JP2017021116A - Cooling device and image forming apparatus - Google Patents

Abstract

A cooling device capable of realizing a compact duct and effective cooling of a cooling target portion close to an air flow path is provided. A cooling device (3) provided in an image forming apparatus for forming an image on a recording medium, comprising a blower (31) for blowing air to a part to be cooled inside the main body of the apparatus, and the air is discharged from an exhaust port (37) of the blower (31). A duct 32 having airflow paths 51 and 52 for circulating the air to be cooled, air branching means 45 and 46 provided in the airflow paths, and a wall surface 55 of the airflow path 52 facing the cooling target part. The cooling device has exhaust holes 47 and 48 for allowing air to flow through the air flow path toward the air outlet, and the airflow path is branched into two directions perpendicular to the exhaust direction of the air blower with the air branching means as the starting point. . [Selection drawing] Fig. 4

Description

  The present invention relates to a cooling device used in an electrophotographic image forming apparatus, and an image forming apparatus such as a copying machine, a printer, and a facsimile equipped with the cooling device.

  In a cooling device used in an image forming apparatus, from the viewpoint of power consumption and cost, the cooling target part is cooled by blowing an air flow through a flow path of a duct branched toward a plurality of cooling target parts by one fan. The technique to do is used conventionally (patent document 1).

  In the conventional cooling device, the air flow path of the branched duct has a shape that is obliquely or gently bent toward the portion to be cooled, so there is a problem that a large space is required and the device is enlarged.

  Then, an object of this invention is to provide the cooling device which can implement | achieve the effective cooling of the cooling target part close | similar to the size reduction of a duct and the airflow path | route.

  In order to solve this problem, the present invention is a cooling device provided in an image forming apparatus for forming an image on a recording medium, the blowing unit for blowing air to a cooling target portion inside the image forming apparatus main body, and the blowing unit Air branching means for branching so as to change the direction of airflow through which the air discharged from the exhaust outlet flows to a direction orthogonal to the discharge direction of the air discharged from the exhaust outlet, and the air branched by the air branching means An exhaust hole that is formed in a wall surface of the air flow path that faces the cooling target part and that passes air toward the cooling target part provided in a direction that intersects the air flow direction of the air flow path. And a cooling device characterized by comprising:

  Since the air flow paths branched in the duct are arranged on the same straight line, the width of the duct can be reduced and the cooling device can be downsized.

1 is a schematic diagram illustrating an overall configuration of an image forming apparatus 1 according to an embodiment. 2 is a schematic diagram illustrating an arrangement of a cooling device 3 in the image forming apparatus 1. FIG. 3 is a perspective view of the cooling device 3. FIG. 3 is a plan view of the cooling device 3. FIG. It is sectional drawing in the XX line of Fig.3 (a). 3 is a partial schematic diagram of a cooling device 3. FIG. It is a schematic plan view showing the shape of the exhaust hole 48 and the airflow. FIG. 6 is a schematic view showing the shape of an exhaust hole 48b formed in the side wall 55 when facing the wall surface (side wall) provided with the exhaust hole (when viewed from a viewer standing on the bottom surface 54). FIG. 10 is a schematic view showing a modification of the second protrusion 45. 1 is a schematic partial cross-sectional view in an image forming apparatus. 3 is a plan view of the cooling device 3. FIG.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a schematic diagram illustrating an overall configuration of an image forming apparatus 1 according to the embodiment.
A recording sheet 7 serving as a printing medium / recording medium is accommodated in a sheet feeding unit at the bottom of the apparatus. A conveyance roller 10 is arranged on the downstream side in the recording paper conveyance direction from the paper supply unit, and conveys the recording paper 7 picked up by the pickup roller 12 to the transfer position between the developing device 80 and the transfer unit 81 at the start of printing. The developing device 80 includes a photosensitive drum as an image carrier that carries a toner image therein. The transfer unit 81 transfers the toner image formed on the photosensitive drum to the recording paper 7. A fixing device 9 that fixes an unfixed image carried on the recording paper 7 by heat and pressure is disposed downstream of the developing device 80 and the transfer unit 81 in the recording paper conveyance direction. The fixing device 9 includes a fixing roller as a fixing member and a pressure roller as a pressure member.

