DE867291C - Method of treating ampoules - Google Patents

Description

Methods of Treating Ampoules This invention relates on a method for the treatment of ampoules by melting a mass a certain part of the surface e.g. a small part or along a Line, which is more fragile than the rest of the ampoule. The coating is selected so that the total contraction exerted by the coating material suffers on cooling from the softening temperature to room temperature, greater is the total contraction of the glass container on which the coating material is applied and thus a state of stress is created in the coating.

Ampoules, vials and similar jar containers are closed by one the end through which they are filled, after introducing the contents in a Flame sealed. By closing the container in this way, the contents are protected against Contamination and evaporation protected. If you want to remove the content is the usual method of breaking off the neck of an ampoule e.g. B. the, the surface scratch the ampoule by placing a file across it in one spot or line pulling the neck, thereby reducing the fragility of the glass at the file mark increase, whereupon one grips the neck between thumb and finger and a flexion pressure on both sides of the weakened line sufficient to break the glass. This opening method has the disadvantage that it is a different device than that Ampoule itself, e.g. B. a file requires. In some cases it is difficult to open, and throat splitting may occur.

It is also suggested to weaken the container by in the glass itself while it is still at a relatively high temperature door is in a predetermined place, usually with the help of a cold object, creates tension. The danger with previously plasticized containers is that that unless the degree of weakening or the kerge is within certain limits adjustable, occasional breakage either by thermal shock or vibration can easily occur.

It has been found through experiments that the fragility of the glass can be regulated by the type of melted coating, d. H. that the breaking strength on the coated part by regulating the differences in expansion or contraction of the melted material versus the expansion or contraction of the glass container can be increased or decreased. It is therefore important when carrying out the invention to expand and regulate the components of the coating material so that a predetermined Difference between the contraction of the glass and the coating is obtained.

It is a further object of the invention to apply a coating, which is visible on the glass either by color or by outline at the point or surface Generates characters on which a cross pressure should be exerted in order to break the Effect glass.

It is well known to color-mark ampoules locally, including by Melting colored glasses to mark ampoules with colorless but different types To be able to tell content apart. But it is new, not such markings according to the color, but rather according to its influence on the fragility of the melting point choose.

As a result of the completely different objective, the hot melt must according to The present invention meet different requirements than known markings was the case to avoid confusion.

Further purposes will become apparent from the following description of the invention visible in connection with the drawings.

Fig. 1 is a view of a sealed ampoule with a contrasting one molten material in a relatively small area; Fig. 2 is a View of another type of ampoule showing the coating material along a Line is attached; Figure 3 is a view of a sealed vial used daxu is intended to bandage material or the like Line is attached at which the vial is to be broken; Fig. 4 explains the Application of the invention to an ampoule with a retracted neck.

In one embodiment of the invention, a frit with a predetermined composition, the degree of contraction of which has been determined in advance, applied. The frit can, for. B. from borosilicates of lead, sodium, or potassium Consist of lithium.

The frit is finely ground and coated with a suitable carrier, z. B. a combination of oils mixed. To the place of the fragile surface to identify, the coating material preferably contains coloring substances, such. B. Salts of cobalt, chromium, titanium or antimony, but the coating can also, if desired, the same color as the container and the break point by a difference be distinguishable in the contour. After applying the coating to the container are glass and coating material heated to a sufficiently high temperature, to melt the frit, but without the melting temperature of the glass is achieved. When the coating melts onto the glass, a certain amount occurs mutual penetration of the coating and glass. The coating solidifies on cooling forming a firm bond between the coating and the container. Usually the softening point of the coating is between about 450 and 600 °.

The term softening point as used herein relates to the maximum on the expansion curve depending on the temperature when determined by means of the interferometer dilatometer. The actual melting temperatures, used to bond the coating material to the glass are higher and range from 500 to 600 °.

Since coating and gals are selected so that their extension or Contraction differ from each other, the one material becomes to a greater extent than the other will shrink. The result is that after cooling the material with a greater contraction, namely the coating, is placed under tension. The difference in the expansion or contraction of the coating and the glass can be like this be regulated so that when a lower further pressure is applied, the breaking strength of the material is exceeded and the break occurs, It has been found that a accidental breakage due to vibration or thermal shock, as is the case with pre-shear or drawing by cold tools is almost entirely avoided.

