JPH0627757A - Toner image formation device - Google Patents

Abstract

PURPOSE:To form toner images on the front and the back of a printed recording body at high speed and certainly by transferring the toner images on first and second recording media to the front and the back of the recording body. CONSTITUTION:One of toner images electro static charge polarities of which are uniformed is transferred to a dielectric belt 19 and made to be a first face toner image 25, and in the same way, the other is made into a second face toner image 18 on a sensitized body 2, continuously. At a transcription part, while a recording paper 26 is sandwiched by a drum with the sensitized body 2 rolled around it and the dielectric belt 19, three of the recording paper 26, the drum and the dielectric belt move at synchronous speed. In this case, the second face toner image 18 is formed on the sensitized body 2, and at the transcription part, the first face toner image 25 and the second face toner image 18 are respectively and simultaneously transferred to the front and the back of the recording paper 2. A transcribed recording paper 29 on both faces of final recording bodies of which the first and the second toner images are transcribed is added with heat by heat rollers 30, 31 and simultaneously fixed.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a toner image forming apparatus.

[0002]

2. Description of the Related Art Conventionally, a number of methods of printing on recording paper and the like using electrophotography, electrostatic recording, and magnetic recording have been proposed. In particular, copying machines using electrophotography and electrophotography and laser scanning have been proposed. A laser printer combined with an exposure method is widely used.

[0003]

However, JP-A-3-22
As disclosed in JP-B-8467, JP-A-55-83070, JP-A-3-221976, and JP-A-3-18182, printing on recording paper is only one side, and USP4, 477, 176 Publication, U
SP4,095,979 describes a method of printing on both sides, but it has drawbacks such as limited types of paper that can be used and complicated mechanism and lack of reliability.

The present invention has been made in view of the above points, and an object of the present invention is to provide a toner image forming apparatus capable of forming a toner image on the front and back sides of a print recording body at high speed and reliably. Is.

[0005]

The above-mentioned object is to form a first toner image on a first recording medium, transfer it to a second recording medium, and form a second toner image on the first recording medium. This is achieved by forming a toner image of No. 1 and transferring these first and second toner images to the front and back of the recording medium.

Further, stable two types of toner images can be obtained on the photosensitive recording medium by measuring the charging voltage and the residual voltage of the photosensitive member and controlling the charging current and the exposure light amount.

Further, the waste of the toner from the developing device used for forming the toner image can be prevented by providing a rotating member upstream and downstream of the developing roll.

Further, in order to collect and use the toner necessary for forming two kinds of toner images in order to eliminate waste,
This can be achieved by mixing two types of toner charged positively or negatively and using an AC bias during development.

Further, in order to form a color image as a toner image and selectively form a color image on the recording medium at a high speed, by driving the belt from the back side of the belt by using an endless recording medium, Can be achieved.

[0010]

Since the above means is provided, it is possible to print on both sides with one sheet of paper.

[0011]

EXAMPLES Next, the present invention will be specifically described by way of examples.

The toner image according to the present invention can be formed on the first recording medium by electrostatic recording, electrophotographic recording, magnetic recording, mechanical imprinting means or spraying. Therefore, the present invention uses these recording methods. The present invention can be applied to printing from a single color to a plurality of colors. In the following embodiments, an example applied to a laser printer in which an electrophotographic recording method and a laser scanning exposure method are combined will be described.

