KR102063944B1 - Electrophotographic image forming apparatus - Google Patents

Abstract

The disclosed electrophotographic image forming apparatus includes a recording medium storage unit in which a recording medium is stored, a pickup unit for picking up the recording medium stored in the recording medium storage unit, and interlocked with each other, and the recording picked up by the pickup unit. A pair of feed rollers for conveying the medium, an image forming unit for forming an image on the recording medium conveyed by the pair of feed rollers, and a first feed roller supporting at least one of the pair of feed rollers And a frame including a support area and a second support area for supporting at least a portion of the image forming unit, wherein the frame is formed between the first support area and the second support area and includes the first support area. And a vibration blocking slit for blocking vibration directly transmitted to the second support region.

Description

Electrophotographic image forming apparatus

An electrophotographic image forming apparatus capable of maintaining stable image quality.

An image forming apparatus using an electrophotographic method supplies a toner to an electrostatic latent image formed on the photosensitive member to form a visible toner image on the photosensitive member, transfers the toner image to a recording medium, and then transfers the transferred toner image to the recording medium. The image is printed on the recording medium by fixing.

To this end, the image forming apparatus includes a pickup unit for picking up a recording medium, a transfer unit for transferring a picked up recording medium, an image forming unit for forming an image on the transferred recording medium, and a fixing unit for fixing the recording medium on which the image is formed. Each unit may be supported in a predetermined frame.

On the other hand, when at least one of the image forming units is exposed to vibration in the process of forming an image by the image forming apparatus as described above, this may lead to deterioration of the image quality.

The vibration transmitted to the image forming unit may be generated by the image forming unit itself, but may be generated by a unit other than the image forming unit. For example, vibration may occur in the transfer unit for transferring the recording medium to the image forming unit. The vibration generated in the transfer unit may be transmitted to the image forming unit via a frame supporting the transfer unit. As a result, the image forming unit may be momentarily shaken, making it difficult to maintain stable image quality.

An object of the present invention is to provide an electrophotographic image forming apparatus capable of preventing direct transmission of vibration between the transfer unit generating the vibration and the image forming unit forming the image, while being supported by one frame.

An electrophotographic image forming apparatus according to an aspect of the present invention includes a recording medium storage unit in which a recording medium is stored; A pickup unit for picking up the recording medium stored in the recording medium storage unit; A pair of feed rollers which mesh with each other to rotate and convey the recording medium picked up by the pick-up unit; An image forming unit which forms an image on the recording medium conveyed by the pair of conveying rollers; And a frame including a first support region for supporting at least one of the pair of feed rollers and a second support region for supporting at least a portion of the image forming unit. And a vibration blocking slit formed between the first support region and the second support region to block transmission of vibration directly from the first support region to the second support region.

At least a portion of the vibration blocking slit may extend in a direction crossing the direction from the first support region to the second support region.

The length of the vibration blocking slit may be 80% to 150% of the axial length of the rotating shaft of the feed roller.

The separation distance between the vibration blocking slit and the rotating shaft of the feed roller may be 1.5% to 30% of the axial length of the rotating shaft of the feed roller.

One of the pair of feed rollers is a first feed roller which is driven to rotate to feed the recording medium, and the other of the pair of feed rollers is a second feed roller which is driven along the first feed roller. Can be.

The second feed roller may be supported by the first support region.

And a friction unit disposed to face the pickup unit and providing a frictional force to a recording medium conveyed between the pickup unit and a direction opposite to the transfer direction.

The pair of feed rollers may support the recording medium when the rear end of the recording medium exits between the pickup unit and the friction unit.

The frame may be integrally formed with the first support region and the second support region.

The frame includes a first subframe including the first support region, a second subframe including a second support region and separated from the first subframe, and the first subframe and the second subframe. The sub frame may be fixed by the fastening member.

The image forming unit includes a photosensitive member, an exposure unit for scanning light to form an electrostatic latent image on the photosensitive member, and a developing unit for supplying toner to the photosensitive member on which the electrostatic latent image is formed to form a toner image on the photosensitive member. And a transfer unit for transferring the toner image onto a recording medium.

The exposure unit may be supported by the second support region.

According to the above-described electrophotographic image forming apparatus, an electrophotographic image forming apparatus capable of providing stable image quality by an image forming unit supported by the same frame as the conveying unit even if vibration occurs in the conveying unit may be implemented. Can be.

