DE1948863C - - Google Patents

Description

Furthermore, it proves to be advantageous in the device according to the invention that the removed Sample can be filled directly into an appropriate container without coming into contact with the atmosphere to come, so that thereby a change or influence of the sample taken is excluded from the outside.

The fulfillment is in the following on the basis of Drawing described for example; in this shows ίο

Fig. 1 Scheraatically a rotary kiln in sectional end view with a sampler according to the invention in the form of a bottom-mounted, continuous, curved pipe; a subsequent position of the sampler is shown above the furnace with a dashed line Lines shown,

F i g. Figure 2 shows the pipe of FIG. 1 in side view,

F i g. 3 is a perspective view of a sampler - According to the invention, in which the pipeline is formed from sections of straight pipes is,

F i g. 4 the sampler of FIG. 3 in the position below the furnace that of FIG. 1, the sampler in the section along line ZZ of FIG. 3 is shown

F i g. 5 the sampler of FIG. 3 in the position above the furnace that of FIG. 1, the sampler in the section along line ZZ of FIG. 3 is shown

F i g. 6 is a top view of the sampler according to FIG. 3 and

F i g. 7 is a sectional view of a sampler similar to that of FIG. 3 is and through an approach is modified at the inlet segment.

The mode of operation of the sampler is now taken in relation to the arrival of the sample Material described by the pipeline in the various illustrated embodiments, in which corresponding parts are identified by the same reference numbers.

The sampler shown is attached to the outlet opening in the wall L of a rotary kiln in such a way that it stands radially close to the outside and rotates with the kiln. An inlet segment A penetrates the outlet opening into the interior of the furnace M. The sampler is oriented in accordance with the direction of rotation of the furnace, which will be more understandable below. If, as a result of the rotation of the oven, the sampler passes under the layer of material being treated in the oven (see FIGS. 1 and 4), at least the inlet segment AB fills with material R. A sample S of this material falls through as B continues to rotate the next part BC of the pipeline and then iv ± the intermediate transfer segment CD. When the sampler reaches a position above the top of the furnace (as shown in phantom in Fig. 1 and shown in Fig. 5), the sample falls through the transfer segment CD and the inlet segment discharges the excess material back into it , as shown at N the oven. As the furnace continues to rotate, the sample is transferred from D through the connecting passage to E , from where it falls through outlet segment EF to outlet F when the sampler approaches the bottom of the furnace again (Figures I and 4). It can be seen from this that the material taken for the sample passes around a loop HBCDEK , which is formed by the segments of the pipeline. In this way, a small sample of the material can be taken in an oven once per revolution without opening the oven to atmosphere, as long as the direction of the loop corresponds to the direction of rotation of the oven. As shown at P in FIG. 7, the size of the sample is determined by the size of the connecting passages between the segments and by the pipe diameter.

The inlet segment carries a clamping flange Q for attachment to the furnace. The part of the inlet opening which is beyond the flange and protrudes into the furnace can be made in various shapes and lengths in order to take a sample at different parts of the material layer. The segment AB can be extended beyond B (to G according to FIG. 7), so that the sample is only taken up in Γ when this additional length of the tube has been filled. At the outlet opening F a simple cover z. B. be attached by a bayonet socket in order to attach the sampler to an oven in which the gases are under pressure, and to close the sampler when it is not needed.

As shown in FIGS. 4 and 5, the connection bushings BC and DE of the sampler of FIG. 3 beveled with respect to the other segments of the bushing to assist in the advancement of the sample around the loop so that it approximates the movement obtained in the embodiment of FIGS.

The sample falling out of the outlet segment can of course be carried out in any convenient way Way to be collected in a suitable container below the stove.

Although it is generally necessary to use the oven to attach and remove the sampler to stop, the furnace may stop to remove the sampler up to a point Time to be postponed.

The sampler is preferably made of heat-resistant tubular steel. One from one Pipe manufactured with a 4 inch diameter, typical structure totaling 30 inches, can be used be able to take samples at about 1360 g per revolution.

