KR970005357A - Filter outlet layer attachment device and filtration method using same - Google Patents

Abstract

The present invention relates to a filter system that uses a coalescing filter element having at least one end cap and wherein the pollutant is filtered from a gas stream and is adhered and discharged from a filter element outside the other components of the filter element. The first element includes an outlet sleeve that also extends outwardly beyond at least one end cap. The filter element may comprise a delivery layer disposed outside the outlet sleeve extending between the end caps. The invention also includes a method for purifying a gas flow using a filter system and a filter element.

Description

Filter outlet layer attachment device and filtration method using same

Since this is a trivial issue, I did not include the contents of the text.

Claims (76)

A filter medium: a filter discharge sleeve located outside the medium; A first end cap having a circumferential surface that confronts in an outward direction and which is located at an end of the filter element and which faces outwardly with a circumferential surface located within the discharge sleeve; And means for attaching the discharge sleeve to the first end cap. The tubular filter element according to claim 1, wherein the means for attachment is a chemical bond. The tubular filter element according to claim 1, wherein the means for attachment is a mechanical engagement. 4. The tubular filter element of claim 3, wherein the mechanical coupling is a compression band that tapers the discharge sleeve to a circumferential surface facing outwardly of the first end cap. 2. The apparatus of claim 1, further comprising: a second end having a circumferential surface facing outwardly, the second end being located at an opposite end from the first end; Further comprising means for attaching the discharge sleeve to the second end cap. The tubular filter element of claim 1, further comprising a porous inner core located within the medium. 7. The tubular filter element according to claim 6, wherein the inner core comprises a mesh. 8. A tubular filter element according to claim 7, wherein the mesh is a wire mesh. The tubular filter element of claim 1, further comprising a porous outer core positioned between the medium and the outlet sleeve. 10. The tubular filter element of claim 9, wherein the outer core comprises a mesh. 11. A tubular filter element according to claim 10, wherein the mesh is a wire mesh. The tubular filter element according to claim 1, wherein the discharge sleeve is colored and also houses a distinguishing indicia. Filter media; A filter discharge sleeve located outside the medium; A delivery layer positioned externally of the outlet sleeve; A first end cap positioned at one end of the filter element and having an outer protrusion having a circumferential surface and an abutment surface facing outwardly facing the interior of the carrier layer; Means for attaching the cap to the first end cap; Characterized in that one end of the discharge sleeve is located adjacent to the abutment surface 14. A tubular filter element according to claim 13, characterized in that the means for attachment is a chemical compound. 14. A tubular filter element according to claim 13, characterized in that the means for attachment is a mechanical engagement. 16. The tubular filter element according to claim 15, wherein the mechanical coupling is a compression band that tilts the carrier layer to a circumferential surface facing outwardly of the first end cap. 14. The apparatus of claim 13, further comprising: a second end having a circumferential surface and an abutment surface facing outwardly and located at an opposite end from the first end; Further comprising means for attaching the carrier layer to the second end cap; One of said end caps having an inlet opening; And the second end of the discharge sleeve is located near the abutment surface of the second end cap. 14. The tubular filter element of claim 13, further comprising a porous inner core located within the medium. 19. The tubular filter element of claim 18, wherein the inner core comprises a mesh. 20. The tubular filter element according to claim 19, wherein the mesh is a wire mesh. 14. The tubular filter element of claim 13, further comprising a porous outer core positioned between the medium and the outlet sleeve. 22. The tubular filter element of claim 21, wherein the outer core comprises a mesh. 23. The tubular filter element according to claim 22, wherein the mesh is a wire mesh. 14. A tubular filter element according to claim 13, characterized in that the carrier layer is colored and also houses the distinguishing indicia. Porous inner core; A filter medium located outside the inner core; A porous outer core located outside the medium; Upper and lower end caps located at either end of the filter element; And means for attaching an outlet sleeve to the end cap, wherein each end cap has a circumferential surface facing in an outward direction located between the outer core and the outlet sleeve, Wherein the lower end cap has an alternative means for replacing the filter element. 26. A tubular filter element according to claim 25, wherein the means for attaching to the discharge sleeve end cap is a mechanical engagement. 27. The tubular filter element of claim 26, wherein the mechanical coupling is a compression band that tapers the discharge sleeve to a circumferential surface facing outwardly of the end cap. 27. The tubular filter element of claim 26, wherein the means for attaching the discharge sleeve to the end cap further comprises a chemical binder. Porous inner core; A filter medium located outside of the inner core; A porous outer core located outside the medium; A filter discharge sleeve having two ends located outside of the outer core; A transport layer located outside the discharge sleeve; Upper and lower end caps located at either end of the filter element; And means for attaching the carrier layer to the end cap, wherein each end cap has a circumferential surface and an abutment surface facing outwardly between the outer core and the carrier layer, wherein each end of the discharge sleeve Is located adjacent each surface of the abutment surface, the upper cap having an inlet opening adjacent the inner core and the lower cap having an alternative means for replacing the filter element. 