KR100267243B1 - Nob adjust control consolidation apparatus for slope error revision in suttle type scanner - Google Patents

Abstract

PURPOSE: A junction structure of a knob adjust device for correcting a slope drift in a shuttle method scanner is provided to perform a correction of the slope drift exactly by preventing a back rash generated by a movement of the knob adjust device through a press part at a junction groove of a frame base. CONSTITUTION: A junction hole(35) of a junction groove(9) is joined with a screw(5) of a knob control device because a pressure is applied in the direction of a projection(10) of the junction groove(9), and the screw(5) is fixed because a pressure is applied in the direction of a junction of a frame. At this time, the pressure is generated by the press part(34). Because of a fixture of the screw(5), a screw thread machined by the screw(5) sticks to a screw thread of the frame, and a backlash is almost removed.

Description

Combined structure of knob adjustment device for tilt deviation correction of shuttle scanner

The present invention relates to a shuttle scanner, and more particularly, to improve the coupling structure of the knob adjuster (Knob Adjust) for correcting the tilt deviation of the shuttle scanner scanner and the charge-coupled device (CCD: Charge Coupled Device) It is related to the structure of the knob adjustment device for the correction of the tilt deviation of the shuttle scanner to eliminate the backlash between the frame fixing the ().

In general, a shuttle scanner is an apparatus for scanning an image recorded on an original while reciprocating left and right in a direction orthogonal to a document's conveying direction, as shown in FIGS. 1 and 2. A lamp assembly including a lamp for scanning light onto a data surface (a surface on which an image is recorded) of the original, and a lens assembly including a lens for collecting reflected light reflected from the original; ), A charge coupling device assembly 3 including a charge coupling device (CCD) for converting the reflected light collected by the lens into an electrical signal. In addition, the lens assembly 2 is composed of a filter, a lens and a lens holder, and the lens holder has a structure capable of flowing between the charge coupling element assembly 3 and the lamp assembly 1. In addition, the lens assembly 2 and the charge coupling device assembly 3 have a structure that can be integrated and rotated.

Threads are machined on the contact portions between the screw 5 of the knob adjusting device 4 for rotating the charge coupling device assembly 3 and the frame 6 of the charge coupling device assembly 3, respectively. As the knob adjustment device 4 rotates by being engaged with the screw thread, the frame 6 is coupled to rotate together (see FIG. 2B).

In addition, the knob adjusting device 4 is fixedly coupled to the frame base 7 on which the charge coupling device assembly 3 is mounted. At this time, a through hole 8 is formed at one side of the frame base 7 to adjust the knob adjusting device. (4) One end of the screw (5) is penetrated through the through hole (8), the other side of the frame base (7) is formed with a coupling groove (9) partly open, knob adjustment device (4) screw (5) The other side of is mounted to the coupling groove (9) through the opening of the coupling groove (9). Here, the step 10 of the coupling groove 9 is designed to be smaller than the outer diameter of the screw 5 of the knob adjusting device 4, and the frame base 7 is made of a material having self-elasticity such as plastic, and the knob adjusting device 4 By pressing the other side of the screw 5 against the step 10 of the coupling groove 9, the other side of the knob adjusting device 4 screw 5 is prevented from being separated after being coupled to the coupling groove 9. . In addition, the inner diameter of the coupling groove 9 having a substantially arc shape is designed to be larger than the outer diameter of the screw adjusting device 4 screw 5 so that the other side of the knob adjusting device 4 screw 5 is connected to the coupling groove 9. It has a structure that can flow in the coupled state (see FIG. 2C).

On the other hand, a typical shuttle scanner can scan a plurality of pixels (Pixel) per slice at the same time or sequentially as shown in Figure 3a, assuming that if the number of pixels per slice 160, 300 DPI ( It is possible to obtain 13.547 mm (4.67 μm × 160 pieces) based on Dot per Inch. That is, one slice is composed of 160 pixels, and one band (scanning area that the scanner head can scan with one shuttle movement) is composed of 160 dots × 2400 slices based on an A4 size document. It consists of 22 bands (297 ÷ 13.547).