1 is a configuration diagram schematically showing an embodiment of an electrophotographic image forming apparatus according to the present invention.
2A to 2C are views schematically showing how the recording medium is picked up by the pickup unit and transferred to the transfer unit in FIG.
FIG. 3 is a view illustrating a recording medium being transported between the pickup unit and the friction unit in FIG. 2C.
4 is an assembled perspective view illustrating a state in which a transfer unit and an exposure unit of the electrophotographic image forming apparatus according to FIG. 1 are mounted on a side frame and a base frame,
5 illustrates the top view of FIG. 4.
6 is a cross-sectional view taken along a line VI-VI in FIG. 5,
7 is a view showing a modified embodiment of FIG.
8 is a cross-sectional view taken along the line VIII-VIII in FIG. 5.
9 is a view for explaining a process of blocking the transmission of vibration in the base frame.
10A to 10B show acceleration values during printing in a state in which the second feed roller and the exposure unit are supported by a base frame (comparative example) in which the vibration blocking slit is not formed, and FIGS. 11A to FIG. 11b is an acceleration value measured during printing while the second feed roller and the exposure unit are supported by the base frame (Example) in which the vibration blocking slit is formed.
12A and 12B show a modified embodiment of the vibration blocking slit.

EMBODIMENT OF THE INVENTION Hereinafter, embodiment of this invention is described in detail, referring an accompanying drawing. In addition, in the present specification and drawings, components having substantially the same functional configuration will be omitted by the same reference numerals.

1 is a configuration diagram schematically showing an embodiment of an electrophotographic image forming apparatus according to the present invention. The image forming apparatus of this embodiment is a monochrome image forming apparatus. The color of the toner is, for example, black.

Referring to FIG. 1, the image forming apparatus includes a recording medium storage unit 10, 10A, a pickup unit 20, 20A, a friction unit 30, a transfer unit 40, an image forming unit 70, and a fixing unit 80. ) And a discharge unit 90.

The recording medium storage units 10 and 10A store the recording medium P and supply the recording medium P to the image forming apparatus. As an example, the recording medium storage unit 10 loads the removable tray 11 and the recording medium P on the main body 1 of the image forming apparatus, and loads the recording medium P into the pickup unit 20. ) May include a knockup plate 12. The knockup plate 12 is elastically pressed in the direction of the pickup unit 20 by the elastic member 13. As another example, the recording medium storage unit 10A may be a plate 14 on which the recording medium P is loaded to manually feed the recording medium P. As shown in FIG.

The pickup unit 20 picks up the recording medium P stored in the recording medium storage unit 10. The pickup unit 20 may be a circular roller. The pickup unit 20 is supported by a rotation shaft 21 and may be elastically deformed so that an outer circumferential surface thereof faces the knockup plate 12 to form a nip. The pick-up unit 20 can withdraw the recording medium P from the recording medium storage unit 10 by rotating while the outer circumferential surface is in contact with the recording medium P. FIG.

The friction unit 30 is disposed to face the pickup unit 20. The friction unit 30 is pressed in the direction toward the pickup unit 20 by the elastic member 31. The friction unit 30 provides a friction force in a direction opposite to the conveying direction on the rear surface of the recording medium P conveyed between the pickup unit 20 and the pickup unit 20. Thus, when a plurality of recording media (P) is located between the friction unit 30 and the pickup unit 20, the remaining recording medium (P) except for the recording medium (P) in direct contact with the pickup unit 20 Can be prevented from being transferred. In other words, it is possible to prevent the feeding of the plurality of recording media P at the same time to the transfer unit 40.

As an example of the friction unit 30, a friction pad method may be employed as shown in the figure. The friction pad method can prevent the feeding of the recording medium P in a relatively simple manner. However, the present invention is not limited thereto, and a retard roller method or a semi retard roller method may be used as the friction unit 30.

Meanwhile, in FIG. 1, as the pickup unit 20, a partial roller is in contact with the knock-up plate 12, and the other roller is in a single roller contacted with the friction unit 30, but is not limited thereto. Although not shown in the drawings, the pickup unit 20 includes a plurality of rollers, for example, a pickup roller and a forward roller, the pickup roller contacts the knockup plate 12, and the forward roller is the friction unit 30. You can also contact

The transfer unit 40 transfers the recording medium P picked up by the pickup unit 20 to the image forming unit 70. The transfer unit 40 is disposed downstream of the transfer direction of the recording medium P from the pickup unit 20 and transfers the recording medium P picked up by the pickup unit 20 in the direction of the image forming unit 70. . The conveying unit 40 includes a pair of conveying rollers 50 and 60 facing each other, and the pair of conveying rollers 50 and 60 rotate with each other.

At least one of the pair of feed rollers 50 and 60 is rotated by a driving unit (not shown). For example, the first feed roller 50 may be driven to rotate by receiving a driving force by the driving unit, and the second feed roller 60 may be driven to rotate along the first feed roller 50. The transfer unit 40 may perform a registration function of aligning the recording medium P or a feeding function of supplying the recording medium P.

