JPH09211727A - Fitting part structure for reflecting mirror - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide the structure of a fitting part by which working efficiency for fitting a reflecting mirror is enhanced and a device is made compact. SOLUTION: By elastically deforming the tip part of a supporting plate 220 by using a finger 242, the entrance of an inserting path 233 is enlarged. In such a state, the back surface 126A of the reflecting mirror 126 is positioned on the plate 220 side and the mirror 126 is inserted in the path 233 along the plate 220. Next, the mirror 126 is moved along the plate 220 and inserted in the path 233 until it abuts on a stopper piece 236. When the whole of the mirror 126 is inserted in the path 233, the mirror 126 is pressed and fixed by a leaf spring 238 formed on the plate 220 and a guide rail 232. Simultaneously, a catch 240 formed on the tip part of the plate 220 is locked to the edge of the mirror 126 so as to prevent the mirror 126 from getting away from the path 233.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a reflecting mirror mounting portion structure, and more particularly to a reflecting mirror mounting portion structure which constitutes a film viewer for pulling out and observing a film stored in a cartridge from the cartridge.

[0002]

2. Description of the Related Art Recently, a return mode has been proposed in which a film is stored in a cartridge without being divided, and the cartridge is returned to a user together with a print photograph from a DPE dealer. In the case of a film returned in such a form, it is impossible to observe a frame image through a negative sheath as in the conventional case when requesting an additional print of a print photo. We propose a film viewer that can be observed.

In this film viewer, a cartridge is loaded in the viewer main body, and a film pulling knob provided in the viewer main body is rotated by a finger to rotate the spool of the cartridge via a gear train connected to the knob. , The film is pulled out from the cartridge. By illuminating the drawn frame image of the film with light from a lamp provided in the lamp house, the frame image can be observed through an observation window opened in the viewer body. The films that are sequentially drawn out are wound around a winding shaft that interlocks with the knob. After the observation is completed, the knob is reversed to rotate the spool in the rewinding direction to store the film in the cartridge.

By the way, depending on the positional relationship between the light source and the observation window, it is necessary to incline the reflection mirror so as to have a predetermined reflection angle in order to change the course of the light beam from the light source and to attach it to the casing of the film viewer. Conventionally, the structure of the reflecting mirror mounting portion for mounting the reflecting mirror has been one in which the reflecting mirror is mounted on a frame-shaped mounting base that is tilted to correspond to a predetermined reflection angle and is screwed. .

After that, as a mounting structure which does not require screwing, as shown in FIG. 16, the locking claws 2, 2 provided in a long shape along both side edges of the frame-shaped mounting base 1 are provided with one hand. It has been developed that the reflection mirror 3 is moved in parallel to the mounting base 1 in the direction (arrow 4) orthogonal to the mounting base 1 and is fitted into the groove 5 formed in the mounting base 1 while being expanded outward.

[0006]

However, in the manufacturing process of the film viewer, the attachment of the reflection mirror is manually performed by the worker on the manufacturing line, so that the conventional screw-fastened structure is extremely inefficient. There is a drawback that In addition, in the conventional mounting structure that does not require screwing, since the reflection mirror 3 needs to be moved in parallel with respect to the mounting base 1, a mounting space for moving the reflection mirror 3 in the casing is required. This has the drawback that there is a limit to the compactness of the device.
Further, as can be seen from FIG. 16, there is a drawback that the mirror surface side 3A side edge portion of the reflection mirror 3 is easily hit by the locking claw 2 at the time of mounting, and light rays are diffusely reflected by the damaged mirror surface portion.

The present invention has been made in view of the above circumstances, and it is possible to improve the work efficiency of attaching a reflecting mirror,
Moreover, it is an object of the present invention to provide a structure for mounting a reflecting mirror which can also make the device compact.

[0008]

In order to achieve the above object, the present invention provides a reflecting mirror mounting portion structure in which a case of an optical system device and a reflecting mirror mounting portion are integrally formed of plastic. The reflection mirror mounting portion has an inclination angle corresponding to the reflection angle, and is integrally formed with the case so that at least a tip portion thereof is elastically deformed, and a support plate that supports a back surface side of the reflection mirror, and the case. A pair of guides that are formed integrally with the support plate and that form an insertion path for inserting the reflection mirror from the tip end portion of the support plate along the support plate together with the support plate and support both mirror-side edges of the reflection mirror. A rail and a leaf spring formed on the support plate for urging the reflection mirror in a direction separating from the support plate surface, and elastically deforming a tip portion of the support plate. The mirror is inserted into the insertion path with the insertion path widened, and the reflection mirror is pressed and fixed to the guide rail by the leaf spring when the elastic deformation is restored. To do.

