JP3630960B2 - Image forming apparatus - Google Patents

Description

【００６２】
尚、かぶりは、以下の方法により求めた。ＴＯＫＹＯ ＤＥＮＳＨＯＫＵ ＣＯ．，ＬＴＤの濃度計ＴＣ−６ＤＳにより転写紙上のかぶり部と画像形成前の転写紙のそれぞれの反射濃度を求め、下記の式、
かぶり濃度（％）＝（転写紙上のかぶり部の反射濃度）−（転写紙の反射濃度）で求めた。
【００６３】
また、画像濃度についてはＸ−ｌｉｔｅ社製の濃度計９４１型を用いて転写紙上画像の反射濃度を測定した。
【００６４】
上記の現像条件にて画像形成を行なったところ、かぶりがなく、即ち表１の評価基準でレベルＢ、画像濃度も１．４以上得られ、ハイライト部のがさつきのない良好な画像が得られた。
【００６５】
実施例２
実施例２においては、図２に示す実施形態の画像形成装置に上述の感光体Ａを用いて、以下の現像条件で画像形成を行ない、転写紙上のかぶりならびに画像濃度の評価を行なった。
【００６６】
・現像条件
現像スリーブ１１は、前述実施例１と同じく、感光体１との距離を５００μｍに設定し、図示しない電源から図１に示したような波形の直流電圧及び交流電圧を印加した。トナーの帯電極性はマイナスとした。図１の波形図にて、
非画像部表面電位Ｖ_Ｄ ＝−６５０Ｖ、
高濃度画像部表面電位Ｖ_Ｌ ＝−２００Ｖ
引き戻し電圧Ｖ_１ ＝＋５００Ｖ、
現像電圧Ｖ_２ ＝−１５００Ｖ、
ブランク電圧Ｖ_３ ＝−５００Ｖ
の条件で、Ｔ_１ 、Ｔ_２ 、Ｔ_３ は、
Ｔ_１ ＝８．０×１０^−５ 秒
Ｔ_２ ＝８．０×１０^−５ 秒
Ｔ_３ ＝８．０×１０^−４ 秒
とした。従って、本実施例においても、前述実施例１と同じく、現像スリーブ１１と感光体１間に発生する最大電界強度が帯電用スリーブ３１と感光体１間で発生する最大電界強度よりも大きくなっている。
【００６７】
以上の現像条件にて画像形成を行なったところ、かぶりが殆ど無く、即ち表１の評価基準でレベルＢ、画像濃度も１．５以上得られ、ハイライト部のがさつきのない良好な画像が得られた。
【００６８】
実施例３
実施例３においては、図２に示す実施形態の画像形成装置に上述の感光体Ａを用いて、以下の現像条件で、画像形成を行ない、転写紙上のかぶり並びに画像濃度の評価を行なった。
【００６９】
・現像条件
現像スリーブ１１は、前述実施例１、２と同じく、感光体１との距離を５００μｍに設定し、図示しない電源から図１に示したような波形の直流電圧及び交流電圧を印加した。トナーの帯電極性はマイナスとした。図２の波形図にて、
非画像部表面電位Ｖ_Ｄ ＝−６５０Ｖ、
高濃度画像部表面電位Ｖ_Ｌ ＝−２００Ｖ
引き戻し電圧Ｖ_１ ＝＋５００Ｖ、
現像電圧Ｖ_２ ＝−１５００Ｖ、
ブランク電圧Ｖ_３ ＝−５００Ｖ
の条件で、Ｔ_１ 、Ｔ_２ 、Ｔ_３ は、
Ｔ_１ ＝８．０×１０^−５ 秒
Ｔ_２ ＝８．０×１０^−５ 秒
Ｔ_３ ＝１．６×１０^−４ 秒
とした。従って、本実施例においても、前述実施例１、２と同じく、現像スリーブ１１と感光体１間に発生する最大電界強度が、帯電用スリーブ３１と感光体１間で発生する最大電界強度よりも大きくなっている。
【００７０】
以上の現像条件にて画像形成を行なったところ、かぶりが殆ど無く、即ち表１の評価基準でレベルＡ、画像濃度も１．６以上得られ、ハイライト部のがさつきのない良好な画像が得られた。
【００７１】
実施例４
実施例４においては、感光ドラムＢを下記の構成とした。即ち、上記の感光ドラムＡの製造で形成した第５層の表面層に代えて、第５層目にポリカーボネイト樹脂に表面抵抗を落とすためにＳｎＯ_２ 等の低抵抗粒子を樹脂２重量部に対し、５重量部分散した２μｍの表面層を有した感光体を用いている。表面抵抗は１０^９ Ωｃｍである。
【００７２】
次に、以下の現像条件で画像形成を行ない、転写紙上のかぶり並びに画像濃度の評価を行なった。
【００７３】
・現像条件
現像スリーブ１１は、前述実施例１、２、３と同じく感光体１との距離を５００μｍに設定し図示しない電源から図１に示したような波形の直流電圧及び交流電圧を印加した。トナーの帯電極性はマイナスとした。図１の波形図にて、
非画像部表面電位Ｖ_Ｄ ＝−６５０Ｖ、
高濃度画像部表面電位Ｖ_Ｌ ＝−２００Ｖ
引き戻し電圧Ｖ_１ ＝＋５００Ｖ、
現像電圧Ｖ_２ ＝−１５００Ｖ、
ブランク電圧Ｖ_３ ＝−５００Ｖ
の条件で、Ｔ_１ 、Ｔ_２ 、Ｔ_３ は、
Ｔ_１ ＝１．０×１０^−４ 秒
Ｔ_２ ＝１．０×１０^−４ 秒
Ｔ_３ ＝２．０×１０^−４ 秒
とした。従って、本実施例においても、前述実施例１、２、３と同じく、現像スリーブ１１と感光体１間に発生する最大電界強度が、帯電用スリーブ３１と感光体１間で発生する最大電界強度よりも大きくなっている。
【００７４】
以上の現像条件にて画像形成を行なったところ、かぶりが若干あった、即ち表１の評価基準でレベルＣ、画像濃度も１．５以上得られ、ハイライト部のがらつきのない良好な画像が得られた。
【００７５】
実施例５
実施例５においては、実施例４の感光ドラムＢを用いて、以下の現像条件で画像形成を行ない、転写紙上のかぶり並びに画像濃度の評価を行なった。
【００７６】
