JPH04269563A - Direct electrostatic recorder - Google Patents

Abstract

PURPOSE:To provide a highly reliable direct electrostatic recorder which is unlikely to fall in impossibility of recording by preventing toner from accumulating on an aperture electrode. CONSTITUTION:A toner cleaning electric field is periodically formed between a reference electrode layer 22 of an aperture electrode 20 and a toner carrier roller 11 by a toner cleaning power source 6. Thereby, toner which is not always taken off from the aperture electrode 20 only by an excitation means is electrostatically removed. Consequently the toner comes not to be accumulated on the aperture electrode.

Description

[Detailed description of the invention]

0001

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a direct electrostatic recording device applied to copying machines, printers, etc.

0002

2. Description of the Related Art Conventionally, one example of this type of direct electrostatic recording device is the one disclosed in US Pat. No. 3,689,935. This direct electrostatic recording device modulates and controls the charged toner on a toner carrier using an aperture electrode configured such that an insulating layer is sandwiched between two electrodes and a large number of openings are provided through the electrodes. An image is formed by adsorption onto a support.

A problem with this electrostatic recording device is that the toner supplied from the carrier adheres and deposits on the surface of the reference electrode layer of the aperture electrode, which obstructs the supply of toner from the carrier. Furthermore, due to this accumulation, the toner fills the opening of the aperture electrode, causing the opening to become clogged. As a method of eliminating this toner accumulation, a method of mechanically sieving off the toner by attaching an excitation means to an aperture electrode is disclosed in the specification and drawings attached to the application of Japanese Patent Application No. 2-196781.

0004

For example, when a highly charged toner adheres to an aperture electrode, it firmly adheres to the aperture electrode with a high mirror image force. It becomes difficult to completely mechanically sieve off the toner that is firmly attached to the aperture electrode by the excitation means. That is, when the adhesion force such as the mirror image force or van der Waals force is superior to the force due to the vibration acceleration of the aperture electrode. This toner that cannot be removed accumulates and prevents the toner from being supplied to the aperture electrode. As a result, there was a problem that this direct electrostatic recording device became unable to record.

The present invention has been made to solve the above-mentioned problems, and prevents toner accumulation by periodically removing toner that cannot be completely removed from the aperture electrode by the excitation means alone, and The purpose is to provide a highly reliable direct electrostatic recording device.

[0006]

[Means for Solving the Problems] In order to achieve this object, the direct electrostatic recording device of the present invention comprises a carrier carrying toner and an insulating layer sandwiched between two electrodes, and an opening provided therein. It includes an aperture electrode, an excitation means attached to the aperture electrode, and a counter electrode provided opposite to the aperture electrode with a support in between, and the charged toner is carried by a carrier up to the vicinity of the aperture electrode. The aperture electrode is used to control modulation so that the aperture is ejected through the aperture toward the counter electrode, and is adsorbed onto the support to record an image, wherein the support and the aperture electrode The present invention is characterized in that means for forming an aperture electrode cleaning electric field between the two electrodes is provided.

[0007]

[Operation] In the direct electrostatic recording device of the present invention having the above configuration, the toner that has not been mechanically sieved off from the aperture electrode by the excitation means cleans the aperture electrode formed between the carrier and the aperture electrode. The electric field causes it to be returned electrostatically or mechanically to the carrier.

[0008]

DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment embodying the present invention will be described below with reference to the drawings.

FIG. 1 is a schematic diagram of a direct electrostatic recording apparatus to which the present invention is applied.

An insertion port 3 and an ejection port 4 are provided on the side of the device exterior 5, and a recording section 1 and a heat fixing section 2 are provided adjacent to the recording section 1 inside the device. After the support P entered through the insertion port 3 is image-recorded in the recording section 1,
The image on the support P is thermally fixed onto the support P in the heat fixing section 2. The support P is then taken out from the takeout port 4 via the guide 33.

Inside the recording section 1, a toner carrying roller 11 is installed.
, an aperture electrode 20 and a counter electrode 25 are provided. Around the toner carrying roller 11, a supply roller 12 is provided in contact with the toner carrying roller 11 upstream in the rotational direction of the toner carrying roller 11, and the supply roller 12, the toner carrying roller 11, etc. It is located in the area surrounded by the case 14. Furthermore, toner T is stored inside the toner case 14. Further, a layer thickness regulating member 13 is provided which contacts the supply roller 12 and makes the toner T adhering thereto a uniform toner T layer. The toner carrying roller 11 is connected to the switch 7.

