Modularized light-guiding apparatus and manufacturing method

Abstract

A modularized light-guiding apparatus and manufacturing method, which may make the light of a light source proceed at least twice light reflections of predetermined directions. The light-guiding apparatus includes a plurality of modularized reflection elements, which may be differentiated to several different types of reflection element. Each type of each reflection element all has substantially same adjoining device and edge size for providing to be adjoined and piled-up with another reflection element. But, the reflection element of different type individually has different number of reflection plane for providing the light to proceed different times of light reflection. It may determined the light reflection times and light-path length for the light-guiding apparatus, by choosing several different types of reflection element among plural reflection elements to proceed the piling-up for the light-guiding apparatus.

Description

More than one reissue application has been filed for the reissue of U.S. Pat. No. 6,619,807. The reissue applications are application Ser. No. 11/229,450 (the present application), and divisional reissue Ser. No. 11/796,694, all of which are reissues of U.S. Pat. No. 6,619,807.

FIELD OF THE INVENTION

The present invention relates to a modularized light-guiding apparatus and manufacturing method, especially to a kind adapted for use in a light-guiding apparatus for an optical scanning apparatus, and to proceed modularization and design for the reflection elements in the light-guiding apparatus to facilitate manufacture and assembly, and to be able to transform out modularized light-guiding apparatus with different light-path lengths, and the corresponding manufacturing method.

BACKGROUND OF THE INVENTION

Please refer to FIG. 1, which shows an embodiment for a typical flat bed optical scanner 1 seen in current market. Mainly, a document window glass is arranged on an upper side surface of the outer shell 11 of a scanner 1 to place a scanned document (not shown). An optical chassis 14, driven by a driving apparatus 13, proceeds a linear motion along the direction of a guiding rod 15 inside a hollow outer shell 11 to proceed an image-scanning job for the document on the glass 12.

Please refer to FIG. 2, which is an A—A sectional view for the optical chassis 14 of a prior optical scanner 1 in FIG. 1. The optical chassis 14 includes: a hollow shell body 141, a light source 142, which is positioned at an appropriate position on the upper side plane of the shell body 141, a light-guiding apparatus, which is assembled by plural reflection mirrors 143, a lens set 144, and a charge-coupled device 145. The light source 142 emits a light to the document (not shown), and its reflection light enters into the interior of the shell body 141 of the optical chassis 14 and is reflected by the plural reflection mirrors 143 in the light-guiding apparatus to lengthen its optical length to an appropriate length. Afterwards, the reflected light is focused by the lens set 144 and formed into an image on the charge-coupled device 145, by which the scanned image data is converted into electronic signals.

Please refer to FIG. 1 and FIG. 2, which show the prior optical chassis 14. Because the reflection mirror 143 is constructed by plating silver on a thin-plate-typed glass that is unable to be directly piled-up and positioned by itself, so additional spring pieces 146, a fixture mechanism, or a method of matching screw locking are needed to fix the reflection mirror 143 at predetermined position inside the shell body 141. Not only the The positioning elements of additional spring pieces 146 and fixture mechanism would directly cause the an increase of parts number and production cost and raise the assembly time and manpower cost, . but also Additionally, even if plenty number of assembly parts is existed, then the occupying volume is caused to increase must be increased, and it is unavoidable to happen the situation that the parts loose may loosen or create uneven holding strength would cause causing position bias for the reflection mirror 143 and lower down decrease the quality of image scanning. Furthermore, because the spring pieces 146 would reduce its holding force due to the elasticity fatigue of the spring pieces 146 caused by long-period use would reduce its holding force or under caused by the vibration situations happened experienced during machine transportation, . Likewise, the prior arts that employs the spring pieces 145 as fixture mechanism for holding the reflection mirror 143 may also occur experience the situations of loosening or position bias in the reflection mirror 143 and cause the quality lowering-down decrease in image scanning and that is needed to be improved .

Furthermore, there is still one big shortcoming in the light-guiding apparatus of the prior optical chassis 14 shown in FIG. 1 and FIG. 2; namely, since each piece of reflection mirror has only one reflection plane to proceed single reflection for the light, and in order to reach the total track (abbreviated as TT value, which is the total value of Y1+Y2 . . .+Y5 as shown in FIG. 2) needed by the lens set 144 to focus image clearly, so the distance between each reflection mirror 143 is needed to be elongated (i.e. an increase in the values of Y2 and Y3), or the light is reflected twice on one reflection mirror, or an additional number of reflection mirrors are is needed to increase for increasing the times of reflection. However, the elongation of distance between each reflection mirror 143 would directly cause the enlargement of the total volume of the optical chassis 14. Twice reflections proceeded on one single mirror would cause the area increase for the reflection mirror or raise the complexity on the designs of light-path routes. And, the increase of the number of reflection mirrors would then cause the raise for increase in both difficulty and cost in element assembly and mirror positioning for the optical chassis 14. All these arrangements are not the perfect solution methods.

