DE458453C - Device for melting glass sockets on hollow glass bodies - Google Patents

Description

Device for melting glass sockets on hollow glass bodies. Devices for fusing nozzles or approaches on hollow glass bodies are known, but with it only nozzles can be melted, whose axis coincides with the longitudinal axis of the hollow glass body collapses. If this is not the case, so far this has to be done Work to be done by hand. The melting of nozzles and similar approaches to elongated hollow glass bodies (e.g. the exciter nozzle to glass rectifier flasks) happened z. B. by hand if the approaches were to be melted obliquely to the longitudinal axis. It was necessary to use the hollow glass body to be provided with the approaches during of the work process to turn continuously so that the softened at the melting point Glass mass did not flow to one side and the wall thickness of the neck on that the entire circumference of the melting point became the same. The hollow glass bodies, however, were usually difficult to handle when heated, and even with well practiced Workers - therefore the production of an uninterrupted series of faultless ones belonged to Workpieces to the exceptions. However, one can generate faulty and therefore generally exclude unusable factory thickness by using the known 'device, in which both the approach and the hollow glass body on matching rotatable Holders can be attached in the appropriate position for melting together, according to the invention in such a way that the one holder is attached to the axis of rotation the melting point of the respectively processed hollow glass body can be pivoted is. If the approaches are to be melted, as in the case mentioned as an example, that its longitudinal axis is the outer wall of the hollow glass body obliquely to its longitudinal axis pierces through, then the device offers the possibility of the approaches only vertically to melt and subsequently with continuous heating of the melting point during the uninterrupted rotation of the entire workpiece around the longitudinal axis of the lugs by pivoting one holder around the axis of rotation of the hollow glass body in the To align the melting point cutting axis at an angle.

In many cases it is important that the angle at which the approaches are to be melted to the glass body is adhered to very precisely. A simple -.Mittel -, the hollow glass body during the relevant part of the operation in DER securely hold the prescribed angle with its Länsachse enclosing position, is that the pivotable clamping device is held in the space required for the various operations layers by a locking mechanism. The locks can be of various types depending on the requirements of the individual cases. For example, you will choose a ratchet if some specific angles, to which a tooth gap of the ratchet expediently corresponds, are often repeated for the axial position of the approaches. On the other hand, use will be made of friction or clamping locks if the angles are to be adjusted on a case-by-case basis. -In the drawing an example of the invention is shown. Fig. I shows a longitudinal section of the device in elevation, Fig. 2 shows a section along the line 2-2 of Fig. I. in side elevation, Fig. 3 a partial section along the line 3-3 of Fig. i in plan.

A bearing a1, in which a support pin is cast, is cast on a base plate a b rests. This pin b carries a circular arc-shaped curved slide guide c, in which a carriage d is guided so that it circles around a point, the in the extension of the axis of the pin b, the center of the curvature of the Slide guide c. The carriage d is stiffened by cross members d ' and at its upper end provided with an arm d =; in a guide bush il is screwed in. One in this sleeve / 'movable, with a conical Hood g 1 provided tube g is under the pressure of a spring g =, with a nut g, serves as a stop. The carriage d carries a shell at its lower end H; it is provided with notches d3, one of which can be rotated on the slide guide c mounted pawl i engages with its ratchet tooth il and- by a spring i = is held in engagement. An air hose is used to supply compressed air into the pipe hl, which connects the bore of the nut g3 with a longitudinal bore b1 of the pin b, which in turn by a transverse bore b = with an annular groove cut out in the bearing a1 a '= and through this is connected to an air hose Ix =. To carry out of the air line b1, k1 is the. Provide the carriage d with recesses d-1, (t5.

To drive the pin b, a belt pulley t is used on a shaft 1l supported in three bearings a3, a4 and a5 and two bevel gear pairs 1711, m = and m3, in. While the bevel gear nzl on the shaft l1 and the bevel gears t17 = and 17t3 on a perpendicular to the shaft! are mounted in two bearings a6 and a7 guided shaft L =, the bevel gear t114 is connected to the journal b. The shaft 11 transmits its movement simultaneously by means of a bevel gear pair rna, tnß to a second shaft 3, which is guided perpendicular thereto in two bearings a3 and a9, and this in turn by means of a bevel gear t117 to a bevel gear mg, which is rotatable in one bearing. This storage is attached to a table top a10, which carries two guide strips all, between which a slide o from a handwheel p by means of a gear g1 mounted in the slide o and a toothed rack g- 'provided on the table top alo in the direction of the axis of a a long wedge r 'provided shaft r, which is parallel to the axis of rotation of the device, is displaceable. The shaft r, which is mounted in a bearing o1 on the slide o and is provided with a spur gear, receives its drive from the bevel gear. It is used to drive an adapter sleeve t, which can be rotated in a bearing and is equipped with a spur gear = 'and a clamping bracket t1. The ratio of all gear pairs working together is 1: 1.

In Fig. I of the drawing, a pear-shaped glass body tt is indicated by dashed lines, to which a connecting piece v is to be melted at a certain angle. For the purpose of producing such workpieces, the glass body u , provided with an injection opening ttl, is inserted between the shell lt and the conical hood g 1 as well as the prepared nozzle v by means of the clamping bracket il into the clamping sleeve t. The glass body u is set by means of the locking pawl i and the grooves d3 so that a generating line of its surface intersects the axis of rotation of the device in the melting point at right angles, for example by inserting the locking tooth il into the rightmost one Groove d3.

After the device is set in rotation from the pulley t is, the melting point (for example by means of a manually operated, in the Drawing of gas blower, not shown) heated until by blowing in Air . in the air hose was a bump on the surface that blows out its The wall finally bursts when more air is blown in. After proper expansion the opening created in this way is approached by the nozzle v under constant heating by moving the slide o by means of the handwheel p to the melting point. As soon as the bodies tt and v touch, they stick together. Now is under further, permanent heating of the melting point of the slide d in the slide guide c pivoted into the position prescribed for the connection nozzle v, in which the Ratchet il engages in another groove d3. Finally, after solidification the melting point, the end of the nozzle which exceeds a prescribed dimension v be melted off.

Claims (1)

PArRINTTANSPRL-CHR: i. Device for melting glass sockets on hollow glass bodies with correspondingly rotatable holders for fastening socket and hollow glass body in the fused-on position, characterized in that one of the holders (e.g. the carriage d with the hood,; 'and the shell h) on its Axis of rotation ( bi about an axis intersecting this axis at the melting point (it is pivotable. Device according to claim r, characterized in that the pivotable holder (d) is secured on its axis of rotation in the positions required for the various work processes by a locking mechanism (il, d3) is recorded.