SK277715B6 - Method of postforming of glass tubes or rods and device for realization of this method - Google Patents

Abstract

Method of postforming of glass tubes or rods with nonrotating external and/or internal surface to decorative external or internal spiral is realized so, that on external surface of glass tube (1) or rod is touchable affected by perpendicular forces to longitudinal axis of glass tube (1) or rod. With the profit is this force developed by winding-up of longitudinal axis of drawing rolls (3) in the angle equal dimension and in the range to 45 degrees with regard to axis perpendicular to longitudinal axis of glass tube (1) or rod device for realization of this method has at least one couple of rotating drawing rolls (3), in which there is at least one drawing roll (3) forced turned. All drawing rolls (3) are in their longitudinal axis adjustable with regard to axis perpendicular to the direction of drawing of glass tube (1) or rod in the range of the angle up to 45 degrees.

Description

Technical field

The invention relates to a method of creeping glass tubes or rods with a non-rotatable outer and / or inner surface. The glass tubes or rods 5 are continuously drawn by a traction machine on a traction path between the traction rolls.

The invention also relates to an apparatus for carrying out this shaping method, which comprises a traction path at the end of which is located a traction machine with traction rolls for pulling glass tubes or rods.

BACKGROUND OF THE INVENTION

The glass gob in the form of a glass tube or rod flows out of the glass dispenser, possibly equipped with a mandrel or a plunger, which is guided to the traction path of the drawing device. The towing device consists, for example, of a trailer. from an endless tension belt 20 stretched between two rotating rollers. Collets are attached to the surface of the endless draw belt to hold the glass tube or rod on the draw belt. The collets spaced at regular intervals on the tensioning belt are opened and clamped using 25 cams and springs. After the cam is run out, the collets are clamped by means of springs and the clamped collets are held by a glass tube or rod which is further carried on the traction path, at the end of which the collets run onto another cam to open them. devices, e.g. cutting or chopping device.

Another type of towing device consists of two endlessly extending towing bands extending parallel to one another between the rotating rollers. A glass tube or rod is guided between the two towing belts.

It is also known to have a traction device comprising a traction track, at the end of which a traction machine with traction rolls is located. 40

In the above methods of guiding the glass tube or rod on the traction path, it may be bent and to a greater extent may exhibit defects such as the ovality of the outer surface and the eccentric location of the inner opening of the tumbled tube. 45

A method for shaping non-rotating outer surfaces of glass rods or non-rotating inner surfaces of glass tubes is known.

E.g. in Czechoslovak patent no. 143 516 discloses an apparatus for producing glass tubes 50 of non-circular cross-sections. This device allows the production of oval tubes, as well as the curvature of the oval arches or the tubes of the shape of three, four, six or even polygonal surfaces with concave or straight walls and slightly rounded edges. The plastic deformation device of the hub comprises at least one pair of rotary cone-shaped pressure rollers and a washer of rotary shape. The pressure rollers of each pair are facing each other with larger diameters and their axes clamp towards the shaped space defined by a 60 angle.

In the Czechoslovak author certificate no. 183 162 discloses a method of forming non-circular cross-sections of continuously drawn glass tubes and cylinders, including an apparatus for performing the method. The molten glass 65 bypasses the plunger tip ending with mandrels, according to which the molten glass is expanded and shaped to the desired cross-sectional shape and clearance of the drawn tube or cylinder.

The glass rods with a non-rotatable outer surface or glass tubes with a non-rotatable outer or inner surface thus obtained are chopped or cut to the desired length in a further technological operation.

SUMMARY OF THE INVENTION

Further creeping of the continuously drawn glass tubes or rods of the non-rotatable outer and / or inner surface allows the creep method according to the invention, characterized in that the outer surface of the glass tube or rod is subjected to forces perpendicular to the longitudinal axis of the glass tube or rod. .

Preferably, forces acting in a direction perpendicular to the longitudinal axis of the glass tube or rod are induced by rotating the longitudinal axes of the draw rollers at an angle of equal magnitude and within 45 ° relative to the axis perpendicular to the longitudinal axis of the glass tube or rod.

An apparatus according to the invention comprising a traction path, at the end of which is located a traction machine with traction rolls for pulling a glass tube or rod, serves to carry out this method. The essence of the invention is that the draw rollers are rotatable and are arranged in at least one pair in which at least one draw roll is rotatably forced. All draw rollers are adjustable in their longitudinal axes with respect to the axis perpendicular to the pulling direction of the sweetened tube or rod in the range up to 45 °.

As a result of this solution, the glass tube or rod rotates about its longitudinal axis on its trajectory, and during this rotation the non-rotating surface is formed into a particular spiral shape. The nature of the spiral depends on the pulling speed, the rotational speed and the shape of the non-rotating surface, which may have the shape of a n-angle, e.g. three, four, five, six, octagon, or star, arch, flower, and so on.

When a glass tube or rod is applied in a traction machine with a force perpendicular to its longitudinal axis, the tube or rod is safely guided on the traction path and rotates over the entire traction path to creep its non-rotating surface in a still plastic state at the beginning of the traction path. .

