KR940002851B1 - Image forming method and apparatus therefor - Google Patents

Abstract

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Description

Image recording method and apparatus

1 is a configuration diagram showing an example of an image recording unit of a conventional image recording apparatus.

2 is a diagram for explaining the image recording operation of FIG.

3 is an overall configuration diagram of an embodiment of an image recording apparatus according to the present invention.

4 is an enlarged cross-sectional view of the side surface of the image recording unit of the image recording apparatus of FIG.

5 is a perspective view of the image recording unit shown in FIG.

6 and 7 each show magnetic flux distribution and magnetic force distribution in the vicinity of the recording electrode in the embodiment shown in FIG.

FIG. 8 is a diagram for showing the arrangement of the magnetic field generating unit and the electrode in the embodiment shown in FIG.

Fig. 9 is a sectional view of the side surface of the bottom image recording unit of the second embodiment of the present invention.

10 is a diagram showing a magnetic flux distribution in the second embodiment.

Fig. 11 is a sectional view of the side of the image recording section of the third embodiment of the present invention.

Fig. 12 is a side sectional view of the image recording section of the fourth embodiment of the present invention.

Fig. 13 is a side sectional view of the image recording section of the fifth embodiment of the present invention.

FIG. 14 is a diagram showing the density distribution of magnetic flux generated by the magnetic field generating portion in the fifth embodiment. FIG.

Fig. 15 is a side sectional view of the image recording section in the sixth embodiment of the present invention.

16 and 17 show magnetic flux distribution and magnetic force distribution in the vicinity of the recording electrode in the sixth embodiment, respectively.

Fig. 18 is a side sectional view of the image recording unit in the seventh embodiment of the present invention.

Fig. 19 is a side sectional view of the image recording section in the eighth embodiment of the present invention.

20 and 21 show magnetic flux distribution and magnetic force distribution in the vicinity of the recording electrode in the eighth embodiment, respectively.

Fig. 22 is a side sectional view of the image recording section in the ninth embodiment of the present invention.

Fig. 23 is a side sectional view of the image recording section in the tenth embodiment of the present invention.

Fig. 24 is a side sectional view of the image recording section in the eleventh embodiment of the present invention.

* Explanation of symbols for main parts of the drawings

1: recording member 2: recording paper

3: sliver portion 4: transfer roller

5: recording electrode 6: hopper

7: rotating blade 8: scraper

9: cleaning blade 10: support

11 magnetic field generating unit 12 screw

13: discharge toner container 14: toner

19: drive motor 20: drive motor

21: recording paper cassette 22: pickup roller

27: discharge tray 28: interface

29: main controller 30: motor drive circuit

31: data output unit for driving the recording electrode

32: transfer voltage control circuit

33: paper sensor 34: toner sensor

36 case

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an image recording method and apparatus for forming a toner image by directly applying charge to toner using a magnetic toner, for example, a conductive magnetic toner (hereinafter referred to as toner).

Conventionally, a recording electrode made of a plurality of recording electrode needles is arranged with a small distance isolation from the cylindrical recording member and the member, and magnetic toner is supplied to a region (recording region) formed at the tip of the recording member and the recording electrode. BACKGROUND ART Image recording apparatuses are known in which charge is applied to a toner by applying a recording voltage to a recording electrode needle in accordance with an image, thereby attaching the toner to the recording member to form a visible image of the toner. Such an image recording apparatus is described, for example, in Japanese Patent Laid-Open No. 1-204079.

1 shows a schematic configuration of an image recording unit of the image recording apparatus according to the prior art. As is apparent from the drawing, in the prior art, when the recording voltage is applied to the recording electrode needle 1003 in the recording area to form an image, the recording member 1001 is rotated at the same time, and the recording portion is the recording area. It is intended to be far from. By this rotation, not only the toner (image forming toner) that is charged by application of the recording voltage from the recording electrode needle and adhered by electrostatic force on the recording member, but also does not form other images, i.e., uncharged toner (Non-burn toner) also spills. In the above prior art, in order to remove this non-burning toner, a non-burning toner removing portion having a magnet roll 1004 forming an alternating magnetic field with the sleeve 1003 is provided. That is, the magnet roll 1004 and the sleeve 1007 in which a plurality of different magnetic poles are alternately arranged around are rotated in the direction of the image table, and the non-image toner on the recording member (sleeve) 1001 is removed by the magnetic force of the magnet roll. Aspirated on the sleeve 1004, moved on the sleeve 1005 by the rotation of the sleeve 1004, and the sleeve 1005 is rotated with the non-burn toner attached by the magnetic force of the magnet roll 1006 again. To the hopper 1008.

On the other hand, the image toner is transferred onto the recording paper 1012 when it comes to the position of the transfer roll 1010 by the rotation of the sleeve 1001 in the direction of the arrow.

In the above prior art, a permanent magnet 1002 is provided in the sleeve 1001 to form a toner chain by a positive magnetic field between the electrode 1003 and the sleeve 1001, and as shown in FIG. Likewise, toner chains are formed according to the permanent magnets. However, as shown in FIG. 2, when the magnet roll 1004 is rotated, an alternating magnetic field is generated accordingly, and when the alternating magnetic field acts on the recording area, the magnetic flux of the permanent magnet is dotted with the dotted line ℓ ₂ , ℓ around the solid line ℓ ₁ . _As shown in FIG. ₃ , the position of the toner chain is shifted, so that the contact position between the toner chain and the sleeve 1001 is shifted by the distance m ₁ , m ₂ and the image is disturbed. For this reason, in the above-mentioned prior art, the sleeve 1007 and the magnet roll 1004 are arranged downstream of the recording area and at a distance from the recording area so as not to affect the recording area of the stirring magnetic field.

In this case, since the distance from the recording area to the position where the sleeve 1001 and the sleeve 1007 are closest (the position at which this image toner is attracted to the sleeve 1007) becomes long, it is charged between them. From the image toner, the charge is transferred to the non-image toner, and the non-image toner is charged and attached to the sleeve 1001.

Therefore, on the recording paper, the charged non-image toner adheres thinly to one surface, so-called fog occurs, and the entire image becomes dark, and the outline of the image becomes unclear. In addition, when an electromagnetic force for removing the non-image toner having the strong charged adhesion force is applied, part of the image toner is also removed, thereby lowering the black density of the image.

It is an object of the present invention to provide an image recording method and apparatus which are improved to eliminate the above-mentioned drawbacks of the prior art.

Another object of the present invention is to effectively remove a non-image toner flowing out of a recording area so that an image toner image having a clear image outline, high black density, and no fog can be obtained. To provide.

In order to achieve the above object, according to one aspect of the present invention, an image recording apparatus of the present invention includes an electrode having an electrode needle, a recording medium 1 which is arranged at a predetermined interval from the electrode and is rotatable, and the electrode. A toner supply unit 6 provided upstream of the recording medium rotational direction of the recording medium, for supplying a conductive magnetic toner between the electrode and the recording medium, and a unit 31 for applying a recording voltage according to an image signal to the electrode. And a toner conveying unit (3,103,231) disposed on the downstream side of the rotational direction of the recording medium of the electrode with the electrode and the recording medium at predetermined intervals, each of which is made of a rotatable nonmagnetic material; The magnetic field generating unit (11, 51, 111, 117, 115, 116) is provided to generate a static magnetic field.

