JP2006095740A - Fan unit and image forming device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a fan unit exhibiting improved gas suction efficiency. <P>SOLUTION: When a fan 108 is rotating (driving), air outside an intake duct 102 is sucked from a suction opening 102a and passes through the intake duct 102 in the direction of an arrow D and enters a communication portion 106. Subsequently the air passes through the communication portion 106, enters an exhaust duct 104, passes through the exhaust duct 104 in the direction of an arrow E and is discharged (externally) from an exhaust opening 104a. In the intake duct 102, since the internal pressure becomes lower than the external pressure (negative pressure), the pressure difference overpowers the urging force of a spring 112b and a valve 112a blocks an opening 102b. In the exhaust duct 104, since the internal pressure becomes higher than the external pressure (positive pressure), the pressure difference overpowers the urging force of a spring 114b and a valve 114a blocks an opening 104b. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a fan unit that allows gas to pass through and discharges, and an image forming apparatus incorporating the fan unit.

  2. Description of the Related Art As an output device for a computer or a workstation, an ink jet type image forming apparatus that forms an image by ejecting ink onto a recording medium such as a recording sheet conveyed in a predetermined conveying direction is known. This ink jet type image forming apparatus is usually a print head having a plurality of ink ejection holes for ejecting ink, a carriage mounted with this print head and scanning (reciprocatingly moving) in a predetermined main scanning direction. It has. Also known is an ink jet image forming apparatus of a type that includes a print head that extends long in a direction perpendicular to the recording medium conveyance direction (width direction of the recording medium), and that fixes the print head during printing. Yes.

  When forming an image on a recording medium using an inkjet image forming apparatus that scans a carriage mounted with a print head, the recording medium being transported is temporarily stopped and the carriage is reciprocated in the main scanning direction. Then, ink is ejected from the ink ejection holes based on the image signal carrying the image information, and an image for one band is formed in a portion of the recording medium located in the image forming area facing the ink ejection holes. Thereafter, the recording medium is transported by the width of one band and stopped, and again, the carriage is reciprocated in the main scanning direction to eject ink from the ink ejection holes based on the image signal. An image is formed in a portion newly located in the image forming area. By repeating such an operation, an image is formed on the entire recording medium.

  In the above-described inkjet image forming apparatus, an image is formed by ejecting liquid ink (ink droplets) onto a recording medium. For this reason, when ink is ejected from the print head, fine mist-like ink (ink mist) is generated around the ink droplets. Also, when ink droplets land on the recording medium, not all of the ink droplets are instantaneously adsorbed on the recording medium, and some of the ink droplets bounce off the surface of the recording medium due to impact of landing or the like. Ink mist may be generated by scattering in a mist.

  The generated ink mist is wound up inside the image forming apparatus by the negative pressure generated in the rearward direction of the carriage as the carriage moves. The rolled up ink mist adheres to components and members inside the image forming apparatus. The adhering ink mist may stain the user's hand that touches internal components and members by opening the cover. Further, when the ink mist adheres to the carriage sliding portion or the encoder or sensor for positioning the carriage, the apparatus may malfunction.

  In order to prevent the above problems, a fan unit is often used that combines a duct for sucking ink mist and a duct for discharging the air inside the apparatus to the outside. By this fan unit, the air inside the image forming apparatus is sucked by the fan and discharged through the duct.

  On the other hand, in addition to the fan for sucking ink mist, there is a fan that sucks air inside the image forming apparatus, such as a platen fan that sucks the recording medium on the plane (platen) of the image forming area facing the ink discharge hole. Similarly to the ink mist suction fan, air inside the image forming apparatus is also sucked into the fan unit and discharged through a predetermined path.

  In the above-described fan unit, ink mist generated inside the image forming apparatus is sucked together with air inside the apparatus, and liquefied mist obtained by liquefying the ink mist is accumulated. In order to collect the liquefied mist in the ink collecting section, an ink flow path through which the liquefied mist passes is required to guide the liquefied mist to the ink collecting section. In such a structure, it is necessary to form an opening in the duct of the fan unit and connect the opening to the ink flow path. However, since this opening is formed in the duct, unnecessary air leakage (air leakage) is caused, and the air suction efficiency of the fan unit is remarkably lowered. In order to prevent this decrease, the fan unit to the ink recovery unit may be fluidly closed (airtight state). However, in the case of such a structure, the ink collecting unit is enlarged and the image forming apparatus is enlarged.

  SUMMARY An advantage of some aspects of the invention is that it provides a fan unit with improved suction efficiency for sucking a gas and an image forming apparatus incorporating the fan unit.