[Embodiment 1] FIG. 1 shows an embodiment of the present invention. In the figure, two types of toner images such as a two-color image are simultaneously transferred and formed on the front and back sides of a recording paper by using a photoconductive photoreceptor as the first recording medium. As shown in the figure, the first recording medium is a drum-shaped substrate 1 on which a belt-shaped photosensitive member 2 is wound. When the photosensitive member 2 is used for a certain amount, it is fed out from the drum-shaped substrate 1. After the use, the drum base 1 is rewound and stored. The surface of the photoconductor 2 on the drum substrate 1 is uniformly corona-charged by the charger 3 as it rotates. The charging device 3 is provided with a grit 4 for controlling the charging voltage.
A high-voltage power supply 5a is connected to the corona wire and a grit power supply 6 is connected to the grit 4. In this embodiment, the photoconductor 2
Are marked as being negatively charged. Then, the laser light 8 emitted from the laser light source 7 is irradiated to form a charge latent image on the photoconductor 2 corresponding to the information to be recorded. At this time, the laser light source 7 is driven by the signal from the recording information source 9. By irradiating the laser beam, two types of charge latent images for forming two types of toner images (for example, two colors) are formed (see FIG. 2, which will be described later), so that the two types of charge latent images are correct and within a certain range. The surface voltage charged by the charger 3 and the light amount of the laser beam 8 are controlled so that the size is made large. Photoconductor 2
Of the surface voltage using the potential sensor 10, the surface voltage V ₀ which non-exposed portion not irradiated with laser light, the surface voltage V _1R sites exposed with the first source, the portion exposed by the second information source At least two of the surface voltage (residual voltage) V _2R are measured, and the controller 11 drives the grid power supply 6 and the laser light source 7 so that V ₀ -V _1R and V _1R -V _2R are within a certain range. And control it. Although each surface voltage changes depending on the developing characteristics described later, V ₀ -V _1R and V _1R -V _2R are approximately equal to each other, and each is approximately ½ of V ₀ and 200.
It is preferably about 500 V. When an organic photoconductor is used as the photoconductor 2, V _2R is 50 to 150 V, and the surface voltage is detected as described above because it changes and fluctuates with use temperature and use time, and V ₀ -V _1R and V _1R -V
By controlling the value of _2R , two types of stable images can be obtained.

Next, the two charge latent images thus formed are developed using two types of toner. For example, two types of toner images are formed using black toner and chromatic color toner, and magnetic toner and non-magnetic toner. Hereinafter, for the sake of explanation, a case where two color toners are used will be described. When black and chromatic color toners are used, it is preferable that the first development is regular development with color toner and the second development is reverse development with black toner in order to prevent image stains due to color mixture and to obtain a sharp black image. A bias power source V13 is connected to the color developing roller 12 of the color developing device, a bias voltage _Vb1 is applied, and positively charged toner is used as the color toner. │V ₀ │ ＞ │
When set to a value of V _b1 │> │V _1R │ (both have negative polarities), the positively charged color toner adheres to a portion having a negative surface voltage larger than V _b1 , and the first latent image becomes visible. Imaged (normal development). Then, the black developing roll 1 of the second developing device
Bias power supply V15 is connected to 4 and bias voltage _Vb2 is applied. A negatively charged toner is used as the black toner. │V _1R │ ＞ │V _b2 │ ＞ │V _2R │
When the values are set to (both have negative polarities), the negatively charged black toner adheres to a portion having a negative surface voltage smaller than V _b2 and the second latent image is visualized (reversal development). In this way, two types of toner images are formed on the photoconductor 2. When a two-component developer including a magnetic carrier and a toner is used as the developer in the above development, the first toner adheres to the peripheral edge of the second latent image due to the peripheral effect of the charge latent image, and the second toner In order to prevent the toner from adhering to the periphery of the first latent image and obtain a toner image with good uniformity, its dynamic developer electric resistance is 10
^{It is 6} to 10 ¹¹ Ωcm, preferably 10 ⁸ to 10 ¹⁰ Ωcm, and the developing gap is 0.5 to 2 mm, preferably 0.7 to 1.5 mm. Further bias V _b1
Alternatively, V _b2 has a frequency of 200 to 5,000 Hz, and its effective value is │V ₀ -V _1R │ or │V _1R -V _2R
It is preferable to superimpose an AC voltage of about 1/2 or less of |.
By doing so, it is possible to obtain a high-density image in which black and color toner images are not mixed with each other and different toner is less attached to the peripheral portion of the image.