  A paper discharge roller 11 for discharging and stacking the fixed recording paper 7 to the paper discharge unit 2 is provided downstream of the fixing device 9 in the recording paper conveyance direction. A cooling device 3 is disposed below the paper discharge unit 2, and a toner bottle 5 containing toner is disposed below the cooling device 3. On the left side of the cooling device 3, an electrical board 4 including an electronic circuit for controlling each component is installed. Under the toner bottle 5, an exposure unit 6 that irradiates the photosensitive drum with exposure light based on image information read by the document reading unit at the top of the apparatus main body is disposed.

The cooling device 3 includes an intake guide 30, a blower fan 31, a first duct 32, a second duct 33, and the like. The developing device 80 and the electrical substrate 4 can be cooled by the cooling device 3.
In this embodiment, although the example of arrangement | positioning of the cooling device 3 in the case of cooling the developing device 80 and the electrical equipment board | substrate 4 is shown, a cooling object part is not limited to these parts, Other parts are made into a cooling object part. Also good.

FIG. 2 is a schematic diagram showing the arrangement of the cooling device 3 in the image forming apparatus 1. FIG. 3A is a perspective view of the cooling device 3, and FIG. 3B is an exploded perspective view of the cooling device 3.
As shown in FIG. 2, the cooling device 3 is disposed at the center inside the main body of the image forming apparatus 1. Here, the frame of the image forming apparatus 1 and the cooling device 3 arranged inside are simply shown. The blower fan 31 of the cooling device 3 is disposed at the center portion in the sheet passing width direction, which is a direction intersecting the recording sheet conveyance direction, and is located at the center portion of the apparatus in the left-right direction as viewed from the front of the image forming apparatus 1. Placed in. The intake guide 30 extends to the front of the apparatus, and can take in air outside the apparatus from the opening 35 (see FIG. 3) at the tip thereof and guide the air to the internal blower fan 31. A front cover that can be opened and closed is attached to the front of the apparatus. Since a gap is formed between the closed front cover and the opening 35, cold air outside the apparatus is taken in from the opening 35 and used for cooling. . Note that a louver may be provided on the front cover facing the opening 35 instead of the gap.

  As shown in FIG. 3A, the cooling device 3 includes a blower fan 31 as a blowing unit for sucking air from the outside of the image forming apparatus 1 and blowing air to a cooling target portion inside the image forming apparatus main body. Have. The blower fan 31 is a sirocco fan, for example. In addition, the cooling device 3 includes a first duct 32 as a duct having an airflow path (first airflow path 51 and second airflow path 52) through which the air discharged from the exhaust port 37 of the blower fan 31 and the intake guide 30 is circulated. And a second duct 33 connected thereto. One end of the intake guide 30 is connected to the suction portion (lower surface of the blower fan) side of the blower fan 31, and the opening 35 at the other end extends to the vicinity of the front cover of the image forming apparatus 1 as described above. Air can be sucked from the outside of the device 1. The air discharged from the blower fan 31 flows through the first duct 32 in two directions indicated by arrows. As will be described later, the air that has flowed to the right side (the front side of the apparatus) flows through the first air flow path 51 and the second air flow path 52 in the first duct 32 and the second duct 33 connected to the first duct 32. . As illustrated, the second duct 33 is bent, and by extending the second duct 33, air can be guided to a desired cooling target portion. However, if it is not necessary to cool another cooling target portion using the second duct 33, the air may be discharged from the discharge port without extending the second duct 33 as shown in FIG.

  As shown in FIG. 3 (b), the first duct 32 has an upper half 32a and a lower half 32b, the lower half 32b receives the blower fan 31, and the upper half 32a covers this. Thus, the blower fan 31 is accommodated in the first duct 32. The blower fan 31 is disposed in the center of the inside of the image forming apparatus main body, and sucks air from the lower surface when the fan rotates and exhausts it from the front exhaust port 37. At the time of assembly, the cover 36 attached to the upper half 32a covers the upper surface of the blower fan 31 and protects the blower fan 31 from dust and dust. The blower fan 31 is disposed on the vent hole 39 formed in the lower half 32 b, and one end of the intake guide 30 is fitted into the lower opening of the vent hole 39. The intake guide 30 is composed of two halves and extends linearly, but the end portion that fits into the lower opening of the vent hole 39 is bent upward. A second duct 33 can be connected to the end of the first duct 32 on the front side of the apparatus main body. Therefore, the first duct 32 and the second duct 33 form an air flow path toward the developing device 80 and the electrical board 4 which are the cooling target portions. In FIG. 1, the extended second duct 33 is shown, and airflow can be blown to the cooling target portion (electrical board 4 in this example) in the apparatus main body in this way.

