply.

The present invention has been made in consideration of the above circumstances, and its purpose is to install a movable wheel on a guide polishing rod made of general processing without using an expensive spline polishing rod, and to move the movable wheel in parallel with the guide shaft rod. It is to provide a tension control device of the copper wire winding machine to maintain the balance by the second guide provided as.

Another object of the present invention is to provide a tension control device for a copper wire winding machine which is stable in driving and can be supplied at low cost by reducing manufacturing costs.

The object of the present invention is to achieve by providing a tension control device for tensioning the transmission state of the copper wire in the winding machine for manufacturing all wire bundles, such as magnetic generating bundles, electromagnetic induction generating bundles used in electric motors, generators or image display, etc. This tension adjusting device is designed to offset expensive spline grinding rods by guiding the movement of the movable wheels, which shift and shift the fixed wheels, which are alternately installed on both sides of the wire line of the copper wire, and the cushioning and absorbing action of the wires. Instead of using a general polishing rod, the second guide is provided in parallel with the guide shaft rod thereof to maintain the balance of the movable wheel. As a result, the driving of the movable wheel is stabilized and manufacturing cost can be reduced to spread at low cost.

1 is a process explanatory diagram schematically showing a transmission process of a general winding machine.

Figure 2 is a longitudinal sectional view of the tension control device for controlling the supply of the coil in the conventional transmission process.

3 is a cross-sectional view showing a state in which the movable wheel of the tension control device is coupled.

Figure 4 is a longitudinal cross-sectional view showing the configuration of the subject innovation tension control device.

Figure 5 is a longitudinal sectional view showing another embodiment of the present invention tension control device.

Figure 6 is a longitudinal sectional view showing another embodiment of the present invention tension control device.

7 is a longitudinal cross-sectional view taken along the line A-A of FIG.

Figure 8 is a longitudinal sectional view showing another embodiment of the present invention.

9 is a cross-sectional view taken along the line B-B of FIG.

* Explanation of symbols for main parts of the drawings

600: back tension 620: movable wheel

630: movable shaft 640: elastic member

650: Second guide

Next, embodiments of the present invention will be described in detail with reference to the accompanying drawings. 4 shows a tension control device applied to the winding machine back tension of the deflection yoke coil as an embodiment of the present invention, and the characteristic technology of the present invention improves the structure of the tension control device to stabilize the driving as well. In other words, manufacturing cost is reduced.

The back tension 600 of the present invention is provided with a guide shaft rod 630 on a horizontal line on a flat plate-like substrate 601, the movable wheel is elastically installed on the guide shaft rod 630 by an elastic member 640 ( 620 is installed to be free to move. This configuration is the same as in the prior art. At this time, the guide shaft rod 630, which the movable wheel 620 is condensed, is used without the use of expensive spline abrasive rods as in the prior art.

In the present invention, a second guide 650 parallel to the longitudinal direction of the guide shaft bar 630 is installed at a position close to the guide shaft bar 630 of the back tension 600 configured as described above, and the movable wheel 620 is guided. It will be controlled to rotate about the shaft (630).

The second guide 650 is formed into a slot by cutting the substrate 601 on which the guide shaft rod 630 is mounted. The second guide 650 has a length that can sufficiently accommodate the operating range of the movable wheel 620, and is configured in parallel with the guide shaft bar 630.

The insertion guide 621 integrally provided at the lower side of the movable wheel 620 is fitted in the second guide 650 configured as described above. The inserter 621 slides with the smallest possible coefficient of friction in the second guide 650. The inserter 621 is a force for the movable wheel 620 to rotate about the guide shaft 630. Suppress and maintain parallelism. In other words, it will serve as a conventional spline polishing rod.

This will be described in detail with respect to the operation of the present invention tension control device. In the present invention, the movable wheel 620 is moved to the left and right by the guide shaft rod 630 and absorbs the transmission line buffer to maintain the tension of the transmission line. This operation is the same as before.

In the present invention, the insertion shaft 621 is integrally provided at the lower portion of the movable wheel 620 moving left and right by the guide shaft rod 630 as described above, and the insertion shaft 621 thereof is provided with the guide shaft rod 630. The second guide 650, which is provided in parallel on the same line, is installed to slide freely so that the movable wheel 620 is not rotated around the shaft when the guide wheel 630 is moved to maintain the equilibrium.

Therefore, the present invention uses a general guide abrasive rod, which is easily supplied and manufactured at a low price, without using a spline shaft made of an expensive abrasive rod to guide the movement of the movable wheel, thereby reducing manufacturing cost and distributing it at a low price. It has an economic effect.

In addition, the present invention is to support the movable wheel at two points by the guide shaft rod and the second guide provided in parallel with the guide shaft rod and additionally provided, there is a structurally stable effect as well as driving the movable wheel. .

5 shows another embodiment of the present invention, which is different from the above embodiment in the present embodiment, in which the second guide for guiding the driving of the movable wheel is formed in the shape of a rod, and one point is the same as the guide shaft rod. It is configured to be rotated on a line.