Additionally, for all the optical chassis light-guiding apparatus in the optical chassis seen in current markets, its the reflection mirror 143 all is reflection mirror are of thin-plate-shaped glass, neither each no reflection mirror 143 is of modularized design, nor can it be inter-piled-up or positioned, while additional designs for positioning devices is are needed to position the inter-angles and distances between each reflection mirrors 143. Not only would any errors on any position angle would cause the lowering-down a decrease of scanning quality, but also for the needs of different resolution, different outer sizes of optical chassis, different scanning paper sizes (the sizes of A3 or A4), or other needs for different light-path routes or total track of optical chassis, a set of position device is designed from the beginning to change the inter-position between each reflection mirror 143, and the usage is very inefficient.

SUMMARY OF THE INVENTION

The first object of the present invention is to provide a modularized light-guiding apparatus and manufacturing method, which include several reflection elements in modularized design, wherein at least one reflection element has two reflection planes and may provide at least twice reflection for light to increase the length of light-path route provided by a single reflection element, thereby a less lower number of reflection element in a narrow space of a light-guiding apparatus would generate a relatively larger light-path length.

The second object of the present invention is to provide a modularized light-guiding apparatus and manufacturing method, which include several reflection elements in modularized design. Each reflection element all is a single element formed to one body, and has different numbers of reflection plane to provide different values of light-path length. Under the condition of no change in the outer volume and size of the light-path apparatus, it is possible to reach the function of changing total track of the light-path apparatus by choosing the reflection elements with different numbers of reflection planes for connection and assembly to fulfil fulfill the needs for of optical chassis having different total tracks, and it is completely unnecessary to design a new optical chassis from the beginning.

The third object of the present invention is to provide a modularized light-guiding apparatus and manufacturing method, which include several reflection elements in modularized design. Each reflection all elements is a single element formed to one body and has substantially same edge size and adjoining plane. Further, it is sufficient to complete the position for the inter-angles and distances between each reflection element to become a light-guiding apparatus, simply by inter-butting and inter-piling-up the adjacent planes between each reflection element. Even Accordingly, no additional position mechanism is needed to proceed the position between each reflection elements. However, the present invention may also fix each reflection element to avoid its loosening by applying additional positioning means.

Preferably, by arranging a position plate individually at two end sides of the reflection elements, and arranging inter-setting-in convex points and concave holes at predetermined positions at two end sides of the position plate and each reflection element, and last by setting-in both convex point and concave hole to make the reflection element position and connect at the predetermined position on the position plate, it can be reached the position and fixation for plural reflection elements can be reached.

Preferably, no matter how many numbers of reflection planes are possessed by the reflection device, the directions and positions for light entering into and emitting away the reflection elements are all the same.

For your esteemed review committee to further understand and recognize the present invention, a detailed description in company with matching drawings are present as following.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is an illustration for the optical scanner of prior art.

FIG. 2 is an illustration for the light-guiding apparatus inside the optical chassis of a prior optical scanner.

FIGS. 3A, 3B, and 3C are the embodiments individually for the reflection elements with several different types in the modularized light-guiding apparatus of the present invention.

FIGS. 4A, 4B, and 4C are several the embodiments individually for the modularized light-guiding apparatus of the present invention applying same number but different types' reflection elements to assemble and generate different light-path lengths.

FIG. 5 is a position plate embodiment for the modularized light-guiding apparatus of the present invention.

FIG. 6 is an embodiment illustration for the modularized light-guiding apparatus of the present invention installed inside an optical chassis of an optical scanning apparatus.

FIG. 7 is another embodiment for the modularized light-guiding apparatus of the present invention, which describes a light-source element having light-source with modularized element and being able to match the usage of inter-piling-up of reflection elements.

FIG. 8 is another embodiment for the modularized light-guiding apparatus of the present invention, which illustrates a light-guiding apparatus piled-up by using nine reflection elements.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

The modularized light-guiding apparatus 20 of the present invention, which provides plural modularized reflection element 21, 22, 23 that can be differentiated to several groups with different types. Each type's each reflection element 21, 22, 23 type all has have substantially the same adjoining mechanism and edge size for providing to be being adjoined and piled-up with another reflection element. But, the reflection elements 21, 22, 23 of different type individually has have different numbers of reflection planes 211, 221, 231 for providing the light to proceed several times of light reflection. It can be decided the The reflection times and light-path lengths of the light-guiding apparatus 20, can be decided by choosing several different types of reflection elements among the plural reflection elements 21, 22, 23 to proceed piling-up the light-guiding apparatus 20.

Several preferable embodiments are proposed as following to describe the detailed structure, motion manner, function, and other characteristics of the modularized light-guiding apparatus of the present invention in detail.

Please refer to FIGS. 3A, 3B, 3C and FIGS. 4A, 4B, 4C, which show the several preferable embodiments for the modularized light-guiding apparatus 20 of the present invention. FIGS. 3A, 3B, and 3C are the embodiments individually for the reflection element 21, 22, 23 with several different types in the modularized light-guiding apparatus 20 of the present invention. FIGS. 4A, 4B, and 4C are several embodiments individually for the modularized light-guiding apparatus 20 of the present invention applying same number but different types' of reflection element 21, 22, 23 to assemble and generate different light-path lengths.

