DE19908623A1 - Production of small precision glass tubes used as sample tubes for analytical investigations comprises over-working the outer surface of a glass tube, heating, pulling the tube and cutting into lengths - Google Patents

Abstract

Small precision glass tubes are produced by over-working the outer surface of a glass tube, heating, pulling the tube and cutting into lengths. Production of small precision glass tubes comprises: (a) over-working the outer surface of a glass tube producing a precise pre-determined outer diameter and a precise predetermined wall thickness distribution; (b) heating the glass tube to its processing and pulling temperature; (c) uniformly pulling the glass tube while maintaining the outer diameter to wall thickness distribution, outer diameter to inner diameter and wall thickness distribution to inner diameter; (d) continuously measuring the outer and inner diameter of the pulled glass tube at at least one measuring point radially to the pulling direction; (e) comparing the measured values with theoretical values; (f) regulating and adjusting the processing and pulling temperatures and the supply and pulling speed of the glass tube; and (g) cutting into lengths.

Description

The invention relates to a method for producing precision glass tubes made of a glass tube with a precise, predetermined internal diameter ser, and their use.

The manufacture of precision glass tubes, i.e. H. Glass tube with completely ge wrestle dimensional deviations (tolerances) is very complex and with high Manufacturing costs associated.

For example, precision glass tubes must be used as Pro Bearings for magnetic nuclear magnetic resonance examinations water from 3.0 mm to 15.0 mm with a tolerance of ≦ ± 0.007 mm and a very small wall thickness distribution of 0.25 mm with a tolerance of ≦ ± 0.005 mm.

In order to achieve the required dimensions and small dimensional deviations, must be produced using conventional, continuous tube drawing processes provided glass tubes with an extensive post-treatment the. This is how a glass tube is first made using a conventional method drawn, which has approximately the required dimensions. The heated glass The tube is then further processed according to the KPG process in order to obtain a pre tisen, to achieve predetermined inner diameter with small tolerances chen. After the glass tube has been closed on one side, the outside becomes area until the desired outer diameter or the ge sanded the desired distribution of wall thickness and then to Errei original transparency, polished.

In addition to the elaborate production and the associated high Ko is the final yield of precision glass tubes that meet the requirements correspond, very low.

It is therefore an object of the invention to find a method which is simple allows more precise and less expensive production of precision glass tubes, that enables a low error rate and thus a higher final yield, whereby the required dimensions should be adhered to exactly and the dimension  deviations reach or even undercut the quality of previous processes should.

This object is achieved with the method described in claim 1 solved.

The method according to the invention is a rework and redraw procedures.

A finished glass tube with a precise, predetermined inner diameter, with in front certain outer diameter and predetermined wall thickness distribution, for example, one after a conventional, continuous pipe drawing process drive glass tube manufactured and internally calibrated according to the KGP process, is on the outer surface to produce a precise, predetermined Outside diameter and a precise, predetermined wall thickness distribution mechanically revised.

The so manufactured and post-processed, still relatively thick glass tube be All features regarding the required dimensions and dimensional accuracy of the precision glass tube to be manufactured. For example, the ratio of outside diameter to wall thickness distribution, outside diameter to inner diameter and wall thickness distribution to the inside diameter exactly the conditions of the precision glass to be manufactured tube.

In a further process step, the glass tube is processed tion or drawing temperature warmed, the heating preferably the same moderate.

While pulling the heated glass tube evenly, for example in an egg ner in itself known recovery system, taking into account the above-mentioned ratios, becomes a thin-walled, long precision glass tubes made.

In order to achieve the required final dimension and the small tolerances, both the outside diameter and the inside diameter of the drawn NEN glass tube constantly, at least at one measuring point radially to Ziehrich tion, measured. The measured values are compared with the predetermined target values of the  Precision glass tube compared. It has to determine the measurement values the use of laser measurement methods is particularly proven.

By direct automatic regulation and setting of the processing or Drawing temperature and the rate of replenishment and removal of the glass tubes, depending on the comparison of the measured and target values, until the measured and If the target values match, the precise, predetermined dimensions and Tolerances of the precision glass tubes set. Then the Precision glass tube cut to length and closed on one side if necessary.

The freshly drawn glass tube (precision glass tube) is preferred cooled evenly, which is achieved for example in that the Procedure in a temperature-controlled, draft-free room, which is closed via a lock is entered, is carried out.

In a further, preferred embodiment of the method, a me revised glass tube with precise, predetermined dimensions and Tolerances drawn so that the precision made from it glass tubes have a factor of 3 to 50 less inside and outside diameter, and a correspondingly smaller wall thickness distribution and Show tolerance than the original glass tube.

In contrast to the previous manufacturing process, in which each is thin walled, and therefore easily fragile glass tubes mechanically reworkable was processed, can be according to the inventive method from one relatively thick, and therefore more fragile glass tube that is easier can be mechanically reworked, very many thin-walled precision glass make tubes. The method according to the invention is not only costly cheaper and less expensive than the previous method, but it is also characterized by a higher final yield and lower error rate te out.

Precision glass tubes can be produced using the method according to the invention are produced that exactly meet the required dimensions and dimensional deviations adhere.

The precision glass produced by the method according to the invention tubes preferably have an inner diameter of 0.5 mm to 19.5 mm,  in particular from 3.5 mm, the tolerance preferably less than ± 0.01 mm, is in particular less than ± 0.007 mm.

