SU1094054A1 - Versions of erasing magnetic head - Google Patents

Abstract

1. The erasing magnetic head containing a winding and a magnetic core interacting with the working surface of the magnetic carrier, consisting of one central and two identical lateral cores, between which working gaps are formed, characterized in that, in order to increase the efficiency of erasing the previously recorded signal and reducing the power consumed, the width of the working gap, located second in the direction of the magnetic carrier, refers to the width of the working gap, located first along the movement and carrier, not less than 2.5: 1, wherein the winding is arranged on the central core. (LF; o ate 4

Description

2. The erasing magnetic head, comprising a winding and a magnetic core interacting with the working surface of the magnetic carrier, consisting of one central and two identical lateral cores, between which working gaps are formed, characterized in that, in order to increase the efficiency, the recorded srL-nalogram is erased and reduce power consumption, both working gaps are the same width, and the winding is divided into two half windings; located on the side cores, wherein the number of turns of the half winding located on the side core first in the direction of travel of the magnetic carrier refers to the number of turns. the half-winding located on the second side core along the magnetic carrier movement is not less than 2.5: 1.

one

The invention relates to instrumentation, in particular, to the design of an erasable magnetic head for magnetic recording apparatus.

A known erasing magnetic head, comprising two lateral and one central cores, in which the working surface in the portion of the pole pieces is made stepwise, i.e., from alternating slots and projections 1.

However, such a head is difficult to manufacture and does not allow sufficiently erasing the waveform when the working magnetic layer is unevenly thick: At the same time, with good quality media, this head works quite reliably.

Closest to the invention is an erasable magnetic head comprising a winding and a magnetic core interacting with the working surface of the magnetic carrier, consisting of one central and two identical side cores, between which working gaps 2 are formed.

However, the well-known head does not efficiently erase the previously recorded waveform and has a relatively high power consumption.

The purpose of the invention is to increase the efficiency of erasing a previously recorded waveform and reducing power consumption.

The goal is achieved according to the first embodiment in an erasable magnetic head comprising a winding and a magnetic conductor interacting with a working surface of a magnetic carrier: consisting of one central and two identical lateral cores, between which working gaps are formed, the width of one of them located second along the movement of the magnetic carrier, refers to the width of the working gap, located first in the direction of movement

carrier, not less than 2.5: 1, with. This winding is located on the central core.

In addition, according to the second option

in erasing magnetic head containing a winding and interacting with pa. The magnetic surface of the magnetic carrier consists of one central and two identical lateral cores, between which working gaps are formed, the edges of these gaps are made the same width, and the winding is divided into two half windings located on the side cores, with the number of turns of the half winding located on the first in the direction of the magnetic carrier, the side core, refers to the amount of the half-winding located on the second in the direction of the magnetic carrier, the side core, not m Less than 2.5: 1.

FIG. 1 shows the design of the head in the first embodiment; in fig. 2 - h steresisan curve, which reduces the operation of the head; in fig. 3 - head design according to the second embodiment.

Magnetic erase head contains

the central core 1 and the two side cores 2 and 3, as well as the winding 4, connected to unit 5, which you can tread as a DC source and, for example, as an erase and bias generator. The head may also have working clearances 6 and 7. In the second embodiment (Fig. 3), the winding is made of two half windings 8 and 9 located on the side cores 2 and 3. And if in the first embodiment (Fig. 1) the working clearances have non-uniform The width of the gap (the width of the gap 7 refers to the width of the gap 6 as 2.5: 1), and the winding 4 is located on the central core 1, then in the second embodiment (Fig. 3) the working gaps have the same width, but the winding in this case is divided into two

half windings 9 and 8, the number of turns of which is 2.5: 1.

During the operation of the head, a current passes through it, for example, a constant, as a result of which two magnetic fluxes appear (Fig. 1) F, and F} ,. These flows create a floor in the working gaps that have the opposite direction. Since the gap 6 has a smaller width compared to the gap 7, the gap 6 has a smaller magnetic resistance with respect to the gap 7, which allows ET in the gap 6 to obtain a greater magnitude of the magnetic field strength. The process occurring in the head is illustrated by the hysteresis curve shown in FIG. 2, where the ratio of the current magnetization I to the saturation magnetization Is is plotted along the ordinate axis, and the ratio of the current magnitude, for example) on the abscissa axis — the magnetic field H to the half of the saturation magnetization Hj / a on curve 10 of initial magnetization. An element of a magnetic carrier (not shown) that has a residual magnetization, for example, If or If, i.e., in any state of residual magnetization, when Ivw. where Ifin is the maximum residual magnetization, first passes Vi,

FSh.2

past the gap 6, where it is acted upon by the HI field (from the flow F1), which allows to obtain a carrier state close to saturation, and then past the gap 7, where it is acted upon by the H2 field (from the flow F, directed opposite to the HIJ field Thus, after the carrier leaves the zone of action of the first field, the carrier magnetization changes already along the hysteresis return loop 11 and the magnetization itself

0 mouth; it is equal to the maximum residual magnetization (point of ordinates). The magnitude of the field Nd is chosen so that after the carrier leaves the zone of action of this field, the magnetization of the carrier itself is close to zero (section 12 of the hysteresis loop in Fig. 2). This state corresponds to the minimum noise during playback. The proposed variants of the erasing magnetic head make it possible to reduce the energy consumption, which is very important for the magnetic recording apparatus as a whole. At the same time, the noise level of the carrier affected by the erasing field is significantly reduced, which affects the quality of the newly recorded signal. /

F1, g.

Claims (2)

EASY MAGNETIC HEAD (ITS OPTIONS). 1. An erasing magnetic head containing a winding and a magnetic circuit interacting with the working surface of the magnetic carrier, consisting of one central and two identical side cores, between which working gaps are formed, characterized in that, in order to increase the erasing efficiency of the previously recorded waveform and reduce power consumption , the width of the working gap, located second in the direction of travel of the magnetic carrier, refers to the width of the working gap, located first in the direction of moving but rer, not less than 2.5: 1, wherein the winding is arranged on the central core. 2. An erasing magnetic head containing a winding and a magnetic circuit interacting with the working surface of the magnetic carrier, consisting of one central and two identical side cores, between which working gaps are formed, characterized in that, in order to increase the erasing efficiency of the previously recorded syshalogram and reduce power consumption , both working gaps are made of the same width, and the winding is divided into two half-windings; located on the side cores, while the number of turns of the semi-winding located on the first side core along the direction of movement of the magnetic carrier relates to the number of turns. Half-winding, located on the second side core along the direction of the magnetic carrier, at least 2.5: 1.