As shown in these drawings, each reflection element 21, 22, 23 all is the comprise a modularized element with shape of a long, narrow block; namely, each reflection element 21, 22, 23 all has have substantially save the same edge size (i.e. same length, width and altitude) and can be randomly chosen to inter-pile-up the light-guiding apparatus, which is called as a modularized element by the manner similar to blocks building blocks. In this preferable embodiment, the reflection elements 21, 22, 23 all is are each preferably a single element formed to one body, of which materials may be glass, crystal, quartz, and transparent acrylic-plastic sheet, etc., or which may also be made of opaque or semi-transparent materials of metal, ceramic, plastic, opaque acrylic-plastic sheet, wood, and paper, etc.

As shown in FIGS. 3A, 3B, 3C, at least a narrow, long reflection plane 211, 221, 231 are is individually arranged on the reflection element 21, 22, 23 along a narrow direction, and several adjoining planes 212, 222, 232 are also arranged on the reflection element 21, 22, 23, and several positioning concave holes 213, 223, 233 are arranged at the predetermined positions on the two end side surfaces positioned at the narrow, long reflection element 21, 22, 23. By forming a cutting portion along a narrow, long direction on the narrow, long reflection element 21, 22, 23, the said reflection planes 211, 221, 231 are formed into slant planes or cutting planes concaved inward with predetermined angle on the reflection element 21, 22, 23. Then at least one layer of plating film 2111, 2211, 2311 of the light-reflection materials are covered on these planes to form the reflection plane 211, 221, 231 that may proceed the light reflection. In this preferable embodiment, the plating film 2111, 2211, 2311 of light-reflection materials can be formed by directly plating materials with excellent light-reflection such as chromium or silver etc. on the reflection plane 211, 221, 231, or by directly adhering the light-reflection plating film 2111, 2211, 231 onto the reflection planes with the same manner as adhering an adherent paper. Or, when the reflection element 21, 22, 23 is made of materials with excellent light-reflection (i.e. partly metals etc.), by polishing the portion of the reflection plane 211, 221, 231, a good effect of light-reflection may also be reached without needing plating film. As shown in FIG. 3A, which is the reflection element 21 may only having have a single reflection plane 211 (abbreviated for type A). FIG. 3B shows the reflection element 22 having two reflection planes 221 (abbreviated for type B). While FIG. C shows the reflection element 23 having three reflection planes 231 (abbreviated for type C). Although these reflection elements 21, 22, 23 of different types having have different numbers of reflection planes 211, 221, 231 to proceed light reflection of different times and provide different lengths of light reflection (light-path length), but, in this preferable embodiment, no matter what kinds of reflection element 21, 22, 23 all has have the same characteristics as following:

(1) Having substantially the same profile edge size (i.e., same length, width, altitude), and substantially the same structure of positioning concave holes. There are only different structures of concaved portions for the different numbers of reflection plane 211, 221, 223, due to cutting formation among each different types of reflection elements 21, 22, 23.

(2) Having substantially the same size and providing adjoining planes 212, 222, 232 capable of inter-matching with adjoining planes 212, 222, 232 of another reflection element 21, 22, 23 (independent of any types ) to inter-close-together for assembly and inter-position for proceeding piling-up to align the reflection element 21, 22, 23.

(3) Independent of any type or reflection element 21, 22, 23 having any numbers of reflection plane, the directions and positions for light entering into or reflecting from each reflection element 21, 22, 23 are all the same, and after emitting to a reflection element 21, 22, 23 with predetermined direction, first, the light all will be reflected at least once on each reflection plane 211, 221, 231, then again emitting out from the reflection element 21, 22, 23 with another predetermined direction.

(4) When several reflection elements 21, 22, 23 (independent of any type) are inter-butting, adjoining and piling up by using the adjoining plane 212, 222, 223, a predetermined direction for light emitting from a reflection element is just corresponding to the predetermined direction for light entering into another adjacent reflection element, and the guidance and transfer of light may be proceeded completely with predetermined directions.

As shown Shown in FIGS. 4A, 4B, 4C, which are several kinds of embodiments that apply the light-guiding apparatus 20a, 20b, 20c constructed by the reflection element 21, 22, 23 as shown in FIGS. 3A, 3B, 3C. These embodiments concretely describe that the present invention, by choosing different number of reflection element 21, 22, 23 or reflection element 21, 22, 23 with different numbers of reflection plane, may adjoin the modularized light-guiding apparatus 20a, 20b, 20c and decide the reflection times and light-path lengths for the light that may be provided by the modularized light-guiding apparatus. In order to describe the implementation effect of the present invention in simple way, only three reflection element 21, 22, 23 are adopted to pile up and construct the light-guiding apparatus 20a, 20b, 20c in FIGS. 4A, 4B, 4C, however it is intended to emphasize that the employable variations for the present invention are absolutely not restricted to the embodiments as shown in FIGS. 4A, 4B, 4C.

