JPH04117693A - Magnetic disk device - Google Patents

Abstract

PURPOSE:To stably execute power supply and the transmission/reception of various signals without fail at all times by executing the power supply and various signal transmission between the magnetic disk device and the outside with noncontact. CONSTITUTION:The power supply is transmitted through mutual electromagnetic induction by transconnector parts 13 and 15, and the transmission/reception of signals is executed through mutual photocoupling by photocoupling parts 14 and 16. The transconnector part 13 on the side of a magnetic disk device 11 is faced to the transconnector part 15 on the outside and the photocouplng part 14 on the side of the magnetic disk device 11 is faced to the photocoupling part 16 on the outside respectively with noncontact in a coupling state. Therefore, even when the device is used for a long period, any physical change such as a change in power transmission efficiency or a change in the quality of signals, etc., is not generated. Thus, between the inside of the magnetic disk device 11 and the outside, the power can be stably supplied and the various signals can be transmitted without fail.

Description

[Detailed Description of the Invention] [Summary] Regarding a magnetic disk device, by performing the supply of power and the transmission of various signals between the magnetic disk device and the outside in a non-contact manner, it is possible to supply power and transmit and receive various signals. The purpose is to always be able to perform stably and reliably, and to provide mutual electronic TI! ! A trunk connector section that transmits power supply power through induction and an optical coupling section that transmits and receives signals through mutual optical coupling are provided between the magnetic disk device and the outside, and between the magnetic disk device and the outside. It is configured by supplying power and sending and receiving various signals without contact.

[Industrial application field]

The present invention relates to a magnetic disk drive, and more particularly to a magnetic disk drive in which a source line and an external input/output signal line are connected in a non-contact manner without compromising reliability at the connection part with the outside. It is.

In recent years, there has been a demand for higher density recording in magnetic recording, and along with this, a highly reliable signal input/output method is required.

That is, when recording and reproducing at high density, the beep/ ) interval becomes narrower, causing peak shifts and S/N deterioration due to waveform interference, and therefore more precise recording and reproducing signals are required.

Therefore, it is desired to accurately exchange signals between the inside and outside of a magnetic disk device, and to be able to supply stable power from the outside to the inside of the device.

[Conventional technology]

Conventionally, the method for connecting the power source and each signal in a magnetic disk device is to use a cable connector that fits into the power source and signal pins that protrude from the inside of the device toward the outside. The socket of the connector configured as above uses a configuration in which the opening clamps each pin by physical pressure, thereby maintaining electrical connection.

[Problem to be solved by the invention]

In such conventional connection methods, when used for a long period of time, the connection part tends to be gradually deformed by physical external force, making the connection unstable.

When an external force is applied to the connector that connects the power supply and various signals mentioned above between the inside and outside of the device, the contact area with the pin changes and large noise is generated for weak signals. . In addition, the power supply becomes unstable and reliability decreases.

The present invention aims to solve the problems of the prior art, and is capable of supplying power and transmitting various signals between a magnetic disk device and the outside in a non-contact manner. The purpose is to enable stable and reliable transmission and reception of various signals at all times.

[Means to solve the problem]

FIG. 1 shows the basic configuration of the present invention.

The present invention provides mutual communication between the magnetic disk device 11 and the outside using the transformer connector section 13.15.
Transmits power supply via magnetic induction, optical coupling unit 14.16
By transmitting and receiving signals through mutual optical coupling, power is supplied and various signals are transmitted and received between the magnetic disk device 11 and the outside without contact.

Further, the present invention provides two divided cores 21, 23 and each core 2 between the magnetic disk device 11 and the outside.
Both cores 21.23
When the two coils 22 and 24 face each other, power is transmitted through electromagnetic induction between the two coils 22 and 24, and the optical fiber cable 25
．． When the ends of both optical fiber cables 25.26 are coupled by the optical coupling section 14.16 having 26, optical signals are transmitted and received between the two optical fiber cables 25.26. 11 and the outside, power supply and various signals are transmitted and received in a non-contact manner.

