JP2006001703A - Positioning device of adjustment part and paper transport apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To solve the problems that in assembling, the positioning adjustment work is always needed to impair the assembling work efficiency because the adjusting part fitted to a counterpart is adjustable in its fixing position. <P>SOLUTION: A positioning boss 21 and a screwing boss 22 are projected on a base frame 6, and the adjusting part 8 is provided with an adjusting elongated hole 14a for freely movably guiding the positioning boss 21 and the screwing boss 22 in the paper transport direction Y and a guide 16B for the screwing boss when it is fitted in the mount attitude in positioning adjustment, and provided with a positioning hole 13a engaged with the positioning boss 21 and a screwing boss guide 16A for freely movably guiding the screwing boss 22 in the paper transport direction Y in the case of mount attitude in default where the adjusting part 8 is turned by 180 degrees round the central axis M relative to the mount attitude in positioning. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a technology of a positioning device for adjusting parts.

In a paper transport device such as a recording paper transport device in a printer or a document transport device in a scanner, a paper transport path is used to prevent skew and wrinkles of the transported paper (recording paper or original). The accuracy of the support position of the shaft of each roller provided along is required. The skew of the paper occurs because the roller shaft is not supported by the main body so that the axial direction of the roller shaft is exactly perpendicular to the paper transport direction. By being sent out in the direction deviated from the direction. Further, if the parallelism between the roller shafts is slightly different, wrinkles may occur on the conveyed paper.
Patent Document 1 discloses an apparatus that performs positioning so that the axes of rollers provided in separate apparatuses are parallel when an optional paper feed cassette apparatus is connected to the printer body. Yes.

Like the roller shaft, a component that requires high positioning accuracy in one direction (in the case of the roller shaft, in the paper conveyance direction) is fixed to a mating component such as a frame so that its supporting position can be adjusted. .
For example, in the case of a roller shaft, it is attached to the frame on the main body side through attachment adjusting parts that also function as bearings at both ends thereof. And this adjustment component is fixed by fastening of a screw.
In addition, for example, a long hole through which the screw shaft is inserted is formed in the adjustment component along the sheet conveyance direction, and the attachment position of the adjustment component on the frame is variably configured.
If the roller shaft is supported by the adjustment component and positioned on the frame, the support position of the roller shaft is indirectly adjusted by adjusting the fixing position of the adjustment component with respect to the frame.
JP-A-7-257762

  However, for example, if the fixing position of the adjustment component for supporting the roller shaft is variably configured with respect to the counterpart component such as the frame, positioning adjustment work is always required during assembly. When the component accuracy is high, there are many cases where there is no problem even if the configuration is positioned by default. Therefore, if positioning adjustment work is always required during assembly, assembly workability is impaired.

  In other words, the problem to be solved is that the adjustment part to be attached to the counterpart part is configured so that its fixed position can be adjusted, so that positioning adjustment work is always required at the time of assembly, which impairs assembly workability. Is a point.

  The problem to be solved by the present invention is as described above. Next, means for solving the problem will be described.

That is, in claim 1,
Adjustment parts,
A mating part to which this adjustment part can be detachably attached in one direction of attachment,
Fixing means for fixing the adjustment part to the counterpart part;
With
The mounting position of the adjustment part with respect to the counterpart part is variably configured in one adjustment direction,
The adjustment part is fixed to the counterpart part at any attachment position by the fixing means.
A positioning device for adjusting parts,
For other parts
A positioning boss,
Auxiliary boss, which has a shorter projection length than the positioning boss,
Formed in parallel with the mounting direction,
Adjustment parts include
When the adjustment part is attached to the counterpart part in a certain posture,
A positioning boss guide and a first auxiliary boss guide are provided to guide the positioning boss and auxiliary boss so that they can move in the same direction.
The adjustment component is movable in the adjustment direction,
When the adjustment component is rotated 180 degrees around the attachment direction with respect to the certain posture,
A positioning hole that engages the positioning boss;
A second auxiliary boss guide for guiding the auxiliary boss in a movable manner in the adjustment direction;
Is provided.