30. A tubular filter element according to claim 29, wherein the means for attaching the carrier layer to the end cap is a mechanical engagement. 32. A tubular filter element according to claim 30, wherein the mechanical coupling is a compression band inclined to a circumferential surface facing the outward facing direction of the end cap. 31. The tubular filter element of claim 30, wherein the means for attaching the outlet sleeve to the end cap further comprises a chemical binder. Filtration tank; Incoming pipe to the tank; An exhaust pipe exiting the tank; A filtration vessel attachable to the tank and also removable from the tank and including a discharge to the tank and a void opening; And a tubular filter element having a filter medium, a filter discharge sleeve located externally of the medium, and at least one end cap, said at least one end cap being located in the end cap of the filter element and being proximate to the filter medium A circumferential surface facing the outward direction and having means for attaching an outlet sleeve to the at least one end cap. 34. The filter system of claim 33, wherein the means for attaching is a chemical bond. 34. The filter system of claim 33, wherein the means for attaching is a mechanical engagement. 37. The filter system of claim 35, wherein the mechanical coupling is a compression band that tapers the discharge sleeve to a circumferential surface facing in the outward direction of the at least one end cap. 34. The filter system of claim 33, wherein the at least one other end cap has a circumferential surface facing outwardly, and also includes means for attaching the outlet sleeve to the other end cap. 38. The filter system of claim 37, wherein the means for attaching is a mechanical engagement. 39. The filter system of claim 38, wherein the mechanical coupling is a compression band that tilts the discharge sleeve to a circumferential surface facing outwardly of the other end cap. 38. The filter system of claim 37, wherein the other end cap has alternative means for replacing the filter element. 41. The filter system of claim 40, wherein the alternate means comprises a ring. 34. The filter system of claim 33, comprising a porous inner core located within the medium. 43. The filter system of claim 42, wherein the inner core comprises a mesh. 44. The filter system of claim 43, wherein the mesh is a wire mesh. 34. The filter system of claim 33, comprising a porous outer core portion positioned between the medium and the outlet sleeve. 46. The filter system of claim 45, wherein the outer core comprises a mesh. 47. The filter system of claim 46, wherein the mesh is a wire mesh. Filtration tank; Incoming pipe to the tank; An exhaust pipe exiting the tank; A filtration vessel attachable to the tank and additionally removable from the tank and including a discharge to the tank and a void opening; And a tubular filter element comprising a filter medium, a filter discharge sleeve located outside the medium, and a delivery layer located outside the discharge sleeve, the at least one end cap being located at one end of the filter element, Means for attaching to the at least one end cap an abutment surface having an inlet opening proximate to the medium and located at one end of the circumferential surface discharge sleeve facing in the outward direction and located between the medium and the carrier layer, Of the filter system. 49. The filter system of claim 48, wherein the means for attaching is a chemical bond. 49. The filter system of claim 48, wherein the means for attaching is a mechanical engagement. 51. The filter system of claim 50, wherein the mechanical coupling is a compression band that tilts the carrier layer to a circumferential surface facing outwardly upwardly of the at least one end cap. 50. The method of claim 48, wherein another at least one end cap has a circumferential surface and an abutment surface facing outwardly, the second end of the discharge layer being located proximate to the further end cap abutment surface, Layer to the other end cap. ≪ RTI ID = 0.0 > 11. < / RTI > 53. The filter system of claim 52, wherein the means for attaching is a mechanical engagement. 54. The filter system of claim 53, wherein the mechanical coupling is a compression band that tilts the carrier layer to a circumferential surface facing outwardly of the further end cap. 53. The filter system of claim 52, wherein the further end cap has alternative means for replacing the filter element. 56. The filter system of claim 55, wherein said alternate means comprises a ring. 49. The filter system of claim 48, further comprising a porous inner core located within the medium. 58. The filter system of claim 57, wherein the inner core comprises a mesh. 59. The filter system of claim 58, wherein the mesh is a wire mesh. 59. The filter system of claim 58, further comprising a porous outer core positioned between the medium and the outlet sleeve. 61. The filter system of claim 60, further comprising a porous outer core positioned between the medium and the outlet sleeve. 