Further, the present invention provides for a pot-shaped core 31 divided into two, a coil 34 housed inside the pot-shaped core 31, and a coil 34 housed inside the pot-shaped core 31 between the magnetic disk device 11 and the outside.
By providing a coupler 30 having an optical cable 36 extending through a central core 33 of
When the end faces of the respective pot-shaped cores 31 and the end faces of the optical cables 36 at 0 face each other, power is supplied and various signals are transmitted and received between the magnetic disk device 11 and the outside without contact. This is what I did.

[Effect]

In the basic configuration shown in FIG. 1, reference numeral 11 indicates a magnetic disk device.

In the magnetic disk device 11, 13 is a transformer connector section for receiving power supply, and 14 is an optical coupling section for transmitting and receiving various signals. In addition, the magnetic disk device 1
Externally, 15 is a transformer connector section for supplying power, and 16 is an optical coupling section for transmitting and receiving various signals.

The trans-connector section 13 on the magnetic disk drive side and the external trans-connector section 15 are configured to face each other in a non-contact manner in a coupled state.

Similarly, the optical coupling section 14 on the magnetic disk device side and the external optical coupling section 16 are configured to face each other in a non-contact manner in the coupled state.

FIG. 2 shows an example of the structure of the trans-connector section and the optical coupling section.

In the magnetic disk device 11, the transformer connector section 1
3 consists of a core 21 and a coil 22. core 21
For example, it consists of one core of an E-shaped cut core divided into two. In addition, the transformer lid portion 15 is connected to the core 23.
and a coil 24. The cores 21 and 23 have the same structure, and can be magnetically joined to each other without contact through the cut surfaces of the cores in a coupled state.

When AC power is externally applied to the coil of the transformer connector section 15 in the coupled state, an AC voltage is generated in the coil 22 in the transformer connector section 13 on the magnetic disk device 11 side due to electric induction. Power is supplied internally.

In the magnetic disk drive 11, the optical coupling section 14 is composed of a plurality of optical fiber cables 25 connected to the inside of the magnetic disk drive. On the other hand, the optical coupling section 16 is made up of a plurality of optical fiber cables 26 that can be connected to the outside.

In the coupled state, the optical fiber cable 25 and the optical fiber cable 26 face each other in a non-contact state. Both optical fiber cables 25 and 26 have their respective end faces polished flat, and are configured to be able to mutually transmit and receive optical signals through their respective end faces in a non-contact manner. Alternatively, lenses or the like may be provided on the end faces of both optical fiber cables 25 and 26 to converge and couple the light.

In the present invention, since it has such a configuration,
Power can be supplied from the outside to the inside of the magnetic disk device through the transformer connector portion in a non-contact manner, and various signals can be sent and received between the inside and outside of the magnetic disk device. Various signals in this case include, but are not limited to, a recording/reproducing signal, a magnetic head switching signal, a read/write switching signal, an error detection signal, and an AE multiplication signal.

According to the present invention, power is supplied by electromagnetic induction in the transformer connector part, and various signals are sent and received through optical coupling in the optical coupling part, so even with long-term use, the power transmission efficiency changes. It is possible to provide a stable supply of power and reliably transmit various signals between the inside and outside of the magnetic disk device without causing physical changes such as changes in the quality of signals sent and received. .

〔Example〕

FIGS. 3(a) and 3(b) show one embodiment of the present invention, illustrating the configuration of a coupler 30 that integrates a transformer connector part and an optical coupling part, and FIG. Cross-sectional view, (b
) is a perspective view.

In the figure, reference numeral 31 denotes a pot-shaped core made of a magnetic material, the end surface 32 of which is polished into a flat surface, for example, and the center core 33 has a through hole at its center. A coil 34 is provided inside the pot-shaped core 31, and is connected to the outside via a power lead wire 35. On the other hand, the optical cable 36 is inserted into the through hole at the center of the central core 33 .

Fixed. The end face 37 of the optical cable 36 is, for example, polished to a flat surface.

FIG. 4 shows an example of how to install the coupler, in which a recess 17 is provided in the lower part of the magnetic disk drive 11.
The coupler 3 shown in FIGS. 3(a) and (b) is attached to that part.
It is shown that 0 is attached.

