JP2955169B2 - Optical system drive - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical system driving apparatus provided for an optical system in which a light source lamp unit of a copying machine or the like and a mirror base unit are driven at a predetermined speed ratio.

[0002]

2. Description of the Related Art A conventional optical system driving apparatus for a fixed platen type copying machine is disclosed in, for example, Japanese Patent Application Laid-Open No. 3-242634, which uses a rack gear for driving a light source (lamp) unit and a mirror base unit. And a pinion gear, a combination of a two-stage planetary gear having a different diameter and an idle gear between a fixed rack gear and a movable rack gear increases the size (thickness) of the driving device, and further increases the light source unit and the mirror base unit. Since there is no means for securely holding the camera, blur during driving is generated.

[0003] As described in Japanese Patent Application Laid-Open No. 1-100527, a wire is used for driving the light source unit and the mirror base unit, but a guide shaft provided in parallel to the side of the wire drive unit. This suppresses the occurrence of blur and vibration.

[0004]

With the above-mentioned wire-driven optical system driving apparatus which has been widely used, the wire tensioning operation is complicated, so that it takes time not only for assembling in a factory or for maintenance work, but also for the optical system. As the scanning is repeated, the wire elongates due to aging, resulting in distortion of the copied image. On the other hand, in the optical system driving device using the pinion gear and the rack gear, no elongation occurs even when the optical system scanning is repeated, and the image quality at the beginning of production can be maintained more permanently.

However, in the optical system scanning means using a pinion gear and a rack gear, the pinion gear rotates on the rack gear. Except for the rack gear fixed to the rack gear, a force to float up from the rack gear also acts. Therefore, if there are factors such as external force, drive transmission unevenness, distortion, torsion, and warpage of the rack gear, the pinion gear floats and generates vibrations and vibrations from the rack gear.

In a conventional optical system driving device, a light source unit and a mirror base unit are supported by a guide shaft, and a rack gear or a pinion gear is provided at a position distant from the guide shaft, generally on the side or oblique side of the guide shaft. Are arranged individually. In this case, when the pinion gear attempts to float due to drive transmission unevenness or the like, the pinion gear floats with the shaft as a support, causing blurring.

[0007] The lifting of the pinion gear during driving also occurs in a portion transmitting from the drive transmission gear of the drive unit on the main body side to the rack of the optical system scanning means. That is, the rack gear is mounted on the mirror base unit, and the rack floats around the guide shaft as a fulcrum.

There is also a mechanism in which a light source unit and a mirror base unit are supported by two guide shafts through one guide shaft on each side of the optical system scanning means. In this case, the respective guide shafts are separate. In addition to fixing with the fixing bracket, the work is performed separately on each side during the work.

[0009]

According to the present invention, there is provided a drive transmission gear for transmitting a driving force to an apparatus body, and a movable rack gear for receiving the driving force of the drive transmission gear to move a mirror unit. What is the moving rack gear formation surface?
A moving rack portion integrally provided with a transmission rack gear provided on the other surface for transmitting the moving force of the mirror unit
A first pinion gear that rotates in accordance with the moving force transmitted to the transmission rack gear; and a first pinion gear that is fixed on the same axis as the first pinion gear and moves on a fixed rack gear that is fixed to the frame, and is spaced apart from the first pinion gear by a pitch. An optical system drive having a second pinion gear for driving the light source unit at half the speed of the mirror unit based on the circular diameter ratio, and a guide shaft supporting the light source unit and the mirror unit and arranged in parallel with the fixed rack gear. In the device, the moving rack is mounted on the same section perpendicular to the rotation axis of the drive transmission gear.
And a guide portion , a first pinion gear, and a guide shaft are arranged, and the guide shaft is located above the first pinion gear.