According to the present invention, the reflecting mirror is moved along the support plate while the tip of the support plate is elastically deformed to widen the insertion path formed by the support plate and the guide rail. The reflection mirror can be easily and quickly attached to the casing by simply inserting the reflection mirror into the casing. Then, the reflection mirror inserted in the insertion path is pressed and fixed by the leaf spring formed on the support plate and the guide rail. In addition, since the reflecting mirror is moved along the support plate and attached, there is almost no need for an installation space in the casing.

[0010]

BEST MODE FOR CARRYING OUT THE INVENTION Preferred embodiments of a mounting structure for a reflecting mirror according to the present invention will be described in detail below with reference to the accompanying drawings. The mounting structure of the reflection mirror according to the present invention,
An example applied to the film viewer will be described below. FIG. 1 is a perspective view showing the outer appearance of a film viewer having a reflecting mirror mounting structure according to the present invention, and FIG. 2 is an enlarged top view of the film viewer shown in FIG.

As shown in FIG. 1, a film viewer 10 is provided.
Is the outer casing 12 and the bottom plate 14 whose bottom side is open.
Is formed into a box shape, and optical system components and control system components, which will be described later, are disposed inside and on the upper surface of the outer casing 12.
The outer casing 12 and the bottom plate are all made of plastic. The outer casing 12 has an outer lid 121 that closes the cartridge storage portion 120 of the film viewer.
The outer lid 121 is opened and closed in conjunction with the inner lid 122 (see FIG. 5) of the cartridge housing portion 120, and the cartridge 44 (see FIG. 3) is inserted into the cartridge housing portion 120. By the insertion of the cartridge 44, the pop-up member (not shown) of the pop-up mechanism provided in the cartridge housing portion 120 is pushed down, and after the cartridge 44 is inserted, the outer lid 1
When the inner lid 122 is closed by interlocking with 21, the inner lid 122 is locked.

As shown in FIG. 2, the observation window 124 and the eject button 1 are provided on the upper surface of the outer casing.
30, information reading button 131, display switching button 132,
A key panel 135 including a feed button 133 and a return button 134 is provided, and a rectangular liquid crystal display panel (hereinafter referred to as “LCD”) 140 is embedded and fixed.

The cartridge 44 accommodated in the cartridge accommodating portion 120 of the film viewer is of the type shown in FIG. 3, and all the members constituting the cartridge 44, such as the body portion 60, the spool 62, and the light shielding member 64. Is made of plastic. The cartridge 44 is of a type in which the film 48 (see FIG. 4) is wound around the spool 62 up to the tip, and when used, the film 48 is sent out of the cartridge 44 by the rotation of the spool 62 from the entrance 68. .

As shown in FIG. 4, in the film 48, a perforation 70A indicating the start end and a perforation 70B indicating the end of the frame image 18 are formed for each frame along the longitudinal direction of the film 48, and the perforations 70A and 70B are formed. A magnetic recording layer 72 is formed between and. Information such as the shooting date / time of the frame, standard, high-definition, shooting size indicating panorama, shutter speed, F value, strobe ON / OFF, roll title, and frame title is magnetically recorded on the magnetic recording layer 72 at the time of shooting. There is.

Further, the optical data 19 is composed of three frame portions, and these frame portions are exposed according to the photographing size set at the time of photographing by the camera. For example, a frame image in which only the left edge frame is exposed was shot in high-definition size, and a frame image in which the left edge and center frame were exposed was shot in panoramic size. The frame image in which the frame portion is exposed can be visually recognized by the user through the observation window 124 as a standard size image. As shown in FIG. 3, the cartridge 44 is provided with a claw 76 in the recess 74 of the spool 62. The claw 76 indicates whether the film accommodated in the cartridge 44 has been developed or undeveloped. When the film has been developed, it is folded and removed in a laboratory or the like and returned to the user. This claw 76
The presence or absence is detected by a protrusion (not shown) formed inside the inner lid 122 of the viewer body 12. That is, this protrusion is inserted into the recess 74 of the spool 62 when the inner lid 122 is closed. Therefore, when the undeveloped cartridge 44 is mistakenly loaded, the projection hits the claw 76 and the inner lid 122 is not closed. As a result, when an undeveloped cartridge is erroneously loaded, it is possible to prevent the cartridge from being exposed.

