US747428A - Glass-cutting machine. - Google Patents

Description

PATENTED DEG. 22,- 1903.

. FLA. HUBBUG'H GLASS CUTTING MACHINE.

APPLICATION IILED DBO. 16, L902.

' 2 SHEETS-SHEET 1.

N0 MODEL.

Unvenlofi ms NORRIS PETERS w, FN TO-UTHO WASMNDTDN. I:v c.

No. 747,428. PATENTED DEC. 22, 1903.

' P. HUBBUGH.

GLASS CUTTING MACHINE.

APPLICATION FILED DEUJIG, 1902.

N0 MODEL. 2 SHEETS-SHEET 2.

- Unvnibr.

THE nomu's PETERS co. PuoYo-umu, wAsumuwm 0.1:;

, and counter-shaft.

UNITED STATES Patented December 22, 1903.

PATENT OFFICE.

THE AUTOMATIC GLASS OUTTI DON, ENGLAND.

NG MACHINE SYNDICATE, OF LON- GLASS-CUTTING MACHIN E.

SPECIFICATION forming part of Letters Patent No. 747,428, dated December 22, 1903. Application filed December 16, 1902. $erial No. 136.440. (No model.)

To all whom it may concern.-

Beitknown that LFRANZ ANTON HUBBUOH, a subject of the Emperor of Germany, residing at Strassburg, Germany, have invented certain new and useful Improvements in' Glass-Cutting Machines, of which the following is a specification.

My invention has reference to improvements in glass-cutting machines, and relates more especially to automatic twin machines with oscillating cutting-disks. It differs from the machine disclosed in United States Letters Patent No. 631,640 principally as regards the position of the arms carrying the cutting-disks and in having two cuttingwheels acting simultaneously on two Opposite parts of the work.

My invention is illustrated by the appended drawings, in which-- v Figure 1 is a front elevation of the machine, and Fig. 2 a section on the line A B of Fig. 5. Fig. 3 represents a detail view of the work-rotating cam to be hereinafter referred to. Fig. 4 is a side elevation of the disengaging mechanism. Fig. 5 is a side elevation of the machine, partly in section. Fig. 6 is a plan of the same.

In the drawings only the top part of the frame on which the mechanism'is mounted is shown. At the top of the frame are two lugs which receive pins on which the oscillating arms b are mounted. The lower ends of these arms are bored and form bearings for the shaft carrying the cutting-disks's. The latter are driven by the flexible shafts w, cooperating by means of bevel-gearing k with a pulley s, driven from the main shafting. From the bosses of the arms 6 horizontal arms extend carrying sliding weights 9': The effect of these weights is to force the arms bin the direction toward each other, whereby the adjustable bolts n are pressed against the levers '0, which raise and lower the cutting-disks, determining the time during which the disk remains in contact with the work 0 being cut. The levers o are mounted on the same pins as the arms I), but their bosses each carry a second arm 0, so

half a revolution.

The latter is provided that arms 12 0 form a bell-crank lever. Rollers r are mounted at the extremities of the arms 0, between which rollers a wedge is enters at intervals, so as to force the arms apart. The wedgelc is located at the end of the double-armed lever m, which is drawn upon at d, Fig. 5. If the wedge is is raised, the arms 0, and therefore also the arms 'v,.will be forced apart, and the cutting-disks are removed the pinion t, gear-wheel r, and acord passing round the grooved pulley 00. This shaft to is provided with suitable, cams.

The work 0 is carried by the support u,

working up and down onthe uprightf. The

work is held in the support on a cork mandrel, which is connected with the work-rotating device, while the bottom of the inverted work"e. g., tum bler-is pressed down on the mandrel by means of aspindle u. The mandrel carries the ratchet-wheel I, the number of teeth of which is selected according to'the number of facets to be cut on the tumbler. It will be noted that the latter during the whole period of Working only has to make The upright f is hollow, and thesupport u cooperates with a spindle in the interior of the upright. The lever z is coupled to this spindle at one end, its opposite end being jointed to the rod (1. At the center of -the lever z is a roller running onacam on the shaft to. If the cam lifts the lever z, the work is'likewise elevated and pushed between the disks .3, which cut the facets required." If the cam allowsthe lever z to sink, the work descends, the friction between support u and uprightf being overcome by a weight suspended by the chain g, Fig. 5.. The work is rotated during this period by means of a cam 6, Fig. 3, mounted on the shaft to. The cam lifts a. lever jointmined number of revolutions.

ed to the rod h, which reciprocates the horizontal spindle d in its bearings t". The spindle d is provided with a pin 7;, engaging with one end of a bell-crank leverp, Fig. 2, the other arm of which leverp carries a pawl which engages in the teeth of the wheel Z, so that the latter is advanced by one tooth at each rotation of the shaft to.