FIG. 4 is a plan view of the cooling device 3.
The cooling device 3 has two first air flow paths 51 and second air flow paths 52 that are divided into two upper and lower stages, and each of these air flow paths intersects and is orthogonal to the recording paper transport direction. It branches toward one end and the other end. The first air flow path 51 and the second air flow path 52 are branched in two directions perpendicular to the exhaust direction of the blower fan 31 with the first protrusion 46 and the second protrusion 45 as the starting point. Here, the first protrusion 46 protrudes from the bottom surface of the first air flow path 51. The second protrusion 45 protrudes from the second air flow path 52, and the upper surface of the second protrusion 45 is set to be the same height as or higher than the bottom surface of the first air flow path 51. Therefore, since the first air flow path 51 and the second air flow path 52 that are close to the blower fan 31 are arranged on the same straight line, the cooling device 3 can be downsized.

  The developing device 80 is disposed below the cooling device 3, and the wall surface (side wall) of the second air flow path 52 facing the developing device 80 is an exhaust hole (also referred to as a slit) 47 through which air flows toward the developing device 80. , 48. The second air flow path 52 is formed in the vicinity of the blower fan 31, and a second protrusion 45 serving as an air branching unit is formed on the path. The first air flow path 51 is formed away from the blower fan 31 (formed on the downstream side in the air flow direction from the second protrusion 45), and a first protrusion 46 as an air branching unit is formed on the path. .

  The exhaust holes 47 and 48 are formed in the side wall 52a and the bottom surface 52b of the second airflow path 52, and in FIG. 4, the bottom surface exhaust holes connected to the side wall exhaust holes can be seen. Four exhaust holes 47 are provided in the region 41 at intervals, and have an opening that becomes larger as the distance from the blower fan 31 increases, that is, the downstream side in the airflow direction. Three exhaust holes 48 are provided in the region 42 at intervals, and have an opening that becomes larger as the distance from the blower fan 31 increases, that is, the downstream side in the airflow direction. This is because the air pressure decreases as the distance from the blower fan 31 to the exhaust holes 47 and 48 increases. By changing the sizes of the exhaust holes 47 and 48 in this way, the amount of air passing through the exhaust holes 47 and 48 is made uniform, and the amount of the longitudinal airflow blown to the developing device 80 is made uniform. Further, by providing an exhaust hole in the air flow path from the branch position of the air flow to the discharge port, it is possible to cool the developing device 80 that is a cooling target portion extending along the air flow path in the vicinity of the air flow path. it can.

  By forming an exhaust hole on the bottom surface connected to the exhaust hole on the side wall, an air flow can be blown to the developing device 80 that is a portion to be cooled disposed below the cooling device 3. In this case, it is preferable that the opening on the bottom surface is not perpendicular to the bottom surface and is formed obliquely downward so as not to generate a vortex of the airflow. The reason for this will be described later. Of course, when the cooling device 3 is disposed directly above the developing device 80, it is not necessary to provide exhaust holes on the side walls, and it is only necessary to provide exhaust holes only on the bottom surface. In other words, the cooling device 3 may have the exhaust holes 47 and 48 that are exhaust holes formed in the wall surface of the second air flow path 52 facing the cooling target part, and allow air to flow toward the cooling target part. .

  As shown in FIG. 4A, the airflow 62 branched to the back side of the apparatus main body in the second airflow path 52 by the second protrusion 45 flows through the region 41, passes through the exhaust hole 47, and is located below the developing device. Cool 80. Further, a part of the air flow 62 further branches into an air flow 43 for cooling the toner replenishment path which is another cooling target portion. As a result, it is possible to cool another cooling target portion while maintaining the downsizing of the duct. On the other hand, the airflow 63 branched to the front side of the apparatus main body in the second airflow path 52 by the second protrusion 45 flows through the region 42 and cools the developing device 80 located therebelow through the exhaust hole 48. The air flow 62 and the air flow 63 travel in opposite directions, in other words, form an angle of 180 °, which means that the second air flow path 52 is formed in a straight line.

