The present application is based on, and claims priority from JP Application Serial Number 2019-015328, filed Jan. 31, 2019, the disclosure of which is hereby incorporated by reference herein in its entirety.
The present disclosure relates to a medium discharging apparatus that discharges a medium, and an image reading apparatus including the medium discharging apparatus.
Some scanners as an example of an image reading apparatus include a medium discharging apparatus that automatically feeds a plurality of media toward a reading unit and discharges the media after being read by the reading unit. The medium discharging apparatus includes a discharge tray for stacking the media read by the reading unit.
For example, JP-A-2010-62839 and JP-A-2018-104154 disclose a scanner including a discharge tray on which read media ejected from the scanner body are stacked.
In the scanner described in JP-A-2010-62839, a document discharge table as a discharge tray includes a front surface cover disposed upstream in a medium discharge direction, and an upper surface cover disposed downstream in the medium discharge direction.
In the scanner described in JP-A-2018-104154, the discharge tray includes a first discharge tray disposed upstream in the medium discharge direction, and a first extension tray, a second extension tray, and a third extension tray that are sequentially disposed downstream in the medium discharge direction.
The scanner discharge tray (document discharge table) disclosed in JP-A-2010-62839, because the tray angle when receiving media is fixed, may cause a stack failure depending on the type of media and the state of the media such as creased or curled. In addition, when the tray angle is fixed, the apparatus size in the medium discharge direction is also fixed.
The scanner discharge tray disclosed in JP-A-2018-104154 can change the angle of the discharge tray when receiving media; however, since the angle of the entire discharge tray is changed, the angle of the first discharge tray on which the front end of the media discharged from the scanner body lands changes. As the inclination of the first discharge tray rising in the medium discharge direction becomes steeper, the medium entry angle with respect to the tray surface increases, and the possibility of media buckling increases.
According to an aspect of the present disclosure, a medium discharging apparatus includes a discharger that discharges a medium from a casing, and a discharge tray including a first tray configured to receive a front end of the medium discharged by the discharger and allow placement of the medium therein, and a second tray that is located downstream of the first tray in a medium discharge direction and configured to allow placement of the medium therein, the discharge tray being configured to switch between a first posture in which the first tray and the second tray form a first angle in a side view in the medium discharge direction, and a second posture in which the first tray and the second tray form a second angle smaller than the first angle without changing the posture of the first tray with respect to the discharger.
Hereinafter, the present disclosure will be schematically described.
A medium discharging apparatus according to a first aspect includes a discharger that discharges a medium from a casing, a discharge tray including a first tray configured to receive a front end of the medium discharged by the discharger and allow placement of the medium therein, and a second tray that is located downstream of the first tray in a medium discharge direction and that is configured to allow placement of the medium therein, the discharge tray being configured to switch between a first posture in which the first tray and the second tray form a first angle in a side view in the medium discharge direction, and a second posture in which the first tray and the second tray form a second angle smaller than the first angle without changing the posture of the first tray with respect to the discharger.
According to this aspect, because the discharge tray is configured to switch between the first posture in which the first tray and the second tray form a first angle in a side view in the medium discharge direction, and the second posture in which the first tray and the second tray form a second angle smaller than the first angle without changing the posture of the first tray with respect to the discharger, it is possible to switch between the first posture and the second posture in accordance with the type and state of the medium or the space where the apparatus is installed.
In this case, because the posture of the first tray with respect to the discharger does not change even if the first posture and the second posture are switched, the entry angle of the front end of the medium discharged by the discharger to a placement surface of the first tray does not change. Therefore, the possibility of buckling of the medium that occurs when the angle of the entire discharge tray is changed can be reduced.
In a second aspect according to the first aspect, the discharge tray is configured to switch between a deployed state that allows placement of the medium can be placed therein and a stored state in which a portion of the casing is covered by the first tray or both the first tray and the second tray.
According to this aspect because the discharge tray is configured to switch between the deployed state in which a medium can be placed therein and the stored state in which a portion of the casing is covered by the first tray or both the first tray and the second tray, for example, when storing the apparatus, the apparatus can be made compact while using the discharge tray in the stored state as a cover for the casing. In addition, the same effect as the first aspect is acquired in the discharge tray in the deployed state.
