JP2004268338A - Liquid injection device - Google Patents

Abstract

A guide shaft for supporting a carriage in a reciprocating manner is fixedly supported on a liquid ejecting apparatus at a low cost with high precision and with a low possibility of being bent by a force acting on the carriage.
An end portion of a left side frame is provided with a support portion extending from the left side frame, an arm portion formed by bending a part of the left side frame at a substantially right angle, and an arm portion. A flexure restricting portion 113 formed by bending and raising the tip of 112 is formed. The carriage guide shaft 61 is screwed and fixed to a hole 114 formed in the arm portion 112 by a screw 115 inserted into a through hole 61 a formed in the carriage guide shaft 61 while being supported by the support portion 111, and flexed. It is supported by the restricting portion 113 in a state where the bending is restricted. The same applies to the end of the right side frame 501.
[Selection] Fig. 9

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a liquid ejecting apparatus having a liquid ejecting head for ejecting a liquid to a material to be ejected and having a carriage supported reciprocally in a predetermined scanning direction.
[0002]
Here, the liquid ejecting apparatus is not limited to a recording apparatus such as an ink jet type recording apparatus, a copying machine, and a facsimile which executes recording on a recording material by ejecting ink from a recording head to a recording material such as recording paper. Including a device for ejecting a liquid corresponding to a specific application from a liquid ejecting head corresponding to the above-described recording head to an ejecting material corresponding to a recording material in place of ink, and attaching the liquid to the ejecting material. Use in meaning. As the liquid ejecting head, in addition to the recording head described above, a color material ejecting head used for manufacturing a color filter such as a liquid crystal display, an electrode material used for forming an electrode such as an organic EL display or a surface emitting display (FED) ( A conductive paste) injection head, a biological organic material injection head used for biochip production, a sample injection head for injecting a sample as a precision pipette, and the like.
[0003]
[Prior art]
In a liquid ejecting apparatus that ejects a liquid while causing a liquid ejecting head that ejects a liquid to a material to be ejected to scan relative to the material to be ejected, as a means for causing the liquid ejecting head to scan relatively to the material to be ejected 2. Description of the Related Art There is known a liquid ejecting apparatus including a carriage that is supported by a guide shaft supported by a liquid ejecting apparatus main body in parallel with a scanning direction of a liquid ejecting head and is reciprocally movable in a predetermined scanning direction. . In such a liquid ejecting apparatus, as a means for switching or adjusting an interval (liquid ejecting interval) between a head surface of a liquid ejecting head and a material to be ejected to a predetermined interval, a carriage is pivoted with respect to a liquid ejecting apparatus main body. In general, a means for displacing the supporting guide shaft is provided on the liquid ejecting apparatus main body side supporting both ends of the guide shaft.For example, an eccentric rotating mechanism using eccentric bushes at both ends of the guide shaft is provided. 2. Description of the Related Art A recording device such as an ink jet recording device in which both ends of a guide shaft are supported by supporting means having the same is known (for example, see Patent Documents 1, 2, and 3).
[0004]
However, since the guide shaft that supports the carriage is displaced, it becomes difficult to support the carriage with higher precision. This is because the guide shaft is axially supported via a mechanism for displacing the guide shaft, and errors and rattling of the mechanism for displacing the guide shaft are caused by parallel movement of the liquid ejecting head mounted on the carriage. This is because it affects the degree and the liquid ejection interval. Further, if the guide shaft is supported only by both ends of the guide shaft, the guide shaft is bent by the weight of the carriage that is supported. As a result, the liquid ejection interval in the vicinity of the center becomes shorter than the liquid ejection interval in the vicinity of both ends of the guide shaft, and the liquid ejection interval is not constant. Is particularly remarkable as the liquid ejecting apparatus is large and the guide shaft is long. If the vicinity of the center of the guide shaft is also supported by the main body of the liquid ejecting apparatus, the deflection of the guide shaft due to the weight of the carriage can be prevented. However, if the support means of the guide shaft is supported at three places near both ends and near the center, The mechanism for displacing the guide shaft becomes large and complicated, and it is possible to switch and adjust the liquid ejection interval by displacing it with an accurate displacement while maintaining the parallelism of the liquid ejection head with high accuracy. It is extremely difficult and unrealistic.
[0005]
Therefore, as an example of the prior art which has solved such a problem, a technique is known in which a guide shaft is fixedly supported by a liquid ejecting apparatus and a means for displacing the liquid ejecting head is provided in a carriage (for example, Patent Document 4). And Patent Document 5). Since the liquid ejecting head is displaced in the carriage without displacing the guide shaft, the guide shaft can be firmly fixed and supported on the liquid ejecting apparatus main body with high accuracy. Therefore, it is possible to extremely reduce the deflection and rattling of the guide shaft, thereby making it possible to make the parallelism of the liquid ejecting head and the liquid ejecting interval constant with high accuracy. Will be possible.
[0006]
[Patent Document 1]
Japanese Patent Application Laid-Open No. 10-21748 [Patent Document 2]
JP 2002-36660 A [Patent Document 3]
JP 2002-127543 A [Patent Document 4]
JP 2001-158147 A [Patent Document 5]
JP 2001-158148 A
[Problems to be solved by the invention]
The rattling of the guide shaft can be easily reduced to a level that does not affect the liquid ejection accuracy by firmly fixing and supporting the guide shaft to the liquid ejecting apparatus with high accuracy. Of the guide shaft due to the force acting on the carriage when the carriage or the carriage reciprocates, it is necessary to provide some means for restricting the guide shaft from bending. For example, as described above, in addition to the both ends of the guide shaft, the vicinity of the center of the guide shaft is also fixedly supported on the liquid ejecting apparatus main body, and the guide shaft is fixedly supported at three positions near the both ends and the center. Such deflection of the guide shaft can be significantly reduced.