・現像条件
現像スリーブ１１は、は、前述実施例１、２、３、４と同じく、感光体１との距離を５００μｍに設定し図示しない電源から図１に示したような波形の直流電圧及び交流電圧を印加した。トナーの帯電極性はマイナスとした。図１の波形図にて、
非画像部表面電位Ｖ_Ｄ ＝−６５０Ｖ、
高濃度画像部表面電位Ｖ_Ｌ ＝−２００Ｖ、
引き戻し電圧Ｖ_１ ＝＋５００Ｖ、
現像電圧Ｖ_２ ＝−１５００Ｖ、
ブランク電圧Ｖ_３ ＝−５００Ｖ
の条件で、Ｔ_１ 、Ｔ_２ 、Ｔ_３ は、
Ｔ_１ ＝８．０×１０^−５ 秒
Ｔ_２ ＝８．０×１０^−５ 秒
Ｔ_３ ＝８．０×１０^−４ 秒
とした。従って、本実施例においても、前述実施例１、２、３、４と同じく、現像スリーブ１１と感光体１間に発生する最大電界強度が帯電用スリーブ３１と感光体１間で発生する最大電界強度よりも大きくなっている。
【００７７】
以上の現像条件にて画像形成を行なったところ、かぶりが若干あった、即ち表１の評価基準でレベルＣ、画像濃度も１．５以上得られ、ハイライト部のがらつきのない良好な画像が得られた。
【００７８】
比較例１
上記実施例との比較例１として、図２に示す実施形態の画像形成装置に上述の感光体Ａを用いて、以下の現像条件で画像形成を行ない、転写紙上のかぶりならびに画像濃度の評価を行なった。
【００７９】
・現像条件
現像スリーブ１１は、感光体１との距離を５００μｍに設定し図示しない電源から図１に示したような波形の直流電圧及び交流電圧を印加した。トナーの帯電極性はマイナスとした。図１の波形図にて、
非画像部表面電位Ｖ_Ｄ ＝−６５０Ｖ、
高濃度画像部表面電位Ｖ_Ｌ ＝−２００Ｖ、
引き戻し電圧Ｖ_１ ＝＋５００Ｖ、
現像電圧Ｖ_２ ＝−１５００Ｖ、
ブランク電圧Ｖ_３ ＝−５００Ｖ
の条件で、Ｔ_１ 、Ｔ_２ 、Ｔ_３ は、
Ｔ_１ ＝２．５×１０^−４ 秒
Ｔ_２ ＝２．５×１０^−４ 秒
Ｔ_３ ＝０ 秒
とした。従って、現像スリーブ１１と感光体１間に発生する最大電界強度が帯電用スリーブ３１と感光体１間で発生する最大電界強度よりも大きくなっている。
【００８０】
以上の条件にて画像形成を行なったところ、かぶりがあり、即ち、表１の評価基準でレベルＤ、画像濃度は１．０しか得られず、ハイライト部はややがさつきのある低品位な画像しか得られなかった。
【００８１】
実施例６
上記実施例との比較例２として、図２に示す実施形態の画像形成装置に上述の感光体Ｂを用いて、以下の現像条件で画像形成を行ない、転写紙上のかぶりならびに画像濃度の評価を行なった。
【００８２】
・現像条件
現像スリーブ１１は、感光体１との距離を５００μｍに設定し図示しない電源から図１に示したような波形の直流電圧及び交流電圧を印加した。トナーの帯電極性はマイナスとした。図１の波形図にて、
非画像部表面電位Ｖ_Ｄ ＝−６５０Ｖ、
高濃度画像部表面電位Ｖ_Ｌ ＝−２００Ｖ、
引き戻し電圧Ｖ_１ ＝＋５００Ｖ、
現像電圧Ｖ_２ ＝−１５００Ｖ、
ブランク電圧Ｖ_３ ＝−５００Ｖ、
の条件で、Ｔ_１ 、Ｔ_２ 、Ｔ_３ は、
Ｔ_１ ＝１．０×１０^−４ 秒
Ｔ_２ ＝１．０×１０^−４ 秒
Ｔ_３ ＝１．１×１０^−３ 秒
とした。従って、現像スリーブ１１と感光体１間に発生する最大電界強度が帯電用スリーブ３１と感光体１間で発生する最大電界強度よりも大きくなっている。
【００８３】
以上の条件にて画像形成を行なったところ、かぶりはほとんどなかった、即ち、表１の評価基準でレベルＡであったが、画像濃度は０．８で、ハイライト部はややがさつきがあった。
【００８４】
【発明の効果】
以上説明したとおり本発明によれば、注入帯電方式で、且つ、かぶりや濃度低下を発生することなく２成分接触現像を行なうことができる。
【図面の簡単な説明】
【図１】本発明に従った現像バイアス電圧の波形を示す波形図である。
【図２】本発明が具現化される画像形成装置を示す概略構成図である。
【図３】図２の画像形成装置の帯電器を示す構成図である。
【図４】本発明に従った他の現像バイアス電圧の波形を示す波形図である。
【図５】本発明に従った更に他の現像バイアス電圧の波形を示す波形図である。
【図６】従来の画像形成装置の一例を示す構成図である。
【図７】図２の画像形成装置の露光装置を示す構成図である。
【図８】図２の画像形成装置の現像装置を示す構成図である。
【図９】現像バイアスにおける交番電界部の比率と、感光体表面電位の関係を示す図である。
【図１０】注入帯電の説明図である。
【符号の説明】
１ 感光ドラム（像担持体）
３ 帯電装置（接触帯電部材）
４ 現像装置
１１ 現像スリーブ（現像剤担持体）[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an image forming apparatus such as a copying machine and a printer, and more particularly to an image forming apparatus that develops an electrostatic latent image on an image carrier with a two-component developer.
