JP3255742B2 - Recording sheet setting device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an image forming apparatus having a paper feeding means for feeding a plurality of types of recording sheets to the image forming apparatus main body, and more particularly, to an image forming apparatus having a plurality of sheet storage stages. The present invention relates to a recording sheet setting apparatus provided with a sheet feeding means capable of replenishing a sheet from a single location in a sheet storage means.

[0002]

2. Description of the Related Art Conventionally, a so-called front-loading type copying machine capable of replenishing paper from the front of an operator has been proposed in order to save space in an office. In this type of copier, there are multiple paper feed stages, so if paper needs to be replenished at the bottom, the lower leg must be bent significantly to improve operability. There is room for In recent years, Westerners who work in Japan are increasing due to internationalization of business. In general, Westerners do not have the habit of sitting on tatami mats, and tend to be very reluctant to take a posture in which their knees are significantly bent when replenishing paper, as this is a difficult posture. This is of course also true when used in Western countries.

[0003] The sheet storage units currently used in the market, such as a sheet cassette and a sheet tray, are provided in a plurality of different types. The size is divided into two types that can be accommodated as needed. Among them, the type that can appropriately accommodate a plurality of different sizes is provided with a side fence and an end fence, in other words, a positioning member in a recording sheet width direction and a positioning member in a feeding direction are provided in a sheet storage portion. The operator manually adjusted the fence to the seat size.

As described above, various types of paper feeders have been proposed and used in the past. In particular, for replenishment of recording sheets, general paper forming apparatuses such as copying apparatuses, facsimile machines, printers, and printing apparatuses are generally used. The operability of the recording sheet replenishing position with respect to the sheet feeding means has been a problem. That is, generally, the conventional paper feeding means,
In other words, the paper feeder is often provided in the lower part of the image forming apparatus main body in the system, and in the case where recording sheets of different sizes are stored in the sheet storage stages provided in multiple stages, At the time of replenishment, the lower the sheet storage stage is, the more the user has to bend down as described above when replenishing the recording sheet, and is forced to take a very difficult posture. As a technique for avoiding this, for example, a technique disclosed in Japanese Patent Application Laid-Open No. 64-29873 is known.

[0005] This prior art relates to a large-capacity sheet feeding device for storing a large amount of recording sheets of a single size and supplying the recording sheets to an image forming apparatus main body, and has a plurality of storage chambers for storing recording sheets. The structure is such that the operator can supply recording sheets to the uppermost storage room. In this structure, a recording sheet is placed between each recording sheet storage chamber,
Two movable guides that can swing in the left and right direction are provided, and the movable guide is appropriately swung according to the remaining amount of recording sheets in the lowermost storage room and the other storage room in which the paper feeding unit is provided, The recording sheet is sequentially dropped by its own weight from the upper storage room to the lower storage room, and the recording sheet is fed from the lowermost storage room to an image forming apparatus, in this case, a facsimile.

[0006]

However, in the above-mentioned prior art, the recording sheet is dropped by its own weight between a plurality of partitioned sheet storage sections, and the recording sheet is moved down to the lowermost sheet storage section in which only a sheet feeding section is provided. Since the recording sheet can be sequentially moved and the recording sheet replenishment position can be set at a relatively high position, the operability associated with the sheet replenishment is improved. However, in this method, the impact force generated by the collision of the recording sheet with the lower sheet storage unit when the recording sheet falls by its own weight, the wind pressure on the recording sheet when the recording sheet falls, and the swing of the movable guide on which the recording sheet is placed Due to external force such as frictional force between the recording sheet and the movable guide during movement, the recording sheet falls into an irregular state after falling. For this reason, the irregular state may cause a failure to drop its own weight to the next sheet storage unit and a paper feeding failure such as a jam or a skew during the paper feeding operation.

The movement of the recording sheet in this prior art is caused by the swing of the movable guide, and the swing of the movable guide is in the width direction of the recording sheet (the direction perpendicular to the sheet feeding direction). Therefore, a swing space for the movable guide is specially required. The movable guide swings in the width direction of the recording sheet due to the two-part structure, and this special swing space needs to be at least about half the width of the stored recording sheet, including at least both sides of the sheet storage unit. The entire device was about twice as large.

Further, since the movable guide is divided into two parts, a certain amount of space is generated at the center of the recording sheet mounting surface. As a result, the central portion of the recording sheet where the load is concentrated most is in a depressed state, and the recording sheet is displaced even in the loaded state, leading to irregular paper sheets.

The above-mentioned prior art is intended for a large-capacity sheet feeding device that stores a large amount of recording sheets of a single size and supplies it to the image forming apparatus main body. Could not adapt.

In the case where the operator manually adjusts the sheet size by operating the fence, if the size of the sheets to be accommodated is different, the fence already installed at a predetermined position in the sheet accommodating portion is moved to the sheet size. They have to be adjusted accordingly. Therefore, the operator has to perform two operations of adjusting the fence and replenishing the sheet, which is troublesome and troublesome, and naturally results in a reduction in productivity.

[0011] The present invention has such has been made in view of the actual situation of the prior art, purpose of that is, an image forming apparatus without the sheet feeding failure may occur with paper replenishment can be easily and accurately To provide .

[0012]

In order to achieve the above-mentioned object, a first means comprises a plurality of recording sheet storage stages arranged in a vertical direction, the recording sheet storage stage being movable in a direction substantially perpendicular to a recording sheet feeding direction. A side fence provided at the uppermost recording sheet storage stage, a side fence driving means capable of moving the side fence and locking at an arbitrary position, and a recording sheet for only the uppermost recording sheet storage stage. Sheet replenishing means capable of replenishing, paper end detecting means for detecting a recording sheet storage stage in a paper out state, and when the paper out state is detected by the paper end detecting means, the paper out state is determined. The size detecting means for detecting the size of the recording sheet accommodated in the detected recording sheet accommodation stage, and the fence driving means are controlled and detected by the size detecting means. It has a configuration that includes a side fence drive control means for moving the side fences were in accordance with the size of the recording sheet.

The second means is provided in a plurality of recording sheet storage stages arranged in a vertical direction and an uppermost recording sheet storage stage movable in a direction substantially orthogonal to the recording sheet feeding direction. A side fence, a side fence driving unit that moves the side fence and can be locked at an arbitrary position, a fence driving control unit that controls the fence driving unit and moves the fence, and a topmost recording sheet storage unit. a sheet supply means capable of replenishing the recording sheet only to stage, and replenishing operation detecting means for detecting an operating state of the seat replenishing means, the detection result of the replenishment operation detecting means, wherein at the time of replenishing side fences Lock state discrimination that outputs a signal to the side fence drive control means to release the lock state of the above and to maintain the lock state when not replenished It has a configuration that includes a stage.

[0014]

[0015]

According to the first means, when the paper end detecting means detects the recording sheet storage stage in which the paper is empty, the size detecting means detects the size of the recording sheet in the paper empty state, The fence drive control means controls the side fence drive means to move the position of the side fence to a position corresponding to the size in the width direction of the recording sheet, and keep the position. Thus, when replenishing recording sheets, the recording sheet storage stage is set to the size of the recording sheet to be replenished.

In the second means, the position of the side fence is held (locked) at the sheet size to be replenished by the first means. When the sheet is supplied, the lock state determining means releases the locked state of the side fence. Set so that seat replenishment is easy. The width direction refers to a direction substantially perpendicular to the sheet feeding direction.

[0017]

[0018]

Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 is an internal configuration diagram showing an entire image forming apparatus according to an embodiment of the present invention. First, an overall system of an image forming apparatus according to the embodiment will be described with reference to FIG.

In FIG. 1, this system comprises a sheet feeding device 1 and an image forming device 2, wherein the sheet feeding device 1 is arranged in substantially the lower half of the entire device, and the image forming device 2 is arranged in the upper portion thereof. I have. An automatic document feeder 3 is provided further above the image forming apparatus 2. A contact glass 4 is provided at an upper end portion of the image forming apparatus which is a lower surface of the automatic document feeder 3, and a document set on the automatic document feeder 3 is automatically placed on the contact glass 4 when a copy signal is input. Will be fed.

The document fed onto the contact glass 4 is read by an image reading section 5 provided in the image forming apparatus 2 and converted into a digital signal. The image writing unit 6 irradiates the photoconductor 7 with a laser beam based on the digital signal. The photoreceptor 7 rotates clockwise when a copy signal is input, is charged to a uniform potential by a charging charger 8, and the image information is turned into a latent image by irradiation of the laser light in the image writing unit 6, and the developing device 9 is visualized. Next, the image visualized by the toner is transferred to the transfer charge 10.
Is transferred onto the sheet 99. On the other hand, the toner remaining on the photoconductor 7 is cleaned by the cleaning device 11,
The charge is uniformly removed by the charge removing lamp 12 on the surface of the photoconductor 7. In each of these steps, one cycle of image formation is formed.

The sheet 99 is fed from the sheet feeding device 1 to the registration rollers 20 and is fed to the transfer unit at a predetermined timing. Alternatively, the sheet 99 can be fed from a so-called manual feed tray 19. After the transfer, the sheet 99 is fixed by the fixing device 14 via the transport device 13, and
It is discharged to 5. These image forming processes are well-known electrophotographic processes.

A sheet storage section 270 having nine storage steps is provided inside the sheet feeding apparatus 1, and only the uppermost sheet storage section 270 can be pulled out toward the front side of the apparatus. Two
The ninth-stage sheet storage units 270b to 270i have exactly the same configuration, and perform the function of a commonly used paper feed cassette. In the following, the one corresponding to the uppermost row is denoted by the subscript a.
, The subscript corresponding to the second row is given a subscript b, and the one corresponding to the ninth row is appended with an alphabet such as a subscript i to clearly show the specific number of steps. Also, the sheet storage unit 2
Reference numeral 70 is integrally covered with a front cover, and is not structured to be detachable from the sheet feeding device 1. Each of the sheet storage sections 270 a to 270 i includes a sheet stacking tray 246 and an end fence 350.

As described above, since the paper feed cassette is not used and the cassette is not required to be attached / detached because the paper feed cassette is not used, the number of paper feed stages more than double that of the paper feed cassette type in the space of the normal paper feeder is required. Can be secured. In the embodiment, about 250 sheets are assumed per one step,
There is no particular limitation. Further, since it is possible to handle up to eight types of sheet sizes, the user hardly feels annoyance that there is no desired size. However, the size used usually is often limited, and a frequently used size may be set in a plurality of stages.

The first-stage sheet stacking tray 246 is a sheet replenishment tray when a sheet end occurs in the sheet storage section 270, and normally no sheets are set. The sheet supply tray 246 is at an intermediate height of the entire machine, and all sheet supply is set here so that the user can work without bending down.

On the right side of the sheet storage section 270, only one sheet feeding unit 406 is provided, which moves up and down to the first to ninth steps to feed the sheets of each tray. Usually, since each tray has a paper feed mechanism, the greater the number of trays, the more the cost and space are required. This has been greatly improved. On the right side of the sheet feeding unit 406, a conveyor belt 419 is stretched from the bottom to the top of the sheet feeding device 1 over the entire area in the vertical direction so as to correspond to the sheets fed from the first to ninth trays. The transport belt 419 is charged by the charging charger 420 inside the transport belt 419, electrostatically attracts the sheet 99 fed by the sheet feeding unit 406, and transports the sheet upward by its own rotation. And a transport guide plate 55 provided at an intermediate portion of the sheet feeding device 1
In the section, separate the sheets. The separated sheet 99 is guided by a pair of transport guide plates 55 and is
6, the sheet is fed to the registration rollers 20.

Below the conveyor belt 419 is a drive roller 41.
7 and the upper part is supported by a discharging roller 418. Since the sheet 99 is electrostatically attracted to the conveyor belt 419, the charge is grounded by the charge eliminating roller 418 to facilitate separation. In addition, the static elimination roller 4
Instead of 18, a charge removing charger may be separately provided.

In order to cope with a sheet jam and maintenance, the sheet feeding unit 406 and the conveyor belt 419 can be opened and closed rightward from the sheet feeding device 1 with the fulcrum as a fulcrum. When the sheet feeding unit opening / closing unit 17 is opened to the right, the sheet storage unit 270 is moved from the right side to the sheet feeding unit 4.
Since 06 is open from the left side, hands can be put in and out, and jam processing and the like can be performed.

When a sheet end occurs, the sheet 99 moves between the respective trays by being held by the sheet feeding unit 406 (described later).
Is provided with a retracting mechanism on the left side so as not to hinder the movement of the sheet. This sheet stacking tray 24
Reference numeral 6 denotes a sheet that can be bent in the sheet feeding direction. When the sheet stacking tray 246 is retracted, the sheet stacking tray 246 is gradually stored in the tray storage unit 60 from the left end.

The tray accommodating section 60 is provided at the left end of the sheet feeding device 1 and has a vertically long space capable of accommodating one sheet stacking tray 246. That is, the plurality of sheet stacking trays 246 are not simultaneously stored in the tray storing unit 60. As described above, the opening and closing movement of the sheet stacking tray 246 can be performed in a space-saving manner, which contributes to downsizing of the apparatus and multi-stage trays.

