DE6606048U - SAMPLER - Google Patents

Description

SAMPLER

Methods for taking samples from liquid iron-steel and metal baths are already known.

Due to the possibility of taking the samples developed by us, the requirements are being met by the industry specimens with larger diameters are also displayed in this way liquid iron, steel and metal baths can be taken, that no slag inclusions from the surface get into the sample. Outside business is supposed to the sample should have as large a diameter as possible. For this reason, the sample design developed by us was would take as follows added.

The sampling tube (Fig. 3a) is not only provided with a capillary (Fig. 3b) and the capillary end (Fig. 3c), but also at the end, which is closed with the cap (Fig. 3d), is narrowed, so here too a small cap- lar-like passage (Fig. 3k) arises. This capillary-like end is again capped, as in FIG. 3 (Fig. 4d) closed. The extraction tube will now be accurate

again as in (Fig. 3) inserted into a cardboard tube (Fig. 3f). If you now bring this embedded extraction pipe (Fig. 3) into the medium to be examined, the penetration of the slag or the oxide layer components into the extraction pipe f (Fig. 3a) prevented. The melting time for the cap) Fig. 4d)

'Is in turn correspondingly the individually selected by the change of the wall thickness to be examined medium so \ daii the final melting of the cap (Fig. 4d) takes place only when the slag or Pxydationsschicht is penetrated.

The medium to be examined can then, according to the principle in j the extraction tube (Fig. 3a) penetrate through the capillary-like opening (Fig. 3k). In said sampling tube (Fig. 3a) be-)-sensitive air escapes through the narrowed kapillarartig] -i or in a capillary projecting side (Fig. 3b) in the '! * Cardboard tube (Fig. 3f). Medium penetrating into the extraction tube (Fig. 3a) reaches the capillary-like narrowed or capillary (Fig. 3b) side of the extraction tube (Fig. 3a). If the medium is not up to this point

■ already previously in the extraction tube until it solidifies

j has cooled, the cooling takes place in the capillary-like Ϊ constriction or the adjacent capillary tube (Fig. 3b). j The amount of heat carried along by the penetrated medium is capillary through the wall of the extraction pipe (Fig. 3a). j-like constricted or n.with a capillary (Fig. 3b) provided end to the investment (Fig. 3e). Thus solidified the penetrated liquid medium at least in the vicinity or ι in the capillary (Fig. 3b) to a solid mass. Depending on

■ Size of the inner diameter of the extraction tube (Fig. 3a) there is the possibility of taking the mass during the removal time, not all the way to the lower end of the capillary (Fig. 3k), completely solidified.

Through the small capillary (Fig. 3k), however, the liquid medium can while pulling out the cardboard tube (Fig. 3f)

no longer run out of the investigating medium. It So there is the possibility to take samples up to a diameter of approx. 50 mm perfectly, yes you can be even larger in diameter.

To achieve rapid cooling of the entire sample, you can immerse the cardboard tube (Fig. 3f) with the entire extraction tube (Fig. 3a) in cold water. So you win a sample that reflects the actual ratio in the liquid medium below the slag cover or below the Corresponds to the oxidation layer at the time of removal. The cooling process inside the extraction tube (Fig. 3a) can be accelerated depending on the extremely high temperatures of the medium to be examined, that the extraction tube (Fig. 3a) and, if necessary, incl. the capillary-like constriction or with a capillary-like end (Fig. 3b) with a jacket made of a very thermally conductive material, e.g. copper (Fig. 3g) is provided.

The design of the cap (Fig. 4d) depends on the one to be examined Medium made, its wall thickness depends on the temperature of the medium to be examined. The melting time of the cap (Fig. 4d) depends on the time it takes to pass the extraction tube (Fig. 3a) through the Bring slag or oxidation layer into the medium to be examined.

In the case of liquid steel, as the medium to be investigated, it is known, however, that this is in the calmed and in the non-calmed Condition to be examined muli. In the steady state, what has been said above applies with regard to the wall thickness of the cap (FIG. 4d). As is well known, unkilled steels are calmed by aluminum or aluminum alloy. The cap (Fig. 4d) of the The extraction tube required for this (Fig. 3a) is made of aluminum. The shape of such a cap is off (Fig. 4) can be seen. The inner diameter of the cap is so large that it is pushed onto the extraction tube (Fig. 3a) according to. The wall thickness is, as (Fig. 3) shows, variable. It depends on the temperature of the steel to be examined. To the aluminum alloy of the To be able to use a cap to calm the steel penetrating into the extraction tube (Fig. 3a), the cap according to <±) manufactured. The middle of the cap base (Fig. 4h) is thinner than the edge of the cap base (Fig. * ± i). The wall thickness of the cylindrical part (Fig. 4j) of the cap corresponds to of the cap edge (Fig. 4i). Melting begins as soon as the sample holder penetrates the slag layer the cap (Fig. * td). The thinnest part of the cap (Fig. 4h) melts first. The liquid, unquenched steel comes with the aluminum alloy when it penetrates the extraction pipe (Fig. 3a) the cap (Fig. 4) in contact. This contact calms this steel. Through the reinforcement the cap (Fig. 4i) ensures that the steel that flows in continues to come into contact with the aluminum and the Cap (Fig. 4) melts further. The calming of the steel is assured on the basis of the tests made. The shape of the extraction tube (Fig. 3a) must not be round, it can also e.g. oval, triangular or star-shaped or similar be executed.

The samples obtained in this way can be used for further chemical investigations.

Claims (7)

PROTECTION CLAIMS 1.) Sampler for taking samples from a liquid Medium below the slag cover or oxide layer, characterized in that the Entxiahmerrohr (Pig. 3a) consists of highly heat-resistant material (e.g. quartz) UQd at one end with the cap (Fig. 3d) and at the other end with a capillary-like constriction or with a Capillary tube is provided. 2.) Cap CPig. 3d) according to item 1, characterized in that the material of the cap (Fig. 3d) matches that to be examined Medium is chosen so as not to falsify the sample taken. 3.) Sntnahmerohr (Fig. 3a) according to pos. 1, characterized in that it is common = on with the cap (Fig. 3d) pos. 2, below Use of a highly heat-resistant investment material (Fig. 3c) is embedded together in a cardboard tube (Fig. 3f) so that part of the cap cylinder (Fig. 3d) in the Investment material lies and the cap base (Fig. 3h) protrudes from the investment material and the cardboard tube. 4.) sampling tube (Fig. 3a) according to item 3, characterized in that the capillary-like constriction or the one with a capillary provided end (Fig. 3b) protrudes inside the cardboard tube from the investment, so that the opening of the capillary is not locked. 5.) Sampling tube (Fig.3a) according to item 4, characterized in that it is surrounded by a good heat conductor (Fig.3g), e.g. copper, for better heat dissipation. 6.) cap (Fig. 3d) according to item 2, characterized in that it is designed for sampling from unstilled medium according to (Fig. 3). 7.) The end of the sampling tube that is immersed in the medium to be measured (Fig. 3a) provided with a capillary-like opening (Fig. 3k).