According to such a configuration, the magnetic field generating unit overcomes the non-imaging toner flowing out of the microgap portion at the tip of the recording electrode by the gravitational field under the action of the transfer force of the recording member, and immediately at the recording electrode tip in space and time. Since the charge is not transferred from the charged image forming toner to the non-image toner, the toner image having a clear outline, high black density, and no fog is obtained. In addition, since the magnetic field generating unit generates a static magnetic field, the toner chain is not disturbed and a high quality toner image is obtained. Preferably, the image recording apparatus can be downsized by using the toner conveying unit as an endless belt. Preferably, the magnetic force generated by the magnetic field generating unit is corrected for the toner near the electrode and upstream of the recording medium from the electrode in the rotational direction of the recording medium in a normal direction toward the recording medium on the surface of the recording medium. It has magnetic field generating members 216 and 225 for generating a magnetic field.

As a result, the toner is stably supplied to the front end of the electrode, and the toner can be aligned at the gap formed between the recording medium and the recording electrode. As a result, the change of the amount of deposition of the toner and the variation of the amount of deposition due to toner consumption are caused. Since the variation of the toner amount by the electrode portion can be prevented, the toner image density is determined only by the voltage applied to the electrode, and a high quality image is obtained.

An embodiment of an image recording method and apparatus according to the present invention will be described below with reference to the accompanying drawings. In the drawings, elements having the same function are denoted by the same reference numerals.

3 is an overall configuration diagram of an embodiment of the image recording apparatus of the present invention, and FIG. 4 is an enlarged cross-sectional view of the side of the image recording portion of FIG. Hereinafter, the structure of this embodiment is demonstrated using FIG. 3, FIG.

In the hopper 6, a conductive magnetic toner (hereinafter referred to as toner) 14 is deposited and stored, and the lowermost toner is in contact with the recording member 1. The recording electrode 5 comprises an electrode substrate 5c made of a nonmagnetic insulator, and a recording electrode needle made of a plurality of nonmagnetic or magnetic conductors arranged in a column state in the vertical direction on the front end of the electrode substrate 5c. 5b, an insulating nonmagnetic material protecting member 5a for protecting the integrated circuit, and an integrated circuit (not shown) for applying a write voltage to each of the recording electrode needles 5b. In addition, the recording electrode 5 is inclined upstream from the front end thereof.

The recording member 1 on the drum is formed of a nonmagnetic conductor 1a whose base is made of aluminum, for example, and an insulator 1b whose surface is made of, for example, anodized film of aluminum or a coating film of thermosetting resin, It is provided with a gap between the recording electrode needle 5b and approximately 20 to 300 mu m.

The recording member 1 is rotated by the drive motor 20 in the direction of the arrow b shown in FIG. 4 perpendicular to the column direction of the recording electrode needle 5b.

The sleeve 3 is made of a hollow nonmagnetic material, and is rotatably supported on the downstream side in the recording direction with respect to the recording electrode 5 and adjacent to the recording electrode 5, and is driven by the drive motor 19. It rotates in the direction of arrow a shown in FIG.

The magnetic field generating portion 11 is a magnet, for example, a permanent magnet, fixed to the recording apparatus main body in the sleeve 3, and extends in parallel therewith to face the rows of the recording electrode needles 5b. For example, the ferrite magnet YBM-2BD manufactured by Hitachi Metal Co., Ltd. has a saturation magnetic flux density of about 0.4T (4000 gauss), and supplies magnetic flux to the recording electrode needle 5b and the hopper 6. The magnetic field generating unit 11 may be an electromagnet as long as it generates a static magnetic field.

The scraper 8 is in contact with the sleeve 3 on one side, and the other side is fixed to the top of the recording electrode 5 by means not shown. The rotary blade 7 rotates in the arrow c direction by the drive mechanism not shown.

On the outer circumference of the recording member 1, a cleaning roller 9 composed of a transfer roller 4 for pressing the recording paper 2 against the recording member 1, and a flexible member contacting one side on the recording member 1; The support 10 which supports the cleaning blade 9 is provided.

In the discharge toner receiver 13, a screw 12 that rotates by a drive mechanism (not shown) is provided. The toner hopper 6 deposits the toner 14 and its lower surface is the recording member 1, so that the toner reflection force generated by the rotation of the recording member 1 and the magnetic attraction force generated by the magnetic field generating unit 11 are Then, the toner 14 stably flows out from the gap between the recording electrode 5 and the recording member 1 on the downstream side of the hopper 6.

At this time, a write voltage according to an image signal is applied from the write electrode driving data output unit 31 to the plurality of write electrode needles 5b from the integrated circuit for driving, and thus the toner present in the gap portion ( A charge is selectively applied to 14, and an electrostatic attraction is generated to the charged toner to which the charge is injected, and is attached to the recording member 1 to form the image forming toner 14a.

The non-image toner to which no charge is injected, when passing through the gap portion by the two forces, the toner conveyance force and the magnetic attraction force, by the magnetic attraction force that overcomes the gravitational disturbance from the magnetic field generating unit 11, arrow C As shown in the figure, the magnetic field generator 11 is made to make an emergency.

The non-burning toner 14b is sucked into the first sleeve 3 by the suction force of the magnetic field generating unit 11, is conveyed in the direction of the arrow a by the rotation of the sleeve 3, and the scraper ( 8) is moved onto the scraper 8 and recovered in the hopper 6. At this time, the rotary blade 7 rotates in the direction of the arrow e to promote the conveyance of the non-image toner 14b onto the scraper 8.

The charging toner 14a for forming an image is transferred onto the recording paper 2 by the pressing force of the transfer roller 4 to form an image.

Here, the non-transfer toner 14c remaining on the recording member 1 without being transferred is removed from the recording member 1 by the cleaning blade 9 and dropped and deposited in the discharge toner receiver 13 by gravity. Then, by the rotation of the screw 12, the waste toner box is recovered.

In FIG. 3, the transfer voltage control circuit 32 is for exerting a coulomb force between the recording paper 2 and the toner of the recording member 1.

The recording paper 2 is housed in the recording paper cassette 21, and is separated and conveyed one by one by the pickup roller 22 rotating in the counterclockwise direction by the drive moker 19. The pickup roller 22 is provided on the mounting shaft via a one-way clutch. When the shaft is driven in the counterclockwise rotation direction in the drawing, the roller is also driven in the counterclockwise rotation direction, and the roller is half the counterweight when the shaft is not driven. The clockwise rotation direction is free to rotate. Then, the recording paper passes between the paper guides 23a, and is driven by the driving motor 20 in contact with the timing roller 24a and the timing roller 24a that rotate in the counterclockwise direction in the drawing. It is nipped and conveyed by the timing roller part which consists of a). In this timing roller portion, the rotational circumferential speed of the recording member 1b and the conveyance speed of the recording paper are made to match. The recording paper which has passed through the timing roller portion passes between the paper guides 23b and reaches the transfer portion. The recording paper passes between the transfer roller 4 and the recording member 1, and the toner image is transferred. The recording sheet after toner transfer passes between the sheet guides 23c and is conveyed to the fixing unit. The fixing unit includes a heat roller 25a incorporating a heater (not shown) in this embodiment, and a bottom roll 25b provided to press the heater, and the heat roller 25a is driven by a drive motor 20 to rotate. do. When passing through the fixing unit, the toner on the recording paper becomes a permanent image. Thereafter, the finished paper passes between the paper guides 23d and passes between the paper discharge rollers 26a and h to reach the paper discharge tray 27. The discharge roller 26a is driven to the drive motor 20 via the heat roller 25a. The discharge roller 26b is a driven roller.

