DE9116848U1 - Disk unit - Google Patents

Description

Disc unit

The invention relates to a window unit according to the preamble of claim 1.

Fig. 5 shows the positional relationship between the spindle motor, the carriage assembly and the stepper motor of a known flexible disk unit.

Fig. 6 is a sectional view illustrating the positional relationship between the spindle motor and the carriage of the disk unit. Fig. 7 shows the entire structure of the disk unit. In these figures, a spindle motor 1 for rotating a magnetic recording medium (not shown) in the form of a flexible disk, a drive magnet la, a stator Ib, a coil Ic, a substrate Id for the spindle motor 1, a clamping hub Ie, a rotation axis If, an IC chip lh, a connection terminal Ij, a magnetic housing In, a frame 2, a carriage assembly 3, a carriage 3a

for mounting a magnetic head 3c, an arm 3b for mounting a magnetic head 3d, a stepping motor 4 for searching and positioning the carriage assembly in the radial direction of the medium, a spindle 4a directly connected to the rotation axis of the stepping motor 4, a sensor 5, a slide cam 6, a cassette holder 7, a lever 8, a substrate 9, a shield cover 10 and a front cover 11.

The operation of the disk unit is described below. When the magnetic recording medium (not shown) is inserted into the unit, it is brought into the write/read position (loading position) by a loading mechanism consisting of the slide cam 6, the cassette holder 7 and the lever 8.

A detailed explanation of the loading mechanism is omitted here. When the medium is brought into the loading position, the hub of the medium is clamped by the clamping hub Ie of the spindle motor 1 attached to the frame 2 and the medium rotates due to the rotation of the spindle motor.

A projection (not shown) provided on the carriage assembly 3 engages in a groove of the spindle 4a directly connected to the axis of the stepping motor 4, so that the rotary movement of the stepping motor 4 is converted into a movement of the carriage assembly 3 in the radial direction of the medium. Therefore, the magnetic heads 3c and 3d on the carriage assembly 3 can be moved in the radial direction of the magnetic recording medium by means of the stepping motor 4 and positioned over the target track. The assembly of the known disk unit is shown in Figs. 5 and 6. This means that an external rotor type spindle motor is used in which the

drive magnet la is arranged outside the stator Ib and the coil lc, and that the carriage arrangement 3 is located above the stator Ib, the coil Ic and the drive magnet la, as can be seen from Fig. 6.

The rotation axis If is arranged above the spindle motor substrate Id, and the clamping hub Ie rotates about the rotation axis If so that the flexible disk serving as a magnetic recording medium is placed on the clamping hub Ie and rotated. Electronic parts such as the IC chip lh and the connection terminal Ij for connecting the substrate 9 of the main unit are arranged on the back of the spindle motor substrate Id. In this case, the height (thickness) of the unit is determined by the total of the thicknesses of the carriage assembly 3, the substrate Id of the spindle motor 1 and the largest of the magnet housing In, the IC chip lh on the substrate Id (on the side opposite the carriage assembly 3) and the connection terminal Ij, as well as the spaces between them.

In the above-described conventional disk unit, the carriage assembly 3 must be made thin in order to reduce the thickness of the disk unit. However, the magnetic heads 3c and 3d can only be reduced in height to a certain extent in conjunction with the medium. Furthermore, the reduction in the thickness of the drive magnet 1a, the coil Ic and the housing In of the spindle motor 1 is limited if the operation is not to be impaired. Similarly, the thicknesses of the IC chip and the electrical connections on the motor substrate Id cannot be reduced. Thus,

it is difficult to make the known disk unit thin.

It is therefore the object of the present invention to provide a disk unit having a thin structure.

This object is achieved according to the invention by the features specified in the characterizing part of claim 1. Advantageous further developments of the disc unit according to the invention emerge from the subclaims.

The disk unit of the present invention having electronic parts and a connection terminal structure comprises a motor substrate for mounting an inner rotor, an outer rotor or a belt drive motor, a clamping member (clamping hub) rotating around the rotation axis of the motor and on which the magnetic recording medium is mounted, a carriage with magnetic heads guided in the radial direction of the clamped magnetic recording medium, electronic parts such as an IC for controlling the motor, and a connection terminal for connecting the leads of the motor substrate to the leads of another substrate. In this disk unit, an extension is provided on the motor substrate, and the electronic parts and the connection terminal are arranged on the extension on the carriage side so that there is no interference with the recording medium.

Since the IC module and the connection terminal are located above the motor substrate on the side of the carriage

and the height of the IC chip and the connection terminal is less than the height of the carriage, it is possible to reduce the thickness of the disk unit.
5

The invention is explained in more detail below using an embodiment shown in the figures. They show:

