The present application claims priority from Japanese Patent Application No. 2016-016561 filed on Jan. 29, 2016 the disclosure of which is incorporated herein by reference in its entirety.
The present invention relates to a sheet tray configured to support a sheet, and a sheet conveying apparatus provided with a sheet tray configured to support a sheet to be fed to a main body of the sheet conveying apparatus.
There is known a sheet tray having a configuration in which a three or more staged-tray including three or more trays is expanded and contracted. For example, there is known a feed tray capable of enlarging a supporting surface for supporting a sheet thereon by drawing (pulling out) a four-staged tray. This feed tray is provided with a lock mechanism for locking the trays at the respective stages so as to prevent a such a situation that a drawn state, wherein the tray(s) is (are) drawn, cannot be maintained due to natural falling of a tray which is arranged at an immediately above the stage of each of the trays by its own weight. Namely, in this feed tray, the locking is performed three times in a process of drawing the four staged-tray completely.
In the above-described feed tray, in a process in which the rays are being drawn, the trays are engaged or locked with one another for a plurality of times until all the trays are completely drawn. Due to this, it is hard for a user to grasp whether or not a complete drawn state, in which all the trays are completely drawn, is achieved.
The present teaching has been made in view of the above-described situation, and an object of the present teaching is to provide a multiple-staged sheet tray in which the complete drawn state can be grasped easily.
According to an aspect of the present teaching, there is provided a sheet tray configured to support a sheet including:
a first tray including a first supporting surface configured to support the sheet;
a second tray including a second supporting surface configured to support the sheet,
a third tray including a third supporting surface configured to support the sheet,
wherein the second tray includes a first engaging section configured to engage with the first tray at the second position;
the third tray includes a second engaging section configured to make contact with the second tray, in a drawing direction from the first position toward the second position, under a condition that the third tray is arranged at a fifth position located between the third and fourth positions, the second engaging section being configured to engage with the second tray at the fourth position;
the second engaging section is configured to be elastically deformable such that the second engaging section is movable in a releasing direction in which the contact between the second engaging section and the second tray is released; and
the second tray and the third tray are configured to be movable integrally in the drawing direction in a state that the second engaging section makes contact with the second tray.
According to the above configuration, in a case that the third tray is moved in the drawing direction, the third tray is moved to the fifth position, and the second engaging section of the third tray makes contact with the second tray in the drawing direction. In a case that the third tray is drawn further in the drawing direction, the third tray and the second tray are moved integrally, that is, the third tray is moved together with the second tray in the drawing direction in the state that the second engaging section makes contact with the second tray. In a case that the second tray is moved up to the second position, the first engaging section of the second tray engages with the first tray. Further, in a case that the third tray is moved up to the fourth position, the second engaging section of the third tray engages with the second tray. In such a manner, the first tray, the second tray and the third tray engage with one another in a state that the second tray is moved to the second position and the third tray is moved to the fourth position.
According to the present teaching, the user can easily grasp the state that all the trays are completely drawn.
In the following, an embodiment of the present teaching will be explained. It is needless to say that the embodiment to be explained below is merely an example of the present teaching, and that it is possible to appropriately change the embodiment of the present teaching without departing from or changing the gist and scope of the present teaching. In the following explanation, an up/down direction 7 is defined with a state that a multi-function peripheral 10 is usably placed (usable state; state depicted in
As depicted in
The printer section 11 has a printer casing 11A in which a feed tray 20 is provided therein. The feed tray 20 A is configured to insertable and removal with respect to the printer casing 11A via the opening 14 in the front/rear direction 8 and configured to accommodate a recording sheet 15 therein. A lower feed tray 20A is arranged at a location below the feed tray 20. Since the function of the lower feed tray 20A is same as that of the feed tray 20, the inner configuration of the printer section 11 depicted in
As depicted in
A feeding roller 26 is arranged at a location above the feed tray 20 and below the recording section 24. The feeding roller 26 is axially supported at a forward end portion of a feeding arm 27. The feeding roller 26 is rotated by the driving force transmitted thereto from a feeding motor (not depicted in the drawings). The feeding arm 27 is rotated in directions indicated by a double-sided arrow 29, about a shaft 28 which is provided at a basal end portion thereof as the rotating center.
The recording sheet 15 having the image recorded thereon in the recording section 24 is discharged to a discharge ray 21 provided on the upper surface of the feed tray 20, and is supported by the discharge tray 21. The discharge tray 21 is supported by the feed tray 20.
As depicted in
The curved portion 23A is defined by a first guide member 18 and a second guide member 19 facing each other with a predetermined spacing distance therebetween. The first guide member 18 defines the curvature outer side of the curved portion 23A. A guide plate 22A, having a non-illustrated separating section for preventing any overlapped feeding of the recording sheets 15, is arranged between the first guide member 18 and a bottom plate 22 constructing the base of the feed tray 20. The second guide member 19 defines the curvature inner side of the curved portion 23A. The linear portion 23B is defined by the recording section 24 and a platen 42 facing each other with a predetermined spacing distance therebetween at a position at which the recording section 24 is arranged. The first guide member 18 and the second guide member 19 are provided to extend in the left/right direction 9 that is a direction perpendicular to the sheet surface of
The recording sheet 15 supported by the feed tray 20 is conveyed by the feeding roller 26 in the curved portion 23A so as to make an upward U-turn from a lower portion toward an upper portion of the curved portion 23A, and then reaches the conveying roller pair 59. The recording sheet 15 pinched by the conveying roller pair 59 is conveyed frontwardly in the linear portion 23B, with an image recording surface of the recording sheet 15 facing toward the recording section 24. The recording sheet 15 arrived at a location immediately below the recording section 24 is subjected to image recording by which an image, etc. is recorded on the image recording surface of the recording sheet 15 by the recording section 24. The recording sheet 15 having the image, etc. recorded thereon is conveyed frontwardly in the linear portion 23B and is discharged to the discharge tray 21. As described above, the recording sheet 15 is conveyed in the conveyance direction 17 indicated by dash-dot line arrows in
As depicted in
As depicted in
The carriage 40 is configured to be movable in the left/right direction 9 by two guide rails (not depicted in the drawings) which are arranged with a spacing distance therebetween in the front/rear direction 8. The recording head 38 is mounted on the carriage 40. An ink is supplied from, for example, an ink cartridge (not depicted in the drawings) to the recording head 24. Nozzles 39 are formed in the lower surface of the recording head 38. In a state that the carriage 40 is moving in the left/right direction 9, the recording head 38 discharges or jets ink droplets of the ink toward the plate 42. With this, an image, etc. is recorded on the recording sheet 15 in a state that the recording sheet 15 is supported by the plate 42.