The control unit in this embodiment performs data exchange such that the interface 28 for inputting / outputting data to / from an external device and the input character code or figure data can be input to the recording electrode needle 5b, or not shown. The recording data is written by the main controller 29 that manages the operation buttons and controls the entire image recording apparatus, the motor drive circuit 30 that drives the drive motors 19, 20, and the print data created by the main controller 29. A data output unit 31 for driving a recording electrode output to the needle, a transfer voltage control circuit 32 for applying a transfer voltage to the transfer roller 4, a plurality of paper sensors 33 provided on a recording paper conveying path, and a hopper And a toner sensor 34 provided near the gap between the inner and recording electrode tip portions and the drum. Incidentally, the control part is actually housed in the case 36 having the dustproof leg 35, but is described outside the case for convenience in FIG.

5 is a perspective view of the image recording section of FIG.

6 and 7 show the calculation results of the distribution of the magnetic flux in the vicinity of the recording electrode and the distribution of the magnetic force represented by the vector by the magnetic field generating unit 11 of the embodiment of FIG. 4, respectively. In the figure, the 0 marks indicate the calculation points every 1 mm in the vertical direction, the direction of the line segments extending there from indicates the direction of the magnetic flux and the magnetic force, the length of the line segments indicates the magnitude thereof, and the diameter of the 0 mark Each step grows four times in size.

In this case, the magnetic force represents the force that the magnetic field acts on the toner particles when the toner particles are present in the space with a gravitational acceleration of 1 G (9.8 cm / s ² ). The toner used in the calculation was a magnetization amount of 50 emu / g (5 × 10 ⁴ amp / mg). When the toner magnetization amount was larger than this value, the magnetic force acting on the toner increases, and when small, the magnetic force decreases.

The magnetic field distribution and magnetic force distribution in FIGS. 6 and 7 bring the following advantages to the image recording apparatus of the present invention.

The toner 14 is chained together in the direction of the magnetic flux shown in FIG. 6 in which the magnetic field generating portion 11 is generated in the hopper 6. The toners bonded in a chain form are separated from the front end of the recording electrode 5 by the conveying force of the recording member 1, and the magnetic field generating portion 11 is released even when a part of the chains is loosened. By the magnetic force shown in FIG. 7, in which 7) is generated, new rows of toner are attracted to the recording electrode 5 side in the direction of the magnetic force, so that the recombination on the chain of the toner is performed quickly.

The toner 14 is stored in an irregular amount in the toner hopper 6, but the toner flows out from the tip of the recording electrode stably by the above-described action.

The non-imaging toner flowing out from the tip of the recording electrode 5 has a large portion of the non-imaging toner from the recording electrode 5 directly below the recording electrode 5 by the magnetic force of the magnetic field generating portion 11 shown in FIG. It starts to fly and is completely removed by the magnetic force of the magnetic field generating portion 11 which is strengthened by the rotation of the recording member 1.

According to this embodiment, the removal of the non-image toner is performed immediately, so that there is no transfer of charge from the charging toner forming the image, and the image outline is clear, the black density is high, and a high-fog toner image is obtained. There is a number.

In addition, according to the present embodiment, since the magnetic absorption input stronger than the gravity acceleration is always applied to the tip of the recording electrode 5, the toner 14 is not always downstream of the tip of the recording electrode 5. You can record from.

In addition, since the non-imaging toner is removed by the branch generating portion at the tip of the recording electrode 5, the removal force can be set to a uniform force in the recording width direction than the removal force by the vacuum source or the air source. You can do it with a simple device.

Here, the angle of the magnetic flux 11a at the tip of the recording electrode 5 shown in FIG. 6 is inclined approximately 10 degrees from the surface on the recording member 1 upstream with respect to the normal of the surface of the recording member 1. Lost In order to obtain a clear image, as shown in FIG. 6, the angle of the magnetic flux needs to be within ± 45 ° with respect to the normal of the recording member 1, and in order to obtain a higher image quality, it is preferable to be within ± 15 °. Do.

The magnetic field generating unit 11 that satisfies the above conditions and stabilizes the toner conveyance in the hopper, as shown in FIG. 8, has a distance between the magnetic poles of a pair of magnetic poles that supplies the strongest magnetic field to the tip of the recording electrode 5. 1 ₁ ) (1 ₂ ) connecting the magnetic pole ends on the recording electrode 5 side with the tip of the recording electrode 5 is shorter (1 ₁ > 1 ₂ ) and the recording electrodes connecting the paired magnetic poles as indicated by the dotted lines. The straight line extending in the direction does not intersect with the recording member 1, or when it intersects, the position thereof is preferably upstream of the recording direction than the tip of the recording electrode 5. Therefore, the magnetic field generating part 11 may be arrange | positioned so that rotation or movement is possible in the direction shown by the arrow in FIG.

In addition, the magnetic force 11b at the tip of the recording electrode 5 shown in FIG. 7 exhibits a value of approximately 13 G (130 m / sec ² ). However, when this magnetic force becomes excessive, the amount of the image forming charge toner at the tip is exceeded. In comparison, the amount of non-image toner increases, so that charge transfer from the charged toner directly under the electrode to the non-image toner may occur, resulting in deterioration of the recording image, and the magnetic force 11b at the tip of the recording electrode 5. Is preferably 50 G (500 m / s ² ) or less.

On the other hand, in order to sufficiently remove the non-image toner from the recording member and to obtain a high-quality image without fog, it is preferable that the magnetic force is stronger. In this embodiment, the shortest distance between the recording member 1 and the magnetic field generating portion 11 is shortened with respect to the shortest distance between the recording electrode 5, the tip and the magnetic field generating portion 11, so that the tip of the recording electrode 5 is shortened. While preventing an excessive increase in the magnetic force, the magnetic force on the recording member 1 is increased to sufficiently remove the non-image toner, thereby obtaining a high quality toner image.

According to this embodiment again, as shown in FIG. 8, since the recording electrode 5 is inclined with respect to the normal of the recording member 1 so that the tip of the recording electrode 5 is located downstream, the recording electrode 5 The space on the downstream side made by the cylindrical recording member 1 can be enlarged. In other words, the angle formed by the tangent of the recording member 1 can be increased to θ _e > 90 °.

Since the space portion extended to the downstream side allows the first magnetic field generating portion 11 embedded in the cylindrical sleeve 3 to be disposed close to the tip of the recording electrode 5, even by the small magnetic field generating means, The required magnetic force can be obtained at the tip of the recording electrode 5.

9 is a side cross-sectional view of the image recording section of the second embodiment, and a difference from the first embodiment shown in FIG. 4 is that the second magnetic field generating section 15 is added again. In other words, the second magnetic field generating portion 15 is composed of, for example, a ferrite magnet having a saturation magnetic flux density of 0.4T. The second magnetic field generating portion 15 has a magnetic pole opposite to the magnetic pole directed to the recording electrode 5 of the first magnetic field generating portion 11 on the upstream side of the hopper 6 in the external recording direction. Are arranged so as to extend in parallel with the rows of the electrode needles 5b. Incidentally, the parts of FIG. 3 other than the image recording section are the same as in the first embodiment, which is also the same in the other embodiments below.

FIG. 10 schematically shows the magnetic flux distribution of the embodiment shown in FIG.

