JPH0687231A - Image forming device - Google Patents

Abstract

PURPOSE:To form a high-density image and prevent occurrence of fog. CONSTITUTION:Toner passing holes 31a are provided in a matrix form in an insulating substrate 31. To the toner passing holes 31a arranged in a line dierection, a voltage is applied by strip-form toner flow inlet-side electrodes 35. To the toner passing holes 31a arranged in a column dierection, a voltage is applied by toner flow outlet-side electrodes 33. An ultrasonic vibration generator 40 is provided on the insulating substrate 31. For forming an electric field in the toner passing hole 31a, an ultrasonic vibration is applied to the insulating substrate 31 in synchronism with a voltage applying timing to the toner flow inlet-side electrode 35.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an image forming apparatus for forming an image using powder toner.

[0002]

2. Description of the Related Art An image forming apparatus using a powder toner as an image recording medium is disclosed in, for example, Japanese Patent Application Laid-Open No. 3-57658. In this image forming apparatus, a supply roller for supplying toner is arranged, and a bias voltage is applied to the toner supply roller. Further, a toner control mechanism is provided to control the supply of toner from the toner supply roller. The toner control mechanism includes an insulating substrate provided with a large number of pinhole-shaped toner passage holes, and a pair of toner inflow sides provided with the substrates sandwiched in order to form an electric field in each toner passage hole. It has an electrode and a toner outflow side electrode. Each of the toner inflow side electrode and the toner outflow side electrode is provided with a through hole aligned with each toner passage hole. When forming an image, a predetermined voltage is applied from the image information generating mechanism to the toner inflow side electrode and the toner outflow side electrode, and an electric field for passing the toner is formed in the corresponding toner passage hole. As a result, the toner passes through the toner passage hole. When an image is not formed, a voltage is applied to the toner inflow side electrode and the toner outflow side electrode by the image information generating mechanism so that an electric field in the opposite direction to that in the case of passing the toner is formed in the toner passage hole. Is applied.

Further, a base electrode is provided on the side of the substrate from which the toner of the toner control mechanism flows out, and the recording paper is conveyed on the base electrode. A high voltage is applied to the base electrode so that the toner can surely move in the recording paper direction.

An ultrasonic vibration generator is provided on the insulating substrate, and the ultrasonic wave generator surely causes the toner to flow into the toner passage hole.

In such an image forming apparatus, a dot (dot) is formed on the recording paper by the toner passing through each toner passage hole, and an image such as a character is formed by the aggregate of the dots. Then, in order to fix the toner image formed on the recording paper, the recording paper is conveyed to the fixing device. In the fixing device, the toner is heated and melted, so that the toner is fixed on the recording paper.

Further, in such an image forming apparatus, in order to form an image of a continuous line or a region having a relatively large area with a high density, a plurality of toner passage holes provided in the insulating substrate are provided in rows and columns. Are arranged in a matrix. For example, one long plate-shaped toner inflow side electrode is arranged in each toner passage hole arranged in the row direction, and one long passage is formed in each toner passage hole arranged in the column direction. A plate-shaped toner outflow side electrode is arranged. Then, a voltage corresponding to the image information is sequentially applied to each inflow side electrode by the image information generating means, a scanning voltage is sequentially applied to each outflow side electrode, and a voltage is applied to a predetermined toner passage hole. .

[0007]

In such an image forming apparatus, the toner is supplied to all the toner passage holes in the row direction along the axis of the toner supply roller. Therefore, since the toner passage hole through which the toner passes is selected, the toner may stay in the toner passage hole in the toner passage hole that does not need to pass the toner. The toner staying in the toner passage hole may adhere to the inner surface of the toner passage hole and block the toner passage hole. If the toner supply amount by the toner supply roller is reduced, it is possible to prevent the toner clogging in the toner passage hole.However, if the toner supply amount is reduced, the density of the formed image is lowered and a clear image is obtained. There is a risk that you will not be able to.