Although the sampler has been described in terms of segments that are external to one another are formed, the tube that forms any individual segment can also lie within the tube, which forms the other segment, as far as the resulting pipeline is required Loop provides.

For this purpose 2 sheets of drawings

Claims (5)

Patent claims: 1. Sampling device for attachment to a rotating treatment chamber, where S the device is a pipeline with an inlet segment for direct material uptake from the chamber and an outlet segment located essentially parallel to the inlet segment for emptying the material removed for the sample and with a transmission segment connected to these two segments ,, characterized in that the transmission segment (CD) is designed as a loop (HBCDEK) . 2. Sampling device according to claim 1, characterized in that it has the shape of a continuous, simply curved tube (AHBCDEKF) . 3. Sampling device according to claim 1, characterized in that it comprises a series of substantially parallel, straight tubes H, CD, K) which are connected to one another by transverse tubes (BC, DE). 4. Sampling device according to claim 1 as od. ^ R 3, characterized in that the transmission segment is designed as a straight pipe piece (CD) which is parallel to the other two segments and at both ends through transverse ducts (BC, DE) with the inlet (AB) or outlet segment (EF) is connected in such a way that these segments (AB, CD, EF) and ducts (BC, DE) form a loop. 5. Sampling device according to claim 4, characterized in that it has a shoulder (G) on the inlet segment (AB) on the other side of the loop. 40 The invention relates to a sampling device for attachment to a rotating treatment chamber, the apparatus comprising a conduit having an inlet segment for direct material intake from the chamber and an outlet segment substantially parallel to the inlet segment for emptying the material taken for the sample as well as with one of these two segments connecting transmission segment. A previously normally used device for taking samples creates a possibility that the material can freely fall to the floor from an outlet opening in the side of the furnace. Subsequent the material must be shoveled into cans. This is dirty and dangerous, and that Material is exposed to the atmosphere for an excessively long time with the associated risk, that I can change the sample. Furthermore, it is common practice to use concentric tubes that are terminated at one end and having a slot lengthways and one connected to outer handles Inner tube can be inserted into a hole in the oven side. The slot of the outer tube is as required aligned accordingly. The inner tube is then rotated by means of the handles so that the Slots match so that the material can pass from the furnace into the inner tube. The slot is then closed by turning the inner tube again, and the sample or an inner container holding it will be removed. The furnace must be set within a very short period (one revolution) stopped twice and started again, which is why the sample obtained does not meet normal operating conditions can correspond. The object of the invention is to provide a device for taking samples from a treatment to create granules subjected to a rotating treatment device, with which a sample corresponding to normal operating conditions without interrupting the activity of the Treatment device is filled directly into a container. To achieve this object, the invention provides that the transmission segment is designed as a loop is. According to an advantageous development of the invention is intended to be in the form of a continuous, singly curved tube. A preferred embodiment of the invention provides that it is a series of substantially parallel, has straight tubes which are interconnected by transverse tubes. According to a further advantageous embodiment of the invention it is provided that the transmission segment is designed as a straight pipe section, the parallel to the other two segments and at both ends by transverse ducts is connected to the inlet or outlet segment, that these segments and passages a Form a loop. In a preferred embodiment, it can also be provided that they have an approach the inlet segment beyond the loop. In this way, in the case of the continuous, curved tube, the tube taken for the sample Material in a virtually continuous manner through the pipeline from the inlet port to the Outlet opening under the influence of gravity during rotation of the treatment device move on. In the case where the pipeline is formed in sections, the material taken for the sample arrives Continue through the pipeline in sections, which are regulated by aligning the transverse feedthroughs which can be normal to the three segments or at different angles, to support the movement of defined quantities of material through the pipeline without falling back. The invention is particularly applicable where the rotary treatment device is a rotary cement kiln is. If the sampler according to the invention is used, representative samples can a heat-treated material is easily transferred to the furnace to any Stage can be removed without interrupting the furnace process. A significant technical advance can thus be seen in the fact that the rotary kiln or another rotating treatment device for sampling does not have to be stopped, so that with it related business interruptions are avoided.