The present application is based on Japanese Patent Application No. 2005-281247 filed on Sep. 28, 2005, the contents of which are incorporated herein by reference.
1. Field of the Invention
The present invention relates to an image recording apparatus and, in particular, to a construction of a frame assembly as a supporting apparatus.
2. Discussion of Related Art
The frame assembly 3 includes a main frame 4, and two slide-base members 5, 6 that are supported by the main frame 4. The main frame 4 has a generally U-shaped transverse cross section, and extends in the direction perpendicular to the drawing of
To position accurately the recording head 2 relative to the platen 1 when the head 2 is moved along the platen 1, it is needed to fix accurately the two slide-base members 5, 6 to the main frame 4. To this end, in a conventional method, the frame assembly 3 is assembled such that the two slide-base members 5, 6 are accurately positioned relative to the main frame 4, before the platen 1 and the recording head 2 are assembled with the frame assembly 3. More specifically explained, in the conventional method, the main frame 4 is provided with one or more engaging portions, and each of the two slide-base members 5, 6 is provided with one or more engageable portions. In a state in which the engaging and engageable portions are engaged with each other, the engaging portions are caulked to position accurately the two slide-base members 5, 6 relative to the main frame 4. The image recording portion is assembled in such a manner that the platen 1 and the recording head 2 are assembled with the pre-assembled frame assembly 3.
However, in the above-explained conventional method, the two slide-base members 5, 6 are substantially permanently fixed to the main frame 4, i.e., cannot be easily disassembled from the same 4. Therefore, the assembling of the image recording portion suffers from the disadvantage that it is difficult to attach the platen 1 and/or the recording head 2 to the frame assembly 3. In addition, recently, there is a tendency that the ink-jet recording device is downsized and accordingly the frame assembly 3 thereof is also downsized. Thus, it is more and more difficult to attach the platen 1 and/or the recording head 2 to the frame assembly 3.
The above-indicated problem seems to be solved by attaching, with screws, the two slide-base members 5, 6 to the main frame 4, such that the slide-base members 5, 6 can be detached from the main frame 4, with a screw driver. In this case, after the platen 1 is assembled with the main frame 4, the two slide-base members 5, 6 are fastened to the main frame 4 and then the ink-jet recording head 2 is attached to the slide-base members 5, 6. In the image recording portion assembled in this manner, however, the main frame 4 or the slide-base members 5, 6 may be locally deformed by the fastening of the screws, so that the slide-base members 5, 6 may not be accurately positioned relative to the main frame 4. In addition, for the purpose of fastening the slide-base members 5, 6 to the main frame 4, it is needed to employ fastening nuts to engage the screws and provide additional spaces in which those nuts are disposed. This makes it difficult to downsize the image recording device.
Each of Patent Document 1 (Japanese Utility Model Application Publication No. 3-31565) and Patent Document 2 (Japanese Patent Application Publication No. 62-71679) discloses a frame structure for use in an image recording device or a multi-function device. In particular, Patent Document 1 discloses a frame structure including a positioning means and a biasing means.
In the above-described technical background, the present invention has been developed. It is therefore an object of the present invention to solve at least one of the above-indicated problems. It is another object of the present invention to provide an image recording apparatus whose image recording portion can be accurately and easily assembled. It is another object of the present invention to provide a method of producing an image recording apparatus accurately and easily.
According to a first aspect of the present invention, there is provided an image recording apparatus, comprising a platen which is adapted to support a recording sheet that is fed in a sheet-feed direction; a recording head which is movable along the platen, in a head-movement direction perpendicular to the sheet-feed direction, so as to record an image on the recording sheet; a frame assembly including a main frame which supports the platen, and at least one slide-base member which is supported by an upper portion of the main frame and which supports the recording head such that the recording head is slideable on the at least one slide-base member along the platen; at least one biasing device which biases the at least one slide-base member toward the main frame in at least a downward direction; and at least one positioning device which positions the at least one slide-base member relative to the main frame in at least one horizontal direction and the downward direction, such that the at least one slide-base member is permitted to be displaced relative to the main frame in an upward direction.