[0002]
[Prior art]
FIG. 6 shows a sectional view of an example of a conventional image forming apparatus.
[0003]
In the figure, first, the original G is set on the original table 10 with the surface to be copied facing down. Next, the copy is started by pressing the copy button. The unit 9 integrally configured with the document irradiation lamp, the short focus lens array, and the CCD sensor scans while irradiating the document, so that the original surface reflected light of the illumination scanning light is imaged by the short focus lens array. Is incident on the CCD sensor.
[0004]
The CCD sensor is composed of a light receiving unit, a transfer unit, and an output unit. In the CCD light receiving unit, an optical signal is converted into a charge signal, and is sequentially transferred to the output unit in synchronization with a clock pulse. The signal is converted into a voltage signal, amplified and reduced in impedance and output. The analog signal obtained in this way is subjected to known image processing, converted into a digital signal, and sent to the printer unit.
[0005]
The printer unit receives the image signal and forms an electrostatic latent image as follows. The photosensitive drum 1 is rotationally driven in a direction indicated by an arrow at a predetermined peripheral speed around a central support shaft, and is subjected to a uniform charging process by the charger 3 so as to be about −650 V during the rotation process. By scanning the surface of the charged surface with a rotating polygon mirror that rotates at high speed on the surface of the solid-state laser element that emits light ON or OFF corresponding to the image signal, the surface of the photosensitive drum 1 is electrostatically compatible with the original image. Latent images are formed sequentially.
[0006]
Here, the developing process will be described. Generally, there are two development methods: non-magnetic toner is coated on a sleeve with a blade or the like, and magnetic toner is coated and conveyed by magnetic force, and developed in a non-contact state with respect to the photosensitive drum. (One-component non-contact development) and the toner coated as described above mixed with a magnetic carrier to the photosensitive drum as a developer, conveyed by magnetic force, and developed in contact with the photosensitive drum There are roughly divided into four types: a method of developing (two-component contact development) and a method of developing the two-component developer in a non-contact state (two-component non-contact development).
[0007]
Among the above four development methods, two-component contact development in which toner particles and a magnetic carrier are mixed and used as a developer and developed in contact with a photosensitive drum because high resolution and halftone are easily obtained. The law is used.
[0008]
In this case, the carrier has a volume resistivity of 10 due to the prevention of overcharge and the development electrode effect⁶-10¹⁰A Ωcm type is used, and an alternating electric field is used as a developing electric field to improve development efficiency and image quality.
[0009]
In recent years, with increasing environmental awareness, direct charging members have been used as a charging method that does not use corona discharge. In particular, the injection charging method is very excellent in a method in which the amount of discharge is extremely small when charging the photoreceptor. The injection charging method is a method in which a charge is injected by injecting charge with an injection charging member to the trapping potential of the surface material of the photoconductor, or a charge injection layer in which conductive particles are dispersed on the surface of the photoconductor. The charged particles are charged by charging with an injection charging member.
[0010]
In this injection charging, it is known that when an alternating voltage is superimposed on the bias applied to the injection charging member, the charging efficiency is improved and the life of the contact charging member can be extended. As the alternating electric field to be superimposed, a peak-to-peak voltage, that is, Vpp of 500 V or more, particularly 700 V or more, and a frequency of 300 to 5000 Hz, preferably 500 to 2000 Hz is suitable.
[0011]
[Problems to be solved by the invention]
However, in such an apparatus that employs two-component contact development using injection charging and an alternating development electric field, there has been a problem that fog or density reduction occurs in the image.
[0012]
In view of the above, the present inventors have conducted various studies on the phenomenon in which the above-described fogging and the decrease in image density occur, and as a result, these phenomena are statically injected into the photosensitive drum from the magnetic carrier during development. It has been found that this occurs when the potential of the electrostatic latent image changes.
[0013]
More specifically, the volume resistivity is 10¹⁰The unit area of the charging sleeve surface (1 cm) with respect to the charging sleeve enclosing a magnet with magnetic particles such as ferrite of Ω · cm or less and a volume average particle size of approximately 100 μm or less, preferably 15 to 50 μm.²) 100 mg or more, provided that the specific gravity of the magnetic particles is 5.0, that is, 100 mg / cm.²The bearing is carried in the above coating state, and the charging sleeve is rubbed against the photosensitive drum at an interval of about 500 μm while maintaining a DC voltage substantially equal to the charged target potential, Vpp = 500 V or more, preferably 700 V or more. And frequency V_f= 300 to 5000 Hz, preferably in an apparatus capable of charging the photosensitive drum by applying a bias superimposed with an alternating voltage of 500 to 2000 Hz, the volume resistivity is 10⁶-10¹⁰It has been found that even in two-component contact development in which development is performed by directly contacting these magnetic carriers with a photoreceptor using a magnetic carrier of about Ω · cm, a charge injection phenomenon similar to injection charging may occur. .
[0014]
This is also the maximum electric field strength generated between the developing sleeve and the photosensitive drum during development._max-De= {-1000 + (-500)} / 500 × 10^-6= -3.0 × 10⁶[V / m]
Is the maximum electric field strength generated between the charging sleeve and the photosensitive drum during injection charging._max-ch= {− 350 + (− 650)} / 500 × 10^-6= −2.0 × 10⁶[V / m]
One of the causes is considered to be larger than the above.