As shown Shown in FIG. 4A, which is a light-guiding apparatus 20a, constructed by using the reflection element 21 of type A and the reflection element 23 of type C, and of which the substantial light reflection number is seven times, and the length of total track is “X1+4*X2+8*X3+X4”.

FIG. 4B shows a light-guiding apparatus 20b, constructed by using the reflection elements of one type A (reflection element 21), one type B (reflection element 22) and one type C (reflection element 23), and of which the substantial light reflection number is six times, and the length of total track is “X1+4*X2+4*X3+2*X5+X6+X4”.

FIG. 4C shows a light-guiding apparatus 20c, constructed by using the reflection element 23 of three type C, and of which the substantial light reflection number is nine times, and the length of total track is “X1+4*X2+12*X3+X4”.

One thing is worth mentioning: for any person who is well-known the light-path apparatus and for an optical chassis, the distance X1 prior to light entering the light-guiding apparatus 20 and the distance X4 (may refer to FIG. 6) between the light-guiding apparatus and the lens set 31 are not relatively easy to be changed (i.e., when comparing FIG. 4A with FIG. 2, wherein X1=Y1, X4=Y4). Namely, we can easily find that the value of light-path length of the prior light-guiding apparatus as shown in FIG. 2 can only be changed mainly by determining the magnitude of distances of Y2 and Y3 between each reflection mirrors 143. As the values of Y2 and Y3 are enlarged in order to increase the total track, then the total volume of entire optical chassis or light-guiding apparatus is also caused to increase greatly. However, relatively, the refection element 21, 22, 23 of the present, designed by modularization, can easily assembly out the light-guiding apparatus 20a, 20b, 20c having plenty different values of total track, by only choosing and using different types of reflection element 21, 22, 23 for matching and piling-up. When we design that X2 is equal to X3, for the light-guiding apparatus constructed by three same reflection element 21, 22, 23, the provided minimum total track (equal to 4*X2, when using three reflection elements 21 of type A) is one-forth for the provided maximum total track (equal to 16*X2, when using three reflection elements 23 of type C), however, the outer profile and volume size of the guiding apparatus are then always kept consistent, and these are the techniques that can not be reached by the all prior light-guiding techniques.

From above-description, we know that the manufacturing method of the modularized light-guiding apparatus 20 of the present invention should include following steps:

• • (1) Preparing plural reflection element 21, 22, 23, which may be differentiate to the reflection element 21, 22, and 23 of several different types. The reflection element 21, 22, 23 of each different type individually have different numbers of reflection planes 211, 221, 231 for providing light to proceed light-reflection of different times and light-path lengths.
  • (2) According to the needed values of light-path length for the intended-manufacturing light-guiding apparatus, the needed types and numbers of reflection elements are calculated out to reach the values of the light-path length; and
  • (3) The light-guiding apparatus is assembled and connected according to the calculation for the needed reflection elements.

In the present invention, since each reflection element 21, 22, 23 all has have substantially the same profile edge size, and adjoining plane 212, 222, 232 capable of inter-matching, and which may be provided with adjoining planes of another reflection elements (independent of any types) for inter-closing-together and positioning to proceed piling-up. Therefore, only by inter-closing-together for adjoining plane 212, 222, 232 between each reflection element 21, 22, 23, it is sufficient to reach the inter-position between each reflection element 21, 22, 23, and facilitate the reflection plane 211, 221, 231 of each reflection element 21, 22, 23 to be able to correspond with the reflection planes of another reflection element to proceed the light-reflections in predetermined directions. It is unnecessary to arrange additional holding elements such as spring pieces 146 etc. as used in prior art, or design additional slant planes with predetermined angles and positions inside the prior shell body 141 to provide support for the position reflection mirrors 143. However, in order to make each reflection element 21, 22, 23 of the light-guiding apparatus 20 of the present invention be able to be connected and fixed firmly without loosing off, in one preferable embodiment of the present invention, the plural reflection element 21, 22, 23 can be made to be positioned, fixed and connected to one body without being able to separate from each other, by applying an additional positioning means.

In one of the preferable embodiments for the positioning means, the adjacent adjoining plane 212, 222, 232 for each adjacent reflection element 21, 22, 23 are is directly adhered and connected by glue, thermal-melting-glue, ultra-sonic-wave melting connection, thermal melting connection, or welding (adapted for metal materials) to reach the position and fixture between the plural reflection element 21, 22, 23.

In another preferable embodiment for the positioning means (not shown in the drawings), the structure of positioning concave holes are similarly arranged on the two side surfaces of the adjacent planes of each reflection element, and are inserted onto the adjacent planes of two adjacent reflection elements by in the manner of tennon a tenon. In another further preferable embodiment for the positioning means (not shown in the drawings), the gliding troughs (or guiding troughs) and the structure of flanges both capable of inter-setting-in are arranged on the adjacent planes of each reflection element for proceeding assembly and fixture. Because the positioning means described in this section is a well-known technique for prior positioning mechanism to inter-set-in two elements, repetitious descriptions are not presented here.