The conveying roller pair 59 is provided with a conveyance roller 60 arranged at a location above the linear portion 23B and a pinch roller 61 arranged at a location below the linear portion 23B while facing the conveying roller 60.
As depicted in
Each of the conveyance roller 60 and the discharge roller 62 is rotated by a driving force transmitted thereto from a conveyance motor (not shown). In a case that the conveyance roller 60 is rotated in a state that the recording sheet 15 is pinched by the conveying roller pair 59 (nip state), the recording paper 15 is conveyed by the conveying roller pair 59 in the conveyance direction 17. In a case that the discharge roller 62 is rotated in a state that the recording sheet 15 is pinched by the discharging roller pair 64, the recording paper 15 is conveyed by the discharging roller pair 64 in the conveyance direction 17.
Note that in this embodiment, the system by which the recording section 24 records the image, etc. on the recording sheet 15 is the ink-jet recording system. Note that, however, the recording system is not limited to the ink-jet recording system. The image recording system may be, for example, the electro-photographic system, etc.
The scanner section 12 is configured as a so-called flat head scanner, and has a scanner main body 71 (also referred to as the “scanner body 71”, as appropriate) disposed on the body unit 10A, and a manuscript cover 72 arranged on the scanner body 71, as depicted in
As depicted in
In the following explanation of the MP tray 13, the respective parts or components of the MP tray 13 will be explained with reference to the respective directions regarding the tray body 30 in the erected state, namely the up/down direction 7, the front/rear direction 8 and the left/right direction 9.
As depicted in
In the following explanation of the tray body 30, the shape, etc., of the tray body 30 will be explained by using the respective directions regarding the tray body 30 in the erected state.
As depicted in
The upper surface 36A is expanding along the front/rear direction 8 and the left/right direction 9 and faces (is oriented) upwardly. In the erected state of the tray body 30 as depicted in
The guide section 36 is formed with a cutout portion, at a central portion in the left/right direction 9 in the rear end portion of the upper surface 36A, such that the cutout portion has a shape recessing frontwardly. In conformity with this, a central portion in the left/right direction 9 in an upper end portion of the guide surface 36B is expanding substantially along the up/down direction 7 and left/right direction 9. With this, in a case that a recording sheet 15 having a small size (for example, an L-sized recording sheet 15 used in the photographic recording) is supported by the MP tray 13, a user can easily take out the recording sheet 15 from the MP tray 13.
As depicted in
The plate portion 91 has a rectangular shape expanding along the up/down direction 7 and the left/right direction 9. The extended portion 92 has a cylindrical (tubular) shape extending in the front/rear direction 8. The rear cover 101 has a shape substantially same as that of the plate portion 91.
As depicted in
As depicted in
As depicted in
The central recessed portion 33 is formed to be recessed rearwardly in the first supporting surface 90A, as depicted in
As depicted in
As depicted in
The projections 95 are projected rearwardly from a lower end portion in the rear surface 90B of the first supporting plate 90. The projections 95 each have a shape in which a central portion thereof in the up/down direction 7 is raised in a mountain-like shape projecting outwardly in the left/right direction 9. Each of the projections 95 has an upwardly inclined surface 95A which is inclined downwardly from the upper end of the projection 95 and outwardly in the left/right direction 9 and which faces upwardly, and a downwardly inclined surface 95B which is inclined upwardly from the lower end of the projection 95 and outwardly in the left/right direction 9 and which faces downwardly. The projections 95 are configured to correspond to engaging sections 133 in a third supporting plate 131 of the third tray 30C (to be described later on). Each of the projections 95 is located at a position at which at least a portion of each of the projections 95 is overlapped with one of the engaging sections 133 in the third supporting surface 131 of the third tray 30C in the front/rear direction 8 and the left/right direction 9.
The projections 94 are projected rearwardly from a lower end portion in the rear surface 90B of the first supporting plate 90. The projections 94 are each formed to have a cylindrical shape or a tubular shape. Each of the projections 94 has a square cylindrical shape extending in the front/rear direction 8. The projections 94 are located at the outer side in the left/right direction 9 relative to the projections 95. Each of the projections 94 has a contact surface 94A expanding in the front/rear direction 8 and the left/right direction 9 while facing upwardly. The projections 94 are configured to correspond to second cutout portions 114 in a second supporting plate 111 of the second tray 30B (to be described later on). Each of the projections 94 is located at a position at which at least a portion of each of the projections 95 is overlapped with one of the second cutout portions 114 in the second supporting surface 111 of the second tray 30B in the front/rear direction 8 and the left/right direction 9.
The guide rails 96 are projecting rearwardly from a central portion in the up/down direction 7 in the rear surface 90B of the first supporting plate 90, while extending in the up/down direction 7. The guide rails 96 are located at the outer side in the left/right direction 9 relative to the projections 94. Each of the guide rails 96 is projected rearwardly, then is bent toward the inner side in the left/right direction 9, and is extending in the up/down direction 7. Each of the guide rails 96 has a sliding surface (not depicted in the drawings) which faces frontwardly and extends along the up/down direction 7 and the front/rear direction 8. The guide rails 96 are configured to correspond to guide rails 119 in the second supporting plate 111 of the second tray 30B (to be described later on). Each of the guide rails 96 is located at a position at which at least a portion of each of the guide rails 96 is overlapped with one of the guide rails 119 in the second supporting surface 111 of the second tray 30B in the front/rear direction 8 and the left/right direction 9. In a case that each of the guide rails 119 is allowed to enter a location in front of the sliding surface of one of the guide rails 96 from the inner side in the left-right direction 9, the guide rails 96 and the guide rails 119 become slidably movable with respect to each other in the up/down direction 7.