[0015]
Therefore, the volume resistivity of the photosensitive drum for injection charging is 10⁶-10¹⁰When a two-component developer having a magnetic carrier of about Ω · cm is superimposed with an alternating electric field of Vpp of 500 V or higher and a frequency of about 2000 Hz to perform reversal development, the magnetic carrier for development is applied to the photosensitive drum in the developing unit. Since charge injection is performed, the potential of both the white background portion (the portion where the photosensitive drum is uniformly charged and not exposed) and the black portion (the portion where the photosensitive drum is uniformly charged and then exposed) are developed. It converges to the DC component of the voltage applied to the sleeve. For this reason, it has been found that the potential difference between the white background portion and the developing sleeve decreases, fogging occurs, and the potential difference between the black portion and the developing sleeve also decreases, resulting in a decrease in image density.
[0016]
In the above description of the conventional example, only the reversal development method has been described as the development method. However, such a problem is not unique to the reversal development method, and may occur in the same manner when the regular development method is used. It became clear by research of the present inventors.
[0017]
[Means for Solving the Problems]
The present invention for solving the above-mentioned problems is a two-component developer comprising an image carrier capable of injection charging, an injection charging member for injection charging a voltage having a vibration component, and a toner and a carrier.On the developer carrier.A developing device that is in contact with the image carrier and performs development under an alternating developing electric field;
SaidThe volume resistivity of the carrier is 10⁶-10¹⁰Ωcm, the development electric field is repeated between the alternating part and the rest part.The
The pause time is 1 to 5 times the alternating period,
The absolute value of the potential of the developer carrying member in the rest portion is larger than the absolute value of the potential of the image portion of the image carrier and smaller than the absolute value of the potential of the non-image portion.It is characterized by this.
[0018]
DETAILED DESCRIPTION OF THE INVENTION
FIG. 2 is a sectional view of the image forming apparatus according to the embodiment of the present invention.
[0019]
Note that the same members as those in the apparatus shown in FIG.
[0020]
FIG. 7 shows a schematic configuration of a laser scanning unit 100 that scans laser light in the above-described apparatus. When laser light is scanned by the laser scanning unit 100, the solid-state laser element 102 is first blinked at a predetermined timing by the light emission signal generator 101 based on the input image signal. The laser light emitted from the solid-state laser element 102 is converted into a substantially parallel light beam by the collimator lens system 103, and further scanned in the arrow C direction by the rotating polygon mirror 104 that rotates in the arrow B direction and the fθ lens group. 105a, 105b, and 105c form a spot image on the scanning surface 106 such as the photosensitive drum 1 or the like. By scanning with such laser light, an exposure distribution for one image scan is formed on the scanned surface 106, and if the scanned surface 106 is scrolled by a predetermined amount perpendicular to the scanning direction for each scan, An exposure distribution corresponding to the image signal is obtained on the scanned surface 106.
[0021]
As shown in FIG. 8, the developing device 4 includes a developer container 16, and the interior of the developer container 16 is divided into a developing chamber (first chamber) R <b> 1 and a stirring chamber (second chamber) R <b> 2 by a partition wall 17. In the toner storage chamber R3, replenishment toner (non-magnetic toner) 18 is accommodated. A replenishing port 20 is provided at the bottom of the toner storage chamber R3, and an amount of replenishing toner 18 corresponding to the consumed toner is dropped and replenished into the stirring chamber R2 through the replenishing port 20.
[0022]
On the other hand, the developer 19 is accommodated in the developing chamber R1 and the stirring chamber R2. As described above, the developer 19 is a two-component developer having a nonmagnetic toner and magnetic particles (carrier). The mixing ratio is about 4 to 10% of non-magnetic toner by weight. The non-magnetic toner has a volume average particle size of about 5 to 15 μm. The magnetic particles are made of resin-coated ferrite particles (maximum magnetization 60 emu / g), the weight average particle diameter is 25 to 60 μm, and the resistance value is 10⁶  -10¹⁰The value of Ω · cm is shown. The magnetic particles have a magnetic permeability of about 5.0.
[0023]
An opening is provided in a portion of the developer container 16 adjacent to the photosensitive drum 1, and the developing sleeve 11 protrudes from the opening by a half circumference to the outside and is rotatably incorporated in the developer container 16. The developing sleeve 11 has an outer diameter of 32 mm and a peripheral speed of 280 mm / sec. The developing sleeve 11 is rotated in the direction of the arrow in the figure. The developing sleeve 11 is disposed so that the distance from the photosensitive drum 1 is 500 μm. The developing sleeve 11 is made of a non-magnetic material, and a magnet 12 serving as a magnetic field generating means is fixed therein.
[0024]
The magnet 12 has a developing magnetic pole S1, a magnetic pole N3 located downstream thereof, and magnetic poles N2, S2, and N1 for conveying the developer. The magnet 12 is disposed in the developing sleeve 11 so that the developing magnetic pole S1 faces the photosensitive drum 1. The developing magnetic pole S1 forms a magnetic field in the vicinity of the developing portion between the developing sleeve 11 and the photosensitive drum 1, and a magnetic brush is formed by the magnetic field.
[0025]
Above the developing sleeve 11, a blade 15 is fixed to the developer container 16 at an interval of 800 μm from the developing sleeve 11, and regulates the layer thickness of the developer 19 on the developing sleeve 11. The blade 15 is made of a nonmagnetic material such as aluminum or SUS316.
[0026]
A conveying screw 13 is accommodated in the developing chamber R1. The conveying screw 13 is rotated in the direction indicated by the arrow in the drawing, and the developer 19 in the developing chamber R <b> 1 is conveyed in the longitudinal direction of the developing sleeve 11 by the rotational driving of the conveying screw 13.
[0027]
A conveying screw 14 is accommodated in the storage chamber R2. The conveying screw 14 conveys the toner along the longitudinal direction of the developing sleeve 11 by its rotation, and the toner freely falls into the stirring chamber R2 from the replenishing port 20.
