JPH0262848B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a compact imaging device used in an exposure optical system of an electrophotographic copying machine or the like. In particular, the present invention relates to an improvement of the imaging device described in Japanese Patent Application No. 55-21386 filed by the present applicant.

The imaging device in the above prior invention includes a multi-lens array in which a large number of lenses are arranged in a row and formed into a plate shape, and a multi-prism array in which a large number of prisms are arranged in a row and formed in a plate shape. , and a multi-prism lens array arranged behind the lens annoy so that each prism corresponds to each lens. Another known example of such a compact imaging device is the strip lens array described in Japanese Patent Publication No. 49-8893. This is composed of three lens sheets, and each lens group forms an erect real image using three lenses, but in order to form an inverted real image of approximately the same size in the middle, the height of the imaging device itself is required. As the distance between lenses increases, it is necessary to accurately set the distance between each lens and the optical axis. In contrast, in the prior invention described above, since no intermediate image is created, problems associated with this do not occur. On the other hand, when a prism array is formed by integral molding of resin, the optical path may fluctuate due to residual distortion, the flatness of the reflective surface may deteriorate due to sink marks, and total internal reflection may occur at the aperture surface. There are disadvantages such as easy occurrence of flare light.

In the present invention disclosed below, an imaging device including a roof mirror lens array using a multi-roof mirror array instead of the multi-prism array in the prior invention is provided. By replacing the prism with a roof mirror, several disadvantages introduced by the use of prisms are overcome. Further, by optimizing each optical dimension, it is possible to provide a high-performance imaging device that is bright, has high resolution, and has no unevenness in light amount. In another embodiment of the present invention, there is provided an imaging device that combines the above roof mirror lens array and a reflecting member, and an imaging device that incorporates these into a line scanning device.

SUMMARY OF THE INVENTION It is therefore an object of the present invention to provide an imaging device that is an improvement over the prior invention.

A further object of the invention is to provide the above-mentioned imaging device with high performance.

A further object of the invention is to provide the above imaging device incorporated into a line scanning device.

These and other objects will become more apparent from the following description with reference to the drawings.

The imaging principle in the roof mirror lens array according to the present invention is the same as that in the prism lens according to the prior invention, as shown in the plan view of FIG. 1 and the side view of FIG. 2. The roof mirror lens array 10 is a multi-lens array 11 formed into a plate shape by arranging a large number of lenses in a row.
and a multi-roof mirror array 12 which is formed into a plate by arranging a large number of roof mirrors arranged in a row at a predetermined interval behind the multi-roof mirror array 12, each lens corresponding to each roof mirror. . The object 13 is imaged horizontally as an erect real image 14 at the same position as shown in FIG. 1, and vertically as an inverted real image 14 at the same position as shown in FIG. Ru. For example, the letter P is imaged as b. Therefore, if they are arrayed in the horizontal direction shown in FIG. 1, the images will be connected.

Each multi-lens array 11 and multi-roof mirror array 12 can be integrally molded from resin or a similar material. By doing so, alignment accuracy is significantly improved and costs are reduced. Since each of the reflective surfaces a and b of the multi-roof mirror array 12 is formed by aluminum vapor deposition, the material such as resin does not necessarily have to be transparent. Furthermore, when molding the multi-roof mirror array 12 using resin or the like, "sink marks" are likely to occur due to differences in wall thickness, so as shown in FIG. can do. Instead of being molded, the array 12 may be formed by adhesively connecting prism blocks to form the array 12'', as shown in FIG. 4, or by cutting grooves.

Various imaging devices can be configured using such a roof mirror lens array 10. FIG. 5 shows an example in which a right-angle mirror 15 is arranged in front of the roof mirror lens array 10, the whole is integrated with a housing, and the object-side optical path and the image-side optical path are used separately. Instead of the right angle mirror 15,
A half mirror 16 as shown in FIG. 6, a mirror 17 in the object side optical path as shown in FIG. 7, and an open or transparent member in the image side optical path, or a pair of right angle prisms 18 as shown in FIG. may be placed respectively.