In the present image recording apparatus, the platen and the recording head may be assembled with the frame assembly, as follows: Before the slide-base member is assembled with the main frame, the platen is attached to an appropriate portion of the main frame. Since the slide-base member has not been assembled with the main frame, an operator can easily attach the platen to the main frame. Thus, the operator can easily and accurately position the platen relative to the main frame.
Subsequently, the operator attaches the slide-base member to the main frame, by utilizing the positioning device. Therefore, the slide-base member can be positioned relative to the main frame in the horizontal direction and the downward direction, such that the slide-base member is permitted to be displaced relative to the main frame in the upward direction. Thus, in the state in which the slide-base member is attached to the main frame, the slide-base member extends parallel to the platen.
In addition, the biasing device biases the slide-base member toward the main frame in at least the downward direction. Thus, the slide-base member is prevented from being moved relative to the main frame in at least the upward direction, i.e., is fixed to the main frame. Since the slide-base member is positioned relative, and fixed, to the main frame owing to the biasing device, no local stresses or deformations are produced in the slide-base member or the main frame. Therefore, the slide-base member is not tilted relative to the platen, and is maintained accurately parallel to the same.
Then, the recording head is attached to the slide-base member. Since the slide-base member is attached to the main frame such that the slide-base member extends parallel to the platen, the recording head can be moved on the slide-base member, along the elongate platen, without being tilted relative to the platen.
According to a second aspect of the present invention, there is provided a method of producing an image recording apparatus, the method comprising temporarily assembling a main frame which is for supporting a platen, and at least one slide-base member which is for supporting a recording head such that the recording head is slideable on the at least one slide-base member along the platen, with each other into a frame assembly in which the at least one slide-base member is supported by an upper portion of the main frame such that the at least one slide-base member is permitted to be removed from the main frame in an upward direction, without using a tool; judging whether the at least one slide-base member is appropriately positioned relative to the main frame, such that the at least one slide-base member extends in a first direction parallel to a second direction in which the platen supported by the main frame extends; temporarily removing, when it is judged that the at least one slide-base member is appropriately positioned relative to the main frame, the at least one slide-base member from the main frame in the upward direction; causing the platen to be supported by the main frame; re-assembling the at least one slide-base member with the main frame, so that the at least one slide-base member extends parallel to the platen supported by the main frame; biasing the at least one slide-base member toward the main frame in at least a downward direction; and causing, before or after the at least one slide-base member is re-assembled with the main frame, the recording head to be supported by the at least one slide-base member, so that the recording head is slideable on the at least one slide-base member along the platen supported by the main frame. The tool may be a screw driver.
The image-recording-apparatus producing method in accordance with the second aspect of the present invention enjoys the same advantages as those of the image recording apparatus in accordance with the first aspect of the present invention.
The above and optional objects, features, and advantages of the present invention will be better understood by reading the following detailed description of the preferred embodiments of the invention when considered in conjunction with the accompanying drawings, in which:
Hereinafter, there will be described preferred embodiments of the present invention by reference to the drawings.
The MFD 10 has a printer function, a scanner function, and a copier function, and includes a printer portion 11 provided in a lower portion thereof, and a scanner portion 12 provided in an upper portion thereof that is integral with the lower portion. In the present embodiment, the printer portion 11 corresponds to an image recording apparatus to which the present invention is applied. The functions other than the printer function may be omitted, that is, the scanner portion 12 may be omitted. Thus, the present invention may be applied to a single-function printer that has only the printer function and does not have the scanner or copier function. Alternatively, the present invention may be applied to an MFD that additionally employs a communication portion and accordingly has a facsimile-machine function.
The MFD 10 as the first embodiment of the present invention is of a small size. However, the present invention may be applied to a large-size MFD that includes a plurality of sheet-supply cassettes and an automatic document feeder (ADF). In addition, the MFD 10 may be connected to a computer (e.g., a personal computer, PC), not shown, so that the MFD 10 may record, based on image data or document data supplied from the computer, an image or a document on a recording sheet. Alternatively, the MFD 10 may be connected to a digital camera, so that the MFD 10 may record, based on image data outputted from the digital camera, an image on a recording sheet. Moreover, the MFD 10 may include a memory receiving portion that can receive each of various sorts of memories, such as a floppy disc, so that the MFD 10 may record, based on image data stored by the each memory, an image on a recording sheet. Here, the recording sheet may be a cut sheet having a fixed size such as A4 Size or B5 Size, a resin-based film, or other sorts of sheets on which images or documents can be recorded.
