JP2011008970A5 - - Google Patents

Description

The present invention relates to an electronic device such as a digital Luke camera, and in particular an electronic apparatus having a rotary steerable operating member.

Conventionally, in electronic devices such as digital Luke camera, in order to adjust the zooming and focusing of the lens barrel, it is common to operate the operation ring around the barrel.

Disassembled perspective view of front cover unit Front view of digital camera Rear view of digital camera Rear view of front cover unit Enlarged view of annular member 22 Side view of annular member 22 and photo reflector Photo reflector output timing chart The figure explaining the annular member at the time of serving as both the opening for detection of a click, and detection Cross section of front cover unit

Hereinafter, a digital camera as an electronic apparatus according to an embodiment of the present invention will be described with reference to FIGS.

FIG. 1 is an exploded perspective view of a front cover unit of a digital camera which is an example of an electronic apparatus .

Next, the configuration of the operation ring 2 that is a rotatable operation member will be described with reference to FIGS. 1 and 4. In FIG. 1, a base 21 formed of a synthetic resin material is bonded and fixed to the inner surface of the front cover 4 with a double-sided tape or an adhesive. Operation ring 2 is fitted from the exterior surface of the front cover 4 to the base over scan 21. After fitting the operation ring 2 to base over scan 21, attaching the annular member 22 is a rotating member that rotates within a digital camera from the inside of the front cover 4 to the operation ring 2. Then, the claw portion 2 a formed on the inner periphery of the operation ring 2 and the hook portion 22 a of the annular member 22 are engaged. The claw portion 2a and the hook portion 22a are formed at three positions at intervals of 120 degrees. Engagement method is not limited to this, permitting the size of the camera body, the operating ring 2 may be screwing fixing the annular member 22.

Thus operation ring 2 will not be removed in the optical axis direction with respect to the front cover 4 and base over scan 21. The outer peripheral surface and the inner circumferential surface of the base over scan 21 of the operation ring 2, that is the inner surface of the annular member 22 and the base over scan 21 slides, the operation ring 2 and the annular member 22 is integrally front It is rotatably held to the cover 4 and base over scan 21.

The base over scan 21 fixed to the front cover 4, the auxiliary light window member 9 is fixed. In addition, the base over scan 21 fixed to the front cover 4, the detection mechanism 42 is operating ring 2 for detecting the rotation of the click mechanism 41 and the operation ring 2 for generating a click feeling when the rotation is fixed.

The click mechanism 41 includes a steel ball 23 that contacts the first hole 22x of the annular member 22, a spring 24 that biases the steel ball 23 toward the annular member 22, a holding member 25 that holds the steel ball 23 and the spring 24, and a spring. The conductive member 26 is electrically connected to one end of 24. Then, attach the conductive member 26 so as to cover the holding member 25 for holding the steel balls 23 and springs 24 by screws 29a, it is secured to the base over scan 21. In this embodiment, since the operation ring 2 is made of metal, such a configuration is adopted. However, if the operation ring 2 is a non-conductive member such as a synthetic resin material , the conductive member 26 can be eliminated.

The click mechanism 41 rotates the annular member 22 to repeat the time when the steel ball 23 falls into the first hole 22x by the urging force of the spring 24 and the time when the steel ball 23 rides on the annular member 22. A click force is generated when falling into the hole 22x. A desired click force can be obtained by adjusting the width X of the first hole 22x according to the diameter of the steel ball 23 or adjusting the biasing force of the spring 24.

The detection mechanism 42 includes a detection flex 28 in which two photo reflectors facing the second hole 22 y of the annular member 22 are mounted, and a fixing member 27 for fixing the detection flex 28 to the resin base 21. The Two holes for positioning the two photo reflectors mounted on the detection flex 28 are formed in the fixing member 27. The photo reflectors are respectively fitted in the two positioning holes, and the detection flex 28 is attached by screws 29b. It is fixed to the base over the scan 21. Thus, the two photo reflectors are positioned so as to face the second holes 22y, respectively.

In this embodiment, the generation of the click force uses the first hole 22x, and the rotation detection uses the second hole 22y that is wider than the first hole. However, as shown in FIG. It is also possible to use a common hole. In this case, since the hole can be made small, the radial direction of the annular member can be made small. However, when the holes are made common, the sliding trace of the steel ball that generates the click force can be formed between the holes of the annular member, so that the reflectance of the annular member changes. Therefore, when a photo reflector is used for detection, the detection reliability is lowered. Further, grease may be applied to reduce wear of the annular member or the steel ball, but also in this case, the reflectance of the annular member changes due to the grease adhering to the annular member. Therefore, if the hole is made common, the reliability of detection is lowered by the grease adhering to the annular member. If a photo interrupter is used, the reliability is improved, but the thickness direction of the imaging device is increased. Further, as shown in FIG. 7, the detection signal has higher detection accuracy when High and Low are equally spaced. For these reasons, the first hole 22x for generating the click force and the second hole 22y for rotation detection are separated without being shared, and the second hole 22y for rotation detection is used for generating the click force . The width is preferably larger in the circumferential direction than the first hole 22x. Further, the circumferential width of the second hole for rotation detection and the circumferential distance between the second holes are set to 5 ° when one click is 10 ° as shown in FIG. Thus, it is preferable that they are equally spaced.

When the circumferential width of the second hole 22y used for rotation detection is reduced, the detection accuracy is affected. However, the circumferential width of the first hole 22x that generates the click force is equal to the diameter of the steel ball 23. On the other hand, unless it is made extremely narrow, even if it is made somewhat narrow, the click force is not greatly affected. On the other hand, if the circumferential width of the first hole 22x is made larger than the diameter of the steel ball 23, the steel ball 23 will play in the first hole 22x, and the click position will not be stable. .

Therefore, in this embodiment, as shown in FIG. 5, the first hole 22x for generating the click force is on the inner peripheral side, and the second hole 22y used for rotation detection is on the outer peripheral side, so that the circular shape of the annular member 22 is increased. The peripheral part is used efficiently.

FIG. 9 shows a cross-sectional view of the front cover unit. As shown in FIG. 9, the lower side of the first hole 22x is arranged operation ring 2, the lower side of the second hole 22y base over scan 21 is arranged. In consideration of detection by the photo reflector, it is preferable that the lower side of the second hole 22y has a space so that the reflected light becomes weak, and the material color is black. The material and material color of the operation ring 2 are often limited by design. From this point, it is preferable that the second hole 22y for rotation detection is on the outer peripheral side. In consideration of the reflection efficiency, it is better to reflect the light beam by the annular member 22 closest to the photo reflector. For these reasons, using a highly reflective material on the annular member 22, it is preferable to use a low reflectance material is the base over scan 21.

1 camera body 2 the operation ring 3 lens barrel 4 front cover 21 base over scan <br/> 22 annular member 23 steel ball 24 spring 25 holding member 26 the conductive member 27 stationary member 28 for detecting the flexible 29 bis 31 photo reflector 41 clicks Mechanism 42 Detection mechanism