[0008]
However, the guide shaft that supports the carriage needs to be arranged in parallel with the scanning direction of the liquid ejecting head with high accuracy, and the surface of the material to be ejected and the liquid ejecting head mounted on the carriage are required. Must be arranged in parallel with the head surface with high precision. For this reason, if the guide shaft is fixedly supported at three locations near both ends and near the center, it becomes extremely difficult to define and support the support position of the guide shaft with high accuracy. In other words, when the guide shaft is fixedly supported at three positions near both ends and near the center, a gap is easily formed between the guide shaft and any one of the three support portions, and the guide is fixed at the fixed support portion near the center. Since the shaft may be fixed in a bent state, it is extremely difficult to support the guide shaft in a state of being arranged in parallel.
[0009]
Further, in recent high-speed liquid ejecting apparatuses, the reciprocating speed of the carriage is high, and the carriage is rapidly accelerated and suddenly stopped. Therefore, a large scanning direction force acts on the carriage, and a large bending is applied to the guide shaft. There is a possibility that this will occur. Further, Patent Documents 4 and 5 described above do not disclose in detail means for fixing and supporting a guide shaft to a liquid ejecting apparatus with high accuracy. And, for example, if the guide shaft is formed of a metal material having extremely high rigidity, or if a complicated adjustment mechanism or the like is provided in the support portion of the guide shaft, it is possible to reduce the possibility that the guide shaft is bent. However, this leads to a significant increase in the cost of the liquid ejecting apparatus, and it can be said that this is not practical in a liquid ejecting apparatus such as an ink jet recording apparatus which requires high cost performance.
[0010]
SUMMARY OF THE INVENTION The present invention has been made in view of such a situation, and an object thereof is to provide a state in which a guide shaft that supports a carriage so as to be able to reciprocate with high accuracy is less likely to be bent by a force acting on the carriage. Another object of the present invention is to fix and support the liquid ejecting apparatus at low cost.
[0011]
[Means for Solving the Problems]
In order to achieve the above object, a first aspect of the present invention is a substantially cylindrical body in which a carriage having a liquid ejecting head for ejecting a liquid to a material to be ejected is disposed in parallel with a scanning direction of the liquid ejecting head. A liquid ejecting apparatus rotatably supported by a carriage guide shaft, comprising: a side frame disposed in a direction substantially orthogonal to the scanning direction near both sides in the scanning direction; A support portion extending from the side frame, an arm portion formed by bending a part of the side frame at a substantially right angle, and a bending restriction formed by bending and raising the tip of the arm portion. And the carriage guide shaft is screwed and fixed to the arm portion while being supported by the support portion, and the carriage guide shaft is supported by the flexure restricting portion and the flexure is regulated. It is lifting, it is a liquid ejecting apparatus characterized by.
[0012]
As described above, since the carriage guide shaft is supported at two points near both ends by the support portion formed integrally with the side frame, the carriage guide shaft becomes parallel to the scanning direction of the liquid ejecting head with high accuracy. In this way, it is easy to arrange the surface to be ejected of the material to be ejected and the head surface of the liquid ejecting head mounted on the carriage in parallel with high accuracy. In addition, a carriage guide shaft that is supported at two points near both ends by a support portion formed integrally with the side frame is screwed and fixed to an arm portion formed by bending a part of the side frame at a substantially right angle. Therefore, the carriage guide shaft can be fixedly supported on the liquid ejecting apparatus with high accuracy.
[0013]
Further, the carriage guide shaft is supported in a state where the bending thereof is restricted by a bending restricting portion formed by bending and raising a tip of an arm portion formed by bending a part of the side frame at a substantially right angle. It is possible to reduce the possibility that the guide shaft is bent by the force in the scanning direction acting on the carriage when reciprocating. The support portion is a part of the side frame, and the arm portion and the deflection control portion are formed by bending a part of the side frame. That is, the support portion, the arm portion, and the deflection control portion are , All are formed as a part of the side frame, so that the carriage guide shaft can be supported with high precision at extremely low cost.
[0014]
Here, the side frames are frames arranged in the direction substantially orthogonal to the scanning direction in the vicinity of both sides of the liquid ejecting apparatus in the scanning direction, and constitute a part of the housing of the liquid ejecting apparatus. In general, components constituting the liquid ejecting apparatus, including the carriage guide shaft, are provided, and are generally formed of a single large metal plate having a thickness capable of obtaining a certain strength.
[0015]
Thus, according to the liquid ejecting apparatus shown in the first aspect of the present invention, the carriage guide shaft that supports the carriage in a reciprocating manner can be bent with high precision and with a low possibility of being bent by the force acting on the carriage. The effect of being able to be fixedly supported on the liquid ejecting apparatus at low cost is obtained.
[0016]
According to a second aspect of the present invention, in the liquid ejecting apparatus according to the first aspect, the side frame is disposed immediately outside the maximum width of the material to be ejected.
[0017]
As described above, since the side frames are respectively disposed immediately outside the maximum width of the material to be injected, the distance between the side frames can be made the narrowest. Therefore, the effect of being able to make the vicinity of the center of the carriage guide shaft more difficult to flex while enabling the liquid to be ejected to the material to be ejected having the maximum width is obtained.
[0018]
According to a third aspect of the present invention, in the first or second aspect described above, the reinforcing plate for preventing deformation of the arm due to a force acting on the deflection restricting portion from the carriage guide shaft is provided on the arm. The liquid ejecting apparatus is characterized in that the liquid ejecting apparatus is mounted on the liquid ejecting apparatus.
[0019]
Since the flexure restricting portion is formed by bending and raising the tip of the arm portion, a force for flexing the carriage guide shaft by the carriage's own weight or a force acting on the carriage when the carriage reciprocates is a flexure restricting portion. Will work. For this reason, there is a possibility that the bent portion of the bending restricting portion formed by bending and raising the arm portion is deformed by the force, and the bending restricting portion is displaced and bent to a position separated from the carriage guide shaft. Therefore, the strength of the arm is increased by laying a reinforcing plate on the arm to prevent the deformation of the arm, so that the arm is prevented from being deformed by the force acting on the deflection regulating portion from the carriage guide shaft. The operation and effect can be obtained. The material of the reinforcing plate preferably has a hardness equal to or higher than that of the side frame.
[0020]
According to a fourth aspect of the present invention, in the above-described third aspect, the reinforcing plate is co-tightened to the arm with a screw for screwing the carriage guide shaft to the arm. This is a liquid ejecting apparatus.