Please refer to FIG. 5, which is another further embodiment of positioning means for the reflection element 21, 22, and 23, of the light-guiding apparatus 20 of the present invention. The positioning means (positioning mechanism) further reaches the position and fixture for plural reflection element 21, 22, 23, by arranging a positioning plate 24 individually on each two end sides of the reflection element 21, 22, 23, and arranging several positioning convex points 241 on the positioning plate to be able to be inter-set-in with the positioning concave hole 213, 223, 23 of each reflection element 21, 22, 23, and by the inter-setting-in for the convex points 241 and the concave point 213, 223, 233 to make the reflection element 21, 22, 23 be able to be positioned and connected at some predetermined position on the positioning plate 24. For example, as shown in FIG. 5, which is the structure of the positioning plate 24 that then may be used to individually fix and connect three reflection element 21, 22, 23 (independent of any type) shown in FIGS. 4A, 4B, 4C to the upper-left, lower-left, and lower-right corner portions of the positioning plate 24, respectively.

Please refer to FIG. 6, which is the light-guiding apparatus 20 of the present invention that is matched with the elements of lens set 31, charge-coupled device 32, light source 33, and optical chassis shell body 34, etc. to assemble and construct an optical chassis that is adapted for using on an optical scanning apparatus. From FIG. 6, we know that the light-guiding apparatus 20 of the present invention may directly provide the effect of light-reflection in predetermined directions and light-path length, by simply only inter-piling-up and positioning the reflection element 21, 22, 23 with each other, wherein the optical chassis is essentially unnecessary to be additionally arranged with another positioning devices or holding elements on or inside its shell body 34, and these arrangements may greatly improve the harassment from the prior art. In use with an optical scanning apparatus, the light-guiding apparatus 20 may transmit light from light source 22, may receive the transmitted light through an opening in a light-guiding apparatus 20, may reflect the received light within the light-guiding apparatus 20(at least three times for example), may release the reflected light through the opening in the light-guiding apparatus 20, and may transmit the released light to a lens set 31. Additionally or alternatively, the light transmitted from the light source 22 to the lens set 31 may be reflected only within the light-guiding apparatus.

Please refer to FIG. 7, which is another preferable embodiment for the modularized light-guiding apparatus of the present invention. In this preferable embodiment, the light source element 33 of the optical chassis may also be designed as a modularized light source element 25 having the substantially same structures of profile edge sizes (length, width, and altitude) and positioning concave holes, etc. as those in the reflection element 21, 22, 23 of the present invention or the modularized light source element 25 may also have the substantially same structures of adjoining plane as those in the reflection element 21, 22, 23. On the predetermined positions of the modularized light source element 25, there are arranged with a light source 251, positioning concave holes 252, and several narrow, long opening trough troughs 253 to provide the passing-through for the light. With this embodiment, the modularized light source element 25 may directly proceed the piling-up and positioning with each reflection element 21, 22, 23, or be assembled to the upper-left corner portion of the positioning plate 24 as shown in FIG. 5 by the positioning concave holes 252, and to be able to facilitate the assembly and manufacture for the optical chassis.

As shown in FIG. 8, which is another further embodiment of the present invention is illustrated, wherein the light-guiding apparatus 20d is comprised of nine reflection elements 23 of type C, and its total reflection number is 27 times.

Above-mentioned embodiments are applied to describe the present invention in detail, and are not the restricted scopes of the present invention. For example, the reflection elements of the present invention are not only restrained to the reflection element 21, 22, 23 with rectangular long stripe shape as shown in FIGS. 3A, 3B, 3C, nor are the present invention restrained to having the number of reflection plane no more than three. Relatively, the reflection element of the present invention may also be designed as the reflection element with similar shapes of pentagon or other multi-side long stripe, and the number of the reflection plane of the reflection elements may also larger than three, or even the reflection plane is an arc plane. Furthermore, the modularized light-guiding apparatus of the present invention are not restricted to be used on the optical chassis of an optical scanning apparatus and can also be adapted for being used in another optical chassis of other optical machines such coping machine etc. that need to proceed the light reflection for reaching the predetermined distance. Again, for example, the reflection elements of the present invention are not restricted to above-mentioned embodiments, wherein each of the reflection planes all only proceeds once a single light-reflection, relatively, ; the reflection element may also be designed to proceed several times of light-reflection on the same reflection plane, ; or under certain circumstance, some reflection plane is may not be able to reflect the light. Therefore, for all the people who are familiar with this kind of technique should understand that any appropriately little change or adjustments of the present invention are still not departed from the merits, spirits, and scopes thereof.

Claims

1. A modularized light-guiding apparatus, which may make the light of a light source proceed at least twice light-reflection of predetermined direction, the modularized light-guiding apparatus includes:

plural reflection elements, each reflection element individually has at least one reflection plane provided to proceed reflection for the light, and each reflection element individually has at least one adjoining plane provided for being adjoined with another reflection element, and only by simple inter-adjoining for the adjoining planes of each reflection element, it is sufficient to reach the inter-position between each reflection element, and facilitate the reflection planes of each reflection element be able to be corresponded with the reflection planes of another reflection element to proceed the light-reflection of predetermined direction.