That is, when the scanning operation is started, the scanned data is stored in the memory in the order of slice. When the scanning operation of one band is completed, image data of 160 × 2400 bytes is stored.

However, due to errors in the assembly process of the scanner module or mechanical assembly tolerances, the line direction (the longitudinal direction of the slice) of the scanner head often does not coincide with the conveying direction of the original. In this case, the data stored in the memory through the scanning operation is in the form of disconnection and inclination between the bands as shown in FIG. 3B. In order to correct this inclination deviation, the knob adjusting device 4 should be adjusted so that the line direction of the scanner head exactly matches the conveying direction of the original. Conventional scanners can calculate the tilt deviation of the image using the scanned data. If a deviation of 1.5 dots occurs in a predetermined direction, rotating the scale formed by the knob adjusting device by 1.5 division as shown in FIG. The module is designed to correct the tilt deviation by rotating 1.5 dots in the opposite direction to the predetermined direction.

However, according to the conventional shuttle scanner, the following problem occurs.

That is, since the coupling groove of the frame base to which the knob adjusting device is coupled has an inner diameter larger than the outer diameter of the knob adjusting device and is formed in a circumferential shape, the central axis of the knob adjusting device flows when the knob adjusting device is operated. Accordingly, a backlash occurs in the engagement portion of the screw thread of the knob adjusting device and the screw thread formed on the frame of the charge coupling device assembly, so that each thread thread is not completely coupled. Therefore, even if the user operates the knob adjusting device, the charge coupling device assembly is actually adjusted within a range smaller than the operation amount of the knob adjusting device due to the backlash gap, so that an error occurs in the amount of correction of the tilt deviation, thereby accurately correcting the tilt deviation. You cannot correct it.

Therefore, the present invention is to solve such a problem, an object of the present invention is to form a pressing portion in the coupling groove of the frame base to which the knob adjustment device is coupled to prevent the flow of the knob adjustment device, accordingly backlash occurs The present invention provides a combined structure of a knob adjustment device for tilt deviation correction of a shuttle-type scanner that enables to correct a tilt deviation by suppressing an error.

1 is a perspective view of a typical shuttle scanner,

2a is a front view and a plan view and a side cross-sectional view of FIG.

Figure 2b is a view showing the backlash occurs when the screw and the screw thread of the frame is coupled by a conventional shuttle scanner,

Figure 2c is a sectional view of the main portion showing the coupling state of the screw and the frame support,

3A is a diagram showing a specification of a scanner head;

3B is a state diagram of a conventional scanner head in which a tilt deviation has occurred and thus data scanned;

Figure 3c is a view showing the adjustment scale formed in the knob adjustment device,

Figure 4 is an exploded perspective view of a shuttle scanner module applied to the present invention,

5 is a coupling structure of the screw and the frame base according to the first embodiment of the present invention,

6 is a view showing a state in which the backlash is removed when the screw and the screw thread of the frame is coupled by the shuttle scanner of the present invention,

7 is a view showing a rotation direction of the knob adjusting device and the rotation state of the frame accordingly;

8 is a coupling structure diagram of a screw and a frame base according to a second embodiment of the present invention.

<Description of the code | symbol about the principal part of drawing>

4: knob adjustment 5: screw

6: frame 7: frame base

9: coupling groove 10: step

34, 36: pressure member 35: coupling tool

A feature of the present invention for achieving the above object is that a pair of supports for supporting a knob adjusting device and a knob adjusting device comprising a screw threaded screw in a predetermined position to be engaged with the thread processed in the charge coupled device assembly. It includes a frame base formed, one side of the screw is coupled to the through-hole formed in any one of the pair of supports, the other side of the screw is formed in the other of the pair of supports coupled to the coupling groove having an opening on one side In the conventional shuttle scanner module: the opposite point of the opening formed in the coupling groove has a circumferential shape, and the point adjacent to the opening formed in the coupling groove has a thread in which a screw thread of the screw coupled to the coupling groove is machined in the charge coupling device assembly. And a pressurizing portion for pressurizing the screw toward the charge coupled device assembly to be engaged with the pressurized state It is.