[0021]
In this manner, the reinforcing plate is fastened to the arm with the screw for screwing the carriage guide shaft to the arm, so that the work of screwing the carriage guide shaft and the mounting of the reinforcing plate can be performed simultaneously, and In the manufacturing process of (1), the work efficiency when attaching the carriage guide shaft can be improved.
[0022]
According to a fifth aspect of the present invention, in the above-described fourth aspect, a reinforcing plate holding portion that engages with the reinforcing plate and holds the reinforcing plate at a position where the reinforcing plate is attached to the arm portion is integrated with the arm portion. The liquid ejecting apparatus is characterized in that the liquid ejecting apparatus is formed as follows.
[0023]
As described above, since the reinforcing plate holding portion is formed integrally with the arm portion, there is no need to manually support the reinforcing plate when the carriage guide shaft is screwed together with the arm portion and the reinforcing plate and screwed. Therefore, in the manufacturing process of the liquid ejecting apparatus, the workability when attaching the carriage guide shaft can be improved.
[0024]
In a sixth aspect of the present invention, in any one of the first to fifth aspects described above, a position at which the carriage guide shaft is screwed to the arm portion is disposed closer to the deflection regulating portion. A liquid ejecting apparatus characterized in that:
[0025]
Thus, by arranging the screwing position of the carriage guide shaft to the arm near the deflection regulating portion, the length of the arm from the screwing portion of the carriage guide shaft to the deflection regulating portion can be shortened. . As a result, the strength of the bent portion of the deflection control portion formed by bending and raising the arm portion can be increased, and as described above, the arm portion is caused by the weight of the carriage and the force acting on the carriage when the carriage reciprocates. This can further reduce the possibility that the bent portion of the bending restricting portion formed by bending and bending is deformed, and the bending restricting portion is displaced and bent to a position separated from the carriage guide shaft.
[0026]
According to a seventh aspect of the present invention, in any one of the first to sixth aspects described above, the length of the deflection restricting portion is a fulcrum of the carriage guide shaft of the support portion from the arm portion. A liquid ejecting apparatus characterized in that the liquid ejecting apparatus is formed to have a length shorter than a length up to an end.
[0027]
As described above, since the arm portion is formed by bending a part of the side frame at a substantially right angle, the carriage guide shaft is screwed to the arm portion, and the arm portion is further tightened so that the arm portion becomes the carriage guide. It will bend in the direction pulled toward the shaft. Therefore, the bending restricting portion formed by bending and raising the tip of the arm portion is pulled toward the carriage guide shaft side by the bending of the arm portion, so that the screw that fixes the carriage guide shaft to the arm portion is screwed. By adjusting the degree of tightening, the bending restricting position of the bending restricting portion can be adjusted. Therefore, the length of the deflection control portion is set to be shorter than the length from the arm portion to the end portion of the support portion serving as the fulcrum of the carriage guide shaft, and the screw for screwing the carriage guide shaft to the arm portion is used. By adjusting the degree of tightening of the deflection restricting portion to adjust the deflection restricting position of the deflection restricting portion, the length of the deflection restricting portion becomes slightly longer due to variation in processing accuracy when forming the deflection restricting portion. Thus, it is possible to prevent the deflection regulating portion from pushing up the carriage guide shaft and causing the carriage guide shaft to float from the support portion.
[0028]
According to an eighth aspect of the present invention, in any one of the first to seventh aspects described above, the support portion has an end serving as a fulcrum of the carriage guide shaft, the end of the carriage guide shaft with respect to the arm portion. A liquid ejecting apparatus having a flat shape in a direction substantially perpendicular to a screwing direction.
[0029]
Since the end serving as the fulcrum of the carriage guide shaft has a flat shape as described above, the fulcrum of the carriage guide shaft can be defined with high accuracy, and the carriage guide shaft can be supported with higher accuracy. Can be. Further, since the end serving as the fulcrum of the carriage guide shaft has a flat shape in a direction substantially perpendicular to the screwing direction of the carriage guide shaft, the load of the carriage guide shaft acts uniformly on the support portion, and Thus, the carriage guide shaft can be supported in a more stable state, and the possibility of rattling in the support portion can be reduced, and the end of the support portion is deformed by the force from the carriage guide shaft. It is possible to further reduce the risk of occurrence.
[0030]
According to a ninth aspect of the present invention, in the above-described eighth aspect, the support portion regulates a support position of the carriage guide shaft in a direction in which an end serving as a fulcrum of the carriage guide shaft is orthogonal to the scanning direction. This is a liquid ejecting apparatus characterized in that the liquid ejecting apparatus has a shape as follows.
[0031]
In this manner, the support portion has a shape in which the end serving as the fulcrum of the carriage guide shaft regulates the support position of the carriage guide shaft in a direction orthogonal to the scanning direction of the liquid ejection head. The position in the direction orthogonal to the axial direction of the carriage guide shaft fixed and supported in parallel with the scanning direction can be regulated. Therefore, the support position of the carriage guide shaft can be defined with higher accuracy.
[0032]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings. First, a schematic configuration of an ink jet recording apparatus as a “liquid ejecting apparatus” according to the present invention will be described.
[0033]
FIG. 1 is a perspective view showing the appearance of an ink jet recording apparatus according to the present invention. FIG. 2 is a schematic side view showing a schematic configuration of the ink jet recording apparatus according to the present invention, FIG. 3 is a perspective view of a main part of the ink jet recording apparatus according to the present invention, and FIG. FIG. 2 is a plan view of a main part of the ink jet recording apparatus according to the present invention. FIG. 5 is an enlarged perspective view of a main part of an inkjet recording apparatus according to the present invention, and FIG. 6 is an enlarged perspective view of a part of the inkjet recording apparatus according to the present invention. FIG. 7 is a side view of a main part of the ink jet recording apparatus according to the present invention.