  No exhaust hole is provided in the first air flow path 51. The airflow 61 branched to the rear side of the apparatus main body in the first airflow path 51 by the first protrusion 46 exits obliquely upward from the opening at the tip while cooling the first airflow path 51, toward the fixing device 9. The hot air from the fixing and fixing device 9 is kept away from the cooling device 3 by spraying. On the other hand, the air flow 44 branched to the front side of the apparatus main body in the first air flow path 51 by the first protrusion 46 is deflected and guided by the second duct 33 connected to the first duct 32 and guided to the electrical board 4. The airflow 61 and the airflow 44 proceed in opposite directions, in other words, form an angle of 180 °, which means that the first airflow path 51 is formed in a straight line.

  As shown in FIG. 4B, which is a partially enlarged view of FIG. 4A, a second protrusion 45 is provided in the vicinity of the blower fan 31 so as to face the exhaust port 37 of the blower fan, and is separated from the blower fan 31. A first protrusion 46 is provided behind the second protrusion 45 (downstream side in the airflow direction). Since these protrusions have a smooth mountain shape or curved surface shape, the airflow from the exhaust port 37 is smoothly branched right and left along the side surfaces of the protrusion from the center of the protrusion. The airflow branched by the second protrusion 45 becomes the airflow 62 and the airflow 63, and the airflow branched by the first protrusion 46 becomes the airflow 61 and the airflow 44. The shape and position of the second protrusion 45 may be determined so that the airflow 62 and the airflow 63 are as strong as possible. Note that the first protrusion 46 is slightly shifted to the right side from the center of the second protrusion 45 for reasons of design of the cooling device 3 to be described later, but the present invention is not limited to this configuration. The lateral width of the exhaust port 37 and the lateral width of the second protrusion 45 are substantially equal.

  On the downstream side of the exhaust hole 47 closest to the blower fan 31, a rib 56 protrudes from the side wall of the second air flow path 52, so that the air flow 62 is welcomed into the exhaust hole 47. The reason why the rib 56 is formed is that the airflow passing through the exhaust hole 47 closest to the blower fan 31 is less than the airflow passing through the other exhaust holes 47 due to various factors. Therefore, depending on the configuration of the cooling device, the ribs 56 may not be provided, and conversely, ribs may be provided for all the exhaust holes 47 and 48.

  The first duct 32, the intake guide 30 and the second duct 33 are all made of a resin member that is light and can be manufactured at low cost and has low thermal conductivity. However, instead of this, the upper half 32a of the first duct 32 disposed in the vicinity of the high-temperature fixing device 9 is made of a resin member having a low thermal conductivity, and the lower side close to the developing device 80 that is a cooling target portion. The half body 32b may be made of a metal member having a high thermal conductivity. This makes it difficult for hot air from the high-temperature fixing device 9 to be transmitted to the first air flow path 51 and the developing device 80 (see FIG. 10). Further, the heat from the developing device 80 is easily absorbed by the first air flow path 51, and the air from the outside of the apparatus is circulated through the first air flow path 51, so that the development located in the first air flow path 51 and the lower part thereof. Effective cooling of the device 80 is possible.

FIG. 5 is a cross-sectional view taken along line XX in FIG.
As shown in the figure, the second protrusion 45 is disposed in the lower part of the exhaust fan 37 in the vertical width, and the first protrusion 46 is disposed in the upper part of the blower fan 31 in the vertical width. ing. In other words, the sum of the height of the second protrusion 45 and the height of the first protrusion 46 is substantially equal to the height of the exhaust port 37 of the blower fan 31. Therefore, a part of the airflow that has come out from the exhaust port 37 hits the second protrusion 45 on the near side, and is branched into the airflow 62 and the airflow 63, and the rest of the airflow that has come out from the exhaust port 37 hits the first protrusion 46 on the back side, The air current 61 and the air current 44 are branched. The first air flow path 51 and the second air flow path 52 are formed in parallel in the direction perpendicular to the longitudinal direction of the cooling device 3, but are divided into upper and lower stages, and the first air flow path 51 is the second air flow path. It is in a position higher than 52. The first protrusion 46 is slightly shifted to the right from the center of the second protrusion 45.

