Optical system supporting device

An optical system supporting device in which an optical system holding member is supported by springs to be movable in focusing and tracking directions; and each of the springs has at least one portion which is oriented parallel with a tangential direction and one bending portion which is bent toward an optical axis of the optical system. Therefore, the holding member is made small in width with respect to the tracking direction; and thus the holding member can be made light in weight such that the driving sensitivity of the holding member is improved.

BACKGROUND OF THE INVENTION 
1) Field of the Invention 
The present Invention relates to an optical system supporting device for 
use in an optical information recording apparatus in which the optical 
information is recorded on an information recording medium such as an 
optical disc and an optical card by illuminating a light beam thereon. 
2) Prior Art Statement 
When illuminating the light beam on the information recording medium in 
order to record the optical information thereon, a focusing control and a 
tracking control of the light beam are necessary with respect to tracks 
formed on the recording medium. For the purpose of the focusing and 
tracking control of the light beam, an objective lens, which is arranged 
at an opposite side of the recording medium, should be smoothly moved in a 
focusing direction and a tracking direction. 
The objective lens is supported by a lens holder, i.e. an optical system 
supporting device; and the movement thereof is conducted by moving the 
lens holder in the focusing and tracking directions. Such optical system 
supporting device is, for instance, disclosed in Japanese Patent 
Preliminary Publication No. 59-221839. FIG. 1 is a schematic perspective 
view showing the optical system supporting device disclosed in this 
publication. An objective lens 21 is held in an objective lens holder 22; 
and the lens holder 22 is arranged on a base plate 23. At both sides of 
the base plate 23 in a tangential direction, are arranged fixing members 
24, 24. It should be noted that in this specification a tracking direction 
is represented by X direction, a tangential direction by Y direction and a 
focusing direction by Z direction, hereinafter. On inner walls of these 
fixing members 24, 24, magnets are provided, respectively. Between one of 
the fixing members 24 and the lens holder 22, four metal wires 25 are 
extended in parallel with Y direction. The wires 25 are arranged parallel 
to each other; and each end of these wires is secured to the fixing member 
24 and the lens holder 22. Therefore, the lens holder 22 is supported by 
the wires 25 so as to be movable in the focusing and tracking directions. 
In Japanese Patent Preliminary Publication No. 60-197942, there is 
disclosed another optical system supporting device. FIG. 2 is a 
perspective view depicting a structure of this device. In this device, the 
lens holder 27 holding an objective lens 28 therein is supported by four 
metal wires 29, 30, 31 and 32. As shown in FIG. 2, the wires 29 and 30 are 
extended in the Y direction, and the wires 31 and 32 are extended in the X 
direction; and one end of each wire is fixed to fixing members 33 and 34 
arranged on a base plate 35. In this device, the lens holder 27 is also 
arranged to be movable in the focusing and tracking directions. 
A critical commercial demand of an optical information recording apparatus 
having such optical system supporting device is that it be made small in 
size. Therefore, the optical system supporting device is also required to 
be made small in size. Further, in the optical information recording 
apparatus, it is required to expand a range over which the information can 
be recorded on the recording medium and the information recorded thereon 
can be read out therefrom. In order to expand the recording/reproducing 
range, the size of the supporting device in the tracking direction 
particularly should be made small. 
However, in the conventional device shown in FIG. 1, there are provided 
tracking coils 26 at both sides in the Y direction of the lens holder 22; 
and the wires 25 are arranged outside one of the tracking coils 26 
straightly. Therefore, the width of the lens holder 22 in the Y direction 
is determined according to the width of the tracking coil 26 and thus the 
width of the lens holder can not be made small. It may be suggested to 
bend the tracking coil 26 into an L shape in order to make the width of 
the lens holder 22 small, but a number of assembling processes of the pick 
up device would be increased. 