[0034]
In the ink jet recording apparatus 50, a paper cassette 7 capable of stacking printing paper P such as plain paper is removably provided on the front surface, and printing is performed on the printing paper P fed from the paper cassette 7. The printing paper P after printing is discharged to the discharge tray 7a. Inside the paper feed cassette 7, a hopper 71 constituting an "automatic feeding means" for automatically feeding the printing paper P stacked in the paper feed cassette 7 can swing about a shaft 72 as a swing axis. It is arranged in. At the time of paper feeding, the hopper 71 swings upward by the spring force of the contracted spring 71a, and the uppermost printing paper P of the printing papers P stacked on the hopper 71 is disposed on the paper feeding cassette 7 side. Is pressed by the pick-up roller 73. The printing paper P is pulled out of the paper supply cassette 7 by the rotation of the pickup roller 73, and is sent out in the paper supply direction A toward the paper supply roller 74 and the reverse roller 75 arranged on the ink jet recording apparatus 50 side.
[0035]
The ink jet type recording apparatus 50 is provided with a paper feed roller 74 and a reverse roller 75 which constitute "automatic feeding means". The paper feed roller 74 is driven to rotate in the paper feed rotation direction AF by the rotation driving force of the paper feed drive motor 58 being transmitted. The reverse roller 75 is supported by a shaft 751 so as to be driven and rotatable with a certain rotational resistance and is pressed against the paper feed roller 74. The shaft 751 transmits the rotational driving force of the paper feed drive motor 58. Then, it is driven and rotated in the paper return rotation direction RR. The printing paper P pulled out of the paper supply cassette 7 by the rotation of the pickup roller 73 is driven to rotate in the paper supply rotation direction AF of the paper supply roller 74 while being sandwiched between the reverse roller 75 and the paper supply roller 74. As a result, paper is fed toward the transport driving roller 51 and the transport driven roller 52.
[0036]
The reverse roller 75 is rotatably supported by a shaft 751 that is driven and rotated in the paper return rotation direction RR so as to be driven and rotatable with a certain rotational resistance. This rotation resistance is set to be smaller than the frictional resistance of the peripheral surface of the paper feed roller 74 and larger than the frictional resistance between the overlapping printing papers P. That is, if the friction coefficient between the paper feed roller 74 and the printing paper P is μ1, the friction coefficient between the printing paper P is μ2, and the friction coefficient between the printing paper P and the reverse roller 75 is μ3, μ1> μ3 The high friction material that forms the outer peripheral surfaces of the feed roller 74 and the reverse roller 75 is selected so that the relationship of> μ2 is satisfied.
[0037]
Therefore, when a plurality of printing papers P are sandwiched between the paper feeding roller 74 and the reverse roller 75, only the uppermost printing paper P is in contact with the peripheral surface of the paper feeding roller 74 and The paper is fed by the drive rotation of 74. Since the driven rotation resistance of the reverse roller 75 is larger than the friction resistance between the overlapped printing papers P, the reverse rotation of the reverse roller 75 is caused to rotate in the paper return rotation direction RR by the drive rotation of the shaft 751 (paper return rotation direction RR). The printing paper P other than the printing paper P is returned to the paper feed cassette 7 by the rotation of the reverse roller 75 in the paper return rotation direction RR. When only one printing sheet P is sandwiched between the sheet feeding roller 74 and the reverse roller 75, the frictional resistance of the peripheral surface of the sheet feeding roller 74 is larger than the driven rotation resistance of the reverse roller 75. The reverse roller 75 is driven to rotate in the paper feed driven rotation direction RF while being in contact with the printing paper P fed by the paper feed roller 74. In this way, the feeding roller 74 and the reverse roller 75 which functions to separate the printing paper P to be multi-fed can be fed without causing the plurality of printing papers P to be fed in an overlapping state. The printing paper P is fed one by one from the cassette 7.
[0038]
The fed printing paper P is conveyed in the sub-scanning direction Y by a predetermined conveyance amount by the driving rotation of the conveyance driving roller 51 while being sandwiched between the conveyance driving roller 51 and the conveyance driven roller 52. The transport drive roller 51 has a high frictional resistance film formed on the peripheral surface of the transport drive roller 51 in contact with the printing paper P, and is rotated by the rotational driving force of the transport drive motor 59 transmitted through the endless belt 591. The plurality of transport driven rollers 52 are individually urged by the transport drive rollers 51 while being rotatably supported by the transport driven roller holder 521. The printing paper P is brought into close contact with the peripheral surface of the transport driving roller 51 by the urging force of the transport driven roller 52, and is rotated by a predetermined rotation amount at a predetermined transport amount in the sub-scanning direction Y by rotation of the transport driving roller 51. Conveyed with high precision. After the leading end of the printing paper P is sandwiched between the transport driving roller 51 and the transport driven roller 52, the reverse roller 75 does not hinder the transport operation of the printing paper P by the transport driving roller 51, that is, reduces the transport load. It is separated from the paper feed roller 74 so as not to give it.
[0039]
The ink jet recording apparatus 50 is a recording head 4 serving as a “liquid ejecting head” as a unit that ejects ink onto the printing surface of the printing paper P conveyed on the platen 53 in the sub-scanning direction Y by the rotation of the conveyance driving roller 51. Is provided. The carriage 1 includes a main carriage 2 supported by a carriage guide shaft 61 so as to be able to reciprocate in the main scanning direction X, and a sub-carriage 3 on which a recording head 4 is mounted, and is formed on the main carriage 2. The bearing member 211 and the bearing member 212 provided on the bearing portion 21 are pivotally supported by the carriage guide shaft 61, and reciprocate in the main scanning direction X in a state where the convex portion 22 is in sliding contact with a paper discharge frame 503 described later. It is movably supported. The carriage guide shaft 61 is supported by the main body of the ink jet recording apparatus 50 in parallel with the main scanning direction X. The carriage guide shaft support 505 is provided on the right side frame 501 near the right end, and the left side is provided near the left end. The carriage 502 is fixedly supported on the frame 502 by a carriage guide shaft support portion 504. The carriage 1 is connected to an endless belt 63 as “carriage driving means” stretched in parallel with the carriage guide shaft 61. The endless belt 63 is stretched between a driving rotation shaft 64 of a carriage driving motor 67 as a “carriage driving force source” and the driven pulley 62, and is rotated in both directions by the driving rotation of the carriage driving motor 67. I do. The carriage 1 reciprocates in the main scanning direction X by the bidirectional rotation of the endless belt 63. The support structure of the carriage 1 will be described later in detail.