In the second embodiment shown in FIG. 9, the magnetization amount of the toner 14 is large, the magnetic force generated by the first magnetic field generating unit 11 is excessively acted, and the toner chain at the electrode 5 is likely to collapse. This is particularly effective when the recording speed is relatively high and the conveying force of the toner is excessively applied. That is, since the magnetic pole on the recording electrode side of the magnetic field generating portion 15 is different from the magnetic pole on the recording electrode side of the magnetic field generating portion 11, the magnetization force of the magnetic field generating portion 11 with respect to the toner near the electrode is zero. The toner chain becomes good because it is weakened by the magnetic field generating unit 15 of 2. As shown in FIG. In other words, the second magnetic field generating portion 15 reduces the magnetic force of the first magnetic field generating portion in the hopper 6, preferably to the toner 14 of the tip of the electrode 5, as shown in FIG. Further, the magnetic flux density at the tip of the recording electrode 5 is increased.

The relatively increasing magnetic flux density improves the electrical coupling between the toner forming the toner chain connecting the recording electrode needle 5b and the recording member 1, thereby increasing the charge amount of the toner, thereby forming the image forming toner on the recording member. It adheres firmly, enabling high quality toner images. In addition, the physical binding force of the toner is also increased, the toner chain is firm and difficult to be disturbed, resulting in a high quality toner image.

According to this embodiment, the toner conveyance force which causes the toner 14 to flow out from the tip of the recording electrode 5 and the magnetic force generated by the magnetic field generating unit 11 can be adjusted appropriately, so that a higher quality toner image can be obtained.

FIG. 11 shows a third embodiment of the present invention. In the first embodiment shown in FIG. 4, the periphery extending in the column direction of the recording electrode needle 5b is magnetized with a plurality of magnetic poles. A hollow second sleeve 17 made of a cylindrical third magnetic field generating portion 16, a nonmagnetic material surrounding the third magnetic field generating portion 16, and a nonmagnetic plate seated on the second sleeve ( 18) is added. The sleeve 17, the plate 18, extends to face the sleeve 3.

The magnetic force of the third magnetic field generating portion 16 sucks the non-image toner 14d that has not been removed from the recording member 1 by the magnetic field generating portion 11 and attaches it to the second sleeve 17. . The alternating magnetic field of the third magnetic field generating portion 16 that is rotated by the driving portion not shown in the arrow f direction, or the third magnetic field generating portion 16 that is stopped and the second rotating in the opposite direction to the arrow f. The conveyance force of the sleeve 17 moves the toner 14d onto the plate 18 from above the second sleeve 17 in the arrow g direction. The toner 14d on the plate 18 is sucked onto the sleeve 3 at a point where the magnetic force of the first magnetic field generating portion 11 beats the third magnetic field generating portion 16. The sucked toner is conveyed onto the sleeve 3 and recovered to the hopper 6, as described in the description of FIG.

This embodiment is particularly effective when the amount of magnetization of the toner 14 must be set low in balance with the passion deposition performance of the toner 14 and the like. That is, when the magnetic force of the magnetic field generating portion 11 cannot be made larger than necessary due to the limitation of the physical space of the sleeve 3, and sufficient magnetic attraction force is not generated in the magnetic field generating portion 11 for the toner having a low magnetization amount. By the cooperative operation of the magnetic field generating portion 11 and the third magnetic field generating portion 16 from the recording member 1, a higher quality toner image without fog can be obtained.

FIG. 12 shows the fourth embodiment of the present invention, and the magnetic field generating unit 51 is added to the magnetic field generating unit 11 of the first embodiment shown in FIG.

The above-described magnetic field generating portion 51 extends in parallel to the magnetic field generating portion 11 and is not removed from the magnetic field generating portion 11 by adjusting the magnetic attraction force on the recording member 1. ) Is sucked onto the sleeve 3 to obtain a high quality toner image without fog.

In addition, the magnetic force on the sleeve 3 is also adjusted to improve the toner conveyance on the sleeve 3. That is, near the magnet 51, the magnetic force by the magnet 11 approaches the tangential direction of the sleeve 3, and the toner tends to clump. Therefore, the magnetic force is prevented by the magnets 51 in the normal direction of the sleeve 3 to prevent the non-image toner from clogging.

This embodiment provides a more compact image recording apparatus as compared with the third embodiment.

FIG. 13 shows the fifth embodiment of the present invention. The difference from the embodiment shown in FIG. 4 is that the magnetic field generating portion 11 made of permanent magnets having a four-sided cross section has a cylindrical permanent magnet 52. As shown in FIG. Is replaced by. 14 shows the magnetic flux density distribution of the magnetic field generator 52 of the fifth embodiment.

The magnetic field generating unit 52 is a circumferential permanent magnet that is stationarily installed with respect to the image recording apparatus main body, and is a position where the magnetic pole 53 facing the recording electrode 5 and the scraper 8 are in contact with the sleeve 3. It has the same stimulus as the stimulus 54 close to. Further, different magnetic poles are alternately arranged between the magnetic poles 53 and the magnetic poles 54 in the direction opposite to the arrow a in the figure.

This embodiment is particularly effective for satisfactorily carrying the toner on the scraper 8. That is, since the magnetic poles 53 and 54 are the same magnetic poles, the magnetic flux in the vicinity of the scraper 8 is canceled, so that the magnetic attraction force directed to the magnetic field generating unit 52 acting on the toner on the scraper 8 is reduced or Since it disappears, the toner conveyance toward the hopper 6 on the scraper 8 is performed satisfactorily.

Although the number of poles in the figure is seven poles, if the toner on the sleeve 3 can be transported, there is no problem even if the pole number is seven poles or less or seven poles or more.

As described above, according to each of the above embodiments, since the magnetic field generating portion is disposed in the rotating hollow sleeve made of a nonmagnetic material provided on the recording electrode side with respect to the recording member on the downstream side of the recording electrode, a high quality toner image can be obtained.

15 is a side cross-sectional view of the image recording unit in the sixth embodiment of the present invention. In this embodiment, the non-magnetic endless belt 103 is replaced with the cylindrical sleeve 3 in the first embodiment. I used it.

The endless belt 103 can be driven by the belt guide 115 composed of a driving roller 107 and a nonmagnetic material downstream of the recording electrode 5 and adjacent to the recording electrode 5. The driving roller 107, which is supported and rotated by a driving mechanism not shown, travels in the direction of the arrow a shown in the drawing.

The magnetic field generating portion 111 is a permanent magnet fixed to the recording apparatus main body in the endless belt 103, and extends in parallel thereto to face the heat of the electrode needle 5B. For example, the saturation magnetic flux density is about 0.4T. (4,000 Gauss) It is a ferrite magnet (YBM-2BD) of Hitachi Metals Co., Ltd., and supplies magnetic flux to the recording electrode needle 5b and the hopper 6.

In this case, the belt guide 115 may be omitted by making the magnetic field generating unit 111 have a shape corresponding to the endless belt 103.

The toner conveyance magnetic field generating portion 111 is disposed in the endless belt 103, and is disposed upstream of the belt traveling direction with respect to the drive roller 107, and extends in parallel with the magnetic field generating portion 111. The magnetic field is supplied onto the endless belt 103.

Here, the magnetic field generating unit 111 and the toner conveying magnetic field generating unit 117 alternately form different magnetic poles depending on the belt 103, and these may serve as one permanent magnet.

The non-imaging toner, into which charge is not injected by the recording electrode, passes through the gap portion between the electrode 5 and the recording member 1 by the two forces, the toner conveyance force and the magnetic attraction force, to the magnetic field generating portion 111. By the magnetic attraction force to overcome the gravitational field from the toward the magnetic field generator 111 as shown by the arrow (c).