Here, an outline of a configuration for moving sheets between trays will be described. Sheet moving means for moving a sheet bundle placed on one tray to another tray is constituted by sheet feeding means, that is, a sheet feeding unit 406. The paper feeding unit 406 is provided with a pressure holding plate 468 and a call roller 436, and the sheet holding unit 270 (any of a to i) to be moved is opposed to the sheet storage unit 270 in a state where the pressure holding plate 468 is lowered. Then, the sheet bundle is pushed out by the end fence 350 until the front end thereof abuts on the pressure holding plate 468, and then the pressure holding plate 468 is raised, whereby the sheet bundle can be held between the call holding roller 436 and the predetermined pressure. In this state, the sheet storage unit 2
The sheet stacking tray 246 of 70 (a to i) is retracted toward the tray housing section 60, and the sheet feeding unit 406 is lowered to a position facing the immediately lower storage stage. The sheet stacking tray 246 in the storage stage is advanced to the sheet feeding unit 406 side, the sheet bundle is placed on the sheet stacking tray 246, and the clamping force between the pressure holding plate 468 and the call roller 436 is released.
Then, the sheet stacking tray 246 is retracted to the sheet feeding position. By repeating this, even if the bottom of the sheet storage portion 270i has been emptied, only to replenish the sheet at the top of the sheet storage portion 270a, replenishment of the sheet is performed in the empty sheet storage portion 270 i And each sea on it
The sheet bundle also moves from the top to the storage units 270a to 270h in order.
Then, all sheets are stored in the sheet storage units 270a to 270i.
Will be.

Further, with the above-described configuration, the device is devised so as to minimize the installation space as a whole. In other words, the paper discharge unit 15 on the left side of the apparatus has almost no protrusion from the image forming apparatus 2, and the paper supply apparatus 1 also has the left cover 21.
It is completely covered with no space on the left. Further, on the right side of the apparatus, there is only required a space to be opened and closed to some extent at the time of jam clearance or the like. The user can perform all operations including sheet setting on the front side of the device,
There is a merit that the installation place is not much restricted. Also,
Since the image forming apparatus 2 is assumed to have a digital optical system, if the image forming apparatus 2 is provided with a function such as vertical / horizontal conversion of the image, the setting direction of the transfer sheet can be unified, for example, horizontally.
In the present embodiment, the sheet size is unified to a vertical size of B4 or more and a horizontal size of A4 or less to prevent the number of sheet sizes set on the tray from increasing too much. However, the present invention is not limited to this.

Next, the configuration relating to the sheet tray will be described.

The first storage section 270a of a plurality of trays in the sheet feeding device 1 provided below the image forming apparatus 2 includes:
Drawer tray 100 that can be pulled out from the main body in a drawer shape
It is integrated with.

An outline of the drawer tray 100 is shown in a perspective view of a main part in FIG.

The drawer tray 100 feeds a sheet to a structure composed of a pair of support members 271 parallel to the sheet feeding direction and two support members in each direction of support members 273 and 274 in the width direction of the sheet. Stacking tray 246 which can be freely moved in a direction parallel to the direction, and its driving means 24
2 (FIG. 32) are provided. Also, the support member 271
Also serves as the front cover. Inside the support member 271, a sheet end surface reference wall 261a serving as a reference when setting a sheet in parallel with the support member 271 is provided.

Each of the supporting members 271 has a tray guide 20 which is a channel-shaped guide rail for smoothly moving the sheet stacking tray 246a when the sheet stacking tray 246a moves.
9, 210 (FIG. 34). Among them, the tray guide 209 is a front lateral guide, and the tray guide 210 is a rear lateral guide.

The support member 274 is connected to the drawer tray 100.
In order to keep the sheet bundle 94 set on the paper feed unit 406 side in an open state, the mounting position is set so as not to hinder the movement of the paper feed unit 406 in FIG. As shown in FIG.
6, the support member 274 and the sheet feeding unit 406 are positioned outside the range of the movement space of the sheet feeding unit 406 even when the sheet feeding unit 406 comes to the sheet feeding position of the uppermost sheet storage unit 270a.
Are arranged at the height of the positional relationship where they do not touch. By disposing the support member 274 at such a position, when the drawer tray 100 is pulled out, the drawer tray 10
The upper surface of the sheet bundle 94 is fully open, and as shown in the plan view of FIG. 4, there is a space in front and rear with respect to the sheet feeding direction of the sheet bundle 94 to be set.
Can be set with both hands without difficulty.

The drawer tray 1 of the support member 274
00, a side fence 30 as shown in FIG.
A guide groove 276 for zero movement is provided. FIG. 5 shows the support member 274 viewed from the inside of the drawer tray 100.

The support member 273 is connected to the drawer tray 100.
As shown in FIG. 6 viewed from the inside of the
A groove 277 that is larger than the cross section of the penetrated sheet stacking tray 246 by one turn so that the sheet stacking tray 246 can pass when moving is provided, and a guide groove 275 that guides the movement of the side fence 300 is provided. The guide groove 275 is provided inside the drawer tray 100.

Pull-out rails 278 and 279 for pulling out the drawer tray 100 from the main body are provided on the upper side of the support members 273 and 274 outside the drawer tray 100 (FIG. 2), and these are provided on the main body side. It is fitted to a drawer rail guide (not shown) so that it can be freely inserted and removed from the paper feeder 1 when the drawer is open.

Next, the operation of the drawer tray 100 configured as described above will be described.

A filler 282 is provided at a lower portion of the support member 273 outside the drawer tray 100 as shown in a plan view of a main part of FIG. Open / close detection of the drawer tray 100 is performed. If the filler 282 has cut the sensor 631, the drawer tray 100
Is closed and not turned off, the control unit 600 (FIG. 100 described later) determines that it is open.

The main body control unit 600 includes a LOCK condition for the drawer tray 100 and a LOC
When the K release condition is set in advance and the LOCK condition is satisfied, as can be seen from the perspective view showing the entire image forming apparatus in FIG. 41, the OPEN / COSE provided beside the drawer tray of the main body. Key 283
Is pressed, the LOCK mechanism of the drawer tray 100 is not released and the drawer tray 100 cannot be pulled out.
If the condition is satisfied, press key 2
When the user presses 83, the LOCK mechanism is released, and the drawer tray 100 can be pulled out.

The lock mechanism of the drawer tray 100 is as follows.
As shown in the schematic configuration diagram of FIG. 7, the tip of the lock pawl 285 engages with a lock groove 284 provided on the upper portion of the support member 271 to perform locking. The lock is released by turning on a solenoid (not shown) connected to the end of the pawl 285 on the side remote from the lock groove 284, thereby removing the tip of the pawl 285 from the lock groove 284.

The above-described sheet stacking tray 246 has a tray shape movable in the sheet feeding direction, and has a so-called bellows shape in which irregularities are repeated in a direction parallel to the sheet feeding direction. , FIGS. 10, 11 and 12
As shown in the front view of the main part of FIG. 3, the sheet can be bent in the sheet feeding direction but not bent in the sheet width direction. At that time, if the groove width x ₁ is as shown in partial front view of FIG. 8 with a certain size, but to bend upward (opening side of the groove) as shown in Figure 10, as shown in FIG. 9 When close to zero as possible the x _2, so that no bending is almost the upper as shown in Figure 11. However, as shown in FIG. 12, it is bent downward (projecting side of the groove).

FIG. 13 is a top view of the sheet stacking tray 246. In the figure, the pitch of the unevenness formed on the upper surface of the tray is changed between the portion where the sheet is placed and the portion where the driving means engages. FIG. 14 is a cross-sectional view taken along the line AA of FIG. 13, showing a cross section of a portion where a sheet is placed, and FIG. 19 is a detailed view of the portion. FIG. 15 corresponds to FIG.
21 is a cross-sectional view taken along the line BB of FIG. 20, showing a cross section of a portion where the driving means meshes, and FIG. 20 is a detailed view of the portion. Also,
As shown in FIG. 18, which is a side view of the sheet stacking tray 246, the portion where the driving means meshes is one step lower than the portion where the sheets are placed, so that the sheets can be easily set. Further, FIG. 16 shows C-
FIG. 17 is a cross-sectional view taken along the line C, and FIG. 17 shows a part of each of the cross-sectional views taken along the line DD in FIG.

The sheet stacking tray 246 is formed, for example, by pressing a sheet metal to have the above-described structure. As shown in FIG. 13, a rectangular notch 255 is provided at the leading end of the sheet stacking tray 246 on the sheet feeding unit side, and serves as a holding area at the leading edge of the sheet bundle 94 when the sheet is moved. A pressure driven lever 461 attached to the paper unit 406 and a pressure holding plate 468
Can directly enter the lower side of the sheet bundle 94. Further, when the sheet feeding unit 406 moves for sheet movement and there is no sheet on the sheet stacking tray 246 stopped at the sheet feeding position 253, the tray 246 does not have to retreat to the standby position 252. , Notch 255
Through the pressure driven lever 461 of the paper feeding unit 406.

The area around the notch 255 is the tray 246.
In comparison with other parts, the strength of the member itself is increased.
That is, as can be seen from FIG. 14, the periphery of the portion is made shallower than the other portions, so that the strength is higher than that of a simple flat plate by adopting such a configuration. Will be able to With such a configuration, the sheet feeding position 253 where the tray 246 becomes cantilevered
Also, even when a large number of sheets are placed on the tray 246 while in the standby position 252, the tip of the tray 246 is prevented from bending, and the movement of the tray 246 and the sheet feeding operation are stabilized. To be done.

FIG. 26 is a sectional view of the sheet feeding device 1 as viewed from the sheet feeding unit 406 side. FIG. 27 is a detailed view of one of the plurality of trays on the front side of the main body, and FIG. 28 is a back side thereof. As shown in each of the drawings, the sheet stacking tray 246 has a protrusion 26
7 are provided, and the protrusions 2 are provided on drop-off preventing portions 268 and 269 provided on the tray guides 209 and 210, respectively.
67 is fitted to prevent the tray 246 from falling off when a large force acts on the tray 246.

As shown in FIGS. 21 and 22, the surface of the sheet stacking tray 246 on the sheet mounting side has an elasticity having a low friction coefficient of μ = 1 or less so as not to hinder the sheet feeding operation and the sheet moving operation. A seat 250 is provided. By providing such sheets, it is possible to eliminate irregularities on the surface of the sheet stacking tray 246 on which the sheets are placed. That is, the side fence 33 for aligning the sheets
0 or the sheet stacking tray 246 of the end fence 350
It is not necessary to make the shape of the surface in contact with the sheet into a shape corresponding to the unevenness of the sheet stacking tray 246. The elastic sheet 250 is fixed by stopping the upstream side and the downstream side in the sheet feeding direction with rivets 251 as shown in FIGS. FIG. 23 is a top view showing a state where the elastic sheet 250 is attached to the sheet stacking tray 246. When providing the elastic sheet 250,
As shown in FIG.
As shown in FIG. 5, when the sheet stacking tray 246 moves and the rear end is bent, the sheet stacking tray 246 just sticks.

The sheet stacking trays 246 having a plurality of levels in the sheet feeding device 1 have the same configuration as that described above, and the sheet storage sections 270 provided with the plurality of levels are provided.
Has the same configuration as the inside of the drawer tray 100 that can be pulled out. Further, the sheet stacking trays 246 of each stage are all provided with a pair of tray guides 209 and 210 provided on covers on the front side and the back side of the main body of the sheet feeding apparatus 1.
And is movable in a direction parallel to the sheet feeding direction.

As a configuration of the sheet stacking tray 246 other than the above-described embodiment, the sheet mounting portion of the sheet stacking tray 246 as shown in FIG. 30, a core member 258 is covered with a soft member 259 having a low coefficient of friction formed in a U-shape as shown in FIG. 31. Further, as shown in FIG. 31, a rib 260 is provided on each convex portion of the embodiment of FIG. 30, as shown in FIG.
On the upper side, a member that does not bend and the like can be given.

The sheet stacking tray 2 thus configured
The operation 46 is movable in the sheet feeding direction. A plurality of sheet stacking trays 2 provided in the sheet feeding device 1
The sheet feeding unit 406 is guided by tray guides 209 and 210 provided in parallel with the sheet feeding direction in all the stages, and as shown in FIG.
A home position for the movement is provided at a position away from the sheet stacking tray 246, and the home position is
2, the stop position of the sheet stacking tray 246a corresponding to one of the LOCK release conditions of the drawer tray 100 in which the sheet stacking tray 246a of the first storage section 270a corresponding to the sheet supply port is stored, and a position for receiving sheet supply. The position is a standby position 252.

When the sheet feeding device 1 performs a sheet feeding operation, the sheet stacking tray 246 of the storage section 270 storing sheets of the selected sheet size is supplied with l ₁ as shown in FIG. The sheet is advanced to the paper feeding position 253 on the paper unit 406 side, and the paper feeding operation is started. When the sheet feeding operation other than the paper end is completed, or when another sheet size is selected, the sheet stacking tray 246 is moved to the standby position 252 again.
To prepare for the movement of the paper feed unit 406. The distance l ₁ from the standby position 252 to the sheet feeding position 253 is determined by the sheet stacking tray 246 when the sheet feeding unit 406 moves.
Are set so that they do not interfere with each other.

Further, when the sheet moves, the sheet moves as shown in FIG.
As shown in (c) and (d), the sheet stacking tray 246 retreats with respect to the sheet feeding unit 406, and the entire surface on which the sheet is placed is opened. You can move. The opening amounts l ₂ and l ₃ of the tray 246 are controlled so as to change according to the size of the placed sheet. The details of the sheet movement, the control thereof, and the movement of the sheet stacking tray 246 at that time will be described later.