In claim 2,
The fixing means includes
A thread groove formed in the auxiliary boss;
A screw that is fastened to the screw groove of the auxiliary boss via an adjustment component;
Consisting of
In the adjustment part,
In a portion overlapping with the positioning hole and the positioning boss guide,
A screw insertion hole for exposing the screw groove is formed regardless of the movement of the adjustment component in the adjustment direction.

In claim 3,
A paper conveying device comprising the adjusting device positioning device according to claim 1,
The counterpart part is a frame on which a roller shaft is supported,
The adjustment component is a support component that supports the roller shaft on the frame.

  As effects of the present invention, the following effects can be obtained.

  According to the first aspect of the present invention, although the adjustment part is a single adjustment part, the adjustment part can be attached so as to be immediately positioned on the counterpart part or can be attached so that the positioning adjustment can be performed. Therefore, when positioning adjustment is required, the adjustment component can be attached to the counterpart component so that the positioning adjustment can be performed, and assembly workability is not impaired.

According to a second aspect of the present invention, in addition to the effect of the first aspect, the member related to making the adjustment component movable in the adjustment direction with respect to the counterpart component is a part of means for fixing the adjustment component to the counterpart component. The structure of the positioning device is made compact.
According to the third aspect of the present invention, it is possible to adjust the inclination of the shaft of the roller related to the sheet conveyance, and it is also possible to assemble without position adjustment giving priority to the assemblability at the time of assembling.

An embodiment of the present invention will be described with reference to the drawings.
In the present embodiment, in an ADF (automatic document feeder) 1 which is one of paper feeders, a roller shaft positioning device constituting a paper feeder provided in the ADF 1 is used. The ADF 1 itself provided with this positioning device is also the present embodiment.

FIG. 1 shows an ADF (automatic document feeder) 1 for feeding a document to a sheet feed type scanner.
In FIG. 1, an ADF 1 is attached to a platen cover 32 that can be opened and closed on a scanner main body 31. A document tray 33 for supplying the document 30 to the ADF 1 is attached to the ADF 1, and a discharge tray 32 a for documents discharged from the ADF 1 is formed on the upper surface of the platen cover 32.
Inside the ADF 1, a paper conveyance path from the document tray 33 to the discharge tray 32a is formed. Various rollers are provided along the paper conveyance path, and the paper 30 is conveyed by driving these rollers.
Note that in this specification, the term “paper” includes both a document to be read by a scanner and a recording paper to be printed by a printer.

As shown in FIG. 1, the ADF 1 is provided with an upper cover 2 that can open and close an internal paper conveyance path.
Various rollers for transporting the paper 30 along the paper transport path are provided on the paper transport path side of the upper cover 2. Among these various rollers, a roller shaft 4 (illustrated in FIG. 2) of the rollers 3 and 3 is provided with a positioning device 5 for positioning in the paper transport direction. Then, the axes 30 of the rollers 3 and 3 are arranged correctly perpendicularly to the sheet conveying direction so that the document 30 conveyed in contact with the rollers 3 and 3 is conveyed without being skewed. ing.

The upper cover 2 is configured by combining a base frame 6 positioned outside the ADF 1 in a closed state and a cover frame 7 provided closer to the paper conveyance path than the base frame 6, and has a hollow casing. It is.
The roller shafts 4 of the rollers 3 and 3 are also arranged between the base frame 6 and the cover frame 7 so that a part of the rollers 3 and 3 protrudes from the opening formed in the cover frame 7 to the paper conveyance path side. The roller shaft 4 is supported by the base frame 6.

A schematic configuration of the positioning device 5 will be described with reference to FIG.
As described above, the roller shaft 4 is configured to be supported by the base frame 6 via the adjustment parts 8 and 8. More specifically, both ends of the roller shaft 4 are supported by the adjustment parts 8. Each adjustment component 8 is fixed to the base frame 6 by screw fastening.
As will be described in detail below, the roller shaft 4 is indirectly positioned on the base frame 6 by positioning the adjustment component 8 with respect to the base frame 6. Therefore, hereinafter, the positioning device 5 is used without distinguishing between a device that positions the roller shaft 4 with respect to the base frame 6 and a device that positions the adjustment component 8 with respect to the base frame 6. Shall.