The image forming unit 70 forms an image on the recording medium P by a transfer photographing method. The image forming unit 70 includes a photosensitive member 71, an exposure unit 72, a developing unit 73, and a transfer unit 76. The developing unit 73 includes a charging roller 74 and a developing roller 75.

The photosensitive member 71 is a photosensitive member in which an electrostatic latent image is formed, and a photosensitive layer having photoconductivity may be formed on the outer circumference of the cylindrical metal pipe.

The charging roller 74 charges the surface of the photosensitive member 71 to a uniform electric potential. A charging bias is applied to the charging roller 74. The charging roller 74 is only one example of a charger, and a corona charger may be used instead of the charging roller 74.

The exposure unit 72 scans the light modulated according to the image information on the surface of the photosensitive member 71 charged at a uniform electric potential to form an electrostatic latent image. As the exposure unit 72, for example, a laser scanning unit (LSU) that scans the photosensitive member 71 by deflecting light irradiated from the laser diode in the main scanning direction using a polygon mirror can be employed.

The developing roller 75 supplies and develops toner on the electrostatic latent image formed on the photosensitive member 71. Through this, a toner image is formed on the surface of the photosensitive member 71.

The transfer unit 76 is positioned to face the surface of the photosensitive member 71. The transfer bias voltage is applied to the transfer unit 76. The toner image developed on the surface of the photosensitive member 71 may be transferred to the recording medium P while the recording medium P passes between the photosensitive member 71 and the transfer unit 76. As an example of the transfer unit 76, a transfer roller may be employed, but is not limited thereto, and a corona transfer machine may be used instead of the transfer roller.

The toner image transferred to the surface of the recording medium P by the transfer unit 76 is held on the surface of the recording medium P by electrostatic attraction. The fixing unit 80 forms a permanent printed image on the recording medium P by applying heat and pressure to the toner image to fix it to the recording medium P. FIG.

The recording medium P passing through the fixing unit 80 is discharged to the outside by the discharge unit 90.

As mentioned above. The recording medium P stored in the recording medium storage unit 10 is transferred to the image forming unit 70 via the pickup unit 20 and the transfer unit 40 and is recorded in the process of passing through the image forming unit 70. A predetermined image is formed on the medium P.

2A to 2C are diagrams schematically illustrating how the recording medium P is picked up by the pickup unit 20 and transferred to the transfer unit 40 in FIG. 1. 2A to 2C, a process in which vibration occurs in the transfer unit 40 during the transfer process of the recording medium P and the transfer process of the recording medium P will be described below.

Referring to FIG. 2A, the pickup unit 20 is driven to rotate and transfers the recording medium P. FIG. The pickup unit 20 is in frictional contact with the recording medium P loaded on the knockup plate 12 to transfer the recording medium P toward the transfer unit 40. When the recording medium P passes between the pickup unit 20 and the friction unit 30, the friction force acts on the rear surface of the recording medium P by the friction unit 30 in the direction opposite to the conveying direction. If there are a plurality of recording media P passing between the pickup unit 20 and the friction unit 30, the recording medium directly contacts the pickup unit 20 by the frictional force acting by the friction unit 30. Except for (P), the rest of the recording medium (P) is limited to transfer.

Referring to FIG. 2B, after the tip P _f of the recording medium P reaches the transfer unit 40, in order to transfer the recording medium P one by one to the image forming unit 70 at predetermined intervals. The driving signal transmitted to the pickup unit 20 is blocked. At this time, in order to smoothly transport the recording medium P, the transport unit 40 is in a state of being driven to rotate before the tip P _f of the recording medium P reaches the transport unit 40. The pickup unit 20 in which the drive signal is blocked is not driven to rotate, but is idle because of a frictional force with the recording medium P carried by the transfer unit 40. Here, whether the tip P _f of the recording medium P has reached the transfer unit 40 can be detected by various methods. For example, a paper detection sensor (not shown) is disposed on the downstream side of the transfer unit 40 to detect whether the tip P _f of the recording medium P has reached the transfer unit 40. Can be.

Meanwhile, while the driving signal transmitted to the pickup unit 20 is transmitted, the transfer speed of the pickup unit 20 may be faster than the transfer speed of the transfer unit 40. In this case, the area of the recording medium P located between the transfer unit 40 and the pickup unit 20 may be stretched like a dotted line. Thereafter, when the driving signal transmitted to the pickup unit 20 is blocked, the pickup unit 20 is temporarily stopped. By the transfer unit 40 having a faster transfer speed than the stationary pickup unit 20, the stretched area of the recording medium P located between the transfer unit 40 and the pickup unit 20 is in a taut state. Since the recording medium P is conveyed by the conveying unit 40 in a taut state, the pickup unit 20 in contact with the recording medium P is idled as shown by the dotted arrow due to the frictional force with the recording medium P. .