In the present embodiment, the same parts as in the above embodiment will be displayed by adding 100 to the part number. In this embodiment, the movable wheel 720 is elastically installed as the elastic member 740 on the guide shaft bar 730 installed on the iron plate 701 on the horizontal line. This configuration is the same as in the prior art. The movable wheel 720 configured as described above has a shaft pin 703 provided in the vertical stand 702 which is vertically downwardly arranged on the same vertical line as the guide shaft bar 730 directly under the guide shaft bar 730, that is, the bottom of the substrate 701. The second guide 750 is configured to be moved and guided by a narrow bar that rotates around the support shaft. In other words, when the movable wheel 720 moves from side to side on the guide shaft rod 730, the rod-shaped second guide 750 rotates on the same line as the guide shaft rod 730 using the shaft pin 703 as the shaft. The wheel 720 suppresses the rotation about the guide shaft rod 730 and maintains the balance of the movable wheel.

6 shows another embodiment of the present invention, which is different from the above embodiment of the present invention, in which the second guide is made of a rail having the same shape as that of the guide shaft rod, that is, a rod shape. In the present embodiment, the same parts as in the above embodiment will be indicated by adding 200 to the part number.

In the present embodiment, the second guide 850 having a rod-like shape which is installed in parallel with the guide shaft rod 850 is provided directly under the guide shaft rod 830 installed in the horizontal direction on the substrate 801. At the bottom of the wheel 820, a rolling roll 821 is installed at the center of the second guide 850 to be in contact with both sides of the second guide 850, so that the movable wheel 820 rides on the guide shaft 830. When moving, the movable wheel is suppressed to rotate about the guide shaft bar.

In this embodiment, the rolling rolls 821 on either or both sides of the rolling rolls 821 in contact with both sides of the second guide 850 are selected to eccentrically install and re-described the rolling as shown in FIG. The roll 821 fits and inserts the insertion shaft 823 into the insertion hole 822 formed on the bottom surface of the body of the movable wheel 820, and screw the insertion shaft 823 inserted into the insertion hole 822. Screwed together. At this time, the insertion shaft 823 to be inserted into the insertion hole 822 configured in the body of the movable wheel 820 at the position to be eccentric in the rolling roll 821, the rolling roll 821 is the eccentric insertion shaft ( 823) is rotated about to achieve a gap control with the second guide. In other words, the bonding state between the rolling roll 821 and the second guide 850 installed at both sides with the second guide 850 at the center is accurately adjusted.

8 and 9 show another embodiment of the present invention, which is different from the above embodiment in that the second guide is installed in parallel with the guide shaft. In the present embodiment, for the same parts as the above embodiment, 300 will be added to the part numbers.

In the present exemplary embodiment, the second guide 950 having a rod shape is installed at a position close to the guide shaft rod 930 installed in the horizontal direction on the substrate 901 in parallel with the guide shaft rod 930. In this way, the movable wheel 920 is installed on the guide shaft bar 930 and the second guide 950 which are arranged in pairs on both the left and right sides, and the shock absorption of the desired transmission line is achieved. In this embodiment, another characteristic configuration is that both wheels are movable wheels, that is, one side is used as a fixed wheel and the other side is a movable wheel as in the present embodiment. will be.

As described above, the embodiment of the present invention has been described, but the present invention is not limited thereto and may be changed within the scope of the claims.

Claims (7)

In the winding machine of all the wire bundles made of the desired winding body by using the mold, it is freely movable on the fixed wheel and the guide shaft bar installed on the horizontal line on the substrate on both sides of the wire path of the copper wire, and is elastically installed by the elastic member. In the tension control device of the winding machine is provided with a movable wheel for absorbing the shock of the transmission line, the guide shaft rod is used as a general polishing rod without using a spline shaft as a polishing rod, and the guide shaft at the lower portion of the guide shaft rod A tension adjusting device for a copper wire winding machine, which is provided in parallel with the rod and has a second guide for controlling the movable wheel moving on the guide shaft rod to rotate about the guide shaft rod to maintain balance. The tension adjusting device of a copper wire winding machine according to claim 1, wherein the second guide comprises a rod which rotates in the same line as the guide shaft bar using the shaft pin of the vertical stand provided directly below the guide shaft bar. The tension adjusting device of a copper wire winding machine according to claim 1, wherein the second guide is installed in parallel with the guide shaft bar directly under the guide shaft bar, and has a rod shape. 4. The tension adjusting device for a copper wire winding machine according to claim 3, wherein rolling rolls are provided on both sides of the lower portion of the movable wheel with respect to the second guide. The tension adjusting device of a copper wire winding machine according to claim 4, wherein the rolling rolls provided on both lower sides of the movable wheel are provided with eccentric shafts. The tension adjusting device of a copper wire winding machine according to claim 1, wherein the second guide is installed in parallel with the guide shaft bar. The tension adjusting device of a copper wire winding machine according to claim 1, wherein both wheels for guiding the transmission line are constituted by movable wheels.