2. The modularized light-guiding apparatus as the claim 1, wherein, each reflection element all is the modularized element of narrow, long stripe shape, namely, each reflection element all has substantially same edge size and can be inter-piled-up to become the light-guiding apparatus.

3. The modularized light-guiding apparatus as the claim 1, wherein, in the plural reflection elements, at least one reflection element has at least two reflection planes, and the light of predetermined direction, emitting to the reflection element, can be proceeded more than twice light-reflection by at least two reflection planes, and then the light emits away the reflection element with predetermined direction.

4. The modularized light-guiding apparatus as the claim 1, wherein, in the plural reflection elements, at least two reflection elements have different numbers of reflection plane.

5. The modularized light-guiding apparatus as the claim 4, wherein, it may decide the light-reflection times and light-path lengths provided by the modularized light-guiding apparatus, by choosing different numbers of reflection element and the reflection element having different numbers of reflection plane to adjoin each other to become the modularized light-guiding apparatus.

6. The modularized light-guiding apparatus as the claim 1, wherein, each reflection element all is a single element that is formed to one body.

7. The modularized light-guiding apparatus as the claim 1, wherein, at least one reflection plane of the reflection element is formed by arranging at least one plane with predetermined angle on the reflection element and covering at least one layer of plating film of light-reflection material on the plane.

8. The modularized light-guiding apparatus as the claim 1, wherein, positioning means are further included to position, fix, and connect the plural reflection elements to one body without separating from each other.

9. The modularized light-guiding apparatus as the claim 8, wherein, the positioning means further reaches the position and fixture for the plural reflection elements, by arranging a positioning plate individually on each two end sides of the reflection elements, and arranging several positioning convex points on the positioning plate to be able to be inter-set-in with the positioning concave holes arranged at predetermined positions of two end sides of each reflection element, and by the inter-setting-in for the convex points and the concave points to make the reflection element be able to be positioned and connected at some predetermined position on the positioning plate.

10. The modularized light-guiding apparatus as the claim 8, wherein, the positioning means reaches the position and fixture for the plural reflection elements, by directly adhering and connecting the adjacent adjoining planes of each adjacent reflection element.

11. The modularized light-guiding apparatus as the claim 1, wherein, no matter how many numbers of reflection plane possessed by the reflection element, the direction and position for the light entering into and emitting away each reflection element are all the same.

12. A modularized light-guiding apparatus, which may make the light of a light source proceed at least twice light-reflection of predetermined direction, the modularized light-guiding apparatus includes:

plural reflection elements, each reflection element individually has at least one reflection plane provided to proceed reflection for the light, and each reflection element individually all has substantially same edge size and can be inter-piled-up to become the light-guiding apparatus, and only by the inter-piling-up for each reflection element, it is sufficient to reach the inter-position for the plural reflection elements, and facilitate the reflection planes of each reflection element be able to be corresponded with the reflection planes of another reflection element to proceed the light-reflection of predetermined direction.

13. The modularized light-guiding apparatus as the claim 12, wherein, in the plural reflection elements, at least one reflection element has at least two reflection planes, and the light of predetermined direction, emitting to the reflection element, can be proceeded more than twice light-reflection by at least two reflection planes, and then the light emits away the reflection element with predetermined direction.

14. The modularized light-guiding apparatus as the claim 12, wherein, each reflection element all is a single element that is formed to one body.

15. The modularized light-guiding apparatus as the claim 12, wherein, positioning means are further included to position, fix, and connect the plural reflection elements to one body without separating from each other.

16. The modularized light-guiding apparatus as the claim 15, wherein, the positioning means further reaches the position and fixture for the plural reflection elements, by arranging a positioning plate individually on each two end sides of the reflection elements, and arranging several positioning convex points on the positioning plate to be able to be inter-set-in with the positioning concave holes arranged at predetermined positions of two end sides of each reflection element, and by the inter-setting-in for the convex points and the concave points to make the reflection element be able to be positioned and connected at some predetermined position on the positioning plate.

17. The modularized light-guiding apparatus as the claim 15, wherein, the positioning means reaches the position and fixture for the plural reflection elements, by directly adhering and connecting the adjacent adjoining planes of each adjacent reflection element.

18. The modularized light-guiding apparatus as the claim 12, wherein, no matter how many numbers of reflection plane possessed by the reflection element, the direction and position for the light entering into and emitting away each reflection element are all the same.

19. A modularized light-guiding apparatus, which may make the light of a light source proceed at least twice light-reflection of predetermined direction, the modularized light-guiding apparatus includes:

plural reflection elements, each reflection element all is a single element formed to one body and each individually has at least a reflection plane provided for proceeding the reflection of the light, and in plural reflection elements, at least one reflection element has at least two reflection planes for making the light proceed at least twice light reflections in the reflection element; and

positioning mechanism, which is used to proceed the position for the plural reflection element, and facilitates the reflection plane of each reflection element to be able to be corresponded with the reflection plane of another reflection element to proceed the light reflection of predetermined direction.