In order to achieve the above object, a fan unit according to the present invention includes a duct through which a gas passes and a fan through which the gas passes, and the fan passes through the duct by driving the fan. ,
(1) An opening / closing part for opening / closing a part of the duct, which is opened / closed by a pressure difference between a pressure inside the duct and a pressure outside the duct, is provided.

here,
(2) The opening / closing part may be opened when the pressure difference is within a predetermined range and closed when the pressure difference is outside the predetermined range.

Also,
(3) The duct is
(3-1) an intake duct into which the outside gas is sucked;
(3-2) an exhaust duct through which the gas inside is exhausted,
(3-3) The intake duct and the exhaust duct communicate with each other;
(4) The fan may be disposed in the communicating portion.

further,
(5) The intake duct is one in which the internal pressure is lower than the external pressure by driving the fan, and external gas is sucked in, and the opening / closing part is attached. ,
(6) The opening / closing unit may be closed while the fan is being driven.

Furthermore,
(7) The exhaust duct is configured such that when the fan is driven, the internal pressure becomes higher than the external pressure and the internal gas is discharged, and the open / close section is attached. And
(8) The opening / closing portion may be closed while the fan is being driven.

An image forming apparatus of the present invention for achieving the above object is
(9) The fan unit described above is provided as a fan unit for collecting ink mist.

  According to the fan unit of the present invention, the opening / closing part opens and closes due to a pressure difference between the pressure inside the duct (internal pressure) and the pressure outside the duct (external pressure), and thus no parts / members for opening / closing the opening / closing part are necessary. Further, when the fan is driven, the suction efficiency for sucking the external gas is improved by setting the opening / closing part to be closed by the pressure difference between the internal pressure and the external pressure.

  The present invention has been realized in a printer that forms an image by ejecting ink from a print head onto a recording medium.

  A schematic configuration of a color printer (hereinafter referred to as a printer), which is an example of an image forming apparatus of the present invention, will be described with reference to FIGS.

  FIG. 1 is a perspective view illustrating a schematic configuration of the printer as viewed from the front. FIG. 2 is a perspective view illustrating a schematic configuration of the printer as viewed from the back.

  The printer 10 includes an operation unit 12 for operating the printer 10, and online / offline, commands, and the like are instructed by various switches arranged on the operation unit 12. Roll paper P (which is an example of a recording medium) is pulled out from one end in the direction of arrow B, and a color image is printed inside the printer 10 on the pulled-out portion (drawing portion) Ph. The paper is discharged from the paper discharge port 14 in the direction of arrow A. A large-capacity ink tank unit 16 is disposed at one end in the width direction of the printer 10. Further, the inside of the printer 10 can be seen by opening the cover 18.

  The roll paper P has a cylindrical shape. When the roll paper P is held at a predetermined position, a rod-shaped spool shaft 82 is inserted into the inner space of the roll paper P. One end of the spool shaft 82 in the longitudinal direction is fixed to the cradle 90 and the other end in the longitudinal direction is fixed to the cradle 92 to be rotatable. Note that both ends in the longitudinal direction of the roll paper P are regulated by the side regulating plates 84 so as not to move.

  A recording paper insertion slot 20 into which the roll paper P is inserted is formed on the back side of the printer 10. A paper feed guide 22 for guiding a recording paper such as a roll paper P is attached to the inside of the printer 10 at the recording paper insertion opening 20.

  With reference to FIG. 3 and FIG. 4, a recording paper conveyance path, a printing (image forming) process, and the like will be described.

  FIG. 3 is a perspective view showing the inside of the printer. FIG. 4 is an enlarged perspective view showing the platen and its peripheral portion. In these drawings, the same components as those shown in FIGS. 1 and 2 are denoted by the same reference numerals.

  The printer 10 can print on a sheet-like recording paper and a recording paper (roll paper P) wound in a roll shape. Here, a conveyance path of the roll paper P inserted from the recording paper insertion port 20 (see FIG. 2) on the back side of the main body will be described.

  The roll paper P is pulled out from one end in the longitudinal direction, and the drawn-out portion Ph is inserted into the recording paper insertion slot 20 from the direction of arrow B (see FIG. 2). The drawn portion Ph of the inserted roll paper P is guided by the paper feed guide 22 and is held between a drive roller 24 and a pinch roller 28 which is rotatably fixed to the pinch roller arm 26. The platen 30 is conveyed to the printing unit 30a (image forming area). A large number of suction holes 30b are formed in the printing unit 30a, and when the drawer portion Ph is conveyed through the printing unit 30a, the printing unit 30a passes from above the printing unit 30a by a suction fan described later from below the printing unit 30a. The inside drawing portion Ph is sucked through the suction hole 30b so that the drawing portion Ph does not float from the upper surface of the printing unit 30a. Thereafter, the drawn portion Ph is further conveyed while being held between the driving roller 24 and the pinch roller 28 and discharged from the recording paper discharge port 14 (see FIG. 1) on the front side of the main body.