2C shows a state where the rear end P _b of the recording medium P is located between the pickup unit 20 and the friction unit 30. Referring to FIG. 2C, when the rear end P _b of the recording medium P conveyed by the conveying unit 40 exits between the pickup unit 20 and the friction unit 30, the recording medium P Since the frictional force acting on the rear end P _b is suddenly released, the recording medium P is caused to bounce in the direction opposite to the frictional force of the pickup unit 20 and the friction unit 30. As a result, an impact is applied to the transfer unit 40 supporting the recording medium P, and as a result, vibration occurs.

FIG. 3 is a diagram illustrating a recording medium P being transferred between the pickup unit 20 and the friction unit 30 of FIG. 2C. Referring to FIG. 3, as the outer circumferential surface of the pickup unit 20 is elastically deformed, a nip is formed between the friction unit 30 and the pickup unit 20.

The rear end P _b of the recording medium P is located in some areas N1 of the nip so that the pick-up unit 20 and the friction unit 30 do not come into direct contact with each other. 20 and the friction unit 30 are in direct contact. As such, due to direct contact with the friction unit 30 in the partial region N2 of the pickup unit 20, the idle unit rotation of the pickup unit 20 is limited as illustrated in FIG. 2B. That is, the pick-up unit 20 may stop instantaneously or slow down in spite of contact with the recording medium P carried by the transfer unit 40. As soon as the recording medium P exits between the pickup unit 20 and the friction unit 30 in this state, the impact acting on the transfer unit 40 appears to be greater, which causes the transfer unit 40 to vibrate more. do.

Meanwhile, in the above-described embodiment, the pickup unit 20 and the friction unit 30 disposed adjacent to the removable tray 11 on the main body 1 have been described as an example, but the causes of vibration are not limited thereto. can do. For example, the transfer unit in the process of exiting the recording medium P between the pickup unit 20A and the friction unit 30A disposed adjacent to the plate 14 of the other recording medium storage unit 10A disclosed in FIG. Vibration may occur at 40. Reference numeral 31A denotes an elastic member for pressing the friction unit 30A, and 21A means a rotation shaft of the pickup unit 20A. In addition, vibration may occur in the transfer unit 40 while the recording medium P exits between the knock-up plate 12 and the pickup unit 20.

4 is an assembled perspective view illustrating a state in which the transfer unit 40 and the exposure unit 72 of the electrophotographic image forming apparatus according to FIG. 1 are mounted on the frames 100 and 200, and FIG. 5 is a plan view of FIG. 4. It is shown. 4 and 5, the support structure of the transfer unit 40 in which vibration has occurred and the relationship between the transfer unit 40 and the exposure unit 72 will be described below. Here, the exposure unit 72 is illustrated as one of the image forming units 70 supported by the same frame 100 as the transfer unit 40, but the present invention is not limited thereto. Of course, it can be applied to at least one of the photosensitive member 71, the developing unit 73 and the transfer unit 76.

4 and 5, a side frame 200 supporting the first feed roller 50 and a base frame 100 supporting the second feed roller 60 and the exposure unit 72 are disclosed. . Side frames 200 are disposed on both sides of the base frame 100.

A plurality of first feed rollers 50 are provided at predetermined intervals on the rotation shaft 51. The first feed roller 50 is supported by the rotation shaft 51, and both ends of the rotation shaft 51 are supported by the side frame 200. At least one of both ends of the rotating shaft 51 is formed with a drive gear 52, the drive gear 52 is connected to the other drive gear 53 installed on the side frame 200, thereby driving force from a drive (not shown) Can be delivered.

A plurality of second feed rollers 60 are provided on the rotating shaft 61 at predetermined intervals. The plurality of second feed rollers 60 corresponds to the plurality of first feed rollers 50. The 1st feed roller 50 and the 2nd feed roller 60 are contacted by the elastic member 62 which presses the rotating shaft 61 of the 2nd feed roller 60. FIG. As an example of the elastic member 62, a spring may be employed. A nip is formed between the first feed roller 50 and the second feed roller 60 which are in pressure contact by the elastic member 62, and the recording medium P is transferred to the image forming unit by the friction force generated between the nips. 70; see FIG. 1).