In a third aspect according to the first aspect or the second aspect, the second tray is configured to be stored in the first tray.
According to this aspect, because the second tray is configured to be stored in the first tray, for example, when the apparatus is not being used or the size of the medium discharged to the discharge tray is small, the second tray can be stored in the first tray, and the apparatus can be arranged in a space-saving manner.
In a fourth aspect according to the third aspect, the second tray includes a sliding shaft that is configured to slide with respect to the first tray in the medium discharge direction and an opposite direction, the first tray includes a guide rail that guides the sliding shaft, and the guide rail has, for positioning the sliding shaft, a first position where the angle of the second tray with respect to the first tray becomes a first angle and a second position where the angle becomes a second angle.
According to this aspect, it is possible to switch between the first posture and second posture of the discharge tray by sliding the sliding shaft of the second tray along the guide rail.
In a fifth aspect according to the fourth aspect, the guide rail includes a holding portion that holds the sliding shaft in one or both of the first position and the second position.
According to this aspect, because the guide rail includes the holding portion that holds the sliding shaft in one or both of the first position and the second position, the posture of the discharge tray can be held.
In a sixth aspect according to any one of the first aspect to the third aspect, the discharge tray is configured to switch between the first posture and the second posture by pivoting of the second tray with respect to the first tray, and the discharge tray includes a locking portion that locks the discharge tray in one or both of the first posture and the second posture.
According to this aspect, it is possible to switch between the first posture and the second posture of the discharge tray and maintain the posture.
In a seventh aspect according to any one of the first to sixth aspects, the second tray is provided with a third tray that can be deployed and stored with respect to the second tray.
According to this aspect, because the second tray is provided with the third tray that can be extended and stored with respect to the second tray, the length of the discharge tray in the medium discharge direction can be further extended.
An image reading apparatus according to an eighth aspect includes a reading unit that reads an image of a medium; and the medium discharging apparatus according to any one of the first to seventh aspects that discharges the medium read by the reading unit.
According to this aspect, in the image reading apparatus including the reading unit that reads the image of the medium and the medium discharging apparatus that discharges the medium read by the reading unit, effects similar to any one of the first to seventh aspects can be obtained.
First, an outline of an image reading apparatus according to an embodiment of the present disclosure will be described with reference to the drawings. In the present embodiment, as an example of the image reading apparatus, a scanner 1 capable of reading at least one of the front surface and rear surface of a medium will be exemplified. The scanner 1 is a so-called document scanner that reads an original such as a document.
In the XYZ coordinate system illustrated in each drawing, the X direction is the apparatus width direction, and the Y direction is the apparatus depth direction. The Z direction indicates the height direction. In addition, the +Y direction corresponds to the front of the apparatus, and the −Y direction corresponds to the rear of the apparatus. In addition, when viewed from the front of the apparatus, the left side is the +X direction, and the right side is the −X direction. In addition, the +Z direction corresponds to the upper side of the apparatus, and the −Z direction side corresponds to the lower side of the apparatus. In addition, the direction in which a medium P is fed is referred to as “downstream”, and the opposite direction is referred to as “upstream”.
Hereinafter, the scanner 1 according to the present disclosure will be described with reference mainly to
The scanner 1 illustrated in
In the present embodiment, an apparatus in which the reading function of the reading unit 5 is omitted from the scanner 1 can also be regarded as the medium discharging apparatus 10.
In the upper rear portion of the casing 2, a supply portion 6 that is a supply port through which the medium P is supplied to the medium transport path R and a feed tray 8 on which the medium P to be supplied from the supply portion 6 can be placed are provided. In addition, a discharging portion 18 that is a discharge port through which the medium P is discharged after being read by the reading unit 5 and the discharge tray 20 that receives the medium P discharged from the discharging portion 18 are provided at a lower front portion of the casing 2. The medium P after being read by the reading unit 5 is discharged from the discharging portion 18 to the discharge tray 20 by a discharge roller pair 17 (
As illustrated in
The scanner 1 is configured to switch between a stored state in which both the feed tray 8 and the discharge tray 20 cover a portion of the casing 2 as illustrated in
Because the feed tray 8 and the discharge tray 20 can be folded and stored, for example, when the scanner 1 is not being used, the apparatus can be made compact while using the feed tray 8 and the discharge tray 20 as a cover for the casing 2.