FIG. 6 is a partial schematic diagram of the cooling device 3. 6A is a plan view of the second protrusion 45 and the first protrusion 46 of the apparatus, and FIG. 6B is a front view of the second protrusion 45 (from the lower side to the upper side in FIG. 6A). It is the schematic when it sees from. In addition, illustration of the 1st protrusion 46 is abbreviate | omitted in FIG.6 (b).
A guide portion 58 is formed on the upper half body 32a, and a second protrusion 45 is formed on the lower half body 32b. As shown in FIG. 6B, the guide portion 58 is positioned above the second protrusion 45 when the upper half body 32a and the lower half body 32b are assembled. As shown in FIG. 6A, the guide portion 58 extends from the left side of the center of the second protrusion 45 to the back side of the apparatus main body. Accordingly, when viewed in this cross section, the rectangular exhaust port 37 region indicated by the alternate long and short dash line is divided into an upper right region 59, an upper left region 60 where the guide portion 58 is present, and a lower region 66 where the second protrusion 45 is present. Therefore, the airflow discharged from the exhaust port 37 of the blower fan 31 is divided into upper and lower portions by the second protrusion 45, and the airflow in the lower region 66 hits the front of the second protrusion 45 and is divided into right and left, and the airflow 62 and the airflow 63 Become. The airflow in the upper right region 59 flows to the back side because there is no obstruction, and is divided into left and right by the first protrusions 46 on the first airflow path 51 to become an airflow 61 and an airflow 44. The airflow (airflow 62) in the upper left region 60 is guided by the guide portion 58 and becomes an airflow 43 for cooling the toner supply path.

  Since the guide portion 58 covers a part of the area of the exhaust port 37 indicated by a dotted line, the first protrusion 46 on the first airflow path 51 is located at the center of the second protrusion 45 as shown in FIG. Is shifted to the right side. More specifically, the center of the first protrusion 46 coincides with the center of the upper right region 59. As a result, the airflow passing through the upper right region 59 is evenly branched right and left by the first protrusion 46.

Here, for convenience, the branching of the airflow discharged from the exhaust port 37 of the blower fan 31 has been described in an easy-to-understand manner, but the airflow needs to be strictly divided into three regions by the second protrusion 45 and the guide portion 58. There is no.
Further, the length of the exhaust port 37 (in the left-right direction in FIG. 6) and the width of the second protrusion 45 are substantially the same. Therefore, the size in the vertical direction in FIG. 6 can be reduced as compared with Patent Document 1 in which the shape is bent obliquely or gently toward the portion to be cooled.

FIG. 7 is a schematic plan view showing the shape of the exhaust hole 48 and the airflow.
FIG. 7 shows the exhaust holes when the cooling device is viewed from above, as in FIG. The airflow flows through an airflow path defined by the side wall 55 and the bottom surface 54 of the first duct 32. The exhaust hole 48 is formed in the side wall 55, and the airflow passing through the exhaust hole 48 hits the cooling target portion. Here, as shown in FIG. 7A, if the exhaust hole 48 is provided perpendicular to the airflow direction with respect to the side wall 55, the pressure difference at the step becomes large and a vortex is generated, and this vortex generates a wind noise. Cause it to occur. Therefore, as shown in FIG. 7B, exhaust holes 48 are provided in the side wall 55 obliquely with respect to the airflow direction. Specifically, the exhaust hole 48 is formed in the wall surface (side wall 55) in an oblique direction from upstream to downstream in the airflow direction. Therefore, as shown in the drawing, the airflow passing through the exhaust hole 48 and the airflow flowing in the airflow path without passing through the exhaust hole 48 form an acute angle. Thereby, the generation of vortices can be suppressed by reducing the pressure difference at the step and making the change in the airflow gentle, and the generation and size of wind noise can be reduced. As for the exhaust hole 47, the direction of the exhaust hole is formed opposite to that shown in FIG.

