CS213911B1 - Setting holder - Google Patents

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an alignment bracket for, in particular, the precise and constant alignment of magnetic heads with respect to a magnetic record carrier, particularly in electronic devices, particularly in the field of computer and measurement equipment. Furthermore, wherever it is necessary to position the magnetic heads, in particular multi-track in precise embodiments by means of positioning plates, to a precisely determined, fixed and stable position.

In the field of accurate and stable alignment of magnetic heads in sophisticated electronic devices, several known alignment bracket designs are used which differ from one another in their design.

One method of magnetic head positioning brackets hitherto used is a bracket which allows the magnetic head to be mounted on a plate that is fixedly connected to the base plate on one side. On the other hand, it is connected to the base plate by means of a differential screw, which is screwed into the base plate by one thread and the other into the magnetic head plate, the magnetic head plate being pushed away from the base plate by spring. board. Here, the tilting of the plate is made possible by the rotation of the differential screw and is also conditioned by the weakening of the plate at a certain location near the fixed attachment to the base plate so as to allow springing of the plate at these locations.

For this embodiment, it seems advantageous that the magnetic head plate is fastened in the region of 1313 911

213 911 does not deform the magnetic head and can be adjusted continuously, but the stability of this setting is clearly dependent on the magnitude of the spring force pushing the magnetic head plate away from the base.

Another known embodiment of the positioning holder of the magnetic heads is one in which the magnetic head plate is firmly screwed to the base plate at one end, the other side of the plate being attracted by the pull screw towards the base while being pushed by the push screw away from the base. If one pull bolt and one push bolt are used, this design is very simple. The screws are usually placed side by side, creating bending moments which cause undesirable deformation of the alignment plates of the magnetic heads. The deformations are directly proportional to these moments and must be compensated by the large thicknesses of the magnetic head alignment plates.

Another solution is a magnetic head alignment plate provided with three ejector bolts resting on the base plate by a spring-induced Talium. By sliding the screws to a certain level, the required position of the magnetic head relative to the base is adjusted. The stability of this alignment method is again dependent on the magnitude of the force exerted by the spring, also with greater spring force the undesirable deformation of the locating plate of the magnetic head occurs and it is therefore necessary to increase its thickness with respect to the minimal deformations.

The known arrangement is a method in which the magnetic head plate is designed as a single-reversible or double-reversible lever supported in one place by a protrusion of the base plate and pulled by a spring to the base plate, in the case of a reversible lever. at the other end. The same applies to this arrangement, as has been said in the previous paragraph.

The examples of magnetic head positioning brackets used hitherto show obvious advantages and disadvantages of the individual solutions, which allow relatively precise positioning of the magnetic heads in electronic devices. When registering the advantages of these solutions, their disadvantages also come to the surface. In the above-mentioned solutions, the stability of the adjustment appears in the first case, and in the second case a certain deformation of the base plates of the magnetic heads given by their design. In other cases, mostly simpler and undemanding, both or one of them usually occurs. In precision and demanding equipment, these deficiencies must be adequately addressed. In addition to the above-mentioned purely functional aspects, other aspects are also contemplated, for example the space requirements of the locating devices can be mentioned and the manner of operation of the locating devices is also negligible.

From this basic information, a new solution for the locating bracket has been sought, which would eliminate the mentioned disadvantages of the above-described solutions of the locating brackets of the magnetic heads.

SUMMARY OF THE INVENTION The base plate is connected to the locating plate by means of an adjusting screw or adjusting nut, an operating ring and a spacer screw or a spacing nut, which passes freely through the adjusting screw or adjusting nut and the operating ring and are screwed into the yoke or a screw that is firmly connected to the base plate. Control ring, adjusting screw or constitution3

213 911 the lock nut and the spacing screw or spacers are coaxial, such as the cylindrical face in the locating plate, the thread in the base plate, the through screw, the cylindrical shoulder of the actuating ring and the cylindrical shoulder of the locating screw or the adjusting nut. The adjusting screw or adjusting nut is provided with transverse walls which contact the transverse walls of the operating ring, which is provided with the operating walls at the opposite end.

This holder arrangement allows accurate and stable alignment of the magnetic heads. Allows you to operate the adjusting and spacer bolts from one compartment. Because the individual parts are aligned coaxially, they cannot generate bending moments during alignment that would cause undesirable deformations of the magnetic head alignment plate. By not using a spring in the solution to eliminate undesirable clearances between the parts, this locating bracket is very strong and the position after adjustment is stable. Another advantage is the low space requirement, which is particularly advantageous, since space in electronic devices is usually limited.

