RU2058830C1 - Hydrocyclone plant for mechanical cleaning of liquid with automatic removal of dehydrated precipitation - Google Patents

Abstract

FIELD: mechanical engineering. SUBSTANCE: plant has hydrocyclones connected between themselves by assembly board and forming together with the latter hydrocyclone assembly for liquid cleaning with one common inlet branch pipe and one outlet branch pipe for purified liquid. Discharging branch pipes of hydrocyclones are hermetically connected with bunker for precipitation collecting and dehydration and are separated from each other inside bynker by cylindrical shells which hinder active agitation and turbulence of flows of thickened precipitation going out of hydrocyclones as well as promote the settling of impurities of thickened flow in bunker. Inside discharing branch pipes there are reflectors made as cones which are bearing surface for descending (thickened) flow and promote better settling of impurities. In lower conical part the bunker has flexible branch pipe for tapping dehydrated precipitation which is overlapped by clamps on rods of pneumatic or hydraulic cylinders. Sensitive body which controls the mass of thickened precipitation and density of dehydrated precipitation in it and passes the information to pneumatic or hydraulic cylinders for discharge of dehydrated precipitation through directive equipment, is connected with the bunker. The plant is also equipped with valve-pulsator which is connected with pressure source and controls the vibration of flexible shell inside the bunker assisting greater thickening of dehydrated precipitation in lower part of the bunker. EFFECT: enhanced efficiency of separating liquid heterogeneous mediums under the action of centrifugal forces. 2 cl, 7 dwg

Description

 The invention relates to techniques for the separation of liquid inhomogeneous media under the action of centrifugal forces and can be used in any industries where mechanical clarification of the liquid and disposal of the precipitate in the desired form is required.

 Known multi-stage hydrocyclone installation [1] which contains liquid-off hydrocyclones with tangential inlet pipes, drain and sand pipes, an expansion chamber with perforated gratings, into which the sand pipes are buried, and a condensed drain separator, the inlet of which is connected to the outlet pipe of the condensed descent of the expansion chamber. The drain pipe of each previous hydrocyclone is connected to the inlet pipe of the subsequent hydrocyclone. The purification of the liquid in such an installation occurs in steps.

 However, such an installation has a low throughput and a low degree of thickening of the sediment.

 Known hydrocyclone installation for thickening suspensions [2] which consists of a hydrocyclone fluid purification unit in the form of an open hydrocyclone with an inlet tangential pipe, a drain pipe and a channel for condensed sludge (sand pipe), a hopper for collecting and dewatering the sludge, tightly connected to the upper part with sand pipe and having a pipe in the lower conical part for the removal of dehydrated sludge. The hydrocyclone is equipped with a thin-layer module for the efficiency of liquid purification. Inside the hopper there are filters and a loosening device that contribute to the dehydration of the thickened sludge. Monitoring the filling of the hopper is carried out by radioisotope elements, which are connected to the electric valve on the sand pipe to open and close the outlet of the thickened sediment. The hopper also has an air discharge nozzle with excess pressure inside the hopper and compressed air from the pressure source for dehydration, as well as to the loosening device. The unloading unit for the dehydrated sludge is made in the form of vibrators mounted opposite to each other in the lower part of the hopper and an electric shutter as a means of shutting off the branch pipe for removing the dehydrated sludge.

 By complicating the design of this installation (the presence of a thin-layer module, a loosening device, filters, all kinds of electric valves, fittings, etc.), it was possible to increase the degree of purification of the liquid and the degree of dehydration of the condensed sludge, but not significantly, since an open type hydrocyclone is used that does not allow reaching the required degree of centrifugal separation. In addition, this installation does not provide a continuous process of sludge dewatering due to the need for filter regeneration during operation. Automation of the dehydrated sludge discharge process has not been achieved. In addition, this installation does not allow for high throughput to achieve a high degree of liquid purification and sludge dewatering.

 The objective of the invention is the provision at high throughput of the installation at the same time a high degree of purification of the liquid, a high degree of dehydration of the condensed sludge and its automatic discharge.

 The problem is solved in that the hydrocyclone installation, including a hydrocyclone fluid purification unit with inlet and drain pipes and a channel for the release of condensed sludge, a hopper for collecting and dewatering the sludge, is tightly connected in the upper part with a channel for the output of the condensed sludge and having a pipe for draining the dehydrated sludge in the lower the conical part, the unloading unit for the dehydrated sludge with means for blocking the branch pipe of its outlet and the pressure source, according to the invention further comprises a guide apparatus connected with a pressure source, and a sensitive body that controls the mass of condensed sludge in the hopper and connected through the guiding equipment to the unloading unit of the dehydrated sludge, the latter being made in the form of pneumatic or hydraulic cylinders, and the branch pipe for removing the dehydrated sludge is elastic. In addition, the hydrocyclone assembly contains two or more hydrocyclones interconnected by a mounting plate, and the outlet channel of the condensed sludge is formed by discharge pipes of hydrocyclones, each discharge pipe being provided with a cylindrical shell surrounding it to separate the flows of thickened sediment and mounted in it coaxially expanding into side of the hopper with a conical reflector. The installation additionally also contains a pulsating valve, and the hopper in the lower part is equipped with an elastic shell, forming with its inner wall a closed cavity associated with the pulsating valve. The pulsating valve, in turn, is connected to a pressure source.