As depicted in
As depicted in
The projections 102 are projected frontwardly from a upper end portion which also forms end portions in the left/right direction 9 in the front surface 101A of the rear cover 101. The projections 102 each have a cylindrical shape. Each of the projections 102 has a contact surface 102A expanding in the front/rear direction 8 and the left/right direction 9 while facing downwardly. The projections 102 are configured to correspond to upper contact surfaces 117A of extended portions 117 in the second supporting plate 111 of the second tray 30B (to be described later on). Each of the projections 102 is located at a position at which at least a portion of each of the projections 102 is overlapped with the upper contact surface 117A of one of the extended portions 117 in the second supporting plate 111 of the second tray 30B in the front/rear direction 8 and the left/right direction 9.
The projections 103 are projected frontwardly from a lower end portion which also forms an end portion in the left/right direction 9 in the front surface 101A of the rear cover 101. Each of the projections 103 is formed as a rib which is H-shaped as seen from the front/rear direction 8. Each of the projections 103 has a contact surface 103A expanding in the front/rear direction 8 and the left/right direction 9 while facing upwardly. The projections 103 are configured to correspond to lower contact surfaces 117B of the extended portions 117 in the second supporting plate 111 of the second tray 30B (to be described later on). Each of the projections 103 is located at a position at which at least a portion of each of the projections 103 is overlapped with the lower contact surface 117B of one of the extended portions 117 in the second supporting plate 111 of the second tray 30B in the front/rear direction 8 and the left/right direction 9.
The projections 104 are projected frontwardly from a lower end portion which also forms a central portion in the left/right direction 9 in the front surface 101A of the rear cover 101. Each of the projections 104 is a rib extending in the up/down direction 7. Each of the projections 104 has a contact surface 104A expanding in the front/rear direction 8 and the left/right direction 9 while facing upwardly. The projections 104 are configured to correspond to first cutout portions 115 in the second supporting plate 111 of the second tray 30B (to be described later on). Each of the projections 104 is located at a position at which at least a portion of each of the projections 104 is overlapped with one of the cutout portions 115 in the second supporting plate 111 of the second tray 30B in the front/rear direction 8 and the left/right direction 9.
The projections 106 are projected frontwardly from outer end portions in the left/right direction 9 which also form a central portion in the up/down direction 7 in the front surface 101A of the rear cover 101. Each of the projections 106 is formed to have a cubic shape. The projections 106 are located at the outer side in the left/right direction 9 relative to the projections 103. Each of the projections 106 has a threaded hole (not depicted in the drawings) recessed inwardly from the outer surface of the projection 96 in the left/right direction 9. The position in the left/right direction 9 of the outer surface of each of the projections 96 corresponds to an inner surface in the left/right direction 9 in the extended portion 92 of the first supporting plate 90. The position of the threaded hole of each of the projections 106 corresponds to one of through holes 97 in the extended portion 92 of the first supporting plate 90.
The rear cover 101 has a cutout portion 105 recessed downwardly from the upper edge of the rear cover 101 at a central portion in the left/right direction 9 of the rear cover 101. The cutout 105 has a rectangular shape elongated in the left/right direction 9. The cutout portion 105 is located at a location above the projections 104. Further, the cutout portion 105 is located at the inner side in the left/right direction 9 relative to the projections 103. The width in the left/right direction 9 of the cutout portion 105 is substantially same as the width in the left/right direction 9 of the third tray 30 (to be described later on).
As depicted in
The second supporting plate 111 has a second supporting surface 111A (also see
The rear surface 111B is provided with a pair of left and right projections 112, a pair of left and right projection 113, a pair of left and right second cutout portions 114, a pair of left and right first cutout portions 115, a pair of left and right engaging sections 116, a pair of left and right extended portions 117, a pair of left and right guide rails 118, a pair of left and right guide rails 119, a pair of left and right projections 120, and a pair of left and right projections 121. The projections 112, the projections 113, the second cutout portions 114, the first cutout portions 115, the engaging sections 116, the extended portions 117, the guide rails 118, the guide rails 119, the projections 120 and the projections 121 are integrally formed with the second supporting plate 111. The second supporting plate 111 is formed, for example, of a resin.
The first cutout portions 115 are recessed upwardly from a lower end edge of the second supporting plate 111 at a central portion in the left/right direction 9 of the second supporting plate 111. Each of the first cutout portions 115 has a rectangular shape. Each of the first cutout portions 115 has a contact surface 115A expanding in the front/rear direction 8 and the left/right direction 9 while facing downwardly. The first cutout portions 115 are configured to correspond to the projections 104 in the rear cover 101 of the first tray 30A. Each of the first cutout portions 115 is located at a position at which at least a portion of each of the first cutout portions 115 is overlapped with one of the projections 104 in the rear cover 101 of the first tray 30A in the front/rear direction 8 and the left/right direction 9.
The projections 112 are projected rearwardly from an upper end portion in the rear surface 111B of the second supporting plate 111. Each of the projections 112 is a rib extending in the left/right direction 9. The projections 112 are located at the outer side in the left/right direction 9 relative to the first cutout portions 115. Each of the projections 112 has an upper surface 112A which is expanding in the front/rear direction 8 and the left/right direction 9 and which faces upwardly, and a lower surface 112B which is expanding in the front/rear direction 8 and the left/right direction 9 and which faces downwardly. The projections 112 are configured to correspond to engaging sections 134 in the third supporting plate 131 of the third tray 30C (to be described later on). Each of the projections 112 is located at a position at which at least a portion of each of the projections 112 is overlapped with one of the engaging sections 134 in the third supporting plate 131 of the third tray 30C in the front/rear direction 8 and the left/right direction 9.