2 formed on the photoreceptor by the above development
The different toner images have different charging polarities. Therefore, in order to make the charging polarities of both of them uniform before transfer, the charger 16
To charge the corona. The charging polarity may be either positive or negative, but here, the case of negative charging by the negative high-voltage power supply 17 is shown. In this way, the toner image having the uniform charging polarity is first transferred to the dielectric belt 19 which is the second recording medium to form the first surface toner image 25.
Subsequently, the second surface toner image 18 is similarly formed on the photoconductor. The first surface toner image 25 is transferred to the dielectric belt 19 by the transfer device 20 under the action of the high voltage power supply 21 for transfer, and then the charging polarity is positively inverted by the charging device 22. At this time, a high voltage power supply 24 is connected to the charger 22 by a switch 23. In this way, the first surface toner 25 is obtained. Next, after the recording paper 26 passes under the image sensor 27, the recording paper 26 is shaped and conveyed by the registration rollers 28 and fed to the transfer portion. At the transfer section, the recording paper 26 is sandwiched between the drum around which the photoconductor 2 is wound and the dielectric belt 19, and the three members move at the same speed. The second surface toner image 18 is formed on the photoconductor 2.
Is formed, and the charging polarity is negative, while the first surface toner image 25 is formed on the dielectric belt 19, and the charging polarity is positive. The polarity of the corona charging of the transfer device 20 is positive. Therefore, in the transfer section, the first
The surface toner image 25 and the second surface toner image 18 are respectively formed on the recording paper 2.
6 Transfers to the front and back simultaneously. In this way, the post-transfer recording paper 29 on which the first and second toner images have been transferred to both surfaces of the final recording body is heated by the heat rolls 30 and 31 to be fixed at the same time.

After the transfer to both sides of the recording paper 26, the charge and toner remaining on the dielectric belt 19 actuate the switch 33 in the static eliminator 32 to apply an AC power source 34 to neutralize and neutralize the charge. The cleaner 35 is contacted to remove the residual toner. Thus, the dielectric belt 19 has the following first
A surface toner image 25 is provided for transfer formation. The charge remaining on the photoconductor 2 and the toner are eraser 36.
(AC corona or uniform exposure alone or a combination of both) is applied and then removed by the cleaner 37 and used for the next image formation.

As described above, it is possible to continuously record two types of toner images on the recording paper 26 on both sides.
According to this apparatus, it is possible to record on any one side of the recording paper. That is, one of the first surface toner image 25 and the second surface toner image 18 described above is formed, and the recording paper 26 is formed.
It can be transferred to. Further, when there is already other information or unnecessary print on one side of the recording paper 26 (for example, when printing on the backing paper), the image sensor 27
It is also possible to detect the presence or absence of it and record it only on the necessary surface.

Although it has been described that the potential sensor 10 is used to control the surface voltage of the photoconductor 2, in order to prevent the influence of the change of the sensitivity of the sensor with time, it is preferable to make a comparison adjustment with the reference voltage at any time. In the present embodiment, this can be achieved by forming a drum cap that closes the longitudinal stitches of the photoconductor 2 from a conductor and maintaining this at a constant voltage. This voltage is applied to the potential sensor 1
It is detected at 0 and compared. A constant voltage element 39 and a capacitor 40 are connected to the drum cap 38 to obtain a constant voltage. The leak resistance 41 is a safety resistance for discharging electric charges when performing drum maintenance or the like after printing is stopped.