  In the following description, the sheet conveyance direction Y, which is the direction in which sheets are conveyed in the ADF 1, the axial direction X, which is the axial direction of the roller shaft 4, and the attachment direction Z, which is the direction in which the adjustment component 8 is attached to the base frame 6. The explanation will be given using three directions.

The schematic shape of the adjustment component 8 will be described with reference to FIGS. 3 and 4.
The adjusting component 8 is roughly formed by cutting out a wall constituting one surface in a hollow rectangular parallelepiped, and has five walls that are perpendicular to each other.
In a posture in which the adjustment component 8 is positioned with the open side without a wall downward, the four walls surrounding the side of the adjustment component 8 include a pair of side walls 11L and 11R facing each other and a side wall 11L And connecting walls 12A and 12B for connecting the 11R. The side walls 11L and 11R are formed in a “D” shape.
Between the side walls 11L and 11R, a wall covering the upper side of the adjustment component 8 is divided into three parts, which are a first upper wall 13, a second upper wall 14, and a connection upper wall 15, respectively. The height positions of the first upper wall 13 and the second upper wall 14 are the same, and the connection upper wall 15 is provided at a position higher than these walls.
The connection wall 12A, the side walls 11L and 11R, and the first upper wall 13 are connected, and the connection wall 12B, the side walls 11L and 11R, and the second upper wall 14 are connected.
In this posture, the axis extending through the center of the connection upper wall 15 located at the center of the adjustment component 8 and extending vertically is defined as a center axis M.

The adjustment component 8 is attached to the base frame 6 in such a posture that the open side without a wall faces the base frame 6 side, and there are an attachment method at the time of default and an attachment method at the time of positioning adjustment. .
Although the mounting method will be described in detail later, the attitude of mounting the adjustment component 8 on the base frame 6 differs between the default mounting method and the positioning adjustment mounting method. Specifically, the posture in which the adjustment component 8 is rotated by 180 degrees around the central axis M when mounting at the default is the posture when mounting at the time of positioning adjustment.

Next, attachment of the adjustment component 8 to the base frame 6 will be described with reference to FIGS. 4, 5, and 6.
The adjustment component 8 is attached to the base frame 6 in such a posture that the direction in which the side walls 11L and 11R face each other is parallel to the axial direction X of the roller shaft 4.
As shown in FIG. 5, the base frame 6 is provided with a positioning boss 21 and a screwing boss 22 protruding in parallel at a portion where the adjustment component 8 is attached. Here, the outer diameter of the screwing boss 22 is formed larger than the outer diameter of the positioning boss 21.
Further, the protruding directions of the positioning boss 21 and the screwing boss 22 coincide with the mounting direction Z in which the adjustment component 8 is attached to the base frame 6. The attachment direction Z is orthogonal to the axial direction X.
On the other hand, as shown in FIG. 4, in the adjustment component 8, a positioning hole 13 a that engages with the positioning boss 21 is formed in the first upper wall 13, and the positioning boss 21 can be inserted into the second upper wall 14. An adjustment long hole 14a is formed.
Here, as shown in FIG. 6, the positioning boss 21 has the first upper wall 13 and the positioning boss 21 in a state in which the adjustment component 8 is attached to the base frame 6 due to the projecting length relationship between the positioning boss 21 and the screwing boss 22. Although protruding from the second upper wall 14, the screwing boss 22 does not protrude.

The state shown in FIG. 4 is a case where the default attachment is performed when the adjustment component 8 is attached to the base frame 6.
At this time, the adjustment component 8 is attached to the base frame 6 so that the positioning boss 21 and the positioning hole 13a overlap and the screwing boss 22 and the adjustment long hole 14a overlap as seen from the attachment direction Z.
When the adjustment component 8 is attached to the base frame 6 by the default attachment method, the attachment position is specified, as will be described in detail later. That is, in the case of the default mounting method, the adjustment component 8 is positioned when it is mounted on the base frame 6.