 The invention differs from the prototype in that the installation further comprises a guide apparatus, a sensitive organ controlling the mass of condensed sludge (including the density of the dehydrated sludge) in the hopper, a pulsating valve, an elastic shell in the lower part of the hopper, the guide apparatus is connected to a pressure source; a sensitive body that controls the mass of condensed sludge in the hopper is connected through the guide apparatus to the unloading unit of the dehydrated sludge; the unloading unit is made in the form of pneumatic or hydraulic cylinders; the drain pipe of the dehydrated sludge is made elastic; a hydrocyclone purification unit contains two or more hydrocyclones; hydrocyclones are interconnected by a mounting plate, the outlet channel of the condensed sediment is formed by discharge pipes of hydrocyclones; each discharge nozzle is surrounded by a cylindrical shell and has a conical reflector expanding toward the hopper inside it coaxially with it. The elastic shell forms a closed cavity with the inner wall of the hopper connected to the pulsating valve; the pulsating valve is connected to a pressure source.

 In the proposed installation, the hydrocyclone fluid purification unit with one inlet pipe and one drain pipe is made in the form of two or more hydrocyclones interconnected by a mounting plate, which makes it possible to supply the initial fluid simultaneously to all the inlet cavities of the hydrocyclones and output the cleaned fluid flows through the drain pipe. This embodiment of the hydrocyclone unit allows both to increase the efficiency of purification of the initial liquid through the use of hydrocyclones with the necessary geometry, and throughput due to the set of the required number of hydrocyclones. The cylindrical shells on the unloading nozzles of hydrocyclones prevent the active mixing and swirling of the condensed sludge flows coming from the hydrocyclone assembly into the hopper, purposefully direct these flows to the lower part of the hopper, preventing the removal of contaminants from the hopper. Thus, contamination in the thickened sediment under the action of centrifugal forces in the cylindrical shells and the gravitational field in the hopper is deposited in the lower part of the hopper. Conical reflectors inside the discharge nozzles are, in turn, a supporting surface for the descending flows of condensed sludge, prevent the exit of contaminants from the hopper and contribute to their deposition in the lower part of the hopper due to the vortex motion caused by the geometry of the reflector. Thus, the dehydrated sludge is collected and accumulated in the lower part of the hopper, displacing the liquid, which is connected to the upward flow and is discharged through the drain pipe. There is an effective purification of the initial liquid in the hydrocyclone unit, thickening of contaminants in the cylindrical shells and effective sedimentation and compaction of the sediment. Due to the continuity of the process, the mass of condensed sludge and dehydrated sludge in the hopper increases. A sensitive organ is configured with a preset value, which, when the mass of the hopper reaches a preset value, transmits information through the guiding equipment to the pneumatic or hydraulic cylinders, and a means for shutting off the dehydrated sludge outlet pipe is activated. Thus, an automatic discharge of dehydrated sludge is carried out. With the control of the mass of condensed sludge in the hopper, the density of the dehydrated sludge is also controlled, since these values are interrelated. The elasticity of the drainage pipe for dewatering sludge prevents clogging of the lower part of the hopper and improves automatic discharge of sludge. Moreover, the existing pulsating valve connected to the pressure source enhances the degree of compaction of the dehydrated sludge during its accumulation due to vibration of the elastic shell associated with it and contributes to its unloading unloading. When the unloading took place, i.e. the mass of condensed sludge in the hopper has decreased, then no information is received from the sensitive organ, the branch pipe of the drainage of the dehydrated sludge is blocked. Condensation occurs again. The process is continuous, high throughput.

 In FIG. 1 shows a general view of a hydrocyclone liquid purification unit with automatic removal of dehydrated sludge, FIG. 2 same, top view; in FIG. 3, section AA in FIG. 2; in FIG. 4, 5, 6 variants of execution of a sensitive organ; in FIG. 7 discharge pipe with a cylindrical shell and a conical reflector.