The invention is explained in the accompanying drawings, in which: Fig. 1 is a front view of the alignment bracket with the magnetic head; Fig. 2 is a section along the AA plane taken through the various functional parts of the alignment bracket; Fig. 4 is a partial cross-sectional view of the locating bracket in a relaxed position; Fig. 5 is a partial cross-sectional view of the locating bracket in a fully stable position; Fig. 6 shows the spatial arrangement of parts and important working surfaces of the locating bracket. design of the positioning holder of the magnetic heads with the positioning and positioning nut

FIG. 1 shows an overall front view of the magnetic head alignment holder having a magnetic head 8 attached to the alignment plate 2. The alignment plate 2 is rigidly connected to the base plate 1 at one end. £ and fastening screw 2. »through which freely passes the second adjustment screw» ^za_ screwed into the caliper sixth »which is rigidly connected with the base plate £.

Giant. 2 is a sectional view taken along the plane AA of the locating bracket shown in FIG. 1. The sectional view in this figure shows that by pulling the spacer screw 2 »screwed by its thread 5a into the thread 6a of the yoke 6 which is fixedly connected to the base plate 1; By means of the connecting screws 6, a fixed connection of the alignment plate 2, via the alignment ring 8 ^{and the} alignment screw 2 to the base plate 6 is caused. The picture also shows the location of individual building elements and their cross-sections. Here too, the clearance 21 between the spacer ring 8 and the adjusting screw 2 can be seen. The basic clearance 20 between the control ring 8 and the adjusting screw 2, which is necessary for the reliable operation of the adjusting bracket, is also apparent.

Fig. 3 shows the assembly sequence of the individual parts of the locating bracket in the exploded state. It is easy to see the individual workspaces that do not coincide with or overlap with others in this exploded drawing. These are the bearing surface of the spacer screw head 5a «the upper bearing surface of the control ring 4a. It is also good to see

213 911 the lower bearing surface of the control ring 4b and the upper face of the alignment plate of the magnetic head 2a. Other pairs of interconnected surfaces - the lower surface of the locating plate 2b and the bearing surface of the exchanger screw 3a - are also clearly visible. Also the threads following the function of the self-threading thread 3b of the adjusting screw and the threads of the base plate are clearly visible.

Giant. 4 and 5 illustrate the function of the positioning device. Fig. 4 shows the magnetic head alignment holder in the released position, while Fig. 5 shows the final stable position.

In the released position of the magnetic head positioning holder, a spacer screw 2 is visible which is screwed by thread 5b into the yoke 6a of the yoke 6 so that a certain clearance 18 is created between the bearing surface of the spacer screw head 5a and the upper bearing surface of the control ring 4a. permits movement of the locating plate 2 of the magnetic head 8 in the direction of this play. By rotating the control ring 6, an alignment screw 2, provided with a thread 2b, is screwed into the thread of the base plate 1a so as to create a clearance 22 between the alignment screw 2 and the alignment plate 2 of the magnetic head 8. the magnetic head plate 2 in the direction of this play. The required position of the locating plate 2 is then ensured in the stable position by tightening the spacer screw 2 by means of the _t ring rings. In this case, the contact surface of the head of the spacer screw 5a is pressed against the upper contact surface of the control ring 4a. the lower locating surface plate 2b sits on doaedací surface 3a of the second securement screw · ^This všeohny while defining a clearance between the threads 3b of the locator screw and the threads of the base plate 1a, as well as to define the clearance between the threads of the screw and the spacer 5b, 6a of the yoke windings <5th

It is clear from the above that setting the adjusting screw 2 into the desired position as well as position stabilization is possible over a wide range, both functions being carried out from one direction. Since the individual parts are located coaxially in the device, no undesired bending moment occurs after stabilization and the magnetic head positioning plate 2 is not deformed.

Giant. 6 illustrates the spatial arrangement of the individual parts of the magnetic head alignment device. The figure shows the individual shapes of parts and functional surfaces, which could not be clearly illustrated in the previous figures.

FIG. 7 shows a solution with a spacer nut 2 ^{and an} adjustment nut 10. This section shows that the pressure of the spacer nut 2 »screwed by its thread onto the thread of the through bolt 11, which is fixedly connected to the base plate and the connecting screws 8, is caused by the fixed connection of the locating plate 2, via the locating ring 8 and the locating nut 10, to the base plate 1;

Claims (1)

Adjusting bracket, characterized in that the base plate (1) is connected to the adjusting plate (2) by means of an adjusting screw (3) or an adjusting nut (10), an operating ring (4) and a spacer screw (5) or a spacer nut (9) wherein the spacing screw (5) or spacing nut (9) passes freely through the adjusting screw (3) or the adjusting nut (10) i 213 911 with the control ring (4) and are screwed into the yoke (6) or through the screw (11), which are firmly connected to the base plate (1), the control ring (4), the adjusting screw (3) or the adjusting the nut (10) and the spacer bolt (5) or the spacer nuts (9) are coaxial, such as the cylindrical surface (2c) in the locating plate (2), the thread (1a) in the base plate (1), the through bolt (11), the cylindrical shoulder (4d) of the control ring (4) and the cylindrical shoulder (3d) of the adjusting screw (3) or the adjusting nut (10), the adjusting screw (3) or the adjusting nut (10) being provided with transverse walls (3c) they touch the transverse walls (4c) of the control ring (4), which is provided with the control walls (4e) at the opposite end.