The rear end of the sheet stacking tray 246 is forcibly bent downward by a guide, and the retreated sheet stacking tray 246 is made to hang down in the apparatus. 64-29873
The space saving can be achieved compared with the sheet storage section partition plate opening system proposed in US Pat. When the retracted sheet loading tray 246 is hung down inside the machine,
The sheet stacking tray 246 of each stage is provided with guides 210a, 210b, 210c, 210d, and 2 as shown in FIG.
10e, 210f, 210g, 210h, 210i, 2
The configuration 12 allows the sheet to be stored in a common tray space on each stage on the downstream side of the sheet feeding device 1 in the sheet feeding direction, thereby saving space. Further, when the uppermost sheet stacking tray 246 is retracted, the rear end does not reach the bottom surface of the sheet feeding device 1, but the sheet stacking tray 246 below interruption stops at the bottom surface. , And a tray guide 214 is provided below the tray guides 209i and 210i of the lowermost tray (246i in the present embodiment) to extend the storage space below the lowermost tray. In addition to the above-described embodiment, the retracted sheet stacking tray 246 may be configured to be wound and stored at the rear end of the sheet stacking tray 246.

The sheet stacking tray 246 is driven and moved by using a drive unit described later. At this time, the movement is controlled with the standby position 252 described above as the home position. In addition, the tray standby position detection sensor 632 of each sheet stacking tray 246,
The tray position sensor ₄ is provided outside the maximum sheet width l4 as shown in FIG. Therefore, it does not hinder the movement of the sheet and does not break even if the sheet falls off.

As shown in the perspective view of the main part of FIG. 35, the sheet stacking tray 246 is located below the portion where the sheet stacking tray 246 starts to bend downward in the sheet feeding direction downstream as shown in the perspective view of the main part. The pulleys 242 provided at both ends of a shaft (not shown) located at the position shown in FIG.
2, one drive motor 22 provided in the main body
The output of 0 is transmitted to the pulley on the back side of the main body among the two pulleys 242 attached to the sheet stacking tray 246 of each stage. The unevenness of the surface of the sheet stacking tray 246 is different in the pitch between the portion where the sheet is loaded as described above and the portion where the driving means is engaged.
2 are arranged so as to mesh with each other. Incidentally, reference numeral 243
Is a sheet stacking tray 246 on which a pulley 242 is pivotally mounted.
Axis of movement.

Driving unit 22 which can be freely moved up and down
Reference numeral 2 denotes a drive motor 220 serving as a drive source, which is used to move a pulley 242 provided on each sheet feed tray 246 and to move the sheet stacking tray 246 by switching a clutch in the drive unit. Both functions for transmitting the drive are switched.

As shown in FIG. 37, the output of the drive motor 220 provided near the base 201 on the back side of the paper feeding device 1 is provided near the top plate 207 of the paper feeding device 1 from the motor output gear 266. Input gear 2 of the drive unit 222 via the drive belt 221 between the idler gears 257
26. Drive unit 2 to which drive has been transmitted
The reference numeral 22 moves between the base 201 for restricting the operation only in the vertical direction and the top plate 207 along two guides 219 provided before and after the drive unit 222. This movement is performed via a roller 224 provided between the drive unit 222 and the guide, as shown in FIG.

The arrangement of gears and clutches inside the drive unit 222 is shown in the schematic configuration diagram of FIG.

In the figure, the input gear 226 to which the drive has been transmitted includes a rising input gear 227 attached to a rising shaft 228, a rising electromagnetic clutch 229, and a gear 23.
0, the ascending gear 231 is rotated, and the rack 218 is rotated.
The drive unit 222 is raised while meshing with. At this time, the descending electromagnetic clutch 234 is ON. When the drive unit 222 reaches the position of the pulley 242 of the sheet stacking tray 246 to be moved, the ascending electromagnetic clutch 229 is turned off and the drive is not transmitted to the gear 230, so that the rotation of the ascending gear 231 stops. Further, the ascending gear 231 is provided with a one-way clutch 232, and since the descending electromagnetic clutch 234 is still in the ON state, the descending shaft 233 is not in a free state, and the ascending gear 231 is connected to the drive unit 222. Since the rotation direction is restricted only in the ascending direction, the ascent of the drive unit 222 stops. Drive unit 222
Is performing the moving operation, the moving electromagnetic clutch 23
7 is OFF, and the driving force is not transmitted to the driving unit for moving the tray 246.

When the moving operation of the drive unit 222 is completed, the moving electromagnetic clutch 237 is turned on, and the input gear 226 is turned on.
Is transmitted to the gear 238 via the movement input gear 235. The driving force is transmitted from the gear 238 to the movement output gear 239, and the driving force is transmitted to the sheet stacking tray 246 by the number of stages to the movement gear 241 provided on the main body side, whereby the movement shaft 243 rotates. Then, the moving pulley 242 provided below the sheet stacking tray 246 rotates, and the sheet stacking tray 246 moves.

A moving shaft 243 on the drive unit 222 side;
The moving shaft 243 on the sheet stacking tray 246 side includes a coupling member (not shown), and includes a drive unit 222.
Reaches the position of the desired sheet stacking tray 246 to be moved, the coupling is performed, and the driving force can be transmitted. The release of the coupling is performed by the drive unit 2
The movement is automatically performed by the movement of the body 22 in any one of the upper and lower directions.

FIG. 39 is a front view of a main part of a driving portion of the sheet stacking tray 246 viewed from the front side of the main body, and FIG. 40 is a top view thereof.

The movement of the tray 246 is performed at the standby position 25.
2 to the paper feed position 253 and the opening position 254
Are moved in the same direction from the paper feed position 252 to the paper feed position 253, and from the paper feed position 253 to the standby position 252, and from the standby position 252 and the paper feed position 253 to the opening position 254 (FIG. The movement operation to 32) is in the same direction.

The above moving operation direction is opposite,
The switching of the direction is performed by switching between forward rotation and reverse rotation of the drive motor 220 and switching the rotation direction of the output gear 266.

The control of the movement of the sheet stacking tray 246 will be described in detail in the control section described later. The control is performed by counting the amount by the tray drive unit position detection sensor 635.

A filler 247 is provided below the sheet stacking tray 246 as shown in FIG.
The tray standby position detection sensor 632 and the tray paper feed position detection sensor 634 detect and control each position.

When the moving operation of the sheet stacking tray 246 of a certain sheet storage section 270 is completed, the drive unit 222
Is the sheet stacking tray 2 of the sheet storage unit 270 of another stage.
In order to execute the movement operation of 46, the mobile electromagnetic clutch 237 that has transmitted the drive to the drive unit is turned off, and the drive force is transmitted to the drive unit again for the movement of the drive unit 222 itself. As a result, the drive unit 222 moves.

As described above, the descending operation is performed by turning off the descending electromagnetic clutch 234 to release the descending shaft 233 and releasing the lock of the one-way clutch 232 with respect to the ascending gear 231. At this time, the drive motor 220 is
2 rotates in the opposite direction to the case where the output gear 266 rises, and rotates the output gear 266 in the opposite direction to that when the output gear 266 rises.

Next, another embodiment of the sheet stacking tray 246 will be described. 43 is a perspective view of an image forming apparatus according to another embodiment, FIG. 44 is a perspective view of a main part showing the uppermost sheet storage unit, and FIG. 45 particularly shows a sheet stacking tray portion of the uppermost sheet storage unit. It is a front view. In these figures, the uppermost sheet storage section 270a of the plurality of sheet storage sections 270 is provided so as to be able to be pulled out from the sheet feeding device 1 '.

The uppermost sheet storage section 270a holds a sheet, and supports a sheet stacking tray 246 movable in the sheet feeding direction, and the sheet stacking tray 246 so as to be movable. The support pipe 750 is integrally fixed to the support pipe 750 and receives a driving force from a drive source (not shown) installed in the main body of the sheet feeding device 1 ′ to move the sheet stacking tray 246 to the support pipe 750.
The moving pulley 751 to be moved on the upper side and the side end surface of the sheet placed on the sheet stacking tray 246 are aligned, and the side fence 331 which can be retreated from the sheet stacking tray 246.
And an end fence 350 having a rear end surface of the sheet and capable of retreating from the sheet stacking tray 246.

The structure of the sheet storage section 270a is shown in FIG.
As can be seen from the perspective view of FIG. 1, the structure is extremely strong because of being integrally formed by the hollow cylindrical member.
In other words, the support pipe 750 extends in a state parallel to the sheet feeding direction, and guides and supports both end surfaces of the sheet stacking tray 246 and the second pipe section 750A.
50B and a third pipe portion 750C and a fourth pipe portion 75 that extend in a state parallel to a direction perpendicular to the sheet feeding direction and are continuous with the first and second pipe portions 750A and 750B.
0D, the first and second pipe sections 750A, 750A, 7D.
A guide rail portion 752 for smoothly moving the sheet stacking tray 246 is formed in 50B, and a third pipe portion 750C located in the sheet feeding direction has a predetermined height which does not hinder sheet movement between the sheet storage portions. There is a rising portion 750E that rises with respect to the sheet stacking tray 246 and extends in a sheet feeding direction for a predetermined length so as not to hinder sheet setting by an operator. Therefore, since the sheet stacking surface area 753 and the sheet feeding area 754 are fully open, the support pipe 750 can realize smooth sheet movement when the sheet moves to the lower sheet storage unit 270. Also, the third pipe portion 750C
The paper feed unit stands by in the space formed by the two rising portions 750E.

Here, the movement of the sheet relating to the tray structure
Let's briefly talk about the set operation.

The sheet storage section 270a is pulled out of the sheet feeding device main body 1 'by an operator.
For example, the sheet is inserted onto the sheet stacking tray 246 from a direction opposite to the sheet feeding direction,
1. The respective end faces of the sheets are abutted against the end fence 350 and set on the sheet stacking tray 246. After the setting is completed, the operator places the sheet storage unit 27 in the pulled-out state.
0a is loaded into the sheet feeding device main body 1 '. After the loading is completed, the sheet stacking tray 246 temporarily moves in the sheet feeding direction, and the sheets set on the sheet stacking tray 246 also move in the sheet feeding direction. Sheet loading tray 246
Moves until the leading edge of the sheet feeding direction comes into contact with a vertically movable paper supply unit 406 (not shown), and stops after the contact. Next, the sheet feeding unit 406 clamps a predetermined portion of the sheet leading edge, and after clamping, the sheet stacking tray 246.
Retreats in the direction opposite to the sheet feeding direction. Furthermore,
The sheet feeding unit 406 descends toward the lower sheet storage unit while holding the leading edge of the sheet. At this time, since the sheet placement surface area 753 and the sheet feeding area 754 are in the fully open state, there is no obstacle to the movement of the sheet, and the sheet is smoothly moved to the lower sheet storage section 270b.

Next, a configuration for aligning sheets will be described.

When the drawer tray 100 is closed after the sheet is set, the set sheet bundle 94 is moved by the impact to the openable drawer tray 100 of the sheet feeding device 1 provided below the image forming apparatus 2. A side fence 300 as shown in a perspective view of a main part of FIG. 47 is provided in order to prevent the pieces from falling apart. The side fence 300 is parallel to the sheet feeding direction, is formed integrally with the shaft 301, and is a stay (support member) 274 (FIG. 4) parallel to the pulling-out direction of the drawer tray 100.
9) and guide grooves 275 (FIG. 48) and 276 (FIG. 49) provided in the side plate 273, respectively, and can be set manually. Stay 274 of drawer tray 100
Racks 307 and 309 are provided above the guide grooves 275 and 276, respectively, and the pinions 306 and 308 attached to the shaft 301 are provided in the guide grooves 276 and the guide grooves 275 of the side plate (support member) 273, respectively. It is meshable with the racks 307 and 309 and is movable. FIG. 48 is a perspective view of a main part of the drawer tray 100 as viewed from the rear side in the drawing direction, and FIG. 49 is a perspective view of the tray 100 as viewed from the entire surface side in the drawing direction.

The sheet bundle 94 is set from the sheet area to be set with the sheet end surface reference wall 261a provided inside the front side plate (support member) 271 of the drawer tray 100 in parallel with the side fence 300. After the sheet bundle 94 is once removed, the sheet bundle 94 is set on the tray 246 for placing the sheet, and then the side fence 300 is moved to a position where the side fence 300 abuts on the sheet bundle 94. When the one-way clutch 304 attached to the gear 305 restricts the rotation only in the direction of the arrow b in FIG. 48, the side fence 300 projects from the gear 305 and the guide groove 275 to the inside of the drawer tray 100. When the pinion 306 is engaged, the side fence 300 cannot move in the direction of the arrow c in FIG. 48, so that the side fence 300 is locked against the direction d of the force acting when the drawer tray 100 is closed.

Side fence 300 for sheet setting
When moving the side fence 300 toward the front side of the main body, hold the handle portion 310 and move the side fence 3
It is operated only by pulling the one-way clutch 3 toward the front side.
04 and a knob 303 to which a gear 305 is attached
48 in the direction of arrow a in FIG. 48 to release the engagement of the pinion 306 and the gear 305 connected to the knob 303, and move the side fence 300 while pressing the knob 303 in the direction of arrow a. Will be

The surface of the sheet stacking tray 246 has a flat surface because the elastic sheet 250 is adhered thereto. However, if the lower end surface of the side fence 300 is a mere flat surface, there is a small gap between the two. Therefore, when the side fence 300 absorbs the force to move the sheet bundle 94 due to the impact when the drawer tray 100 is closed, several sheets may slip through the minute gap. Therefore, under the side fence 300, a pawl 313 as shown in the side view of the main part of FIG.
Is provided. The pawl 313 is swingable with respect to the support shaft 312. In a free state, the pawl 313 attempts to rotate in the direction indicated by the arrow L in FIG.