62. The filter system of claim 61, wherein the crimping mesh is a wire mesh. Filtration tank; Incoming pipe to the tank; An exhaust pipe exiting the tank; A filtration vessel which is attachable to the tank and which is attachable to the tank and which can also be removed from the tank and which also includes a discharge to the tank and a pore opening; And a porous outer core positioned outside the vagina, a filter outlet sleeve located outside of the outer core, an extrude positioned between the outer core and the outlet sleeve, A tubular filter element comprising an upper and a lower end cap each having a circumferential surface facing in the direction of the filter element and means for attaching an outlet sleeve to the end cap, The upper cap having an inlet opening adjacent the inner core, 64. The filter system of claim 63, wherein the means for attaching the payload sleeve to the end cap is a mechanical engagement. 64. The filter system according to claim 63, wherein the mechanical coupling is a compression band that tilts the discharge sleeve to a circumferential surface facing outwardly of the end cap. 65. The filter system of claim 64, wherein the means for attaching the outlet sleeve to the end cap is a chemical bond. Filtration tank; Incoming pipe to the tank; An exhaust pipe exiting the tank; A filtration vessel attachable to the tank and removable from the tank, the filtration vessel also including a discharge to the tank and a void opening; And a porous outer core positioned outside of the medium, a filter discharge sleeve located outside of the outer core, a transport layer located outside of the outlet sleeve, an outer core And means for attaching the carrier layer to the end cap, wherein the abutment surface abuts one end of the upper and lower end caps and sleeves, respectively, having a circumferential surface facing in an outward direction located between the carrier layers, Wherein the end cap is located at one end of the filter element and the top cap has an opening adjacent the inner core. 68. The filter system of claim 67, wherein the means for attaching the carrier layer to the end cap is a mechanical engagement. 69. The filter system of claim 68, wherein the mechanical coupling is a compression band that tilts the carrier layer to a circumferential surface facing the outward direction of the end cap. 69. The filter system of claim 68, wherein the means for attaching the carrier layer to the end cap is also a chemical bond. Positioning a porous, cylindrical inner core within the filter media; Attaching a lower end cap to one end of the filter element, the lower end cap including a projection having a circumferential surface facing outwardly; Attaching to the other end of the filter element an upper end cap with a withdrawal portion, the projecting portion including a projection having a circumferential surface facing outwardly; Positioning a filter discharge sleeve outside the filter medium and the end cap; And disposing a compression band around the outlet sleeve that tilts with respect to a circumferential surface facing in an outward direction of the outlet sleeve. 72. The method of claim 71 including disposing the discharge sleeve about a second compression discharge sleeve tilting about a circumferential surface facing the outward direction of the upper end cap. Positioning a porous inner cylindrical core within the filter media; Positioning a filter discharge sleeve outside the filter medium; Attaching to the one end of the filter element a lower end cap comprising a projection having a circumferential surface facing outwardly and a contact surface located near one end of the outlet sleeve; At the other end of the filter element, a protrusion having a circumferential surface facing outwardly, and a contact surface for positioning the outlet sleeve near one end. Attaching an upper end cap with an inlet portion; Positioning the carrier layer outside the filter medium and the end cap; And disposing a carrier band around the carrier layer that tilts the carrier layer against a circumferential surface facing the outward direction of the lower end cap. 72. The method of claim 73, further comprising disposing a second compression band around the carrier layer that tilts the carrier layer against a circumferential surface facing the outward direction of the upper end cap. Passing a gas flow through a filter system surrounding the tubular filter element; Passing a gas flow through the porous cylindrical inner core of the filter element; Passing a gas flow through the porous cylindrical inner core of the filter element; Passing a gas flow through the aperture to the filter medium; Separating the phosphorous contamination from the gas stream; Coalescing the contaminants as the contaminants continuously move outwardly and downwardly toward the lower end cap located inside the sleeve; Moving contaminants outwardly and downwardly with a filter discharge sleeve located in an outward direction; Dropping contaminants from the sleeve without contacting the lower end cap; And passing the gas stream out of the filter element and filter system, wherein the contaminant falls into the filtration vessel and also emerges from an outlet located in the lower surface of the vessel. Way. Passing a gas flow through a filter system surrounding the tubular filter element; Passing a gas flow through the porous cylindrical inner core of the filter element; Passing a gas flow through the aperture to the filter medium; Separating incoming contaminants from the gas stream; Coalescing the contaminants as the contaminants continuously move in the outward direction toward the lower end cap located inside the sleeve; Moving outwardly and downwardly adhered contaminants to an outwardly located filter discharge sleeve; Further moving contaminants adhering in the outward direction and the downward direction to the outwardly located transport layer: dropping contaminants from the transport layer without contacting the lower end cap; And passing the gas stream out of the filter element and the filter system, wherein the contaminant exits the outlet from the lower surface of the vessel when it falls into the filter vessel.