Fig.1

to 4 a top view, side view and

exploded view of a disk unit according to an embodiment of the invention, and 15

Fig.5

to 7 a top view, side view and

exploded view of a known disk unit. 20

Fig. 1 shows the positional relationship between the spindle motor, the carriage, the stepping motor and the magnetic recording medium. Fig. 2 shows the positional relationship between the stator, the coil and the carriage. Fig. 3 shows the positional relationship between the spindle motor and the carriage in a sectional view. Fig. 4 shows the overall structure of the disk unit. In these figures, a spindle motor 1 with a rotor for rotating a magnetic recording medium 12, a drive magnet la provided on the outer circumference of the rotor, an annular stator Ib, a coil Ic provided on the inner circumference of the stator Ib, a substrate Id, a clamping hub Ie, a rotation axis If and a recess Ig kept free from the coil Ic, which is formed by pressing in (recessing) a part of the outer

circumference of the stator 1b inwardly, an IC chip 1h for the spindle motor, »a connection terminal 1j for the substrate 9, a frame 2, a slide assembly 3, a slide 3a for attaching a magnetic head 3c, an arm 3b for attaching a magnetic head 3d, a stepping motor 4 for moving the slide assembly 3 in the radial direction of the medium and for positioning it, a spindle 4a connected to the rotation axis of the stepping motor 4, a sensor 5, a slide cam 6, a cassette holder 7, a lever 8, a substrate 9, a shield cover 10 and a front cover 11. On the motor substrate Id, an extension Ix extends from the spindle motor 1 to one side of the carriage assembly 3 so that electronic parts such as the IC chip lh and the connection terminal Ij are mounted on the upper side, on which the carriage assembly 3 is located, of the extension Ix.

The operation of the disk unit is described below. As shown in Fig. 4, when the magnetic recording medium (not shown) is inserted into the unit, it is brought into the read/write position (loading position) by a loading mechanism consisting of the slide cam 6, the cassette holder 7 and the lever 8. A detailed explanation of the loading mechanism is omitted here. When the medium is brought into the loading position, the hub of the medium is clamped by the clamping hub Ie of the spindle motor 1 attached to the frame 2, and the medium rotates by the rotation of the spindle motor.

A projection (not shown) provided on the carriage arrangement 3 engages in a groove of the spindle 4a, which is directly connected to the axis of the stepper motor 4.

so that the rotary motion of the stepping motor 4 is converted into a motion of the carriage assembly 3 in the radial direction of the medium. Therefore, the magnetic heads 3c and 3d on the carriage assembly 3 can be moved in the radial direction of the magnetic recording medium by means of the stepping motor 4 and positioned over the target track.

The disc unit according to the invention is shown in Figs.

1, 2 and 3. That is, an inner rotor type spindle motor is used in which the drive magnet la is arranged inside the stator Ib and the coil Ic, and further a recess Ig kept clear of the coil Ic is formed by pressing a part of the outer circumference of the stator Ib toward the inner circumference thereof. When the carriage 3a is positioned on the inner circumference side, it enters the recess Ig and is on the same plane as the stator Ib, the coil Ic and the drive magnet la.

According to Fig. 1, the parts mounted on the spindle motor substrate Id, i.e. the IC package lh and the connection terminal Ij, are in the same plane above the extension Ix, thus being outside the area in which the medium 12 is loaded.

Therefore, the heights of the IC chip lh and the connection terminal Ij are smaller than those of the carriage 3a. The height (thickness) of the unit is determined by the total of the thicknesses of the carriage assembly 3 and the substrate Id of the spindle motor 1 and the gap between them, as can be seen from Fig. 3. The IC chip lh and the connection terminal Ij are mounted on the substrate Id in the

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the same plane as the carriage assembly 3 and further the medium is loaded in such a manner that there is no interference with the IC chip and the connection terminal on the spindle motor substrate. Therefore, it is possible to reduce the thickness of the unit and obtain an inexpensive disk unit without impairing the mechanical strength thereof by making a hole (not shown) in the outgoing part frame or without having a height difference in the outgoing part frame.

It is possible to connect the spindle motor substrate and the main unit substrate at a short distance and at a low cost because the spindle motor substrate is extended to a large extent.

As shown in Fig. 1, an inner rotor type spindle motor having the recess Ig is used to explain that the IC chip lh and the connection terminal Ij, i.e., the parts on the substrate Id of the spindle motor 1 are arranged so as not to interfere with the magnetic recording medium in the in-plane direction. The same effect can be obtained with either an inner rotor or an outer rotor or a belt-driven motor.

The recess Ig in a part of the stator Ib can also be formed by a corresponding opening.

Claims (2)

New protection claims 1. Disc unit with a motor for rotating a magnetic recording medium located on one side of the motor, a motor substrate for mounting the motor located on another side of the motor, electronic components for controlling the motor, a connecting element for connecting a line to the motor substrate, and a carriage arrangement comprising a carriage and an ^P arm, each having a head, thereby characterized in that the motor substrate (Id) has a has an extension region (Ix) which extends beyond the magnetic recording medium (12), that the electronic components (lh) and the connecting element (Ij) are arranged on the extension region (Ix) and the motor substrate (Id) is otherwise kept free of electronic components (lh), and that the total height of the electronic components (lh) and the connecting element (Ij) is included in the height of the slide arrangement. 2. Disk unit according to claim 1, characterized in that the motor is a spindle motor (1) which contains the rotor for rotating the magnetic recording medium (12) and a magnets (la) on the outer circumference of the rotor, that an annular stator (Ib) surrounds the spindle motor (1) and has a recess (Ig) for receiving the carriage (3a) when it is moved to the magnetic recording medium (12) and that a coil (Ic) on the inner circumference of the stator (Ib) opposite the Magnet (la) is provided, wherein the recess (lg) is kept free from the coil (Ic).