Although the transfer device 20 is a corona charger in FIG. 1, a roll to which a voltage is applied may be used instead. In this case, since the radius of curvature of the dielectric belt 19 in contact with the drum of the photoconductor 2 can be made small, the recording paper 26 can be smoothly separated from the transfer portion, the voltage of the high-voltage power supply 21 may be low, and Body 2 and recording paper 2
6 has an advantage such as good adhesion with 6. In the present embodiment, two types (colors) of toner images are created by dividing the surface charging voltage of the photoconductor 2 into two equal parts, and two types of toner, positive and negative, are used for normal development and reversal development. It is a method of developing and forming, but it is needless to say that a plurality of types (colors) of toner may be formed on the photoconductor 2 by repeating exposure and development a plurality of times to perform multiple development. In this case, only regular development or reversal development may be repeated, in which case the system of the charger 16 for aligning the charging polarities before transfer can be omitted, but even if the charging polarities of a plurality of types of toner are the same, When the absolute values and distributions are different, it is preferable to recharge before transfer. Further, when two or more types of toner images are formed on the photoconductor 2 by multiple development, the drum is rotated once in this embodiment. However, it may be formed by a plurality of rotations, for example, black, magenta, cyan. When a multi-color image and a full-color image are formed using four colors, yellow and yellow, it is preferable to form the image by four rotations. In this case, the cleaner 37 is of course retracted. Furthermore, in the present embodiment, when two kinds of toner images are formed, two developing devices are used, but a mixture of a positive polarity toner and a negative polarity toner is used as a developer, and a DC voltage is used as a bias voltage. It is also possible to use a single developing device by using the one in which the AC voltage is superimposed (see FIG. 6). Further, in the present embodiment, the photoconductor 2 which is the first recording medium is drum-shaped, and the dielectric belt 19 which is the second recording medium is belt-shaped. However, these are drum-drum-shaped and belt-shaped. -Belt shape, belt shape-
It may be any combination of drums, and the second
The recording medium may be a dielectric, a semi-conductor or a conductor. In the case of a conductor, the bias power supply for transfer is directly connected to this.

FIG. 2 illustrates a state when the two types of charge latent images described in the embodiment of FIG. 1 are formed on the photoconductor. The horizontal axis x is the position, and the vertical axis -v is the surface voltage.
Since it is negatively charged, it is a negative voltage. V ₀ is an unexposed portion, V _1R is an intermediate exposure level, and V _2R is a voltage level at the maximum exposure amount. Potential difference V ₀ formed by intermediate exposure
First information -V _1R, V _1R can be formed at a maximum exposure level
Making a charge latent image of the second information -V _2R. Bias voltage V _b1 of the first developing device │V _b1 │> │V _1R │, bias voltage of the second developing device is set so as to be │V _1R │> │V _b2 │. Therefore, the amount of light must be controlled so that the intermediate exposure level is always between _Vb1 and _Vb2 . Otherwise, fogging will occur in the background of the image. For this, V
Set _1R in use to be substantially half a V ₀ -V _{1 R,} detected by the potential sensor 10 a voltage of at least V _1R, better to control the intermediate exposure amount, preferably V _0, V _It is preferable to detect _1R and V _2R and control the charging ability of the charger 3, the intermediate exposure amount of the exposure light source, and the maximum exposure amount so that these values become predetermined values. The detection by the potential sensor 10 (see FIG. 1 for both) can be performed continuously or at predetermined intervals by utilizing the space between the cut sheets and the outside of the recording area of the continuous sheets.