The extraordinary non-image toner 14b is attracted to the endless belt 103 by the magnetism of the magnetic field generating unit 111, conveyed in the direction of the arrow a by the traveling of the endless belt 103, and the scraper 8 Is moved onto the scraper 8 and is recovered in the hopper 6. Here, the toner conveying magnetic field generating section 111 generates a magnetic field for adsorbing the non-imaging toner 14b on the endless belt 103 with respect to the drive roller 107 on the upstream side of the belt running direction, thereby producing a non-imaging toner ( 14b) is made to be able to be conveyed against gravity.

16 and 17 show calculation results of the magnetic flux distribution and the magnetic force distribution by the magnetic field generator 111 of the embodiment of FIG. 15, respectively.

16 and 17 degree display methods are the same as that of FIG.

In this embodiment, similarly to the first embodiment, in the hopper 6, the toner 14 is coupled in a chain shape in the direction of the magnetic flux generated by the magnetic field generating unit 111.

In this embodiment, the shortest distance between the recording member 1 and the magnetic field generating portion 111 is shortened with respect to the shortest distance between the tip of the recording electrode 5 and the magnetic field generating means. The magnetic force on the recording member 1 is increased while preventing excessive increase in the magnetic force, so that the non-image toner can be sufficiently removed to obtain a high quality toner image.

Further, the space portion widened downstream by the recording electrode 5 and the cylindrical recording member 1 arranges the first magnetic field generating portion 111 embedded in the belt 103 close to the tip of the recording electrode 5. Therefore, the above-described necessary magnetic force can be obtained at the tip of the recording electrode 5 even by the small magnetic field generating portion.

Further, according to this embodiment, the non-image toner is conveyed by the endless belt 103 so that the non-image toner is recorded beyond the long side of the recording electrode 5 having a substantially longitudinal cross section even when the volume of the toner conveying portion is reduced. The conveying distance sufficient to enable collection | recovery to the hopper 6 of the upstream of a direction is obtained, and it becomes possible to miniaturize an apparatus.

In addition, according to the present embodiment, since the endless belt 103 is disposed along the surface of the recording electrode 5 in the recording direction side and the surface of the recording member 1, the magnetic field generating portion at the tip of the recording electrode 5 is arranged. Since the magnetic field generating unit 111 can be made small or a magnetic field such as a plastic magnet has a low price and is easy to process, it is possible to apply sufficient magnetic force. It is possible to reduce the size and cost.

FIG. 18 shows the seventh embodiment of the present invention, with respect to the sixth embodiment shown in FIG. 15, in the endless belt 103 and downstream of the magnetic field generating unit 111 in the recording direction. A stationary second magnetic field generating portion 116 is added close to (1) and in which a plurality of magnetic poles are parallel to the recording direction.

In addition, in order to configure the belt traveling system according to the second magnetic field generating portion 116, the conveying magnetic field generating portion 117 is additionally disposed from the belt guide 115. These magnetic field generators 116 and 117 extend in parallel with the magnetic field generator 111. Here, the magnetic field generating section 111, the second magnetic field generating section 116, and the toner conveying magnetic field generating section 117 can also serve as one magnetic field generating means having a plurality of magnetic poles.

This embodiment is particularly effective when it is necessary to set the magnetization amount of the toner 14 to be low due to the balance of passion deposition performance of the toner 14 or the like. That is, the magnetic force of the magnetic field generating unit 111 cannot be made larger than necessary due to the limitation of the traveling system of the endless belt 103, and the magnetic field generating unit 111 generates sufficient magnetic attraction force for the toner having a low magnetization amount. When it is impossible to do so, by the cooperative operation of the magnetic field generating portion 111 and the second magnetic field generating portion 116 on the recording member 1, a higher quality toner image without a fork is obtained.

Since the second magnetic field generating unit 116 is plurally magnetized in the recording direction, the vector component of the magnetic force acting on the non-image toner on the recording member is converted by the rotation of the recording member 1, thereby converting it to the non-image toner. It is possible to generate minute vibrations, so that the non-imaging toner firmly attached to the recording member 1 by intermolecular forces or the like can be effectively removed by minute vibrations.

In addition, since the second magnetic field generating unit 116 imparts an excitation action to the above-mentioned non-image toner in a wide area along the recording member 1, the conventional non-image toner removing means can be removed. The non-image toner firmly adhered to the recording member 1, which could not be obtained, can also be removed, so that a higher quality toner image without fog can be obtained with a simple configuration.

In the sixth and seventh embodiments, the magnetic field generating units 15, 16 or 51 may be selectively added as in the second to fourth embodiments.

19 is a side cross-sectional view of the image recording unit in the eighth embodiment of the present invention. In this embodiment, the sleeve 215 is provided in the hopper again in the first embodiment, and at the same time, the magnetic field generating unit ( 216) For example, permanent magnets are installed. The magnetic field generating portion 216 is opposed to and extends in parallel with the rows of the electrode needles 5b.

In the present embodiment, in the toner hopper 6, the toner 14 is conveyed toward the recording member 1 by the rotation of the sleeve 215 in the direction of the arrow d. Since the magnetic field generating portion 11 and the magnetic field generating portion 216 generate a magnetic force for attaching the toner 14 to the recording member 1 by providing the magnetic pole close to the recording member 1 facing the same magnetic pole, the sleeve The toner 14 on the 215 is attached on the recording member 1. Then, the toner conveyance force generated by the rotation of the recording member 1 and the magnetic attraction force generated by the magnetic field generating unit 11 are obtained from the hopper 6 from the gap between the recording electrode 5 and the recording member 1. The toner 14 is stably spilled to the downstream side of the.

Also in this embodiment, similarly to the first embodiment, the non-imaging toner, in which no charge is injected from the recording electrode 5, passes through the gap portion by the two forces, that is, the toner conveyance force and the magnetic attraction force. By the magnetic attraction force which overcomes the gravitational field from the part 11, it flies toward the magnetic field generating part 11 like arrow c.

20 and 21 show calculation results of the magnetic flux distribution and the magnetic force distribution by the magnetic field generators 216 and 11 of the embodiment of FIG. 19, respectively.

20 and 21 degree display methods are the same as that of FIG.

In this embodiment having the magnetic field distribution in FIG. 20 and the magnetic force distribution in FIG. 21, the following advantages of the image recording apparatus of the present invention are shown.

The sleeve 215 is made of a hollow nonmagnetic material and is in the hopper 6 upstream with respect to the recording electrode 5, in the hopper 6, has a gap with the recording electrode 5, and is close to the recording member 1. And rotated in the direction of the arrow d shown in FIG. 19 by a driving mechanism not shown.

The magnetic field generating portion 216 is relatively small with respect to the magnetic field generating portion 11, is disposed to face the same magnetic pole as the magnetic field generating portion 11 in the sleeve 16, and is parallel to the rows of the recording electrode needles 5b. It extends and is close to the recording member 1, and is fixed to the recording apparatus main body. The magnetic field generating unit 216 is a permanent magnet, for example, a ferrite magnet (YBM-2BD) manufactured by Hitachi Metal Co., Ltd. having a saturation magnetic flux density of about 0.4T (4000 gauss), and the recording electrode needle 5b and the hopper ( 6) Supply the magnetic flux. The magnetic field generating unit 216 may be an electromagnet as long as it forms a static magnetic field.