5(a) and 5(b) illustrate a method of coupling the magnetic disk device to the outside, in which (a) the magnetic disk device 11 is housed in the recess 17 of the computer main body 18. (b) shows the state in which the magnetic disk device is pulled out from the recess 17.

As shown in FIG. 5(a), when the magnetic disk drive 11 is stored in a predetermined position within the computer main body, the coupler 30A on the magnetic disk drive 11 side and the coupler 30B in the computer main body 18 are as follows. The end faces thereof are configured to face each other without contacting each other.

In the second state, the end surfaces of the valve-shaped core of the coupler 30A on the magnetic disk drive side and the valve-shaped core of the coupler 30B on the computer main body side are polished flat, so that
The coils provided inside each are tightly coupled, and the power supply lead f! The power supplied to the coil from 35B is transmitted to the coil on the magnetic disk device 11 side by electromagnetic induction, and is then connected to the source lead wire 3.
The signal is supplied to the magnetic disk device through 5A.

In addition, at this time, the optical cable 36B on the computer main body side and the optical cable 36A on the magnetic disk device side provided in the central core have their respective end surfaces polished flat and face each other, so the optical signals are transmitted to each other with low loss. The information is sent and received between the computer main unit and the magnetic disk drive. In addition,
Instead of polishing the end face of the optical cable into a flat surface as described above, a lens or the like may be provided to converge the light and couple it to each other.

[Effects of the Invention] As explained above, according to the present invention, the supply of power and the transmission of various signals between the magnetic disk device and the outside can be
Since this can be done contactlessly and efficiently, the supply of power and the transmission and reception of various signals can always be performed stably and reliably.

Therefore, according to the magnetic disk device of the present invention, it is always stable and
It is possible to perform reliable recording and reproduction, and it greatly contributes to high-density recording in magnetic disk devices.

[Brief explanation of the drawing]

Fig. 1 is a diagram showing the basic configuration of the present invention, Fig. 2 is a diagram showing an example of the configuration of a transformer connector section and an optical coupling section, and Fig. 3 (a
), (b) is a diagram showing an embodiment of the present invention, FIG. 4 is a diagram illustrating a method for attaching a coupler, and FIG. 5 (a), (
b) is a diagram illustrating a method of coupling the magnetic disk device to the outside; 11 is a magnetic disk device, 13.15 is a transformer connector section, 14.16 is an optical coupling section, 21 and 23 are cores, 22
．． 24 is a coil, 25.26 is an optical fiber cable, 3
1 is a valve-shaped core, 33 is a central core, 34 is a coil, and 36 is an optical cable. Fig. 1 Fig. 2 Coil (a) (b) Fig. 3 A drawing showing an embodiment of the present invention Fig. 3 Fig. 3 A drawing illustrating the method of attaching the coupler (a) Recess (b)

Claims (3)

[Claims] (1) A transformer connector section (13, 15) that transmits power from the power supply via electromagnetic induction between them, and an optical coupling section (1) that transmits and receives signals via optical coupling between them.
4, 16) are provided between the magnetic disk device (11) and the outside, and power supply and various signals are transmitted and received between the magnetic disk device (11) and the outside without contact. disk device. (2) It has two divided cores (21, 23) and coils (22, 24) provided in each core (21, 23), and when both cores (21, 23) are opposed, both A transformer connector section (13, 15) that transmits power supply power via electromagnetic induction between the coils (22, 24), and an optical fiber cable (25, 26) having an end of both optical fiber cables (25, 26). The optical coupling section (14, 16), which transmits and receives optical signals between both optical fiber cables (25, 26) when the sections are coupled, is connected to the magnetic disk device (
11) and the outside, and supplying power and transmitting and receiving various signals between the magnetic disk device (11) and the outside in a non-contact manner. (3) One pot-shaped core (31) divided into two, a coil (34) housed inside the pot-shaped core (31), and a central core (33) of the pot-shaped core (31). A coupler (30) having an optical cable (36) extending therethrough is provided between the magnetic disk device (11) and the outside, and each pot-shaped core (31) in both couplers (30)
) and the end surface of the optical cable (36) face each other, power is supplied and various signals are transmitted and received between the magnetic disk device (11) and the outside without contact. Magnetic disk device.