[Embodiment 2] FIG. 3 shows another embodiment of the present invention. This figure shows a concrete structure of a developing device suitable for the development of the embodiment shown in FIG. One of the problems of a developing device that uses powder toner as a developing method is to provide a device that regularly cleans and maintains the toner scattered outside the developing device to pollute the surroundings, and suctions and collects the scattered toner. There was a need. Further, there is a problem that the printing cost becomes high because the developing device is replaced after a certain period of use. Further, when two kinds of development are performed as shown in FIG. 1, there is a drawback that other toner is mixed in the developing device. The developing device having the structure shown in FIG. 3 eliminates these drawbacks and can be used semipermanently. The developing device 42 of this embodiment uses a two-component magnetic developer composed of a magnetic carrier and a non-magnetic or magnetic toner as a developer. A magnet roll 44 is provided in the developing roll 43 to fix the magnet. The developer is attracted onto the developing roll 43 by the magnetic force and is conveyed to the developing unit by rotation. Screw 45,
Reference numeral 46 is a stirring and mixing member for making the toner concentration in the developer uniform. The developing device of this embodiment has toner seal rolls 47 and 48 that rotate before and after the developing roll. These two seal rolls are attached to the surface of the photoconductor 2 and 0.5-2.
Since they are close to each other with a gap of mm, the toner is prevented from flowing out, the toner is electrostatically and physically adsorbed by this roll, and the toner is returned to the developing device and used again for development. In order to promote electrostatic adsorption, it is preferable to apply a direct current or a voltage obtained by superimposing an alternating current on a direct current from the bias power sources 50a and 50b. This bias power source may be the same as that applied to the developing roll. When a magnetic carrier is used as in this embodiment, it is preferable to install a magnet 49 in the toner seal roll 48 in order to capture the carrier attached to the photosensitive member or the carrier outside the developing device. Further, when a magnetic toner is used as the toner, it is preferable to install a magnet also inside the toner seal roll 47. Further, the positional relationship between the magnetic pole position of the magnet 44 and the toner seal rolls 47 and 48 should be close to the magnetic pole of the magnet 44 as shown in FIG. Thereby, the toner attached to the toner seal rolls 47 and 48 can be removed by the magnetic brush formed of the magnetic poles, and the toner is prevented from being blown out from the inside of the developing device. The toner or carrier attached to the toner seal rolls 47 and 48 can be completely removed by peeling it off with a member such as a blade. The magnetic pole arrangement of the magnet 49 installed in the toner seal rolls 47 and 48 is as shown in FIG.
It is desirable that the magnetic flux has the same magnetic poles as the magnetic poles of the magnet 44 facing each other in FIG. 3 and the magnetic flux density is lower than that, so that the magnetic particles can be efficiently returned to the developing device. In the present embodiment, the magnet 49 in the toner seal roll 48 is provided, but instead of the permanent magnet, a magnetic material having no magnetic pole is arranged at the magnetic pole position of the magnet 49, and magnetic particles are attracted by the induction magnetic action. It may be done. If the developer does not have magnetism, the magnets 44 and 49 shown in the figure are unnecessary, but toner seal rolls 47 and 48 are provided before and after the developing roll 43 as in this embodiment.
By providing the toner, it is possible to prevent the toner from scattering. In the figure, 50c is a bias power source.

[Third Embodiment] FIG. 4 shows still another embodiment of the present invention. The figure shows an example of printing on both sides. The method for forming the first surface toner image 25 and the second surface toner image 18 on the photoconductor 2 is the same as in the case of FIG. 1, but the step of transferring each image to the recording paper 26 is different. First, the toner image 25 on the first surface is transferred onto the dielectric belt 19. This is performed by bringing the dielectric belt 19 into contact with the photoconductor 2 and applying the voltage of the transfer power source 53 to the transfer roller 51 via the switch 52. Be seen. After that, the polarity of the toner is reversed to the positive polarity by the action of the charger 22. Next, the second surface toner image 18 is formed on the photoconductor 2, and at this time, the dielectric belt 1
9 is separated from the photoconductor 2. The recording paper 26 is shaped and conveyed by the registration roller 28, contacts the photoconductor 2 having the toner image 18 on the second surface, and is transferred to the upper surface of the recording paper 26 under the action of the transfer unit 54, the switch 55, and the high-voltage power supply 56. Surface toner image 18
Is transcribed. Subsequently, the lower surface of the recording paper 26 is brought into contact with the dielectric belt 19 having the toner image 25 on the first surface, and the toner image 2 on the first surface is transferred under the action of the transfer device 57, the switch 58 and the high voltage power supply 59.
5 is transferred to the lower surface of the recording paper 26. In this way, toner images can be formed on the upper and lower surfaces of the recording paper. Hereinafter, the fixing of the toner image, the removal of the toner and the electric charge remaining on the dielectric belt 19 and the photoconductor 2 are performed in the same manner as the embodiment of FIG. In the above description, the charging polarity of the first surface toner image 25 is reversed by the charger 22, but this need not necessarily be reversed, and may be omitted or recharged to the same polarity. In this case, the polarity of the high voltage power supply 59 is reversed (in this example, it becomes positive).