The projections 120 are projected rearwardly from a lower end portion in the rear surface 111B of the second supporting plate 111. The projections 120 each have a cylindrical (tubular) shape. The projections 120 are located in the left/right direction 9 at positions which are substantially same as those of the projections 112, respectively. Each of the projections 120 has a contact surface 120A expanding in the front/rear direction 8 and the left/right direction 9 while facing upwardly. The projections 120 are configured to correspond to contact walls 137 in the third supporting plate 131 of the third tray 30C (to be described later on). Each of the projections 120 is located at a position at which at least a portion of each of the projections 120 is overlapped with one of the contact walls 137 in the third supporting plate 131 of the third tray 30C in the front/rear direction 8 and the left/right direction 9.
The guide rails 118 are projecting rearwardly from substantially the entire area in the up/down direction 7 in the rear surface 111B of the second supporting plate 111, while extending in the up/down direction 7. The guide rails 118 are located at substantially same positions as the outer edges in the left/right direction 9 of the projections 120. Each of the guide rails 118 is projected rearwardly, then is bent toward the inner side in the left/right direction 9, and is extending in the up/down direction 7. Each of the guide rails 118 has a sliding surface (not depicted in the drawings) which faces frontwardly and extends along the up/down direction 7 and the front/rear direction 8. The guide rails 118 are configured to correspond to guide rails 135 in the third supporting plate 131 of the third tray 30C (to be described later on). Each of the guide rails 118 is located at a position at which at least a portion of each of the guide rails 118 is overlapped with one of the guide rails 135 in the third supporting surface 131 of the third tray 30C in the front/rear direction 8 and the left/right direction 9. In a case that each of the guide rails 135 is allowed to enter a location in front of the sliding surface of one of the guide rails 118 from the inner side in the left-right direction 9, the guide rails 118 and the guide rails 135 become slidably movable with respect to each other in the up/down direction 7.
The projections 113 (an example of a first projection) are projected rearwardly from an upper end portion in the rear surface 111B of the second supporting plate 111. Each of the projections 113 is a rib having a T-shape. The projections 113 are located at the outer side in the left/right direction 9 relative to the guide rails 118. Each of the projections 113 has a contact surface 113A which is expanding in the front/rear direction 8 and the left/right direction 9 and which faces downwardly. The projections 113 are configured to correspond to projections 132 in the third supporting plate 131 of the third tray 30C (to be described later on). Each of the projections 113 is located at a position at which at least a portion of each of the projections 113 is overlapped with one of the projections 132 in the third supporting surface 131 of the third tray 30C in the front/rear direction 8 and the left/right direction 9.
The second cutout portions 114 are recessed upwardly from the lower end edge of the second supporting plate 111. Each of the second cutout portions 114 has a rectangular shape. The second cutout portions 114 are arranged at positions which are substantially same in the left/right direction 9 relative to the projections 113. Each of the second cutout portions 114 has a contact surface 114A expanding in the front/rear direction 8 and the left/right direction 9 while facing downwardly. The second cutout portions 114 are configured to correspond to the projections 94 in the first supporting plate 90 of the first tray 30A. Each of the second cutout portions 114 is located at a position at which at least a portion of each of the second cutout portion 114 is overlapped with one of the projections 94 in the first supporting plate 90 of the first tray 30A in the front/rear direction 8 and the left/right direction 9.
The projections 121 are projected from the upper end portion of the second supporting plate 111, respectively toward the inner sides in the left/right direction 9. Each of the projections 121 is formed to have a cubic shape. The projections 121 are located at the outer side in the left/right direction 9 relative to the second cutout portions 114. Each of the projections 121 has a contact surface 121A which is expanding in the front/rear direction 8 and the left/right direction 9 and which faces upwardly. The projections 121 are configured to correspond to an operation section 136 in the third supporting plate 131 of the third tray 30C (to be described later on). Each of the projections 121 is located at a position at which at least a portion of each of the projections 113 is overlapped with the operating section 136 in the third supporting surface 131 of the third tray 30C in the front/rear direction 8 and the left/right direction 9.
The guide rails 119 are projecting frontwardly from a central portion in the up/down direction 7 in the second supporting surface 111A of the second supporting plate 111, while extending in the up/down direction 7. The guide rails 119 are located at the outer side in the left/right direction 9 relative to the second cutout portions 114. Each of the guide rails 119 is projected frontwardly, then is bent toward the outer side in the left/right direction 9, and is extending in the up/down direction 7. Each of the guide rails 119 has a sliding surface 119A (see
The engaging sections 116 (an example of a first engaging section) are located at a lower end portion of the second supporting plate 111. The engaging sections 116 are located at the outer side in the left/right direction 9 relative to the guide rails 119. As depicted in
The extended portions 117 (an example of a third projection) are projected outwardly in the left/right direction 9 from a lower end portion of the second supporting plate 111. The extended portion 117 each have a rectangular planar shape. Each of the extended portions 117 has an upper contact surface 117A expanding in the front/rear direction 8 and the left/right direction 9 while facing upwardly, and a lower contact surface 117B expanding in the front/rear direction 8 and the left/right direction 9 while facing downwardly. The upper contact surface 117A of each of the extended portions 117 is configured to correspond to one of the projections 102 in the rear cover 101 of the first tray 30A. The lower contact surface 117B of each of the extended portions 117 is configured to correspond to one of the projections 103 in the rear cover 101 of the first tray 30A. The upper contact surface 117A of each of the extended portions 117 is located at a position at which at least a portion of the upper contact surface 117A is overlapped with one of the projections 102 in the rear cover 101 of the first tray 30A in the front/rear direction 8 and the left/right direction 9.