  The printer 10 includes a carriage 40 that reciprocates in the direction of arrow C (main scanning direction). The carriage 40 includes a head holder 42, and a print head 44 is detachably attached to the head holder 42. Ink is supplied to the print head 44 from an ink tank unit 46 (with six colors of black, cyan, magenta, yellow, light cyan, and light magenta) via an ink supply tube (ink conduit) 48. .

  As shown in FIG. 3, the carriage 40 is fixed to a belt 52 that is hung on the rotation shaft of the carriage drive motor 50, and this belt 52 is moved in the direction of the arrow by forward and reverse rotation of the carriage drive motor 50. Go back and forth in direction C. As the belt 52 reciprocates in the arrow C direction, the carriage 40 is also guided by the two guide rails 54 and reciprocates in the arrow C direction.

  In order to detect the position of the carriage 40 in the main body (apparatus main body) of the printer 10, the linear encoder scale 56 is arranged over the entire range in which the carriage scans (reciprocates). The linear encoder scale 56 is for detecting the position of the carriage 40 by a sensor using optics or magnetism. A scale reader (not shown) that reads the linear encoder scale 56 optically (or magnetically) is mounted on the carriage 40. By reading the linear encoder scale 56 with this scale reader, the position of the carriage 40 is detected. The linear encoder scale 56 and the scale reader have a known structure.

  The roll paper P is intermittently conveyed in a direction orthogonal to the arrow C direction (the conveyance direction of the roll paper P). When an image is to be formed on the drawing portion Ph of the roll paper P, the roll paper P is temporarily stopped, and the carriage 40 is reciprocated in the direction of arrow C while the image forming area ( Ink is ejected from the print head 44 to a portion located in the area corresponding to the print unit 30a. Thereafter, the roll paper P is conveyed by a predetermined length, and an image for the next band is formed in a new portion located in the image forming area. This operation is repeated over the entire length of the roll paper P. As a result, a color image is formed on the roll paper P, and the roll paper P on which the image has been formed is sandwiched between the drive roller 24 and the pinch roller 28 and conveyed while being conveyed. 1).

  In the printer 10, when ink is ejected from the print head 44, fine mist-like ink (ink mist) is generated around the ink droplets. Also, when ink droplets land on the recording medium, not all of the ink droplets are instantaneously adsorbed on the recording medium, and some of the ink droplets bounce off the surface of the recording medium due to impact of landing or the like. Ink mist may be generated by scattering in a mist. In order to remove (remove) the ink mist generated in this way, the printer 10 incorporates a fan unit that sucks air in the internal space of the printer 10 and discharges it to the outside.

  The principle of the fan unit of the present invention will be described with reference to FIGS.

  FIG. 5 is an explanatory diagram schematically showing the fan unit when the fan is stopped. FIG. 6 is an explanatory diagram schematically showing the fan unit when the fan is driven (rotated).

  A fan unit 100 showing the principle of the fan unit described later includes an intake duct 102 in which external air (an example of gas) is sucked together with ink mist, an exhaust duct 104 from which the internal air is discharged, and an intake duct. 102 and a communication portion 106 that allows the exhaust duct 104 to communicate with each other. A fan 108 that allows air to pass through the intake duct 102 and the exhaust duct 104 is disposed in the communication portion 106. Here, the intake duct 102 and the exhaust duct 104 are substantially cylindrical.

  A suction port 102a through which external air is sucked is formed at one longitudinal end (upper portion in the figure) of the intake duct 102, and at the other longitudinal end (lower portion in the figure). An opening 102b is formed. In addition, an opening / closing portion 112 that opens and closes an opening 102b (a part of the intake duct 102) is attached to the intake duct 102. On the other hand, an exhaust port 104a through which the air inside the exhaust duct 104 is exhausted is formed at one end in the longitudinal direction (the upper portion in the figure) of the exhaust duct 104. , The lower part) is formed with an opening 104b. The exhaust duct 104 is attached with an opening / closing part 114 that opens and closes an opening 104b (a part of the exhaust duct 104). The communicating portion 106 is disposed so as to communicate the upper half of the intake duct 102 and the upper half of the exhaust duct 104.