As examples of the way in which selected coatings can be applied to glass objects, rolures from the glasses, the analyzes of which are given below, have been provided with coatings in a relatively small area, the composition of which is also given in the table. The named guests have the following analyzes: ABCDE %%%%% SiO2 ................................ 74.7 65.2 67.6 - 68.3 B2O3 ................................ 9.6 5.0 1.5 - 2.2 Al2O3 ............................... 5.6 2.4 2.8 18.0 2.0 ZnO ................................. 0.1 5.4 - 10.0 6.8 MgO ................................. - 1.6 4.0 - 0.1 ABCDE %%%%% CaO ....................................... 0.9 2.6 5.6 - 5.7 Na2O ...................................... 6.4 9.1 15.1 - 14 , 5 K2O ....................................... 0.5 0.8 1.3 - 0.4 Sb2O5 ..................................... 0.009 0.6 - - - Fe2O3 ..................................... - 3.3 - - - MnO ....................................... - 4.0 - - - BaO ....................................... 2.2 - 1.9 - - P2O5 ...................................... - - - 72.0 - As2O5 ..................................... 0.027 - - - - Expansion coefficient .................... 60 x 10-7 69 x 10-7 91 x 10-7 59 x 10-7 88 x 10-7 Softening temperature ° C ................. 653 612 590 675 600 Stoving temperature ° C ..................... 676 548 520 605 536 Two of the coatings used have the following analyzes: away %% SiO2 ........................... 27.9 27.2 B2O3 ........................... 4.2 2.9 Al2O3 .......................... 1.3 0.84 TIO2 ........................... 12.5 - ZnO ............................ - 2.3 PbO ............................ 48.8 51.0 CaO = MgO ...................... 0.16 0.17 Na2O ........................... 2.9 1.08 K2O ............................ 0.19 0.22 Li2O ........................... 0.73 - - 0.86 Cr2O3 .......................... - 5.6 CoO ............................ - 1.2 CdO ............................ - 7.2 As2O5 .......................... 0.58 - Sb2O5 .......................... - 0.1 expansion coefficient ......... 86 x 10-7 73 x 10-7 Softening temperature ° C 463 484 A third lead chloride coating, labeled c, was applied to a particular glass from the previous analysis table. This coating material consists of 74.5% lead and 25.5% chlorine.

The lead chloride softens at a temperature of 501 and has a coefficient of expansion difficult to determine, but which is relatively large. Tests carried out showed a linear thermal expansion coefficient from about 298 x 10-7 per degree over a temperature range from room temperature to 300 °.

In the case of the glass labeled A and coated with composition a is the coefficient of expansion of the glass per degree at ordinary temperatures 0.000 005, while that of the coating is 0.000 0086. The softening temperature of the Gleses is 653 ° and that of the coating 463 °. The coated glass is heated to the stoving temperature of the glass (575 °), at which temperature the coating melts, but no deformation of the glass occurs. THAT'S WITH THE COVER provided glass is cooled. The cover material is still soft up to about 460 °, but becomes solid at about 430 ° on further cooling. When this temperature is reached the coating is firmly connected to the glass and must therefore assume its dimensions.

When cooling below this temperature range, infloge begins the difference between the contractions of the coating and the glass is a tension to develop. IN this temperature range, the container glass experiences a contraction, the extent of which remains constant with the temperature, while the coating material a Suffers contraction, the extent of which changes with temperature. The contraction of the coating material in this temperature range is greater than the contraction this container. As the cooling progresses, a temperature is reached at which the coating material assumes a contraction that remains constant with the temperature, but when this point is reached the coating material has a greater contraction experienced than the container. This discrepancy in contraction manifests itself in the Occurrence of tension between the coating and the glass, with the direction of the Stress is such that a state of stress occurs in the coating material.

This tension helps initiate a fracture when a additional tension occurs by flexion of the fingers or other means.

The glass is directly below the applied coating material in a state of compression.

An analysis of the stress pattern shows, however, that the zone of the glass is in a state of tension immediately outside the coating material.

These local stresses in the glass can be used as a starting point serve for the breakage in the event of additional stress. This explains why the trend of the fracture was observed at times along the edge of the applied coating material will.

When an external load is applied to the combination of glass and the Coating material is added so that they have an additional stress load in the Surface results, the break will take place at the point where the combined stress loads first exceed the dielectric strength of the material. If this point is in the coating itself, the crack will begin in the surface of the coating material and progress through the coating into the glass. He kicks more often Point the greatest weakness in the glass in the immediate area of the applied Coating adjacent zone. Because of this, breakage usually occurs at the borderline of the applied coating.

The coating a becomes solid at about 430 ° on cooling from this temperature down to room temperature this material undergoes a contraction of 45 microns per centimeter. Glass A has a contraction of 20 microns per centimeter at Cooling from 430 ° to room temperature. Therefore, when the coating material a is applied to the Glass A is melted and the compound is cooled to room temperature, the coating contracts 125% more than the glass. The ones to break The force required by bending the glass is 58% less when the coating a is melted on the surface than with the glass without the coating.