A drive transmission gear for transmitting a driving force to the apparatus body, a moving rack gear for receiving the driving force of the driving transmission gear and moving the mirror unit, and a movable rack gear formation.
The surface is a moving rack integrally provided with a transmission rack gear provided on the other surface for transmitting the moving force of the mirror unit.
And a first pinion gear that rotates in accordance with the moving force transmitted to the transmission rack gear, and moves on a fixed rack gear fixed on the same axis as the first pinion gear and fixed to the frame. Having a second pinion gear for driving the light source unit at half the speed of the mirror unit based on the pitch circle diameter ratio, and a guide shaft supporting the light source unit and the mirror unit and arranged in parallel with the fixed rack gear. In the system drive device,
Move on the same cross section perpendicular to the rotation axis direction of the drive transmission gear
The rack portion and the first pinion gear are respectively arranged, and the axis center of the guide shaft is set between the tooth thickness center section in the rotation axis direction of the first pinion gear and the tooth thickness center section in the second pinion gear rotation axis direction, and the first pinion gear. And above the second pinion gear.

The drive transmission gear for transmitting the driving force to the apparatus main body and the movable rack gear forming surface are provided on the other surface. The movable rack gear for receiving the driving force of the drive transmission gear and moving the mirror unit is provided. Moving rack unit provided integrally
And a transmission rack gear for transmitting the moving force of the mirror unit, a first pinion gear that rotates with the moving force transmitted to the transmission rack gear, and fixed coaxially to the first pinion gear and fixed to the frame. A second pinion gear that moves on the fixed rack gear and drives the light source unit at half the speed of the mirror unit based on the pitch circle diameter ratio with the first pinion gear, and supports the light source unit and the mirror unit and is parallel to the fixed rack gear. An optical system driving device having a guide shaft disposed therein,
Move on the same cross section perpendicular to the rotation axis direction of the drive transmission gear
The rack portion and the first pinion gear are respectively arranged, and the axis center of the guide shaft is set between the tooth thickness center section in the rotation axis direction of the first pinion gear and the tooth thickness center section in the second pinion gear rotation axis direction, and the first pinion gear. , And above and below the second pinion gear.

[0012] The guide shaft is composed of two shafts arranged side by side.
Shaft thickness of the first pinion gear in the rotation axis direction
Center section and tooth thickness center section in the direction of the rotation axis of the second pinion gear
And between the first pinion gear and the second pinion gear.
When the point located above is used as the reference point, two guides
The shaft center of the shaft is the position of the shaft center of the two guide shafts.
And the reference point are arranged so that their distances are substantially the same .

A drive transmission gear for transmitting a driving force to the apparatus body, a movable rack gear for receiving the driving force of the drive transmission gear to move the mirror unit, and a movable rack gear forming surface;
Is a moving rack part provided on the other surface and integrally provided with a transmission rack gear for transmitting the moving force of the mirror unit.
A first pinion gear that rotates in accordance with the moving force transmitted to the transmission rack gear; and a first pinion gear that is fixed on the same axis as the first pinion gear and moves on a fixed rack gear that is fixed to the frame, and is spaced apart from the first pinion gear by a pitch. A second pinion gear that drives the light source unit at half the speed of the mirror unit based on the circular diameter ratio; and two guide shafts that support the light source unit and the mirror unit and are arranged in parallel with the fixed rack gear. In the optical system driving device, on the same cross section perpendicular to the rotation axis direction of the drive transmission gear,
The moving rack portion and the first pinion gear are respectively arranged, and a straight line connecting the axis centers of the first pinion gear and the second pinion gear is defined as a reference straight line. When a point between the pinion gear and the tooth thickness center section in the rotation axis direction is a reference point, and a straight line obtained by rotating the reference straight line by a predetermined angle around the reference point is a second reference straight line, each of the two guide shafts The axis centers are arranged on the second reference straight line, and the distance between each axis center position and the reference point is substantially the same.

[0014]

[Action] optical system driving device according to the present invention includes a driving Doden our gears,
The mirror unit is moved by driving the drive transmission gear .
Moving the rack gear, heat transfer is reached Den the moving force of the mirror unit
Reaches rack gear, and move that has been transmitted to the transmission Rakkugi ya
Rotates with the power, the first pinion to leave create a speed ratio of the counterpart of the light source unit and the mirror base unit 4
The gears are arranged on the same line, and the lift of each gear can be held down by the guide shaft.