As depicted in
The third supporting plate 131 has a third supporting surface 131A expanding entirely in the third supporting plate 131 along the up/down direction 7 and the left/right direction 9, while facing frontwardly.
The third supporting surface 131A is provided with a pair of left and right projections 132, a pair of left and right engaging sections 133, a pair of left and right engaging sections 134 and a pair of left and right guide rails 135. The projections 132, the engaging sections 133, the engaging sections 134 and the guide rails 135 are integrally formed with the third supporting plate 131. The third supporting plate 131 is formed, for example, of a resin.
The engaging sections 134 (an example of a second engaging section) are located at a lower end portion of the third supporting plate 131. As depicted in
The engaging sections 133 (an example of a third engaging section) are projected downwardly from a lower end edge at a portion located closely to a central portion in the left/right direction 9 of the third supporting plate 131. The projections 133 are located on the inner side in the left/right direction 9 relative to the engaging sections 134. As depicted in
The contact walls 137 are projected frontwardly from a lower end edge in the third supporting surface 131A of the third supporting plate 131. The contact walls 137 are each formed as a rib extending in the left/right direction 9. The contact walls 137 are located at the outer side in the left/right direction 9 relative to the engaging sections 134. Each of the contact walls 137 has a contact surface 137A expanding in the front/rear direction 8 and the left/right direction 9 while facing upwardly. The contact walls 137 are configured to correspond to projections 120 in the second supporting plate 111 of the second tray 30B. Each of the contact walls 137 is located at a position at which at least a portion of each of the contact walls 137 is overlapped with one of the projections 120 in the second supporting plate 111 of the second tray 30B in the front/rear direction 8 and the left/right direction 9.
The guide rails 135 are projecting frontwardly from a lower end portion in the third supporting surface 131A of the third supporting plate 131, while extending in the up/down direction 7. The guide rails 135 are located at substantially same positions as the outer edges in the left/right direction 9 of the contact walls 137. Each of the guide rails 135 is projected frontwardly, then is bent toward the outer side in the left/right direction 9, and is extending in the up/down direction 7. Each of the guide rails 135 has a sliding surface (not depicted in the drawings) which faces rearwardly and extends along the up/down direction 7 and the front/rear direction 8. The guide rails 135 are configured to correspond to the guide rails 118 in the second supporting plate 111 of the second tray 30B. Each of the guide rails 135 is located at a position at which at least a portion of each of the guide rails 135 is overlapped with one of the guide rails 118 in the second supporting plate 111 of the second tray 30B in the front/rear direction 8 and the left/right direction 9. In a case that each of the guide rails 118 is allowed to enter a location behind the sliding surface of one of the guide rails 135 from the outer side in the left-right direction 9, the guide rails 135 and the guide rails 118 become slidably movable with respect to each other in the up/down direction 7.
The projections 132 are projected frontwardly from an lower end portion in the third supporting surface 131A of the third supporting plate 131. Each of the projections 132 is a rib which is an inverted T-shaped as seen from the front/rear direction 8. The projections 132 are located at the outer side in the left/right direction 9 relative to the guide rails 135. Each of the projections 132 has a contact surface 132A which is expanding in the front/rear direction 8 and the left/right direction 9 and which faces upwardly. The projections 132 are configured to correspond to the projections 113 in the second supporting plate 111 of the second tray 30B. Each of the projections 132 is located at a position at which at least a portion of each of the projections 132 is overlapped with one of the projections 113 in the second supporting surface 111 of the second tray 30B in the front/rear direction 8 and the left/right direction 9.
The third supporting plate 131 has an operating section 136 which is plate-shaped and formed at an upper end edge of the third supporting surface 131, projecting frontwardly from the supporting surface 131A and expanding along the front/rear direction 8 and the left/right direction 9. The operating section 136 has a rectangular planar shape. As depicted in
As depicted in
The second supporting plate 111 of the second tray 30B and the third supporting plate 131 of the third tray 30C are assembled to each other such that the sliding surfaces (not depicted in the drawings) in the guide rails 118 of the second supporting plate 111 and the sliding surfaces (not depicted in the drawings) in the guide rails 135 of the third supporting plate 131 are opposite to each other. With this, the second supporting plate 111 and the third supporting plate 131 are allowed to be slidable with respect to each other in the up/down direction 7 (an example of the sliding direction).
The rear cover 101 of the first tray 30A is assembled to the first cover 30A such that the peripheral edge portion of the front surface 101A of the rear cover 101 makes contact with the rear end portion of the extended portion 92 of the first supporting plate 90. Then, the screw holes of the projections 106 in the rear cover 101 are positioned and screwed with the through holes 97 of the extended portion 92 in the first supporting plate 90.
A first state depicted in
At the stored position of the second tray 30B, the contact surface 94A of each of the projections 94 in the first supporting plate 90 makes contact, in the up/down direction, with the contact surface 114A of one of the second cutout portions 114 in the second supporting plate 111. Further, the contact surface 103A of each of the projections 103 in the rear cover 101 makes contact, in the up/down direction 7, with the lower surface 117B of one of the extended portions 117 in the second supporting plate 111. With this, downward movement of the second tray 30B to a position below (lower than) the stored position of the second tray 30B with respect to the first tray 30A is regulated or restricted. At the stored position of the second tray 30B, the second supporting plate 111 is overlapped with the first supporting plate 90 in the front/rear direction 8, in a state that the second supporting plate 111 is located on the rear side of the first supporting plate 90.
At the stored position of the third tray 30C, the contact surface 120A of each of the projections 120 in the second supporting plate 111 makes contact, in the up/down direction 7, with the contact surface 137A of one of the contact walls 137 in the third supporting plate 131 (see
Furthermore, in the first state, the upwardly inclined surface 133B of each of the engaging sections 133 in the third supporting plate 131 makes contact with the downwardly inclined surface 95B of one of the projections 95 in the first supporting plate 90, and thus the engaging sections 133 engage with the projections 95. With this, in a state that any force sufficient for releasing the engagement of the engaging sections 133 with respect to the projections 95 is not applied to the third tray 30 in the up direction (an example of a drawing direction), upward movement of the third tray 30C to a position above the stored position of the third tray 30C with respect to the second tray 30B is prevented.