[0040]
Further, the ink jet type recording apparatus 50 includes a paper discharge drive roller 54, a paper discharge driven roller 55, and a paper discharge auxiliary roller 56 as means for discharging the print paper P after printing to the paper discharge tray 7a. . The discharge drive roller 54 is rotated by the rotation driving force of the transport drive motor 59 described above. The paper discharge driven roller 55 is a toothed roller that has a plurality of teeth around it, and the tip of each tooth is sharply pointed so as to make point contact with the printing surface of the printing paper P. The plurality of paper ejection driven rollers 55 are urged by the paper ejection drive roller 54 in a state where they are rotatably supported by the paper ejection frame 503, respectively, and the printing paper P rotates the paper ejection drive roller 55. When the printing paper P is ejected, the printing paper P contacts with the printing paper P and is urged against the paper ejection drive roller 54, and rotates following the ejection of the printing paper P. Also, the paper discharge auxiliary roller 56 is rotatably supported by the paper discharge frame 503 so as to be rotatable, and is discharged to the paper discharge tray 7a while being rotated in contact with the printing surface of the print paper P discharged in the discharge direction B. Guide the printing paper P to be printed.
[0041]
Further, the ink jet recording apparatus 50 includes a linear encoder device for detecting the absolute position of the carriage 1. The linear encoder device has a linear scale 65 parallel to the carriage guide shaft 61 and a linear scale sensor 12 mounted on the carriage 1. The linear scale 65 has a belt-like transparent flexible film in which a number of slits are formed at regular intervals in the main scanning direction X, and a constant tension is applied by a spring 66 to arrange the linear scale without slack. It is stretched by. The linear scale sensor 12 detects the slit of the linear scale 65, converts the detection state of the slit into an electric pulse signal, and outputs the signal.
[0042]
Further, in the ink jet recording apparatus 50, the four ink cartridges 82 are provided not in the carriage 1 but in the ink cartridge accommodating portion 8, and are provided by an ink supply means (not shown) via an ink tube (not shown). Thus, the ink is supplied from the ink cartridge 82 to the carriage 1. The black ink cartridge 82K has an IC chip 83K carrying information about black ink mounted thereon, and the cyan ink cartridge 82C has an IC chip 83C carrying information about cyan ink mounted thereon, and the magenta ink cartridge 82M Is mounted with an IC chip 83M carrying information on magenta ink, and the yellow ink cartridge 82Y is equipped with an IC chip 83Y carrying information on yellow ink. Each IC chip 83 wirelessly communicates with a storage device (not shown) for storing variable information such as ink remaining amount, in addition to fixed information such as ink color, and a communication circuit board 84 mounted on the carriage 1. And a communication device (not shown).
[0043]
On the other hand, on the carriage 1 reciprocating in the main scanning direction X, a communication circuit board 84 for communicating with each of the IC chips 83 is set up substantially vertically by a communication circuit board frame 81. When the carriage 1 moves in the main scanning direction X, the communication circuit board 84 contacts the IC chip 83 of any one of the four ink cartridges 82 arranged in the main scanning direction X. opposite. Then, by communicating with the IC chip 83, it is possible to read and rewrite various information stored in the IC chip 83. The communication circuit board 84 is electrically connected to a circuit inside the carriage 1 via the connection section 85. Further, the communication circuit board frame 81 is a metal mounting frame having a shape that covers the periphery of the communication circuit board 84 as much as possible. Unnecessary radiation noise from 84 is shielded. The communication circuit board frame 81 is electrically connected to the housing of the ink jet type recording apparatus 50 and is grounded, so that an effect of reducing unnecessary radiation noise from the communication circuit board 84 can be obtained.
[0044]
Further, the ink jet recording apparatus 50 includes an ink system 100 that performs maintenance of the recording head 4 in a state where the moving position of the carriage 1 is at the home position. The ink system 100 uses the paper feed driving motor 58 as a driving force source to lock the carriage 1 to seal the head surface of the recording head 4 and to suck ink on the head surface of the recording head 4 as necessary. To fix the meniscus. The ink system 100 is provided with a cap 571 as a “sealing member” for sealing the recording head 4, and a direction perpendicular to the head surface of the recording head 4 (reference R ) Is provided with a cap case 57 as a “sealing member holder” disposed so as to reciprocate and advance / retreat in the movement area of the carriage 1. A carriage lock 572 as a “carriage locking member” that locks the carriage 1 by engaging with the carriage 1 and a trigger member 573 described later are integrally formed on the cap case 57. By moving the cap case 57 into the movement area of the carriage 1 while the carriage 1 is located at the home position, the carriage lock 572 engages with the carriage 1 to lock the carriage 1 and record with the cap 571. The head surface of the head 4 is sealed.
[0045]
The ink jet recording apparatus 50 has a control unit 200 that performs printing control by driving and controlling various driving force sources based on information from various sensors. The control unit 200 mainly performs the following control. Do. The print paper P is fed by controlling the drive of a paper feed drive motor 58 based on information from a paper sensor (not shown) that detects the leading edge of the print paper provided in the paper feed path. The absolute position of the carriage 1 is calculated by counting the electric pulse signals output from the linear scale sensor 12, and the carriage driving motor 67 is driven and controlled based on the absolute position to reciprocate the carriage 1 in the main scanning direction X. At the same time, an ink ejection timing signal is generated from the electric pulse signal output from the linear scale sensor 12, and the drive circuit of the recording head 4 is driven and controlled based on the ink ejection timing signal to eject ink onto the printing surface of the printing paper P. . The rotation amount of the conveyance drive roller 51 is detected by a rotation amount detecting means (not shown) such as a known rotary encoder device, and the printing paper P is moved in a predetermined direction in the sub-operation direction Y based on information of the rotation amount detecting means. The transport drive motor 59 is drive-controlled so that the transport is performed by the transport amount, and the transport drive roller 51 is driven to rotate. Printing is performed by alternately repeating the operation of ejecting ink onto the printing surface of the printing paper P while reciprocating the carriage 1 in the main scanning direction X, and the operation of transporting the printing paper P by a predetermined transport amount. After the execution, the rotation of the transport driving motor 59 is further controlled to rotate the paper discharge drive roller 54, and the print paper P after printing is discharged to the paper discharge tray 7a.