 The installation (Fig. 1) contains a mounting plate 1 with the required number of seats, hydrocyclone modules 2 (instead of hydrocyclone modules there may be hydrocyclones). The hydrocyclone modules 2 are interconnected by a panel and together with the mounting plate 1 form a hydrocyclone fluid purification unit with a common inlet pipe 3 for the initial liquid, a common drain pipe 4 for the purified liquid. Inside the mounting plate 1 (Fig. 2) there is a channel 5 that ensures the supply of the source fluid from the inlet pipe 3 to the inlets of 6 hydrocyclones 2. The discharge pipes 7 of the hydrocyclones 2 (Fig. 1) are hermetically mounted on the cover 8 of the sediment collection and dewatering hopper 9. On a cylindrical shell 10 is mounted to each nozzle. The hopper 9 is supported by a cover 8 through the sensing organ 11 to the supporting frame 12. The sensing organ 11 can be made in the form of springs with a given stiffness (Fig. 3), hydraulic cylinders (Fig. 4), in the form of elastic shells (Fig. 5). Another execution is possible. The sensing organ 11 is connected through an electric converter 13 and an amplifier 14 (Fig. 1) to a guide apparatus, which in this particular example is a spool 15. The apparatus (Fig. 1) also contains a pressure source (compressor) 6, to which a spool 15 is connected and through the pipe 17 and the valve 18, the pulsating valve 19. In the lower part of the hopper 9 (Fig. 1) there is a pipe for the drainage of dehydrated sludge 20, which is made in the form of a hose with an internal elastic wall. For its overlap, diametrically located clamps 21 are used on the rods 22 of the pneumatic cylinders 23. An elastic shell 24 is mounted inside the hopper 9, forming a closed cavity 25 with the inner wall of the hopper 9, which is connected to the valve by the pulsator 19.

 To reduce the removal of contaminants through the ascending flows inside the cylindrical shells 7, conical reflectors 26 can be installed coaxially with them (Fig. 6). For receiving dehydrated sludge there is a receiving container 27.

 Hydrocyclone installation works as follows.

 The source fluid enters through the inlet pipe 3 through the channel 5 in the mounting plate 1 simultaneously to the hydrocyclone modules 2, where in the swirl chambers of each hydrocyclone element 2 is separated, cleaned. The ascending flows of the purified liquid of each hydrocyclone 2 are discharged through the discharge pipe 4, and mechanical impurities (condensed sample) are moved under the action of centrifugal forces into the hopper for collecting and dewatering the sludge 9. Moreover, the cylindrical shells 10 exclude active mixing, swirling the flows of condensed sludge and thereby reduce the outflow contaminants from the hopper 9. In addition, the geometry of the reflectors 26 allows you to create supporting surfaces for the descending flows of condensed sediment directly in the hopper and also exclude ynos contaminants from the hopper 9.

 Condensed sediment under the action of centrifugal forces in the cylindrical shells 10 of the gravitational field in the hopper 9 is compacted. If necessary, the crane 18 is turned on and the thickened sludge is subjected, using the pulsating valve 19, to additional vibration compaction with an elastic shell 24. In the hopper 9, the sludge is thickened and densified in the lower part of the hopper 9, and as it accumulates, the mass of thickened increases (and the mass of dehydrated) the sediment and, in general, the mass of the hopper 9, which through the cover 8 and the supporting frame 12 is perceived by the sensing elements 11. When filling the hopper 9 by a predetermined amount, which is configured sensitive organ (sensitive elements 11), there is a command from the sensitive organ 11 through the electric converter 13 and the amplifier 14 to the spool 15, which supplies air from the compressor 16 to the rod cavities of the pneumatic cylinders 23. The internal cavity of the elastic pipe 20 opens, and the accumulated mass of the dehydrated sludge under excess pressure in the hopper 9 moves to the receiving container 27. To facilitate unloading, the pulsator valve 19 is turned on, with the help of which the mass is subjected to vibration compaction and additional pushing of the dehydrated sludge through the pipe approx. 20 per receiving container. When you exit the required amount of sediment with a given density in the receiving container 27 from the pipe 20, the mass in the hopper 9 decreases by a certain amount and as a result, the spool 15 switches to its original state. The drain pipe of the dehydrated sludge is again blocked by clamps 21, and a new process begins of filling the hopper 9 with condensed sludge and compaction of the dehydrated sludge.

Claims (3)

 1. HYDROCYCLONIC INSTALLATION OF MECHANICAL CLEANING OF LIQUID WITH AUTOMATIC REMOVAL OF DEHYDRATED DRAINAGE, including a hydrocyclone unit for cleaning liquid with inlet and drain pipes and a channel for exiting condensed sludge, hermetically connected by the upper part to the outlet channel of the condensed sludge sediment and having a dehydrated sludge sediment outlet and dehydrated sludge and a pressure source, characterized in that it further comprises a guide apparatus associated with the pressure source, and a sensitive organ for controlling the mass of dehydrated sludge in the hopper, connected through the guiding equipment to the unloading unit of the dehydrated sludge, the latter being made in the form of pneumatic or hydraulic cylinders, and the branch pipe for removing the dehydrated sludge is flexible, the hydrocyclone unit contains two or more hydrocyclones interconnected mounting plate, and the outlet channel of the condensed sludge is formed by discharge pipes of hydrocyclones, with each discharge pipe inside the hopper equipped with a cylinder surrounding it shell.  2. Installation according to claim 1, characterized in that it further comprises a pulsating valve connected to a pressure source, and the hopper in the lower part is provided with an elastic shell forming a closed cavity with its inner wall, the cavity being connected to the pulsating valve.  3. Installation according to claim 1, characterized in that each discharge pipe is equipped with a reflector mounted coaxially in it and made in the form of a cone, expanding towards the hopper.

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