20. The modularized light-guiding apparatus as the claim 19, wherein, the positioning means further reaches the position and fixture for the plural reflection elements, by arranging a positioning plate individually on each two end sides of the reflection elements, and arranging several positioning convex points on the positioning plate to be able to be inter-set-in with the positioning concave holes arranged at predetermined positions of two end sides of each reflection element, and by the inter-setting-in for the convex points and the concave points to make the reflection element be able to be positioned and connected at some predetermined position on the positioning plate.

21. The modularized light-guiding apparatus as the claim 19, wherein, the positioning means reaches the position and fixture for the plural reflection elements, by the design of each reflection element has adjoining planes which have substantially same edge size, and by directly adhering and connecting the adjacent adjoining planes of each adjacent reflection element.

22. The modularized light-guiding apparatus as the claim 19, wherein, no matter how many numbers of reflection plane possessed by the reflection element, the direction and position for the light entering into and emitting away each reflection element are all the same.

23. A modularized light-guiding apparatus, which may make the light of a light source proceed at least twice light-reflection of predetermined direction, the modularized light-guiding apparatus includes:

plural reflection elements, which can be differentiated to different types of reflection element, and each type's each reflection element all has substantially same adjoining mechanism for providing to be adjoined and piled-up with another reflection element, but the reflection elements of different type individually has different numbers of reflection plane for providing the light to proceed several times of light reflection, wherein it can be decided the reflection times of the light-guiding apparatus, by choosing several different types of reflection elements among the plural reflection elements to proceed piling-up.

24. The modularized light-guiding apparatus as the claim 23, wherein, each reflection element all is a single element that is formed to one body.

25. The modularized light-guiding apparatus as the claim 23, wherein, a positioning means is further included, and the positioning means reaches the position and fixture for the plural reflection elements, by arranging a positioning plate individually on each two end sides of the reflection elements, and arranging several positioning convex points on the positioning plate to be able to be inter-set-in with the positioning concave holes arranged at predetermined positions of two end sides of each reflection element, and by the inter-setting-in for the convex points and the concave points to make the reflection element be able to be positioned and connected at some predetermined position on the positioning plate.

26. The modularized light-guiding apparatus as the claim 23, wherein, the positioning means reaches the position and fixture for the plural reflection elements, by the design of each reflection element has substantially same adjoining planes which have substantially same edge size, and by directly adhering and connecting the adjacent adjoining planes of each adjacent reflection element.

27. The modularized light-guiding apparatus as the claim 23, wherein, no matter how many numbers of reflection plane possessed by the reflection element, the direction and position for the light entering into and emitting away each reflection element are all the same.

28. A modularized light-guiding apparatus, which may make the light of a light source proceed at least twice light-reflection of predetermined direction, the modularized light-guiding apparatus includes:

plural reflection elements, which can be differentiated to different types of reflection element, and each type's reflection element has individually has different numbers of reflection plane for providing the light to proceed several times of light reflection; and

positioning mechanism, which is used to proceed the position for the plural reflection element, and facilitates the reflection plane of each reflection element to be able to be corresponded with the reflection plane of another reflection element to proceed the light reflection of predetermined direction;

wherein, it can be decided the times of light reflection for the light-guiding apparatus, by choosing predetermined number of several reflection elements with different types among the plural reflection elements, and by the positioning mechanism to position and assembly the light-guiding apparatus.

29. The modularized light-guiding apparatus as the claim 28, wherein, each reflection element all is a single element that is formed to one body.

30. The modularized light-guiding apparatus as the claim 28, wherein, the positioning means reaches the position and fixture for the plural reflection elements, by arranging a positioning plate individually on each two end sides of the reflection elements, and arranging several positioning convex points on the positioning plate to be able to be inter-set-in with the positioning concave holes arranged at predetermined positions of two end sides of each reflection element, and by the inter-setting-in for the convex points and the concave points to make the reflection element be able to be positioned and connected at some predetermined position on the positioning plate.

31. The modularized light-guiding apparatus as the claim 28, wherein, the positioning means reaches the position and fixture for the plural reflection elements, by the design of each reflection element has substantially same adjoining planes which have substantially same edge size, and by directly adhering and connecting the adjacent adjoining planes of each adjacent reflection element.

32. The modularized light-guiding apparatus as the claim 28, wherein, no matter how many numbers of reflection plane possessed by the reflection element, the direction and position for the light entering into and emitting away each reflection element are all the same.

33. A manufacturing method for a modularized light-guiding apparatus includes following steps:

preparing plural reflection elements, which may be differentiate to the reflection element of several different types, and the reflection elements of each different type individually have different numbers of reflection planes for providing light to proceed light-reflection of different times and light-path lengths;

according to the needed values of light-path length for the intended-manufacturing light-guiding apparatus, the needed types and numbers of reflection elements are calculated out to reach the values of the light-path length; and

the light-guiding apparatus is assembled and connected according to the calculation for the needed reflection elements.