In the first state, the second tray 30B and the third tray 30C are positioned in a space defined between the first supporting plate 90 and the rear cover 101 of the first tray 30A.
In a case that a user operates the operating section 136 of the third tray 30C in the first state so as to lift (draw or pull) the third tray 30C from the first state upwardly, the tray body 30 is eventually changed to have an elongated state depicted in
In a case that the third tray 30C is moved from the first state upwardly via the through holes 97, the engagement of the engaging sections 133 with respect to the projections 95 is released. Specifically, at first, the projecting portion 133D of each of the engaging sections 133 slidably moves in the downwardly inclined surface 95B and moves upwardly. Accompanying with this, the elastic portion 133C of each of the engaging sections 133 is elastically deformed, thereby allowing the projecting portion 133D to move outwardly in the left/right direction 9 along the downwardly inclined surface 95B. Then, after the projecting portion 133D climbs over the downwardly inclined surface 95B to be a position above the downwardly inclined surface 95B, the projecting portion 133D moves upwardly while moving to the inner side in the left/right direction 9 along the upwardly inclined surface 95A.
Afterwards, the third tray 30C moves upwardly, while the second tray 30C is remaining in a stopped state (non-moving state). Then, the tray body 30 reaches a second state as depicted in
In the second state depicted in
Namely, in a drawing process for drawing the third tray 30C from the first state up to the second state, the state in which the projections 112 and the engaging sections 134 are apart (separated) from each other is changed to the contact state, as depicted in
In a case that the third tray 30C is further moved upwardly from the second state, the engaging sections 134 of the third supporting plate 131 pull the projections 112 of the second supporting plate 111, without climbing over the projections 112. A force required for elastically deforming the elastic portion 134C of each of the engaging sections 134 in a direction separating the projecting portion 134D of each of the engaging sections 134 away from one of the projections 112 is greater than the force for pulling the second tray 30B upwardly (for example, the weight of the second tray 30B). Accordingly, the second tray 30 is moved upwardly via the through holes 97, following the movement of the third tray 30C. Then, the second tray 30B is moved up to a second contact position with respect to the first tray 30A. The second contact position is a position at which the downwardly inclined surface 93B of each of the projections 93 in the first supporting plate 90 makes contact, in the up/down direction 7, with the upwardly inclined surface 116B of one of the engaging sections 116 in the second supporting plate 111.
In a case that the third tray 30C is moved further upwardly from a state that the third tray 30C is located at the first contact position and the second tray 30B is located at the second contact position, a rearward force is applied, by the downwardly inclined surface 93B of each of the projecting portions 93, to the upwardly inclined surface 116B of one of the engaging sections 116 in the second supporting plate 111. A force for elastically deforming the elastic portion 116C in a direction separating the projecting portion 116D of each of the engaging sections 116 away from one of the projections 93 (namely, in a rearward direction) is weaker than the force applied to the upwardly inclined surface 116B by the downwardly inclined surface 93B when the third tray 30C located at the first contact position with respect to the second tray 30B is pulled upwardly (for example, the elastic deformation force of the elastic portion 134C of each of the engaging sections 134). Accordingly, the elastic portion 116C of each of the engaging sections 116 is elastically deformed so as to allow the upwardly inclined surface 116B to move in a direction for separating the upwardly inclined surface 116B away from the projection 93 (in a rearward direction). With this, the contact between the downwardly inclined surface 93B of each of the projections 93 and the upwardly inclined surface 116B of one of the engaging sections 116 is released, thereby allowing the third tray 30 to move further upwardly with respect to the second tray 30B. Then, the state of the tray body 30 reaches a third stated as depicted in
In the third state depicted in
At the drawn position of the second tray 30B, the contact surface 102A of each of the projections 102 in the rear cover 101 of the first tray 30A makes contact, in the up/down direction 7, with the upper contact surface 117A of one of the extended portions 117 in the second supporting surface 111 of the second tray 30B. With this, upward movement of the second tray 30B up to a position above the drawn position of the second tray 30B with respect to the first tray 30A is regulated. Also at the drawn position of the second tray 30B, the second supporting plate 111 is overlapped with the first supporting plate 90 in the front/rear direction 8, in a state that the second supporting plate 111 is located behind (located on the rear side of) the first supporting plate 90, with an overlapping area smaller than that in the case that the second tray 30B is located at the first position.
Further, at the drawn position of the second tray 30B with respect to the first tray 30A, the downwardly inclined surface 116A in each of the engaging sections 116 in the second supporting plate 111 of the second tray 30B makes contact, in the up/down direction 7, with the upwardly inclined surface 93A of one of the projections 93 in the first supporting plate 90 of the first tray 30A, and thus the engaging sections 116 engage with the projections 93 (see
Since the upwardly inclined surface 93A and the downwardly inclined surface 93B of each of the projections 93 are inclined as depicted in
Further, since the elastic deformation of the elastic portion 134C of each of the engaging sections 134 is in the state of being returned in the front direction by a small extent, the projecting portion 116D of each of the engaging sections 116 is in a state of being urged toward the upwardly inclined surface 93A of one of the projections 93. This urging force is converted by the inclination of the upwardly inclined surface 93A to a force urging the second tray 30B upwardly. With this, the second tray 30B is urged upwardly in a state that the contact surface 102A of each of the projections 102 of the first tray 30A makes contact, in the up/down direction 7, with the upper contact surface 117A of one of the extended portions 117 of the second tray 30B. Accordingly, this suppresses any movement in the up/down direction 7 (unsteadiness, rattling) of the second tray 30B.