However, when the sheet stacking tray 246 moves forward as shown in the side view of the main part of FIG.
The tapered portion 314 rides on the sheet stacking tray 246 from the tapered portion 314 at the longitudinal end, and the tip of the pawl 313 is parallel to the sheet stacking tray 246 and has moved from the upper sheet storage unit. Sheet bundle 94
Will be placed on it. Further, when the sheet stacking tray 246 is retracted, the support of the weight portion of the pawl 313 is lost, so that the sheet stacking tray 246 rotates in the direction of a in FIG.
It stops at the point where it hits the side fence 300.

Next, another embodiment of the side fence will be described.

A side fence according to another embodiment is as follows.
As shown in the perspective view of the main part of FIG. 52, the front view of the main part of FIG. 53 and the plan view of the main part of FIG. It is supported by a guide groove 276 formed in the rail-shaped member and is guided along the groove, and moves in the direction of the arrow in the figure. The side fence 331 for aligning the sheet feeding side end surfaces is provided in the uppermost sheet storage section 27 of the plurality of sheet storage sections 270 which can be pulled out with respect to the sheet feeding device main body 1.
0a only.

The side fence 331 is in contact with the sheet-side end surface and is aligned with the sheet-side end surface. The support bar 333 is fixed to the surface of the fence portion 332 opposite to the sheet contact surface and extends in the sheet width direction. Support bar 3
The drive motor unit 334 moves the motor 33 in the sheet width direction. The contact portion 332A of the fence portion 332 that contacts the tray surface is formed in a comb-like shape that engages with the corrugated tray surface, so that the movement guide and sheet enter the tray corrugated recess when the fence portion moves. Even if you do, you can be sure to align. Support bar 33
The drive motor unit 3 is provided on the end side opposite to the end of the fence 3.
A rack 333A is formed to be engaged with the gear 334A of the fence unit 33.
Transmit to 2. The drive motor unit 334 is
Gear 334A for transmitting the rotation of F.34 to fence 332
And is fixed to the guide rail 276 via the base 335. In other words, side fence 3
31 is integrally attached to the sheet storage unit 270, and when the sheet storage unit 270 is pulled out with respect to the sheet feeding device main body 1, the side fence 331 is also pulled out at the same time. The guide rail 276 is provided with a notch 336 for evacuation so that the fence 332 can be retracted out of the tray area.
2 can be moved smoothly through the notch 336 when retracting out of the tray area.

The operation of the side fence 331 according to another embodiment based on the above configuration will be described below.

When any one of the plurality of sheet storage units 270 is in the paper end state, a sheet size signal indicating the paper end is input to a control circuit (not shown) (not shown), and from the control circuit to the drive motor unit 334. The number of pulses corresponding to the amount of movement of the fence unit 332 determined from the sheet size signal is output, and the drive motor unit 334 rotates a predetermined number. The fence unit 332 includes the drive motor unit 33
With the rotation of 4, it moves via the support bar 333 and waits at a predetermined position. The uppermost sheet storage portion 270a is pulled out of the sheet feeding device main body 1 for replenishing sheets, and the sheets are stored in the side fence 331 already located at a predetermined position.
Is set in the sheet storage portion 270a in accordance with the setting. After the setting is completed, the sheet storage unit 270a is loaded into the sheet feeding device, and after the loading is completed, the drive motor unit 334 rotates in the reverse direction, and the fence unit 332 retreats outside the sheet stacking tray 246 through the notch 336. I do.

The movement of the fence 332 will be further described.

Image forming apparatus 2 provided with paper feeder 1
Has a digital function equipped with a full memory capable of rotating read image information. As for the vertical (T) set of A4 and B5 originals, horizontal (Y) conversion by rotation processing is possible, so that the main sheet sizes accommodated in the sheet feeding device 1 are set to A4Y, B5Y, A3T and B4T. The length in the sheet width direction is 297 mm (A4Y, A3
T) and 257 mm (B5Y, B4T).
Further, the sheet is set on the basis of the front end face of the apparatus. Therefore, the fence 332 is located at the retreat position where the sheet is retracted outside the area of the sheet stacking tray 246, and is located at 257 mm from the front end face of the apparatus.
And a second set position of 297 mm from the front end face of the apparatus.

Next, the mechanism and operation related to the end fence will be described continuously.

The end fence 350 is installed at the sheet end of each sheet storage section 270 as shown in the schematic configuration diagram of the image forming apparatus system of FIG. That is, the end fence 350 in this embodiment is different. A sheet trailing end 9 of each stage of the sheet feeding device 1 of the different size multi-stage sheet feeding system which is provided below the image forming apparatus 2 and includes a sheet stacking tray 246 for stacking a plurality of vertically stacked sheets 99.
9c, the end fences 350a to 350i of all the stages are stacked as shown in FIG.
Is automatically moved between the optimal position of the end fence 350 corresponding to the size of the stacked sheets 99 of each stage and the retreat position, and the optimal position of each end fence 350 is determined until the next signal comes. An automatic control unit including a detecting unit for holding, a driving unit, and a holding unit is provided. Further, only the end fence 350a for the uppermost drawer tray 100a is automatically controlled by changing the mechanism for holding the optimum position of the end fence 350a adapted to the stacked sheets, and the position of the end fence 350a is manually changed arbitrarily. It is configured to be able to.

The end fence mechanism is located between the sheet storage section 270 of the sheet feeding device 1 and the sheet feeding device front cover 16, and faces from the front as shown in the schematic configuration of the end fence 350 in FIG. The drive shaft 364 is held vertically at the center slightly to the left, and the drive shaft 3
64, one drive motor 359 capable of normal and reverse rotation is fixed via a motor mounting bracket 360 fixed to the paper feeder frame 200, and between the drive motor 359 and the drive shaft 364, An eccentricity absorbing coupling 361 is provided, and both are connected with the eccentricity absorbing coupling 361 interposed therebetween.

Since the paper feeder frame 200 is a structure composed of the base 201, the top plate 207 and the four pillars, the drive shaft 36 attached thereto via a bracket is attached thereto.
It is extremely difficult to accurately assemble the shaft core of No. 4 and the shaft center of the drive motor 359. Therefore, the misalignment of the two axes is absorbed by the eccentricity absorbing coupling 361 shown in detail in FIG. However, due to the overall structure, when the axis of the drive shaft 364 and the axis of the drive motor 359 are accurately assembled, they can be directly connected as shown in FIG. 57 or can be directly connected as shown in FIGS. Alternatively, the drive motor 359 may be assembled by swinging the drive motor 359 to the right or left as viewed from the front, or to the back or front, with respect to the drive shaft 364 by using a connection means using a gear train.

As a driving means for automatically controlling the end fence 350, assembling and maintenance are easier than using a belt or a cable, and rotation from the driving motor 359 is controlled via a rack and pinion to reduce the number of parts. The end fence 350 can be configured to move in a thrust direction. In addition, the fence 351
Move range from a position slightly retracted from the rear end of the sheet having the maximum sheet size to the rear end at the time of feeding the minimum sheet, so that the rack 35 formed integrally with the fence portion 351 can be moved.
2 is to prevent the rack 352 from coming off the gear 369 even if the fence 351 moves the maximum movement amount.
The rack 35 is longer than the maximum movement amount of the fence unit 351.
2 must be formed. However, in recent years, users have been demanding space saving of the machine, so the fence 351, the rack 352, the drive shafts 362, 36
4, the rack 352 comes to the left end when the fence 351 comes to the left end.
2 is the gear 36 of the drive shafts 362 and 364
9a-i. Then, as shown in FIG. 55, the drive shafts 362 and 364 necessarily come near the center of the machine.

Next, the structure of the clutch unit will be described.

As shown in FIGS. 55 and 61, the drive shaft 364 is composed of a drive shaft 362 for the first sheet storage portion at the uppermost stage and a drive shaft 364 for the second sheet storage portion and thereafter.
Consists of books. Between the two drive shafts 362 and 364, a shaft coupling 377 held by a bearing 366 and operated by the on / off operation of the solenoid 370 is attached to the drive shaft 364 for the second and subsequent sheet storage sections. Near the distal end of the outer diameter of the drive shaft 364, the stroke 390 of the shaft coupling 377 is set in the thrust direction.
A plurality of knurls 365 are attached to the drive shaft 364 near the tip of the inner diameter of the shaft coupling 377, and a plurality of knurls 365 are attached to the drive shaft 364 at a certain interval longer than that of the knurl 365 (see FIG. 72).
5 and a thrust knurl 37 meshing with the knurl 365 of the drive shaft 364.
8, the two mesh with each other to connect the drive shaft 364 and the shaft coupling 377 (FIGS. 73 to 76).

In the shaft coupling connecting mechanism, the ascending lever 373 is always rotated in the direction A around the fulcrum 374 by a bracket (not shown) by a tension spring 376, and is in a falling state. The shaft coupling 377 is always in a state of being lowered by the compression spring 380 along the drive shaft 364 (FIG. 72). However, the shaft coupling side has a compression spring 380
May be abolished, and the shaft joint 377 may be lowered by its own weight.

The operation timing and operation procedure of the shaft coupling connecting mechanism section are as follows: (1) The sheet 99 is supplied to the first sheet storage section of the drawer tray 100, and after the drawer tray 100 is set in the main body, the supplied sheet 99 is supplied. (2) When the size of the sheet 9 is detected from the first sheet storage portion 270a,
9 is fed, (3) when shifting the sheet 99 in the first sheet storage section 270a to the second sheet storage section 270b and thereafter, the solenoid 370 is turned on, and the joint 372 attached to the plunger 371 is turned on. By rotating the ascending lever 373 in the direction B around the fulcrum 374, a standing state 373 'is reached, and the arc surface 375 of the ascending lever rises the shaft coupling along the drive shaft 377' and rises. 74 (FIG. 74), the disk 379 at the end of the shaft coupling comes into contact with the disk 363 mounted below the drive shaft 362 for the first sheet storage unit, and transmits the rotation of the drive motor 359. Discs 363 and 379 attached to shaft coupling and drive shaft
May be formed by a high friction member as a means for transmitting the drive, or a groove may be provided on the surface where the two are in contact with each other.

The drive shaft 364 can skip one electromagnetic clutch 368 from a functional and economical point of view.
6 to the sheet feeding device structure (FIG. 55). The same number of spur gears or helical gear 369-equipped electromagnetic clutches 368 as the number of seat storage units are attached to the drive shaft 364 in the same direction as the sheet storage unit position in the same vertical direction.
On the right side or left side of the figure, an end fence position detection sensor 357 is attached to the main body of the sheet feeding device 1 via a sensor attachment bracket 358 at each stage, and the harness is crawl around. However, when there is no space in the entire layout, only the uppermost electromagnetic clutch 368a may be set in the opposite direction as shown in FIG. Further, only while the electromagnetic clutch 368 is ON, the drive from the drive motor 359 is driven via the drive shaft 364 and the end fence 350 via the electromagnetic clutch 368.
It is transmitted to.

The end fence 350a of the first sheet storage section 270a is always engaged with the gear 369a of the electromagnetic clutch 368a by the lock member 381 shallowly, and when the drive from the drive motor 359 is not transmitted.
(1) The sliding load between the guided portion 353a of the end fence 350a and the upper and lower guide rails 355a and 356a,
(2) meshing load between the rack 352a of the end fence 350a and the gear 369a of the electromagnetic clutch 368a;
(3) When the drawer tray is pulled out, when the drawer tray is set on the main body, and when the drawer tray is set by the engagement of the gear 369a of the electromagnetic clutch 368a and the lock member 381, or the like, the device is not moved during standby. However, when the end fence 350a is manually positioned or automatically controlled, the end fence 350a is not completely locked.
The end fence 350a can be moved such that the tooth tip 391a of the gear 369a pushes back the lock member 381 (FIGS. 62, 63, and 67).

The end fences 350b-i below the second sheet storage section 270b are provided with stoppers 384 held via brackets 383a-d on brackets (not shown) attached to the upper, middle, and lower portions of the feeder frame 200, respectively. The tension spring 389 constantly rotates in the direction of arrow C in FIG. 64 around the fulcrum 388, and the elastic member 386 of the stopper tip 385 hits several tooth tips 391b to 391i of the gears 369b to 369i of the electromagnetic clutches 368b to 368i. The fences 350b to 350i are not moved (FIG. 64-solid line). With this configuration,
As shown in FIG. 65 and FIG.
Since the gear 92 does not mesh with the gear 369 to restrict the rotation, the tooth surface is not damaged when the stopper hits, and the gear is not rotated excessively (about 1/2 tooth rotation or less). Then, the end fence 35 after the second sheet storage section 270b
To move 0b to 350i, the dedicated solenoid 387 is turned on at the same time as or slightly before the drive motor 359 is rotated, so that the stopper 384 is rotated in the D direction, and the gears 369b to 369b of the electromagnetic clutches 368b to 368i are rotated.
The elastic member 386 is formed from the tooth tips 391b to 391i of the 369i.
To enable rotation (FIG. 64-2 dashed line).