Next, referring to FIG. 5, the frame image 18
An observation optical system for observing (see FIG. 4) through the observation window 124 will be described. As shown in FIG. 5, the desired frame image 18 to be observed is stopped at a predetermined observation position P on the film transport path. At this observation position P,
A light source for illuminating a frame image, such as a miniature bulb 125A
The lamp house 125 provided with is attached and fixed by the attaching structure described later. Further, a reflection mirror 126 is arranged at a position facing the lamp house 125 with the film conveyance path interposed therebetween. Furthermore, in the observation window 124,
The lens holder 127 allows lenses 128A and 128
B is provided. Reference numeral 129 is a lamp cover that is opened and closed when the miniature bulb 125A is replaced.

Then, the transmitted light of the frame image illuminated by the miniature electric bulb 125A in the lamp house 125 is transmitted by the observation optical system having the above-described structure to the reflection mirror 126 and the lens 1.
It is guided to the observation window 124 via 28A and 128B, so that the frame image can be observed through the observation window 124. Next, the structure of the lamp house 125 will be described with reference to FIGS. 6 and 7.

The lamp house 125 has an irradiation port 205 for irradiating the frame image 18 with the light of the miniature bulb 125A on the front side which is the observation position P side, and an opening 202 for taking the miniature bulb 125A in and out on the rear side. Main body 204 of the lamp house and a lid 2 for opening and closing the opening 202
The lamp house main body 204 and the lid 206.
Are integrally formed via a thin groove-shaped hinge portion 208. As a material for forming the lamp house 125, a plastic such as polypropylene which is easy to be integrally formed by a mold and which is less likely to cause fatigue damage of the hinge portion 208 due to the opening / closing operation of the lid 206 as much as possible is preferable. . In addition, the color of the lamp house 125 is preferably silver or a white color that easily reflects light,
It is more preferable to use a plastic raw material to which a light diffusing agent is added.

The lamp house main body 204 has an irradiation port 2
05 is formed in a trumpet cylinder shape that is larger than the opening 202, and the four sides 204 that form the lamp house main body 204.
Lower surface 204 of A, 204B, 204C, 204D
D is bent inward. A cutout 210 continuous from the opening 202 is formed on the bent lower surface 204D, and the lower step portion 20 of the lower surface 204D is formed.
4a has a cylindrical socket portion 125a of a miniature bulb 125A.
A semi-circular first notch 210A is formed in accordance with the shape of the above, and the upper step 204b of the lower surface 204D guides the socket 125a of the miniature bulb 125A to the first notch 210A. A second cutout portion 210B that locks the groove 125b formed in the socket portion 125a of the miniature electric bulb 125A is formed. Also, the lower surface 20
A pair of locking claws that engage with the lower edge 206A of the lid 206 when the openings 202 are closed by the lids 206 on both sides of the second cutout portion 210B at the opening edge of the upper step portion 204b of 4D. 212 is formed. This prevents the lid 206 from opening when closed. Further, in the lower step portion 204a of the lower surface 204D, the first cutout portion 210A is formed.
A pair of pieces 207, 207 are formed on the edge of the.

On the other hand, the lid 206 is formed such that the tip end on the side opposite to the hinge portion 208 is longer than the length that closes the opening 202, and the plurality of comb-shaped projections are formed on the long dimension. Piece 206B is formed. The projecting piece 206B located in the middle of the projecting piece 206B serves to fix the miniature light bulb 125A to the lamp house main body 204 by pressing the socket portion 125a of the miniature light bulb 125A toward the deep side of the second cutout portion 210A. I do.