[0046]
FIG. 8 is a perspective view of a main part showing the vicinity of the carriage 1. Next, the support structure of the carriage 1 will be described with reference to FIG.
[0047]
In the carriage 1, the bearing 21 is supported by a carriage guide shaft 61 serving as “first carriage supporting means”, and the protrusion 22 is in sliding contact with a discharge frame 503 serving as “second carriage supporting means”. , And supported so as to be able to reciprocate in the main scanning direction X. The carriage 1 is inclined obliquely so that the head surface of the recording head 4 is arranged at a predetermined inclination angle with respect to the horizontal direction in a direction (sub-scanning direction Y) orthogonal to the main scanning direction X. And is supported by the carriage guide shaft 61 and the paper discharge frame 503 (FIG. 6). Therefore, the recording head 4 at the position of the center of gravity of the carriage 1 is arranged at a higher position on the carriage 1. In the carriage 1, an endless belt 63 is connected to the connecting portion 24 as a “transmitting portion” to which the rotation of the carriage driving motor 67 is transmitted. The connecting portion 24 is formed on the main carriage 2, and is disposed between the carriage guide shaft 61 and the discharge frame 503 and at a position lower than the position of the center of gravity of the carriage 1.
[0048]
In this manner, by tilting the carriage 1, the position of the recording head 4, which is the position of the center of gravity of the carriage 1, can be disposed at a position higher than the position of the carriage 1. can do. Accordingly, the connecting portion 24 is disposed at a position lower than the position of the center of gravity of the carriage 1, and the posture of the carriage 1 when transmitting the driving force of the carriage driving motor 67 to the carriage 1 can be stabilized. The posture at the time of the reciprocating movement is stabilized, and the vibration is less likely to be generated, so that it is possible to reduce the inclination of the carriage 1 and the deterioration of the ink ejection accuracy due to the vibration of the carriage 1.
[0049]
Further, the above-described linear scale 65 is disposed near the carriage guide shaft 61 between the carriage guide shaft 61 and the paper discharge frame 503. By arranging the linear scale 65 between the carriage guide shaft 61 and the discharge frame 503 and in the vicinity of the carriage guide shaft 61 that is far away from the recording head 4, the minute scale generated on the carriage 1 is reduced. In addition to reducing the effects of vibration and tilt, it is possible to reduce the risk that ink mist in which the ink ejected from the recording head 4 floats in a mist state adheres to the linear scale 65. Further, between the endless belt 63 and the linear scale 65, a long frame 506 in the main scanning direction X that shields the recording head 4 side of the linear scale 65 is provided. 4 is substantially blocked, and the risk of ink mist adhering to the linear scale 65 can be further reduced.
[0050]
9 is an enlarged perspective view showing a carriage guide shaft support portion 504 that supports the carriage guide shaft 61 on the left side frame 502. FIG. 10 is different from FIG. It is the perspective view shown from the angle. FIG. 11 is an enlarged perspective view of a carriage guide shaft support portion 505 that supports the carriage guide shaft 61 on the right side frame 501. FIG. 12 shows the carriage guide shaft support portion 505 in FIG. It is the perspective view shown from the angle different from.
[0051]
At the end of the left side frame 502, a support portion 111 extending from the left side frame 502, an arm portion 112 formed by bending a part of the left side frame 502 at a substantially right angle, and a tip of the arm portion 112 are provided. A flexure restricting portion 113 formed by bending and raising is formed. The carriage guide shaft 61 is screwed and fixed to a hole 114 formed in the arm portion 112 by a screw 115 inserted into a through hole 61 a formed in the carriage guide shaft 61 while being supported by the support portion 111, and flexed. It is supported by the restricting portion 113 in a state where the bending is restricted. Similarly, at the end of the right side frame 501, a support part 121 extending from the right side frame 501, an arm part 122 formed by bending a part of the right side frame 501 at a substantially right angle, and an arm A deflection regulating portion 123 formed by bending and raising the tip of the portion 122 is formed. The carriage guide shaft 61 is screwed and fixed to a hole 124 formed in the arm portion 122 with a screw 125 inserted into a through hole 61b formed in the carriage guide shaft 61 while being supported by the support portion 121, and flexed. It is supported by the restricting portion 123 and is supported in a state where the bending is restricted.
[0052]
As described above, the carriage guide shaft 61 is supported at two points near both ends by the support portions 111 and 121 formed integrally with the right side frame 501 and the left side frame 502, and the carriage guide shaft 61 is The arm 112 is arranged so as to be parallel with the main scanning direction X with high accuracy, and so that the printing surface of the printing paper P and the head surface of the recording head 4 mounted on the carriage 1 are parallel with high accuracy. And is screwed to the arm 122 and fixedly supported by the ink jet recording apparatus 50. Further, since the carriage guide shaft 61 is supported by the deflection restricting portions 113 and 123 and is supported in a state where the deflection is restricted, the main scanning direction X acting on the carriage 1 when the carriage 1 reciprocates. By this force, the possibility that the carriage guide shaft 61 is bent can be reduced. The support portion 111, the arm portion 112, and the deflection control portion 113 are all formed by a part of the left side frame 502, and the support portion 121, the arm portion 122, and the deflection control portion 123 are all formed by the right side frame. Since the carriage guide shaft 61 is formed as a part of the carriage 501, the carriage guide shaft 61 can be fixedly supported with high precision at extremely low cost. Further, the right side frame 501 and the left side frame 502 are arranged at a slightly wider interval than the width of the printing paper P of the maximum size that can be printed in the ink jet recording apparatus 50, whereby the ink jet recording apparatus 50 In this case, it is possible to make the vicinity of the center of the carriage guide shaft 61 harder to bend while enabling printing on the printing paper P of the maximum size that can be printed.
