DE2160982A1 - Measuring cylinder - with base of non-refractory glass bonded to cylinder of refractory glass by plastic part - Google Patents

Abstract

Cylindrical measuring vessel of refractory glass has a base which is not refractory, and is bonded to the cylinder by means of adhesive or by means of a plastic part gripping the cylinder. The base consists of corrosion resistant glass or another corrosion resistant material. The plastic part consists of PTFE or another heat resistant material. The plastic part grips the cylinder to a height of ca. 1 cm on two sides. The cylinder can be removed from the plastic part by hand.

Description

CYLINDRICAL MEASURING VESSEL MADE OF FIRE-RESISTANT GLASS WITH BASE The invention relates to a cylindrical measuring vessel made of refractory glass with an on the, Iand of the measuring vessel, preferably applied by screen printing, horizontal lines comprehensive graduation and with a glass base for the measuring vessel.

There are two types of measuring vessel for each maximum measurable volume. The tall, slender shape is called the graduated cylinder and the broad, squat shape is called man scale length. The known measuring vessels have a base made of glass, which with the Lfeßgefaß is welded. Since you can only weld pale types of glass together, is it is necessary to make the base out of fireproof glass when the measuring vessel is out Refractory glass is0 It is not possible to use a foot made from ordinary glass to weld a measuring vessel made of refractory glass.

Because of the different material value, but mainly because welding both difficult and different for the different materials difficult is a device made of ordinary glass for 3 DM and a device made of fireproof glass for 7 DM on the market, Assuming the same dimensions0 These numbers apply to one of many other single device. Nor is it the case that you have feet on the one hand and on the other hand can manufacture the cylindrical kettle vessels in advance and these can then later weld together. Rather, the welding takes place in one Glashütte instead, as long as the feet and the measuring vessels from their manufacture are hot.

The welding can only be carried out by trained specialists. Nevertheless, such a weld has internal tensions that will one day affect the material tear, the devices are dried and sterilized up to + 2000C0 Dabai the tensions can be released and the weld seam breaks.

If a measuring vessel is damaged, the entire device is worthless The welded-on foot also interferes with the printing of the graduation, including the dashes O In the vast majority of cases, these degrees are and smears as well as inscriptions applied in the screen printing process, which are so high that they are palpable.

Because of the foot, however, the screen printing frame cannot be sufficient Push it far down so that screen printing cannot be carried out in its area For example, with a 100 ml measuring vessel, all values below 10 ml are omitted.

The lower values are also omitted for another reason, for which Just mentioned example, two points are separated out, e.g. the dash for 10 ml and the line for 100 ml. The intermediate areas are then divided linearly because of the necessary accuracy for each measuring vessel individually. Because of that During the welding process, the area just above the bottom of the measuring vessel is no longer exactly cylindrical (e.g. it can be slightly conical), a linear extrapolation in this area would be Scale indicate incorrect values. Vessels of the specified kind are already being made for many generations.

It has also become known to make the foot out of plastic. It has an upward cylindrical sleeve into which the measuring vessel with its lower part can be inserted0 As plastic material is specific is easy and because of withdrawals, voids and also for price reasons Can't be injected as thick as you want, the plastic feet are light.

as a result, it suffers in particular in the case of the graduated cylinders sonlanken Form the stability and the device can tip over.

These and other disadvantages may have been the reasons that Measuring vessels with a plastic base could not establish themselves on the market at all.

The object of the invention is to provide a reading vessel including a foot that avoids all of the above-mentioned disadvantages and also enables measuring vessels made of refractory glass, which are comparable in price with the known ones Devices made of ordinary glass, according to the invention, the task is solved by that the measuring vessel base made of glass is connected to the measuring cylinder with adhesive, or by means of a plastic part that is glued to the bottom of the measuring vessel and a measuring cylinder clamped, is connected to the measuring cylinder 0 This measurement can be applied to the measuring cylinder, But can also be used on mixing cylinders that differ from the first two Distinguish species by the fact that they have a ground inner cone at the top, which can be closed with a stopper so that you shake the cylinder can without liquid flowing out.

It is advantageous if the base of the measuring vessel is made of non-refractory glass0 This makes the measuring vessel cheaper.

It is helpful if the graduation including the dashes reaches to the bottom of the measuring vessel. You can then also reliably read smaller amounts, And because of these quantities, you don't need to use a smaller vessel, its filling level with the same volume is, of course, greater than 0 It is useful if the graduation including all dashes is a round division. This makes one special accurate paralllex-free reading.

Further advantages and features of the invention emerge from the following Description of the exemplary embodiments.

Fig. 1 shows a measuring vessel with glue between the measuring cylinder and measuring vessel base.

Fig. 2 shows an e-cylinder and a measuring vessel base connected by means of a plastic part.

in ::: eßzylinaer 11 consists of glass, isU open at the top and melted shut at the bottom. It has a pouring spout 12. A maximum of 100 inl can be measured. The graduation 13 goes from 10 ml to 10 ml, while the intermediate strokes from 1 ml go to 1 ml. The graduation 13 and the intermediate lines 14 as well as the writing 17 are applied by screen printing and have a palpable height. The ãeßgefäßfuß 28 made of ordinary glass has a hexagonal outline and dome-shaped high vault 29, so that the base of the measuring vessel only stands on its outer areas 31.

The base of the measuring vessel 28 and the measuring cylinder 11 are connected with an adhesive layer 19 (Fig. 1 or a plastic part 15 (Fig, 2) that glued on the measuring vessel foot and that holds the measuring cylinder with a force fit.

The plastic part includes the measuring cylinder of two times, so that the Graduation remains visible down to the base of the measuring cylinder.

The clamping plastic part 15 enables the measuring cylinder to be detached 11

Claims (1)

Claims 1. Cylindrical measuring vessel made of refractory glass with one applied to the wall of the measuring vessel, preferably by screen printing, horizontal graduation with a non-fireproof base of the measuring vessel, characterized in that the measuring vessel base 28 is connected to the measuring cylinder by means of adhesive 19 11 is connected or by means of a plastic part 15 under the measuring vessel bottom 28 is glued on and that holds the LIeßylinder 21 by clamping, with the upper part of the measuring vessel connected ist0 2. measuring vessel according to claim 1, characterized in that de measuring vessel foot 28 is made of non-refractory but corrosion-resistant glass or X is made of other solid is made, which is as corrosion-resistant as possible. 30 measuring vessel according to claim 1 with glue between the measuring cylinder and Measuring vessel base, characterized in that, in contrast to the amalgamation of different Glass types in this gluing by means of an adhesive 19 at different Glass expansions of the measuring cylinder 11 and the base of the measuring vessel 28 in the case of heating and To cool down, hold the measuring cylinder and the base of the measuring vessel together and do not shatter. 4. Measuring vessel according to claim 1 with plastic part 15 between the measuring cylinder and Xeßgefäßfhß, characterized in that the plastic part is made of tetraflourethylene or a similar temperature-resistant material is made. 5. Measuring vessel according to claim 1 with plastic part 15 between the upper part of the measuring vessel and measuring vessel base, characterized in that the plastic part is the measuring cylinder 11 from below about 1 cm high from two sides clamped and that with from Edge of the force that can be applied, the measuring cylinder detaches itself from the plastic part.