On the other hand, the conventional device denoted in FIG. 2, succeeds in 
making the width (in the X direction) of the lens holder 27 per se small, 
so that the lens holder 27 can be arranged in the vicinity of a spindle 
motor (not shown), which is provided for driving the pick up device as a 
whole. However, between the lens holder 27 and the fixing member 34, there 
are extended the metal wires 31 and 32 in the X direction, and thus the 
size in the X direction of the device as a whole becomes large. The 
information recording medium is generally stored in a cartridge, and in 
the cartridge, there is provided an opening for passing a light beam 
therethrough. Therefore, when the lens holder 27 is moved in the X 
direction, the fixing member 34 makes contact with the opening of the 
cartridge, so that recording and read out of information at an outer 
portion of the recording medium could not be conducted. 
SUMMARY OF THE INVENTION 
The present invention has for its purpose to provide an optical system 
supporting device in which the width in the tracking direction can be made 
small. Therefore, the optical information recording apparatus having the 
optical system supporting device according to the invention can be made 
small in size as a whole; and it is possible to record information even at 
an outer portion of the recording medium and to read out information 
recorded thereat. 
In order to carry out the above mentioned purpose, the optical system 
supporting device according to invention comprising: 
holding means for holding an optical system; 
driving means for driving said holding means in focusing and tracking 
directions; 
supporting means for supporting said holding means to be movable in the 
focusing and tracking directions, comprising at least a couple of 
supporting members for supporting said holding means; 
a base plate for carrying said holding means, driving means and supporting 
means; and 
each of said supporting members comprising at least one parallel portion 
being in parallel with a tangential direction and one bending portion 
being bent toward an optical axis of said optical system, and these 
parallel portions and the bending portion being formed in series as a 
single unit. 
In the optical system supporting device according to the invention, the 
supporting means for supporting the lens holder, i.e. the optical system 
holding means, comprises a bending portion which is bent toward the 
optical axis of the optical system. Therefore, it is possible to make the 
width in the X direction of the lens holder small.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT 
FIGS. 3 to 5 are schematic views showing the first embodiment of the 
optical system supporting device according to the invention. 
An objective lens 1 is arranged in an objective lens holder 2; and around a 
side wall of the lens holder 2 is wound a focusing coil 4. At both sides 
in a tangential direction of the lens holder 2 are mounted four tracking 
coils 5. A base plate 8 is formed by pressing and in a center portion of 
the base plate 8, is formed a concave portion 8a through which a light 
beam can be passed. On the base plate 8, there are provided a couple of 
outer yokes 9a, 9a and a couple of inner yokes 9b, 9b extending in 
parallel with said concave portion 8a in the X direction. The inner yokes 
9b, 9b are positioned in openings 3 and 3 arranged in the lens holder 2. 
On inner walls of both the outer yokes 9a, 9a, there are provided three 
magnets 10, 11, 11, respectively. The center magnet 10 is sandwiched by 
the side magnets 11, 11 and the polarity of the center magnet 10 is 
magnetized in an opposite manner to that of the side magnets 11, 11. 
At one side of the base plate 8 in the Y direction, there is provided a 
fixing member 7. Four springs 6 are extended from the fixing member 7 to 
the lens holder 2 such that the lens holder 2 is supported by the springs 
6 so as to be movable in the X and Z directions. The springs 6 are formed 
by etching a thin plate of beryllium copper having a thickness of about 
0.1 mm. As illustrated in FIG. 4, the springs 6 are covered by dampers 12 
made of butyl rubber. 
FIG. 5 depicts a connecting portion between the spring 6 and the lens 
holder 2. A projection 2a for arranging an end of the spring 6 is provided 
at a predetermined portion of the lens holder 2; and in the projection 2a 
there is provided a concave portion 2b. The concave portion 2b is engaged 
with the end 6j of said spring 6; and the end 6j is secured thereto by 
means of an agent. At the end portion 6j of the spring 6, there is 
provided a hole 6k through which said agent is sunk into a space formed 
between the spring 6 and the projection 2a, so that the spring 6 is 
engaged with the projection 2a in a fixed manner. In the end portion 6j of 
the spring 6, there is provided a small projection 6i. The movement in the 
Y direction of the spring 6 is limited by means of the projection 6i and 
the position of the spring 6 in the Y direction is determined by the 
engagement of the end portion 6j of the spring 6 with the projection 2a of 
the lens holder 2. Therefore, the position of the spring 6 can be 
determined easily and correctly without using a special positioning 
member, Further, in the end portion 6j, there is provided a notch portion 
6h to which a terminal 13 of the focusing coil 4 or the tracking coil 5 is 
connected by means of a soft solder. Since the terminal 13 is firstly held 
by the notch 6h and then the terminal 13 is secured thereto by the soft 
solder, the terminal 13 is secured to the spring 6 in an efficient manner. 