The toner 14 in the hopper 6 adheres to the sleeve 215 by the magnetic force of the magnetic field generating portion 16 as shown in FIG. Here, since the magnetic field generating portion 216 forms a static magnetic field, the toner 14 is always sucked on the sleeve 215 regardless of whether the sleeve 215 is rotated. The sucked toner is conveyed to the recording member 1 side by the rotation of the sleeve 215. In the vicinity of the upstream side of the recording electrode 5, the magnetic force of the magnetic field generating portion 11 is stronger than the magnetic force of the magnetic field generating portion 216, and thus is attracted from the surface of the sleeve 215 toward the tip of the recording electrode 5. In the vicinity of the upstream side of the recording electrode 5, the toner 14 is aligned on the recording member 1 by the magnetic force directed to the recording member 1. In this case, regardless of the amount of the toner 14 in the hopper 6, a sufficient amount of toner 14 can always be supplied to the tip of the recording electrode 5, so that the toner in the hopper 6 due to toner consumption The amount of toner 14 supplied to the tip of the recording electrode 5 due to the change of the deposition amount of the 14 or the unevenness of the toner deposition amount in the hopper 6 in the arrangement direction of the recording electrode needle 5b. This is not changing. Therefore, since the density of the toner image is determined only by the applied voltage between the recording electrode needle 5b and the recording member 1, a high quality image is obtained.

That is, since the magnetic force in the direction of the recording member 1 acts strongly on the toner by the magnetic field generating portions 216 and 11 near the tip of the recording electrode 5, the toner is stably supplied to the tip of the electrode 5. Therefore, the printing quality can be maintained satisfactorily even at a high speed factor, and the black density can be raised.

Further, in order to obtain high image quality, the magnetic flux density at the tip of the recording electrode 5 is increased, and the bonding force of the toner 14 aligned between the recording electrode needle 5b and the recording member 1 is increased, thereby recording electrode 5b. It is necessary to make good electrical contact between the recording member 1 and the recording member 1. For this purpose, it is necessary to strengthen the magnetic force of the magnetic field generating section 11, but in this case, the force for pulling the toner 14 in the recording direction from the tip of the recording electrode 5 becomes excessive, thereby recording the toner 14. The amount of outflow from the gap formed in the electrode needle 5b and the recording member 1 becomes excessive, resulting in disturbance on the toner image.

The magnetic field generating portion 216 disposed in the hopper 6 has an action of controlling the magnetic force by which the magnetic field generating portion 11 pulls the toner 14 in the recording direction, even when the magnetic flux density is increased. The outflow from the tip of the recording electrode 5 is optimized to obtain a high quality image.

Next, most of the non-image toner flowing out from the tip of the recording electrode 5 starts to fly to the sleeve 3 directly from below the recording electrode 5 by the magnetic force shown in FIG. It is completely removed by the magnetic force which becomes stronger by the rotation of 1).

According to this embodiment, since the toner 14 can always be arranged on the recording member 1 and supplied with the toner 14, the density unevenness (stain) of the toner image can be reduced and at the tip of the recording electrode 5, By controlling the magnetic force of the toner 14, the outflow of the toner 14 from the tip of the recording electrode 5 can be appropriately stabilized, thereby obtaining a high quality toner image.

In addition, since the removal of the non-image toner is performed immediately under the recording electrode 5, there is no transfer of charge from the charged toner forming the image, so that the outline of the image is clear, the black density is high, and the fog is high. A toner image can be obtained.

FIG. 22 is a side sectional view of the image recording section of the ninth embodiment of the present invention, and in this embodiment, the stationary magnetic field generating section (8) in the recording member 1 is used instead of the sleeve 215 and the magnetic field generating section 216 of the eighth embodiment. 226), for example, permanent magnets. The magnetic field generating portion 226 is fixed to the recording apparatus main body and is disposed opposite to the magnetic field generating portion 11 with a magnetic pole opposite thereto.

In this embodiment, similarly to the eighth embodiment, since the strong magnetic force in the direction of the recording member 1 is applied to the toner near the tip of the recording electrode 5, the same effect is obtained.

19 and 22, the embodiments of FIGS. 11 to 13 may be applied.

23 shows a tenth embodiment of the present invention. The difference from the eighth embodiment shown in FIG. 19 is that the sleeve 3 is an endless belt 231 of a nonmagnetic material, and an antistatic voltage for applying a voltage to the antistatic means and the antistatic means by the conductive rubber. The installation means is installed.

The endless belt 231 is supported in such a manner that the endless belt 231 is movable, and is disposed in the belt 231 near the highest value with respect to the gravity direction of the belt traveling system and is rotated by the driving roller 220 extending in the belt 231 width direction. Drive in the direction of arrow a. At the positions opposite to the drive roller 220 with the belt 231 interposed therebetween, the pressure rollers 18 are disposed near both ends of the belt 231 in the width direction, and the belts (at both ends of the belt 231). 231 is pressed against the driving roller 220 to increase the driving force of the belt 231. The pressure roller 218 extends in the width direction of the belt 231 and is rotatably supported. It is connected to the blade shaft 271, and the blade 217 is fixed in the blade shaft 271. The pressing roller 218 and the blade 217 rotate in the direction of an arrow f in the figure by the rotation of the driving roller 220. The tension mechanism 221 is connected to the belt 231 to keep the tension of the belt 231 constant. Further, a sheet-like magnetic field generating portion having a plurality of magnetic poles along the belt 231 from the downstream side of the belt traveling direction to the vicinity of the driving roller 220 with respect to the magnet 11 serving as the magnetic field generating portion, for example, the rubber magnet 219. Is placed.

The toner 14b sucked on the belt 231 by the magnet 11 is conveyed by the running of the belt 231, and moves on the guide 8 by the blade 217 to move in the hopper 6. It is recovered. The rubber magnet 219 applies a magnetic force to the toner 14b on the belt 231 to prevent toner falling from the belt 231.

The belt 231 is a flexible polymer material, and is made of polyamide, polyethylene terephthalate, or the like, or a rubber material of 0.1 mm to 1.0 mm in thickness, preferably 50 μm to 0.1 mm in thickness, and the belt is charged to the recording member ( It is preferable that conductivity is imparted to the surface or the material itself is conductive so as not to disturb the toner image of phase 1).

According to this embodiment, the physical constraints of the arrangement of the magnets 11 are less than that of the case where the cylindrical member is used in the sleeve, and the magnets 11 can be closer to the tip of the recording electrode 5, so that the recording electrode 5 It is possible to increase the magnetic flux density at the tip and to improve the electrical coupling between the recording electrode needle 5b and the toner 14 connecting the recording member 1, thereby enabling a high quality toner image.

On the other hand, the blade 9 disposed upstream of the hopper 6 in the recording direction is conductive and has a reverse polarity with the voltage applied to the recording electrode needle 5b on the blade 9 which is in uniform contact with the recording member 1. The antistatic voltage applying unit 222 for applying the voltage of is connected.

The blade 9 removes the non-transfer toner 14c from the recording member 1 and remains on the recording member 1 by applying a voltage to the recording member 1 by the antistatic voltage applying unit 222. Remove the recording potential.

According to this embodiment, there is no ghost or fog due to the recording potential remaining in the recording member, and a high quality image is obtained.

In this embodiment, the implementations of FIGS. 15 and 18 may be applied.

24 shows an eleventh embodiment of the present invention. The difference from the embodiment shown in FIG. 23 is that the antistatic roller 223 whose surface is made of conductive rubber and is rotatably supported is added.