[0015]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A basic optical system driving device according to the present invention has a schematic configuration as shown in FIG. 1. First, a main drive is a movable rack gear movable inside the optical system from a drive transmission gear 2 of a clutch unit 1. 3 is transmitted to the lower gear 3a, and the transmitted driving force is transmitted from the upper gear 3b of the rack gear 3 to the first pinion gear 4. The lower gear 3a of the movable rack gear 3 corresponds to the movable rack gear means of the present invention, the upper gear 3b corresponds to the transmission rack gear means of the present invention, and the movable rack gear 3 corresponds to the movable rack section . As shown in FIG. 2, the first pinion gear 4 is fixed on the second pinion gear 5 and a two-stage gear or on the same axis 6, and when the first pinion gear 4 is driven, it is necessarily driven integrally. The light source unit 8 moves by itself along the fixed rack gear 7, and moves. The moving ratio between the light source unit 8 and the mirror unit 9 is the first pinion gear 4 and the second pinion gear 4.
It is determined by the pitch circle diameter ratio with the pinion gear 5.

[0016] To explain an embodiment of the device with reference to the accompanying drawings, first, in FIG. 3, FIG. 1, the same parts of FIG. 2 when indicated by the same reference numerals, when the light source unit 8 and the mirror unit 9 is scanned In these light source units 8
And a guide shaft 10 which supports the mirror unit 9 and is arranged in parallel with the fixed rack gear 7, and which is one of the drive transmission gear 2, the movable rack gear 3 and the two-stage gear of the clutch unit 1 in the right angle direction. The pinion gear 4 is located above an imaginary straight line 11 passing through the center of each pinion gear 4.

Each gear in FIGS. 3 to 9 is represented by a pitch circle. By arranging the guide shaft 10 on the center of the drive transmission gear 2, the wobbling and floating of each gear are minimized, and finally, the optical system works effectively against blurring. .

Next, in FIG. 4, the first pinion gear 4 and the second pinion gear 5 are not divided into two-stage gears as described above, but are divided and fixed on the same shaft 6. Also in this configuration, the guide shaft 10 is positioned above a virtual straight line 11 passing through the centers of the drive transmission gear 2, the movable rack gear 3 and the first pinion gear 4. By arranging the guide shaft 10 on the center of the drive transmission gear 2 in the same manner as described above, the wobble and floating of each gear can be minimized, and finally the optical system can be effectively prevented from blurring. It works.

Next, in FIG. 5, on the imaginary straight line 11 passing through the centers of the drive transmission gear 2, the movable rack gear 3 and the first pinion gear 4 which is one of the two-stage gears, and the center of the second pinion gear 5 Virtual line 1 passing through
The guide shaft 10 is located between the first pinion gear 4 and the second pinion gear 5. That is, the virtual straight line 1 passing through the center of the guide shaft 10
Distance X ₁ from the top of 1 ”to the virtual straight lines 11 and 11 ′
And X ₁ ′ are substantially equal.

Assuming that the center of the second pinion gear 5 is farther from the center of the first pinion gear 4 in a two-stage gear type, the center shaft fluctuates around the guide shaft 10 and the floating is amplified. The position of the shaft 10 is determined by the first pinion gear 4 and the second pinion gear 5.
Is set at the middle position of the center of the tooth thickness of the above, that is, the position of the distance X ₁ ≒ X ₁ ′ , so that the above-mentioned inconvenience can be minimized.

Next, in FIG. 6, the first pinion gear 4
In a modification of the optical system driving device shown in FIG. 5 in which the second pinion gear 5 and the second pinion gear 5 are not two-stage gears, the guide shaft 10 is not above the first pinion gear 4 but on a virtual straight line 11 passing through the center of the first pinion gear 4. The imaginary straight line 1 ′ is located between the imaginary straight line 11 ′ passing through the center of the second pinion gear 5 and above the first pinion gear 4 and the second pinion gear 5.
1 and 'distance X ₂ and X ₂ from' the 11 is positioned at approximately equal.