On the other hand, as shown in FIG. 7, the posture of the adjustment component 8 rotated 180 degrees around the central axis M with respect to the default mounting posture is the mounting posture during positioning adjustment.
At this time, when viewed from the mounting direction Z, the positioning boss 21 and the adjustment long hole 14a overlap, and the screwing boss 22 and the positioning hole 13a overlap.
When the adjustment component 8 is attached to the base frame 6 by the attachment method at the time of positioning adjustment, the attachment position can be adjusted in the paper conveyance direction Y, as will be described in detail later. It can be fixed at the point. Therefore, the positioning of the roller shaft 4 supported by the adjustment component 8 in the paper conveyance direction Y can be adjusted. On the other hand, in the default mounting method, the roller shaft 4 is positioned at the default position, and the fixing position of the adjustment component 8 cannot be adjusted. Therefore, the support position of the roller shaft 4 cannot be adjusted.

Here, the structure which supports the roller shaft 4 with the adjustment component 8 is demonstrated.
As described above, the adjustment component 8 functions as a means for supporting the roller shaft 4 with respect to the base frame 6. Further, as described above, the adjusting component 8 can be attached to the base frame 6 in two ways: a default attaching method and a positioning adjusting attachment method.
The adjustment component 8 is provided with a configuration that can support the roller shaft 4 in accordance with these two attachment methods. More specifically, in the adjustment component 8, the portion related to the support of the roller shaft 4 is configured to be point symmetric with respect to the central axis M.

As shown in FIGS. 3, 8, and 9, the side wall 11 </ b> L (11 </ b> R) is formed with a recess 11 a that opens to the base frame 6 side. The concave portion 11 a is a long hole-shaped opening that has a width substantially matching the outer diameter of the roller shaft 4 and is longer along the mounting direction Z than the outer diameter of the roller shaft 4.
The roller shaft 4 is movable in the attachment direction Z within the range of the formation length of the recess 8a, and the movement is restricted in the paper transport direction Y.
A spring is provided between the roller shaft 4 and the base frame 6 via a bearing or the like, and the roller shaft 4 is elastically supported by the base frame 6 in the mounting direction Z.

As shown in FIGS. 8 and 9, the portions where the recesses 11 a are formed in the side walls 11 </ b> L and 11 </ b> R are point-symmetric with respect to the central axis M. In particular, the recesses 11a and 11a of the side walls 11L and 11R are different portions in the paper transport direction Y and do not overlap in the axial direction X. That is, even if the roller shaft 4 is inserted into the adjustment component 8 through the recess 11a along the axial direction X, the roller shaft 4 does not penetrate the adjustment component 8 and is restrained by the side wall 11R (or the side wall 11L). Will be.
Furthermore, on the inner surface (the surface on the side of the central axis M) of the side wall 11L (or the side wall 11R), as seen from the axial direction X, a protruding portion 11b is provided at a portion overlapping the concave portion 11a of the other side wall 11R (or the side wall 11L). Is formed. That is, the roller shaft 4 inserted into the adjustment component 8 more precisely contacts the protruding portion 11b of the side wall 11L (or the side wall 11R), and the penetration from the adjustment component 8 is stopped.
Then, the movement of the roller shaft 4 in the axial direction Y with respect to the base frame 6 is restricted by the adjustment components 8 and 8 disposed at both ends of the roller shaft 4.

The attachment of the adjustment component 8 to the base frame 6 will be described in more detail.
First, a description will be given of a configuration in which the adjustment component 8 is supported by the base frame 6 so as to be movable only in the sheet conveyance direction Y regardless of whether the attachment is a default attachment or a positioning adjustment.

As shown in FIGS. 9 and 6, a screw boss guide 16A including a pair of guide walls 16a and 16a parallel to the side walls 11L and 11R is provided below the positioning hole 13a. Each guide wall 16a is fixed to the first upper wall 13 and the connection wall 12A. The distance between the guide walls 16a and 16a is substantially the same as the outer diameter of the screw boss 22, and the screw boss 22 can be inserted between the guide walls 16a and 16a.
Similarly, a screw boss guide 16B comprising a pair of guide walls 16b and 16b parallel to the side walls 11L and 11R is provided below the adjustment long hole 14a. Each guide wall 16b is fixed to the second upper wall 14 and the connection wall 12B. The distance between the guide walls 16b and 16b is substantially the same as the outer diameter of the screw boss 22 and the screw boss 22 can be inserted between the guide walls 16b and 16b.