The antistatic roller 223 is disposed on the downstream side in the recording direction of the blade 9 so as to be rotatable upstream in the recording direction of the hopper 6. The voltage applied to the recording electrode needle 5b and the reverse polarity voltage is applied to the antistatic roller 223 from the antistatic voltage applying unit 222, and the residual potential of the recording member 1 is removed to prevent ghosts and fog. do.

According to this embodiment, since the antistatic roller 223 is also rotated in accordance with the rotation of the recording member 1, there is no wear of the antistatic rubber of the antistatic roller 223, and it can be stabilized for a long time and can perform static elimination. In addition, since the non-transfer toner 14c is removed by the blade 9 on the downstream side in the recording direction of the antistatic roller 223, the toner adheres to the antistatic roller 223 so that the antistatic effect is not unstable. , A high-quality image without fog is obtained.

In addition, you may apply the Example of FIG. 15, FIG. 18 to this embodiment.

According to the eighth to eleventh embodiments of the present invention, since the first sleeve incorporating the magnet is provided in the hopper in which the conductive magnetic toner is deposited, the toner in the hopper is attracted to the sleeve surface by the magnetic field formed by the magnet. The toner is supplied to the gap formed between the recording electrode and the recording member by the inertia force in accordance with the first sleeve rotation, so that the toner is continuously supplied to the recording electrode part continuously despite the uneven deposition amount of the toner in the hopper. An image can be obtained. In addition, since the magnet in the first sleeve is a static magnetic field, there is no influence on the non-charged toner by the alternating magnetic field, so that a small magnetic force can be used and the size of the first sleeve can be reduced. In addition, since the non-image toner can be effectively spilled onto the surface of the second sleeve by the second magnet provided in the second sleeve disposed downstream of the recording electrode, it is adhered to the surface of the recording member electrostatically. The image toner can be distinguished from the image toner, so that the outline of the image is clear, the black density is high, and no fog is obtained.

In addition, the electrostatic magnetic toner remaining on the recording member surface without being transferred can be stably removed from the recording member surface by providing an antistatic mechanism made of the conductive rubber downstream from the transfer portion and decharging the recording member surface. There is an effect of obtaining a high quality toner image without being affected by the toner remaining in the film.

In the tenth and eleventh embodiments, the magnetic field generating portion may be provided in the recording member 1 as in the ninth embodiment.

The antistatic voltage applying unit and the antistatic roller of the tenth and eleventh embodiments are applicable to the first to ninth embodiments.

In each of the above embodiments, the magnetic field generating unit may be a permanent magnet or an electromagnet as long as it generates a magnetic field.

In addition, the image recording section may be configured to combine the features of the embodiments.

Claims (36)