In the feature of the present invention, the pressing portion is processed in a straight line extending from the circumference of the point adjacent to the opening to contact the screw, or the point adjacent to the opening to the contact with the screw extends from the circumference and has a small curvature compared to the circumference. It is processed in the form of a cylinder.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the coupling mechanism for adjusting the tilt deviation of the shuttle scanner according to the present invention will be described in detail. First, in adding reference numerals to the elements of each drawing, it should be noted that the same elements are denoted by the same reference numerals as much as possible even if they are displayed on different drawings. In describing the present invention, when it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

4 is an exploded perspective view of the shuttle scanner module applied to the present invention.

Referring to Figure 4 describes the assembly process of the shuttle scanner module as follows.

After the filter 12 is inserted into the lens holder 11, the lens 13 is fitted and the lens assembly 2 is assembled by fixing them in a heat fusion method. In addition, the charge coupling device board 14 is fastened to the frame 6 by the fastening member 15 to assemble the charge coupling device assembly 3, and then the spring 16 is fitted to the outside of the lens holder 11. The charge coupling device assembly 3 is coupled to one side 17 of the frame 6 and the cap lens 18 is rotated against one side 17 of the frame 6 to be fixed. Here, a stepped portion 19 is formed at one side of the lens holder 11 so that the spring 16 fitted to the outer surface of the lens holder 11 is supported by the stepped portion 19. In addition, the outer surface of one side 17 of the frame 6 and the inner surface of the cap lens 18 are formed with screw-shaped fastening grooves 20 and 21, respectively, so that the cap lens 18 and the cap lens 18 are rotated. One side 17 of the frame 6 is fastened and fixed.

After the combination of the lens assembly (2) and the charge coupling device assembly (3) coupled through the above process to the frame base (7), the spring clip (23) in the clip groove 22 formed on one side of the frame (6) ), One side of the screw (5) of the knob adjusting device (4) is fitted into the through hole (8) formed in any one of the support 24 of the left and right support of the frame base (7), knob adjustment The other side of the screw 5 of the device 4 is forcibly fitted into the engaging groove 9 formed in the other support 25 of the frame base 7. Here, the detailed structure of the coupling groove 9 corresponds to the essential point of the present invention and will be described in detail later.

Meanwhile, the lamp assembly 27 is assembled by inserting the lamp board 27 into the reflector 26 and inserting at least one lamp 29 into the through hole 28 of the reflector 26. Then, the assembled lamp assembly 1 is fitted to the bottom of the cover lower 30, and the frame base 7 assembly (lens assembly 2 and the charge coupling device assembly 3) is assembled into the lamp assembly. (1) is coupled to the upper end of the fastening and fastening with a fastening member (31).

When the assembly process is completed, the tilt deviation correction operation of the scanner module is performed, and then the cover upper (Cover Upper) 32 is coupled to the cover lower 30, and the label 33 is attached to a predetermined position. Is complete.

On the other hand, the structure of the support 24, 25 of the knob adjustment apparatus 4 and the frame base 7 is demonstrated in detail.

According to the first embodiment of the present invention, as shown in FIG. 5, one side of the coupling groove 9 formed on the other support 25 of the frame base 7 has a cylindrical shape, and the other side of the coupling groove 9 is provided. That is, at the point close to the opening, a straight pressing portion 34 extending from the above circumference is processed. In addition, the stepped portion 10 is formed at the end of the pressing portion 34 to prevent the detachment of the screw 5 coupled to the coupling groove 9. A coupler 35 is formed in which the region extends from the step 10 to the outer surface direction of the support 25. When the screw 5 of the knob adjusting device 4 to be coupled to the coupling hole 35 of the coupling groove 9 having such a structure is pressed and pushed in the direction of the step 10 of the coupling groove 9, the plastic The screw 5 of the knob adjusting device 4 is coupled to the coupling groove 9 by the self-elasticity of the support 25 made of a material having self-elasticity, and the like, and the frame 6 is moved by the pressing portion 34. It is pressurized in the direction to be coupled and fixed without flowing in the coupling groove 9.