[0028]
The developing sleeve 11 carries the developer at a position near the magnetic pole N2, and the developer 19 is conveyed toward the developing portion as the developing sleeve 11 rotates. When the developer 19 reaches the vicinity of the developing portion, the magnetic particles of the developer 19 rise from the developing sleeve 11 while being linked by the magnetic force of the magnetic pole S1, and the magnetic brush of the developer 19 is formed. FIG. 3 shows the charger 3.
[0029]
Injection charging is a method of charging while directly injecting charge from a charging member to a member to be charged, and a surface potential that rises approximately 1: 1 with a bias applied to the charging member is obtained on the surface of the member to be charged.
[0030]
As shown in the figure below, in conventional contact charging such as roller charging, the charged member is charged by discharge, so there is a difference between the bias applied to the charging member and the surface potential appearing on the charged member surface. Arise. (Normally about 600V)
[0031]
On the other hand, in injection charging, as can be seen from the figure, the difference between the bias applied to the charging member and the potential appearing on the surface of the member to be charged is approximately OV, 200 V or less, particularly preferably 100 V or less, as described above. is there.
[0032]
In the charger 34, a charging magnetic particle 35 for injection charging is coated with a regulating member 33 on a sleeve 31 containing a fixed magnet 32 in a container 34, and the photosensitive member 1 is in contact with the photosensitive member 1. The sleeve 31 is rotated while contacting and rubbing so that the sleeve 31 moves in the direction opposite to the moving direction. Further, the distance between the sleeve 31 and the photosensitive member 1 is set to be approximately 500 μm.
[0033]
By the way, the magnetic particles 35 for charging are
・ Mixed resin and magnetite or other magnetic powder and molded into particles, or mixed with conductive carbon to adjust resistance,
・ Sintered magnetite, ferrite, or those whose resistance value is adjusted by reducing or oxidizing them,
A coating material (such as a phenol resin in which carbon is dispersed) having a resistance adjusted to the above magnetic particles may be coated or plated with a metal such as Ni to have an appropriate resistance value.
[0034]
If the resistance value of the charging magnetic particles 35 is too high, the charge cannot be uniformly injected into the photoreceptor, and a fogged image due to a minute charging failure is generated. If it is too low, when there is a pinhole on the surface of the photoconductor, current concentrates in the pinhole and the charging voltage drops, and the surface of the photoconductor cannot be charged, resulting in a charging failure in a charging nip shape. Therefore, the resistance value of the magnetic particles is 1 × 10²  ~ 1x10¹⁰Ω is preferably 1 × 10 in consideration of the existence of a pinhole or the like on the photosensitive drum.⁶  Ω or higher is desirable. The resistance value of the charged magnetic particles is a metal cell to which a voltage can be applied (low area 228 mm).²  ), 2 g of charged magnetic particles were added, weighted, and a voltage of 100 V was applied for measurement.
[0035]
As the magnetic characteristics of the magnetic particles for charging, it is better to increase the magnetic binding force in order to prevent the magnetic particles for charging from adhering to the drum, and the saturation magnetization is 100 (emu / cm).³  The above is desirable.
[0036]
Actually, the magnetic particles for charging used in this example had an average particle size of 30 μm and a resistance value of 1 × 10.⁶  Ω, saturation magnetization 200 (emu / cm³  )Met.
[0037]
Bias to the charging sleeve 31 at −650 V_pp= 700V, V_fBy applying a bias on which an alternating electric field composed of a sine wave of 1000 Hz is applied, the photosensitive member 1 is uniformly charged to −650V. After that, an image is formed by the process described in the conventional example. Therefore, the maximum electric field strength generated between the charging sleeve 31 and the photosensitive member 1 during charging is {−350 + (− 650)} / 500 × 10.^-6= −2.0 × 10^-6[V / m].
[0038]
The charging device 3 may be a corona charger, but the injection charging method is very excellent in that the amount of discharge is extremely small when charging the photosensitive member, and the surface state of the photosensitive member is suppressed from being contaminated by discharge products. Method.
[0039]
Next, the photosensitive drum in this embodiment will be described.
[0040]
・ About photosensitive drum A
A subbing layer is provided as a first layer on a drum base made of aluminum having a diameter of 30 mm, and is a conductive layer having a thickness of 20 μm for preventing the occurrence of moire due to reflection of exposure. The second layer is a positive charge injection preventing layer, which serves to prevent the positive charge injected from the drum substrate from canceling the negative charge charged on the surface of the photosensitive member, and has a volume resistance by amylan resin and methoxymethylated nylon. Rate 10⁶  It is a medium resistance layer having a thickness of about 0.1 μm adjusted to a resistance of about Ω · cm. The third layer is a charge generation layer, which is a layer having a thickness of about 0.3 μm in which a disazo pigment is dispersed in a resin, and generates positive and negative charge pairs upon exposure. The fourth layer is a charge transport layer, in which hydrazone is dispersed in a polycarbonate resin, and is a p-type semiconductor. The fifth layer is SnO to reduce the surface resistivity of the polycarbonate resin.₂  A surface layer of 2 μm in which 5 parts by weight of low resistance particles such as 5 parts by weight are dispersed with respect to 3 parts by weight of the resin. The volume resistivity of the surface layer is 10¹³Ω · cm. By controlling the surface resistivity in this way, the direct chargeability is improved and a high-quality image can be obtained. The photoreceptor is not limited to OPC but can be realized by an a-Si drum, and further high durability can be realized.
[0041]
This fourth layer is 10% in terms of volume resistivity against the negative charge given to the photosensitive drum during image formation.¹⁶Insulating property of Ω · cm or more. Accordingly, the fifth layer which is one of the features of the present invention is different in electrical properties, and the relationship is the relationship of the fourth layer> the fifth layer in terms of volume resistivity.
[0042]
Here, the volume resistivity of the surface layer is a value measured by arranging metal electrodes at intervals of 200 μm, injecting the surface layer preparation liquid between them to form a film, and applying a voltage of 100 V between the electrodes. . The measurement is a value measured under conditions of a temperature of 23 ° C. and a humidity of 50% RH.