When the miniature electric bulb 125A is attached to the lamp house 125 thus constructed, the procedure is as follows. First, the lid 206 is swung with the hinge portion 208 as a swing shaft to open the opening 202, and then the miniature electric bulb 125A is inserted into the lamp house main body 204 from the opening 202. That is, the socket portion 125a of the miniature bulb 125A is brought into contact with the first cutout portion 210A, and the socket portion 125A
The groove 125b formed in a is formed into the second cutout portion 210B.
To be engaged. As a result, the miniature bulb 125A is temporarily fixed to the lamp house main body 204. In this state, the lid 206 is swung to close the opening 202, and the lower edge 20 of the lid 206 is closed.
Locking claw 212 in which 6A is formed on the lamp house main body 204
To lock. As a result, the leaf-spring-shaped protruding piece 206B formed at the tip of the lid 206 presses the socket portion 125a of the miniature bulb 125A toward the deep side of the first cutout portion 210A to firmly lamp the miniature bulb 125A. House body 2
It is fixed to 04 and the miniature bulb 125A is completely attached.
In the fixing, the socket portion 125 of the miniature bulb 125A
Since a contacts both the first cutout 210A and the piece 207, the wobble of the miniature electric bulb 125A is prevented. Further, since the leaf spring-shaped protruding piece 206B is formed on the lid 206, it is more easily elastically deformed than a single plate, so that the miniature bulb 125A is not damaged. In addition, miniature bulb 1
When removing 25A from the lamp house 125, the procedure may be reversed.

Therefore, even when the miniature light bulb 125A is replaced due to a break in the filament of the miniature light bulb 125A or the like, the miniature light bulb 125A can be replaced easily and quickly. Moreover, in the lamp house 125 of the present invention, since the lamp house main body 204 and the lid 206 are integrally formed via the hinge portion 208, a special support portion for supporting the miniature light bulb 125A and the lid 206 for the lamp house main body 204 are provided. No need for screws to fix

In order to attach the lamp house 125 to the observation position P, as shown in FIG. 8, the mounting claws 214 formed at the upper and lower positions on the front side of the lamp house main body 204 are opened to the observation position P, respectively. The opening 216 is formed in the front plate 219 of the main body of the apparatus and is fitted in the locking grooves 218 formed in the upper and lower positions. Next, the structure of the mounting portion of the reflection mirror 126 will be described with reference to FIGS.

FIG. 9 is a view showing a mounting structure of the reflection mirror 126 with a part of the outer casing 12 cut away.
10 to 12 are cross-sectional views taken along the line AA of FIG.
It is a figure which shows the attachment procedure of the reflection mirror 126. As shown in FIG. 9, below the observation window 124 formed on the upper surface of the outer casing 12, a support plate 220 that integrally supports the rear surface side 126A (see FIG. 10) of the reflection mirror 126 in the outer casing 12 is provided. To be The reflection mirror 126 supported by the support plate 220 reflects the path of light from the miniature bulb 125A at a right angle and guides it to the observation window 124.
It is arranged to be inclined by 135 ° with respect to the path of light from the miniature electric bulb 125A so as to correspond to the reflection angle.

The support plate 220 is formed in a substantially hexagonal shape, and is a base end edge 22 which is an upper side of the support plate 220 which is inclined and arranged.
2 and both side edges 224 are supported by a cylindrical frame 226 that hangs integrally with the outer casing 12 from the observation window 124, whereby the tip portion 22 below the support plate 220.
8 is elastically deformable. The frame 226
The miniature bulb 125A side is formed in a frame shape so that the light from the miniature bulb 125A hits the reflection mirror 126. In addition, the side edges 22 of the support plate 220 in the frame body 226
A guide rail 232 that supports the mirror surface side 126B of the reflection mirror 126 is formed on both side plates 230 that support 4 in parallel to the support plate, and a base edge 222 of the support plate 220.
A stopper piece 236 is formed on the upper plate 234 supporting the. As a result, the support plate 220 and the guide rail 232 form an insertion path 233 (see FIG. 10) for inserting the reflection mirror 126 along the support plate 220, and the reflection mirror 126 inserted into the insertion path 233 serves as a stopper. Piece 23
Since it abuts on 6, it is always inserted to a fixed position. Further, a plate spring 238 that forms a part of the support plate 220 and that biases the reflection mirror 126 in a direction away from the support plate 220 is formed in the center of the support plate 220. A locking claw 240 that prevents the reflection mirror 126 inserted in the insertion path 233 from coming off the insertion path 233 is formed at the tip portion.