As shown in
In the upper portion of the MFD 10, there is provided the scanner portion 12, i.e., so-called “flat-bed” scanner. As shown in
An operation panel 15 is provided in a front end portion of the upper portion of the MFD 10. The operation panel 15 is for operating the printer portion 11 and the scanner portion 12. The operation panel 15 includes various operation keys and a liquid crystal display (LCD) that are used by a user to input various commands to operate the MFD 10. In the case where the MFD 10 is connected to the above-described computer, the MFD 10 is operated according to commands supplied from the computer via a printer driver. The MFD 10 has, in a left, top portion of the front surface thereof (
As shown in
As shown in
An upper or base end portion of the sheet-supply arm 26 is supported by an axis member 17 such that the arm 26 is pivotable upward and downward about the axis member 17. In a state in which the sheet-supply tray 20 is set in the MFD 10, a sheet-supply clutch or a spring, not shown, biases the sheet-supply arm 26 toward the sheet-supply tray 20; and in a state in which the sheet-supply tray 20 is not set in the MFD 10, the arm 26 is kept at an upper, retracted position thereof. When the sheet-supply arm 26 is pivoted downward, the sheet-supply roller 25 supported by the lower end portion of the arm 26 is pressed on the uppermost one of the recording sheets stacked on the sheet-supply tray 20. If, in this state, the sheet-supply roller 25 is rotated, a frictional force is produced between an outer circumferential surface of the roller 25 and an upper surface of the uppermost recording sheet and, owing to this frictional force, the uppermost recording sheet is moved toward the inclined sheet-separate plate 22. When the leading end of the uppermost recording sheet engages the inclined sheet-separate plate 22, the recording sheet is guided upward along the sheet-supply path 23. When the uppermost recording sheet is moved toward the inclined sheet-separate plate 22, the underlying recording sheet or sheets may be moved with the uppermost recording sheet, because of the friction or static electricity produced therebetween. However, the further moving of the underlying recording sheet or sheets is prevented by the sheet-separate plate 22.
Except for a portion of the sheet-supply path 23 where the image recording portion 24 is provided, the sheet-supply path 23 is defined and constituted by an outer guide surface and an inner guide surface that are opposed to each other with an appropriate distance therebetween. In the MFD 10, the outer guide surface is constituted by an inner surface of a casing of the printer portion 11, and the inner guide surface is constituted by a surface of a guide member 28 provided inside the casing. One or more guide rollers 29 are provided in one or more curved portions of the sheet-supply path 23, as shown in
As shown in
The ink-jet recording head 40, supplied with the inks, ejects droplets of the inks toward the recording sheet being intermittently stopped on the elongate platen 41, while the head 40 is reciprocated along a predetermined path, in the main scanning direction, i.e., the lengthwise direction of the platen 41. Thus, a desired image is recorded on the recording sheet. To this end, the recording sheet needs to be temporarily stopped on the platen 41. However, the recording head 40 needs to be prevented from ejecting too many ink droplets toward a same position on the recording sheet. Hence, the ink-jet recording head 40 is repeatedly reciprocated in the main scanning direction while the recording sheet is intermittently fed by incremental amounts or distances in the sub-scanning direction. Hereinafter, this sheet-feeding operation will be referred to as the intermittent sheet-feeding operation, where appropriate.
As shown in
The present invention relates to the metallic frame assembly 72 wherein the two slide-base members 42, 43 are attached to the main frame 73 such that the two slide-base members 42, 43 are positioned relative to the main frame 73 by respective positioning devices, described later, and are biased toward, and thereby fixed to, the same 73 by respective elastic biasing devices, also described later. Since the two slide-base members 42, 43 are attached to the main frame 73 by the positioning devices and the elastic biasing devices, the image recording portion 24 as an image recording apparatus can be assembled easily and accurately.
A carriage driving device 46 is provided on the downstream-side slide-base member 43. The carriage driving device 46 includes an endless, timing belt 45 connected to the carriage 44. The timing belt 45 extends in the widthwise direction of the sheet-supply path 23, and is driven or circulated by a CR (carriage) motor, not shown. When the timing belt 45 is driven, the carriage 44 is moved in the main scanning direction while being supported by the two slide-base members 42, 43.