[0053]
A reinforcing plate 116 is attached to the arm 112 to prevent the arm 112 from being deformed by a force acting on the deflection control section 113 from the carriage guide shaft 61. Similarly, a reinforcement plate 126 for preventing the arm 122 from being deformed by the force acting on the deflection regulating portion 123 from the carriage guide shaft 61 is attached to the arm 122. Thereby, the strength of the arm 112 and the arm 122 can be increased. A reinforcing plate holding portion 117 and a reinforcing plate holding portion 118 that engage with the reinforcing plate 116 and hold the reinforcing plate 116 at a position where the reinforcing plate 116 is attached to the arm portion 112 are formed integrally with the arm portion 112. Similarly, a reinforcing plate holding portion 127 and a reinforcing plate holding portion 128 that engage with the reinforcing plate 126 and hold the reinforcing plate 126 at the position where the reinforcing plate 126 is attached to the arm portion 122 are formed integrally with the arm portion 122. . The reinforcing plate 116 is fastened to the arm 112 with a screw 115, and the reinforcing plate 126 is similarly fastened to the arm 122 with a screw 125. Therefore, in the manufacturing process of the ink jet recording apparatus 50, when attaching the carriage guide shaft 61, the work of screwing the carriage guide shaft 61 and the work of attaching the reinforcing plates 116 and 126 can be performed at the same time. The work efficiency at the time of attaching can be improved.
[0054]
The screw positions of the carriage guide shaft 61 are respectively disposed near the deflection control portion 113 of the arm portion 112 and near the deflection control portion 123 of the arm portion 122, and from the screw portion (hole 114) of the carriage guide shaft 61. The length of the arm portion 112 up to the deflection control portion 113 and the length of the arm portion 122 from the screwed portion (hole 124) of the carriage guide shaft 61 to the deflection control portion 123 are set to be short. Thereby, the strength of the bent and raised portions of the deflection restricting portions 113 and 123 can be increased. In addition, the length of the flexure restricting portion 113 is formed to be shorter than the length from the arm portion 112 to the end portion of the support portion 111 serving as the fulcrum of the carriage guide shaft 61. The length is formed to be shorter than the length from the arm 122 to the end of the support 121 serving as the fulcrum of the carriage guide shaft 61. The holes 114 and 124 are formed with female screws that engage with the screws 115 and 125, and the carriage guide shaft 61 is screwed to the arm 112 and the arm 122. ), The arm 112 and the arm 122 are bent in a direction to be pulled toward the carriage guide shaft 61. The bending restricting portion 113 is pulled toward the carriage guide shaft 61 by the bending of the arm portion 112, and the bending restricting portion 123 is pulled toward the carriage guide shaft 61 by the bending of the arm portion 122. Therefore, by adjusting the degree of tightening of the screws (screws 115 and 116) that screw the carriage guide shaft 61 to the arm 112 and the arm 122, the deflection control position by the deflection control unit 113 and the deflection control unit 123 is adjusted. Can be adjusted to be in appropriate positions.
[0055]
13 is an enlarged side view showing the vicinity of the bearing portion 21 and the carriage guide shaft 61 of the carriage 1, and FIG. 14 is an enlarged side view showing the vicinity of the carriage guide shaft 61 of FIG. is there.
[0056]
The bearing portion 21 is provided with metal bearing members 211 and 212 at both ends in the main scanning direction X. The bearing member 211 and the bearing member 212 have a circular arc-shaped inner peripheral surface exceeding 180 degrees along the outer peripheral surface of the carriage guide shaft 61 through which the carriage guide shaft 61 is passed as shown in the drawing. For this reason, while the carriage 1 is supported by the carriage guide shaft 61, the bearing portion 21 can pass through the portion fixedly supported by the carriage guide shaft support portion 504 and the carriage guide shaft support portion 505, and the carriage guide shaft It is also possible to move outside the support portion 504 and the carriage guide shaft support portion 505.
[0057]
On the inner peripheral surfaces of the bearing member 211 and the bearing member 212, there are formed two tangential planes 131 and 132 which are slidably in contact with the outer peripheral surface of the carriage guide shaft 61 and are opposed at a certain angle. The tangent plane means a plane that contacts the curved surface at one point on the curved surface, and two planes (tangential planes) that contact the outer peripheral surface of the carriage guide shaft 61 at one point on the outer peripheral surface of the carriage guide shaft 61. 131 and a tangent plane 132) are formed on the inner peripheral surface of the bearing member 211. Although not shown, the same applies to the bearing member 212. Further, at both ends in the circumferential direction of the inner peripheral surfaces of the bearing member 211 and the bearing member 212, a convex part 133 and a convex part 134 are provided as “pressing means” for pressing the tangent plane 131 and the tangential plane 132 to the carriage guide shaft 61. Are formed. The protrusions 133 and 134 are passed through the carriage guide shaft 61 in a state where the carriage guide shaft 61 slightly spreads the arc-shaped inner peripheral surfaces of the bearing member 211 and the bearing member 212, and the expanded inner peripheral surface is the original. The protrusions 133 and 134 are formed so as to press the tangent plane 131 and the tangent plane 132 against the outer peripheral surface of the carriage guide shaft 61 by a force that attempts to return to.
[0058]
As described above, since the posture of the carriage 1 is regulated by the tangent plane 131 and the tangent plane 132, the posture of the carriage 1 generated when the driving force in the main scanning direction X is transmitted to the carriage 1 from the carriage driving motor 67. And the vibration of the carriage 1 can be reduced. Further, by pressing the tangent plane 131 and the tangent plane 132 against the carriage guide shaft 61 by the protrusions 133 and 134, the force of regulating the posture of the carriage 1 by the tangent planes 131 and 132 can be further increased. it can. Further, the tangent plane 131 and the tangent plane 132 are formed so as to be substantially symmetrical with respect to the direction of gravity. The plane 131 and the tangent plane 132 are pressed against the carriage guide shaft 61, and the force of regulating the posture of the carriage 1 by the tangent plane 131 and the tangent plane 132 can be further increased.