FIG. 70 and FIG.
As shown in a perspective view of a main part of FIG. 1, a fence 35 for regulating the sheet 99 with a moldable material such as a mold or aluminum.
1, a rack 352 corresponding to a spur gear or a helical gear 369, a guided portion 353, and a filler 354 for an end fence position detection sensor 357 are integrally formed, and a feeder structure is formed by upper and lower guide rails 355, 356. The body is held so as to mesh with the gear 369 of the electromagnetic clutch 368 attached to the drive shaft 364, and so that the filler 354 cuts off the end fence position detection sensor 357. However, when there is not much restriction on cost or the like, a part may be made of sheet metal and a combination of a sheet metal and a formed member may be used.

The end fence 350 held by the upper and lower guide rails 355, 356 forms a fence 351 so as to extend from the near side to the far side, and the rear end 99c of the shift loaded on the tray 246 of the sheet storage section. A gap of about 1 mm to 3 mm is provided between the sheet stacking tray 246 and the sheet stacking tray 246 for stacking the sheets 99. As shown in FIG. With the sheet attached, the gap is filled, and the stacked sheets do not interfere with the tray 246 when the end fence 350 moves, and conversely, do not interfere with the end fence 350 when the tray 246 moves. 99 will be regulated. Also, even if the elastic member 386 or the like is not attached, the lower surface of the side fence 350 'is made uneven as shown in FIG. May be.

Sheet storage section 2 in drawer tray 100
When the sheet 99 is replenished onto the sheet stacking tray 246 of 70 and the drawer tray 100 is set in the main body of the paper feeder 1, the sheet detection sensor 3
94 detects "sheets present" or "sheets absent" on the tray (FIG. 77).
0 is turned on, the drive motor 359 is rotated in the direction E (FIGS. 63 and 70), and the drive shaft 364 and the shaft coupling 377 for the second storage section and thereafter are returned to drive the drive shaft 362 for the first sheet storage section. And return the electromagnetic clutch 368a with the gear, and the rack 352 from the gear 369a.
The drive is transmitted to a, and the end fence 350a is moved to the left end of the home position. At this time, the rack 352
The filler 354a below a continuously cuts the end fence position detection sensor 357a while moving, and calculates the size of the set sheet 99 in the shift feed direction from the number of cuts of the end fence position detection sensor 357a.

In the machine of this system, the size and direction of the sheet that can be passed from the paper feeder 2 in the domestic machine are set as A3 and B4 sizes are vertically fed, and A4 and B5 sizes are only horizontally fed. This is because not only facsimile machines and printers, but also copying machines in recent years, the digitization of the image reading unit 5 in the automatic document feeder 3 and the image writing unit 6 in the image forming apparatus 2 have advanced, and the technology has advanced. It is clear that further digitization will progress in the future, as the parts required for digital machines are becoming cheaper. There are various merits when a digital machine is used, but one of them is that the read information is changed by passing through a storage unit during the signal transmission from the image reading unit 5 to the image writing unit 6. There are things you can do. Thus, when the original size and orientation are A4 or B5 and vertical, the storage unit can convert the orientation of the original to horizontal and send it to the image writing unit 6.

As described above, on the sheet stacking tray 246 in the sheet feeding device 1, only one size of four sheets 99 of one leaf is formed. That is, the sheet 9 detected by the end fence 350
The size of the sheet 99 can be determined only by the size in the sheet feeding direction of No. 9.

Thereafter, the drive motor 359 is rotated in the direction F to move the end fence 350a to the end of the sheet, which is the original position, of the end fence position detection sensor 357a.
Return while managing with. The movement of the end fence 350 at the time of determining the sheet size is such that the filler 354 of the end fence keeps cutting the end fence position detection sensor 357 from the set position to the left end which is the home position. Eventually the last rightmost filler 354
After turning off the end fence position detection sensor 357, the end fence position detection sensor 357 does not turn on because the filler 354 is not present, and remains off. Therefore, when the ON signal from the end fence position detection sensor 357 is lost, and when the OFF time when the filler 354 continues to cut off the sensor 357 exceeds a certain extent, the electromagnetic clutch 3
68 is cut off, the drive from the drive motor 359 is cut off, and the end fence 350 stops. Thereafter, the drive motor 359
The electromagnetic clutch 368 is connected until the filler 354 of the end fence turns off the end fence position detection sensor 357 again, and the end fence position detection sensor 3
After 57 is turned on, the electromagnetic clutch 368 is disengaged again and the end fence 350 stops. In addition, this position is set as the home position of the end fence 350, and is set as the rear end of the maximum feedable sheet (A3) during standby.

Next, the control of the side fence configured as described above will be described.

First, control of the side fence when the drawer tray is pulled out (hereinafter, referred to as “Open”) and when the drawer tray is pushed in and set (hereinafter, referred to as “Close”) will be described.

Controlling the lock of the side fence 331, particularly, the open operation of the drawer tray 100 (first-stage sheet storage section)
Control at the time of n / Close will be described.

FIG. 78 is a flowchart showing a control procedure at the time of sheet supply. In addition, although it is represented as S0 in the flowchart, in order to correspond to the figure, in the description in the text, the corresponding figure number is shown in parentheses after S representing the step, such as S (78) 0 step. Hereinafter, the same notation is used in the description of the flowchart.

In this procedure, first, it is assumed that in step S (78) 0, the drawer tray 100 is in the Close state and the side fence 331 is locked. S
(78) In one step, the CPU 6 determines whether or not an operator has input a drawer tray Open request to a member such as an auto load key provided on the front portion of the drawer tray 100 or the key input unit 612 of the operation unit 610.
01, and if there is no Open request, the state is maintained. If there is an Open request, S (78) 2
Proceeding to a step, it is detected whether or not the drawer 100 is locked. Then, in step S (78), it is determined whether or not the condition is such that the drawer tray 100 is currently locked. If the condition is locked, the lock condition is released and the process returns to step S (78) 2 to lock. If not, the process proceeds to step S (78) 4 to unlock the drawer tray 100 by the lock mechanism. And S
(78) In step 5, the tray opening amount detection sensor 631 detects whether or not the drawer tray 100 has been pulled out by the operator, and the CPU 601 determines.

In this determination, when the drawer tray 100 is not pulled out, the lock of the drawer tray 100 is released as it is. Conversely, when it is determined that the drawer tray 100 is pulled out, in step S (78) 6 The lock of the side fence 331 is released to enable manual movement. Then, sheet replenishment by the operator is completed,
When the drawer tray 100 is to be set in the paper feeder 1 again, in step S (78), the operator touches a member such as an auto close key provided on the front part of the drawer tray 100 or the key input unit 612 of the operation unit 610 in step S78. Whether the drawer tray close request is input from the CP
It is determined by U601. With this determination, the drawer tray C
When the "close" request has not been input, the operation of the operator has not been completed, so that the side fence 331 is kept unlocked.
When an “ose” request is input, the work by the operator has been completed.
Lock 1 again. Then, in step S (78) 9, the drawer tray 100 is again moved by the operator to the sheet feeding device 1.
Tray opening amount detection sensor 63
1 and is determined by the CPU 601. In this determination, when the drawer tray 100 is not set,
The side fence 331 remains locked, and if it is determined that the drawer tray 100 has been set, the drawer tray 100 is locked again in step S (78). In step S (78) 11, the CPU 601 controls the side fence driving unit 626 to retreat the side fence 331 from above the sheet stacking tray 246 in preparation for the movement of the sheet stacking tray 246.

In this manner, when the drawer tray 100 is open, the locked state of the side fence 331 is released, and when the drawer tray 100 is closed, the locked state is maintained.
In this case, it is possible to increase the setability of the sheet at the time, and prevent the sheet from being loosened by the impact at the time of the Close, so that the reliability can be improved. Also, the drawer tray 100
After the sheet is set in the sheet feeding device 1, the sheet stacking tray 246 is prevented from moving by being retracted from the side fence 331.

Next, the control of the side fence and the end fence will be described with reference to the flowchart of FIG.

Side fence 33 of first-stage sheet storage section
0, the movement control of the end fence 350a, particularly the control at the time of seat end will be described.

In step S (79) 0, the i-th stage (i
If a sheet end occurs in the sheet storage portion of ≧ 2), S
(79) In one step, the first-stage sheet storage unit 2
The presence or absence of the sheet 70a is detected based on the remaining sheet data stored in the nonvolatile RAM 605. And S (7
9) In two steps, the CPU 601 determines whether or not there is a sheet in the first-stage sheet storage unit 270a. If it is determined that there is a sheet, the side fence 330 is used.
Since it cannot move with the end fence 350a, the control is not performed and the control ends. Conversely, if it is determined that there is no sheet, the sheet size at the end of the sheet is detected from the sheet size data stored in the nonvolatile RAM 605 in step S (79) (SI).
ZE), S (79) The end fence driving unit 622 and the side fence driving unit 6 by the CPU 601 in four steps.
26, the side fence 300 and the end fence 350a are automatically moved in accordance with the SIZE to notify the operator of the sheet size to be set.

By doing so, the sheet 99 is stored in the first-stage sheet storage section 270a when a sheet end occurs.
If there is no sheet 99, and if there is no sheet 99, the positions of the side fence 300 and the end fence 350a are automatically moved according to the size of the sheet 99 that has been seated in advance, so that the operator can set it. Since it is possible to inform the user of the sheet size to be set, sheet setting errors can be reduced, and operability can be improved.

The control of the movement of the end fence 350, particularly the control at the time of moving the sheet, will be described.

FIG. 80 is a flow chart showing the control procedure of this end fence movement. First, in step S (80) 0, when a sheet end occurs in the sheet storage unit of the i-th stage (i ≧ 2), in step S (80) 1, the CPU 601 prepares the sheet feeding unit driving unit for the movement of the sheet 99. The CPU 601 controls the pressing lever driving unit 625 to hold the sheet 99 by the pressing lever 453 by controlling the control unit 621 to move the sheet feeding unit 406 from the i-th stage to the (i-1) -th stage. In step S80-2, the sheet size SIZE of the (i-1) th stage is detected based on the sheet size data stored in the nonvolatile RAM 605. S (80) 3 steps in step C
The PU 601 controls the end fence drive unit 622 to automatically move the i-stage end fence 350 to a position slightly longer than the SIZE sheet 99 feeding direction in advance so that even if the sheet 99 moves, the end fence 350 In preparation for the movement of the sheet 99 so as not to hit.

Then, in step S (80) 4, the CPU
The control unit 601 controls the sheet feeding unit driving unit 621 to move the sheet feeding unit 406 from the (i-1) th stage to the ith stage. After the movement of the sheet 99 to the ith stage is completed, S (80) 5
In step, the end fence driving unit 6 is controlled by the CPU 601.
By controlling the position of the sheet 22, the i-stage end fence 350 is automatically moved to the position in the sheet feeding direction of the SIZE sheet 99, and the position of the sheet 99 is properly regulated so that the sheet 99 is not scattered. Further, in step S (80), the CPU 601 executes
To control the pressure lever drive section 625 to control the pressure lever 4
The hold of the sheet 99 by 53 is released, and the control ends.

In this manner, the position of the destination end fence 350 is automatically moved and changed in advance in accordance with the size of the sheet 99 to be moved, and the position is slightly longer than the sheet size in the sheet feeding direction. , The sheet 99 can be prevented from hitting the end fence 350 when the sheet 99 is moved due to the end fence 350 being at an inappropriate position. In addition, the moving time of the sheet 99 can be shortened, thereby improving the productivity. Further, after the sheet is moved, the end fence 35 is adjusted to the sheet size.
By arranging “0” at an appropriate position, the sheet 99 can be regulated properly, so that it is possible to prevent the sheet 99 from varying.

Further, control of the end fence at power-on will be described.

The control at power-on when the end fence 350 is moved will be described in detail with reference to the flowchart showing the control procedure in FIG.

First, in this process, in step S (81) 0, the power of the apparatus main body is turned on, and in step S (81) 1, the control counter i used in the CPU 601 is set to 1, and (81) The sheet size S based on the sheet size data of the i-th stage (first stage) stored in the nonvolatile RAM 605 in two steps
ISE1 is detected. Then, in step S (81) 3, the CPU 601 causes the end fence driving unit 622 to execute the operation.
To move the i-th end fence 350 to the home position H. P. Move up to

In step S (81), the CPU 601 checks the encoder pulse of the end fence drive motor 359 to determine whether the movement of the end fence 350 has been performed normally. The end fence 35 is displayed on the display section 611 of the section 610.
The operation of 0 is displayed as abnormal to alert the operator. Conversely, if the operation was performed normally, S (81) 5
In the step, the encoder pulse of the end fence drive motor 359 at that time is counted, and the sheet size (SIZE2) is detected from the result. Here, the sheet size can be detected only by the moving distance of the end fence 350 because the setting direction of the sheet 99 of each size is determined. That is, A3 and B4 are vertical, A
4 and B5 are horizontal. Then, S (8
1) In step 6, SIZE1 and S
It is determined whether ISE2 is equal. In this determination, S
If SIZE1 and SIZE2 are not equal, the operation unit 610
Is displayed on the display unit 611 indicating that the size data of the nonvolatile RAM 605 is abnormal, and the operator is warned.
Conversely, if SIZE1 and SIZE2 are equal, S (8
1) A counter i for control is set to i + 1 (2) in 7 steps. Then, in step S (81), it is determined whether the value of the control counter i is larger than 9 (the lowermost row is the ninth step).
2 to S (81) 8 steps to end fence 3 of next stage
When the value of i is larger than 9, the control is terminated because the check has been completed up to the lowermost stage.