  The opening / closing part 112 that opens and closes the opening 102b of the intake duct 102 has a simple structure including a valve 112a and a spring 112b. The valve 112a is disposed so as to open and close the opening 102b from the outside (outside) of the intake duct 102. One end of the spring 112b is fixed to the protruding plate 102c protruding from the inner wall surface of the intake duct 102. A convex portion of the valve 112a is inserted and fixed inside the other end of the spring 112b. When no force is applied to the valve 112a from the outside, the valve 112a is open without closing the opening 102b by the urging force (spring force) of the spring 112b, as shown in FIG. That is, the biasing force of the spring 112b is set so that the valve 112a opens the opening 102b when no force is applied to the valve 112a from the outside. On the other hand, as described later, when the fan 108 rotates (drives) and the pressure inside the intake duct 102 becomes lower than the external pressure, the pressure difference between the external pressure and the internal pressure of the intake duct 102 Overcomes the biasing force of the spring 112b and the valve 112a closes (closes) the opening 102b. As described above, the opening / closing part 112 is configured to open and close due to the pressure difference between the outside and the inside of the intake duct 102.

  The opening / closing part 114 for opening and closing the opening 104b of the exhaust duct 104 has a simple structure including a valve 114a and a spring 114b. The valve 114a is disposed so as to close the opening 104b from the inside (inside) of the exhaust duct 104 so as to be freely opened and closed. One end of the spring 114b is fixed to the protruding plate 104c protruding from the external wall surface of the intake duct 102. A convex portion of the valve 114a is inserted and fixed inside the other end of the spring 114b. When no force is applied to the valve 114a from the outside, the valve 114a is opened without closing the opening 104b by the urging force (spring force) of the spring 114b, as shown in FIG. That is, the biasing force of the spring 114b is set so that the valve 114a opens the opening 104b when no force is applied to the valve 114a from the outside. On the other hand, as described later, when the fan 108 rotates (drives) and the pressure inside the exhaust duct 104 becomes higher than the outside pressure, the pressure difference between the outside pressure and the inside pressure of the exhaust duct 104. Overcomes the biasing force of the spring 114b, and the valve 114a closes (closes) the opening 104b. As described above, the opening / closing portion 114 is configured to open and close due to the pressure difference between the outside and the inside of the exhaust duct 104.

  In the intake duct 102, when the fan 108 is stopped (that is, when the pressure difference between the outside and the inside of the intake duct 102 is within a predetermined range, and this pressure difference is almost zero), it is shown in FIG. Thus, since the valve 112a is pushed outward (downward in FIG. 5) by the biasing force of the spring 112b, the opening 102b is open without being blocked. For this reason, the liquefied ink M existing inside the intake duct 102 (mainly the inner wall surface) is discharged from the opening 102b along the inner wall surface.

  Similarly, in the exhaust duct 104, when the fan 108 is stopped (that is, when the pressure difference between the outside and the inside of the exhaust duct 104 is within a predetermined range and this pressure difference is almost zero), FIG. As shown in FIG. 5, since the valve 114a is pushed inward (upward in FIG. 5) by the biasing force of the spring 114b, the opening 104b is not closed and is open. For this reason, the liquefied ink M present inside the exhaust duct 104 (mainly the inner wall surface) is discharged from the opening 104b along the inner wall surface.

  On the other hand, when the fan 108 is rotating (driving), as shown in FIG. 6, the air outside the intake duct 102 is sucked from the suction port 102a and passes through the intake duct 102 in the direction of the arrow D to communicate with the communicating portion 106. Then, the air passes through the communicating portion 106 and enters the exhaust duct 104, passes through the exhaust duct 104 in the direction of arrow E, and is discharged (externally) from the exhaust port 104a. In this case, since the internal pressure of the intake duct 102 is lower than the external pressure (becomes a negative pressure), this pressure difference overcomes the biasing force of the spring 112b as shown in FIG. A valve 112a closes the opening 102b. Further, since the internal pressure of the exhaust duct 104 is higher than the external pressure (becomes positive pressure), this pressure difference overcomes the urging force of the spring 114b as shown in FIG. 114a closes the opening 104b. Thus, when the fan 108 is rotating, the opening 102b is blocked by the valve 112a and the opening 104b is blocked by the valve 114a, so that the air enters and exits only from the suction port 102a and the exhaust port 104a. Since the air does not enter and exit from other portions of the intake duct 102 and the exhaust duct 104, the suction efficiency is improved.

  An example in which the fan unit 100 is applied to the printer 10 will be described with reference to FIGS.

  First, the basic structure of the printer 10 will be described with reference to FIGS.

  FIG. 7 is a perspective view showing the printer with the exterior cover and the like removed. FIG. 8 is a perspective view showing the printer with the platen and the like removed from the state shown in FIG.

