TH47952B - Shallow edge air support surface feature for optimal transducer spacing. - Google Patents

Abstract

DC60 shallow edge on the tail rail that allows the slider to float closer to the center for recording and Show less sensitivity to curl than sliders, as well as one or more support structures and rails with side edges and used support surfaces. Elevated air above at least one rail support structure is composed of a magnetic element positioned on the support structure. The edge of the rail near the magnetic parts has been edged in order to make the The minimum buoyancy of the magnetic piece above Record plate while This is to prevent the collision of the rail with the log plate during the self-winding condition. Make the edge of the rail to form the tail edge, released by the edge of the rail near With parts Magnet is lower than the surface for air-powered support, but higher. Support structure Shallow edges in the surface To support The difference between the slider / disk spacing the lowest to the lowest and the magnetic head / disc spacing. On the other hand, it maximizes the effectiveness of the surface edge transducer spacing for air-close support to the piece. The magnetic part was shortened by ion-reactive edging. Verb or the use of ions A shallow edge at the rear edge rail that allows the slider to float closer to the logging medium and is indicated to at least roll less than the slider, including the support structure and the rail. One rail with side edges and a support surface. Raised air above the support structure The edge of the rail close to Magnetic components have been edged in order to make the The lowest float of the magnetic piece above the log plate while This is to prevent the collision of the rail with the log plate during the Curling up the features that have been Make the edge of the rail to form the tail edge, released by the edge of the rail near To the magnetic components below the surface for Air but higher Support structure Shallow edges in the surface for support, resulting in The difference between the slider / mechanical log space minimum given Minimum and magnetic head / disc spacing, in which the On the other hand, it achieves the maximum effectiveness of the surface edge transducer spacing for air-close support to the piece. The magnetic part was shortened by ion-reactive edging. Verb or the use of ions

Claims (2)