An electrode 5 having an electrode needle; A recording medium (1) rotatably disposed with a predetermined gap with the electrode; Toner supply means (6) provided on an upstream side of the recording medium rotating direction of the electrode, for supplying a conductive magnetic toner between the electrode and the recording medium; Means (31) for applying a recording voltage in accordance with an image signal to said electrode; Toner conveying means (3, 103, 231) on the downstream side of the recording medium of the electrode in a rotational direction, each of the electrode and the recording medium comprising a nonmagnetic material which is disposed with a predetermined gap and is rotatable; And an magnetic field generating means (11, 51, 111, 117, 115, 116) installed inside said toner conveying means and generating a static magnetic field. The magnetic flux in the same direction as the magnetic flux generated by the magnetic field generating means in a gap between the electrode and the recording medium, wherein the recording medium is located upstream of the rotational direction of the recording medium and is located upstream of the toner supply means. An image recording apparatus having a second magnetic field generating means (15) for generating. 3. An image according to claim 2, wherein the magnetic pole on the recording medium side of said first magnetic field generating means (15) provided inside said toner conveying means is an image opposite in polarity with the magnetic pole on said electrode side of said second magnetic field generating means (11). Logger. 2. The second toner conveying means (17) according to claim 1, further comprising: a second toner conveying means (17) which is downstream from the rotational direction of the recording medium, and which is disposed on the downstream side of the toner conveying means with a predetermined gap therebetween, and which is rotatable; 2. An image recording apparatus having a magnetic field generating means (16) provided inside a toner conveying means. 2. The magnetic field according to claim 1, wherein the magnetic force generated by the magnetic field generating means for the toner on the toner conveying means in the vicinity of the recording medium in the toner conveying means is corrected in a normal direction toward the conveying means. An image recording apparatus having a magnetic field generating means (51) for generating a. An image recording apparatus according to claim 1, wherein said magnetic field generating means generates a magnetic force greater than the gravity of toner with respect to toner on said recording medium downstream of said electrode. 2. The magnetic field generating means according to claim 1, wherein the magnetic field generating means has a shorter distance between the magnetic pole ends on the electrode side and the electrode tip than the distance between the magnetic poles of the pair of magnetic poles for supplying the strongest magnetic field to the tip of the electrode. And a straight line extending in the direction of the electrode connecting the pair of magnetic poles does not intersect with the recording medium or, when intersecting, the position is disposed upstream of the electrode tip. An image recording apparatus according to claim 1, wherein said toner conveying means is a cylindrical or cylindrical sleeve made of a non-magnetic body. An image recording apparatus according to claim 1, wherein said toner conveying means is an endless belt made of a nonmagnetic material. 10. The magnetic field generating means according to claim 9, wherein the magnetic field generating means is disposed in a hollow portion surrounded by the paragraph belt, and, on the hollow portion of the endless belt, on the downstream side of the rotation direction of the recording medium from the magnetic field generating means. And a magnetic field generating member in which a plurality of magnetic poles are alternately disposed to face the recording medium in a direction. 2. The magnetic force of the magnetic field generating means according to claim 1, wherein the magnetic force generated by the magnetic field generating means is applied to the toner in the vicinity of the electrode and upstream of the recording medium from the electrode in the rotational direction of the recording medium. An image recording apparatus having magnetic field generating members (216, 225) for generating a correcting magnetic field. 12. The magnetic field generating member according to claim 11, wherein said magnetic field generating member has a hollow sleeve 215 of a nonmagnetic material which is disposed in said toner supply means, and a magnet 216 provided in said sleeve to generate a static magnetic field. Image recording device. 12. The magnetic field generating member of claim 11, wherein the magnetic field generating member has a magnet for generating a static magnetic field disposed inside the recording medium, and the magnetic pole on the electrode side of the magnet is opposite to the magnetic pole on the electrode side of the magnetic field generating means. Image recording device. 2. The electrostatic discharge means (9, 10, 223) made of a conductive rubber in contact with the recording medium on an upstream side of the recording medium of the toner supply means, and means (222) for applying a voltage to the electrostatic discharge means. Image recording apparatus having a. A recording electrode in which a plurality of recording electrode needles are arranged in a column; A cylindrical or columnar recording member that rotates with the recording electrode and a predetermined gap portion; Means for supplying a conductive magnetic toner upstream of the recording member in the moving direction of the recording electrode, and applying a recording voltage to the plurality of recording electrode needles in accordance with an image signal, thereby causing the gap portion to be moved by the movement of the recording member. An image recording apparatus for selectively giving electric charge to the conductive magnetic toner passing through to obtain a string image of a charged toner, the image recording apparatus being downstream of the recording direction in the recording direction, and each of the recording electrode and the recording member; A hollow slab made of a nonmagnetic material spaced apart from a predetermined gap so as to be rotatable; Magnetic field generating means provided in the hollow portion of the sleeve in an arrangement direction of the recording electrodes to generate a static magnetic field; And an rotation means for rotating the sleeve. 16. An image according to claim 15, wherein said magnetic field generating means is a rod-shaped permanent magnet, and generates an image that generates a sufficient magnetic force to attract a non-imaging toner passing through a predetermined gap portion between the recording electrode and the recording member to the outer periphery of the sleeve. Logger. 16. The toner according to claim 15, wherein the magnetic field generating means generates a magnetic force that overcomes the gravitational field with respect to the toner, and adjusts the outflow of the toner from the predetermined gap portion to face the recording member from the tip of the recording electrode. And a magnetic force for attracting the non-image toner having passed through the gap portion on the outer circumference of the sleeve. 16. An image recording apparatus according to claim 15, comprising means for recovering toner circulated in the outer circumference of the sleeve in a hopper. A recording electrode arranged to replace the plurality of electrode needles in the moving direction of the recording member; A recording member moving with the recording electrode and the minute gap portion; A hopper for depositing magnetic toner on the upstream side of the recording electrode in the moving direction, and for supplying the toner to the microgap by moving the recording member; A driver for applying a voltage corresponding to an image to be recorded on the recording electrode and charging a toner part in contact with the recording member; A cylindrical sleeve made of a nonmagnetic material downstream of the recording electrode in a moving direction and provided in a space made by the recording electrode and the recording member; Magnetic field generating means disposed in the sleeve to assist the stable outflow of the toner from the microgap portion and to absorb the non-charged toner immediately after passing through the microgap portion on the outer periphery of the sleeve; And a means for rotating the sleeve. A cylindrical or cylindrical rotatable electrode body provided with a conductor layer on an outer circumferential surface of the conductive nonmagnetic material and having a recording member; A recording electrode having a plurality of recording electrode needles provided to face each other with a small gap between the conductor layer of the electrode body; Toner deposition means provided on an electrode body for supplying conductive magnetic toner to a recording area composed of the recording electrode tip and its dielectric layer; Means for rotating the electrode body; A sleeve made of a nonmagnetic material which is rotatable downstream of the electrode body of the recording electrode and is rotatably installed in proximity to the recording electrode and the electrode body; Disposed in the sleeve to stably supply the toner to the recording area to assist the outflow of the toner to fill the microgap with the toner, and to adsorb the electrostatic force with a predetermined or more constant power with the recording member in the outflow toner; Magnetic field generating means for adsorbing non-imaging toner to the outer periphery of the sleeve; Means for rotating the sleeve to convey the toner adsorbed around the sleeve; An image recording comprising a driver for selectively applying a voltage corresponding to an image to be recorded between the recording electrode and the electrode body, and selectively adsorbing toner in the recording area and in contact with the recording member to the recording member Device. 20. A recording apparatus according to claim 19, wherein a second electrode provided on the recording direction of the hopper and upstream of the hopper in a direction of movement of the recording member such that an electrode facing the recording electrode of the magnetic field generating means and a pole of polarity are directed toward the recording member. An image recording apparatus provided with a magnetic field generating means. 16. The image recording apparatus according to claim 15, wherein unnecessary toner removing means for adsorbing the toner having a weaker adsorption force with the recording member that does not contribute to image formation among the toners on the recording member again is provided on the downstream side in the recording direction than the sleeve. Device. 17. The image recording apparatus according to claim 16, wherein a magnetic field generating means for adjusting a force for sucking the non-image toner to the outer circumference of the sleeve is provided in the slab, apart from the permanent magnet. A rotatable cylinder or columnar recording member having a uniform dielectric layer formed on the outer circumferential surface thereof; A recording electrode having a plurality of electrode needles, the tip of which has a small gap with the outer circumferential surface of the recording member and is uniformly disposed in the axial direction of the recording member; Means for depositing a conductive magnetic toner and supplying the toner to a recording area consisting of the recording electrode tip and the recording member; Means for rotating the recording member; A rotatable sleeve which is downstream of the recording member in the rotational direction of the recording electrode, and which is made of a hollow nonmagnetic material which is disposed in contact with and close to the outer surface of the recording electrode and the recording member; Rod-shaped magnetic field generating means disposed in the sleeve and having a circular cross section; Means for rotating the sleeve; And a driver for selectively applying a potential to each electrode needle of the recording electrode in synchronization with the rotation of the recording member to charge the toner portion in contact with the surface of the dielectric layer in the recording area. An image recording apparatus according to claim 24, wherein a conveying means for conveying the toner encircled on the outer circumference of said sleeve is conveyed to a means for supplying said toner. 27. The magnetic field generating means of claim 25, wherein the rod-shaped magnetic field generating means having a circular cross section is the same as the magnetic pole opposite to the recording electrode and the magnetic pole adjacent to the conveying means, and between the two magnetic poles is different from the other magnetic poles. Image recording apparatus having no stimulus. 16. An image recording apparatus according to claim 15, wherein said sleeve is composed of an endless belt. 28. The unnecessary toner removing means according to claim 27, wherein the toner removing means is disposed in the endless belt and is disposed on the downstream side of the recording direction than the magnetic field generating means and adsorbs the non-imaging toner attached on the recording member to the outer circumference of the endless belt. One image recording device. An image recording apparatus according to claim 28, wherein said unnecessary toner removing means comprises magnetic field generating means having a plurality of magnetic poles in parallel in the recording direction facing said recording member. 16. An image recording apparatus according to claim 15, wherein a hollow first sleeve of a nonmagnetic material that is rotatable is provided in the toner supply means, and a first magnet that generates a magnetic field in the first sleeve. 31. The second magnet according to claim 30, wherein a hollow second sleeve of a nonmagnetic material that is rotatable is provided downstream of the recording member in the recording direction of the recording electrode, and a second magnet generating a static magnetic field in the second sleeve. Arranged image recording device. 32. The image recording apparatus according to claim 31, wherein the second sleeve provided on the downstream side of the recording member in the rotational direction of the recording electrode comprises an endless belt. An image according to claim 30, wherein an antistatic means for contacting said recording member and provided with a voltage applying means for applying a voltage to said antistatic means is provided upstream of the rotation direction of said recording member of said toner supply means. Logger. An electrode 5 having an electrode needle; A recording medium (1) rotatably disposed with a predetermined gap with the electrode; Toner supply means (6) provided on an upstream side of the electrode in the recording medium rotational direction, for supplying conductive magnetic toner between the electrode and the recording medium; An image recording method in an image recording apparatus having means 31 for applying a recording voltage corresponding to an image signal to the electrode, wherein the electrode and the recording medium are located downstream of the rotational direction of the recording medium of the electrode. And toner conveying means (3, 103, 231) each made of a non-magnetic material which is arranged with a predetermined gap and is rotatable, and generates a static magnetic field in the vicinity of the electrode from the inside of the toner conveying means. 35. The method of claim 34, wherein the generating of the static magnetic field comprises: generating a magnetic force that overcomes the field of gravity with respect to the toner, adjusting the outflow of the toner from the gap between the electrode and the recording medium, and Forming a connection state by the toner toward the recording medium from the tip of an electrode, and generating a magnetic force for sucking the non-image toner passing through the gap portion to the outer periphery of the toner conveying means. 35. The magnetic field generating step according to claim 34, wherein the static magnetic field generating step has a step of generating a magnetic force sufficient to attract a non-image toner that has passed through a gap between the electrode and the recording medium to the outer periphery of the toner conveying means. How to record.