TH55793B - Multi-stage Axial Flow Cyclone Separator - Google Patents

Abstract

New request update 5/8/2016 The long axis multilayer cyclone fluid separator consists of an initial vortex generation section consisting of an initial vortex generation section which is structured outside open-ended with diffuse gaps inside. fluid that will distribute the incoming fluid from the primary fluid inlet for a channel Transmits the external fluid into the vortex distribution gap to pass into the channel. Create a preliminary vortex before passing it to the vortex accelerating section that is structured on the outside with an open end with a diffuse gap on the inside. will disperse the incoming fluid from the fluid inlet for being a transmission channel The external fluid enters the fluid distribution gap to pass into the rate channel. acceleration of the vortex and induce the vortex transmitted from the primary vortex to vortex faster before passing to the fluid separator with a structure Outside the open end, inside there is a space to collect the heavier fluid from the channel. side exit while the inside of the outer structure separates the fluid, there is a pipe through which Fluid is installed in the middle to separate the light vortex fluid through the open end. can also be infected vortex accelerator and fluid separator for vortex flow rate Faster and longer system eddy currents to improve separation efficiency. to be as high as you want

Claims (5)

Disclaimer (all) which will not appear on the advertisement page. : New requests updated 5/8/2016 1. The long-axis multi-layer cyclone fluid separator consists of - a preliminary eddy-generation section (1) consisting of an outer structure. Of the preliminary eddy section (4) that is structured outside the open end There is a fluid distribution gap inside (5) for distributing the incoming fluid from Primary fluid inlet (6) that is one or more channels Lateral, the outer structure of the primary eddy section (4) or tubular At least one lateral protrusion, the outer structure of the primary eddy channel (4) for the passage of fluid from the outside into the fluid distribution gap (5) for the flow into the pre-flow channel. (7) of the eddy generating device (8) installed inside the outer structure of the preliminary eddy section (4), in which the eddy generating device (8) is characterized as The structure is on the axis. Within the line, or part, where the inside is a cylindrical gap to create Primary vortex (7) and at least one side through hole (9) for the passage of fluid into the primary eddy channel (7). 9) will be the output surface c where the beginning of the said surface will do The smallest angle to the fluid ejection line a from the side through hole (9) and the curved exit surface c is the nearest surface. When comparing the surface surrounding the fluid ejection line a from the lateral through-hole (9) by placing the lateral through-hole component (9) and the arc surface c of the side-through-hole, (9) As a Coanda Profile, the fluid that is pushed in from the through hole is deflected. It flows finely along the curving surface c along the flow b causing the Coanda effect to induce the fluid in the preliminary eddy channel (7) to the flow A along the line. The plane of the arc surface c forms a layered vortex in the preliminary eddy channel (7), where one open end of the outer structure of the preliminary eddy block (4) forms a cover ( 10) for covering to set the flow of fluid Only through the introductory fluid inlet (6) - The eddy acceleration section (2) consists of an outer structure. Of the accelerating part of the eddy eddy (14) characterized by the outer structure The open end is inside the fluid distribution gap (15) for distributing the fluid that Inlet from at least one fluid inlet (16) that is characterized by The outer structure of the eddy acceleration section (14), or one or more tubes extends laterally, the outer structure of the eddy acceleration section (14) for the fluid transmission channel. From the outside enters the fluid distribution gap (15) to pass it into the vortex acceleration (17) of the apparatus for the eddy rate (18), which the device for generating the eddy acceleration (18) ) Will look like The axial structure is within, along or partially, where the inside will be. A conical gap for creating vortex acceleration (17) installed inside. The outer structure of the section produces the eddy acceleration (14) for receiving the fluid. Entering from the fluid distribution gap (15) and the lateral area of the apparatus for Establish the acceleration of the eddy current (18), there will be at least one side through hole (19). For the flow of fluid from the vortex diffusion gap (15) into the vortex acceleration (17), the flank surface of the side perforation (19) will At the beginning, the outward curve of the surface is at the minimum angle to the fluid ejection line, a \ 'from the lateral puncture hole (19), and the ejection surface c \. 'Will be the closest surface. In comparison with other surfaces surrounding the ejection of fluid a \ 'from the through hole (19) by placing the lateral through-hole elements (19) and the c \' curve-exiting surface, such a coanda profile. Fluid being pushed in from a through hole is The flow is diverted along the curving surface c \ ', which shows the flow b \', causing the coanda effect to induce the fluid in the gap, creating the acceleration of the eddy current (17) passed from the section. Preliminary eddy creation (1) is directed along the flow A \ 'to flow into a layer on the plane of the curved surface, c \' to create a layered eddy in the gap. The eddy current acceleration (17) with the diameter of the upstream opening is larger than the diameter of the The open end of the transmission receiving base of the eddy acceleration device (18) increases the acceleration along the circumference that is gradually shortened by the slope of the cone base of the acceleration device. Of the eddy flow (18) before it is passed into the fluid junction (3) - the fluid junction (3) consists of the outer structure of the flow junction (22) with the outer structure, the open end has a side In a gap (23) for collecting the heavy volute fluid through the side outlet (24) that is one or more recesses on the side of the outer structure of the fluid junction (22) or At least one of the tubes extending outside the structure. Of the fluid junction (22) for the heavy fluid flow channel on the inside of the outer structure of the fluid junction (22), the fluid junction (25) is installed in the center through which the fluid is transferred (25). It will look like a round pipe with a circular inside (26) for the outlet of the light fluid. And the size of the flow pipe (25) is smaller than the opening of the eddy acceleration section (2), which is a circular center opening to create a fluid separation gap ( 27) to separate the heavy fluid and pass it through the fluid collection gap (23), and one open end of the outer structure of the fluid splitter (22) is the outer mounting edge (28) for the gripping edge. Fastening of the fluid transmission pipe (25) 2. The long axis multilayer cyclone fluid separator according to the claim 1 creates a preliminary eddy flow (7), there is an isthmus (20) to support the Eddy in the channel, creating a preliminary eddy flow (7), sufficiently and quickly enough to a degree first Forward in the next order 3. A multi-layer cyclone fluid separator along the long axis according to any claim 1-2, with a preliminary fluid inlet (6) imported along the axis at the source with a cover plate (10) over it. Only the open end of the pre-flow device (8) is at the source and opens a gap around the pre-flow device to allow the material to flow into the pre-flow gap (5) and into the preliminary eddy channel. (7) Through-hole (9) 4. Long axis multi-layer cyclone fluid separator according to claim 1-3, one of the characteristics of eddy-accelerated extension conduction. Conical form followed by a separate fluid section And or an extension that creates acceleration Of a cylindrical eddy flow, followed by at least one fluid junction, connected to the fluid junction (3). 5. The long axis multi-layer cyclone fluid separator according to any claim 1-3 with the divergent fluid separator. Instead of the fluid intersection (3)