Then, the reflection mirror 126 is attached to the attachment structure of the reflection mirror attachment portion thus configured as follows. First, as shown in FIG.
The distal end portion of the support plate 220 is elastically deformed by 42 to insert the insertion path 2
Expand the entrance of 33. Next, as shown in FIG. 11, in this state, the back surface 126A of the reflection mirror 126 is attached to the support plate 220.
Of the support plate 220 and the frame-shaped 226 four frame-shaped crosspieces of the miniature bulb 125A.
The reflection mirror 126 is inserted into the insertion path 233 from between the lower crosspiece 231 and the lower crosspiece 231. In this case, the lower surface 2 of the crosspiece 231
31A is formed as a flat smooth surface that does not damage the mirror surface 126B even if the mirror surface 126B of the reflection mirror 126 contacts. When the tip of the reflection mirror 126 is inserted into the insertion path 233, the finger 242 is separated from the support plate 220 and the support plate 2 is removed.
The elastic deformation of the tip of 20 may be restored. Next, as shown in FIG. 12, the reflection mirror 126 is moved along the support plate 220 and inserted into the insertion path 233 until it comes into contact with the stopper piece 236. The reflection mirror 126 has an insertion path 233.
When it is completely inserted into the support plate 22,
It is pressed and fixed by the leaf spring 238 and the guide rail 232 formed in 0, and the locking claw 240 formed at the tip of the support plate 220 locks on the edge of the reflection mirror 126.
The reflection mirror 126 is prevented from coming off the insertion path 231.

In this way, the reflection mirror 126 is inserted into the insertion path 2.
Since it is only necessary to insert the reflecting mirror 126 into the outer casing 33, the reflecting mirror 126 can be easily and quickly attached to the outer casing 12. Further, the support plate 220 in which the reflection mirror 126 is inclined from the bottom side of the exterior casing 12 in accordance with the reflection angle.
Since it is moved along the inclination direction of
2 requires almost no installation space.

Next, the control system of the film viewer will be described with reference to FIG. The cartridge storage unit 1
20 has a rotary shaft 82 that engages with the spool 62 of the cartridge, and a take-up shaft 86 is provided in the take-up chamber facing the cartridge housing 120. The winding shaft 86
The upper and lower ends of which are rotatably supported by the viewer body, and a gear 88 is fixed to the upper part of the winding shaft 86.
This gear 88 is connected to a motor 92 via a clutch 90. The clutch 90 causes the gear 88 to slide with respect to the motor 92 when the torque applied to the gear 88 (that is, the winding torque of the film 48) exceeds a predetermined torque, and winds the film 48 at a constant speed. The shaft 86 is adapted to be wound up. In addition, the motor 92
The driving force is also transmitted to the gear of the rotary shaft 82 that engages with the spool of the cartridge via a gear mechanism (not shown).

The gear mechanism rotates the spool 62 to send out the film 48, transmits power to the rotary shaft 82 until the leading end of the film 48 is wound onto the winding shaft 86, and is wound during the subsequent winding. The power is transmitted only to the take-up shaft 86 side. Also, the gear mechanism is
When rewinding the film 48 into the cartridge 44,
Power is transmitted only to the rotating shaft 82 side.

The motor 92 is driven by the drive signal from the motor driver 96, and the motor driver 9
6, the CPU 98 built in the viewer main body 12 controls the rotation direction and the rotation amount output to the motor 92. A command signal corresponding to the operation of each button 130 to 134 from the key panel 135 shown in FIGS. 1 and 2 is output to the CPU 98. When the command signal is output, the CPU 98 controls the motor driver 96 so that the motor 92 performs the operation corresponding to the signal.

By the way, the film 48 pulled out from the cartridge 44 is conveyed along the guide plate 100 shown in FIG. 13, and after passing through the observation window 124,
It is wound around the winding shaft 86 along the guide plate 102. The perforation sensor 104 is provided on the guide plate 100 side.
Is provided. The perforation sensor 104 detects the perforations 70A (see FIG. 4) on the leading end side and the perforations 70B (see FIG. 4) on the trailing end side of the conveyed film 48 for each frame, and when they are detected, the H level is detected. The signal is output to the CPU 98. In the present embodiment, when the perforation sensor 104 detects the perforation 70A on the starting end side, the frame image in front of the frame image is positioned in the observation window 124. Also, the perforation sensor 1
A capstan roller 105 is arranged near 04. The rotational force from the motor 92 is transmitted to the capstan roller 105, and the film 48 pulled out from the cartridge 44 is conveyed at a constant speed by the rotational force of the capstan roller 105.