The outer diameter preferably has 1.0 mm to 20.0 mm, in particular 5.0 mm, the tolerance preferably less than ± 0.01 mm, in particular re is less than ± 0.007 mm, and the wall thickness distribution is preferred 0.10 mm to 0.50 mm, in particular 0.20 mm to 0.40 mm and especially be preferably 0.25 mm, the tolerance being less than ± 0.01 mm, in particular is less than ± 0.007 mm.

Furthermore, the internally calibrated is mechanically revised Glass tube preferably using a diamond tool, and especially before The mechanical reworking of the outer surface of the glass tube takes place by grinding, thereby grinding the outer surface of the glass tube until the required dimensions and tolerances are reached.

Because the mechanically revised glass tube is pulled again time-consuming polishing of the ground outer surface is not necessary because the required transparency of the precision glass tubes according to the how that sets itself.

Glass tubes with a length of 500 mm to 2000 mm are preferred have mechanically revised by the inventive method and pulled back.

The resulting precision glass tubes are preferred to be 150 to 300 mm cut to length.

The subsequent one-sided closing of the precision glass tubes can via a base molding machine known per se, which is a means further reduction in manufacturing costs.

The precision glass tubes are preferably used as sample holders ear tubes for analytical investigations, especially for magnetic ones Nuclear magnetic resonance examinations.

The following example illustrates the invention.

example

A glass tube manufactured according to the KPG process with a precise In diameter of 70.0 mm and a tolerance of the inner diameter of ± 1.5 mm becomes mechanical by grinding the outer surface revised, with a precise outer diameter of 80.0 mm with a Tolerance of ± 1.5 mm is generated. The outer diameter of the glass tube before grinding is ≧ 80 0 mm ± 1.5 mm. The wall thickness distribution is set to 5.0 mm with a tolerance of ± 1.0 mm. The glass pipe is heated to its processing or drawing temperature. The respective temperature can be taken from the literature for a specific glass or be determined experimentally. While pulling the glass tube evenly in a redrawing system there is a long, thin precision glass tube with an outer diameter of 5.0 mm with a tolerance of ± 0.094 mm, an inside diameter of 4.38 mm with a tolerance of ± 0.094 mm and a wall thickness distribution of 0.31 mm and a tolerance of ± 0.06 mm manufactured. The precision glass tube is cut to 200 mm each and closed on one side.

Claims (15)

1. Process for the production of precision glass tubes from a glass tube with a precise, predetermined inner diameter, characterized by the steps,

• - mechanical reworking of the outer surface of the glass tube while generating a precise, predetermined outer diameter and a precise, predetermined wall thickness distribution,
• - heating the glass tube to its processing or drawing temperature,
• - even pulling of the glass tube while maintaining the ratio se outside diameter to wall thickness distribution, outside diameter to inside diameter and wall thickness distribution to inside diameter,
• - constant measurement of the outside and inside diameter of the drawn glass tube at at least one measuring point radially to the drawing direction,
• - comparison of the measured values with predetermined target values,
• - Regulating and setting the processing or drawing temperature and the replenishment and removal speed of the glass tube, depending on the comparison, until the measured values agree with the target values, and
• - Cut to length and, if necessary, seal the precision glass tubes on one side.

2. The method according to claim 1, characterized, that the drawn glass tube (precision glass tube) evenly abge is cooled. 3. The method according to claim 1 or 2, characterized, that a 3 to 50 times smaller outside and inside diameter and a correspondingly smaller wall thickness distribution and tolerance of Precision glass tube compared to the mechanically revised glass tube is set. 4. The method according to at least one of claims 1 to 3, characterized, that an inside diameter of the precision glass tubes of 0.5 mm to 19.5 mm, in particular 3.5 mm is set.   5. The method according to claim 4, characterized, that a tolerance of the inner diameter of less than ± 0.01 mm, esp special less than ± 0.007 mm is set. 6. The method according to at least one of claims 1 to 5, characterized, that the outer diameter of the precision glass tubes from 1.0 mm to 20.0 mm, in particular of 5.0 mm is set. 7. The method according to claim 6, characterized, that a tolerance of the outer diameter of less than ± 0.01 mm, esp special of less than ± 0.007 mm is set. 8. The method according to at least one of claims 1 to 7, characterized, that a wall thickness distribution of the precision glass tubes from 0.1 mm to 0.5 mm, in particular from 0.2 mm to 0.4 mm is set. 9. The method according to claim 8, characterized, that a tolerance of the wall thickness distribution of less than ± 0.01 mm, ins special of less than ± 0.007 mm is set. 10. The method according to at least one of claims 1 to 9, characterized, that a glass tube, which has a length of 500 mm to 2000 mm, ge is pulled. 11. The method according to at least one of claims 1 to 10, characterized, that the precision glass tubes cut to 150 mm to 300 mm the. 12. The method according to at least one of claims 1 to 11, characterized,  that the outer surface of the glass tube using diamond tools mecha nically revised. 13. The method according to at least one of claims 1 to 12, characterized, that the outer surface of the glass tube is mechanically covered by grinding is being processed. 14. The method according to at least one of claims 1 to 13, characterized, that the glass tube with a precise, predetermined inner diameter after the KPG process is produced. 15. Use of at least one of claims 1 to 14 herge provided precision glass tubes as sample tubes for analyti cal studies, especially for magnetic nuclear magnetic resonance Investigations.