As illustrated in
The upper unit 4 is, by pivoting with respect to a pivot shaft 4a illustrated in
The casing 2 is supported by a support member 19 as illustrated in
As illustrated in
The edge guides 12a and 12b are provided so as to be slidable in the X-axis direction in accordance with the size of the medium P. In the present embodiment, the edge guides 12a and 12b are configured such that following the X movement of the edge guide 12a on the +X side by a known rack and pinion mechanism, the edge guide 12b on the −X side moves in the opposite direction.
The feed tray 8 is configured such that the medium P is aligned at the center thereof in the width direction and is fed by a so-called center sheet feeding method by a feeding roller 14 (described later) provided in a center region in the width direction.
In addition, the feed tray 8 includes an auxiliary feed tray 9 that is capable of switching between a pulled-out state in which the auxiliary feed tray 9 is pulled out from the feed tray 8 as illustrated in
As illustrated in
The second tray 22 is configured to be slidable with respect to the first tray 21. The third tray 23 is configured to be slidable with respect to the second tray 22. The fourth tray 24 is configured to be slidable with respect to the third tray 23.
As illustrated in the middle diagram of
At the front end of the fourth tray 24, a restricting portion 25 is provided that is foldable with respect to the fourth tray 24 and restricts the movement of the medium P placed on the discharge tray 20 in the +Y direction. Further, the second tray 22, the third tray 23, and the fourth tray 24 may be configured to be folded and stored instead of being stored in the upstream tray.
Because the second tray 22, the third tray 23, and the fourth tray 24 can be stored in the first tray 21, when the apparatus is not being used or when the size of the medium P discharged to the discharge tray 20 is small, the second tray to the fourth tray can be stored in the first tray 21, and the apparatus can be arranged in a space-saving manner.
The configuration of the discharge tray 20 that is a characteristic portion of the scanner 1 or the medium discharging apparatus 10 of the present embodiment will be described in more detail after the medium transport path R has been described.
In addition, as illustrated in
The medium transport path R in the medium discharging apparatus 10 will be described below mainly with reference to
The transport roller pair 16 includes a transport driving roller 16a and a transport driven roller 16b. The discharge roller pair 17 is a discharger that discharges the medium P from the casing 2, and includes a discharge driving roller 17a and a discharge driven roller 17b.
The feeding roller 14, the transport driving roller 16a, and the discharge driving roller 17a are provided to be pivotable with respect to the lower unit 3. In addition, the separation roller 15, the transport driven roller 16b, and the discharge driven roller 17b provided at a position facing the feeding roller 14 are provided to be pivotable with respect to the upper unit 4.
The medium P placed on the feed tray 8 is picked up by the feeding roller 14 and sent toward the transport roller pair 16. Specifically, the medium P is fed downstream by the feeding roller 14 rotating while being in contact with the surface of the medium P that faces the feed tray 8. Therefore, when a plurality of media P are set on the feed tray 8 of the scanner 1, the media P on the lower side are sequentially fed downstream.
At a position facing the feeding roller 14 in
The transport roller pair 16 transports the medium P fed by the feeding roller 14 toward the reading unit 5. Similarly to the feeding roller 14, the transport roller pair 16 is also provided in the center region in the X-axis direction, which is the width direction.
The reading unit 5 includes a first reading unit 5a provided on the upper unit 4 side and a second reading unit 5b provided on the lower unit 3 side. In the present embodiment, the first reading unit 5a and the second reading unit 5b are formed as a contact image sensor module (CISM) as an example.
The first reading unit 5a reads the surface of the medium P facing upward, and the second reading unit 5b reads the opposite surface of the medium P, that is, the surface of the medium P facing downward.