The second feed roller 60 is supported by the rotation shaft 61, the rotation shaft 61 is supported by the base frame 100. The rotating shaft 61 is pressed in the direction of the first feed roller 50 by the elastic member 62 while the load is supported by the plurality of lower support parts 111 formed on the base frame 100. The elastic member 62 is in contact with the rotating shaft 61 at the other end 62b (see FIG. 8) while one end 62a (see FIG. 8) is fixed to the base frame 100. Both ends of the rotation shaft 61 are inserted into the side support 112 formed in the base frame 100. The position of the rotation shaft 61 is limited by the side support 112.

When the recording medium P exits between the pick-up unit 20 and the friction unit 30, the vibration generated in the first feed roller 50 and the second feed roller 60 is the first feed roller 50. It is transmitted to the side frame 200 for supporting the rotating shaft 51 of, and the base frame 100 for supporting the rotating shaft 61 of the second feed roller 60, respectively.

The impact applied to the first feed roller 50 is transmitted to the side frame 200 along the rotating shaft 51. The vibration transmitted to the side frame 200 may be transmitted to the base frame 100 which is fixedly connected to the side frame 200, but in the process of transmitting the vibration along the side frame 200, a substantial portion of the vibration is lost to the base frame ( It does not substantially affect the exposure unit 72 supported by 100.

The vibration applied to the second feed roller 60 is transmitted to the base frame 100 along the rotation shaft 61. In particular, since the rotating shaft 61 of the second feed roller 60 is supported by the elastic member 62 which provides the elastic force in the direction of the first feed roller 50, the vibration is along the elastic member 62. It is transmitted to the base frame 100.

The exposure unit 72 may be supported on the base frame 100 together with the second feed roller 60. The base frame 100 includes a first support region 110 for supporting the second feed roller 60 and a second support region 120 for supporting the exposure unit 72. In the first support region 110, a lower support portion 111, a side support portion 112, and a support portion 113 for supporting the elastic member 62 may be formed to support the rotating shaft 61 of the second feed roller 60. Can be. A plurality of support parts 121 supporting the exposure unit 72 may be formed in the second support area 120.

As such, when the second feed roller 60 and the exposure unit 72 are supported on the base frame 100, it is necessary to prevent the vibration generated in the second feed roller 60 from being transmitted to the exposure unit 72. There is. Because, when a vibration acting on the second feed roller 60 is transmitted to the exposure unit 72, the exposure unit 72 is shaken, which affects the electrostatic latent image formed on the photosensitive member 71 Because.

In order to prevent the vibration acting on the second feed roller 60 from being transmitted directly to the exposure unit 72 along the base frame 100, between the first support region 110 and the second support region 120. The vibration blocking slit 130 may be formed.

The vibration blocking slit 130 has a function of blocking the vibration transmitted from the second feed roller 60 to the first support region 110 to be directly transmitted to the second support region 120. The vibration blocking slit 130 removes a portion of the base frame 100 located in a path through which vibrations are directly transmitted from the first support region 110 to the second support region 120, whereby the vibration is the second support region. Can be prevented from being delivered directly to 120. Due to the vibration blocking slit 130, in the process of bypassing the vibration blocking slit 130 with the vibration transmitted toward the second support region 120, a substantial portion of the vibration may be eliminated. Through this, it is possible to prevent the image quality degradation due to the vibration of the exposure unit 72.

The vibration blocking slit 130 may be formed in a direction crossing the direction from the first support region 110 to the second support region 120. For example, the first support region 110 may extend in a direction (x-axis direction) perpendicular to the direction (y-axis direction) toward the second support region.

6 is a cross-sectional view taken along the line VI-VI in FIG. 5, and FIG. 7 is a view showing a modified embodiment of FIG. 6. 8 is a cross-sectional view taken along the line VIII-VIII in FIG. 5.

Referring to FIG. 6, the second feed roller 60 is supported in the first support region 110 of the base frame 100, and the exposure unit 72 is supported in the second support region 120.

The base frame 100 may connect the first support region 110 and the second support region 120 without passing through the side frame 200. For example, in the base frame 100, the first support region 110 and the second support region 120 may be integrally formed as shown in the drawing. However, the structure of the base frame 100 is not limited to a structure in which the first support region 110 and the second support region 120 are integrally formed, and the first support region 110 and the second support region ( If the structure 120 is connected may be modified. For example, as shown in FIG. 7, the base frame 100 includes a first subframe 101 including a first support region 110, a second support region 120, and a first subframe 101. Including a second sub-frame 102 separated from the first sub-frame 101 and the second sub-frame 102 may be fixed by a fastening member 103. As an example of the fastening member 103, a bolt may be used, but is not limited thereto.