Each of the four manifold chambers 53 has an inclined surface that is opposed to the corresponding group of ink ejection nozzles 50 and is inclined downward as seen in a direction of flowing of the corresponding ink. Thus, a transverse-cross-section area of each manifold chamber 53 gradually decreases in the direction of flowing of ink. In the present embodiment, walls that define the ink ejection nozzles 50 are formed of a piezoelectric material, and each nozzle 50 ejects, from an opening outlet 50a thereof, a droplet of ink when the corresponding wall is deformed. However, each nozzle 50 may be modified to eject droplets of ink in any of different known manners.
The ink-jet recording head 40 has, on respective upstream sides of the four manifolds 51, four buffer tanks 54 respectively corresponding to the four inks C, M, Y, K. Each of the four buffer tanks 54 communicates with a corresponding one of the four manifold chambers 53 via a corresponding one of the four communication passages 52. In addition, the ink-jet recording head 40 has four ink-supply inlets 54a that are connected to the four ink tanks 59 (
As shown in
Another drive roller (i.e., another feed roller) 57 and another presser roller 58 are provided on a downstream side of the ink-jet recording head 40 with respect to the sheet-supply path 23. The second drive roller 57 is driven or rotated by the LF motor, not shown, that drives the first drive roller 55. More specifically described, the second drive roller 57 is rotated in synchronism with the first drive roller 58 via an interlocking device, not shown. The second drive roller 57 and the second presser roller 58 cooperate with each other to nip the recording sheet to which the droplets of inks have been applied. When the second drive roller 57 is rotated, the recording sheet is conveyed downstream along the sheet-supply path 23. The conveying of recording sheet is also monitored by the sheet-supply encoder, not shown. Thus, a rotation amount of the first drive roller 55 is detected as a rotation amount of the second drive roller 57 through the encoder, and an amount of conveying of the recording sheet is determined by the control device, not shown, based on the thus detected rotation amount.
The first presser roller 56 is elastically biased toward the first drive roller 55 so as to press, with an appropriate pressing force, the same 55. Therefore, when the first drive roller 55 and the first presser roller 56 cooperate with each other to nip the recording sheet, the first presser roller 56 is elastically retracted by an amount corresponding to the thickness of the recording sheet. Thus, the rotating force of the first drive roller 55 is reliably transmitted to the recording sheet. This is true with the second drive roller 57 and the second presser roller 58. In the present embodiment, however, the second presser roller 58 presses the recording sheet on which the image has been recorded. Therefore, in order to prevent the deterioration of the image recorded on the recording sheet, the second presser roller 58 is constituted by a spur roller having a plurality of projections along an outer circumferential surface thereof.
The recording sheet, nipped by the first drive roller 55 and the first presser roller 56, is intermittently conveyed, on the platen 41, in incremental amounts each corresponding to one image line recorded on the sheet. Each time a new image line is opened on the recording sheet, the ink-jet recording head 40 is moved in the main scanning direction to traverse the sheet. Thus, an image is recorded in the sub-scanning direction from the leading end of the recording sheet toward the trailing end thereof. The second drive roller 57 and the second presser roller 58 cooperate with each other to nip the leading end of the recording sheet on which the image is being recorded. That is, the recording sheet whose leading-end-side portion is nipped by the first drive roller 55 and the first presser roller 56 and whose trailing-end-side portion is nipped by the second drive roller 57 and the second presser roller 58 is intermittently conveyed in the incremental amounts each corresponding to one image line recorded on the sheet. Thus, the ink-jet recording head 40 records the image on the recording sheet while the sheet is intermittently conveyed in this manner. After the image is recorded in an appropriate area on the recording sheet, the second drive roller 57 is continuously rotated so that the recording sheet, nipped by the second drive roller 57 and the second presser roller 58, is discharged onto the sheet-discharge tray 21.