Since the upward movement of the second supporting plate 111 is regulated, in a case that the third tray 30C is moved further upwardly from the third state, a rearward force is applied by each of the projections 112 to the upwardly inclined surface 134B of one of the engaging sections 134 of the third supporting plate 131. The engaging sections 134 are formed such the force elastically deforming the engaging sections 134 rearwardly is weaker than this force applied to the upwardly inclined surface 134B. Accordingly, each of the engaging sections 134 is elastically deformed to thereby allow the upwardly inclined surface 134B to move rearwardly. With this, the contact between the lower surface 112B of each of the projections 112 and the upwardly inclined surface 134B of one of the engaging sections 134 is released, and thus the third tray 30C is allowed to move further upwardly. Then, the state of the third tray 30C reaches a fourth state as depicted in
In the fourth state, the second tray 30B is at the drawn position with respect to the first tray 30A. Further, in the fourth state, the third tray 30C is located at a drawn position with respect to the second tray 30B (an example of a fourth position; hereinafter referred to simply as the “drawn position of the third tray 30C).
At the drawn position of the third tray 30C, the contact surface 113A of each of the projections 113 in the second supporting plate 111 of the second tray 30B makes contact, in the up/down direction 7, with the contact surface 132A of one of the projections 132 in the third supporting surface 131 of the third tray 30C. With this, upward movement of the third tray 30C up to a position above the drawn position of the third tray 30C with respect to the second tray 30B is regulated. Also at the drawn position of the third tray 30C, the third supporting plate 131 is overlapped with the second supporting plate 111 in the front/rear direction 8, in a state that the third supporting plate 131 is located behind (located on the rear side of) the second supporting plate 111, with an overlapping area smaller than that in the case that the third tray 30C is located at the third position.
Further, at the drawn position of the third tray 30C with respect to the second tray 30B, the upper surface 112A of each of the projections 112 in the second supporting plate 111 of the second tray 30B makes contact, in the up/down direction 7, with the downwardly inclined surface 134A in one of the engaging sections 134 in the third supporting plate 131 of the third tray 30C, and thus the engaging sections 134 engage with the projections 112 (see
The upper surface 112A and the lower surface 112B of each of the projections 112 are expanding along the front/rear direction 8 and the left/right direction 9 but are not inclined in the up/down direction 7. Therefore, in a process (operation) in which the third tray 30C is being moved upwardly and when the engaging sections 134 are engaging with the projections 112, the projecting portion 134D of each of the engaging sections 134 is moved rabidly rearwardly, and then climbs over the projection 112, and then is moved rapidly frontwardly. Further, the elastic deformation in the rear direction of the elastic portion 134C of each of the engaging sections 134 is in a state of being fully returned in the front direction, which in turn causes the user to feel a strong (large) click feeling.
In a case that a downward force is applied to the operating section 136 of the third tray 30C in the tray body 30 in the fourth state, at first, the engagement of the engaging sections 116 of the second tray 30B with respect to the projections 93 in the first supporting plate 90 of the first tray 30A is released. During this process, the force applied to the downwardly inclined surface 116A of each of the engaging sections 116 by the upwardly inclined surface 93A of one of the projections 93, the elastic portion 116C of each of the engaging sections 116 is elastically deformed such that the projecting portion 116D of each of the engaging sections 116 is moved rearwardly. After that, the projecting portion 116D of each of the engaging sections 116 climbs over one of the projections 93, thereby allowing the elastic portion 116C to be elastically returned (restored). This is caused because the engaging force of the engaging sections 116 of the second tray 30B with respect to the projections 93 in the first supporting plate 90 of the first tray 30A is weaker than the engaging force of the engaging sections 134 in the third supporting plate 131 of the third tray 30C with respect to the projections 112 of the second tray 30B. With this, the second tray 30B is moved downwardly. Then, the state of the tray body 30 is changed to a state that the second tray 30B is located at the stored position and the third tray 30C is located at the drawn position.
In a case that the downward force is further applied to the operating section 136 of the third tray 30C in the tray body 30 in this state, the engagement of the engaging sections 134 of the third tray 30C with respect to the projections 112 of the second tray 30B is released. During this process, the force applied to the downwardly inclined surface 134A of each of the engaging sections 134 by the upper surface 112A of one of the projections 112, the elastic portion 134C of each of the engaging sections 134 is elastically deformed such that the projecting portion 134D of each of the engaging sections 134 is moved rearwardly. After that, the projecting portion 134D of each of the engaging sections 134 climbs over one of the projections 112, thereby allowing the elastic portion 134C to be elastically returned. With this, the third tray 30C is moved downwardly. Then, the third tray 30C is moved up to a third contact position with respect to the first tray 30A. At the third contact position, the upwardly inclined surface 95A of each of the projections 95 in the first supporting plate 90 makes contact, in the up/down direction 7, with the downwardly inclined surface 133A of one of the engaging sections 133 in the third supporting plate 131.
In a case that the third tray 30C is further moved downwardly from this position, a force outwardly in the left/right direction 9 is applied to the downwardly inclined surface 133A of each of the engaging sections 133 in the third supporting plate 131, by one of the projections 95. In a case that a force stronger than the force elastically deforming the engaging sections 133 outwardly in the left/right direction 9 is applied to the operating section 136, the engaging sections 133 are thereby elastically deformed so as to move the downwardly inclined surfaces 133A outwardly in the left/right direction 9. With this, the projecting portion 133D of each of the engaging sections 133 is guided by the upwardly inclined surface 95A of one of the projections 95, and the elastic portion 133C is elastically deformed such that the projecting portion 133D is moved outwardly in the left/right direction 9. Afterwards, when the projecting portion 133D climbs over a ridge defined between the upwardly inclined surface 95A and the downward inclined surface 95B, the projecting portion 133D is guided by the downwardly inclined surface 95B, and the elastic portion 133C is elastically deformed such that the projecting portion 133D is moved inwardly in the left/right direction 9. With this, the third tray 30C is moved downwardly, and the state of the third tray 30C is returned to the first state.