[0043]
Next, the most characteristic part of the present invention will be described. The present inventors have developed an image carrier for injection charging, in particular, the volume resistivity of the surface layer is 10⁹-10¹⁴A photosensitive drum which is an image carrier adjusted to about Ω · cm, and a volume resistivity of 10⁶-10¹⁰In an image forming apparatus equipped with a developing device using a two-component developer of about Ω · cm, the potential difference between the white background portion and the developing sleeve decreases during development, and fogging occurs, and the potential difference between the black portion and the developing sleeve also decreases. As a result, the inventors have found a developing bias that can solve the problem of a decrease in image density.
[0044]
That is, according to the study by the present inventors, the developing bias applied to the developing sleeve is a direct current consisting of only the DC component for approximately 1 to 5 times the total time of the alternating electric field portion and the time for applying the alternating electric field. It has been found that the above-described problems can be avoided by setting the bias so that the boundary portions are alternately included.
[0045]
For example, by applying a developing bias having the waveform shown in FIG. 1 between the developing sleeve 11 and the photosensitive drum 1, good image formation without shading can be performed without causing fogging or a decrease in image density. It became so.
[0046]
Here, the characteristics of the developing bias according to the present invention will be described with reference to FIG.
[0047]
Pull-back voltage V₁T₁Development voltage V after applying for a while₂T₂A voltage corresponding to a DC bias in consideration of fogging of a non-image area, ie, a blank voltage V₃= 1/2 ・ (V₁+ V₂) T₃Apply for hours. This V₃For the value of (V₁+ V₂) Not only 1/2 but V₁And V₂The same effect can be obtained if the value is between.
[0048]
At this time, the application time of these biases was set as follows in order to prevent the injection phenomenon to the photosensitive drum by the developing carrier as described above, and to obtain a good image with no win.
[0049]
(T₁+ T₂) ≦ T₃≦ 5 ・ (T₁+ T₂(Seconds)
[0050]
Here, using FIG. 9, the time ratio P of the alternating electric field portion in the developing bias, that is, P = (T₁+ T₂) / (T₁+ T₂+ T₃) And the photoreceptor potential after passing through the developing nip will be described.
[0051]
In FIG. 9, the horizontal axis represents the time ratio P of the alternating electric field portion in the developing bias, and the vertical axis represents the photoreceptor potential after passing through the developing nip.
[0052]
When the time ratio P of the alternating electric field portion is set between 0 and 1, when the value of P exceeds 0.5, V at the photoreceptor potential is obtained._DPart: non-image part potential, for example, -650V, charged charging member, the charged part of the photosensitive member, V_LPart: V_DA portion adjusted to −200 V, for example, at a potential corresponding to a high-density image portion by exposing the portion to a high-density image portion,₁And V₂The average value of FIG. 9 was found to converge to −500V.
[0053]
As can be seen from the results of FIG. 9, it is necessary to provide a resting (blank) voltage portion consisting only of DC voltage in the alternating electric field portion of the developing bias, particularly in the total time during which actual development is performed in the developing nip. On the other hand, by setting it to 1/2 or more, almost no charge is injected from the developing magnetic carrier to the photosensitive drum, and as a result, it is possible to prevent the occurrence of fogging and a decrease in image density.
[0054]
This is presumably because the blank portion has a DC voltage, so that charge injection is unlikely to occur, and the blank portion has the effect of blocking the movement to inject charge at the alternating portion.
[0055]
Note that the absolute value of the voltage in the blank portion is the non-image portion potential V._DAbsolute value and image portion potential V_LBy setting the difference between the absolute values, the potential difference between the image portion and the non-image portion is reduced, and the charge injection preventing effect is high.
[0056]
Further, in the development bias, the influence on the development characteristics of applying a bias consisting of only the DC component for a time approximately 1 to 5 times the total time of applying the alternating electric field in this way is 5 5 By making the voltage less than double, a sufficient shaking effect on the toner on the developing sleeve can be obtained by applying an alternating electric field, and in addition, the toner separated from the developing carrier by being more than 1 time However, before the reverse electric field is applied to the developing sleeve, it is given sufficient time to adhere to the photosensitive drum, and the highlight portion can be prevented from being scratched. You can also see that.
[0057]
In addition to the developing bias shown in FIG. 1, two bias voltages are used as shown in FIG. 4, and three bias voltages are used as shown in FIG. It has been found that the same effects as described above can be obtained even with a plurality of sets.
[0058]
Next, using the above-described photoreceptor A in the image forming apparatus of the embodiment as shown in FIG. 2, image formation was performed under the following development conditions, and the fog on the transfer paper and the image density were evaluated.
[0059]
・ Development conditions
The developing sleeve 11 was set to a distance of about 500 μm from the photosensitive member 1 and applied with a DC voltage and an AC voltage having a waveform as shown in FIG. The charging polarity of the toner was negative. That is, in the waveform diagram of FIG.
Non-image area surface potential V_D  = −650V,
High density image area surface potential V_L  = -200V
Pull-back voltage V₁  = + 500V,
Development voltage V₂  = -1500V,
Blank voltage V₃  = -500V
T₁  , T₂  , T₃  Is
T₁  = 1.0 × 10^-4  Second
T₂  = 1.0 × 10^-4  Second
T₃  = 2.0 × 10^-4  Second
It was. Accordingly, the maximum electric field strength generated between the developing sleeve 11 and the photosensitive member 1 during development is (−1500) / 500 × 10.⁶[V / m], which is larger than the maximum electric field strength generated between the charging sleeve 31 and the photosensitive member 1 during charging.
[0060]
The evaluation standard of the fog density is as shown in Table 1 below.
[0061]
[Table 1]

[0062]
The fog was determined by the following method. TOKYO DENSHOKU CO. , LTD, the reflection density of each of the fogging portion on the transfer paper and the transfer paper before the image formation is obtained by a density meter TC-6DS of LTD,
Fog density (%) = (reflection density of fog part on transfer paper) − (reflection density of transfer paper).