An aperture electrode 20 is arranged above the toner carrying roller 11.

As shown in FIG. 4, the aperture electrode 20 is
It is formed by sandwiching an insulating layer 21 between a reference electrode layer 22 and a large number of control electrode layers 23, and further has a large number of openings 24 arranged in a row. The reference electrode layer 22 is provided on the entire surface of the insulating layer 21 on the toner carrying roller 11 side, and each control electrode layer 23 is arranged around the opening 24 on the upper surface of the insulating layer 21 . The insulating layer 21 is made of a polymer resin film having a thickness of 25 μm, such as polyimide. Further, the reference electrode layer 22 and the control electrode layer 24 have a thickness of 1 μm and are formed by a thin film forming method, for example, a sputtering method.
It is made of a certain amount of metal film, for example copper. The opening 24 is a through hole with a diameter of about 80 μm. The reference electrode layer 22 is connected to ground, and each control electrode layer 23 is connected to the image signal S, respectively.

Further, the reference electrode layer 21 and the toner carrying roller 11 are at the same potential during recording, but when the switch 7 is switched, a toner cleaning voltage is applied by the toner cleaning power supply 6, and the reference electrode layer 21 A toner cleaning electric field is formed between the toner carrying roller 11 and the toner carrying roller 11 .

A pair of piezoelectric elements 9 are provided at both ends of the aperture electrode 20. This piezoelectric element 9 has an oscillator 8
is attached so that the aperture electrode 20 can be excited.

A counter electrode 2 is provided above the aperture electrode 20.
5 is placed. Further, a space is provided between the counter electrode 25 and the aperture electrode 20 through which the support P can pass. This counter electrode 25 is connected to a negative (-) power source E, for example.

The support P is conveyed from the insertion opening 3 to the heat fixing section 2 via the counter electrode 25 by a guide 33 and a pair of guide rollers 34 .

Inside the heat fixing section 2, a heat roller 31 having an internal heat source and a press roller 32 are provided in contact with each other, and a support P is provided between the heat roller 31 and the press roller 32. It is configured so that it can pass through.

Next, the operation of the direct electrostatic image recording apparatus constructed as described above will be explained.

Inside the recording unit 1 , the toner T carried by the supply roller 12 is rotated to form a constant layer of toner T, and then supplied to the toner carrying roller 11 . At this time, toner T
is in contact with the supply roller 12 and the toner carrying roller 11 and rubbed, and is charged, for example, positively (+). plus(
The toner T charged to +) is carried by the toner carrying roller 11 and supplied to the aperture electrode 20 .

On the other hand, the support P inserted into the apparatus through the insertion port 3 is conveyed to the counter electrode 25 by a guide 33 and a guide roller 34.

At this location, an image signal voltage is applied from the image signal S to the control electrode layer 23 of the aperture electrode 20. The flow of toner T is modulated and controlled based on this image signal voltage. In other words, minus (-
) When a voltage is applied to the control electrode layer 23, the opening 24
An electric field is generated in which the positively charged toner T moves from the reference electrode layer 22 to the control electrode layer 23.
The toner T passes through the opening 24. Further, when no voltage is applied from the image signal S, no electric field is generated inside the opening 24, so the toner T does not pass through the opening 24.

Now, the aperture electrode 20 is excited by the vibration of the piezoelectric element 9 by the oscillator 8. Then, most of the toner T that has adhered or is about to adhere to the aperture electrode 20 due to the mirror image force and van der Waals force is given vibrational acceleration by this excitation and falls. However, for example, toner T with a high charge amount adheres to the aperture electrode 20 with a high mirror image force, so it may not fall from the aperture electrode 20 only with the above excitation. If a large amount of such toner T adheres to the aperture electrode 20, the supply of toner T necessary for printing may be obstructed or the opening 24 of the aperture electrode 20 may be blocked, making the apparatus unable to record. In order to avoid this disadvantage, in this embodiment, for example, every time printing is completed, the switch 7 is switched and the toner cleaning power supply 6 is used to clean the toner between the aperture electrode 20 and the toner carrying roller 11. Form an electric field.