In this way, when the power is turned on, the position of the end fence 350 of each sheet storage unit is moved to the home position and the operation is confirmed. Is displayed on the screen. At that time, the end fence drive motor 3
The sheet size is detected from the result of counting the 59 encoder pulses and compared with the sheet size data stored in the nonvolatile RAM 605 to check whether there is any abnormality in the contents. This can also be displayed on the display unit 611 of 610. This allows
The operator can confirm the presence or absence of the abnormality by the display.

Next, a mechanism related to sheet feeding and its control will be described.

The sheet feeding unit 406 is provided so as to be movable in the vertical direction of the sheet feeding device 1 installed below the image forming apparatus 2 as can be seen from FIG. Regardless of, one sheet covers all stages of sheet feeding and sheet movement.

As shown in the front view of FIG. 82, the paper feed unit 406 includes a call roller 435, a pair of separation rollers 450, a pressure lever 453, a pair of conveyance guides 486, and a sheet leading edge aligner. 9, a detection unit for the sheet, and a driving unit 484 (FIG. 9) for driving each roller.
4).

The calling roller portion 435 includes a calling roller 436, a bracket 437 for holding the roller 436, and an auxiliary bracket 439 for supporting the bracket 437 as shown in FIGS. 497 is swingably supported. The roller 436 is a sheet loading tray 2
The uppermost sheet 98 on the sheet stacking tray 246 and the uppermost sheet 98 on the sheet stacking tray 246 are pressed against the uppermost sheet 98 on the sheet stacking tray 246 by a predetermined pressure due to their own weight and the elastic force of a tension spring (not shown). 98 sheets around
As shown in FIG. 94, the rotation from a driving motor 407 as a driving source is transmitted to a driving unit 484 in a paper feeding unit 406 via a driving belt 409 to a pair of separating units 450 as a next transporting unit. The feeding roller 436 is rotated through the clutch 485 to carry the sheet. Thereafter, the feeding roller unit 435 is retracted upward 445 via a lever by a sheet feeding solenoid (not shown), and is separated from the sheet 99 (FIG. 84 (d)). The rotation of the drive motor 407 is transmitted to the drive roller 417 via a drive gear 496 and an idler 495. In addition, in FIG.
46 is a fixed solenoid, 447 is an arm, 44
8 is a lever.

The pair of separation rollers 450 separates the sheet sent by the call-up roller 436 from the other sheets below only the top sheet 98 and drives the drive section 484.
And transmits the driving force input through the paper feed clutch to convey the sheet to the next conveyance means and thereafter. Thereafter, in order to stop the sheet before the pair of separation roller portions 450, a feed roller 451 for conveying the sheet is provided on the upper side, and a separation roller for separating the sheet is provided on the lower side as shown in FIG. 452 are arranged and driven.

As shown in FIG. 84, the pressure lever portion 453 includes two types of levers 457 and 461 separately held at two fulcrums 458 and 462, respectively, and two types of levers 457 and 461.
7 and 461 each include a pressure holding plate 468 held by separate fulcrums 459 and 463, and a dedicated drive motor 470 (FIG. 87) for driving them. The sheet feeding unit 406 feeds the sheet 99 on the sheet stacking tray 246. When supplying the sheet to the image forming apparatus 2, the sheet stacking tray 246 is supported from below (FIG. 84 (c)). In addition, the operation is performed when the sheet 99 on the sheet stacking tray 246 is moved to the subsequent sheet stacking tray 246 of the sheet storage unit 270.

As shown in FIGS. 88 and 89, the sheet leading end aligning section 472 rotates around the fulcrum center to rotate the sheet leading end 9.
9a, an arm 473 for aligning the arm 9a, a solenoid 476 for operating the arm 473, and a joint 4 connecting them.
74, and a tension spring 475 for always retracting the arm to a position where there is no obstacle to sheet conveyance. Thus, the supply of the sheet 99 to the image forming apparatus 2 is completed by the calling roller unit 435 and the pair of separation roller units 450, and before the sheet stacking tray 246 is returned from the unillustrated sheet feeding position to the standby position, the solenoid 476 is set. Of the arm 4 through the joint 474
Rotate 73 from the retracted position 477 about the fulcrum to the protruding position 478 that is flush with the sheet leading edge reference wall or slightly protrudes toward the sheet storage unit 270, and protrudes from the stacking position to a position immediately before the pair of separation roller units 450. The returned sheet 99 is returned to the original stacking position, and the leading edge of the sheet is aligned. In FIG. 88, reference numeral 487 denotes an upper guide plate, and reference numeral 48 denotes an upper guide plate.
8 is a lower guide plate.

Each detecting section relating to the sheet detects the sheet height 92 on the sheet stacking tray 246 by using the call roller section 43.
8 and the sheet upper limit detection sensor 480 (FIG. 8)
4) and a sheet end detection sensor 481 for detecting the presence or absence of a sheet 99 on the sheet stacking tray 246 (FIG. 93).
A sheet remaining amount detection sensor 482 (FIG. 87) for detecting the remaining amount of the sheet 99 on the sheet stacking tray 246 together with the pressurizing lever 453, and a sheet stacking tray 246 by a call roller 435 and a pair of separation rollers 450. When the sheet 99 is conveyed from the top to the image forming apparatus 2, the sheet 99 includes a sheet leading edge detection sensor (not shown) that detects whether the sheet 99 has been conveyed within a predetermined time. Note that the seat end detection sensor 481 detects the seat end by detecting the position of the other end of the actuator 498 that rotates while one end abuts on the sheet 99.

The paper supply unit 406 moves as follows.

That is, as shown in FIGS. 90 and 91, the sheet feeding unit 406 connects the moving motor 410 and the cable 415 connecting the sheet feeding unit 406 to the front and rear at the stage where the sheet 99 is to be fed. After being moved by driving, and the sheet stacking tray 246 at that stage is moved from the standby position to the sheet feeding position, the calling roller 436 in the sheet feeding unit 406 is moved by the calling roller 436 and the bracket 437 holding the calling roller 436, and The paper feed unit 406 is moved downward by setting the lower limit position 444 by the weight of the auxiliary bracket 439 and the elastic force of the above-described tension spring (FIG. 84 (a)). Eventually, the call roller 436 hits the uppermost sheet 98 on the sheet stacking tray 246, but the sheet feeding unit 406 continues to move down (FIG. 84).
(B)), the lower limit position 444 with respect to the sheet feeding unit 406
Position of the call roller 436 that was
To move toward the calling roller 436.
The filler 438 of the bracket 437 supporting the sheet feed unit 406 cuts off the sheet upper limit detection sensor 480.
Stops and paper can be fed (FIG. 84 (c)).

When a large number of sheets 99 on the sheet stacking tray 246 are fed one by one by the sheet feeding unit 406, the sheet height (stacking height) 92 on the sheet stacking tray 246 is proportional to the number of sheets fed. Decreasing. Accordingly, the position of the call roller 436 with respect to the sheet feeding unit 406 is lowered, and the filler 438 of the bracket 437 holding the call roller 436 that has cut off the sheet upper limit detection sensor 480 cannot be cut. Then, the moving motor 410 for moving the sheet feeding unit 406 is rotated, and the height position of the sheet feeding unit 406 is lowered and stopped until the filler 438 of the bracket 437 holding the calling roller 436 cuts off the sheet upper limit detection sensor 480 again. .

By repeating the above operation, the positional relationship between the uppermost sheet 98 on the sheet stacking tray 246 and the sheet feeding unit 406 is maintained within a certain range in which sheets can be fed.

The structure of the pressure lever is as follows.

The rotation centers 458 and 462 of both the pressure levers of the pressure lever portion 453 are in the range of the pressure lever operable range 4.
By providing on the parallel line of the intermediate position 455 of 54,
When the pressing levers 457, 461 are rotated by a certain amount, the vertical movement amount error of the action points 459, 462 is minimized (FIG. 86 (b)). Both pressure levers 457, 461
Are the action points 459, 463 from the rotation centers 458, 462.
It consists of two kinds of levers 457 and 461 having the same shortest distance to the other. At the rotation centers 458 and 462 of the two pressure levers, sector gears 460 and 465 each having the same module and the same reference pitch circle diameter on the same arc are provided one by one. The pressure drive lever 457 side has a sector shape. On the pressure driven lever 461 side, the fan-shaped driven gear 465 is moved from the pressure driven lever center 462 to the lever so that the drive gear 460 is located outside the line connecting the lever center 458 and the action point 459 from the pressure drive lever center 458. It is fixed so as to be inside the line connecting the center 462 and the action point 463 (FIG. 86).

Between the two front and rear pressure levers 457 and 461, the two fan gears 460 and 465 are engaged, and the pressure drive lever 457 and the rotation center 4 of the pressure driven lever 461 are engaged.
The intermediate gear 466 is connected to both the sector gears 4 so that the line connecting the action points 459 and 463 to the action points 459 and 463 becomes parallel.
When they are not meshed with 60 and 465, they are mounted one by one so that they can rotate freely, and a rotational drive is applied to the pressure drive lever shaft 456 (FIG. 85), and through the sector gear 460 on the pressure drive lever 457 side. The fan-shaped gear 465 on the pressure driven lever 461 side is rotated via the intermediate gear 466 so that the pressure driven lever 461 is rotated with the pressure driving lever 457 at the same angle and at the same speed. In FIG. 85, reference numeral 469 denotes a double feed prevention plate. Also, the pressure drive lever shaft 4
As shown in FIG. 87, a worm wheel 467 is attached to the shaft 56 so that the rotation of the dedicated drive motor 470 is
4 to the worm wheel 467, and the rotation is transmitted from the worm wheel 467.

The points of action 459 and 463 of the two pressure levers
, The pressure holding plate 468 is attached so as to be rotatable at the same center-to-center distance as the distance between the rotation centers of the two pressure levers. Therefore, two pressure levers 457, 461
Is rotated, the pressure holding plate 468 moves in parallel while maintaining the initial angle. The pressure levers 457 and 461 are driven by the dedicated driving motor 470 as shown in FIG. 7 as described above, and the pressure holding plate 468 moves the paper supply unit 406 by substantially the same amount as the paper supply unit 406 has moved. Rotate in the direction opposite to the direction in which the pressing lever 457,
The pressure holding plate 468 attached at the tip of 461 is raised.

As described above, the sheet feeding unit 406 stores the sheets 99 one by one from the sheet storage unit 270 in the sheet feeding device 1 in the different-size multi-stage sheet feeding system.
Feeding unit 4
06 must be able to move up and down smoothly and accurately from another location to a predetermined position. Therefore, the guided members 433 and 433 made of a low friction member are provided before and after the sheet feeding unit.
434 is attached from the paper feeding unit main body 431 via the arm 432 (FIG. 98), and the guide rails 403 and 404 are fitted to the main body skeleton 401 so that the front and rear guided members 433 and 434 fit with a small gap therebetween. (FIG. 99) so that the paper feeding unit 406 can move smoothly within the restricted range (FIG. 95). Further, a moving motor 410 for accurately moving the paper feeding unit 406 in the vertical direction is attached to the main body skeleton 401 via a motor mounting bracket 413, and the moving motor 410 and the paper feeding unit 406 are connected by two front and rear cables 415. The connection movement is performed (FIGS. 90 and 91).

An intermediate conveying means for conveying the sheet 99 sent from the paper feeding unit 406 into the image forming apparatus 2 is provided between the paper feeding unit 406 and the right exterior 405 in the paper feeding device 1. Have been. As shown in FIGS. 94 and 95, the intermediate conveyance means includes three electrostatic conveyance belts 419 having a large thickness, a driving roller 417 provided below, a discharging roller 418 provided above and a charging charger 4 provided above.
A vertical transport unit 416 including a drive motor 407 for driving the paper feed unit 406 is provided, which is fixed to the main body skeleton 401 holding the paper feed unit 406. Reference numeral 16 denotes a front cover.

The main body skeleton 401 is a structure 40 having four sides.
A right exterior 405 is fixedly formed on the sheet feeding device 2, and is attached to the upper and lower two locations on the back side of the sheet feeding device 1 by a hinge 421 so as to be freely opened and closed. A handle 422, a hook (not shown) attached to the handle, and a lock (not shown) for locking the hook are provided on the front side of the right exterior 405. These form a sheet feeding unit opening / closing section 400.

The paper feeding unit opening / closing section 400 always locks a hook attached to the handle 422 by a tension spring (not shown) via a lever (not shown) so that it cannot be opened and closed from the outside. But,
(1) When an operation failure occurs for some reason while a sheet in the sheet storage unit is being moved to another sheet storage unit,
(2) While the sheet is being supplied from the sheet feeding device to the image forming apparatus,
When a paper feeding failure occurs due to some factor, (3)
When a malfunction occurs in the image forming apparatus or the automatic document feeder for some reason, a solenoid (not shown) directly connected to the lever operates to release the lock of the hook and open the sheet feeding unit opening / closing section 400. I do. And
The paper feeding unit 406 cannot be opened except at the time of occurrence of the above three inconveniences, thereby preventing a user or the like from inducing a malfunction. In addition, when the above three problems occur, the sheet 99 generally has to be removed because the sheet 99 exists in the transport path. Then, when the user pulls the handle 422 of the sheet feeding unit opening / closing section 400,
The sheet feeding unit opening / closing unit 400 can be opened in one step, so that the subsequent processing can be performed quickly and the original copy operation can be immediately returned. In addition, replacement of consumable parts of the sheet feeding unit 406 and the vertical transport unit 416 by a service person or the like can be performed in the same manner at the time of maintenance, so that it is possible to reduce time, which is a guide for labor costs borne by companies and users, and to reduce costs. Contribute to reduction.