[0063]
As for the image density, the reflection density of the image on the transfer paper was measured using a densitometer type 941 manufactured by X-lite.
[0064]
When the image was formed under the above development conditions, there was no fog, that is, a level B and an image density of 1.4 or more were obtained according to the evaluation criteria shown in Table 1, and a good image with no highlight area was obtained. It was.
[0065]
Example 2
In Example 2, image formation was performed under the following development conditions using the above-described photoreceptor A in the image forming apparatus of the embodiment shown in FIG. 2, and the fog on the transfer paper and the image density were evaluated.
[0066]
・ Development conditions
As in the first embodiment, the developing sleeve 11 was set to a distance of 500 μm from the photosensitive member 1, and a DC voltage and an AC voltage having waveforms as shown in FIG. 1 were applied from a power source (not shown). The charging polarity of the toner was negative. In the waveform diagram of FIG.
Non-image area surface potential V_D  = −650V,
High density image area surface potential V_L  = -200V
Pull-back voltage V₁  = + 500V,
Development voltage V₂  = -1500V,
Blank voltage V₃  = -500V
T₁  , T₂  , T₃  Is
T₁  = 8.0 × 10^-5  Second
T₂  = 8.0 × 10^-5  Second
T₃  = 8.0 × 10^-4  Second
It was. Accordingly, in this embodiment, as in the first embodiment, the maximum electric field strength generated between the developing sleeve 11 and the photosensitive member 1 is larger than the maximum electric field strength generated between the charging sleeve 31 and the photosensitive member 1. Yes.
[0067]
When image formation was performed under the above development conditions, there was almost no fogging, that is, a level B and an image density of 1.5 or more were obtained according to the evaluation criteria in Table 1, and a good image with no highlight portion blurring was obtained. Obtained.
[0068]
Example 3
In Example 3, image formation was performed using the above-described photoreceptor A in the image forming apparatus of the embodiment shown in FIG. 2 under the following development conditions, and the fog on the transfer paper and the image density were evaluated.
[0069]
・ Development conditions
As in the first and second embodiments, the developing sleeve 11 was set to a distance of 500 μm from the photosensitive member 1, and a DC voltage and an AC voltage having waveforms as shown in FIG. 1 were applied from a power source (not shown). The charging polarity of the toner was negative. In the waveform diagram of FIG.
Non-image area surface potential V_D  = −650V,
High density image area surface potential V_L  = -200V
Pull-back voltage V₁  = + 500V,
Development voltage V₂  = -1500V,
Blank voltage V₃  = -500V
T₁  , T₂  , T₃  Is
T₁  = 8.0 × 10^-5  Second
T₂  = 8.0 × 10^-5  Second
T₃  = 1.6 × 10^-4  Second
It was. Accordingly, in this embodiment, as in the first and second embodiments, the maximum electric field strength generated between the developing sleeve 11 and the photosensitive member 1 is larger than the maximum electric field strength generated between the charging sleeve 31 and the photosensitive member 1. It is getting bigger.
[0070]
When image formation was performed under the above development conditions, there was almost no fogging, that is, a level A and an image density of 1.6 or more were obtained according to the evaluation criteria of Table 1, and a good image with no highlight portion blurring was obtained. Obtained.
[0071]
Example 4
In Example 4, the photosensitive drum B has the following configuration. That is, instead of the surface layer of the fifth layer formed in the manufacture of the photosensitive drum A, SnO is used to reduce the surface resistance of the polycarbonate resin in the fifth layer.₂  A photosensitive member having a surface layer of 2 μm in which 5 parts by weight of low resistance particles such as 5 parts by weight are dispersed with respect to 2 parts by weight of resin is used. Surface resistance is 10⁹  Ωcm.
[0072]
Next, an image was formed under the following development conditions, and the fog on the transfer paper and the image density were evaluated.
[0073]
・ Development conditions
As in the first, second, and third embodiments, the developing sleeve 11 was set to a distance of 500 .mu.m from the photosensitive member 1, and a DC voltage and an AC voltage having a waveform as shown in FIG. The charging polarity of the toner was negative. In the waveform diagram of FIG.
Non-image area surface potential V_D  = −650V,
High density image area surface potential V_L  = -200V
Pull-back voltage V₁  = + 500V,
Development voltage V₂  = -1500V,
Blank voltage V₃  = -500V
T₁  , T₂  , T₃  Is
T₁  = 1.0 × 10^-4  Second
T₂  = 1.0 × 10^-4  Second
T₃  = 2.0 × 10^-4  Second
It was. Accordingly, in this embodiment, as in the first, second, and third embodiments, the maximum electric field strength generated between the developing sleeve 11 and the photosensitive member 1 is the maximum electric field strength generated between the charging sleeve 31 and the photosensitive member 1. Is bigger than.
[0074]
When the image was formed under the above development conditions, there was a slight fog, that is, a level C and an image density of 1.5 or more were obtained according to the evaluation criteria in Table 1, and a good image with no highlight portion blurring was obtained. Obtained.
[0075]
Example 5
In Example 5, an image was formed using the photosensitive drum B of Example 4 under the following development conditions, and the fog on the transfer paper and the image density were evaluated.
[0076]
・ Development conditions
As in the first, second, third, and fourth embodiments, the developing sleeve 11 sets the distance from the photosensitive member 1 to 500 μm and generates a DC voltage and an AC voltage having waveforms as shown in FIG. Applied. The charging polarity of the toner was negative. In the waveform diagram of FIG.