As shown in
The purging device 47 includes a cap member 49 that covers the lower surface (i.e., “nozzle-open” surface) of the ink-jet recording head 40; a suction pump, not shown, that is connected to the head 40 via the cap member 49; and a moving device, not shown, that moves the cap member 49 toward, and away from, the nozzle-open surface of the head 40. When the moving device is operated, the cap member 49 fluid-tightly covers the nozzle-open surface of the recording head 40. Then, when the suction pump is operated, the inks are sucked from the recording head 40. The suction pump may be of a type in which a flexible tube is sequentially flattened by a roller so as to move air in the tube, or of any known type. The waste-ink tray 48 opens upward, i.e., toward the nozzle-open surface of the recording head 40, and receives or collects the waste inks that are ejected by the head 40 for the purpose of preventing the clogging of the ink ejection nozzles 50.
As described above, the ink supplied from each of the four ink tanks 59 to the ink-jet recording head 40 via the ink-supply passage, is temporarily stored by a corresponding one of the four buffer tanks 54 (
As shown in
In the present embodiment, the cap member 49 includes a color-ink cap portion 70 and a black-ink cap portion 71 that are formed integrally with each other. The color-ink cap portion 70 is adapted to fluid-tightly cover, altogether, the ink ejection nozzles 50 corresponding to the cyan ink C, the magenta ink M, and the yellow ink Y; and the black-ink cap portion 71 is adapted to fluid-tightly cover only the ink ejection nozzles 50 corresponding to the black ink K. Since the color-ink cap portion 70 and the black-ink cap portion 71 are separate from each other, the color inks C, M, Y are not mixed with the black ink K in the cap member 49 when the inks C, M, Y, K are sucked from the ink-jet recording head 40. Therefore, the inks C, M, Y, K are prevented from being mixed with each other in the ink ejection nozzles 50 of the recording head 40.
The waste-ink tray 48 is for receiving the inks when the ink-jet recording head 40 carries out an idling operation that is called a “flushing” operation. When the flushing operation is carried out, the recording head 40 (or the carriage 44) is moved to the left-hand end portion of the movement range W2, so that the recording head 40 ejects the droplets of inks toward the waste-ink tray 48. However, that the purging device 47 and the waste-ink tray 48 are provided in the right-hand and left-hand end portions of the movement range W2, respectively, is not essentially required. For example, the purging device 47 and the waste-ink tray 48 may be provided vice versa, i.e., in the left-hand and right-hand end portions of the movement range W2, respectively, or may be both provided in one of the two end portions of the range W2.
Next, the metallic frame assembly 72 will be described in detail by reference to
The main frame 73 has, at lengthwise opposite ends thereof, two end plates 74, 75, respectively, that are integrally formed with the remaining portion of the member 73. More specifically described, the two end plates 74, 75 are formed by bending, upward, lengthwise opposite end portions of a bottom plate of the main frame 73. However, the end plates 74, 75 may be produced independent of the remaining portion of the main frame 73, and may be attached to the remaining portion by appropriate means such as welding.
As shown in
The first end plate 74 has, at respective appropriate positions, two recessed portions 90, 91 (i.e., two bearing portions). Likewise, the second end plate 75 has, at respective appropriate positions, two recessed portions 92, 93 (i.e., two bearing portions). The two recessed portions 90, 92 are located on an axis line parallel to the lengthwise direction of the main frame 73, and are opposed to each other in that direction. Likewise, the two recessed portions 91, 93 are located on another axis line parallel to the lengthwise direction of the main frame 73, and are opposed to each other in that direction. The two recessed portions 90, 92 function as two bearing portions that cooperate with each other to bear the axis member of the first drive roller 55 as the feed roller (
The main frame 73 has many through-holes and openings including openings 94, 95. Those through-holes and openings are used for avoiding the physical interference of the main frame 73 with various components attached to peripheral devices, or for attaching, to the main frame 73, brackets to which other components are fixed, or for attaching, to the main frame 73, fixing members to fix the frame assembly 72 as a whole to the casing of the printer 11 or the scanner portion 12.
The upstream-side, i.e., first slide-base member 42 is an elongate, plate-like member, and has a generally U-shaped transverse cross section. The first slide-base member 42 extends parallel to the lengthwise direction of the main frame 73, and includes a bottom-wall portion 96 and two side-wall portions 97, 98 respectively provided at widthwise opposite ends of the bottom-wall portion 96. An upper surface of the bottom-wall portion 96 supports one end portion of the carriage 40 carrying the ink-jet recording head 40, such that the carriage 40 is movable relative to the bottom-wall portion 96. A low-friction tape 128 having a low friction coefficient is adhered to a portion of the bottom-wall portion 96 that supports the one end portion of the carriage 44 and guides the movement of the same 44. Thus, the carriage 44 can be smoothly moved along the first slide-base member 42.