In the case of attachment at the default time, the screwing boss 22 of the base frame 6 is inserted between the guide walls 16 b and 16 b of the adjustment component 8. On the other hand, in the case of attachment at the time of positioning adjustment, the screwing boss 22 of the base frame 6 is inserted between the guide walls 16 a and 16 a of the adjustment component 8.
As will be described below, the adjustment component 8 is supported by the base frame 6 at two locations, that is, the positioning boss 21 and the screwing boss 22, and can be moved in the paper transport direction Y, or can be moved and moved itself. It is regulated.
Here, whether it is the attachment at the time of default or the attachment at the time of positioning adjustment, the screwing boss 22 is formed of a pair of parallel guide portions (guide walls 16a and 16a or guide walls) formed on the adjustment component 8. The movement is relatively restricted by 16b and 16b).

Here, the case of attachment at the time of default is demonstrated using FIG.
In the case of the default mounting, as described above, when viewed from the mounting direction Z, the positioning boss 21 and the positioning hole 13a overlap, and the screwing boss 22 and the adjustment long hole 14a overlap. A component 8 is attached to the base frame 6.
The positioning hole 13 a is an opening through which the positioning boss 21 can be inserted, and is a hole having substantially the same diameter as the positioning boss 21. For this reason, when the positioning boss 21 is inserted into the positioning hole 13 a, the movement of the adjustment component 8 is restricted by the positioning boss 21.
More specifically, with only the above configuration, the adjustment component 8 can rotate around the positioning boss 21, but the screwing boss 22 can be moved only in the paper conveyance direction Y by the screwing boss guide 16 </ b> B. Since it is in an allowable state, it does not rotate. That is, the adjustment component 8 is positioned on the base frame 6 by the movement restriction of the screwing boss 22 by the screwing boss guide 16B and the movement restriction of the positioning boss 21 by the positioning hole 13a.
This position is the default position. Since the roller shaft 4 and the adjustment component 8 are integrated in the paper transport direction Y, the position of the roller shaft 4 when the adjustment component 8 is in the default position is also referred to as the default position, and is not particularly distinguished. And

The third position restricting means that functions in the case of default mounting will be described with reference to FIGS. 5, 6, and 10.
As shown in FIGS. 5 and 6, ribs are respectively provided in a cross shape in four directions at the lower portion of the positioning boss 21. In particular, the ribs 17 and 17 projecting toward the side walls 11L and 11R are related to the positioning of the adjustment component 8 with respect to the base frame 6.
On the other hand, as shown in FIG. 10, at the same height as the ribs 17, 17, recesses 16 c that allow the ribs 17 to be inserted are formed in the respective guide walls 16 a. The width of the rib 17 (thickness in the paper transport direction Y) is substantially the same as the opening width of the recess 16c (opening width in the paper transport direction Y).
For this reason, when the default attachment is performed, the ribs 17 are inserted into the recesses 16 c, and the adjustment component 8 is restricted in movement in the paper transport direction Y with respect to the base frame 6.
Note that the movement restriction of the adjustment component 8 by the engagement between the recesses 16 c and the ribs 17 assists the positioning by the engagement between the positioning hole 13 a and the positioning boss 21.

As shown in FIG. 11, when the default attachment is completed, the adjustment component 8 is fixed to the base frame 6 by fastening screws 20.
Here, a screw groove 22a is formed on the axial center of the screwing boss 22, and the screw 20 can be fitted into the screw groove 22a.
In the case of the default mounting, the screwing boss 22 and the adjustment long hole 14a are overlapped when viewed from the mounting direction Z. The width of the adjustment long hole 14a (in the axial direction X) is smaller than the outer diameter of the screwing boss 22 and larger than the inner diameter of the screw groove 22a. The thread groove 22a is exposed from the adjustment long hole 14a.
Therefore, the adjustment component 8 is fixed to the base frame 6 by fastening the screw 20 to the screw boss 22 through the washer 23 having a diameter larger than the width of the adjustment long hole 14a (in the axial direction X).