Referring back to FIG. 6, the first support region 110 includes a lower support portion 111 protruding upward, and the lower support portion 111 supports the load of the rotating shaft 61 of the second feed roller 60. do. The second support region 120 includes a support portion 121 protruding upward, and the support portion 121 supports the exposure unit 72. A vibration blocking slit 130 is formed between the first support region 110 and the second support region 120, and the second support region 120 is formed in the first support region 110 through the vibration blocking slit 130. This prevents vibration from being transmitted directly.

The reinforcing member 150 may be installed in the base frame 100. Through the reinforcing member 150, it is possible to prevent the strength of the base frame 100 due to the formation of the vibration blocking slit 130. However, in order to prevent the vibration blocked by the vibration blocking slit 130 from being transmitted through the reinforcing member 150, the reinforcing member 150 is disposed to be spaced apart from the path through which the vibration is transmitted.

Referring to FIG. 8, the rotation shaft 61 of the second feed roller 60 is pressed in the direction of the first feed roller 50 by the elastic member 62. The elastic member 62 is in the state where one end 62a is supported by the support part 113 of the base frame 100, and the other end 62b contacts the rotating shaft 61 of the second feed roller 60, The rotary shaft 61 of the second feed roller 60 is pressed. Since the second feed roller 60 is pressed in the direction of the first feed roller 50 by the elastic force of the elastic member 62, at least one of the second feed roller 60 and the first feed roller 50. When the vibration occurs, the impact is transmitted to the base frame 100 through the elastic member 62.

Meanwhile, in the process of transmitting the vibration to the base frame 100 through the elastic member 62, a part of the vibration may be absorbed by the elastic member 62. However, since the elastic member 62 is in a state of strongly pressing the rotation shaft 61 of the second feed roller 60, the vibration absorbed by the elastic member 62 itself is only a part, and most vibrations It is transmitted to the support part 113 of the base frame 100. The vibration transmitted to the support part 113 may be transmitted in the arrow direction A along the base frame 100, but the vibration transmitted in the arrow direction A along the base frame 100 may have a predetermined width w. It is blocked by the vibration blocking slit 130 having.

FIG. 9 is a view for explaining a process in which vibration transmission is blocked in the base frame 100, and a portion of the base frame 100 is schematically illustrated in FIG. 5. 9, the vibration generated in the second feed roller 60 is transmitted to the elastic member 62, and the vibration transmitted to the elastic member 62 is arrowed along the base frame 100 via the support 113. Conveyed in direction A; The vibration transmitted in the arrow direction A is directly blocked by the vibration blocking slit 130 to the second support region 120. Vibration generated in the first support region 110 may disappear in the process of bypassing the vibration blocking slit 130, thereby substantially affecting the exposure unit 72 supported by the second support region 120. Will not reach.

In addition, the vibration generated in the second feed roller 60 may be transmitted from the plurality of lower support parts 111 without passing through the elastic member 62. Vibration transmitted to the lower support 111 is also directly blocked by the vibration blocking slit 130 to the second support region 120. Therefore, the vibration generated in the first support region 110 does not substantially affect the exposure unit 72 supported by the second support region 120.

If the vibration blocking slit 130 is not formed in the base frame 100, vibration may be directly transmitted from the first support region 110 to the second support region 120 along the base frame 100. Therefore, vibration may be transmitted to the exposure unit 72 supported by the second support region 120.

However, in the present embodiment, since the transmission of the shock can be interrupted through the vibration blocking slit 130 formed between the first support region 110 and the second support region 120, the vibration of the exposure unit 72. Can be minimized.

The vibration blocking slit 130 may extend in a direction crossing the direction from the first support region 110 to the second support region 120. The vibration blocking slit 130 may have a rectangular shape as shown in the drawing. However, the shape of the vibration blocking slit 130 is not limited thereto, and the shape of the vibration blocking slit 130A and 130B may be modified as shown in FIGS. 12A and 12B.

Referring back to FIG. 9, the length L _H of the vibration blocking slit 130 may be 80% to 150% of the axial length L _S of the rotation shaft 61 of the second feed roller 60. For example, when the axial length L _S of the rotating shaft 61 of the second feed roller 60 is about 300 mm, the length L _H of the vibration blocking slit 130 is about 240 mm to about 450 mm. Can be. When the length L _H of the vibration blocking slit 130 is less than 80% of the axial length L _S of the rotation shaft 61 of the second feed roller 60, the vibration is transmitted to the exposure unit 72. It cannot be difficult to block. Specifically, the vibration generated in the second feed roller 60 may be transmitted through the plurality of lower support parts 111 supporting the lower portion of the second feed roller 60 in addition to the elastic member 62 described above. When the length L _H of the vibration blocking slit 130 is less than 80% of the axial length L _S of the rotation shaft 61 of the second feed roller 60, the vibration transmitted through the lower support 111 is Since it may be transmitted to the second support region 120 without being blocked, the vibration transmitted to the exposure unit 72 may not be blocked effectively. On the other hand, when the length L _H of the vibration blocking slit 130 is greater than 150% of the axial length L _S of the rotation shaft 61 of the second feed roller 60, the vibration transmission is blocked. It may be advantageous, but this increases the size of the base frame 100, which may lead to an increase in the size of the image forming apparatus itself.