  The basic structure of the printer 10 includes a left plate 120 and a right plate 122 that are separated by a predetermined distance, two beams 124 and 126 spanned between the left plate 120 and the right plate 122, and a platen base that supports the platen 30. 128. The platen table 128 is fixed to the left side plate 120 and the right side plate 122.

  A rectangular parallelepiped space is formed by the left side plate 120, the right side plate 122, and the two beams 124 and 126, and the fan unit 200 is accommodated in this space. The fan unit 200 applies the above-described fan unit 100 and is screwed to the two beams 124 and 126. Thus, the fan unit 200 fixed between the left side plate 120 and the right side plate 122 constitutes a part of the structure, and also plays a role of strengthening prevention of twisting of the main body of the printer 10. Below the platen table 128, two mist fans 202, 202 and a platen fan 204, which will be described later, are arranged.

  An ink tray 130 on which the ink tank 16 (see FIG. 1) and the like are mounted is arranged outside the right side plate 122. The ink tray 130 is screwed to the two beams 124 and 126. . The fan unit 200 is provided with a frame 132 in which an ink collection container (not shown) is stored. The frame 132 is screwed to the two beams 124 and 126.

  The fan unit 200 will be described with reference to FIGS.

  FIG. 9 is a perspective view showing a schematic configuration of the fan unit. FIG. 10 is a top view showing the bottom case. FIG. 11 is a perspective view showing the bottom case from above. FIG. 12 is a perspective view showing the bottom case from below. FIG. 13 is a bottom view of the fan base as viewed from below (back side). FIG. 14 is an enlarged perspective view showing the ink tray.

  The fan unit 200 includes a rectangular parallelepiped bottom case 300 having an open top, and a rectangular parallelepiped fan base 400 that closes the opening of the bottom case 300 and is slightly smaller than the opening. The fan base 400 is disposed on the bottom case 300 and also has a lid function for closing the opening of the bottom case 300. Since the fan base 400 is slightly smaller than the opening of the bottom case 300, all of the ink (ink mist liquefied) adhering to the fan base 400 located above the bottom case 300 is guided to the bottom case 300. (Flowed). Two mist fans 202 and 202 that are sirocco fans and a platen fan 204 that is a sirocco fan are fixed to the upper surface of the fan base 400 by a fan fixing plate 206.

  The bottom case 300 is made of plastic. The interior of the bottom case 300 is divided into a plurality of rooms by several inner walls and partition ribs as will be described later. Inside the bottom case 300, as shown in FIG. 10 and FIG. 11, etc., partition ribs 302 formed at the center of the inside and connecting two trapezoids, and a rectangular first inner wall 304 are formed. A second inner wall 306 formed on the opposite side of the first inner wall 304 across the partition rib 302, and a third inner wall 308 that extends slightly in parallel to the second inner wall 306 slightly away from the second inner wall 306. It is made. Inside the bottom case 300, two mist fan intake chambers 312 surrounded by a main body outer wall 301, a partition rib 302, a rectangular first inner wall 304, and a second inner wall 306 are formed. A platen fan intake chamber 314 is formed in the bottom case 300 and is surrounded by the partition rib 302 and the first inner wall 304. Further, an exhaust chamber 316 surrounded by the first inner wall 304 is formed inside the bottom case 300. Further, in the bottom case 300, a single drain ink channel chamber 318 surrounded by the second inner wall 306 and the third inner wall 308 is formed. Thus, the inside of the bottom case 300 is partitioned into a plurality of rooms.

  On the other hand, the fan base 400 is also made of plastic. Inside the fan base 400, as shown in FIG. 13, the partition rib 302 and the first, second, and third inner walls 304 of the bottom case 300 are hermetically sealed in order to hermetically seal a plurality of rooms formed inside the bottom case 300. , 306 and 308 are formed. When the bottom case 300 and the fan base 400 are overlapped and joined, the partition rib 302 and the first, second, and third inner walls 304, 306, and 308 of the bottom case 300 are fitted into the recesses 402 of the fan base 400, and the mist fan intake The airtightness of the chamber 312, the platen fan intake chamber 314, the exhaust chamber 316, and the exhaust ink flow path chamber 318 is maintained. When the bottom case 300 and the fan base 400 are overlapped and joined, the self-tapping screw holes 320 (8 places) of the bottom case 300 and the screw holes 404 (8 places) of the fan base 400 are fixed by self-tapping screws. Further, the screws are passed through the ten screw holes 330 of the bottom case 300 and the ten screw holes 440 of the fan base 400 and fixed to the beams 124 and 126 with these screws. Thereby, the mist fan intake chamber 312, the platen fan intake chamber 314, the exhaust chamber 316, and the exhaust ink passage chamber 318 are formed.