In the different-size multi-stage paper feeding system, when the sheets 99 in the sheet storage unit 270 arbitrarily selected are supplied to the image forming apparatus 2 one by one by the paper feeding unit 406, the sheet storage unit Since the sheet stacking tray 246 remains fixed in the vertical direction, the sheet feeding unit 406
Changes the vertical position according to the remaining amount of sheets on the tray. Separately, the sheet storage unit 270 is provided with a sheet regulating wall on four sides, that is, a front end and a rear end in the sheet feeding direction and two side surfaces parallel to the sheet feeding direction, so that the sheets on the tray fall within a predetermined range. I have. However, in this embodiment, since the sheet storage portion 270 is not provided with the sheet front end reference wall, the sheet front end reference wall 49 is provided on the sheet feeding unit 431 side.
3 (FIGS. 88, 96, and 97). The sheet leading end reference wall 493 is provided on the sheet storage unit 270 side of the separation roller unit 450 and on the lower separation roller 452 side of the separation roller unit 450. However, in the paper feeding unit 406, the calling rotor 436 and the feed roller 45 that cannot maintain their original shapes due to wear and deterioration over time.
1, and a separation roller 452. When the quality of these rollers becomes unsatisfactory due to wear or deterioration, it is desired that the rollers can be easily replaced with new rollers in a short time. However, by providing the sheet leading end reference wall 493 in the sheet feeding unit 406, the periphery of the separation roller is blocked, so that when the quality cannot be satisfied due to abrasion or deterioration, it cannot be easily replaced. Therefore, as shown in FIG. 96, the fulcrum 48 is
9, a fulcrum 489 is rotatably supported by the sheet feeding unit main body 431, and the sheet front end reference wall 493 is made of a magnetic material, and a portion of the sheet feeding unit main body 431 corresponding to the upper portion of the sheet front end reference wall 493. Is provided with a magnet 490. In this case, the relationship between the sheet leading edge reference wall 493 and the magnet 490 regulates the sheet 99 stored in the sheet storage unit 270 when the sheet leading edge reference wall 493 comes into close contact with the magnet 490, and the sheet leading edge reference wall 493.
When the magnet 490 is released from the attraction of the magnet 490, it falls down to the side opposite to the separation roller. The rotation support structure between the sheet leading edge reference wall 493 and the sheet feeding unit main body 431 may be designed as long as the sheet leading edge reference wall 493 is rotatably supported with respect to the sheet feeding unit main body 431. Various modifications are possible.

With this configuration, when the separation roller 452 is replaced, the sheet leading edge reference wall 493 is required.
Is pulled toward the anti-separation roller side, and the sheet end reference wall 49 is pulled.
By detaching the magnet 3 from the magnet and rotating it about the fulcrum 489, the separation roller 450 is exposed so that the replacement work can be easily performed.

In the case of not being configured to be rotatable in this way, as shown in FIG. 97, the sheet leading end reference wall 493 is attached to the sheet feeding unit main body 431 by screws 491, and can be easily removed when the separation roller 450 is replaced. You may do so.

Next, the operation of moving the paper feed unit will be described.

Since the single sheet feeding unit 406 covers all the sheet storage sections 270a to 270i in the sheet feeding apparatus 1, it is necessary to detect the position when moving up and down. Accordingly, a filler 494 is provided for each stage in the sheet feeding unit opening / closing unit 400, and a sheet feeding unit position detection sensor 492 is provided in the sheet feeding unit 406, and the sensor 492 from the lowest position, which is the home position, is provided. Filler 49
The position of the paper feed unit 406 is recognized based on the number obtained by cutting four (FIG. 90).

The positional relationship between the sheet storage unit 270 and the sheet feeding unit 406 when the sheet feeding unit position detection sensor 492 cuts the filler 494 is such that the calling roller 436 is set at the lower limit position 444 (FIG. 84 (a)). ) And the sheet feeding unit 40 so as to maintain a certain constant height common to all the stages where the call roller 436 does not touch the uppermost sheet 98.
A filler 494 is provided for the sheet feed unit position detection sensor 492 of FIG. 6 (FIG. 90).

At the bottom of the home position, another filler 49 is provided immediately before the filler 494 at the regular position.
4 and turn off the paper feed unit position detection sensor 492 earlier than the regular sensor-on time,
It informs that the position where the next filler 494 is cut is the home position. FIG. 92 shows a timing chart for this detection.

The remaining amount of sheets in each sheet storage section 270 is
When the sheet feeding unit 406 raises the pressure holding plate 468 of the pressure lever 453 by the same amount as the amount of movement that has been lowered from the standby position at that level until the sheet upper limit detection sensor 480 of the call roller 435 is turned on, The amount of rotation of the pressure drive lever shaft 456 is detected by the sheet remaining amount detection sensor 482 using the encoder 471 provided in the drive unit (FIG. 87). Also, at the time of paper feeding, the paper feeding unit 406
In the mode in which the sheet feeding unit 406 performs the operation without using the pressure lever 453, the sheet upper limit detection sensor 480 of the call roller 435 is turned on from the standby position of that stage.
The amount of movement that has decreased until the drive shaft 413 is moved from the feed unit movement motor 410 via the gear train.
(FIG. 91).

Next, the relationship between the control modes of the image forming apparatus according to the embodiment will be described. Hereinafter, the basic configuration of the system will be described.

FIGS. 100 and 101 are block diagrams of a control system of the image forming apparatus according to the embodiment. These two figures constitute one control system.

In FIG. 100, a control unit (controller 600) operates a central processing unit (hereinafter, referred to as a “CPU”) 601, a timer 602, and a CPU 601 constituting a micro computer for controlling the copying machine main body. R that stores fixed data such as program data
OM603, set flags of various modes, set number of sheets,
Volatile RAM 6 that temporarily stores temporary data such as binding margins and loses the data when the power is turned off.
04. Stores process setting data, logging data such as the number of jams, the number of serviceman calls, the number of sheets passed, and the size data of each sheet storage unit.
Non-volatile RAM 605, CP
The I / O 606 includes an U / 601, an operation unit 610, a copy process unit 613, a paper feed control unit 620, and an I / O 606 that controls an interface with the sensor unit 630. The I / O 606 controls the entire copy sequence based on a control program stored in the ROM 603.

The CPU 601 includes an operation unit 610 for detecting various displays and various input information from an operator via the I / O 606, a copy process unit 613 for performing image formation such as charging and development, a paper feed control unit 620, It is connected to a sensor unit 630 connected to various sensor groups for detecting copy information, machine state information, and the like.

An operation unit 610 includes a display unit 611 such as a CRT display or an LCD for displaying various messages to the operator, and a key input unit 612 for detecting various input information (print keys, mode keys, etc.) from the operator.
The control output from the copying process unit 613 is sent to each unit 614 that executes the copying process including the charging charger 8 and the developing device 9 described above and controls them.

Further, as shown in FIG.
Reference numeral 20 denotes a sheet feeding unit driving unit 621 that drives a sheet feeding unit moving motor that moves the sheet feeding unit up and down; an end fence driving unit 622 that drives an end fence driving motor that moves the end fence; A paper feed / transport drive unit 623 that drives a paper feed / transport drive motor that drives each roller related to the transport and electrostatic transport failure,
A tray drive unit 624 that drives a tray drive motor that handles the movement of the tray; a pressure lever drive unit 625 that drives a pressure lever drive motor that raises the pressure lever during paper feeding and when shifting sheets down. And an end fence drive unit 626 that drives an end fence drive motor that moves the side fence. further,
The outputs of the various sensor groups of the sensor unit 630 are output to the I / O 606
The CPU 601 detects the control sequence via the CPU 601 and executes a copy sequence based on the control program stored in the ROM 603. At this time, with respect to paper feed control such as paper feed and paper end, various signals such as a paper feed operation signal and a paper end processing signal are sent from the CPU 601 to the paper feed control unit 612 via the I / O 606. Paper feed controller 612
Sends a drive signal to each drive unit (not shown) based on these signals, and performs processing such as paper feed and paper end by controlling the drive signal.

Further, the sensor section 630 is provided with a sheet end detection sensor 48 for detecting the presence or absence of a sheet at that stage during sheet feeding.
1. A sheet remaining amount detection sensor 482 that detects the remaining amount of sheets in a stage being fed in several stages, and a sheet feeding unit position detection sensor that detects the number of the sheet feeding by counting from the home position. 492, a sheet leading edge detection sensor 483 for checking conveyance such as whether a sheet is correctly fed when a sheet is fed, a sheet upper limit detection sensor 480 for detecting an upper limit of a sheet bundle on a tray, and an end fence for detecting a position of an end fence. The position detection sensor 357, the sheet detection sensor 394 for detecting the presence or absence of a sheet when the drawer tray is taken in and out, the tray opening amount detection sensor 631 for detecting the open amount when the drawer tray is pulled out in combination with the encoder, and the home position of the tray. Tray standby position detection sensor 632 to detect, human body to detect presence of operator Knowledge sensor 633, the tray sheet feed position detecting sensor 634 for detecting the feed position of the tray, and is configured from the tray driving unit position detecting sensor 635 and the like.

In the above system, a series of CPs
The determination operation of U601 may be stored in the ROM 603 and / or the nonvolatile RAM 605 in advance. This is the same in each control operation described later.

The sheet size is detected by the first-stage sheet storage section 270a. The detection of the lateral dimension of the sheet is performed by the end fence 350. First, in this detection, first, the end fence 350 is moved to the home position. At this time, the filler 354 on the lower side of the rack (not shown) continues to cut the end fence position detection sensor 357 (not shown) while moving, and the sensor is turned off. The horizontal dimension of the set sheet is calculated from the calculated number, and the sheet size is detected by the CPU 601 based on this.

First, the table size (hereinafter referred to as "tbl
size ". (I) is a table for storing sheet size data, replenishment date data, and paper type data as shown in FIG. 102, and tbl size (i) is table data for the i-th sheet storage unit. ing. tbl size (i) is a non-volatile RAM (60
5) Provided above, the data is retained even when the power of the apparatus main body is turned off. Further, in this table, when the sheet 99 is set in the first sheet storage section 270a, the size of the sheet 99 is detected in the first sheet storage section 270a as described above, and the size data is registered. Further, if a sheet is moved between the sheet storage units, tbl s
The sheet size data and the like of size (i) are also changed according to the sheet movement. Hereinafter, sheet size detection and sheet size registration in FIG. 103 will be described with reference to a flowchart illustrating a processing procedure.

First, in step S (103) 0, the CPU 601 determines whether a sheet has been moved from the ith-stage sheet storage unit to the (i + 1) -th-stage sheet storage unit. N
If it is o, the process proceeds to step S (103) 2 where the CPU 601 determines whether or not there is a sheet supply in the first-stage sheet storage section 270a. If No, the mode is out of the scope of this mode, so that the mode is reset and the process exits from this mode and ends. Yes
If so, proceed to S (103) 3 steps or less, tbl si
At ze (i), the sheet size data and the like detected by the first-stage sheet storage section 270a are registered.

Next, in step S (103), it is determined whether a request for sheet replenishment date registration has been made. Also,
In step S (103), it is determined whether or not there is a request to register the paper type data of the supply sheet. Then, according to these conditions, S (103) 5, S (103) 7, S
(103) Steps 8 are executed. That is, tbl
In step S7, sheet size data and replenishment date data are added to tbl size (1), which is table data of the first-stage sheet storage unit, of size (i).
It is registered as shown in the column of l size (1). And
This mode ends when the registration of each data is completed.

On the other hand, if it is determined in step S (103) 0 that the sheet has been moved from the ith-stage sheet storage unit to the (i + 1) -th-stage sheet storage unit, the result is Yes, ie, the (i + 1) -th-stage sheet storage unit is If the sheet is moved between the sheet storage units because of the paper end, the predetermined sheet size data and the like of the table tbl size are also updated according to the sheet movement (S (103) ) 1 step). Table tbl siz
FIGS. 102 (a) and 102 (b) show how data is updated in e. If a sheet is moved from the second-stage sheet storage unit 270b to the third-stage sheet storage unit 270c, tbl
The table data of size (3) is tbl size
It will be rewritten by the data of (2). Further, the data of tblsize (2) is cleared by 0 because the second-stage sheet storage unit is empty.

Even when a sheet is moved between the sheet storage units by this operation, the predetermined sheet size data and the like in the table tbl size are also updated according to the sheet movement, so that the CPU 601 The sheet size of the sheet storage unit 270 is the data table tbl.
It can be correctly recognized by referring to the size.

[0171]

As is apparent from the above description, the present invention having the above-described structure has the following effects.

In other words, according to the first aspect of the present invention, when the paper end detecting unit detects the recording sheet storage stage in the paper empty state, the size detection unit detects the size of the recording sheet stored in the recording sheet storage stage. Is detected, the side fence drive control means drives and controls the side fence drive means in accordance with the detected size, and moves the side fence to a position corresponding to the size of the recording sheet. This allows the operator to replenish sheets simply by replenishing the recording sheet in the uppermost recording sheet storage stage, so that the operator can easily replenish sheets without taking a cramped posture, such as bending down. It is possible to improve the operability at the time of replenishing the seat.