The width w of the vibration blocking slit 130 may be about 0.3 mm to 200 mm. When the width w of the vibration blocking slit 130 is less than 0.3 mm, the formation of the vibration blocking slit 130 may be difficult. On the other hand, when the width w of the vibration blocking slit 130 is greater than 200 mm, the length of the optical path between the exposure unit 72 and the photosensitive member 71 may be increased.

The distance D between the vibration blocking slit 130 and the rotating shaft 61 of the second feed roller 60 is 1.5% to the axial length L _S of the rotating shaft 61 of the second feed roller 60. 30% apart. For example, when the axial length L _S of the rotating shaft 61 of the second feed roller 60 is about 300 mm, the vibration blocking slit 130 and the rotating shaft 61 of the second feed roller 60 are rotated. The separation distance (D) may be about 5mm to about 90mm. The separation distance D between the vibration blocking slit 130 and the rotating shaft 61 of the second feed roller 60 is less than 1.5% of the axial length L _S of the rotating shaft 61 of the second feed roller 60. In this case, it may be difficult to stably support the rotating shaft 61 of the second feed roller 60 because the space for the first support region 110 is narrowed. On the other hand, the separation distance D between the vibration blocking slit 130 and the rotating shaft 61 of the second feed roller 60 is 30 of the axial length L _S of the rotating shaft 61 of the second feed roller 60. When exceeding the%, it is difficult to block the vibration to be transmitted to the second support region 120 early.

Meanwhile, in FIG. 9, the rotation shaft 61 of the second feed roller 60 is illustrated as a single member, but is not limited thereto. For example, the rotation shaft 61 of the second feed roller 60 may include a plurality of members spaced apart in the axial direction. In this case, the axial direction length L _S of the rotating shaft 61 of the 2nd feed roller 60 means the total length which a some member occupies in an axial direction.

10A to 10B illustrate acceleration values during printing while the second feed roller 60 and the exposure unit 72 are supported by a base frame (comparative example) in which the vibration blocking slit 130 is not formed. 11a to 11b show that the printing is performed while the second feed roller 60 and the exposure unit 72 are supported by a base frame (example) in which the vibration blocking slit 130 is formed. While the acceleration value is measured.

In the base frame 100 according to the embodiment, the distance D from the rotational axis 61 of the second feed roller 60 is 31 mm, the length L _H is about 310 mm, and the width w is about 5 mm. The vibration blocking slit 130 is formed, and the vibration blocking slit 130 is not formed in the base frame according to the comparative example. The other units of the image forming apparatus were experimented with the same configuration as that shown in FIG. Acceleration measurements were taken for about 8 seconds.

10A and 11A measure acceleration values at the rotational axis 61 of the pickup unit 20, and start to change the acceleration values of the pickup unit 20 while printing is in progress. Referring to FIG. 10A, an acceleration value having a predetermined magnitude begins to be measured about 1 second when the image forming apparatus is powered on. Thereafter, a first peak P1 _S in which the acceleration value suddenly increases in the vicinity of about 3 seconds, which is a moment when a driving signal is transmitted to the pickup unit 20, is generated. Thereafter, the acceleration value decreases, and a second peak P2 _S suddenly increases around 4 seconds, which is the moment when the driving signal transmitted to the pickup unit 20 is blocked. Then, the acceleration value decreases again, and at about 5.3 seconds, the moment when the rear end P _b of the recording medium P exits between the pickup unit 20 and the friction unit 30, the acceleration value suddenly increases. 3 peaks (P3 _S ) appear. In FIG. 11A, although the acceleration value is slightly different, the similar pattern showing the first peak P1 _S , the second peak P2 _S and the third peak P3 _S is shown.

10B and 11B illustrate acceleration values measured in the second support area 120 in which the exposure unit 72 is supported, and shows the acceleration of the second support area 120 supporting the exposure unit 72 during printing. Initiate a change in the acceleration value.