[Embodiment 4] FIG. 5 shows still another embodiment of the present invention. In the figure, a full-color image is formed on both sides of the recording body. A belt-shaped photoconductor is used as the photoconductor 2, and a charge latent image formed on the photoconductor is selected and developed one by one from a color developing device group 60 including four developing devices for yellow, magenta, cyan, and black. Then, this is sequentially aligned and transferred to the transfer drum 62 to form a full-color first-surface toner image 25, which is further transferred to the transfer drum 64. For the transfer drums 62 and 64, for example, an aluminum substrate coated with an elastic dielectric is used. To selectively form a toner image of each color on the photoconductor 2, as shown in the figure, the developing device is fixed, and the development selection structure opposed to each color development device is moved from the development selection structure group 61 from the back surface of the photoconductor 2. Let it develop. By doing so, it is not necessary to move the developing device as in the conventional case, and it is possible to increase the speed and reduce the cost of the apparatus. The transfer to the transfer drum 62 is performed by the transfer power supply 63, and the transfer to the transfer drum 64 is performed by selecting the transfer power supply 66 with the switch 65. At this time, the voltage of the transfer power supply 66 is set higher than the voltage of the transfer power supply 63. In this embodiment, the toner polarity during development is negative.

Next, the full-color second surface toner image 18 is formed on the transfer drum 62 in the same manner after removing the toner and the electric charge remaining on the transfer drum A62 by the cleaner 71 and the static eliminator 72. At this time, the transfer power source 66 is set to the non-transfer power source 67 side by the switch 65, and the polarity of the transfer power source is reversed. On the other hand, the charger 68 is operated under the action of the switch 69 and the high-voltage power supply 70 to reverse the charge polarity of the toner of the first surface toner image 25 (from negative to positive). According to this
The first and second surface toner images 25 and 18 are transferred onto the transfer drums 62 and 64.
Each held on top. Then, the recording paper 26 that has been shaped and conveyed by the registration rollers 28 is transferred onto the transfer drums 62 and 64.
The transfer power source transferred to the transfer drum 64 and applied to the transfer drum 64 is changed to the transfer power source 66 side by the switch 65. This allows
The full-color first and second surface toner images 25 and 18 are simultaneously transferred to both surfaces of the recording paper 26. The post-transfer recording paper 29 having the toner images on both sides of the image is simultaneously fixed by the heat rolls 30 and 31, and double-sided printing is obtained. Toner and electric charge remaining on the transfer drums 62 and 64 are removed by operating the cleaner 71, the static eliminator 72, the cleaner 73, and the static eliminator 74, and prepare for the next double-sided printing. Members 71, 72, 73, 74 for removing these toners and charges
Of course, when the normal first and second surface toner images 25 and 18 are not present on the transfer drums 62 and 64, it is not operated. In the above description, the transfer drum 62,
Although 64 is always in contact, the second surface toner image 1
When forming 8 on the transfer drum 62, it is desirable that the transfer drum 64 be separated from the transfer drum 62. In this case, the non-transfer power source 67 may be omitted. In this embodiment, the transfer drum 62, which is the first and second recording medium,
Although both 64 are dielectrics, they may be semiconductors or one of them may be a conductor such as metal. Further, it does not have to be a drum shape, and may be a belt shape or a combination of a drum shape and a belt shape.