34. The manufacturing method for a modularized light-guiding apparatus as the claim 33, wherein, independent on any type, each reflection element all has substantially same adjoining planes that have substantially same edge sizes, and it may reach the position for the plural reflection elements by directly piling up and adjoining together the adjacent adjoining planes for each adjacent element.

35. The manufacturing method for a modularized light-guiding apparatus as the claim 33, wherein, no matter how many numbers of reflection plane possessed by the reflection element, the direction and position for the light entering into and emitting away each reflection element are all the same.

36. The manufacturing method for a modularized light-guiding apparatus as the claim 33, wherein, each reflection element all is a single element that is formed to one body.

37. A modularized light-guiding apparatus, comprising:

a first reflection component including at least one reflection plane and at least one adjoining plane;

wherein the at least one adjoining plane is configured to adjoin with a second reflection component to reach an inter-position between the adjoined reflection components; and

wherein the at least one reflection plane of the first reflection component is configured to correspond with a reflection plane of the second reflection component to reflect light in a predetermined direction within a chassis of an optical machine; and

wherein the adjoined first reflection component and second reflection component are configured to receive and release the light through an opening defined by the first and second reflection components.

38. The apparatus of claim 37, wherein the first reflection component includes at least two reflection planes.

39. An apparatus, comprising:

a first reflection component including at least one reflection plane and at least one adjoining plane;

a second reflection component including at least one reflection plane and at least one adjoining plane;

wherein the adjoining plane of the first reflection component and the adjoining plane of the second reflection component are configured to adjoin the first reflection component to the second reflection component; and

wherein the adjoined first reflection component and second reflection component are configured to receive and release light in a predetermined direction within a chassis of an optical machine; and

wherein the adjoined first reflection component and second reflection component are configured to receive and release the light through an opening therein.

40. The apparatus of claim 39, further comprising a third reflection component including at least one reflection plane and at least one adjoining plane, wherein the third reflection component is configured to replace the second reflection component to change a light path length within the chassis of the optical machine without changing the predetermined direction.

41. The apparatus of claim 39, further comprising a third reflection component including at least one reflection plane and at least one adjoining plane, wherein the third reflection component is configured to replace the second reflection component to change a light path length within the chassis of the optical machine without changing the size of the chassis of the optical machine.

42. The apparatus of claim 39, further comprising a third reflection component including at least one reflection plane and at least one adjoining plane, wherein the third reflection component is configured to replace the second reflection component to change a light path length within the chassis of the optical machine without changing the predetermined direction and without changing the size of the chassis of the optical machine.

43. The apparatus of claim 39, further comprising a third reflection component including at least one reflection plane and at least one adjoining plane, wherein the number of reflection planes of the third reflection component is different from the number of reflection planes of the second reflection component, and wherein the third reflection component is configured to replace the second reflection component to change a light path length within the chassis of the optical machine without changing the predetermined direction.

44. The apparatus of claim 39, wherein the number of reflection planes of the first reflection component is different from the number of reflection planes of the second reflection component.

45. The apparatus of claim 39, wherein the light reflected within the chassis of the optical machine is reflected only within the apparatus.

46. The apparatus of claim 39, wherein the light is received and released through the opening at a constant direction and position regardless of the number of reflections performed within the adjoined first reflection component and second reflection component.

47. The apparatus of claim 39, wherein the adjoined first reflection component and second reflection component are configured to reflect the light at least three times before releasing the light.

48. The apparatus of claim 39, wherein the first reflection component and the second reflection component have substantially the same edge size.

49. A method comprising:

receiving transmitted light through an opening;

reflecting the received light via at least one reflection plane of a first reflection component;

releasing the reflected light out through the opening; and

replacing the first reflection component with a second reflection component including at least one reflection plane, wherein a number of reflection planes of the first reflection component is different from a number of reflection planes of the second reflection component;

wherein the replacing of the first reflection component with the second reflection component changes a light path length within a chassis of an optical machine.

50. The method of claim 49, wherein the replacing of the first reflection component with the second reflection component changes the light path length within the chassis of the optical machine without changing a receiving direction of the light and without changing a releasing direction of the light.

51. The method of claim 49, wherein the replacing of the first reflection component with the second reflection component changes the light path length within the chassis of the optical machine without changing the size of the chassis of the optical machine.

52. The method of claim 50, wherein the replacing of the first reflection component with the second reflection component changes the light path length within the chassis of the optical machine without changing the size of the chassis of the optical machine.

53. The method of claim 49, wherein the light is received and released at a constant direction regardless of the number of reflections performed.

54. The method of claim 49, wherein the light is reflected at least three times.

55. An optical apparatus comprising:

means for generating light representing a scanned object within a chassis of the optical apparatus; and

means for reflecting light received through an opening defined by adjoined reflection components, wherein the light is received and released through the opening at a constant direction within the chassis of the optical apparatus regardless of the number of reflections performed by the adjoined reflection components;

wherein the means for reflecting light allows a light path length within the chassis to be manipulated without changing the size of the chassis of the optical apparatus.

56. The optical apparatus of claim 55 wherein the number of reflections is at least three.