By applying ultrasonic vibration to the insulating substrate by the ultrasonic vibration generator provided on the insulating substrate, clogging of the toner in the toner passage hole is suppressed. The stronger the ultrasonic vibration applied to the insulating substrate, the greater the effect of preventing toner clogging in the toner passage hole. For this reason, it is preferable to increase the ultrasonic vibration from the ultrasonic vibration generator in order to prevent the toner clogging at the toner passage hole. However, the stronger the ultrasonic vibration applied to the insulating substrate, the larger the toner vibration. Since kinetic energy is given, the toner may not be able to be controlled in the toner passage hole depending on the electric field formed in the toner passage hole. As a result, the toner passes through the toner passage holes that do not need to pass the toner,
There is a possibility that a so-called fog phenomenon may occur in which toner is dropped onto the non-image forming portion.

The present invention solves the above problems, and an object thereof is to provide an image forming apparatus capable of preventing clogging of toner passage holes and forming a clear high-density image without fog. To provide.

[0010]

An image forming apparatus according to the present invention is provided with a toner passage hole through which a charged toner can pass, a substrate to which the charged toner is supplied to each toner passage hole, and each toner. A pair of toner inflow side electrode and toner outflow side electrode arranged so as to sandwich the substrate so that an electric field is formed in the passage hole, and an electric field capable of passing the charged toner in the toner passage hole by the image forming information. Any one of the toner inflow side electrode and the toner outflow side electrode for forming an electric field in the toner passage hole, and image information generating means for applying a voltage between the toner inflow side electrode and the toner outflow side electrode And an ultrasonic vibration generating means for applying ultrasonic vibration to the substrate in synchronism with the voltage application timing.

[0011]

In the image forming apparatus of the present invention, according to the image information, the toner inflow side electrode and the toner outflow side electrode
An electric field that allows the charged toner to pass through is formed in the toner passage hole, and the charged toner passes through the toner passage hole. Ultrasonic vibration is applied to the substrate in synchronization with the voltage application for forming the electric field at this time, so that the toner in the toner passage hole surely passes through the toner passage hole.

[0012]

EXAMPLES Examples of the present invention will be described below. As shown in FIG. 1, the image forming apparatus of the present invention has a toner container 10 containing toner. The toner container
An opening 11 that is open downward is formed in the opening 10, and a toner supply roller 20 that supplies toner downward is rotatably arranged in the opening 11. The toner supply roller 20 is configured such that a sponge layer is provided on the outer peripheral surface of a conductive metal roller portion, and the powder toner stored in the developer storage container 10 is negatively charged, By rotating the toner supply roller 20 in the direction indicated by the arrow B in FIG. 1, the toner is sequentially supplied downward by the sponge layer on the outer peripheral portion. The metal roller portion of the toner supply roller 20 is grounded and has a voltage of 0V.

A toner control mechanism 30 is provided below the toner supply roller 20 in a state of being close to the toner supply roller 20. The toner control mechanism 30 has a flat insulating substrate 31. As shown in FIG. 3, the insulating substrate 31 has a large number of toner passage holes 31a penetrating the substrate 31,
The toner supply rollers 20 are arranged in a row direction along the axial direction and in a column direction slightly inclined with respect to a direction orthogonal to the row direction, and the toner passage holes 31a are arranged in a matrix. . Each toner passage hole 31a has a constant inner diameter. Further, an ultrasonic vibration generator 40 is provided on the insulating substrate 31, and the ultrasonic vibration generator 40 is provided.
Thus, ultrasonic vibration is applied to the insulating substrate 31.

On the toner inflow side surface of the insulating substrate 31 on the toner supply roller 20 side, the toner passage holes 31 arranged in the row direction are arranged.
A plurality of long plate-shaped toner inflow side electrodes 35 for applying a voltage to the toner inflow side portion of a are provided parallel to the row direction. In addition, on the side of the toner outflow side of the insulating substrate 31 opposite to the toner supply roller 20, a plurality of long plate-shaped members for applying a voltage to the toner outflow side portions of the toner passage holes 31a arranged in the row direction are provided. The toner outflow side electrodes 33 are provided in parallel with the column direction. As shown in FIG. 2, each toner inflow side electrode 35 is provided with a through hole 35a having the same diameter as that of each toner passage hole 31a in alignment with each toner passage hole 31a. Also, for each toner outflow side electrode 33,
Similarly, a through hole 33a having the same diameter as each toner passage hole 31a.
Are provided in alignment with the toner passage holes 31a.