Thereby, the screw thread processed to the screw 5 of the knob adjusting device 4 and the screw thread of the frame 6 come into close contact with each other so that the backlash hardly occurs (see FIG. 6). In this state, when the knob adjusting device 4 is rotated in a predetermined direction, the screw thread formed on the screw 5 of the knob adjusting device 4 and the screw thread of the frame 6 are in close contact with each other. It does not flow, and the frame 6 is rotated by a displacement corresponding to the amount of rotation of the knob adjusting device 4.

For example, as shown in FIG. 7, when the knob adjusting device 4 is rotated in the 'a' direction, the frame 6 rotates in the direction shown at the bottom of FIG. 7, and the knob adjusting device 4 is rotated as 'b'. Rotation in the 'direction rotates the frame 6 in the direction shown at the top of FIG.

Therefore, no backlash occurs between the thread formed in the screw 5 of the knob adjusting device 4 and the thread of the frame 6 so that the frame 6 rotates as much as the operation displacement of the knob adjusting device 4. Therefore, the correction of the slope deviation is performed correctly.

On the other hand, the knob adjusting device coupling structure of the present invention may be applied to the second embodiment as shown in FIG.

That is, referring to FIG. 8, one side of the coupling groove 9 formed in the other support 25 of the frame base 7 has a cylindrical shape, and the other side of the coupling groove 9, that is, the point close to the step 10. The cylindrical press part 36 which has a curvature smaller than the above circumference is processed. When the pressing portion 36 having such a structure is applied to the apparatus of the present invention, the same result as in the above first embodiment can be obtained. At this time, when processing the shape of the pressing portion 36 in the circumferential shape, the contact area between the pressing portion 36 and the knob adjusting device 4 is increased, the pressing effect is improved.

Meanwhile, in the detailed description of the present invention, specific embodiments have been described, but various modifications are possible without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined by the claims below and equivalents thereof.

As a result, according to the combined structure of the knob adjustment device for tilt deviation correction of the shuttle scanner according to the present invention, there are the following advantages.

(1) The coupling state of the screw of the knob adjusting device and the thread of the frame is formed by forming a pressurizing portion for pressing the knob adjusting device so that the screw of the knob adjusting device and the thread of the frame come into close contact with the frame groove where the knob adjusting device is engaged. Since backlash does not occur in the frame, the frame rotates in response to the adjustment displacement of the knob adjustment device so that accurate tilt deviation correction can be performed. As a result, the reliability of the product is improved.

(2) It is very efficient because backlash can be removed without the need for additional parts.

Claims (3)

A knob adjusting device including a screw threaded at a predetermined position to be engaged with a screw threaded in the charge-coupled device assembly, and a frame base having a pair of supports formed to support the knob adjusting device, wherein one side of the screw In the shuttle-type scanner module coupled to the through-hole formed in any one of the pair of supports, the other side of the screw is coupled to the coupling groove formed in the other one of the pair of supports and having an opening on one side: Opposite points of the opening formed in the coupling groove have a circumferential shape, and a point adjacent to the opening formed in the coupling groove includes a screw thread of the screw coupled to the coupling groove processed in the charge coupling device assembly. And a pressurizing portion for pressing the screw toward the charge-coupled device assembly to be engaged in a pressurized state. The method of claim 1, wherein the pressing unit, The coupling mechanism for adjusting the tilt deviation of the shuttle scanner, characterized in that the point adjacent to the opening in contact with the screw is processed in a straight line extending from the circumference. The method of claim 1, wherein the pressing unit, Combination structure of the tilt control device for adjusting the tilt deviation of the shuttle scanner characterized in that the point adjacent to the opening in contact with the screw extends from the circumference and is processed into a circumference having a small curvature compared to the circumference.

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