Next, in FIG. 7, since each of the above embodiments has only one guide shaft 10, it is inevitable that the guide shaft 10 is swung in a pendulum type around the guide shaft 10. Therefore, two guide shafts are provided vertically and vertically. In this case, the first pinion gear 4 and the second pinion gear 5 are of a type fixed on the same shaft 6, and the intermediate position of the center of each tooth thickness, that is, the distance X ₂ , X ₂ ′ is X ₂ ≒ X ₂ ′. And the shaft 6 to which the first pinion gear 4 and the second pinion gear 5 are fixed.
Two guide shafts 10a, 10
b is positioned so that it passes through the center.

Next, in FIG. 8, the first pinion gear 4
And the second pinion gear 5 are of a two-stage gear type.
The two guide shafts 10a and 10b
5 are aligned in parallel with the axis 6 to which the
The distances X ₃ , X ₃ ′ from the virtual straight line 11 ″ joining the pinion gear 4 and the second pinion gear 5 to the virtual straight lines 11, 11 ′ of the guide shafts 10 a, 10 b are located at X ₃ ≒ X ₃ ′. 1 pinion gear 4 and 2nd pinion gear 5
Are positioned so that the centers of the two guide shafts 10a and 10b pass in a direction perpendicular to the axis 6 to which the shaft 6 is fixed.

Specifically, the guide shafts 10a, 10a
Assuming that the diameter of b is Z , X ₃ + X ₃ ′> Z is inevitable. However, if the distance between the guide shafts 10a and 10b is short, there is no strength, so it is necessary to further increase the distance. Depending on the material of the frame supporting the guide shafts 10a and 10b, if it is a general iron material (such as SPCC),
It is considered to be at least about three times the plate thickness t. Therefore, X ₃ + X ₃ ′> Z + 3t. On the other hand, if X ₃ + X ₃ ′ is too large, it is difficult to perform the assembling operation. Therefore, it can be determined that a point (about 150 mm) that fits in one hand is one limit point. That is, 150> X ₃ + X ₃ ′> Z + 3t.

Further, in FIG. 9, two guide shafts 10a and 10a are provided as in the embodiment shown in FIGS.
0b, but the first pinion gear 4 and the second pinion gear 5 are two-stage gears, and a certain angle a ° or a ′ ° with respect to the shaft 6 to which the two-stage gears 4 and 5 are fixed. It is set to be located with. At this time, the angle a ° is a ° ≒ a ′ °, and 0 ° <a ° <9.
0 °.

The closer the angle a ° is to 90 °, the more
The height direction of the optical system scanning unit increases, and the depth direction of the optical system scanning unit increases as the angle a ° approaches 0 °. Therefore, to minimize the height and depth of the unit, the angle a °
Desirably, it is set to ≒ 45 °.

The distance between the guide shafts 10a and 10b is inevitably X ₃ + X ₃ ′> Z, where Z is the diameter of the guide shafts 10a and 10b. If the distance between them is short, there is no strength, so it is necessary to further increase the distance. Although it depends on the material of the frame supporting the guide shafts 10a and 10b, it is considered that a general iron material (such as SPCC) should secure at least about three times the plate thickness t. Therefore, X ₄ + X ₄ ′> Z + 3t. On the other hand, if X ₄ + X ₄ ′ is too large, it is difficult to perform assembling. Therefore, it can be determined that a limit (about 150 mm) that fits in one hand is one limit point. Further, a first pinion gear 4 and a second pinion gear 5 are also provided between the guide shafts 10a and 10b. If the total thickness of these is Y, 150> X ₄ + X ₄ ′> Z + 3t + Y
Is desirable.

[0028]

In the optical system driving apparatus according to the present invention, the guide shaft 10 is disposed above the drive transmission gear 2, the movable rack gear 3, and the first pinion gear 4 where the driving unit is concentrated. by the movement rack gear 3, the first peak
This prevents floating of the nonion gear 4 to prevent blur and vibration.