The bottom-wall portion 96 of the first slide-base member 42 has two elongate through-holes 99, 100 (e.g., two engaging recesses). As shown in
As shown in
Like the first slide-base member 42, the downstream-side, i.e., second slide-base member 43 is an elongate, plate-like member, and has a generally U-shaped transverse cross section. The second slide-base member 43 is distant from, and is opposed to, the first slide-base member 42 in the sheet-feed direction A (
The bottom-wall portion 102 of the second slide-base member 43 has two elongate through-holes 105, 106 (e.g., two engaging recesses) and two elongate through-holes 107, 108 (e.g., two engaging recesses). As shown in
As shown in
As described above, the through-hole 100 of the first slide-base member 42 and the projection 87 of the shoulder portion 83 of the main frame 73 are aligned with each other, and the projection 87 is fitted in the through-hole 100, as shown in
As shown in
As shown in
The above-described two spring members 109 are fitted in the respective through-holes 106 of the two projections 87, 80. As shown in
As shown in
If the operator releases each spring member 109 after it is fitted in the corresponding through-hole 106 and the corresponding spring accommodating portion 101, the each spring member 109 is elastically restored to its original shape, i.e., the two leg portions 119, 120 thereof are moved away from each other along the horizontal, upper surface 121 of the bottom-wall portion 96 of the first slide-base member 42. Consequently the two leg portions 119, 120 of each spring member 109 are elastically pressed against the two inclined surfaces 117, 118 of the corresponding projection 87, 80, respectively. Since the two inclined surfaces 117, 118 are inclined in the above-described manner, the two leg portions 119, 120 that are being elastically pressed against the two inclined surfaces 117, 118, respectively, are moved toward the bottom-wall portion 96 of the first slide-base member 42, while being guided by the two inclined surfaces 117, 118, respectively. Thus, the two leg portions 119, 120 of each spring member 109 are pressed, owing to the respective elastic forces thereof, against the upper surface 121 of the bottom-wall portion 96 of the first slide-base member 42, and the first slide-base member 42 is elastically biased toward the two shoulder portions 83, 76 of the main frame 73, owing to the respective pressing forces caused by the respective elastic forces of the two spring members 109.
The two spring members 109 and the two projections 87, 80 cooperate with each other to constitute a first elastically biasing device that elastically biases the first slide-base member 42 toward the main frame 73. Since the two spring members 109 are attached to the frame assembly 72 in the above-described manner, the first slide-base member 42 is accurately attached or fixed to the main frame 73, such that the first slide-base member 42 extends accurately parallel to the elongate platen 41 positioned relative to the main frame 73. Moreover, since the two spring members 109 can be easily removed from the frame assembly 72, the first slide-base member 42 is easily detachable from the main frame 73.
Like the first slide-base member 42, the through-holes 107, 108 of the second slide-base member 43, and the projections 88, 89 of the shoulder portion 84 of the main frame 73 are aligned with each other, and the projections 88, 89 are fitted in the through-holes 107, 108, as shown in
As shown in
As shown in
One of the above-described two spring members 114 is engaged with the two projections 88, 89; and the other spring member 114 is engaged with the two projections 81, 82. As shown in
As shown in
If the operator releases each spring member 114 after it is engaged with the corresponding one pair of projections 88, 89, or 81, 82, the each spring member 114 is elastically restored to its original shape, i.e., the two leg portions 125, 126 thereof are moved toward each other along the horizontal, upper surface 127 of the bottom-wall portion 102 of the second slide-base member 43. Consequently the two leg portions 125, 126 of each spring member 114 are elastically pressed against the respective inclined surfaces 125, 126 of the corresponding pair of projections 88, 89, or 81, 82. Since the two inclined surfaces 123, 124 are inclined in the above-described manner, the two leg portions 125, 126 that are being elastically pressed against the two inclined surfaces 123, 124, respectively, are moved toward the bottom-wall portion 102 of the second slide-base member 43, while being guided by the two inclined surfaces 123, 124, respectively. Thus, the two leg portions 125, 126 of each spring member 114 are pressed, owing to the respective elastic forces thereof, against the upper surface 127 of the bottom-wall portion 102 of the second slide-base member 43, and the second slide-base member 43 is elastically biased toward the two shoulder portions 84, 77 of the main frame 73, owing to the respective pressing forces caused by the respective elastic forces of the two spring members 114.