The draw rollers are arranged in at least one pair facing opposite to provide the thrust required to pull the tube. At least one roller is rotatably forced. This draw roller rotates the glass tube or rod and its movement is transferred to the next draw roller, which also begins to rotate. The range of adjustment of the angles of the draw rollers in their longitudinal axis relative to the axis perpendicular to the pulling direction depends on the desired twist of the glass tube or rod and its outer diameter.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention is described in detail below in two exemplary embodiments shown in the accompanying drawings, in which: FIG. 1 shows the guide of the glass tube of the inner square opening to the traction path, where a substantial part of the traction path is shown.

Fig. 2 shows a hexagonal cross-section of a glass tube on a traction path with three pairs of traction cylinders, Fig. 3 in a graphical representation of the force acting of a traction roller on a shaped glass tube; 4 and 5 the shapes of glass tubes and glass rods.

DETAILED DESCRIPTION OF THE INVENTION

Example 1

The feeder outlet (not shown) is provided with a cylindrical plunger with equally spaced cylindrical mandrels. The glass flowing out of the glass dispenser opening flows around this plunger, which forms an inner square profile in the glass. The obtained glass tube 1 with an inner square hole is guided to the traction track 2 and from there to a traction machine, a substantial part of which is formed by a pair of traction rolls 3 (Fig. 1). The glass tube 1 has e.g. outer diameter 2 mm, square inner hole side is 0.8 mm. The diameter of the draw rollers 3 is 100 mm, their longitudinal axes being offset from the axis perpendicular to the longitudinal axis of the glass tube 1 by the same angle, 10 °. One of the draw rollers 3 is rotatably forced and rotates at a speed of 350 rpm. On the outer surface of the glass tube 1 at a pulling speed of 1.8 m. s' ¹ is applied in contact at opposite points with forces acting perpendicularly to the longitudinal axis of the glass tube 1. The forced rotary draw roller 3 rotates both the glass tube 1 and the opposite rotary roller 3. The glass tube 1 rotates in its longitudinal axis over the entire trajectory 2 and at the beginning of the pulling path 2, when the glass tube 1 is still in a plastic state, it is deformed into an inner spiral, which under the given conditions represents a spiral (Fig. 4) with a thread pitch of about 36 mm.

Example 2

An enamel strip flows out of the feed opening of the feeder and is molded in a known manner into a glass rod 5 of hexagonal cross-section. The glass rod 5 is guided to the traction path 2 between three pairs of traction rollers 3 (FIG. 2). In each pair of drawing rollers 3, one roll 3 is always rotatably forced. In the case of a long hauling track 2, all the towing rollers 3 can be forced to rotate. The described 5 mm outside diameter circle passes on the traction path 2 at a speed of 0.3 m.s ^-1 between three pairs of 120 mm diameter traction rolls 3 rotating at 50 rpm. The longitudinal axes of the draw rollers 3 are rotatable at an angle of 15 ° diverted from a direction perpendicular to the longitudinal axis of the glass rod 5.

Under these conditions, at the beginning of the pulling path 2, the glass rod 5, which is still in a plastic state, is deformed into an outer spiral 4 (FIG. 5), the thread pitch of which is approximately 60 mm.

For the purpose of explaining the invention, FIG. 3 is a graphical representation of the force acting of the pulling cylinder 3 on the glass tube 1 by means of vectors A, B and C and at speeds a, b and c. Vector C expresses the force exerted by the rotation of the draw roller 3 and transmitted to the outer surface of the glass tube

1. Due to the stiffness of the glass tube 1, the vector of force C acting perpendicularly to the longitudinal axis of the pulling roller 3 decomposes into two vectors A and B, perpendicular to each other. Vector B acting parallel to the longitudinal axis of the glass tube 1 causes the glass tube 1 to be drawn in a straight direction. The vector A acting on the surface of the glass tube 1 in a direction perpendicular to the longitudinal axis of the glass tube causes it to rotate about the longitudinal axis.

If c is the circumferential speed of the draw rollers 3, the drawing speed in the direct direction b will correspond to the relation b = c.cos a, where a is the angle of rotation of the draw rollers 3 from the axis perpendicular to the longitudinal axis of the glass tube. will then correspond to the relation a = c.sin and. The resulting rotation speed n of the glass tube 1 will then depend on its outer diameter d and will be defined by the relation a

n = -.

π.ά

Industrial usability

The solution serves to create a decorative inner or outer spiral on glass tubes 1 or sticks 5 of a non-rotatable outer and / or inner surface, which are intended for jewelery industry, for chandelier pendants etc.

Claims (3)

PATENT CLAIMS A method for creeping glass tubes or rods of a non-rotatable outer and / or inner surface that are continuously drawn on a trajectory by a pulling machine between pulling rollers, characterized in that the outer surface of the glass tube or rod is subjected to tactile, perpendicular forces on the longitudinal axis of the glass tube or rod. 2. The method of claim 1, wherein forces acting in a direction perpendicular to the longitudinal axis of the glass tube or rod are induced by rotating the longitudinal axes of the draw rollers at an angle of equal magnitude and within 45 ° relative to the axis perpendicular to the longitudinal axis of the glass. tubes or sticks. An apparatus for carrying out the method according to items 1 to 2, comprising a traction path at the end of which is located a traction machine with traction rolls for pulling a glass tube or rod, characterized in that the traction rolls (3) are rotatable and arranged in at least one pair of which at least one draw roller (3) is rotatably forced, all draw rollers (3) being adjustable in their longitudinal axes relative to the axis perpendicular to the pulling direction of the glass tube (1) or rod (5) in the range up to 45 °.