[0059]
The support portion 111 has a flat central portion at the end serving as a fulcrum of the carriage guide shaft 61 in a direction substantially perpendicular to a screwing direction of the carriage guide shaft 61 by the screw 115. Have a shape that regulates the position in the sub-scanning direction Y of the carriage guide shaft 61 fixed and supported in parallel with the main scanning direction X with the carriage guide shaft 61 interposed therebetween. Although not shown, the same applies to the support portion 121.
[0060]
As described above, the portion serving as the fulcrum of the carriage guide shaft 61 at the ends of the support portions 111 and 121 has a flat shape in a direction substantially orthogonal to the screwing direction of the carriage guide shaft. By defining the fulcrum of the guide shaft 61 with high accuracy, the carriage guide shaft 61 can be supported with higher accuracy. In addition, the load of the carriage guide shaft 61 acts evenly on the support portions 111 and 121, and the carriage guide shaft 61 can be supported in a more stable state. Can be reduced, and the risk that the ends of the support portions 111 and 121 are deformed by the force from the carriage guide shaft 61 can be further reduced. Further, since both sides of a portion serving as a fulcrum of the carriage guide shaft 61 are formed so as to sandwich the carriage guide shaft 61 and regulate the position of the carriage guide shaft 61, the carriage fixed and supported in parallel with the main scanning direction X. The position of the guide shaft 61 in the sub-scanning direction Y can be regulated.
[0061]
The invention of the present application is not limited to the above embodiments, and various modifications are possible within the scope of the invention described in the claims, and these are also included in the scope of the invention of the present application. Needless to say.
[Brief description of the drawings]
FIG. 1 is an external perspective view of an ink jet recording apparatus according to the present invention.
FIG. 2 is a schematic side view of an ink jet recording apparatus according to the present invention.
FIG. 3 is a perspective view of a main part of an ink jet recording apparatus according to the present invention.
FIG. 4 is a plan view of a main part of the ink jet recording apparatus according to the present invention.
FIG. 5 is a perspective view of a main part of an ink jet recording apparatus according to the present invention.
FIG. 6 is a side view of a main part of the ink jet recording apparatus according to the present invention.
FIG. 7 is a side view of a main part of the ink jet recording apparatus according to the present invention.
FIG. 8 is an essential part perspective view showing the vicinity of a carriage.
FIG. 9 is a perspective view of a carriage guide shaft support portion of the left side frame.
FIG. 10 is a perspective view of a carriage guide shaft support portion of the left side frame.
FIG. 11 is a perspective view of a carriage guide shaft support portion of the right side frame.
FIG. 12 is a perspective view of a carriage guide shaft support portion of the right side frame.
FIG. 13 is an enlarged side view showing the vicinity of a bearing portion of the carriage.
FIG. 14 is an enlarged side view showing the vicinity of a carriage guide shaft.
[Explanation of symbols]
Reference Signs List 1 carriage, 2 main carriage, 3 sub-carriage, 4 recording head, 7 paper feed cassette, 8 ink cartridge accommodating section, 11 carriage cover, 21 bearing section, 24 connecting section, 50 ink jet recording apparatus, 51 transport drive roller, 52 Conveyance driven roller, 53 Platen, 54 Discharge drive roller, 55 Discharge driven roller, 56 Discharge auxiliary roller, 57 Cap case, 61 Carriage guide shaft, 65 Linear scale, 73 Pickup roller, 74 Paper feed roller, 75 Reverse roller , 81 communication circuit board frame, 82 ink cartridge, 84 communication circuit board, 111, 121 support, 112, 122 arm, 113, 123 deflection control, 116, 126 reinforcing plate, 131, 132 tangent plane, 133, 134 Convex part, 200 control part, 211, 212 bearing member, 571 cap, 572 carriage lock, 573 trigger member, X main scanning direction, Y sub scanning direction

Claims (9)

Liquid mounted on a carriage having a liquid ejecting head for ejecting a liquid to a material to be ejected is reciprocally supported by a carriage guide shaft having a substantially cylindrical shape and arranged in parallel with the scanning direction of the liquid ejecting head. An injection device,
A side frame disposed near the both sides in the scanning direction in a direction substantially orthogonal to the scanning direction,
At an end of the side frame, a support portion extending from the side frame, an arm portion formed by bending a part of the side frame at a substantially right angle, and a tip of the arm portion bent and raised are formed. And a flexure restricting portion are formed,
The carriage guide shaft is screwed and fixed to the arm portion while being supported by the support portion, and is supported by the flexure restricting portion in a state where the flexure is restricted. Liquid ejector. The liquid ejecting apparatus according to claim 1, wherein the side frame is disposed immediately outside the maximum width of the material to be ejected. 3. The liquid ejecting apparatus according to claim 1, wherein a reinforcing plate for preventing deformation of the arm due to a force acting on the deflection control unit from the carriage guide shaft is overlaid on the arm. 4. . The liquid ejecting apparatus according to claim 3, wherein the reinforcing plate is fastened to the arm with a screw for screwing the carriage guide shaft to the arm. The liquid according to claim 4, wherein a reinforcing plate holding portion that engages with the reinforcing plate and holds the reinforcing plate at a position where the reinforcing plate is attached to the arm portion is formed integrally with the arm portion. Injection device. The liquid ejecting apparatus according to any one of claims 1 to 5, wherein a screwing position of the carriage guide shaft to the arm portion is disposed near the deflection control portion. The length of the deflection restricting portion according to any one of claims 1 to 6, wherein a length of the bending restricting portion is formed to be shorter than a length from the arm portion to an end portion of the support portion serving as a fulcrum of the carriage guide shaft. A liquid ejecting apparatus. The support portion according to any one of claims 1 to 7, wherein an end portion serving as a fulcrum of the carriage guide shaft has a flat shape in a direction substantially perpendicular to a screwing direction of the carriage guide shaft to the arm portion. A liquid ejecting apparatus comprising: 9. The device according to claim 8, wherein the support portion has a shape that regulates a support position of the carriage guide shaft in a direction orthogonal to the scanning direction, the end serving as a fulcrum of the carriage guide shaft. Liquid ejector.

Images