A voltage is applied to each toner inflow side electrode 35 and each toner outflow side electrode 33 by an image information generating mechanism 50. The image information generating mechanism 50 operates in response to a signal from a device body such as a word processor, a facsimile, a computer or the like, and supplies a voltage corresponding to the image information to each toner inflow side electrode 35 and each toner outflow side electrode 33.

For example, in the case of negatively charged toner, as shown in FIG. 4, a voltage of +100 V is usually applied to each toner inflow side electrode 35, and each toner outflow side electrode 33 has a negative voltage of −100 V. The voltage of 200V is applied. Then, the toner inflow side electrodes 35 are sequentially supplied with a voltage of −100 V for a predetermined time t.
The toner outflow side electrode 33 corresponding to the toner passage hole 31a that allows the toner to pass therethrough.
Is set to 0V for a predetermined time t based on the timing when the toner inflow side electrode 35 is set to -100V. To the toner outflow side electrode 33, a time t _{1 is} faster than the timing at which the toner inflow side electrode 35 is applied with a voltage of −100V.
It is set to 0V.

A metal base electrode 60 is provided below the toner control mechanism 30 so as to face the toner control mechanism 30. A recording paper 70 on which a toner image is formed is arranged on the upper surface of the base electrode 60, and the recording paper 70 is conveyed on the base electrode 60 in the direction indicated by arrow A in FIG. A positive bias voltage of, for example, +600 V is applied to the base electrode 60 by a predetermined positive bias power source 62.

When a predetermined toner image is formed on the recording paper 70 by the toner control mechanism 30, the recording paper 70 is conveyed to a fixing device (not shown) and the toner image is fixed.

An image forming process by the image forming apparatus having such a configuration will be described. Normally, a voltage of + 100V is applied to all the toner inflow side electrodes 35, and a voltage of -200V is applied to all the toner outflow side electrodes 33. Therefore, in this state, the negatively charged toner conveyed by the toner supply roller 20 is attracted to the toner inflow side electrode 35 charged to + 100V,
The toner is fed from the toner supply roller 20 onto each toner inflow side electrode 35.

The respective toner inflow side electrodes 35 are sequentially synchronized with the conveyance timing of the recording paper 70 as shown in FIG.
The voltage of 0V is applied for a predetermined time t. At this time, the ultrasonic vibration generator 40 synchronizes with the timing at which a voltage of −100 V is applied to each of the toner inflow side electrodes 35 and is shorter than the time t at which −100 V is applied to the toner inflow side electrode 35. It is designed to be driven by t ₂ . When the toner is allowed to pass through the predetermined toner passage hole 31a, the toner outflow side electrode 33 corresponding to the toner passage hole 31a is used for a predetermined time as image information for forming an image from the image information generating means 50. Is set to 0V. The toner inflow side electrode 35 is the toner outflow side electrode 33.
There has so voltage of -100V is applied at a timing delayed by t ₁ time than the timing to be at 0V.

The voltage applied to the toner inflow side electrode 35 is
When + 100V is reversed to -100V, the toner inflow side electrode
The negatively charged toner attracted to the toner 35 repels from the toner inflow side electrode 35 and is attracted to the toner supply roller 20. At this time, the toner outflow side electrode 33
Is set to 0V so as to attract the negatively charged toner, so the toner separated from the toner inflow side electrode 35 is attracted to the toner outflow side electrode set to 0V,
The toner passes through the toner passage hole 31a.