The medium P, after having at least one surface read by the reading unit 5, is nipped by the discharge roller pair 17 located downstream of the reading unit 5 and is discharged from the discharging portion 18.
Further, in the present embodiment, the feeding roller 14, the separation roller 15, the transport driving roller 16a, and the discharge driving roller 17a are driven by a drive source (not illustrated) so as to rotate. In addition to a configuration in which the rollers are all driven by the same drive source, the rollers may be driven by two or more drive sources.
In this embodiment, as an example, the separation roller 15, the transport driving roller 16a, and the discharge driving roller 17a are driven by a common drive source, and the feeding roller 14 is driven by another drive source.
Hereinafter, the discharge tray 20 will be described.
As described above, the discharge tray 20 illustrated in
In the present embodiment, as illustrated in
Further, the upper view of
In the present embodiment, as an example, the first angle α1 is set to about 180° so that the first tray 21 and the second tray 22 are substantially flush. In addition, the second angle α2 is set to an obtuse angle.
Because the posture of the first tray 21 with respect to the discharge roller pair 17 does not change when the discharge tray 20 is switched between the first posture and the second posture, even if the posture of the discharge tray 20 is switched, the entry angle of the front end of the medium P discharged by the discharge roller pair 17 into the first tray 21 does not change. Therefore, the risk of buckling of the front end of the medium P that occurs when the entirety of the discharge tray 20 is pivoted to change the inclination angle of the discharge tray 20 can be reduced.
The first posture and the second posture of the discharge tray 20 can be switched between the first posture and the second posture in accordance with the type of the medium P, such as the rigidity and thickness of the medium P, the state of the medium being bent or curled, and the space where the scanner 1 is to be installed.
For example, because the second posture of the discharge tray 20 (the lower diagram in
On the other hand, when the rigidity of the medium P is high, or when the front end of the medium P is bent downward or curled, the front end of the medium P may abut against the second tray 22, which is inclined, and may buckle.
When discharging such a medium P, buckling of the front end of the medium P can be suppressed by setting the discharge tray 20 to the flat first posture (upper view in
Hereinafter, an example of a configuration for switching between the first and second postures of the discharge tray 20 will be described with reference to
As illustrated in each drawing of
The first tray 21 includes a guide rail 32 that guides the sliding shaft 31. Further, in the present embodiment, the tray pivot shaft 30 is also guided by the guide rail 32.
The guide rail 32 includes, for positioning the sliding shaft 31, a first position C1 (upper diagram in
More specifically, the guide rail 32 includes a first rail portion 32a that extends substantially horizontally in the first tray 21, and a second rail portion 32b that is inclined toward the +Z direction from a +Y side end portion of the first rail portion 32a.
In the present embodiment, the first position C1 is a +Y side end portion of the first rail portion 32a, and the second position C2 is disposed on a +Y side end portion of the second rail portion 32b.
In a state where the second tray 22 is stored in the first tray 21, the sliding shaft 31 is in the position illustrated in the middle diagram of
In addition, when the discharge tray 20 is in the second posture in which the angle of the second tray 22 with respect to the first tray 21 is the obtuse second angle α2, after the second tray 22 has been pulled out until the sliding shaft 31 has been guided along the first rail portion 32a and positioned at the first position C1, the front end of the second tray 22 is lifted further upward, and the second tray 22 is pulled out in the +Y direction while being pivoted with respect to the tray pivot shaft 30. At this time, the sliding shaft 31 moves along the second rail portion 32b.
A recessed portion 33 is formed in the second position C2 as illustrated in the middle diagram of
With the configuration as described above, the first posture and the second posture of the discharge tray 20 can be easily switched.
Further, a recessed portion can also be provided through which the sliding shaft 31 can enter the first position C1 of the first rail portion 32a. As a result, a click feeling can be obtained when the second tray 22 is completely pulled out, and the sliding shaft 31 can be configured not to easily move from the first position C1.
