JPH03139668A - Electrostatic recorder - Google Patents

Abstract

PURPOSE:To prevent the occurrence of paper jam by embedding a transfer electrode in insulating resin in order to form a resin molded part, and making paper guides function perfectly by means of the resin molded part. CONSTITUTION:The electrostatic recorder uses the transfer electrode 40, as a transfer means, and the resin molded part. The transfer electrode 40 generates a transfer electric field between the developer carrier and a recording medium 48 and transfers an electrostatic latent image on a developer thin layer onto the recording medium 48. The resin molded part is composed of the insulating resin 44 in which the transfer electrode 40 is embedded and supported. The resin molded part is disposed so that a part of it fills gaps between the transfer electrode 40 and the paper guides 64 and 66. Since the gaps between the transfer electrode 40 and the paper guides 64 and 66 are filled with the insulating resin by the use of the resin molded part which embeds the transfer electrode 40 in the insulating resin, the paper guides function perfectly. Thus, the occurrence of paper jam can be prevented at the time of transfer.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of the Invention The present invention relates to electrostatic recording devices that utilize modulated ion currents.

BACKGROUND OF THE INVENTION Conventionally, various types of electrostatic recording techniques have been known.
Examples include those described in Japanese Patent No.-209481. Fifth
The figure explains the principle, and the one-component toner 18 supplied onto the toner carrier roll 10 in which the dielectric layer 4 is provided on the conductive cylinder 12 forms a layer in contact with the toner carrier roll 10. The member 16 forms a toner thin layer with a uniform thickness, and the layer forming member 16 and the one-component toner 18 are triboelectrically charged in a positive or negative manner by a triboelectrification series. As a result, a thin layer of negatively charged toner is carried on the toner carrier roll. From the ion source 20 toward this thin layer, the ion source 20
An ion flow is supplied while applying a bias voltage between the conductive cylinder 12 and the conductive cylinder 12 by a bias power supply 22, and the ion flow is converted into a voltage according to an image signal by an ion flow modulation means 24 consisting of a plurality of aperture elements. By applying power from the control power supply 26 to the ion flow modulating means 24, the ion flow from the ion source is modulated in accordance with the image signal, and the modulated ion flow is selectively impinged on the charged toner thin layer. A toner electrostatic latent image is formed in accordance with the image signal. The formed toner electrostatic latent image is transferred onto the recording medium by applying a bias voltage between the conductive cylinder and the transfer electrode using a bias power source, thereby forming a toner image.

FIG. 6 is a typical example of a conventional electrostatic recording device that utilizes the above principle. In this electrostatic recording device, the toner 18 is stored in a hopper 36]・toner transport roll 3
8. Further, a transfer electrode 40 is arranged facing the toner carrying roll, and paper guides 64 and 66 are provided on both sides of the transfer electrode, over which the recording medium 48 is conveyed. ing.

The toner electrostatic latent image formed as described above is transferred to the recording medium 4 by applying a bias voltage between the conductive cylinder 12 and the transfer electrode 40 by the bias power supply 42.
8. In the figure, 32 indicates a tube, 34 indicates pressurized air, and other symbols have the same meanings as explained in FIG. 1.

Problem to be Solved by the Invention However, in the conventional electrostatic recording device as shown in FIG. The transfer electrode is exposed to the surface of the transfer electrode, and is disposed with a gap provided between the transfer electrode and the paper guides disposed on both sides of the transfer electrode.

Therefore, when the recording medium enters, the leading edge of the recording medium enters the gap between the paper guide and the transfer electrode, which often causes troubles such as paper jams.

The present invention has been made to solve the above-mentioned problems in the prior art, and its purpose is to provide an electrostatic recording device that prevents troubles such as paper jams during transfer.

Means and Effects for Solving the Problems The present inventors have discovered that when a resin molded body in which a transfer electrode is embedded in an insulating resin is used, the gap between the transfer electrode and the paper guide is filled with the insulating resin. It has been found that the above purpose is achieved because it complements the role of a paper guide.

That is, the present invention provides a developer carrier that carries a thin layer of charged developer on its surface, and supplies an ion flow modulated in accordance with an image signal to the developer carrier on the developer carrier. In an electrostatic recording device, the electrostatic recording device includes a modulated ion supply means for supplying modulated ions, and a transfer means for selectively transferring the developer on the developer carrier to a recording medium. A transfer electrode that generates a transfer electric field to transfer an electrostatic latent image on a thin layer of developer to a recording medium, and a resin molded body made of an insulating resin in which the transfer electrode is buried and supported are used. A part of the body is arranged so as to fill the gap between the transfer electrode and the paper guide.

