SU950925A1 - Shelter for areas of transloading of loose materials - Google Patents

Description

(54) COVERING DOWNLOADS FOR BULK MATERIALS

Claims (1)

1 The invention relates to the mining industry and can be used for the dedusting of places of transshipment of bulk materials also in the metallurgical and other industries. An aspiration shelter is known, including an external and internal housing with seals, a loading chute, an aspiration pipe, and a foam generator with a foam dispenser. The disadvantages of this air cover are the large amount of suction air and the difficulty of operation. Closest to the invention is a shelter for the bulk material transfer layer, including an outer and an inner housing with an upper wall, a loading chute, a bypass and a suction joint. The disadvantages of such a shelter are large volumes of exhausted air and the insufficient efficiency of bleeding the entrainment of small fractions of the material being loaded. The purpose of the invention is to reduce the amount of aspirated air and reduce the entrainment of thin 4 fractions; overloaded material. The goal is achieved by the fact that the upper wall of the inner hull of the shelter is filled with a convex perforated surface and forms an additional suction chamber with the walls of the loading chute and baynas, and is equipped with an additional suction nozzle. FIG. 1 shows a shelter for bulk material handling sites, general view; in fig. 2 is the same, section A-A in FIG. 1. Shelter of loading places of this material contains inner 1 and outer case 2, loading chute 3, bypass 4 and main suction nozzle 5. In the innermost case 1, the cover forms a continuation of loading chute 3 and bypass 4 closed from the ends of the side walls 6. On the section between the loading chute 3 and the bypass 4, the wall of the 7th interior of the housing 1 is convexly hollowed out with a perforation. BayipH of the inner casing U1FYT11Ya Convex derf (ф10} oval upper wall 7 together with the walls of the loading chute 8 and bypass 4 extends the chamber of the additional suction 8, which has an additional outlet pipe 9. In the upper part, the loading chute 3 communicates with the bypass 4 through holes 1O. Internal The Kqpnyc 1 shelter has an I septum, and the loading case is covered from the end by a shutter. The shelter operation is as follows: The dusty air flow ejected by the falling material goes into the inner building cover 1: Under the action of the executive suction 8 removed through the chamber, Air (in the amount of 5% of entering the shelter through the loading chute 3) most of the air flow sticking to the perforated upper wall 7 of the inner shell of the cover 1, which at the same time, the lower wall of the additional suction chamber 8 is introduced and sent to the bypass 4, and then through the openings H is returned to the loading chute 3 for re-ejection. Thus, the constant recirculation of a significant part of the air flow around the chamber of the additional outlet 8 occurs. As a result, the amount of aspirated air removed from the outer shelter through the main branch pipe is reduced by the amount of air reshaping in the shelter, and this This leads to a significant reduction in the entrainment of fine fractions of the material into the aspiration system and causes an increase in the efficiency of dust removal. The use of the invention will make it possible to increase the dust content of the air in the areas of overload to the level of sanitary standards and reduce operating costs. Invention Shelter for bulk solids handling sites, including an internal research institute building with an upper wall, loading chute, bypass and suction nozzle, characterized in that, in order to reduce the amount of aspirated air and reduce entrainment of small fractions of dust, the upper wall of the inner case is filled with a convex perforated surface and forms with the walls of the loading chute and the bypass chamber an additional suction, which is equipped with an additional end fitting. f -t-f t "- + f-i-f - + t -n - ++ H- -H-h-H + -H-4-4-4 + - -f 12 V / fig 2