The toner cleaning power supply 6 applies a positive voltage to the reference electrode layer 22 of the aperture electrode 20, as shown in FIG. 2, for example. This voltage application forms an electric field directed from the aperture electrode 20 toward the toner carrying roller 11 . This electric field causes the positively charged toner T attached to the aperture electrode 20 to be electrostatically returned toward the toner carrying roller 11 . As a result, the aperture electrode 20 is cleaned before moving on to the next print.

For example, as shown in FIG. 3, when the toner cleaning power source is an AC power source, an alternating electric field is formed between the reference electrode layer 22 of the aperture electrode 20 and the toner carrying roller 11. This electric field causes the charged toner T to
Move back and forth around this place. Then, the toner T repeatedly collides with the aperture electrode 20 and knocks off the toner T adhering to the aperture electrode 20 (sputtering phenomenon). As a result, the aperture electrode 20 is cleaned before moving on to the next print.

A negative (-) voltage is applied to the counter electrode 25 by a power source E. An electric field is formed between the counter electrode 25 and the aperture electrode 20 by this voltage,
The toner T modulated along this electric field is attracted to the counter electrode 25. Then, the toner T is applied to the support P.

Thereafter, the support P is conveyed from the recording section 1 to the heat fixing section 2, and the image on the support P is thermally fixed.

The support P that has passed through the heat fixing section 2 is guided through the guide 3.
3 to the take-out port 4 and taken out.

As explained above, according to this embodiment, a toner cleaning electric field such as a reverse toner flying electric field or an alternating electric field is periodically formed between the aperture electrode 20 and the toner carrying roller 11 by the toner cleaning power supply. By doing so, toner that could not be completely removed from the aperture electrode 20 due to excitation is removed. Therefore, the aperture electrode 20
Since printing is always performed with almost no toner adhering to the surface, a direct electrostatic recording device with high printing reliability is provided.

The present invention is not limited to the embodiments described in detail above, and it is easy to make changes without departing from the spirit thereof.

For example, the toner cleaning power supply 6 may be an AC bias power supply. That is, it is a combination of the embodiment shown in FIG. 2 and the embodiment shown in FIG.
It has a dual effect of pulling back the adhered toner and at the same time knocking it off (spatter phenomenon), making it extremely effective.

[0032]

As is clear from the above detailed description, in the direct electrostatic recording device of the present invention, the toner cleaning power supply creates a toner reverse flying electric field between the aperture electrode and the toner carrying roller, or By periodically forming a toner cleaning electric field such as an alternating electric field, toner that cannot be completely removed from the aperture electrode due to excitation is removed. Therefore, since printing is always performed in a state where almost no toner adheres to the aperture electrode, a direct electrostatic recording device with high printing reliability is provided.

[Brief explanation of the drawing]

FIG. 1 is a configuration diagram of a direct electrostatic recording device of the present invention.

FIG. 2 is an explanatory diagram illustrating the operation.

FIG. 3 is an explanatory diagram illustrating the operation.

FIG. 4 is a perspective view of an aperture electrode.

[Explanation of symbols]

6 Toner cleaning power supply 7 Switch 11 Toner carrying roller 20 Aperture electrode 21 Insulating layer 22 Reference electrode layer 23 Control electrode layer 24 Opening 25 Counter electrode T Toner P Support E Power supply

Claims (1)

[Claims] [Claim 1] A carrier supporting toner, an aperture electrode having an insulating layer sandwiched between two electrodes and having an opening.
The aperture electrode includes an excitation means attached to the aperture electrode, and a counter electrode provided opposite the aperture electrode with a support in between, and the charged toner is carried by the carrier up to the vicinity of the aperture electrode, and the aperture electrode is In a direct electrostatic recording device in which an image is recorded by being caused to fly through the aperture toward the counter electrode through modulation control by an electrode, and being adsorbed to the support, an image is recorded between the support and the aperture electrode. 1. A direct electrostatic recording device, comprising means for forming an aperture electrode cleaning electric field.