In the electrostatic recording device of the present invention, a thin layer of charged developer is formed on the developer carrier by an appropriate means, and a modulated ion supply means is applied to the thin layer according to an image signal. A modulated ion stream is provided to form an electrostatic latent image. Next, while applying a bias voltage to the transfer electrode, the recording medium is passed between the developer carrier and the transfer electrode, and a developer corresponding to the electrostatic latent image formed on the developer thin layer is applied to the recording medium. Make a transcription. In the present invention, the transfer electrode is embedded in an insulating resin to form a resin molding, and the surfaces of the resin molding where the transfer electrode is exposed fill the gap between the transfer electrode and the paper guide on both sides of the transfer electrode. Because the recording medium enters through the paper guide, it advances along the resin molding and is inserted between the transfer electrode and the developer carrier, and after the transfer, the recording medium enters the resin molding. Follow the body to reach the paper guide. Therefore, paper jams will not occur.

Example Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 shows an embodiment of the electrostatic recording device of the present invention. In the figure, IO is a toner carrier roll, which has a structure in which a dielectric layer 14 is provided on a conductive outer cylinder 12. Reference numeral 16 denotes a layer forming section, which regulates the toner 18 conveyed by the toner conveying roll 38 to form a charged thin layer of -like thickness on the toner carrier roll. 20 is an ion source, 24 is an ion flow modulating means, and an insulating support 30
are integrated to form a chamber 28.

Pressurized air 34 is supplied to the chamber from a tube 32.

A voltage for forming ions is applied from a power source 22 to the ion supply source, and a voltage is applied to the ion flow modulating means 24 from a control power source 26 in accordance with an image signal. Further, reference numeral 40 denotes a transfer electrode, which is embedded in an insulating resin 44 to constitute a resin molded body, and to which a bias voltage is applied by a bias power supply 42. 64 and 66 are paper guides for guiding and transporting the recording medium 4B.

To further explain the electrostatic recording device, the toner carrier roll 10 is made of a stainless steel conductive shirt.
A dielectric cylinder made of thermosetting phenolic resin is fitted and bonded to the top. The toner 18 is stored in the hopper 36, and is transported by a toner transport roll 38 and supplied onto the toner carrier roll. The toner on the toner carrier roll 10 is regulated by the layer forming member 16 to form a thin toner layer of uniform thickness, and is uniformly charged by the layer forming member and the toner frictional charging system.

In this example, the charging potential of the toner thin layer is -30
~-70V. Further, as the layer forming member 16, a stainless steel member is used as a support, and a friction portion with the toner is made of silicone rubber.

As the ion flow modulator 24, for example, Japanese Patent Application Laid-Open No. 61-25
The ring-shaped electrode shown in Publication No. 166 or Japanese Patent Application Laid-open No. 1983
, -1.69853 is used, and is held at a distance of 0.02 to 5 mm, preferably 0.1 to 3 mm, from the toner carrier roll 10 by a holding means such as a tracking roll. provided.

As shown in FIG. 3, the ion supply source 20 is a plate-shaped element in which a flat plate electrode 50 is embedded in a ceramic plate 46.
A discharge electrode 52 is provided on one surface. The buried flat plate electrode 50 and discharge electrode 52 are formed by applying thick film printing, and nickel, tungsten, or the like is used from the viewpoint of ozone resistance.

A ceramic with a thickness of 0.5 mm is interposed between the flat plate electrode 50 and the discharge electrode 52. Between the flat plate electrode 50 and the discharge electrode 52, a frequency of 500 to 101 (Ilz,
Peak-to-peak voltage v p-p is 3.5 to 8 KV (7) AC
A voltage is applied to generate ions by creeping discharge.

Pressurized air is supplied to the chamber 28, and the static pressure is 1 to 1000 m 100 O, more preferably 10 to 500 m
+nmH20 range. The material constituting the insulating support body 25 may be any insulating material, and in addition to resin, ceramic, glass, rubber, etc. can be used.

