DE971643C - Method and device for processing minerals, in particular hard coal, in low fluidity - Google Patents

Description

Method and device for processing minerals, in particular Bituminous coal, in heavy liquid The main patent relates to a method and a Device for processing minerals, in particular hard coal, in heavy liquid with the help of centrifugal force. The feed material is transported with a flow of transport liquid in the direction of the axis of rotation through a heavy fluid rotating field that is within one filled with heavy liquid, closed or below that of the rotating field generated back pressure held container is maintained and only on the periphery is in communication with the interior of the container. With this procedure, the light good components in the transport liquid & stream, while the heavy outward i through the heavy fluid rotating field and leak into the container.

The present invention relates to an extremely advantageous and useful one Modification of the method and the device according to patent 944 121, in which according to the invention, the transport liquid flow on the circumference of the container in the direction of rotation and preferably in the plane of the heavy fluid rotating field approximately tangentially züi this is fed. He leaves the container again after a the largest possible circumferential distance tangentially. Furthermore, in the axial direction of the container a rinsing liquid stream, preferably of water, through the central part of the Rotating field-es passed through, which displaced the light ones after the rotating field center Discharges good constituents on an ongoing basis. In this way the rotating field is created by the flow of transport liquid not disturbed and enough opportunity for the light components of the task given to move within the rotating field towards its center of rotation, from where they are passed through the rotating field centrally in the axial direction Rinsing liquid flow are continuously removed.

The rotating field is preferably conical in the space between two Maintain traction sheaves of an impeller. The gap points in the middle to The axis of rotation has an inlet opening on one side and an outlet opening on the other for the central flushing liquid flow. The container for the impeller is in the Area of the impeller circumference equipped with an annular space in which the impeller protrudes with its circumferential slot and at the approximately tangential one and one Outlet nozzles for the transport liquid flow are connected.

When operating the device with heavy liquid suspensions the weight required to maintain the density in the rotating field according to the invention with the central flushing flow introduced into the rotating field and thereby in its grain size so roughly dimensioned that it will certainly be thrown out of the flushing flow into the rotating field is and the same penetrated under the action of centrifugal forces to the outside.

The drawing shows an embodiment of the subject matter of the invention shown, namely Fig. i shows a cross section of the device along the line IJ in Fig.: 2, while Fig. 2 shows a section along line II-II in Fig. I.

In a container i there is housed an impeller 2 which essentially consists of two preferably conical drive pulleys 3, 4. The traction sheaves enclose a space which has a central inlet opening through the hollow drive shaft 5 on one side and a central outlet opening 6 for a flushing liquid flow on the opposite side. The drive shaft 5 is led out of the container i in a pressure-tight manner by means of the stuffing box 7. The outlet opening 6 is in front of an outlet nozzle 8 in the container and is against the interior of the same by a seal 9, for. B. a gap or labyrinth seal, sealed. The space between the traction sheaves is only connected to the container via the annular slot on the circumference of the impeller. The container i surrounds the impeller with play and has an annular space ii opposite the annular slot io of the impeller, in which an inlet nozzle 1: 2 is approximately tangential to the impeller and in the direction of rotation of the same and an outlet nozzle 13 is tangential to the container circumference and is spaced apart in the circumferential direction of the annular space merge. The cross section of the outlet connection 13 can be adjusted by means of a throttle valve 14.

Mode of operation During operation, the container i and the impeller: 2 are filled with heavy liquid. The impeller then generates a dynamic pressure in the container i, which depends on the impeller speed and the weight of the heavy liquid. A transport liquid flow consisting of heavy liquid is fed to the container i through the nozzle 1: 2, which enters the impeller approximately tangentially, participates in its rotary movement in the area of the annular slot io in the impeller and exits the container i again tangentially through the nozzle 13. By appropriately dimensioning the inlet pressure of the transport liquid flow and the throttle cross section 14, the pressure in the container is dimensioned so high that the impeller cannot be emptied by the pumping action. The heavy liquid content of the impeller then performs a flow-free rotation with the latter and forms the heavy liquid rotating field a. The flow speed of the transport liquid flow in the area of the rotating field circumference preferably corresponds approximately to the circumferential speed of the rotating field. Through the hollow drive shaft 5 , a rinsing liquid stream of water or heavy liquid is fed centrally to the rotating field a, which flows through the rotating field in the region of its axis of rotation and leaves it again through the outlet opening 6. The feed material is added to the transport liquid flow and with it arrives in the circumferential zone of the rotating field and thus in the area of the highest centrifugal effect. The light constituents of the feed material are displaced sharply towards the center of rotation of the field into the area of the central flushing flow, which discharges them, while the heavy constituents remain outside in the transport liquid flow and leave the container with it through the outlet nozzle 13.

The separation density in the rotating field a can be maintained by a slight excess pressure of the transport liquid flow, under which heavy liquid is continuously introduced into the rotating field from the outside to the inside. The heavy liquid can also be fed to the field with the central flushing flow through the hollow shaft 5 , in particular when using suspensions of heavy substances. The load added to the flushing flow is then centrifuged out of the central flushing flow in the area of the rotating field and continuously feeds the rotating field from the inside to the outside. The grain size of the weighted material is dimensioned so roughly that it will be centrifuged out of the flushing flow with certainty.

This has the considerable advantage that the rinsing liquid which removes the light constituents does not need to be subjected to weight recovery. In order to give the scavenging flow loaded with the charged substance a rotational speed necessary for the safe ejection of the charged substance , a deflection disk 15 can be provided between the two traction sheaves 3, 4, which guides the scavenging flow into an area of higher circumferential speed of the impeller contents. Furthermore, radial blades 16 can be provided in the entry zone of the flushing flow, which inevitably set the flushing flow in revolutions.

Claims (1)

PATENT CLAIMS: i. Method for processing minerals, in particular hard coal, in heavy liquid with the help of centrifugal force, according to which the material to be processed is guided into a heavy fluid rotating field with a transport fluid flow, which is maintained within a container filled with heavy fluid, closed or held under the dynamic pressure generated by the rotating field and only is in connection on the circumference with the inside of the container, according to Patent 944 121, characterized in that the transport liquid flow is fed to the heavy liquid rotating field on the circumference of the container (i) in the direction of rotation and in the plane of the heavy liquid rotating field (a), approximately tangential to this, and the same after the greatest possible circumferential distance leaves tangentially again and that in the axial direction of the container a rinsing liquid flow, preferably of water, is passed through the central part of the rotating field (a), which displaces the light ones towards the center of the rotating field th good constituents continuously discharges. : 2. Method according to claim i, characterized in that the flow speed of the supplied transport liquid flow in the area of the rotating field (a) is set approximately equal to its peripheral speed. Documents considered: German Patent No. 804403; German Patent Applications P i: 25o IVb / i2eD (published on g 8 1 95 1.), C 6 1 5 VI / ia (published on:. 26 io the 1950s.), P 3381 VI / ia (published on 31. 5 . 1951); French patent specification No. 978 177.