The glass D has a coefficient of thermal expansion of 0.000 0059 per degree and when it cools down from 430 ° to room temperature it pulls by about 24 Microns per centimeter. Therefore, when a coating a is melted onto the glass D. and the compound is cooled to room temperature, the coating will turn 88% contract more than the glass. The glass coated with the coating material a D requires 44% less stress to break from bending than that uncoated glass.

The coating b solidifies at about 450 ° and experiences when it cools from at this temperature a contraction of about 48 microns per centimeter up to room temperature. Glass B pulls about 30 microns as it cools from 450 ° to room temperature per centimeter together. Therefore, when the coating b is melted onto the glass B. and the compound is cooled to room temperature, the coating will turn over 37% more than contract the glass. It was found by experiment that the glass B, the glass B coated with coating b, 15% less stress to break needed than the uncoated glass. The glass E has a coefficient of expansion of 0.000 0088 per degree and experiences a when cooling from 430 ° to room temperature Contraction of about 36 microns per centimeter.

Therefore, if the coating material a melted on the glass E and If the compound is cooled to room temperature, the covering material will become contract by 25% more than the glass.

Experiments have shown that the coated with the coating material a Glass E requires 11% less stress to be broken by beige than the uncoated one Glass E.

A number of experiments have found that a minimum value the weakening by the applied coating must be achieved in order to ensure a secure and to ensure easy breakage with the application of force and also to ensure irregular breakage Avoid breaking or splitting the ampoule.

The minimum degree of weakening appears to be in the area at which requires at least 11% less force to pull the coated Break off the neck of the ampoule as required to break the uncoated ampoule were.

By combining a carefully selected coating with a given one Glass can have any degree of weakening above this 11% minimum.

So it is clear that the important factors in achieving the expediency and applicability of the present invention does not cover the usually determined coefficients of expansion aind, but the total contractions of the molten coating and glass even when cooling from the furnace or melting temperature to room temperature.

It should be noted that all coating materials at deeper Temperatures than the deformation temperatures of the glasses soften or melt. Therefore a connection is made without destroying the glass body on which the coating is applied is applied, formed. It should also be noted that glasses A, B, c and E contain silicate, while glass D is silicate-free. On the other hand, the coating materials are a and b contain silicate and therefore different from material c, which is silicate-free, It can therefore be seen that very satisfactory results can be obtained with any combination Made of silicate gel with both silicate-containing and silicate-free coating material be achieved. In any combination, however, the contraction of the remainder is essential larger than that of the vitreous. On the other hand, it is characteristic that if the contraction of the coating and the glass are the same or approximately the same, the strength of the area of the combined gas and coating does not decrease is and can even be reinforced. It is therefore imperative to choose a coating with a greater contraction than that of the glass is important.

The coating material can be applied to the container A, as in one of the figures shown e.g. B. over a small area, as at B in Fig. 1, or along a Line as shown at B 'in Figs. 2, 3 and 4 is attached. In some It may be desirable to fill in the marker or line above the larger one Part or possibly the entire circumference of the ampoule to extend to the Line or the place of the break, especially if an uneven thickness or contour is present with more than normal resistance. While special glass frits or Enamels are mentioned in the preceding examples, the covering materials can be used be selected from a wide list of fusible coating materials, their Dimensions and properties have been determined in advance.

The container is attached to the part where the coating is known Method attached, broken when opened. While usually to open Finger pressure on both sides of the fragile section marked by color and or the shape is recognizable, dividing can also be done by impact, z. B. heat or cold, take place at the fragile point.

The terms color and coating are used interchangeably herein, however, both relate to the fusible material. The different examples from Glasses and coatings given in this specification are for illustrative purposes only of the invention, not compiled as its limitation.

Claims (5)

PATENT CLAIMS: 1. Method for the treatment of ampoules, vials and the like. Made of glass, characterized in that one at a predetermined point and to the predetermined extent over the circumference a mass, preferably in the form of a Line or stripe, the contraction coefficient of which is greater than that of the glass, then the glass is heated until the coating material melts and then glass and melted application compound with the generation of local stresses at the point of application, which encourage breakage at this point, to room temperature cools down. 2. The method according to claim 1, characterized in that a melting frit is used, the melting point of which is significantly below the softening point of the ampoule or vial glass. 3. Ampoules, vials or the like made of glass according to the method according to claim 1 and 2, characterized in that their fragility is locally caused by melting a glass frit, which has a larger contraction coefficient than the glass, is increased. 4. Ampoule, vial or the like. made of glass according to claim 3, characterized in that that the melting frit at the junction between the neck and the transition is melted to the shoulder part. 5. Ampoule, vial or the like. made of glass according to claim 3 and 4, characterized characterized in that the frit is colored differently than the gals of the ampoules, Vials or the like.