The roof mirror lens array according to the present invention can dramatically improve its imaging performance by appropriately setting each optical dimension. FIG. 9 is an equivalent diagram in which the optical system using a roof mirror is replaced with a symmetrical optical system that does not use a roof mirror, in order to facilitate understanding. In the roof mirror lens, the light from the object that has passed through the lens is opposed by the roof mirror and passes through the lens again to form an image, so two identical lenses 19,
This is equivalent to arranging one roof mirror 20 and one roof mirror 21 between the object plane 22 and the image plane 23. In this lens system, each symbol is defined as follows.

r: Radius of curvature of the lens θ: Half angle of view D: Diameter of the lens H: First principal point H': Second principal point l1: Distance between principal points l2: Distance between extreme principal points t1: Lens thickness (lens t2: Distance between lens surfaces and roof ridgelines t3: Distance between object plane (imaging plane) lenses L: Distance between object plane and imaging plane Each dimension is determined as follows.

r1=22.65 r2=-84.191 r3=-r2=84.191 r4=-r1=-22.65 θ=10.1゜ D=8.6 l1=13.8 l2=22.5 t1=4.0 t2=11.6 t3=36.2 L=103.6 Refractive index nd=1.491 When a roof mirror lens array is constructed with these specifications, it becomes as shown in FIG. Reference numeral 24 indicates a light shielding plate, and this light shielding plate is arranged between the interlens space of the multi-lens array and the top of the roof of the multi-roof mirror array. In this figure, it is defined as follows.

Example pitch P = 9.2 Space between lenses k = P - D = 0.6 Effective height of roof mirror surface t4 = 4.3 When the roof mirror lens array is configured in this way, focal length f = 36.0 mm, F value = 2.1 Angle of view 2θ =
20.2°, making it possible to obtain a bright, high-resolution lens with less light loss and an MTF of 60% or more at 5lP/min. In addition, by setting the array pitch P to 9.2 mm, the unevenness of the light amount at the required scanning line position can be reduced by 5.
It can be kept within %. That is, the first
As shown in Figure 1, when a roof mirror lens with a lens diameter D = 8.6 is arranged in a single row array with an arrangement pitch P = 9.2, a single roof mirror lens is placed at the slit position d = 2.8 mm away from the optical axis A, that is, on the scanning line. The light amount distribution of the lens and its combined light amount distribution are as shown in FIG. A curve 25 represents the light amount distribution on the scanning line, a curve 26 represents the combined light amount distribution, and a curve 27 represents the light amount distribution of a single roof mirror lens on the optical axis A. Note that in FIG. 11, the symbol G represents the diameter of the effective screen size.

FIG. 13 shows an imaging device 30 in which a right-angle mirror 28 is disposed in front of a roof mirror lens array having each dimension, and the entire unit is formed into a unit by a housing 29 together with a light shielding plate 24.
An example is shown. This is an example of a line scanning imaging device, where the object height and image height are equal to d=2.8 mm, and this range is used as the scanning line position. In this figure, the codes and their values other than those mentioned above are as follows.

t5=22.0 t6=14.0, t7=14.2 t8=5.0 In FIG. 14, such an imaging device 30 is used together with a line light emitter 31 such as a light emitting diode array, and a life-size line image of the light emitting section 31a is obtained. Recording medium 3
FIG. 15 shows an example of a recording apparatus that uses a photosensitive drum 33 as a recording medium. Reference numeral 34 is an electrostatic charger, 35 is a cleaning device, 3
Reference numeral 6 represents a developing device, 37 a transfer charger, and 38 a static elimination charge lamp. This device is of a two-rotation, one-copy type, with one rotation of the photoreceptor drum 33.
Charging, exposure, development, transfer, and charge removal are performed in the first rotation, and cleaning of the photoreceptor is performed in the second rotation. FIG. 16 shows an example of a reading device in which the imaging device 30 according to the present invention is combined with a solid-state scanning element 39, for example, an equal-magnification line sensor using an amorphous semiconductor, a so-called flat bed sensor, and a light source 4.
The image of the document 42 on the document support glass 41 illuminated by 0 is projected onto the flatbed sensor 39 through the imaging device 30. This method employs a method in which the original is moved and the optical system is stationary; however, if the original is a book rather than a sheet, as shown in FIG. 17, the method is such that the original is held still and the optical system is moved.

As described above, the imaging device according to the present invention has the following effects.

1) By using a roof mirror array, even if there is internal distortion within the plastic member, the imaging performance will not be affected.

2) Since the molded member for the roof mirror array does not have to be transparent, it is possible to use materials with less "sink marks", which widens the scope for selection.