One workman has to attend some six machines and cannot, therefore, always be present when the work on the machine is finished. The machines must therefore stop automatically, and this is done by uncoupling the shaft to, on which the cams e and e are mounted and which is rotated by the toothed wheel t, Figs. 2 and 4. The cam e efiects the up-and-down motion of the work, while the cam e raises and sinks the cutting-disks.

Fig. 4 shows to a somewhat enlarged scale the parts which effect uncoupling of the shaft to after a desired number of rotations. The toothed wheel t, which is rotated from the counter-shaft pulley s by means of toothed gearing and cord pulleys, is not mounted directly upon the shaft w, Figs. 1 and 2, but is carried by a disk q, keyed to the shaft to and provided with a peripheral slot, in which engages the hook y of the pivoted arm 2, which is secured to an arm of the Wheel t. The hook y of the arm .2 is held in the slot of the disk g by means of a fiat spring, and the shaft to is rotated in the direction of the arrow 1 when the wheelt is set in rotation by the counter-shaft. The hook y therefore must be withdrawn from the slot as soon as the shaft to has made the predeter- For this purpose a ratchet-wheel n is mounted on a pin projecting from the frame of the machine, Figs. 1 and 2. The hub of this wheel is formed as acasing and contains a spring tending to turn the wheel at in the direction of the arrow 2, Fig. 4. At the other end of the said pin a double-armed lever 0 is loosely mounted, the horizontal arm of which rests on a small cam of the shaft 10', sothat at each rotation of the latter a cam b lifts the one arm of the lever 0 through an angle of such extent that the other arm of this lever 0 by means of the pawl q, pivoted to it at as, Fig. 4, advances the wheel 02 farther in the direction of the arrow 3, In order that the wheel it may not spring back again owing to the spring already described, a double-armed lever a is provided on the main frame vertically above the shaft to, having a pawl c, which after theadvance of the wheel by one tooth falls behind the latter. The pawl q can now retreat each time in order at each revolution of the shaft to to advance the wheel n by one tooth. When the shaft w has made the desired number of revolutions, the wheel n has to effect disengagement. For this purpose a peripheral slot is provided inwhich a pin m, projecting from the wheel at, is located. When disengagement is required, the pin m has traveled so far that the slanting end h of the arm 2 during the rotation of the wheel 25 strikes the pin m. This causes the book 1 to be lifted from the notch in'the disk q, and the wheel 25 now rotates farther without the disk q and shaft 10'. When the tumbler has been removed and a new piece of work introduced, so that the machine has to be started again-11. e., the shaft w caused to rotate-it is only necessary to pull the handle of the lever a in the direction of the arrow 4. This will cause the pawl o, and thus also the pawl g above it, to-be raised out of the wheel n. The spring in the hub of the wheel at, which during the rotation of the work was gradually compressed, now comes into action and turns the wheel at backward until a pin d, secured to it and projecting rearwardly, strikes against a stop on the frame of the machine. The handle of the lever 61. must now be let go, and the machine commences to work again instantly, the hook y snapping into the notch in the periphery of the disk g. In order that the machine may thus be automatically stopped after a smaller number of revolutions of the shaft w, four holes are provided in the wheel 72 for the pin (1, which can thus be adjusted as desired. Final adjustment is effected by sliding the pin m in the slot in the wheel n. V