The full-color print speed in this embodiment is reduced to 1/4 of the developing process speed because the transfer drum 62 is rotated four times to form a full-color toner image. Four types of developing systems are prepared, and drum-shaped or belt-shaped transfer recording medium (corresponding to transfer drum 62)
If a so-called tandem type in which toner images of respective colors are superposed on the transfer medium is arranged around the sheet, a full-color image can be formed without lowering the printing speed, and this can be printed on both sides of the recording paper.

As described above, double-sided printing can be performed on both sides of the recording medium with one sheet of paper, as in the embodiment described with reference to FIGS. 1 and 4. Although the description is omitted, in any of FIG. 1, FIG. 4, and FIG. 5, when the photosensitive member 2 is exposed by a laser beam or the like to form a latent image, the exposure is started so that the respective surfaces are correctly printed. An information processing mechanism including a memory and a reading circuit is added to the light modulation circuit so that the position can be changed, the right writing and the left writing can be performed.

[Embodiment 5] FIG. 6 shows still another embodiment of the present invention. This embodiment corresponds to the embodiment of FIG.
In contrast to developing two kinds of toner images with two developing devices,
It is developed by one developing device. For the two-color developing device 75, a developer having a color toner charged to the positive polarity and a black toner charged to the negative polarity (consisting of only toner or carrier and toner) is used. Bias voltage is applied. The bias power supply includes a DC bias power supply 76 and an AC power supply 77. The DC bias is not substantially equal to V _1R shown in FIG. 2, and the AC voltage (including pulse) is 200 to 5,000 Hz.
Therefore, it is preferable that the effective value is approximately 1/2 or less of │V ₀ -V _1R │ or │V _1R -V _2R │. By doing so, it is possible to prevent unnecessary toner adhesion due to fogging and edge effects on the background portion. When a two-component developer including a magnetic carrier and a toner is used as the developer, its dynamic electric resistance (resistance when the developer is moving) is 10 ⁶ to
10 ¹¹ Ωcm, preferably 10 ⁸ to 10 ¹⁰ Ωcm, and the development gap thereof is 0.5 to 2 mm, preferably 0.7 to 1.5.
When it is set to mm, good results that a high density image is obtained with less fog can be obtained. As described above, when two toners of positive and negative polarities are mixed to form two-color (two types) toner images, the toner image remaining on the photoconductor 2 or the dielectric belt is collected by a cleaner and developed. It can be returned to the container 75 for use. On the other hand, when using two developing devices, it is difficult to separate and return two types of toner.

In the above-mentioned embodiment, the transfer to the first and second recording media and the transfer of the final recording medium (for example, recording paper) are performed electrostatically, and the fixing to the final recording medium is performed by the heat roll. There is. However, transfer is not limited to electrostatic transfer, and may be adhesive transfer, heat fusion transfer, mechanical sliding or pressure transfer, magnetic transfer (in the case of magnetic toner), or the like. In the case of heat fusion transfer, it is possible to perform the fixing step at the same time. For example, the transfer drums 62 and 64 in FIG. 5 are formed in a belt shape, and if a heating element (heater) is arranged on one or both back surfaces of each belt corresponding to the transfer portion onto the recording paper and is pressed, both surfaces of the recording paper are transferred. Can perform thermal transfer and fixing. Even in this thermal transfer fixing, neither the first recording medium nor the second recording medium need be transfer media.
One may be a latent image forming recording medium such as a photoconductor.
For example, without rotating the photoreceptor of FIG. 1 around the drum substrate, a combination of a belt-shaped dielectric belt and a photoreceptor belt is used to form toner images on the first and second sides, and this is used as recording paper. It is fixed by thermal transfer.

Further, although the powder toner developer is used as the toner image forming means in the above-mentioned embodiments, it can be applied to the case of double-sided printing using the liquid developer.

As described above, according to this embodiment, after the first toner image is formed on the first recording medium, this is transferred to the second recording medium, and the second toner image is further transferred to the second recording medium. Since these two toner images are formed on one recording medium and transferred to both front and back surfaces of another recording medium (recording paper), it is possible to print on both sides with one sheet of paper.