3) By making the wall thickness of the roof mirror array substantially equal, "sink marks" etc. can be significantly reduced, and the flatness of the reflective surface is also improved.

4) Since it becomes an air medium between the lens and the roof mirror surface, in addition to the effect of 1) above, flare light is reduced without the influence of backside reflection of the prism aperture surface as in the conventional case.

5) By setting the optical dimension of the roof mirror lens array as shown in the example, it is possible to achieve much improved performance in terms of brightness and resolution compared to the conventional strip lens, and a special correction plate can be used to prevent unevenness in the amount of light. Without using it, it can be kept below 5%.

6) The roof mirror lens array is shown in Figures 5 to 8.
By using a line-scanning imaging device as shown in the figure, we can create a compact recording device that can provide a sufficient amount of exposure even when combined with a light emitting diode array, which has a relatively limited amount of light. can be provided. Further, the present invention can also be applied to a reading device as shown in FIGS. 16 and 17 using a normal light source.

7) By appropriately determining the length of the light shielding plate 24 with respect to the diameter D of the lens, it is possible to reduce disturbance light while suppressing light loss.

8) Since the lens array, roof mirror array, and light shielding member are integrally molded in the housing, adjustment is easy and costs can be reduced.

Although the present invention has been described above with reference to the specific embodiments shown in the drawings, the present invention includes various modified embodiments within the spirit and scope of the invention as set forth in the claims.

[Brief explanation of the drawing]

FIG. 1 is a schematic plan view showing the imaging function of the roof mirror lens array according to the present invention, FIG. 2 is a schematic side view of FIG. 1, and FIGS. 3 and 4 are the roof mirror lens array according to the present invention. 5 to 8 are schematic side views showing different examples of the imaging device according to the present invention, and FIG. 9 is a schematic plan view showing different examples of the imaging device according to the present invention. Explanatory diagram showing the lens system, No. 10
11 is an explanatory diagram showing the dimensions of the roof mirror lens array according to the present invention, FIG. 11 is an explanatory diagram showing the effective screen area of the roof mirror lens array according to the present invention, and FIG. 12 is a diagram showing the light amount distribution in FIG. 11. An explanatory diagram, FIG. 13, is an explanatory diagram showing dimensions of an example of an imaging device according to the present invention, and FIGS.
The drawings are schematic side views showing different examples of recording devices incorporating the imaging device according to the present invention. 10... Roof mirror lens array, 11... Lens array, 12... Roof mirror array, 13... Object,
14...image, 30...imaging device.

Claims (1)

[Scope of Claims] 1. A multi-lens array in which a large number of adjacent lenses are arranged in a row to form a plate shape, and a multi-roof mirror array in which a large number of adjacent roof mirrors are arranged in a row to form a plate shape. And,
a multi-roof mirror array arranged at a predetermined interval behind the multi-lens array so that each of the roof mirrors corresponds to each lens; and a space between each lens of the multi-lens array and a space between the multi-roof mirror array An imaging device comprising: a light-shielding member disposed between the tops of each roof to reduce disturbance light; and the entire imaging device is integrated with a housing. 2. The imaging device according to claim 1, wherein the multi-lens array and the multi-roof mirror array are integrally molded from plastic or a similar material. 3. The imaging device according to claim 2, wherein the rear back surface shape of the multi-roof mirror array is the same as the front surface shape, and the wall thicknesses are substantially equal. 4. The imaging device according to claim 1, 2, or 3, wherein a right-angle mirror is arranged in front of the roof mirror lens array, and the whole is integrated with a housing. 5. The imaging device according to claim 1, 2, or 3, wherein a half mirror is arranged in front of the roof mirror lens array and the whole is integrated with a housing. 6. The imaging device according to claim 1, 2, or 3, wherein a mirror is arranged on the object side or the image side in front of the roof mirror lens array, and the whole is integrated with a housing. 7. The imaging device according to claim 1, 2 or 3, wherein a pair of right angle prisms are arranged in front of the roof mirror lens array and the whole is integrated with a housing. 8 The refractive index of each lens in the multi-lens array is 1.491, the diameter is 8.6 mm, and the radius of front curvature is
22.65mm, rear radius of curvature -84.191mm, thickness 4.0
mm, the distance from the rear surface of the lens to the ridgeline where both reflective surfaces of the roof mirror intersect is 11.6 mm, and the arrangement pitch of each lens and roof mirror is 9.2 mm. 4
Imaging device as described in section.