According to the second aspect, the drive unit is concentrated by the drive transmission gear 2, the movable rack gear 3, and the first pinion gear 4. On the other hand, the light source unit 8 is fixed by the fixed rack gear 7 meshing with the second pinion gear 5. since the drives the second pinion gear 5 in the configuration of the first aspect
Floating and rattling cannot be prevented. So, drive
Transmission gear 2, moving the rack gear 3, moth between the first pinion gear 4 parts of the second pinion gear 5, the fixed rack gear 7 parts
And the drive shaft 2 is moved.
The rack gear 3, the first pinion gear 4, the second pinion gear 5, and the fixed rack gear 7 prevent blurring and vibration of both parts.

In the third aspect, the drive transmission gear 2, the moving rack gear 3, the first pinion gear 4 and the second pinion gear are provided .
Anion gear 5, by disposing the guide shaft 10 upward and downward between the fixed rack gear 7 parts, without even touching in the longitudinal direction about the guide shafts <br/> DOO 10, also thin suppressed height Can be provided.

[0031] In claim 4, the first pinion gear 4, equidistant relative to a point between the second pinion gear 5 2
By disposing the guide shafts 10a and 10b,
In addition to the lifting of the gear portion, the optical system prevents the light source unit 8 and the mirror unit 9 from being distorted, the drive transmission gear 2 and the fixed rack gear 7 from being twisted and distorted, and prevents the entire optical system from being shaken or vibrated.

[0032] In claim 5, the first pinion gear 4, between the second pinion gear 5, the first pinion gear 4, etc equiangularly based on the center of the axis 6 of the second pinion gear 5
By arranging the two guide shafts 10a and 10b at a distance , the height, the left and right (front and rear) directions of the apparatus are suppressed, and blurring and vibration are reliably prevented as described above.

[Brief description of the drawings]

FIG. 1 is a side sectional view of a basic optical system driving device of the present invention.

FIG. 2 is a perspective view showing an example of meshing between a pinion gear and a rack gear of the present apparatus.

FIG. 3 is a cross-sectional view of one embodiment in the case of one guide shaft in the present apparatus.

FIG. 4 is a cross-sectional view of another embodiment in which one guide shaft is used in the present apparatus.

FIG. 5 is a cross-sectional view of another embodiment in the case of one guide shaft in the present apparatus.

FIG. 6 is a cross-sectional view of another embodiment in the case of one guide shaft in the present apparatus.

FIG. 7 is a cross-sectional view of an embodiment of the present apparatus when two guide shafts are used.

FIG. 8 is a cross-sectional view of another embodiment in which two guide shafts are used in the present apparatus.

FIG. 9 is a cross-sectional view of another embodiment in which two guide shafts are used in the present apparatus.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Clutch unit 2 Drive transmission gear 3 Moving rack gear 4 1st pinion gear 5 2nd pinion gear 7 Fixed rack gear 8 Light source unit 9 Mirror unit 10 Guide shaft

──────────────────────────────────────────────────続 き Continued on the front page (58) Field surveyed (Int.Cl. ⁶ , DB name) G03B 27/50

Claims (5)