The transfer electrode 40 is made of stainless steel, for example, and the insulating resin 44 in which it is embedded is made of thermoplastic resin, and the resin molded body can be formed by injection molding or the like. . At this time, the upper surface of the resin molded body is molded so as to function as a part of the paper guide, and the tip portion of the transfer electrode and the voltage application lead portion are exposed to the surface of the resin molded body. The transfer voltage applied between the transfer electrode and the toner carrier roll is
DCo, 5-2. OKV, and the distance between the tip of the transfer electrode and the surface of the toner carrier roll is adjusted to be 0.1 to 0.8 mm.

FIG. 2 is a diagram illustrating details of the transfer electrode portion. The transfer electrode 40 is embedded in an insulating resin 44 to form a resin molded body, and after the transfer electrode is embedded, the paper guide surface A of the resin molded body is processed such as polishing so that there is no difference in level from the exposed part of the transfer electrode. It is finished to have a smooth flat surface to prevent it from forming.

Further, the resin molded body is formed so that overlap portions C and D exist between the paper guides 64 and 66 located upstream and downstream in the paper feed direction. The upstream paper guide 64 is higher than the paper guide surface A of the resin molding by a dimension B (0,1 to OJ m+n), and the overlap part D with the downstream paper guide 66 is tapered. Because of the shape, the recording medium 48 is not caught during paper feeding, and the paper can be fed smoothly.

In the electrostatic recording apparatus shown in FIG. 1, a corona discharge device as described in Japanese Patent Application Laid-Open No. 63-34155 may be used as the ion supply source 20. FIG. 4 shows an embodiment in this case, in which a corona discharge device consisting of a discharge wire 54, a shield 56 surrounding the discharge wire, and a high-voltage power source 58 is used.

Pressurized air 34 was introduced into the ion generator 60, and ions controlled by the ion flow modulator 24 were sent out together with the pressurized air. A DC high voltage power source 58 of 2 to 5 KV was connected to the discharge wire 54 via a resistor 62 of IMΩ. The static pressure of the ion generating part 60 is 1 to I000 mmH20,
Desirably, it was adjusted to 1.0 to 500 mmH2O. Note that other symbols in the figure have the same meanings as those described in FIG. 1 above.

Effects of the Invention In the electrostatic recording device of the present invention, the transfer electrode is embedded in an insulating resin to form a resin molded body, and the resin molded body complements the role of a paper guide. When the agent is transferred to the recording medium, the recording medium does not cause troubles such as paper jams.

[Brief explanation of the drawing]

FIG. 1 is a block diagram of an embodiment of the electrostatic recording device of the present invention, and FIG.
The figure is an explanatory diagram for explaining the transfer electrode part, Figure 3 is a sectional view of the ion source diagram, Figure 4 is a configuration diagram of another embodiment of the electrostatic recording device according to the present invention, and the fifth figure is the electrostatic recording device. FIG. 6 is a diagram showing the structure of a conventional electrostatic recording device. DESCRIPTION OF SYMBOLS 10... Toner carrier roll, I2... Conductive cylinder, 14... Dielectric layer, 16... Layer forming member, 18...
...Toner, 20...Ion supply source, 22...
- Power source, 24... Ion flow modulating means, 26... Control power source, 28... Chamber, 30... Insulating support,
32... Pipe, 34... Pressurized air, 36... Hopper 38... Toner transport roll, 40... Transfer electrode, 4
2... Bias power supply, 44... Insulating resin, 46.
- Ceramic plate, 48... Recording medium, 50... Flat plate electrode, 52... Discharge electrode, 541... Discharge wire, 56... Shield, 58...
High voltage power supply, 60... Ion generation section, 62... Resistor,
64.66...Paper guide. 2

Claims (1)

[Claims] (1) A developer carrier that carries a thin layer of charged developer on its surface, and modulated ions that supply an ion flow modulated in accordance with an image signal to the developer thin layer on the developer carrier. In an electrostatic recording device comprising a supply means and a transfer means for selectively transferring the developer on the developer carrier to a recording medium, the transfer means includes a transfer electric field between the developer carrier and the developer carrier. A transfer electrode that generates an electrostatic latent image on a thin layer of developer and transfers it to a recording medium, and a resin molded body made of an insulating resin in which the transfer electrode is buried and supported are used. An electrostatic recording device characterized in that a portion is arranged to fill a gap between a transfer electrode and a paper guide.