Referring to FIG. 10B, as shown in FIG. 10A, a predetermined acceleration value starts to be measured about 1 second after the power is supplied to the image forming apparatus. Thereafter, a first peak P1 _L in which the acceleration value suddenly increases in the vicinity of about 4 seconds, which is the moment when the driving signal transmitted to the pickup unit 20 is blocked. Thereafter, the acceleration value decreases, and the second peak at which the acceleration value suddenly increases is about 5.3 seconds, which is the moment when the rear end P _b of the recording medium P exits between the pickup unit 20 and the friction unit 30. (P2 _L ) is displayed. When the first peak (P1 _L ), the acceleration value was about 4 m / s ² , and when the second peak (P2 _L ), the acceleration value was about 7 m / s ²

In contrast, referring to FIG. 11B, the acceleration value change of the second support region 120 of the base frame 100 on which the vibration blocking slit 130 is formed is completely different from the graph of FIG. 10B. Specifically, the acceleration value of a predetermined size starts to be measured after the power is turned on to the image forming apparatus, but most of the acceleration values are less than 2 m / s ² , and the acceleration values are up to about 2.36 m / s ² . It was only. In the second support region 120 of the base frame 100 in which the vibration blocking slit 130 is formed, the rear end of the recording medium P as well as about 4 seconds, which is the moment when the driving signal is blocked by the pickup unit 20 ( The acceleration value was maintained below 2.5 m / s ² even at about 5.3 seconds, which is the moment when P _b ) exits between the pickup unit 20 and the friction unit 30. That is, the first and second peaks P1 _L and P2 _L of FIG. 10B do not appear. This means that when the magnitude of the acceleration value is proportional to the force, the sudden vibration does not act on the second support region 120. Therefore, it can be seen that the vibration blocking slit 130 formed in the base frame 100 can effectively block the transmission of vibration to the second support region 120.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is merely exemplary, and those skilled in the art to which the art belongs can make various modifications and other equivalent embodiments therefrom. Will understand. Therefore, the true technical protection scope of the present invention will be defined by the claims below.

1: main body 10, 10A: recording medium storage unit
11: tray 12: knock-up plate
13: elastic member 14: plate
20, 20A: Pickup unit 21, 21A: Rotating shaft
30, 30A: friction unit 31, 31A: elastic member
40: transfer unit 50: first feed roller
51: rotating shaft 52: drive gear
53: other drive gear 60: second feed roller
61: rotating shaft 62: elastic member
70: image forming unit 71: photosensitive member
72: exposure unit 73: developing unit
74: charging roller 75: developing roller
76: transfer unit 80: fixing unit
90: discharge unit 100: base frame
110: first support region 111: lower support portion
112: side support portion 113: support portion
120: second support region 121: support
130: vibration blocking slit 150: reinforcing member
200: side frame P: recording medium

Claims (12)

A recording medium storage unit in which a recording medium is stored;
A pickup unit for picking up the recording medium stored in the recording medium storage unit;
Rotating with each other, and conveying the recording medium picked up by the pickup unit, comprising a first conveying roller which is driven to rotate to convey the recording medium and a second conveying roller driven along the first conveying roller A pair of feed rollers;
Forming an image on the recording medium conveyed by the pair of feed rollers, a photosensitive member, an exposure unit for scanning light to form an electrostatic latent image on the photosensitive member, and a toner on the photosensitive member on which the electrostatic latent image is formed. An image forming unit including a developing unit for supplying a toner image to the photosensitive member, and a transfer unit for transferring the toner image to a recording medium;
A side frame supporting the first conveying roller;
And a base frame including a first support region supporting the second transfer roller and a second support region supporting the exposure unit.
The base frame has an electrophotographic image having a vibration blocking slit formed between the first support region and the second support region to block transmission of vibrations from the first support region to the second support region. Forming device. The method of claim 1,
At least a portion of the vibration blocking slit,
And an electrophotographic image forming apparatus extending in a direction crossing the direction from the first support region to the second support region. The method of claim 1,
The length of the vibration blocking slit is,
An electrophotographic image forming apparatus of 80% to 150% of an axial length of a rotation axis of the second feed roller. The method of claim 1,
The separation distance between the vibration blocking slit and the rotation axis of the second feed roller,
An electrophotographic image forming apparatus of 1.5% to 30% of the axial length of the rotation axis of the second feed roller. delete delete The method of claim 1,
And a friction unit disposed to face the pickup unit and providing a frictional force to a recording medium conveyed between the pickup unit and a direction opposite to the transfer direction. The method of claim 7, wherein
The pair of feed rollers,
And an electrophotographic image forming apparatus which supports the recording medium when the rear end of the recording medium exits between the pickup unit and the friction unit. The method of claim 1,
The base frame,
And an electrophotographic image forming apparatus in which the first support region and the second support region are integrally formed. The method of claim 1,
The base frame,
A first subframe including the first support region and a second subframe including a second support region and separated from the first subframe,
And the first sub frame and the second sub frame are fixed by a fastening member. delete delete

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