As described above, in a case that the third tray 30C is moved upwardly, the third tray 30C is moved to the contact position with respect to the second tray 30B, and the engaging sections 134 of the third tray 30C make contact, in the up direction, with the projections 112 of the second tray 30B. In a case that the third tray 30C is moved further upwardly, the second tray 30B and the third tray 30C are integrally moved (the second tray 30B is moved together with the third tray 30C) upwardly in a state that the engaging sections 134 are making contact with the projections 112 of the second tray 30B. In a case that the second tray 30B is moved up to the drawn position of the second tray 30B, the engaging sections 116 of the second tray 30B engage with the projections 93 of the first tray 30A. Further, in a case that the third tray 30C is moved up to the drawn position of the third tray 30C, the engaging sections 134 of the third tray 30C engage with the projections 112 of the second tray 30B. In such a manner, in a state that the second tray 30B is moved up to the drawn position of the second tray 30B and that the third tray 30C is moved up to the drawn position of the third tray 30C, the first tray 30A, the second tray 30B and the third tray 30C engage with one another.
Before the engaging sections 134 of the third tray 30C engage with the projections 112 of the second tray 30B, the engaging sections 116 of the second tray 30B engage with the projections 93 of the first tray 30A. Accordingly, it is possible to suppress such a situation that the sheet tray is used only the third tray 30C is drawn.
By moving the third tray 30C from the contact position with respect to the second tray 30B toward the drawn position of the third tray 30C in the state that the engaging sections 116 of the second tray 30B engage with the projections 93 of the first tray 30A, the engaging sections 134 of the third tray 30C are thereby elastically deformed so as to release the contact with respect to the projections 112 of the second tray 30B, and the third tray 30C is easily moved to the drawn position of the third tray 30C.
The click feeling perceived by the user with respect to the engagement of the engaging sections 116 of the second tray 30B is made to be small. Accordingly, when the user perceives a large click feeling, namely, when the engaging sections 134 of the third tray 30C engage with the projections 112 of the second tray 30B, the state is achieved wherein the engaging sections 116 and the engaging sections 134 are both in the engaged states thereof, respectively. Accordingly, it is possible to easily grasp the state that the second tray 30B is located at the drawn position of the second tray 30B and that the third tray 30C is located at the drawn position of the third tray 30C, namely the state that the second tray 30B and the third tray 30C are both in a fully drawn state thereof.
Further, the second tray 30B receives the force in the up direction, due to the urging force brought about by each of the engaging sections 116 with respect to the upwardly inclined surface 93A of one of the projections 93. Namely, the second tray 30B at the drawn position of the second tray 30B receives the force in the up direction in a state that the movement of the second tray 30B in the up direction is restricted (regulated). Accordingly, the movement of the second tray 30B in both directions in the up/down direction 7 is suppressed.
The drawing direction for each of the second and third trays 30B and 30C is the up direction. Accordingly, in a case that the movements of the second and third trays 30B and 30C are stopped (aborted) in a state that the second tray 30B has not moved up to the drawn position of the second tray 30B and that the third tray 30C has not moved up to the drawn position of the third tray 30C, the second and the third trays 30B and 30C easily return to the stored positions thereof, respectively, due to the gravity. Accordingly, the user can easily grasp the state that all the trays are completely drawn.
The third tray 30C is provided with the engaging sections 133 configured to engage with the first tray 30A under a condition that the second tray 30B is located at the stored position of the second tray 30B and that the third tray 30C is located at the stored position of the third tray 30C. Accordingly, the MP tray 13 is maintained in the state that the second tray 30B and the third tray 30C are both at the stored positions, respectively.
The rear surface 111B of the second supporting plate 111 of the second tray 30B and the rear surface 131B of the third supporting plate 131 of the third tray 30C are covered (hidden) by the rear cover 101. Accordingly, the outer appearance of the MP tray 13 can be improved. Further, the second and third trays 30B and 30C can be protected by the rear cover 101.
In the state that both of the second tray 30B and the third tray 30C are located at the stored positions thereof, respectively, the second and third trays 30B and 30C are in a state of being covered (hidden) by the first tray 30A. Accordingly, in this state, the outer appearance of the MP tray 13 can be improved. Further, the MP tray 13 can be made compact.
In the above-described embodiment, the engaging sections 116 are formed integrally with the second supporting plate 111 of the second tray 30B, and the second supporting plate 111 is formed of a resin. Accordingly, the elastic deformation of the engaging sections 116 is elastic deformation of the resin forming the engaging sections 116. In contrast to this, for example, it is allowable that the engaging sections 116 are configured to be movable relative to the second supporting plate 111 such that the downwardly inclined surface 116A of each of the engaging sections 116 is movable in the front/rear direction 8, and that each of the engaging sections 116 is urged by an elastic member, such as a spring, in a direction of allowing the downwardly inclined surface 116A of each of the engaging sections 116 to make contact with the downwardly inclined surface 93B of one of the projections 93. This is similarly applicable also to the engaging sections 134 and 133.
Further, in the engagements regarding the engaging sections 116, 133 and 134, the engaging sections 116, 133 and 134 are each an elastically deformable member, and the projections 93, 95 and 112 each are not an elastically deformable member. However, it is allowable to adopt a configuration wherein the engaging sections 116, 133 and 134 each are not an elastically deformable member, and the projections 93, 95 and 112 are each an elastically deformable member. Furthermore, it is also allowable to adopt a configuration wherein both of the engaging sections 116, 133 and 134 and the projections 93, 95 and 112 are elastically deformable.
Moreover, provided that the engaging sections 116, 133 and 134 are engageable with the projections 93, 95 and 112, respectively, the direction in which the engaging sections 116, 133 and 134 are elastically deformed and the direction in which the projections 93, 95 and 112 are projected can be changed in any way. Further, the direction in which other projection(s) regarding the engagement are projected can be changed in any way, as well.
Number | Date | Country | Kind |
---|---|---|---|
2016-016561 | Jan 2016 | JP | national |