(57) [Claims] 1. A drive transmission gear for transmitting a driving force to an apparatus body, a moving rack gear for receiving a driving force of the driving transmission gear to move a mirror unit, and a moving rack gear forming surface.
Is a movable rack provided on the other surface and integrally provided with a transmission rack gear for transmitting the moving force of the mirror unit.
A first pinion gear that rotates with the moving force transmitted to the transmission rack gear; a fixed pinion gear that is fixed coaxially with the first pinion gear and that is fixed to a frame; The pitch circle diameter ratio of
A second pinion gear that drives the Stanislaus Lo Kuang source units 1 a rate half of the mirror unit, optical having a light source unit and the fixed guide shaft disposed in parallel with the rack gear supporting said mirror unit, the In the system driving device, the moving rack unit , the first pinion gear,
An optical system driving device, wherein a guide shaft is arranged, and the guide shaft is located above the first pinion gear. 2. A drive transmission gear for transmitting a driving force to an apparatus main body, a movable rack gear for receiving a driving force of the drive transmission gear to move a mirror unit, and a movable rack gear forming surface.
Is a movable rack provided on the other surface and integrally provided with a transmission rack gear for transmitting the moving force of the mirror unit.
A first pinion gear that rotates with a moving force transmitted to the transmission rack gear; a first pinion gear that is fixed on the same axis as the first pinion gear and moves on a fixed rack gear that is fixed to a frame; The pitch circle diameter ratio of
A second pinion gear that drives the Stanislaus Lo Kuang source units 1 a rate half of the mirror unit, optical having a light source unit and the fixed guide shaft disposed in parallel with the rack gear supporting said mirror unit, the In the system drive device, the moving rack portion and the first pinion gear are arranged on the same cross section perpendicular to the rotation axis direction of the drive transmission gear, and the center of the guide shaft is set to the first pinion gear.
An optical system drive, which is disposed between the center section of the tooth thickness in the rotation axis direction of the pinion gear and the center section of the tooth thickness in the direction of the second pinion gear rotation axis and above the first pinion gear and the second pinion gear. apparatus. 3. A drive transmission gear for transmitting a driving force to an apparatus main body, a movable rack gear for receiving a driving force of the drive transmission gear to move a mirror unit, and a movable rack gear forming surface.
Is a movable rack provided on the other surface and integrally provided with a transmission rack gear for transmitting the moving force of the mirror unit.
A first pinion gear that rotates with a moving force transmitted to the transmission rack gear; a first pinion gear that is fixed on the same axis as the first pinion gear and moves on a fixed rack gear that is fixed to a frame; The pitch circle diameter ratio of
A second pinion gear that drives the Stanislaus Lo Kuang source units 1 a rate half of the mirror unit, optical having a light source unit and the fixed guide shaft disposed in parallel with the rack gear supporting said mirror unit, the In the system drive device, the moving rack portion and the first pinion gear are arranged on the same cross section perpendicular to the rotation axis direction of the drive transmission gear, and the center of the guide shaft is set to the first pinion gear.
It is characterized in that the pinion gear is disposed between the center section of the tooth thickness in the rotation axis direction and the center section of the second pinion gear in the rotation axis direction, and above and below the first pinion gear and the second pinion gear, respectively. Optical system drive. 4. The guide shaft is composed of two shafts arranged side by side, and is arranged between a center section of the first pinion gear in the direction of the rotation axis and a center section of the second pinion gear in the direction of the rotation axis. In addition, when a point located above the first pinion gear and the second pinion gear is set as a reference point, the axis center of the two guide shafts is defined by the axis center position of the two guide shafts and the reference point. The optical system driving device according to claim 2, wherein the optical system driving device is arranged so that the distances are substantially the same. 5. A drive transmission gear for transmitting a driving force to an apparatus main body, a moving rack gear receiving a driving force of the driving transmission gear to move a mirror unit, and a moving rack gear forming surface.
Is a movable rack provided on the other surface and integrally provided with a transmission rack gear for transmitting the moving force of the mirror unit.
A first pinion gear that rotates with a moving force transmitted to the transmission rack gear; a first pinion gear that is fixed on the same axis as the first pinion gear and moves on a fixed rack gear that is fixed to a frame; The pitch circle diameter ratio of
A second pinion gear that drives the Stanislaus Lo Kuang source units 1 a rate half of the mirror unit, and two guide shafts supporting said light source unit and the mirror unit is arranged in parallel with the fixed rack gear, the In the optical system driving device having, on the same cross section perpendicular to the rotation axis direction of the drive transmission gear,
The moving rack portion and the first pinion gear are arranged, respectively, a straight line connecting the axis centers of the first pinion gear and the second pinion gear is a reference straight line, and the tooth thickness of the first pinion gear in the rotational axis direction on the reference straight line. When a point between the central section and the tooth thickness center section in the rotation axis direction of the second pinion gear is a reference point, and a straight line obtained by rotating the reference straight line by a predetermined angle around the reference point is a second reference straight line. An optical system drive wherein the center of each axis of the two guide shafts is arranged on the second reference straight line, and the distance between the center of each axis and the reference point is substantially the same. apparatus.