The two spring members 114 and the four projections 88, 89, 81, 82 cooperate with each other to constitute a second elastically biasing device that elastically biases the second slide-base member 43 toward the main frame 73. Since the two spring members 114 are attached to the frame assembly 72 in the above-described manner, the second slide-base member 43 is accurately attached or fixed to the main frame 73, such that the second slide-base member 43 extends accurately parallel to the elongate platen 41 positioned relative to the main frame 73. Moreover, since the two spring members 114 can be easily removed from the frame assembly 72, the second slide-base member 43 is easily detachable from the main frame 73.
In the MFD 10 constructed as described above, the image recording portion 24 is produced in the following method: First, the first and second slide-base members 42, 43 are assembled with the main frame 73 so as to provide the frame assembly 72. Then, whether this frame assembly 72 has a designed or required accuracy, i.e., whether the two slide-base members 42, 43 are sufficiently accurately positioned relative to the main frame 73 is judged or inspected. Unless the slide-base members 42, 43 are sufficiently accurately positioned relative to the main frame 73, and unless the inaccuracy can be corrected, then the frame assembly 72 is discarded as a defective one.
On the other hand, the frame assembly 72 that has passed the inspection is temporarily disassembled into the main frame 73 and the two slide-base members 42, 43, without using a tool such as a screw driver. Then, the platen 41 is attached to an appropriate position or portion of the main frame 73 free of the slide-base members 42, 43. Since the slide-base members 42, 43 are not attached to the main frame 73, the operator can easily attach the elongate platen 41 to the main frame 73. Therefore, the platen 41 can be easily and accurately positioned relative to the appropriate portion of the main frame 73.
Subsequently, each of the two slide-base members 42, 43 is attached to the main frame 73, with the corresponding positioning device and the corresponding elastically biasing device. Therefore, the two slide-base members 42, 43 can be positioned relative to the platen 41 such that the elongate slide-base members 42, 43 extend accurately parallel to the elongate platen 41. Since the slide-base members 42, 43 are positioned relative, and fixed, to the main frame 73 owing to the respective elastic forces of the spring members 109, 114, no local stresses or deformations are produced in the slide-base members 42, 43 or the main frame 73. Thus, the slide-base members 42, 43 are not tilted relative to the platen 41, and are maintained accurately parallel to the same 41. In addition, since the slide-base members 42, 43 are fixed to the main frame 73 without using any bolts or nuts, it is not needed to provide, in the frame assembly 72, any spaces in which the bolts or nuts are to be disposed. Thus, the MFD 10 can enjoy a reduced size.
Then, the ink-jet recording head 40 is attached to the two slide-base members 42, 43. Since the two slide-base members 42, 43 are attached to the main frame 73 such that the slide-base members 42, 43 extend parallel to the platen 41, the recording head 40 can be moved on the slide-base members 42, 43, along the elongate platen 41, without being tilted relative to the platen 41. However, the ink-jet recording head 40 may be attached to the two slide-base members 42, 43, before the slide-base members 42, 43 are attached to the main frame 73.
Thus, in the present embodiment, when the MFD 10 is produced, in particular, when the image recording portion 24 is produced, the frame assembly 72 is assembled once so as to be judged with respect to the accuracy of assembling. Thus, when the MFD 10 is produced, a defective frame assembly or assemblies 72 can be discarded with reliability. That is, the MFD 10 can be produced under a high-grade quality control. After the accuracy of the frame assembly 72 is thus checked, the frame assembly 72 is disassembled and, in the state in which the two slide-base members 42, 43 are separate from the main frame 73, the elongate platen 41 is attached to the main frame 73. Then, the two slide-base members 42, 43 are positioned relative, and fixed, to the main frame 73, and the ink-jet recording head 40 is mounted on the slide-base members 42, 43. Therefore, the assembling of the MFD 10, in particular, the image recording portion 24 can be easily carried out, while the platen 41 and the recording head 40 are accurately assembled with the frame assembly 72.