According to the second aspect of the present invention, the operation state of the sheet replenishment means is detected by the replenishment operation detecting means, and if the result of the detection is the replenishment, the locked state of the side fence is released, and the replenishment is performed. If not, the position of the recording sheet size is held and the storage position of the recording sheet is regulated, so the lock of the side fence is released only when the uppermost recording sheet storage stage is in a state of replenishing the recording sheet. Sheet can be easily supplied. Thus, the operator can easily replenish the uppermost sheet storage tier without bending down when replenishing the recording sheets, and can improve operability when replenishing the sheets.

[0174]

[Brief description of the drawings]

FIG. 1 is a schematic configuration diagram illustrating an entire system of an image forming apparatus according to an embodiment.

FIG. 2 is a perspective view schematically illustrating a drawer tray in the sheet feeding device.

FIG. 3 is a front view of the sheet feeding device showing an installation position of a drawer tray.

FIG. 4 is a plan view showing a state where a drawer tray is pulled out.

FIG. 5 is a front view of one support member viewed from the inside of a drawer tray.

FIG. 6 is a front view of the other support member viewed from the inside of the drawer tray.

FIG. 7 is a plan view showing a lock mechanism of the drawer tray.

FIG. 8 is a main part front view showing the structure of the sheet stacking tray.

FIG. 9 is a main part front view showing another structure of the sheet stacking tray.

FIG. 10 is a main part front view showing a bent state of the sheet stacking tray.

FIG. 11 is a main part front view showing a bent state of the sheet stacking tray.

FIG. 12 is a front view of a main part showing a bent state of the sheet stacking tray.

FIG. 13 is a plan view of a sheet stacking tray.

FIG. 14 is a sectional view taken along line AA of FIG.

15 is a sectional view taken along line BB of FIG.

FIG. 16 is a diagram showing a part of a section taken along line CC of FIG. 13;

FIG. 17 is a diagram showing a part of a section taken along line DD in FIG. 13;

FIG. 18 is a side view of the sheet stacking tray.

FIG. 19 is an enlarged view of a main part of FIG. 14;

FIG. 20 is an enlarged view of a main part of FIG.

FIG. 21 is a main part front view showing a state where an elastic sheet is attached to a sheet stacking tray.

FIG. 22 is a main part front view showing a state where an elastic sheet is attached to a sheet stacking tray.

FIG. 23 is a plan view showing a state where an elastic sheet is attached to a sheet stacking tray.

FIG. 24 is a front view showing a state where a sheet stacking tray to which an elastic sheet is attached is extended.

FIG. 25 is a front view showing a state where the sheet stacking tray to which the elastic sheet is attached is bent.

FIG. 26 is a diagram schematically illustrating a cross-sectional structure of a sheet feeding device viewed from a sheet feeding unit installation side.

27 is a diagram illustrating a mounting structure on the front side of the sheet stacking tray in FIG. 26;

28 is a diagram showing a mounting structure on the back side of the sheet stacking tray in FIG. 26.

FIG. 29 is a perspective view of a main part showing another embodiment of the sheet stacking tray.

FIG. 30 is a perspective view of a main part showing still another embodiment of the sheet stacking tray.

FIG. 31 is a perspective view of a main part showing still another embodiment of the sheet stacking tray.

FIG. 32 is an operation explanatory view showing the operation of the sheet stacking tray.

FIG. 33 is a sectional view showing a mounting position of a tray position sensor for detecting a position of a sheet stacking tray.

FIG. 34 is a schematic configuration diagram showing a movable position of a sheet stacking tray.

FIG. 35 is a perspective view of a main part showing a part of a driving mechanism of the sheet stacking tray.

FIG. 36 is a schematic configuration diagram showing the arrangement of gears and clutches inside the drive unit in the sheet stacking tray drive mechanism.

FIG. 37 is a side view schematically showing a drive mechanism of the drive unit.

FIG. 38 is a plan view of FIG. 37.

FIG. 39 is a side view schematically showing a driving portion of the sheet stacking tray.

FIG. 40 is a plan view of FIG. 39.

FIG. 41 is a perspective view showing the entire image forming apparatus system in a state where the drawer tray is pulled out.

FIG. 42 is a plan view of a drawn-out tray.

FIG. 43 is a perspective view illustrating an entire image forming apparatus system according to another embodiment.

FIG. 44 is an essential part perspective view showing a state in which a drawer tray of the sheet feeding device according to the other embodiment is pulled out.

FIG. 45 is a schematic configuration diagram showing a structure of a drawer tray of a sheet feeding device according to another embodiment.

FIG. 46 is a perspective view showing a structure of a sheet storage section of a sheet feeding device according to another embodiment.

FIG. 47 is a perspective view of a main part showing a state where the drawer tray is pulled out from the sheet feeding device.

FIG. 48 is an essential part perspective view showing a state where the drawer tray is pulled out from the sheet feeding device.

FIG. 49 is a perspective view of a main part showing a state where the drawer tray is pulled out from the sheet feeding device.

FIG. 50 is a main part front view showing a relationship between a claw of a side fence and a sheet stacking tray.

FIG. 51 is an essential part front view showing the operation of the claws of the side fence when the sheet stacking tray has entered.

FIG. 52 is a perspective view showing a structure of a side fence according to another embodiment.

FIG. 53 is a front view of FIG. 52.

FIG. 54 is a plan view of FIG. 52.

FIG. 55 is a schematic configuration diagram showing a mechanism section of an end fence.

FIG. 56 is a main part front view showing the configuration of an eccentricity absorbing coupling when the shaft center of the drive shuff and the shaft center of the drive motor in the mechanism section of the end fence are connected.

FIG. 57 is a partial cross-sectional front view showing an example in which the axis of the drive shuff and the axis of the drive motor in the mechanism section of the end fence are directly connected.

FIG. 58 is a plan view showing an example in which the shaft center of the drive shuff and the shaft center of the drive motor in the mechanism section of the end fence are connected by a gear train.

FIG. 59 is a front view showing an example in which the shaft center of the drive shuff and the shaft center of the drive motor in the mechanism section of the end fence are connected by a gear train.

FIG. 60 is a plan view showing an example in which the shaft center of the drive shuff and the shaft center of the drive motor in the mechanism section of the end fence are connected by a gear train.

FIG. 61 is an enlarged front view of a main part showing a clutch mechanism in a mechanism part of the end fence.

FIG. 62 is an essential part perspective view showing a moving mechanism of the end fence.

FIG. 63 is a front view of a main part showing a moving mechanism of the end fence.

FIG. 64 is a main part front view showing a lock mechanism of the end fence.

FIG. 65 is a front view of a main part showing a conventional example of a lock mechanism of an end fence.

FIG. 66 is a main part front view showing the operation of the conventional example of the lock mechanism of the end fence.

FIG. 67 is a configuration diagram schematically showing a drive mechanism of an end fence.

FIG. 68 is a main part side view showing a configuration between an end fence and a sheet stacking tray.

FIG. 69 is a main part side view showing another configuration between the end fence and the sheet stacking tray.

FIG. 70 is a perspective view of a main part showing a mechanism for moving the end fence.

FIG. 71 is a perspective view of a main part showing a moving mechanism of the end fence.

FIG. 72 is an operation explanatory view showing an operation of the clutch mechanism in the mechanism section of the end fence.

FIG. 73 is an operation explanatory diagram showing an operation of a clutch mechanism in a mechanism section of the end fence.

FIG. 74 is an operation explanatory diagram showing an operation of the clutch mechanism in the mechanism section of the end fence.

FIG. 75 is an operation explanatory view showing the operation of the clutch mechanism in the mechanism section of the end fence.

FIG. 76 is an operation explanatory view showing the operation of the clutch mechanism in the mechanism section of the end fence.

FIG. 77 is a perspective view showing a mounting position of a sheet detection sensor.

FIG. 78 is a flowchart showing a control procedure at the time of sheet supply.

FIG. 79 is a flowchart showing a control procedure in moving the side fence and the end fence.

FIG. 80 is a flowchart showing a control procedure when the end fence moves the sheet.

FIG. 81 is a flowchart showing a control procedure when power is turned on for the end fence.

FIG. 82 is a front view showing a schematic configuration of a sheet feeding unit.

FIG. 83 is a perspective view showing a call roller unit of the sheet feeding unit and a mechanism related thereto.

FIG. 84 is an operation explanatory diagram illustrating an operation of holding a sheet bundle of the sheet feeding unit.

FIG. 85 is a perspective view showing a pressure holding plate of the paper feeding unit and a mechanism related thereto.

FIG. 86 is an operation explanatory diagram showing the operation of the pressure lever.

FIG. 87 is a perspective view showing a main part of a drive mechanism of the pressure lever.

FIG. 88 is a front view showing a main part of the sheet leading end alignment mechanism.

FIG. 89 is a plan view showing a main part of a sheet leading end alignment mechanism.

FIG. 90 is a side view illustrating a schematic configuration of a sheet feeding and conveying unit.

FIG. 91 is an enlarged perspective view of a main part showing a main part of a paper feeding and conveying unit.

FIG. 92 is a timing chart showing detection timing of a sheet feeding unit position detection sensor.

FIG. 93 is a schematic configuration diagram showing a mechanism near a seat end detection sensor mounting position.

FIG. 94 is a perspective view showing a main part of a driving mechanism of the sheet feeding unit.

FIG. 95 is a perspective view of a main part showing a configuration of a sheet feeding and conveying unit.

FIG. 96 is a front view of a main part showing a configuration of a separation roller unit.

FIG. 97 is a perspective view of a main part showing a configuration of a separation roller unit.

FIG. 98 is a side view schematically showing a support mechanism of the sheet feeding unit.

FIG. 99 is a front view schematically showing a support mechanism of the sheet feeding unit.

FIG. 100 is a block diagram showing a part of a basic system of the image forming apparatus according to the embodiment, and forms one system integrally with FIG. 101;

FIG. 101 is a block diagram showing another part of the basic system of the image forming apparatus according to the embodiment, and forms one system integrally with FIG. 100;

FIG. 102 is a diagram illustrating a table for storing sheet size data, supply date data, and paper type data in the image forming apparatus according to the embodiment.

FIG. 103 is a flowchart illustrating a processing procedure for sheet size detection and sheet size registration in the embodiment.

[Explanation of symbols]

 REFERENCE SIGNS LIST 1 sheet feeder 2 image forming device 3 automatic document feeder 99 sheets 246 sheet stacking tray 270 sheet storage unit 350 end fence 406 feeder unit 419 transport belt 600 control unit (controller) 601 central processing unit (CPU) 602 timer 603 ROM 604 Volatile RAM 605 Non-volatile RAM 606 I / O unit 610 Operation unit 611 Display unit 612 Key input unit 613 Copy process unit 620 Paper feed control unit 621 Paper feed unit drive unit 622 End fence drive unit 623 Paper feed / transport drive unit 624 Tray drive unit 625 Pressure lever drive unit 630 Sensor unit

──────────────────────────────────────────────────の Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI B65H 7/04 B65H 7/04 (72) Inventor Tamaya 1-3-6 Nakamagome, Ota-ku, Tokyo Ricoh Company, Ltd. (72) Inventor Masanori Nagayama 1-3-6 Nakamagome, Ota-ku, Tokyo Inside Ricoh Company (72) Inventor Jun Odaka 1-3-6 Nakamagome, Ota-ku, Tokyo Inside Ricoh Company Limited ( 72) Inventor Hiroyuki Taniyama 1-3-6 Nakamagome, Ota-ku, Tokyo Inside Ricoh Co., Ltd. (56) References JP-A-4-283762 (JP, A) JP-A-4-251047 (JP, A) JP-A-64-29873 (JP, A) (58) Fields investigated (Int. Cl. ⁷ , DB name) B65H 1/30 320 B65H 1/04 320 B65H 3/44

Claims (2)

(57) [Claims] A plurality of recording sheet storage stages arranged in a vertical direction; and a side fence provided in an uppermost recording sheet storage stage movable in a direction substantially orthogonal to a recording sheet feeding direction. A side fence driving means capable of moving the side fence and locking at an arbitrary position; a sheet replenishing means capable of replenishing recording sheets only to the uppermost recording sheet storage level; Paper end detecting means for detecting a recording sheet storage stage in an empty state; and, when a paper empty state is detected by the paper end detecting means, a record stored in the recording sheet accommodation stage in which the paper empty state is detected. Controlling the fence driving means to detect the size of the sheet; and controlling the side fence according to the size of the recording sheet detected by the size detecting means. Recording sheet set apparatus having a side fence drive control means for moving the scan, the. 2. A plurality of recording sheet storage stages arranged side by side in a vertical direction, and a side fence provided in an uppermost recording sheet storage stage movable in a direction substantially orthogonal to a recording sheet feeding direction. A side fence driving unit that moves the side fence and can be locked at an arbitrary position; a fence driving control unit that controls the fence driving unit and moves the fence; a sheet supply means capable of replenishing the recording sheet only for a replenishment operation detecting means for detecting an operating state of the seat replenishing means, the detection result of the replenishment operation detecting means, at the time of replenishment before
And a lock state determining unit that outputs a signal to the side fence drive control unit to release the locked state of the side fence and maintain the locked state when the side fence is not replenished.