KR890701835A - Pulp Screening Apparatus and Screening Method of Pulp Suspension - Google Patents

Abstract

No content

Description

Pulp Screening Apparatus and Screening Method of Pulp Suspension

Since this is an open matter, no full text was included.

The invention will be described in more detail with reference to the accompanying drawings and embodiments. 1 is a partial detailed cross-sectional view showing a part of a rotor and a screen according to one embodiment of the present invention; FIG. 2 is a schematic view showing a contour surface of a rotating element (rotor); FIG. 3 is a view of a rotating element having a braided segment. Figure showing another embodiment.

Claims (19)

Screen cylinders in containers formed of a screen plate having a contoured surface consisting of a container with an unscreened inlet for pulp, a first outlet for accept, a second outlet for reject, a bottom surface and a hole in the bottom surface, predetermined velocity In a device for screening a low consistency pulp consisting of a rotating element capable of moving in the vicinity of the screen cylinder, the space between the screen cylinder and the rotating element defining a screen zone, the rotating element 90 is adapted to the screen. Having a contour surface opposite the contour surface of the plate, the contour surface of the screen plate and the rotating element providing or forming a positive pressure generating means for causing a positive pressure pulse to the inlet of the hole of the screen plate The positive pressure pulse is accepted Pulp screening device, characterized in that passing through the screen plate. The pulp screening device of claim 1, wherein the rotating element is a rotor. The pulp screening apparatus of claim 1, wherein the rotating element consists of a blade segment. 3. The screen element of claim 2 wherein the rotating element is a rotor and the contour surface of the rotor consists of grooves formed with a first bottom surface, an inclined surface, an upper surface and a side surface, such that the screen plate is at the screen surface at the inlet side. A pulp screening device, characterized by having a groove in the groove. 5. The rotor of claim 4, wherein the rotating element is a rotor, wherein the contour surface of the rotor consists of grooves formed of a first bottom surface, an inclined surface, an upper surface and a side surface parallel to the surrounding surface, the side surface being the Perpendicular to or substantially perpendicular to the bottom surface, wherein the inclined surface is at an angle of 5 ° to 60 ° with respect to the first bottom surface, such that the screen plate has grooves at the inlet side recessed to the screen surface. Pulp screening device. The method of claim 1, wherein the positive pressure generating means consists of two cooperative contour surfaces, one contour surface of which is the surface of the screen plate, the other contour surface is the surface of the rotor, and the contour surface is the bottom A pulp screening device comprising a surface, an oil surface, an inclined side and a downstream side with respect to the bottom surface, wherein the downstream side is the positive pressure generating means. 7. The pulp screening apparatus according to claim 6, wherein the leading surface of the rotor is a side perpendicular to the bottom surface. 7. The pulp screening apparatus according to claim 6, wherein the inclined surface of the rotor is a riding surface. A method of screening a pulp suspension of high concentration at a high volume, wherein the pulp suspension is introduced into an apparatus and the unscreened pulp flows into the screening zone, wherein the pulp flows into the circumferential passage at a high flow rate. Is subjected to the combined positive pressure of the contoured screen cylinder and the contoured screen cylinder of the rotating element at the inlet of the hole, thereby allowing the acceptor to pass through the hole at a high flow rate by a positive pressure pulse, followed by a large capacity. Pulp screening device. Consisting of a container, a screen cylinder in the container, a rotating element moving around the screen plate at a predetermined speed, an inlet for unscreened pulp, an accept for the tool, a first outlet for screened pulp and a second outlet for reject, The first and second outlets are in operative communication with the screen cylinder, the rotating element has a contour surface, the screen cylinder has a screen plate, the screen plate has holes and a contour surface at its bottom, and The contour elements of the rotating element and the screen cylinder face each other and define a screening zone between the contour surfaces, the inlet introduces the unscreened pulp into the device and the screening zone, the pulp in the screening zone Introducing the pulp suspension into a device that flows through the circumferential passage at a high flow rate. 10. The method according to claim 9, wherein the pulp is subjected to the combined positive pressure of the contoured screen cylinder and the contour surface of the rotating element at the inlet of the hole, thereby allowing the acceptor to open the hole at a high flow rate by a positive pressure pulse. A pulp screening device, characterized in that a large capacity is passed through. 11. The pulp suspension of claim 10 wherein the pulp suspension alternates between high frequency positive and negative pressure pulses, the positive pulses being generated by a rotating element in the aperture of the screen cylinder and oriented towards the aperture, thereby suspending the suspension at high flow rate by the pressure pulses. And then the suspension is subjected to a negative pulse generated by the rotating element in the screen hole and oriented away from the hole of the screen cylinder so that the fibers and debris attached to the hole are removed and the fiber on the surface of the screen cylinder A pulp screening device, characterized in that formation of a mat is prevented to maintain a large capacity. 12. The method of claim 11, wherein the pulp suspension receives a positive pressure pulse generated by the contour surface of the scurine and the contour surface of the rotating element at the inlet of the hole. The method of claim 10, wherein the average pressure drop across the screen aperture is greater than the pressure drop across the screen. The method of screening a pulp suspension according to claim 13, wherein the pressure drop across the screen hole is greater than the pressure drop across the screening device. The method for screening a pulp suspension according to claim 10, wherein the frequency of the pressure pulse is 50 Hz or more. The method of claim 10, wherein the average pressure drop between the outlet and the inlet of the hole in the screen is at least 10 KPa. 11. The method of claim 10, wherein the magnitude of the positive pulse is greater than the magnitude of the negative pulse. The method of screening a pulp suspension according to claim 10, wherein the average flow rate through the holes of the screen is at least 2.7 m / sec. Container, cylindrical scullin plate in container with enveloping surface, screen plate with contour surface and hole, rotating element moving around screen plate at predetermined speed, inlet for unscreened pulp, accepting in container, for screening pulp A first exit; and a second exit for reject, wherein the first and second exits have a low viscosity pulp in operative communication with the screen, wherein the rotating element has a contoured surface, the screen plate The contour surface of the rotor and the contour surface of the rotor face each other and define a screening zone, the inlet for unscreened pulp is in communication with the screening zone, and the contour surface of the screen plate provides a positive pressure generating means. The means being a bar located downstream of the screen aperture A bar forms an upstream side, a downstream side and an upper surface, the aperture is located in a plane between the bars, the plane is substantially parallel to the enveloping surface of the screen plate, and the upper surface is the plane between the bars. And wherein the downstream side is substantially perpendicular to the enveloping surface. ※ Note: The disclosure is based on the initial application.