  Mist fan intake holes 406 and 406 are formed at portions corresponding to the suction sides of the two mist fans 202 and 202 shown in FIG. 9, and the air inside the mist fan intake chamber 312 is supplied to the two mist fans 202 and 202. Aspirated by 202. Further, a platen fan intake hole 408 is formed at a portion corresponding to the suction side of the platen fan 204 shown in FIG. 9, and air inside the platen fan intake chamber 314 is sucked by the platen fan 204.

  Ink mist is sucked into the mist fan intake chamber 312 through the following paths (1) to (3). (1) Ink mist is sucked from a duct 208 (shown in FIG. 9) that is disposed at both longitudinal ends (left and right portions) of the fan unit 200 and communicates with the internal space of the apparatus including the recording unit of the printer 10. (2) The ink mist is sucked from the hole 30c (see FIG. 7) at one end in the longitudinal direction of the platen 30 through the chimney 210 (see FIG. 8) connected to the platen base 128. (3) Ink mist is sucked from the hole 123b through the chimney 123a of the preliminary discharge receptacle 123 (see FIG. 8). In particular, this portion can efficiently suck ink mist generated during head aging.

  The platen fan intake chamber 314 is closed (formed airtight) by the platen base 128 and the platen 30 (see FIG. 3) via the chimneys 212 and 212 (see FIG. 8) of the two platen bases 128, respectively. It communicates with the negative pressure chamber for suction. In the platen 30, air is sucked through a large number of suction holes 30 b (see FIG. 7) to prevent the recording medium from floating from the printing portion 30 a (upper surface) of the platen 30.

  A portion of the fan base 400 that coincides with the exhaust side of the two mist fans 202, 202 shown in FIG. A platen fan exhaust hole 412 through which exhaust passes is formed in a portion of the fan base 400 that coincides with the exhaust side of the platen fan 204 shown in FIG. The mist fan exhaust hole 410 and the platen fan exhaust hole 412 communicate with a single exhaust chamber 316 extending substantially throughout the longitudinal direction of the fan unit 200. Exhaust gas that has passed through the mist fan exhaust hole 410 and the platen fan exhaust hole 412 is guided to a maintenance cartridge (not shown) from two exhaust ports 322 formed on the bottom surface of the bottom case 300, and is filtered (not shown). ) To the outside of the device. A mist suction hole 414 for sucking ink mist and a suction hole 416 communicating with the hole 30c at one end of the platen 30 in the longitudinal direction are formed at one end of the fan base 400 in the longitudinal direction. A mist suction hole 418 for sucking ink mist and a preliminary discharge suction hole 420 for sucking ink mist generated during preliminary discharge are formed at the other longitudinal end of the base 400. In addition, a large number of ribs 422 that promote liquefaction of ink mist are formed inside the fan base 400. Further, two platen suction holes 424 for sucking air from the numerous suction holes 30b of the platen 30 are formed.

  As shown in FIG. 11 and FIG. 14, the ink tray 130 is formed with an ink discharge portion 132 that discharges ink received by the ink tray 130, and the ink discharge portion 132 is formed on the bottom surface of the ink tray 130. A slope is formed that is sloped down toward (tilt). The ink received by the ink tray 130 flows through the inclined bottom surface and is discharged from the ink discharge unit 132.

  As shown in FIG. 11, the ink discharge portion 132 of the ink tray 130 is inserted into the discharge ink flow path chamber 318 formed by the bottom case 300 and the fan base 400. In the ink tray 130, the recovery system waste ink, the overflow ink of the ink tank unit 46 (see FIG. 3), and the preliminary discharge receptacle 123 (see FIG. 8) are discharged and guided by the ink guide 123 c (see FIG. 8). The waste ink is received. Ink received by the ink tray 130 is received by the ink discharge passage chamber 318 via the ink discharge portion 132. Note that two buffer recesses 324 that prevent ink from leaking outside from the insertion port are formed at the insertion port of the drainage ink flow channel chamber 318 into which the ink discharge unit 132 is inserted.

  On the bottom surfaces of the mist fan intake chamber 312 and the platen fan intake chamber 314, a gradient is formed that descends toward the ink drain hole 326 formed substantially at the center of the bottom case 300. Therefore, the ink accumulated in the mist fan intake chamber 312 and the platen fan intake chamber 314 flows into the ink drain hole 326. A nozzle member 350 is attached to the bottom side of the bottom case 300 on the back side of the ink drain hole 326 as shown in FIG. An ink discharge hole 352 is formed in the nozzle member 350, and the ink collected in the bottom case 300 is discharged from the ink discharge hole 352 and collected in a maintenance cartridge (not shown). An example of the opening / closing part of the fan unit of the present invention is disposed between the bottom surface of the bottom case 300 and the nozzle member 350. An example of the opening / closing part will be described with reference to FIGS. 15 to 18.