At this time, the toner inflow side electrode 35 is -100V.
Since the ultrasonic vibration is applied to the substrate 31 in synchronism with the timing when the voltage is applied, the toner flowing into the toner passage hole 31a surely passes through the toner passage hole 31a. Moreover, the timing at which the voltage applied to the toner inflow side electrode 35 is reversed is delayed by a predetermined time t ₁ from the timing at which the toner outflow side electrode 33 is set to 0 V, and therefore,
The electric field formed to pass the toner in the toner passage hole 31a is shorter than the time when the voltage is applied to the toner inflow side electrode 35 and the toner outflow side electrode 33 for forming the electric field, and in a short time, The toner passes through the toner passage hole 31a. The toner that has passed through the toner passage hole 31a is transferred to the base electrode 6
It is attracted to 0 and supplied onto the recording paper 70. As described above, when the toner is not allowed to pass through the toner passage hole 31a, the toner is collected on the toner inflow side electrode 35 to supply the toner into the toner passage hole 31a in a short time. Since the ultrasonic vibration is applied to the substrate 31 only when the toner passes through the hole 31a, the image density is lowered even when the recording paper 70 is conveyed at a high speed. There is no fear, and the recording paper
If 70 is not transported at high speed, the resolution will be improved. There is no possibility that the toner will be clogged in the toner passage hole 31a.

When a voltage of -100 V is applied to the toner inflow side electrode 35, the toner in a state of repelling from the toner inflow side electrode 35 has the toner outflow side electrode 33 of 0.
When it reaches V, it passes through the toner passage hole 31a,
When the toner outflow side electrode 33 is set to −200V without being set to 0V, it is attracted to the toner supply roller 20 side without passing through the inside of the toner passage hole 31a. Also in this case, since the ultrasonic wave is applied by the ultrasonic vibration generator 40, the toner does not remain in the toner passage hole 31a, and the inside of the toner passage hole 31a is reliably cleaned. As a result, it is possible to prevent the occurrence of so-called fogging, in which toner adheres to a portion where an image need not be formed. Furthermore, since the operating time of the ultrasonic vibration generator 40 is shortened, heat generation of the ultrasonic vibration generator 40 is suppressed, and power consumption is also reduced.

[0024]

According to the image forming apparatus of the present invention,
The ultrasonic vibration is applied to the substrate only when the toner passes through the toner passage hole, so that the toner surely passes through the toner passage hole and the toner passage hole is filled with the toner. There is no risk of jamming. Further, since the toner surely passes through the toner passage hole, the image density is improved, and the occurrence of fogging in which the toner adheres to a portion where an image is not formed is prevented.

[Brief description of drawings]

FIG. 1 is a schematic configuration diagram showing an example of an image forming apparatus of the present invention.

FIG. 2 is a cross-sectional view showing an enlarged main part of the image forming apparatus.

FIG. 3 is a plan view of an insulating substrate used in the image forming apparatus.

FIG. 4 is a time chart for explaining the operation of the toner inflow side electrode and the toner outflow side electrode of the image forming apparatus.

FIG. 5 is a time chart showing the relationship between the voltage application timing of the toner inflow side electrode of the image forming apparatus and the drive timing of the ultrasonic vibration generator.

[Explanation of symbols]

 20 Toner Supply Roller 30 Toner Control Mechanism 31 Insulating Substrate 31a Toner Passage Hole 33 Toner Outflow Side Electrode 35 Toner Inflow Side Electrode 40 Ultrasonic Vibration Generator 50 Image Information Generation Mechanism 60 Base Electrode 70 Recording Paper

Continuation of front page (51) Int.Cl. ⁵ Identification number Reference number within the agency FI Technical indication location H04N 1/29 E 9186-5C (72) Inventor Shinji Koga 1-228 Tamatsukuri, Chuo-ku, Osaka Mita Within Kogyo Co., Ltd.

Claims (1)

[Claims] 1. A substrate is provided with a toner passage hole through which the charged toner can pass, the substrate to which the charged toner is supplied to each toner passage hole, and an electric field formed in each toner passage hole. A pair of the toner inflow side electrode and the toner outflow side electrode arranged with the substrate sandwiched therebetween, and the toner inflow side electrode and the toner outflow side so that an electric field through which the charged toner can pass is formed in the toner passage hole by the image forming information. Image information generating means for applying a voltage between the side electrodes, and to the substrate in synchronization with the voltage application timing of either the toner inflow side electrode or the toner outflow side electrode for forming an electric field in the toner passage hole. An image forming apparatus comprising: an ultrasonic vibration generator that applies ultrasonic vibration.