Further, the deployed state in which the medium P can be placed in the discharge tray 20 may be a state in which the second tray 22, the third tray 23, and the fourth tray 24 are stored in the first tray 21 as illustrated in
In addition, in the present embodiment, in the stored state of the scanner 1 illustrated in
The guide rail 32 can also be formed as in a first modification illustrated in
In the configuration of
In addition, also in the first modification, a state in which the angle of the second tray 22 with respect to the first tray 21 is set to the second angle α2 can be maintained by fitting the sliding shaft 31 into the recessed portion 33.
The guide rail 32 can also be formed as in a second modification illustrated in
In the second modification illustrated in
When the sliding pin 36 is in the position illustrated in the upper diagram of
The mechanism for positioning the angle of the second tray 22 with respect to the first tray 21 to the first angle α1 and the second angle α2 may be formed as in a third modification illustrated in
The third modification illustrated in
The first stopper 37a and the second stopper 37b are pressed upward from below the guide rail 32 by a pressing member such as a spring member (not illustrated) and protrude into the guide rail 32. When the second tray 22 is pulled out in the +Y direction or retracted in the −Y direction, the first stopper 37a and the second stopper 37b are configured so as to be pushed by the tray pivot shaft 30 and to recede below the guide rail 32.
As illustrated in the upper diagram of
In addition, as illustrated in the lower diagram of
The angle of the second tray 22 with respect to the first tray 21 can be set to the first angle α1 by the first stopper 37a, and, the angle of the second tray 22 with respect to the first tray 21 can be set to the second angle α2 by the second stopper 37b.
The guide rail 32 can also be formed as in a fourth modification illustrated in
Further, without forming the recessed portion 33 in the end portion of the second rail portion 32b, it is also possible to provide the heart cam mechanism 34 as in the second modification illustrated in
Hereinafter, another example of the discharge tray 20 will be described with reference to
The discharge tray 20 described in the second embodiment is configured to switch between a first posture (upper view in
In the discharge tray 20 illustrated in
Although not illustrated, in a state where the second tray 22 is stored in the first tray 21, the tray pivot shaft 40 is located at a −Y direction end portion of the guide rail 42. When the second tray 22 is pulled out, the tray pivot shaft 40 slides along the guide rail 42 in the +Y direction, and as illustrated in the upper diagram of
From the state of the discharge tray 20 illustrated in the upper diagram of
The second tray 22 is provided with the support bar 41 as the locking portion described above. When the discharge tray 20 is set to the first posture illustrated in the upper diagram of
With the configuration as described above, the discharge tray 20 can be easily switched between the first posture and second posture and the posture can be maintained.
In addition, the discharge tray 20 may be configured to switch between not only the above-described two postures but also a plurality of postures by pivoting of the second tray 22 with respect to the first tray 21. In this configuration, a locking portion that locks the discharge tray 20 may be provided in each of a plurality of postures.
As illustrated in
The lock pin 43 can be provided on the first tray 21 as an example. The second tray 22 is provided with a pin hole (not illustrated) into which the lock pin 43 can be inserted and removed. As illustrated in the lower diagram of
In
As illustrated in the upper diagram of
When the discharge tray 20 is in the second posture, the lock pin 43 can be moved in the +X direction and inserted into a pin hole (not illustrated) provided in the second tray 22 to maintain the second posture of the discharge tray 20.
Hereinafter, yet another example of the discharge tray 20 will be described with reference to
As illustrated in the upper view of
As illustrated in each drawing of
As illustrated in the upper diagram of
The third tray 23 and the fourth tray 24 can be pulled out to the free end side of the second tray 22, which has been pivoted.
Still yet another example of the discharge tray 20 will be described with reference to
As illustrated in
The first tray 21 includes an outlet 26A through which the second tray 22A can advance on the side surface in the +Y direction, and an outlet 26B through which the second tray 22B can advance.
The second tray 22A can be advanced substantially horizontally with respect to the first tray 21, as illustrated in the upper diagram of
With the above configuration, by moving the second tray 22A forward, the discharge tray 20 can be set to the first posture illustrated in the upper diagram of
In addition, it goes without saying that the present disclosure is not limited to the above embodiment, and various modifications are possible within the scope of the disclosure described in the claims, and they are also included in the scope of the present disclosure.
Number | Date | Country | Kind |
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2019-015328 | Jan 2019 | JP | national |