  In FIG. 4A, the exhaust holes 47 and 48 have different sizes, but the angles of the exhaust holes 47 and 48 with respect to the side walls as shown in FIG. 7B are the same. However, the angles of the exhaust holes 47 and 48 with respect to the side walls may be formed differently, and the angle of the airflow hitting the cooling target portion may be changed.

  In the present embodiment, since the developing device 80 that is the cooling target portion is located obliquely below the cooling device 3, the exhaust hole 48 is obliquely below, that is, above the side wall 55 so that the airflow is discharged obliquely downward. Preferably, it is formed from the bottom to the bottom (FIG. 7D).

FIG. 7C is a schematic plan view showing a modified example of the exhaust hole 48.
A guide rib 57 extending toward the developing device 80 is provided on the outer wall surrounding the exhaust hole 48 provided obliquely on the downstream side in the airflow direction. The air flow can be reliably guided to the cooling target portion by the guide rib. At this time, it is preferable that the air flow entrance of the exhaust hole 48 does not protrude from the side wall 55.

FIG. 8 is a schematic view showing the shape of the exhaust hole 48b formed in the side wall 55 when facing the wall surface (side wall) provided with the exhaust hole (when viewed from the viewer standing on the bottom surface 54). is there.
As shown in FIG. 8A, when the exhaust hole provided in the airflow path is a rectangular exhaust hole 48a, the airflow hits the side wall 55 perpendicularly, so that the airflow is disturbed and a vortex is easily generated. Therefore, as shown in FIG. 8B, the exhaust holes are formed as exhaust holes 48b inclined with respect to the airflow direction. The exhaust hole 48b extends obliquely upward toward the downstream side in the airflow direction from the bottom surface 54 adjacent to the side wall 55 where the exhaust hole is formed, and has a parallelogram shape. Therefore, the angle α of the exhaust hole 48b on the upstream side in the airflow direction is an acute angle. Due to the parallelogram cross-sectional shape of the exhaust hole 48b, the airflow can be received and the airflow can be gently guided to the outside of the duct, and noise can be reduced.

FIG. 9A is a schematic front view showing a modification of the second protrusion 45, and FIG. 9B is a schematic plan view thereof.
In this example, the second protrusion 45 formed in a smooth mountain shape is formed corresponding to the center in the width direction of the exhaust port 37 of the blower fan 31, and the developing device 80 is provided at the center of the second protrusion 45. A rectangular hole 49 through which air flows is formed. Here, the hole 49 only needs to have a symmetrical shape. For example, the hole 49 may be circular. Therefore, the airflow that has exited from the exhaust port 37 of the blower fan 31 and hit the second protrusion 45 flows through the hole 49 and hits the developing device 80, the airflow 62 that flows to the back side of the apparatus body, and the front side of the apparatus body. Branches to the air flow 63. By forming the holes 49, the developing device 80 below the second protrusions 45 can be cooled, and the amount of the longitudinal airflow blown to the developing device 80 can be made more uniform. Since the airflow exiting from the exhaust port 37 of the blower fan 31 directly hits the second protrusion 45, the hole 49 may be small as shown in FIG. 9A, and the opening of the hole 49 has a symmetrical shape. If you do. The size of the hole 49 is selected so that, for example, the amounts of the left and right airflows 62 and 63 are the same, or the left and right airflows 62 and 63 are not weakened.

FIG. 10 is a schematic partial cross-sectional view in the image forming apparatus.
The developing device 80, which is a cooling target portion, is provided in a direction that intersects the airflow direction of the airflow path. The air (arrow 86) discharged from the exhaust holes 47 and 48 exits downward from the second air flow path 52 and blows onto the upper portion of the developing device 80. The first air flow path 51 and the second air flow path 52 are formed in parallel with the longitudinal direction of the developing device 80, and the first air flow path 51 is located closer to the fixing device 9 that is a heat source. Accordingly, the first air flow path 51 has a role as a heat transfer suppression layer / air layer that suppresses the transfer of hot air (arrow 85) from the high-temperature fixing device 9 to the developing device 80 and the second air flow path 52. . The first air flow path 51 suppresses the temperature rise of the toner collection path 82 and the like installed in the upper part of the developing device 80 and the temperature rise of the air in the second air flow path 52. The toner collection path 82 is a path for collecting and re-supplying toner that has not been used for development. By preventing the temperature of the toner recovery path 82 from rising, the toner inside can be prevented from melting.