Moreover, the case of the attachment at the time of positioning adjustment is demonstrated using FIG.
In the case of mounting at the time of positioning adjustment, as described above, when viewed from the mounting direction Z, the positioning boss 21 and the adjustment long hole 14a overlap, and the screwing boss 22 and the positioning hole 13a overlap.
The adjustment long hole 14a is an opening through which the positioning boss 21 can be inserted, and an opening having a width substantially the same as the outer diameter of the positioning boss 21 extends along the paper transport direction Y in the mounted posture at the time of positioning adjustment. Is formed. That is, the adjustment long hole 14a is parallel to the guide walls 16a and 16a.
For this reason, when the attachment at the time of positioning adjustment is performed, the positioning boss 21 is relatively movable along the adjustment long hole 14a.
In the mounting state at the time of the positioning adjustment, the guide walls 16b and 16b are located on the side (in the axial direction X) of the positioning boss 21, but each guide wall 16b is located above the ribs 17 and 17. The height position and the vertical width of the adjustment part 8 of each guide wall 16b are set so as to be positioned. The guide walls 16b and 16b do not interfere with the ribs 17 and 17, and the relative movement of the positioning boss 21 is not restricted by the guide walls 16b and 16b.
Further, when mounting at the time of positioning adjustment is performed, the screwing boss 22 is inserted between the guide walls 16a and 16a, and is regulated so as to be movable only in the paper transport direction Y by the screwing boss guide 16A.
With the above configuration, the adjustment component 8 is restricted to the base frame 6 at two locations (positioning boss 21 and screwing boss 22) so as to be movable only in the paper transport direction Y. Therefore, in the case of attachment at the time of positioning adjustment, the adjustment component 8 is movable only in the paper transport direction Y with respect to the base frame 6.

In the case of attachment at the time of positioning adjustment, the adjustment component 8 is movable in the paper transport direction Y with respect to the base frame 6. Unlike the attachment at the time of default, the adjustment component 8 is not positioned on the base frame 6. Is in a state.
Therefore, the position where the adjustment component 8 should be fixed to the base frame 6 can be adjusted in the paper transport direction Y as necessary.
In the case of the present embodiment, since both end portions of the roller shaft 4 are supported by the adjustment parts 8 and 8, respectively, either one of the adjustment parts 8 is moved along the paper transport direction Y, so that the roller It is possible to adjust the attitude of the shaft 4, that is, the inclination angle with respect to the paper transport direction Y.

When the position where the adjustment component 8 is to be fixed to the base frame 6 is specified, the adjustment component 8 is fixed to the base frame 6 at that position.
Even in the case of attachment at the time of positioning adjustment, the adjustment component 8 can be fixed to the base frame 6 by fastening the screw 20.
In the case of mounting at the time of positioning adjustment, when viewed from the mounting direction Z, the screwing boss 22 and the positioning hole 13a are overlapped. The inner diameter of the positioning hole 13a is smaller than the outer diameter of the screwing boss 22 and larger than the inner diameter of the screw groove 22a. In addition, a screw insertion hole 13b is formed in the first upper wall 13 along the paper transport direction Y in a posture in which the adjustment component 8 is attached so as to overlap the positioning hole 13a. Even if the adjustment component 8 is moved in the paper conveyance direction Y with respect to the base frame 6, the screw groove 22 a is exposed from the screw insertion hole 13 b, and the screw 20 is inserted with the adjustment component 8 interposed between the screw fixing bosses 22. It can be fastened.
In this way, after specifying the position where the adjustment component 8 is to be fixed on the base frame 6, the adjustment component 8 is positioned with respect to the base frame 6 by fixing by fastening the screws 20.

In the present embodiment, both ends of the roller shaft 4 are supported by the adjustment component 8 and supported by the base frame 6. However, the roller shaft 4 is supported by the adjustment component 8. It is sufficient that it is at least one of the above. In this case, one of the end portions of the roller shaft 4 is supported by the adjustment component 8 and the other end portion is supported by a simple support component whose support position cannot be adjusted.
This is because in order to adjust the posture of the roller shaft 4 (inclination angle with respect to the paper transport direction Y), it is only necessary to adjust the support position of one end of the roller shaft 4 with respect to the paper transport direction Y. is there.
Even when both ends of the roller shaft 4 are supported by the adjustment component 8, only one adjustment component 8 is actually adjusted, and the other adjustment component 8 is attached at the default time. The fixed position shall not be changed.