  FIG. 15 is a perspective view showing the nozzle member from above. FIG. 16 is a perspective view showing a portion on the back side of the ink drain hole in the bottom surface of the bottom case, in which the nozzle member is removed. FIG. 17 is an enlarged perspective view showing the periphery of the ink drain hole in the bottom surface of the bottom case. FIG. 18 is a perspective view showing the discharge valve from below. In these drawings, the same components as those shown in FIGS. 9 to 14 are denoted by the same reference numerals.

  The nozzle member 350 has a rectangular parallelepiped shape, and screw holes 354 and 356 are formed at both ends in the longitudinal direction. These screw holes 354 and 356 are overlapped with the screw holes 344 and 346 of the bottom case 300 to allow screws (not shown) to pass therethrough. As a result, the nozzle member 350 is screwed to the bottom case 300. A rectangular and flat discharge valve 370 is attached below the ink drain hole 326. The discharge valve 370 opens and closes the ink drain hole 326. The discharge valve 370 corresponds to the valve 112a shown in FIG.

  As shown in FIGS. 16 and 18, a pair of hinge shafts 372 are formed at one end in the longitudinal direction of the discharge valve 370. The hinge shaft 372 protrudes outward in the width direction of the discharge valve 370. A bearing groove 348 a into which the upper half of the pair of hinge shafts 372 is fitted is formed in the frame 348 on the bottom surface of the bottom case 300. The frame 348 has a size slightly larger than the nozzle member 350 and is used to fix the nozzle member 350 to the bottom case 300. The lower half of the pair of hinge shafts 372 is fitted into the bearing grooves 358 of the nozzle member 350. By fitting the pair of hinge shafts 372 into the bearing groove 348a and the bearing groove 358 and screwing the nozzle member 350 to the bottom case 300, the discharge valve 370 can be attached so that the ink drain hole 326 can be freely opened and closed. It becomes.

  On the upper surface of the other end in the longitudinal direction opposite to the portion where the hinge shaft 372 is formed in the discharge valve 370 (the surface on the ink drain hole 326 side and the surface facing the inside of the bottom case 300). A cylindrical guide shaft 374 is formed. A valve opening spring 376 is inserted into the guide shaft 374. For this reason, the guide shaft 374 is disposed in the valve opening spring 376, and the guide shaft 374 is difficult to see in FIG. The valve opening spring 376 corresponds to the spring 112b shown in FIG. One end of the valve opening spring 376 is in contact with the upper surface of the discharge valve 370, and the other end is in contact with the wall 349 of the bottom case 300. The wall 349 is located above the discharge valve 370 in the bottom case 300. The valve opening spring 376 urges the other end portion of the discharge valve 370 downward so as to open the ink drain hole 326. Note that two convex portions 378 are formed on the lower surface of the other end portion in the longitudinal direction of the discharge valve 370 on the guide shaft 374 side. The convex portion 378 is provided to maintain an appropriate gap between the discharge valve 370 and the nozzle member 350 when the other end in the longitudinal direction of the discharge valve 370 is pushed downward to open the ink drain hole 326. It has been.

  The discharge valve 370, the valve opening spring 376, the mist fan 202, the platen fan 204, the mist fan intake chamber 312 (which is an example of the duct according to the present invention and corresponds to the intake duct 102 shown in FIG. 6), and the platen fan An example of the fan unit of the present invention is configured by the intake chamber 314 (which is an example of a duct according to the present invention and corresponds to the intake duct 102 shown in FIG. 6).

  The movement of the discharge valve 370 will be described.

  When the mist fan 202 and the platen fan 204 are not driven (rotated), there is almost no difference between the pressure inside the platen fan intake chamber 314 and the pressure outside (the portion closer to the nozzle member 350 than the discharge valve 370). Since the pressure difference is within a predetermined range, the other end in the longitudinal direction of the discharge valve 370 (the portion opposite to the hinge shaft 372) is pushed downward by the valve opening spring 376, and the ink drain hole 326 is removed. Is open. Therefore, the ink that has flowed into the ink drain hole 326 is collected by the nozzle member 350. The ink collected in this manner drops (drops) from the ink discharge hole 352 of the nozzle member 350 and is collected in a maintenance cartridge (not shown).