  As described above, according to the cooling device according to the embodiment of the present invention, the cooling device 3 including the first duct 32 and the second duct 33 is arranged on the same straight line with the two airflow paths branched. Downsizing is realized. Further, by providing the exhaust hole in the air flow path from the branch position of the air flow to the discharge port, it is possible to cool the portion to be cooled close to the air flow path. Air can be sent to a wide range of objects to be cooled using a small cooling device.

  If a slit is provided perpendicular to the airflow direction of the duct, the airflow generates vortices and the like in the slit portion, causing pressure loss, resulting in a decrease in cooling efficiency and wind noise. By forming the slit inclined from the airflow direction toward the cooling target portion, the pressure loss can be reduced and the generation of vortices can be suppressed, so that the cooling efficiency can be increased and the wind noise can be suppressed.

  In addition, when the developing device 80 can be sufficiently cooled by the airflow from the exhaust holes 47 and 48 of the second airflow path 52, the first airflow path 51 that mainly functions as the heat transfer suppression layer may be omitted. For example, as shown in FIG. 11, only the second air flow path 52 may be used.

  The image forming apparatus 1 according to the embodiment of the present invention includes a developing device 80 having an image carrier that carries a toner image, a fixing device 9 that is a heat source for fixing the toner image carried on the recording medium 7, and Preferably, the cooling device 3 is provided between the developing device 80 and the fixing device 9.

Cooling device 31 Blower fan (Blower unit)
51 First air flow path (air flow path)
52 Second air flow path (air flow path)
45 Second projection (air branching means)
46 1st protrusion (air branching means)
47, 48 Exhaust hole 80 Developer (cooling target part)

JP 2013-238735 A

Claims (10)

A cooling device provided in an image forming apparatus for forming an image on a recording medium,
A blowing means for blowing air to a cooling target inside the image forming apparatus main body;
An air branching means for branching so as to change the airflow direction in which the air discharged from the exhaust port of the blower means changes to a direction orthogonal to the discharge direction of the air discharged from the exhaust port;
An air flow path for circulating the air branched by the air branching means;
An exhaust hole that is formed on a wall surface of the air flow path facing the cooling target part and that allows air to flow toward the cooling target part provided in a direction intersecting the air flow direction of the air flow path. And cooling device.   The cooling device according to claim 1, wherein the exhaust hole is formed in the wall surface in an oblique direction from upstream to downstream in the airflow direction.   The cooling device according to claim 1 or 2, wherein when facing the wall surface provided with the exhaust hole, the exhaust hole is an exhaust hole inclined with respect to the airflow direction.   The cooling device according to any one of claims 1 to 3, wherein a plurality of the exhaust holes are provided at intervals and have a larger opening toward the downstream side in the airflow direction.   The air branching means is formed corresponding to the center part in the width direction of the exhaust port of the air blowing means, and a hole through which air flows through toward the cooling target part is formed at the center of the air branching means. The cooling device according to any one of claims 1 to 4, wherein   The cooling device according to any one of claims 1 to 5, wherein a guide rib extending toward the cooling target portion is provided on an outer wall surrounding the exhaust hole. The air flow path has a first air flow path having no exhaust hole and a second air flow path having the exhaust hole,
The first air flow path and the second air flow path are formed in parallel with the longitudinal direction of the cooling target portion, and the first air flow path is located closer to the heat source. The cooling apparatus as described in any one of -6.   8. The cooling device according to claim 7, wherein one of the airflows branched in two directions by the air branching means in the second airflow path is further branched toward another cooling target portion.   The cooling device according to any one of claims 1 to 8, wherein a length in the width direction of the air branching unit is the same as a length in the width direction of the exhaust port of the blower unit. A developing device having an image carrier for carrying a toner image;
A fixing device which is a heat source for fixing a toner image carried on a recording medium;
An image forming apparatus comprising: the cooling device according to claim 1 between the developing device and the fixing device.

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