As shown in FIG. 4, at both ends of said fixing member 7 there are provided 
concave portions 7a, 7a into which the other ends 6e, 6e of the spring 6 
are fixed. It should be noted that in the other end 6e of the spring 6, 
the numeral number 6d represents a projection for determining the position 
of the spring 6, and 6f a hole for sinking the adhesive agent. In each of 
the other ends 6e of the springs 6, there is further provided projection 
6g. The projection 6g is secured to a land of a print substrate (not 
shown) by means of a soft solder in order to supply an electric current to 
the focusing coil 4 and the tracking coil 5 via the springs 6. 
Each spring 6 comprises a first parallel portion 6a arranged in parallel 
with the tangential direction, a bending portion 6b bent toward an optical 
axis of the objective lens 1 and a second parallel portion 6c parallel 
with the tangential direction. It should be noted that these parallel and 
bending portions are formed in series. Because the bending portion is bent 
toward the optical axis of the optical system and the second parallel 
portion 6c is arranged at a side of the objective lens 1, a distance 
between the second parallel portions 6c and 6c is the shortest in 
comparison with the distance between the first parallel portions 6a and 6a 
and the distance between the bending portions 6b and 6b. That is to say, 
the second parallel portions 6c and 6c are closest to the objective lens 
1. As shown in FIG. 3, two springs 6 are provided at each end portion of 
the fixing member 7, respectively, in the Z direction; and the springs 6 
and 6 arranged in the lower positions have the same structure as those of 
the springs 6 and 6 arranged in the upper positions. The lens holder 2 is 
supported by these four springs movably in the X and Z directions. 
In accordance with the optical system lens holder of the invention, the 
width in the X direction of the lens holder can be made small. Therefore, 
a space formed in the vicinity of the objective lens 1 becomes large so 
that a spindle motor (not shown) having a large diameter can be used. 
Further, it is possible to arrange a sensor for detecting a position of 
the lens holder 2 in the X direction in the space. Furthermore, since the 
distance between the second parallel portions 6c, 6c of the springs 6, 6 
is arranged to be narrower than the distance between the first parallel 
portions 6a, 6a, a stiffness of the springs 6 with respect to a rotation 
of the lens holder about the Y axis can be increased in comparison with 
the springs all portions of which are arranged in straight manner. 
In the first embodiment, as shown in FIG. 4, the numerical references 
W.sub.a, W.sub.b and W.sub.c represent the widths in a direction 
perpendicular to the extending direction of each portion of the springs 6. 
The numerical reference W.sub.a represents the width of the first parallel 
portion 6a, W.sub.b the bending portion 6b and W.sub.c the second parallel 
portion 6c, respectively. Additionally each spring 6 is arranged such that 
the width Wa of the first parallel portion 6a is equal to the width 
W.sub.c of the second parallel portion 6c and the width W.sub.b of the 
bending portion 6b is larger than the widths W.sub.a and W.sub.c. For 
instance, it may be arranged that the widths W.sub.a and W.sub.c are about 
0.3 mm, respectively, and the width W.sub.b is about 0.5 mm. The thickness 
of each spring 6 in Z direction is uniform at all portions. By such 
arrangement, the stiffness of the springs with respect to the rotations of 
the lens holder 2 about the X and Y axes and the stiffness of the springs 
in Y direction are increased. Therefore, it is possible to prevent that 
the optical axis of the objective lens 1 is inclined and possible to make 
a resonance frequency of the objective lens high. 