The positioning device for adjusting parts of the present invention will be summarized.
The positioning device of the present invention includes an adjustment component, a counterpart component to which the adjustment component is detachably attached in one direction of attachment, and a fixing means for fixing the adjustment component to the counterpart component.
In the present embodiment, the positioning device 5 for the adjustment component 8 that supports the roller shaft 4 is used, and the counterpart component to which the adjustment component 8 is attached is the base frame 6. The fixing means for fixing the adjustment component 8 to the base frame 6 includes a screw groove 22a formed in the screwing boss 22 of the base frame 6, and a screw 20 fitted into the screw groove 22a via the adjustment component 8. It is made up of.

In addition, in the positioning device of the present invention, the attachment position of the adjustment component with respect to the counterpart component is variably configured in one adjustment direction, and the adjustment component is fixed to the counterpart component at any attachment position by the fixing means. This is a configuration.
In the present embodiment, this adjustment direction is set to be the paper transport direction Y in the ADF 1. Further, if the adjustment long hole 14a is within the range of the formation length, the attachment position of the adjustment component 8 with respect to the base frame 6 is adjusted along the paper conveyance direction Y, and the adjustment hole 8a is adjusted at any position within this range. It can be fixed by the screw 20.

In the positioning device of the present invention, the mating part is formed with a positioning boss and an auxiliary boss having a projection length shorter than the positioning boss and projecting in parallel along the mounting direction.
In the present embodiment, a positioning boss 21 and a screwing boss 22 as the auxiliary boss are provided on the base frame 6 so as to protrude in parallel along the mounting direction Z.

In the positioning device according to the present invention, the adjustment component includes a positioning boss guide and a first boss guide for guiding the positioning boss and the auxiliary boss so as to be movable in the same direction when the adjustment component is attached to the counterpart component in a certain posture. An auxiliary boss guide is provided. The adjustment component is movable in the adjustment direction.
In addition, a positioning hole that engages with the positioning boss when the adjustment component is rotated 180 degrees around the attachment direction with respect to the certain posture, and a second auxiliary that guides the auxiliary boss movably in the adjustment direction. And a boss guide.

In the present embodiment, the adjustment component 8 is adjusted to guide the positioning boss 21 so as to be movable in the paper transport direction Y when the adjustment component 8 is mounted on the base frame 6 in the mounting posture at the time of positioning. A long slot 14a and a screwing boss guide 16B as a first auxiliary boss guide for guiding the screwing boss 22 so as to be movable in the paper transport direction Y are also provided. The adjustment component 8 is movable in the paper transport direction Y with respect to the base frame 6.
Further, the adjustment component 8 is provided with a positioning hole 13a that engages with the positioning boss 21 and a screwing boss 22 when the adjustment component 8 is mounted on the base frame 6 in the default mounting posture. A screw boss guide 16A serving as a second auxiliary boss guide that is movably guided in the transport direction Y is provided.
The default mounting posture of the adjustment component 8 is a posture obtained by rotating the mounting posture when positioning the adjustment component 8 by 180 degrees around the mounting direction Z (or the central axis M).

For this reason, if the adjustment component is attached to the counterpart component in a certain posture (the posture at the time of positioning adjustment), the adjustment component can be mounted at a position that is variable with respect to the counterpart component and rotated 180 degrees with respect to the certain posture. If attached in a posture, the adjustment part is immediately positioned when it is attached to the counterpart part.
Therefore, although it is a single adjustment part, it is possible to attach the adjustment part so that it is immediately positioned on the counterpart part, or to be able to adjust the positioning. Therefore, when positioning adjustment is required, the adjustment component can be attached to the counterpart component so that the positioning adjustment can be performed, and assembly workability is not impaired.

In the positioning device of the present invention, the fixing means includes a screw groove formed in the auxiliary boss and a screw fastened to the screw groove of the auxiliary boss via an adjustment component. Further, the adjustment component is formed with a screw insertion hole for exposing the screw groove at a portion overlapping with the positioning hole and the positioning boss guide regardless of the movement of the adjustment component in the adjustment direction.
In the present embodiment, the auxiliary boss for enabling the adjustment part to be attached to the counterpart part in a variable manner in the adjustment direction is the screw boss 22, and this screw boss 22 is a part of the fixing means. As well. The screw insertion hole 13b is formed on the first upper wall so as to overlap the positioning hole 13a so that the screw 20 can be fastened to the screw boss 22 even if the mounting position of the adjustment component 8 on the base frame 6 changes. 13 is formed.
In the case of attachment at the time of default, the screw 20 is fastened to the screwing boss 22 through the adjustment long hole 14a. At this time, the adjustment long hole 14a through which the screw shaft of the screw 20 passes is the screw 20 It is wider than the passing range of the screw shaft. Therefore, the screw insertion hole is included in the adjustment long hole 14a.