In addition, in the present embodiment, the frame assembly 72 has the four recessed portions 90, 91, 92, 93 (
In addition, the two slide-base members 42, 43 are supported by the four shoulder portions 76, 77, 83, 84 of the main frame 73, by being placed on the respective support surfaces 78, 79, 85, 86 of the shoulder portions 76, 77, 83, 84. Since the six projections 80, 81, 82, 87, 88, 89 projecting from the four support surfaces 78, 79, 85, 86 fit in the six through-holes 99, 105, 106, 100, 107, 108 of the two slide-base members 42, 43, respectively, the two slide-base members 42, 43 are accurately positioned relative to the main frame 73. Thus, the two positioning devices that respectively position the two slide-base members 42, 43 relative to the main frame 73 enjoy a simple arrangement, which leads to reducing the production cost of the frame assembly 72. The respective support surfaces 78, 79, 85, 86 of the shoulder portions 76, 77, 83, 84 cooperate with each other to define the horizontal plane as the reference plane, and the six projections 80, 81, 82, 87, 88, 89 of the main frame 73 and the six through-holes 99, 105, 106, 100, 107, 108 of the two slide-base members 42, 43 cooperate with each other to constitute two on-line positioning portions each of which positions a corresponding one of the two slide-base members 42, 43 relative to the main frame 73 in each of the two horizontal directions perpendicular to each other.
Moreover, the four spring members 109, 114 are attached to the frame assembly 72 in the state in which the two slide-base members 42, 43 are attached to the main frame 73. Thus, owing to the respective biasing forces caused by the respective elastic forces of the four spring members 109, 114, the two slide-base members 42, 43 are biased toward the main frame 73. The respective elastic forces of the four spring members 109, 114 can be easily converted into the respective biasing forces, by the eight inclined surfaces 117, 118, 123, 124 of the six projections 80, 81, 82, 87, 88, 89. Thus, the two elastically biasing devices that elastically bias the two slide-base members 42, 43 to the main frame 73, respectively, enjoy a simple arrangement, which leads to further reducing the production cost of the frame assembly 72 or the image recording portion 24. In addition, since each of the four spring members 109, 114 can move or displace along the corresponding two inclined surfaces 117, 118, 123, 124, the vibration of the frame assembly 72 can be absorbed by the spring members 109, 114, which leads to improving the quality of images recorded on each recording sheet.
In particular, in the present embodiment, the six projections 80, 81, 82, 87, 88, 89 that are used for positioning the two slide-base members 42, 43 are also used for holding the four spring members 109, 114. Thus, each of the two positioning devices and the two elastically biasing devices enjoy a still simpler arrangement.
Each of the four spring members 109, 114 is formed by bending or curving, on a plane, a metallic wire such as a spring-steel wire. Thus, each of the four biasing members 109, 114 that bias the two slide-base members 42, 43 toward the main frame 73 enjoys a simple arrangement and a low cost, which leads to reducing the production cost of the image recording portion 24. In addition, since each of the four metallic-wire-based spring members 109, 114 is attached to the frame assembly 72 so as to be extended parallel to the corresponding slide-base member 42, 43 and be pressed thereon, the vibration of the frame assembly 72 can be effectively absorbed, which leads to improving the quality of images recorded on each recording sheet.
In addition, each first spring member 109 as a portion of the first biasing device that biases the first slide-base member 42 toward the main frame 73 has the two symmetric leg portions 119, 120 that are moved or displaced in opposite directions, respectively, when the each first spring member 109 is elastically restored to its original shape after being elastically deformed. The two symmetric leg portions 119, 120 are held in pressed contact with the two symmetric inclined surfaces 117, 118 (
In the present embodiment, each of the four spring members 109, 114 has a symmetric shape. However, each spring member may have an asymmetric shape so long as two portions thereof that are engaged with the two inclined surfaces 117, 118, or 123, 124, respectively, are moved or displaced in opposite directions, respectively, when the each spring member is elastically restored to its original shape after being elastically deformed.
It is to be understood that the present invention may be embodied with various changes, modifications, and improvements that may occur to a person skilled in the art without departing from the spirit and scope of the invention defined in the appended claims.
Number | Date | Country | Kind |
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2005281247 | Sep 2005 | JP | national |