In the plan view shown in FIG. 4, magnetic fluxes, which work with the 
tracking coil 5 and the focusing coil 4, are indicated. A magnetic flux 
generated by the magnet 10 goes through one side 5a of the tracking coil 
5, further goes to the inner yoke 9b via the focusing coil 4. On the other 
hand, a magnetic flux generated by the magnet 11 goes through the other 
edge 5b of the tracking coil 5, in an opposite direction to the magnetic 
flux generated by the magnet 10. Therefore, the position of the optical 
beam illuminated on the track formed on the recording medium can be 
controlled by supplying a given electric current to the focusing coil 4 
and the tracking coil 5. 
As stated above, in the first embodiment, flat-shaped tracking coils 5 are 
secured on the side portions of the lens holder in the tangential 
direction. Therefore, the size of the optical system driving device in the 
tangential and tracking directions can be made small. The magnetic flux 
which works with the focusing coil 4 does not give damage to a driving 
sensitivity of the lens holder 2. It should be noted that three magnets 
are arranged at both inner walls of the outer yokes 9a, 9a, respectively, 
but it may be possible to arrange only on magnet magnetized in a multiple 
manner for the three magnets. 
FIG. 6 is a plan view showing the second embodiment of the optical system 
supporting device. In FIG. 6, the portions corresponding to the first 
embodiment are denoted by the same numerical references. 
The one end portion 6j of the spring 6 is engaged with the projection 2a 
provided in the lens holder 2, and the end portion 6j is fixed to the 
projection 2a by means of an agent. On the other hand, the other end 
portion 6e of the spring 6 is fixed to the concave portion 7a provided in 
the fixing member 7 in the same manner. As clear from FIG. 6, both of the 
end portions 6j and 6e of the springs 6 are formed to be hook-shaped 
toward the inner side. Additionally the projections 2a of the lens holder 
2 are projected to the Z direction. Therefore, it is possible to make the 
size of the lens holder 2 in the X direction smaller. It should be noted 
that, in FIG. 6, there is no indication of damper 12 in order to make the 
figure simple. Although there is no indication of the springs arranged in 
the lower position, the lens holder 2 and the magnets 11 are put between 
the respective two springs 6 arranged in the upper and lower positions of 
the device. 
In such structure of the springs 6 according to the second embodiment, the 
effective lengths of the springs 6, which are bent in the X and Z 
directions, can be made long. Therefore, when the lens holder 2 is 
deviated in the X direction, the deviation amount thereof in the Y 
direction becomes small. And, as stated above, in the second embodiment, 
the projections 2a are not projected in the X direction but in the Z 
direction, and thus the lens holder 2 can be formed small in size and 
light in weight. Therefore, the driving sensitivity of the holding member 
2 is increased and the moment of inertia about the Y axis thereof becomes 
small. Thus the resonance frequency is elevated. Further, it is possible 
to efficiently prevent resonance in the projections 2a themselves. 
The present invention is not limited to the above explained embodiments and 
several modifications or variations can be applied thereto. For example, 
the springs 6 may be arranged in shapes as shown in FIGS. 7A and 7B. That 
is to say, the springs 6 may have their shapes such that each has only one 
parallel portion and one bending portion as shown in FIG. 7A; and such 
that each has two parallel portions and one bending portion but the 
bending portion is bent at a right angle as shown in FIG. 7B. 
In the present invention, the driving means for driving the lens holder 2 
is not limited. Further, the present invention can be applied to a lens 
holder which is driven only in the focusing direction. 
As stated above, according to the present invention, the optical system 
holding member, i.e. lens holder 2 is supported by springs each having a 
bending portion bent toward the optical axis of the optical system. Thus, 
it is possible to make the size of the holding member small in the 
tracking direction. Since the weight of the holding member also becomes 
light, the driving sensitivity of the holding member can be increased. 
Further, since the supporting member, i.e. springs, comprises the bending 
portion, the holding member is not affected by a resonance mode of the 
springs so much. 
Furthermore, since the size of the lens holder in the tracking direction 
can be made small, the lens holder can move in a wide range so that it is 
possible to write in and read out the information on and from the 
information recording medium in a wide range. Moreover, the space formed 
at both sides of the lens holder becomes large, and then it is possible to 
arrange the spindle motor having a large diameter and a high efficiency in 
this space.