Non-image area surface potential V_D  = −650V,
High density image area surface potential V_L  = -200V
Pull-back voltage V₁  = + 500V,
Development voltage V₂  = -1500V,
Blank voltage V₃  = -500V
T₁  , T₂  , T₃  Is
T₁  = 8.0 × 10^-5  Second
T₂  = 8.0 × 10^-5  Second
T₃  = 8.0 × 10^-4  Second
It was. Accordingly, in this embodiment, as in the first, second, third, and fourth embodiments, the maximum electric field strength generated between the developing sleeve 11 and the photosensitive member 1 is the maximum electric field generated between the charging sleeve 31 and the photosensitive member 1. It is larger than the strength.
[0077]
When the image was formed under the above development conditions, there was a slight fog, that is, a level C and an image density of 1.5 or more were obtained according to the evaluation criteria in Table 1, and a good image with no highlight portion blurring was obtained. Obtained.
[0078]
Comparative Example 1
As Comparative Example 1 with the above examples, the above-described photoreceptor A is used in the image forming apparatus of the embodiment shown in FIG. 2 to form an image under the following development conditions, and the fog on the transfer paper and the image density are evaluated. I did it.
[0079]
・ Development conditions
The developing sleeve 11 was set to a distance of 500 μm from the photosensitive member 1 and a DC voltage and an AC voltage having a waveform as shown in FIG. 1 were applied from a power source (not shown). The charging polarity of the toner was negative. In the waveform diagram of FIG.
Non-image area surface potential V_D  = −650V,
High density image area surface potential V_L  = -200V
Pull-back voltage V₁  = + 500V,
Development voltage V₂  = -1500V,
Blank voltage V₃  = -500V
T₁  , T₂  , T₃  Is
T₁  = 2.5 × 10^-4  Second
T₂  = 2.5 × 10^-4  Second
T₃  = 0 seconds
It was. Accordingly, the maximum electric field strength generated between the developing sleeve 11 and the photosensitive member 1 is larger than the maximum electric field strength generated between the charging sleeve 31 and the photosensitive member 1.
[0080]
When image formation was performed under the above conditions, there was fogging, that is, only a level D and an image density of 1.0 were obtained according to the evaluation criteria in Table 1, and the highlight portion was somewhat low-quality with slight roughness. Only an image was obtained.
[0081]
Example 6
As Comparative Example 2 with the above example, image formation is performed under the following development conditions using the above-described photoreceptor B in the image forming apparatus of the embodiment shown in FIG. 2, and the fog on the transfer paper and the image density are evaluated. I did it.
[0082]
・ Development conditions
The developing sleeve 11 was set to a distance of 500 μm from the photosensitive member 1 and a DC voltage and an AC voltage having a waveform as shown in FIG. 1 were applied from a power source (not shown). The charging polarity of the toner was negative. In the waveform diagram of FIG.
Non-image area surface potential V_D  = −650V,
High density image area surface potential V_L  = -200V
Pull-back voltage V₁  = + 500V,
Development voltage V₂  = -1500V,
Blank voltage V₃  = -500V,
T₁  , T₂  , T₃  Is
T₁  = 1.0 × 10^-4  Second
T₂  = 1.0 × 10^-4  Second
T₃  = 1.1 × 10^-3  Second
It was. Accordingly, the maximum electric field strength generated between the developing sleeve 11 and the photosensitive member 1 is larger than the maximum electric field strength generated between the charging sleeve 31 and the photosensitive member 1.
[0083]
When image formation was performed under the above conditions, there was almost no fogging, that is, level A according to the evaluation criteria in Table 1, but the image density was 0.8, and the highlight portion was somewhat rough. It was.
[0084]
【The invention's effect】
As described above, according to the present invention, two-component contact development can be performed by an injection charging method without causing fogging and density reduction.
[Brief description of the drawings]
FIG. 1 is a waveform diagram showing a waveform of a developing bias voltage according to the present invention.
FIG. 2 is a schematic configuration diagram illustrating an image forming apparatus in which the present invention is embodied.
3 is a configuration diagram illustrating a charger of the image forming apparatus in FIG. 2;
FIG. 4 is a waveform diagram showing waveforms of other development bias voltages according to the present invention.
FIG. 5 is a waveform diagram showing a waveform of still another developing bias voltage according to the present invention.
FIG. 6 is a configuration diagram illustrating an example of a conventional image forming apparatus.
7 is a block diagram showing an exposure apparatus of the image forming apparatus in FIG. 2. FIG.
8 is a configuration diagram showing a developing device of the image forming apparatus of FIG. 2;
FIG. 9 is a diagram illustrating a relationship between a ratio of an alternating electric field portion in a developing bias and a photoreceptor surface potential.
FIG. 10 is an explanatory diagram of injection charging.
[Explanation of symbols]
1 Photosensitive drum (image carrier)
3 Charging device (contact charging member)
4 Development device
11 Development sleeve (developer carrier)

Claims (5)

An image carrier that can be charged by injection, an injection charging member that injects and charges the photosensitive member by applying a voltage having a vibration component, and a two-component developer having toner and a carrier are carried on the developer carrier to form an image carrier. A developing device having a developing means that makes contact and develops in an alternating developing electric field;
A volume resistivity ¹⁰ 6 ^{to 10 10} [Omega] cm of the carrier, the developing electric field is Ri and the name repeatedly resting portion alternating portion,
The pause time is 1 to 5 times the alternating period,
2. An image forming apparatus according to claim 1, wherein the absolute value of the potential of the developer carrying member in the rest portion is larger than the absolute value of the potential of the image portion of the image carrier and smaller than the absolute value of the potential of the non-image portion . The image forming apparatus according to claim 1, wherein the alternating portion alternates a plurality of times. 3. The image forming apparatus according to claim 1 , wherein the injection charging member has magnetic particle spikes in contact with the image carrier. The image forming apparatus according to any one of claims 1, wherein the maximum electric field intensity in the developing unit is greater than or equal to the maximum field intensity of the charging unit 3. It said image bearing member includes a photosensitive member, an image forming apparatus according to any one of 4 to claims 1, characterized in that it has a surface layer of the provided volume resistivity 10 9 ^{to 10} 14 ^cm on the photoreceptor.

Images