DE212C - Machine for the representation of spiral springs - Google Patents

Description

1877.

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WESTERN WIRE INDUSTRY CLUB. Machine for the representation of spiral springs.

Patented in the German Empire on July 3, 1877. Longest duration: March 18, 1892.

The principle according to which the springs are made by means of the machine described below is based on the fact that three points define a circle, and that one goes through it these three points can only lay a single circle.

The machine is so constructed that it supplies springs of all sorts, namely: cylindrical, conical, double conical and finally feathers with a bulge in the Middle, like those that are used for moderator lamps etc.

Over two rollers or wheels MM, sheet I, FIG ι., And 2, with screwed-groove, which sit on the shafts PP ', a third, smaller roller G is positioned at the end of an upward and downward movable prism NN. A fourth roller M ' is attached to the shaft P ¹ , which is mounted on the horizontal arms of the lever JJ in such a way that by unscrewing the screws K (Fig. 1, sheet I), the shaft P * is depressed, and therefore the roller M ¹ grasps the wire passed between it and the roller M and continues it under pressure. The periphery of the role M \. is ribbed so that the wire cannot slide and the circumference is measured to be 20 cm in length; the role thus serves as a measuring wheel for the wire lengths that are required for the springs.

If during the advancement of the wire between the pulleys MAf, G and M (Fig. 1 sheet I), the position of the pulley G is changed by pulling the prism N downwards at an even speed, and if the pulley G is then evenly moved with the same If the speed is returned to the first position, a spring is created, the coils of which decrease in diameter and then expand again to the same extent.

The movement of the machine is based on the shaft O , which is provided with the crank S for manual operation, and also for eventual. Belt operation carries the TT pulleys. The gear / transmits the rotation 'of the shaft O through the gears / to the shafts P, Q, P ¹ and P ² , as can be seen from the drawing, with a transmission ratio of 1: 2. The conical friction disk wedged on the shaft O outside the machine frame B drives the shaft D resting in the bearings CC, which carries the double screw Γ at the head end. The diameters of the conical disks H ' and H are in the same ratio to one another as /: / namely = 1: 2.

The piece CCC, which carries the bearing CC, can be rotated around the shaft OO (FIG. 2, sheet I) and can be adjusted by means of a nut screw U as desired. The endless screw engages in a wheel-ff R mounted on the shaft ZZ ; the other end of this shaft bears an eccentric disk. £; Fig. 1, sheet I, shows this disk E from the front.

The prism NN, to which the roller G is attached, is moved up and down by an angle lever LL , which has its pivot point in X. An arm L ', also rotatable about X , rests with its upper end, which is provided with a small roller G ² , on the eccentric EE . Arm L ' and lever L are connected to one another by a screw V ¹ and two nut screws E' E ¹ are used to adjust them so that they form an angle lever of a certain invariable angle. With a single revolution of the shaft Z , the action of the eccentric disk (Fig. 1, sheet I), the roller G is slowly led down and back up again. The wire, which has now passed under it, first makes further turns, which gradually contract and then expand again.

The shape of the spring produced in this way is determined by the shape of the disk E and the number of teeth on the worm wheel R. The more teeth the latter has, the more revolutions of the worm, including the main shaft O and the rollers MMM ' driven by the same, are required for a full turn of the disk E , and consequently a greater length of wire is passed under the Mefs roller M ¹ . The worm gears R and the various disks are of course kept in stock for the various types of springs and placed on the shaft Z for use.

To set up the eccentric disk E for the production of, for example, a double conical spring, the roller G ² is first placed on the weakest part of the eccentric and the screw V is lifted out; the wire FF

is inserted between the rollers, and by turning the crank S , the lever LL is adjusted by turning the nut screws E'E 'so that the circle formed by the wire passing through has the maximum diameter required for the pattern spring . Then you make half a turn on the eccentric to see whether the wire winding corresponds to the desired smallest diameter of the spring.

The required for spring wire length is determined by the-set-up at the opposite end of the shaft Z worm wheel R, for which purpose, as has been mentioned above, the bearing piece C of the shaft D depending on the diameter of the wheel R by means of the clamping screw U can be adjusted . In continuous operation, a hammer, which is guided from the shaft Z by a lifting thumb, eccentric or, as shown on page II, through a washer with a notch and a bracket with a tooth, makes a notch in the wire after every single rotation of the shaft Z. and so ends the pen. ;

In order to give the spring coils the necessary distance, the rollers M ¹ and M must not lie in the same plane with the free-standing roller M; small discs W allow the rollers to be given the necessary position.

In the manufacture of cylindrical springs, the screw V is suspended; the lever ZZZ ¹ therefore remains immobile and the roller G does not change its position as a result.

Claims (5)

Patent claims: ■; 1. The application of three roles, one of which, its position changes according to the construction and adjustment of the machine. '; 2. The use of levers related to ·; with an eccentric roller determine the intermittently recurring sizes of the diameter of spiral springs. 3. The use of a measuring wheel, with which the length of the wire for the passage ' is determined in the machine. 4. The disposition of the roll M to the ribbed. Roller JIf \ which, working like a rolling mill, moves the wire forward. : 5. The combination of the rollers M and M ' with the roller G, which changes its position, thereby eliminating the previously common wooden reels on which the springs were previously rotated. ■. . For this purpose 2 sheets of drawings.