[0031]

As described above, according to the present invention, the first toner image is formed on the first recording medium, the toner image is transferred onto the second recording medium, and the second toner image is transferred onto the first recording medium. Toner images are formed, and these first and second toner images are transferred to the front and back of the recording body, so that it is possible to print on both sides with one sheet of paper, and the toner can be printed on the front and back of the print recording body. A toner image forming apparatus capable of forming an image at high speed and reliably can be obtained.

[Brief description of drawings]

FIG. 1 is an explanatory diagram showing a configuration of a double-sided printing apparatus as an embodiment of a toner image forming apparatus of the present invention.

FIG. 2 is a characteristic diagram for explaining the charge latent image in FIG. 1 and showing the relationship between position and surface voltage.

FIG. 3 is an explanatory diagram of another embodiment of the toner image forming apparatus of the present invention.

FIG. 4 is an explanatory diagram of double-sided printing of still another embodiment of the toner image forming apparatus of the present invention.

FIG. 5 is an explanatory diagram of full-color double-sided printing of still another embodiment of the toner image forming apparatus of the present invention.

FIG. 6 is an explanatory view showing a two-color developing system of still another embodiment of the toner image forming apparatus of the invention.

[Explanation of symbols]

2 ... Photoconductor, 18 ... 2nd surface toner image, 19 ... Dielectric belt, 25 ... 1st surface toner image, 26 ... Recording paper, 30, 31
... heat roll.

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁵ Identification code Internal reference number FI technical display location G03G 15/02 102

Claims (7)

[Claims] 1. A toner image forming apparatus in which a toner image formed on a first and a second recording medium is transferred onto a recording medium to form a toner image, the first image being formed on the first recording medium.
Toner image is formed on the second recording medium, the second toner image is formed on the first recording medium, and the first and second toner images are formed on the recording medium. A toner image forming apparatus characterized in that the toner image forming apparatus is adapted to transfer to the front and back of the toner. 2. The toner image forming apparatus according to claim 1, wherein the toner images transferred to the front and back of the recording medium have different charges and are simultaneously electrostatically transferred. 3. The toner image forming apparatus according to claim 1, wherein the first and second toner images are color toner images transferred to the first and second intermediate transfer media, respectively. 4. A toner image forming apparatus in which a charge latent image based on two different information groups is formed on a photoconductive photosensitive member, the surface voltage of the non-exposed portion and the exposed portion of the photosensitive member is measured, By controlling the charging ability of the charger that charges the body and the light amount of the exposure light source, the surface voltage of the part exposed by the first information source is changed to the surface voltage of the non-exposed part and the part exposed by the second information source. A toner image forming apparatus characterized in that a value between the surface voltage and the surface voltage is substantially constant. 5. A developing roll, a recording medium, and a developing machine are provided,
In a toner image forming apparatus that visualizes a charge latent image or a magnetic latent image using toner, members that rotate upstream and downstream of the developing roll are provided, and flow out of the developing machine along the surface of the recording medium. A toner image forming apparatus, characterized in that a developer is captured and the captured developer is returned to the developing machine. 6. A photoconductive photosensitive member comprising a developing roller, and
In a toner image forming apparatus in which a charge latent image formed on the basis of three different information groups is simultaneously developed with a developer having two kinds of positively or negatively charged toner, a bias voltage applied to the developing roll is A toner image forming apparatus characterized in that a DC voltage having a value between a surface voltage of a non-exposed portion and a surface voltage of an exposed portion of a photoconductor and an alternating voltage of 200 to 5,000 Hz are superposed. . 7. A toner image forming apparatus comprising a developing machine, wherein two or more types of toner images are formed by using an endless belt-shaped recording medium, wherein a plurality of developing machines are fixed in position.
A toner image forming apparatus, characterized in that a developing / non-developing state is selected by driving a specific structure of a development selecting structure group which is installed on a belt-shaped back surface so as to face a developing roll of the developing machine.