The guide plate 102 has an optical sensor 106.
And the magnetic head 108 are arranged in parallel. The optical sensor 1
Reference numeral 06 is for reading the optical data 19 when the shooting size of the optical data 19 and the optical data 19 such as a bar code indicating a frame number are recorded, and these optical data 19 are read. Is reproduced and stored in the RAM 112 of the CPU 98. The magnetic head 108 includes a magnetic recording layer 72 of the film 48.
The magnetic information recorded in the CPU is read, and the read information is reproduced by the magnetic information reproducing device 114 and is read by the CPU.
It is stored in the RAM 112 of 98. Incidentally, reference numeral 115
Is a light source for irradiating the frame image located in the observation window 16 from the back side. Further, reference numeral 116 is an alarm,
This alarm 116 is for the cartridge 4 of the film 48.
The CPU 98 is controlled so that an electronic sound is generated when the rewinding of the film 4 is completed, the film 48 is abnormally conveyed, or the like.

The information stored in the RAM 112 is stored in the CPU
LC shown in FIG. 1 and FIG.
It is displayed on D140. On the first screen shown in FIG. 14 (A), for example, Nichiji (shooting date and time), size (shooting size), shutter (shutter speed), weight (F value),
A strobe (strobe ON / OFF) is displayed, and a roll title and a frame title are displayed on the second screen shown in (B) switched by the display switching button 132 (see FIG. 2).

Next, the operation of the film viewer having the above structure will be described with reference to the flowchart shown in FIG. First, connect the AC adapter to the film viewer to enable power supply to the film viewer (S
20). Subsequently, the cartridge is placed in the cartridge storage unit 1
20 and locks with the inner lid 122 (S2
1). At this time, whether or not the inserted cartridge has been developed is determined by the presence or absence of the claw 76 provided on the cartridge (S22). If the claw 76 is not broken,
LCD with an error message indicating "Undeveloped"
It is displayed on 140, and then automatically ejected (S2
3). That is, the lock of the inner lid 122 is released, and the cartridge is ejected by the operation of the pop-up mechanism.

On the other hand, when the cartridge is already developed (when the claw 76 is broken), the film is pulled out from the cartridge and the loading operation of winding the film leader portion around the winding shaft 86 is performed (S24). At the end of this loading operation, the frame image of the top frame of the film is stopped at the observation position where the observation window 124 can observe it.
Further, the light source for illuminating the frame image is turned on.

Here, when the information reading switch 131 is pressed (S25), the film is rewound once when the leading frame is stopped at the observing position and once when the leading frame is not at the observing position. (S26), the film is continuously fast-forwarded to the last frame and stopped (S26).
28). Also, during this continuous fast-forwarding, each magnetic information recorded on the magnetic recording layer (hereinafter referred to as a leader track) of the film reader section and the magnetic recording layer (hereinafter referred to as a frame track) corresponding to each frame is continuously recorded. The read magnetic information is stored in the RAM (S27).

Therefore, when the reading of the magnetic information is completed, the final frame can be observed through the observation window 124, and the magnetic information of the final frame is displayed on the LCD 140. Now, when the feed switch 133 or the return switch 134 is pressed in the state where an arbitrary frame image is stopped at the observation position, the film is fed one frame in the feed direction or the return direction. It is possible to confirm the frame image one frame after or one frame before the frame (S29). Further, when the reading of the magnetic information is completed, the magnetic information of the frame image currently stopped at the observation position is displayed on the LCD 140.

After the confirmation of the frame image and the like is completed, when the take-out switch 130 is pressed (S30), the light source is turned off and the film is rewound into the cartridge (S31). When the film winding is completed, the lid 122 is unlocked, and the cartridge is automatically ejected from the cartridge storage section 120 by the pop-up mechanism (S3).
2).

The feed switch 133 or the return switch 13
If 4 is pressed continuously, the film is continuously fed in the feeding direction or the returning direction. Further, this film viewer has a power saving function, the AC adapter is connected as shown in step S20, and the cartridge is inserted and the lid 1 is supplied in a state in which power can be supplied to the film viewer.
When 22 is closed, or when the switch or the like is pressed, the power is turned on. After that, when no operation time of switches etc. elapses from the normal power-on state, for example, 3 minutes, to save power and prevent deterioration of the film due to light heat of the light source, turn off the light source and turn off the power. It becomes a mode. When any switch is operated in the power save mode, the power is turned on again and the light source is turned on.