The above-described devices codperate in such manner that the whole of the work is regulated by the shaft w. When a tumbler has been finished and a second is to be set in the machine, the disks .9 are first drawn apart by turning over the lever h, so that the wedge is lifted as high as possible and held in the position of rest. The counter-shaft during this time is not stopped, since the shaft to is uncoupled by the automatic disengaging device. When the tumbler has been adjusted in the lowest position of the support u, the disks 3 must be gradually lowered upon it. The disks therefore engage first at the bottom of the tumbler. By slightly turning the lever to the shaft to is now coupled with the wheel 25, which is continually in rotation,

being driven from the counter-shaft, whereupon the various cams come into action. The tumbler is first pushed upward a certain definite distance for the cutting of the facets. Immediately on reaching its highest position the cutting-disks are lifted, a small lever f, pivoted at g being depressed by a cam on the shaft 11;, whereby at d a pull is exercised which forces the wedge k between the rollers 'r. The cam now allows the tumbler, with its support, to descend into the lowest position, and during this time the pawl of the lever p engages with the ratchet-wheel Z and rotates the work by the amount of one facet. Thus if the tumbler, e. g., has twelve surfaces to be cut, the wheel l must be turned through six teeth distributed over one-half of the wheel. This operation of the machine will continue until all the facets are cut. The wheel n counts the number and disengages the wheel if from the shaft w immediately all the surfaces have been cut.

What I claim is- 1. A glass-cutting machine, comprising two oscillating bell-crank levers, a vertical cutting-disk carried by one arm of each of said levers, flexible shafts driving said disks, a wedgeheaded lever engaging between the ends of the other arms of said bell-crank le ver, a cam-shaft actuating said wedge-headed lever whereby the disks may be pressed apart, a vertically reciprocating and rotating workholder, means actuated by said cam-shaft for rotating said work-holder, and clutch mechanism for throwing the cam-shaft out of gear on completion of the work, all substantially as described.

2. A'glass-cutting machine, comprising two oscillating bell-crank levers, vertical cuttingdisks carried by one arm of each of said levers, counterweighted oscillating lever-arms, devices carriedby said arms for maintaining the proper distance between work and cutting-disks, flexible shafts driving said disks, a wedge-headed lever engaging between the ends of the other arms of said bell-crank lever, a cam-shaft actuating said wedge-headed lever whereby the disks may be pressed apart, a vertically reciprocating and rotating workholder, means actuated by said cam-shaft for rotating said work-holder, and clutch mechanism for throwing the cam-shaft out of gear on completion of the work, all substantially as described.

3. A glass-cutting machine,comprising two oscillating bell-crank levers,vertical cuttingdisks carried by one arm of each of said levers,counterweighted oscillating lever-arms, devices carried by said arms for maintaining the proper distance between work and cutting-disks, flexible shafts driving said disks, a wedge-headed lever engaging between the ends of the other arms of said bell-crank lever,a cam-shaft actuating said wedge-headed lever, whereby the disks may be pressed apart, a vertically reciprocating and rotating work-holder, means actuated by said camshaft for rotating said work-holder, consisting of a lever system operated by said camshaft, a horizontal sliding spindle actuated by said lever system, a pivoted bell-crank lever having a pawlarm actuated by said ver,a cam-shaft actuating said wedge-headed.

lever, whereby the disks may be pressed apart, a vertically reciprocating and rotating work-holder, means actuated by said camshaft for rotating said work-holder, consisting of a lever system operated by said camshaft, a horizontal sliding spindle actuated by said lever system, a pivoted bell-crank lever having a pawl-arm actuated by said spindle, and a ratchet-wheel on the toolholder rotated by said pawl, and clutch mechanism for throwing the cam-shaft out of gear on completion of the work, comprising a toothed wheel,receiving its motion from the shaft ng, notched disk keyed t0 the cam-shaft, a clutch -arm carried by the toothed wheel engaging in said notch, a ratchet-wheel pivoted to a stationary part of the framing, spring means tending to rotate said ratchet-wheel in a contrary direction to the direction of rotation of the toothed wheel, a bell-crank lever loosely mounted on the axis of said ratchet-wheel, one arm of which leveris actuated by the cam-shaft, a pawl carried by the other arm engaging in the ratchetwheel teeth, a double-armed hand-lever carrying a pawl engaging in said ratchet-Wheel below the first-mentioned pawl and a laterally-projecting pin on the ratchetwheel which releases the clutch-arm on striking it, all substantially as described.

In testimony that I claim the foregoing as my invention I have signed my name in presence of two subscribing witnesses.

FRANZ ANTON HUBBUOH.

Witnesses:

GUSTAV SOHWEISS, MARTHA L. BRITTAIN.

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