  It should be noted that there is a gradient descending toward the ink discharge hole formed in the vicinity of the ink drain hole 326 on the bottom surface of the drain ink flow path chamber 318. For this reason, the ink discharged from the ink tray 130 is dropped from the ink discharge hole through the discharged ink flow path chamber 318 and collected in a maintenance cartridge (not shown). The cylindrical tip portion of the ink discharge hole and the cylindrical tip portion of the ink discharge hole 352 of the nozzle member 350 are cut into a bamboo basket shape to improve ink shortage.

  When the mist fan 202 and the platen fan 204 are driven (rotated), the pressure (internal pressure) inside the two mist fan intake chambers 312 and the inside of the one platen fan intake chamber 314 and the outside (discharge valve) The other end in the longitudinal direction of the discharge valve 370 (the part on the opposite side of the hinge shaft 372) due to the pressure difference (the internal pressure is lower than the external pressure) of the pressure (external pressure) of the nozzle member 350 from 370 Since the valve overcomes the urging force of the valve opening spring 376 and is not pushed downward, the discharge valve 370 closes the ink drain hole 326. For this reason, the mist fan intake chamber 312 and the platen fan intake chamber 314 are airtightly separated (fluidly independent) to provide a space for performing their respective functions.

  As described above, according to the fan unit 200, the ink drain hole 326 is discharged by the pressure difference between the internal pressure (internal pressure) of the mist fan intake chamber 312 and the platen fan intake chamber 314 and the external pressure (external pressure). Since the valve 370 moves to open and close the ink drain hole 326, components and members for opening and closing the ink drain hole 326 are unnecessary except for the discharge valve 370 and the valve opening spring 376. Further, while the mist fan 202 and the platen fan 204 fan are driven, the ink drain hole 326 remains closed due to the pressure difference between the internal pressure and the external pressure, so that the suction efficiency for sucking the external gas is improved.

FIG. 2 is a perspective view illustrating a schematic configuration of the printer as viewed from the front. It is a perspective view which shows schematic structure of the printer of FIG. 1 seen from the back. It is a perspective view which shows the inside of a printer. It is a perspective view which expands and shows a platen and its peripheral part. It is explanatory drawing which shows typically a fan unit when the fan has stopped. It is explanatory drawing which shows typically a fan unit when the fan is driving (rotating). It is a perspective view which shows the printer which removed the exterior cover etc. It is a perspective view which shows the printer which removed the platen etc. from the state of FIG. It is a perspective view which shows schematic structure of a fan unit. It is a top view which shows a bottom case. It is a perspective view which shows a bottom case from the top. It is a perspective view which shows a bottom case from the bottom. It is the bottom view which looked at the fan base from the bottom (back side). FIG. 3 is an enlarged perspective view illustrating an ink tray. It is a perspective view which shows a nozzle member from the top. It is a perspective view which shows the part of the back side of an ink removal hole among the bottom faces of a bottom case, and has removed the nozzle member. It is a perspective view which expands and shows the peripheral part of an ink removal hole among the bottom faces of a bottom case. It is a perspective view which shows a discharge valve from the bottom.

Explanation of symbols

100, 200 Fan unit 102 Intake duct 102a Suction port 104 Exhaust duct 104a Exhaust port 108 Fan 112a Valve 112b Spring 114 Opening and closing part 202 Mist fan 204 Platen fan 312 Mist fan intake chamber 314 Platen fan intake chamber 316 Exhaust chamber 318 Exhaust ink flow path Chamber 326 Ink drain hole 370 Discharge valve 376 Valve opening spring

Claims (6)

In a fan unit that includes a duct through which a gas passes and a fan that allows the gas to pass through the duct, and the gas passes through the duct by driving the fan.
A fan unit comprising an opening / closing part that opens and closes a part of the duct that opens and closes due to a pressure difference between a pressure inside the duct and a pressure outside the duct. The opening / closing part is
2. The fan unit according to claim 1, wherein the fan unit is opened when the pressure difference is within a predetermined range, and is closed when the pressure difference is outside the predetermined range. The duct is
An intake duct that sucks in the external gas,
An exhaust duct through which the gas inside is exhausted,
The intake duct and the exhaust duct are in communication,
The fan is
The fan unit according to claim 1, wherein the fan unit is disposed in the communicating portion. The intake duct is
By driving the fan, the internal pressure becomes lower than the external pressure and external gas is sucked, and the opening / closing part is attached,
The opening / closing part is
The fan unit according to claim 3, wherein the fan unit is closed during driving of the fan. The exhaust duct is
The internal pressure of the fan becomes higher than the external pressure by driving the fan, and the internal gas is discharged, and the opening / closing part is attached,
The opening / closing part is
The fan unit according to claim 3, wherein the fan unit is closed while the fan is driven. An image forming apparatus comprising the fan unit according to claim 1 as a fan unit for collecting ink mist.

Images