The mounting structure of the reflection mirror according to the present invention is not limited to the film viewer, and can be applied to all optical system devices such as overhead projectors that require the reflection mirror.

[0041]

As described above, according to the reflecting mirror mounting portion structure of the present invention, the distal end portion of the support plate is elastically deformed to expand the insertion path formed by the support plate and the guide rail. Then, the reflecting mirror can be easily and quickly attached to the apparatus main body only by moving the reflecting mirror along the supporting plate and inserting it into the insertion path.

Further, since the reflecting mirror is moved along the inclination direction of the supporting plate which is inclined corresponding to the reflection angle, there is almost no need for a mounting space in the apparatus, so that the apparatus is more compact than the conventional one. Can be achieved.

[Brief description of drawings]

FIG. 1 is a perspective view showing an outer appearance of a film viewer to which a reflecting mirror mounting portion structure according to the present invention is applied.

FIG. 2 is an enlarged top view of a film viewer.

FIG. 3 is a perspective view of a cartridge.

FIG. 4 is an explanatory view of a cartridge and a film.

5 is a block diagram showing an optical system of the film viewer shown in FIG.

FIG. 6 is a perspective view illustrating a lamp house structure, showing a state in which a lid is closed.

FIG. 7 is a perspective view illustrating a lamp house structure, showing a state in which a lid is opened.

FIG. 8 is an explanatory view illustrating a structure for attaching the lamp house to the main body of the apparatus.

FIG. 9 is an explanatory diagram in which a part of an outer casing is cut out in order to explain a mounting structure of a reflecting mirror according to the present invention.

FIG. 10 is a cross-sectional view illustrating a first stage of the operation of attaching the reflection mirror to the reflection mirror attachment structure.

FIG. 11 is a cross-sectional view illustrating a second stage of the operation of attaching the reflection mirror to the reflection mirror attachment portion structure.

FIG. 12 is a cross-sectional view illustrating a third stage of the operation of attaching the reflection mirror to the reflection mirror attachment structure.

FIG. 13 is a block diagram illustrating a control system of a film viewer.

14 (A) and 14 (B) are plan views of the LCD for explaining the contents displayed on the LCD of the film viewer.

FIG. 15 is a flowchart showing the operation of the film viewer.

FIG. 16 is an explanatory diagram illustrating a conventional reflecting mirror mounting structure.

[Explanation of symbols]

 10 ... Film viewer 12 ... Exterior casing 14 ... Bottom plate 44 ... Cartridge 48 ... Film 124 ... Observation window 120 ... Cartridge storage 121 ... Outer lid 122 ... Inner lid 125 ... Lamp house 125A ... Miniature bulb (light source) 125a ... Miniature bulb Flange portion 126 ... Reflection mirror 202 ... Lamp house main body opening 204 ... Lamp house main body 206 ... Lid 206B ... Projection piece 208 formed on the lid 208 ... Hinge part 210 ... Notch part 212 ... Locking claw 220 ... Support plate 226 … Frame 232… Guide rail

Claims (2)

[Claims] 1. A reflection mirror mounting portion structure in which a case of an optical system device and a reflection mirror mounting portion are integrally formed of plastic, wherein the reflection mirror mounting portion has an inclination angle corresponding to the reflection angle. And a support plate integrally formed in the case so that at least its tip is elastically deformed, and supporting the back side of the reflection mirror; and the reflection mirror formed integrally with the case, the tip of the support plate being the reflection mirror. From a pair of guide rails that form an insertion path to be inserted along the support plate together with the support plate, and that support both mirror-side edges of the reflection mirror, and the reflection mirror formed on the support plate. A leaf spring that urges the support plate surface in a direction away from the support plate surface, and elastically deforms the distal end portion of the support plate to widen the insertion path so that the mirror serves as the insertion path. While inlet attachment portion structure of a reflective mirror, wherein the reflecting mirror when undoing the elastic deformation is to be pressed and fixed to the guide rail by the leaf spring. 2. The attachment of a reflection mirror according to claim 1, wherein a locking claw for preventing the reflection mirror inserted in the insertion path from coming off is formed at a tip portion of the support plate. Part structure.