  For this reason, the member involved in making the adjustment component movable in the adjustment direction with respect to the counterpart component also serves as a part of means for fixing the adjustment component to the counterpart component, and the configuration of the positioning device is It is made compact.

The sheet conveying apparatus of the present invention includes the positioning device for the adjustment component, and the counterpart component is a frame that supports a roller shaft, and the adjustment component is a support component that supports the roller shaft on the frame.
In the present embodiment, the sheet conveying device is ADF 1, the frame on which the roller shaft 4 is supported is the base frame 6, and the adjustment component 8 is a support component that supports the roller shaft 4 on the base frame 6.

  For this reason, it is possible to adjust the inclination of the shaft of the roller related to the sheet conveyance, and it is also possible to assemble without prior position adjustment, giving priority to the assemblability.

It is a perspective view which shows ADF. FIG. 5 is a view of a roller shaft positioning device as viewed from a direction perpendicular to a paper transport direction. It is a perspective view of an adjustment component. It is a top view of the adjustment component in the attachment state at the time of default. It is a top view which shows the positioning boss | hub and the screwing boss | hub seen from the attachment direction of adjustment components. It is AA sectional drawing of FIG. It is a top view of the adjustment component in the attachment state at the time of positioning adjustment. It is a side view of the adjustment component seen from the axial direction of the roller shaft. It is BB sectional drawing of FIG. It is CC sectional drawing of FIG. It is a top view of the adjustment component of the state fixed by screw fastening.

Explanation of symbols

1 ADF (paper transport device)
4 Roller shaft 6 Base frame (parts)
8 Adjustment part 13a Positioning hole 13b Screw insertion hole 14a Long hole for adjustment (positioning boss guide)
16A Screw boss guide (first auxiliary boss guide)
16B Screw boss guide (second auxiliary boss guide)
20 screws (part of fixing means)
21 Positioning boss 22 Screw boss (Auxiliary boss and part of fixing means)
Y Paper transport direction (adjustment direction)
Z Mounting direction

Claims (3)

Adjustment parts,
A mating part to which this adjustment part can be detachably attached in one direction of attachment,
Fixing means for fixing the adjustment part to the counterpart part;
With
The mounting position of the adjustment part with respect to the counterpart part is variably configured in one adjustment direction,
The adjustment part is fixed to the counterpart part at any attachment position by the fixing means.
A positioning device for adjusting parts,
For other parts
A positioning boss,
Auxiliary boss, which has a shorter projection length than the positioning boss,
Formed in parallel with the mounting direction,
Adjustment parts include
When the adjustment part is attached to the counterpart part in a certain posture,
A positioning boss guide and a first auxiliary boss guide are provided to guide the positioning boss and auxiliary boss so that they can move in the same direction.
The adjustment component is movable in the adjustment direction,
When the adjustment component is rotated 180 degrees around the attachment direction with respect to the certain posture,
A positioning hole that engages the positioning boss;
A second auxiliary boss guide for guiding the auxiliary boss in a movable manner in the adjustment direction;
Is provided,
A positioning device for adjusting parts. The fixing means includes
A thread groove formed in the auxiliary boss;
A screw that is fastened to the screw groove of the auxiliary boss via an adjustment component;
Consisting of
In the adjustment part,
In a portion overlapping with the positioning hole and the positioning boss guide,
A screw insertion hole is formed for exposing the screw groove regardless of the movement of the adjustment component in the adjustment direction.
The positioning device for an adjustment component according to claim 1. A paper conveying device comprising the adjusting device positioning device according to claim 1,
The counterpart part is a frame on which a roller shaft is supported,
The adjustment component is a support component that supports the roller shaft on the frame.
A sheet conveying apparatus characterized by the above.

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