(All) rights which will not appear on the advertisement page: 1. Slider for supporting the transducer above the moving recording medium. Which includes Supporting structures, which have lateral, leading and trailing edges in relation to the Moving of the recording medium The rails are centered on the support structure between the side edges of the rail support. Which has a sidewall edge and an airborne support surface. It is raised above the surface support structure for air-powered support, including the intermediate overhang at the end of the rail, where the rail is assembled with magnetic components. Which is installed on the mid overhang, and here the rails only include the trailing edge on the side of the mid overhang that End of the rail The tail edge is released, which will be arranged. And has been configured in order to Increase the distance between the rail edge and the recording center. This will prevent the collision of the rail with The medium for recording when the slider is winding 2. Slider of claim 1, in which the parent part The steel is supported at the end edge of the supporting structure. 3. Slider of claim 1, where the rail is also assembled. With the tip released with the edge of the rail close to the part The magnet has been shortened relative to the rear edge of the support structure 4. Slider of claim 1, wherein the rail with a piece The magnet that is supported on the corresponding part Has been centered on the slider between the flanks. Of the supporting structure 5. Slider of the claim 1, in which the rail contains parts Supported magnets on the respective parts. It is positioned along one side of the support structure. 6. The slider of the claim 1 also includes an optional rail. At least one rail is for the aerodynamic control of the slider. 7. Slider of claim 3, which here makes Shortened of the rails near the magnetic parts have been moved The level of the supporting structure completely. 8. Slider of claim 1, in which the edge of the rail is approaching. Along, the magnetic parts have been edged by the edge making technique. Ions react 9. Slider of claim 1, wherein the web edge near the piece The magnetic part is ionized with a 1 0. slider of claim 1, wherein the edge of the surface For support using air, close to both sides of the parent part. Steel has been removed 1 1. Slider of claim 10, in which the edge of the floor A surface for air-based support near the magnetic components received Moving out to a level below the support surface. Air-operated but above the supporting structure 1 2. slider of claim 1, in which the edge of the surface For near-air support, magnetic components have been Move it to a level below the supporting surface. 1 3. Transducer slider for supporting the slider with floating above the disk to record moving and It has log / mechanical slider distance and head / log distance. Magnetic field consists of Support structures with flank, front and rear edges With the movement of the record plate and At least one air-based support surface. Has been arranged on a support structure facing the plate Log with moving In which here the surface for secondary Acquire at least one surface to provide a bonding surface. For magnetic head And here at least one edge of the floor The airborne support surface near the magnetic head has been Move in order to increase the mechanical clearance between the record plate and the slider. 1 4. Slider of claim 13, wherein the edge of the floor Air-cushioned support skin near both sides of the head. The iron has been removed 1 5. Slider of claim 13, which is here the surface for Air-powered support that provides a surface for head attachment. The magnet is positioned at the center of the slider 1 6. The slider of the right holder 15, wherein the edge of the floor The air-operated support surfaces near both sides of the magnetic head are obtained. Removal 1 7. Slider of claim 16, in which the edge of the floor The air-powered support surface near the magnetic head was introduced. Issued in order to completely open onto the supporting structure. 1 8. Slider of claim 16, in which here the surface For air support, the magnetic head has been moved. Out to a level below the surface for airborne support, but Above the supporting structures 1 9. Slider of claim 16, in which thereof of the floor The airborne support surface near the magnetic head has been moved. Issued by ion-reactive edge techniques 2 0. Slider of claim 16, herein the edge of the floor The airborne support surface near the magnetic head has been moved. Issued using ion mill 2 1. Slider of claim 13, wherein the edge of the floor The airborne support surface near the magnetic head has been moved. Issued by ion-reactive edge 2 2. slider of claim 13, herein the edge of the floor The airborne support surface near the magnetic head has been moved. Issued using ion mill 2 3. Slider of claim 13, in which the floor portion The air cushioned support surface close to the magnetic head has been Shortened in relation to the end of the supporting structure and section The head is indented from the trailing edge 2 4. System for information collection and retrieval consisting of at least one rotating log with a recording surface. Record for recording information on this related section. The shroud to be attached to the log plate for the protection of the log plate, the supporting structure that has been attached to the actuator arm assembly. Close to the recording surface of a rotating log, the support structure is selectable, positioned above the floor. Rotating plate surface Fixed support structure Selectable position above the disk surface, rotated by supporting structure actuator with flank, front edge and edge. The end relates to the movement of the recording medium and at least one rails with sidewalls and trough surfaces. The air receiver is raised above the support structure, where at least one rail contains the resulting magnetic component. Being fixed near the end of the rail And here the edge of The rails close to the magnetic parts have been shortened in distances. Relative to the rear edge of the supporting structure in order to make High, the levitation of the magnetic element is the lowest above the log disk, and in order to make the distance between the edge of the rail and the recording medium Record maximum for preventing collision of the rail with the recording medium. 2. 5. Slider of claim 21 where the rail is also assembled. With the end edge released by the edge of the rail near the parent part The steel has been shortened relative to the rear edge of the support structure 2 6. Slider of claim 21, wherein the rail with a piece The magnet part which is supported on this related part. Has been centered on the slider between the flanks of the Support structure 2 7. Slider of claim 21, in which the rails with pieces The magnet part which is supported on this related part. It has been arranged along the sides of the supporting structure. 2. 8. The slider of the claim 21 also includes an additional rail. Fill at least one track to achieve air control. The science of the slider 2. 9. Slider of claim 21, in which the edge makes The shortening of the rails near the magnetic parts have been moved further into the Completely level of support structure 3 0. Slider of claim 21, wherein the edge of the rail Near the magnetic parts has been shortened by making a pattern edge. Ions react 3 1. Slider of claim 21, wherein the edge of the rail Near the magnetic parts were shortened by the use of ion mill 3 2. slider of claim 24, wherein the edge of the floor Air-cushioned support skin near both sides of the part. The magnet has been removed. 3. 3. Slider of claim 32, in which this of the floor. A surface for air-based support near the magnetic components received Moving out to a lower level support surface is used. Air but above the supporting structure 3 4. Slider of claim 24, in which the edge of the floor A surface for air-based support near the magnetic components received Moving out to a lower level support surface is used. Air, but above the supporting structure. 3 5. Methodology for creating sliders for spacing Head to plate, the best record consists of steps of Shaping Supporting structure with flank, front and tail edge shaping the air-facing support surface. Face-to-face rotary record, support surface Air, which creates a mounting surface for magnetic heads and moving at least one edge of the surface for pattern support. Use air near the magnetic head in order to increase the mechanical distance. Between the record plate and the slider. 3 6. The methodology of claim 35 also consists of a procedure. Of guiding the edge of the surface for near-air support for both Two sides of the magnetic head 3 7. Slider of claim 35, in which the steps of Impregnation of the magnetic head surface also consists of steps. Step of positioning the magnetic head at the center of the slider 3 8. Slider of claim 35, in which the steps of Guiding the edges of the surface for airborne support near the mother head. The iron out consists of the process of removing the edges in order to expose the 3 9. Slider of claim 35, in which the procedure of Guiding the edges of the surface for airborne support near the mother head. The iron out consists of the process of bringing the edge to a lower level. The air-out support surface, but above the substructure substrate, supports 4 0. Methodology of claim 35, in which the procedure of Guiding the edges of the surface for airborne support near the mother head. Iron removal also consists of the process of removing the edges through the process of making Ion edge reactive 4 1. Methodology of claim 35, in which the procedure of Guiding the edges of the surface for airborne support near the mother head. The iron also consists of the process of removing the edges using the ion mill 4. 2. Methodology of claim 29, in which the procedure of Bringing a portion of the airborne support surface close to the head The release magnet also consists of the process of making a surface to The shorter the air-operated support relative to the rear edge of the structure. Support and indentation in the header from the edge (42 claims, 5 pages, 6 photos).