CN201449517U - Multilayer-structure organic photo conductor - Google Patents

Multilayer-structure organic photo conductor Download PDF

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Publication number
CN201449517U
CN201449517U CN2009200471945U CN200920047194U CN201449517U CN 201449517 U CN201449517 U CN 201449517U CN 2009200471945 U CN2009200471945 U CN 2009200471945U CN 200920047194 U CN200920047194 U CN 200920047194U CN 201449517 U CN201449517 U CN 201449517U
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China
Prior art keywords
interface
coat
layer
charge generating
generating layers
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Expired - Lifetime
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CN2009200471945U
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Chinese (zh)
Inventor
余荣清
潘道成
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SUZHOU GOLDENGREEN TECHNOLOGIES Ltd
Suzhou Goldengreen Technologies Ltd)
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SUZHOU GOLDENGREEN TECHNOLOGIES Ltd
Suzhou Goldengreen Technologies Ltd)
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Priority to CN2009200471945U priority Critical patent/CN201449517U/en
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Abstract

The utility model discloses a multilayer-structure organic photo conductor, which comprises a conductive matrix and an electric charge blocking layer, an electric charge generating layer, and an electric charge transmitting layer which are covered on the surface of the conductive matrix from the inside to the outside in sequence, wherein, the electric charge blocking layer is formed through the composition of an oxidizing layer on the surface of the conductive matrix and a coating layer containing high-molecular material, a large amount of concave micropore structures are arranged on the surface of the oxidizing layer adjacent to the coating layer, and at least one interface of the interfaces between the oxidizing layer and the coating layer, the coating layer and the electric charge generating layer and the electric charge generating layer and the electric charge transmitting layer is provided with a corrugated structure. The organic photo conductor has the advantages of stable property, easy manufacture, good output printing quality, high product qualification rate, long service life and lower comprehensive cost.

Description

The organic photoconductor of sandwich construction
Technical field
The utility model belongs to the technical field of organic photoconductor, relates in particular to a kind of sandwich construction of organic photoconductor.
Background technology
Organic photoconductor is the core component in the modern office equipments such as duplicating machine, laser printer, laser facsimile and multifunctional digital code intergrated machine, is mainly used in and realizes that light is with changing and imaging technique.
Organic photoconductor is also referred to as organic light guide drum, and its structure reaches the electric charge barrier layer, charge generating layers and the charge transport layer that cover the conducting base surface from inside to outside successively and forms mainly by conducting base, and matrix generally adopts conductive materials such as aluminium, aluminium alloy to make.And traditional electric charge barrier layer or form by single oxide layer, its shortcoming is: the technological requirement harshness, make trouble, yield rate is low, cost is high, the image quality instability; Be made up of the single coat that contains macromolecular material, its shortcoming is: life of product is low, easily breakdown, weatherability is poor.And the interface between electric charge barrier layer and charge generating layers, charge generating layers and charge transport layer is the interface on plane, the shortcoming of this interfacial structure is: a little less than the interface binding power, in use peel off easily, be easy to generate interference figure, influence the printing output quality.
Summary of the invention
The purpose of this utility model is to provide a kind of can improve the electric charge barrier layer breakdown characteristics, by simplifying product processes, reduces production costs, and can improve the organic photoconductor of the sandwich construction of product percent of pass.
Further purpose of the present utility model is to provide a kind of can reduce the incident diffraction of light, improves diffuse effect, thereby improves the quality of image, prevents to interfere the appearance of image; And can improve the organic photoconductor of the sandwich construction of adhesion between the coating and intermiscibility.
For realizing the purpose of this utility model, a kind of organic photoconductor of sandwich construction, comprise conducting base, and the electric charge barrier layer, charge generating layers and the charge transport layer that cover the conducting base surface from inside to outside successively, described electric charge barrier layer is that the coat by the oxide layer on conducting base surface and pbz polymer material is composited, and has a large amount of microcellular structures in the oxide layer adjacent with coat.
For realizing further purpose of the present utility model, a kind of organic photoconductor of sandwich construction also comprises: have at least in the interface between the interface between the interface between described oxide layer and coat, coat and the charge generating layers, charge generating layers and the charge transport layer on the interface to have wave structure;
Interface between described surface oxide layer and the coat is provided with wave structure, and is planar structure on the interface between the interface between coat and the charge generating layers, charge generating layers and the charge transport layer;
Being planar structure on the interface between described surface oxide layer and the coat, is wave structure on the interface between coat and the charge generating layers, is planar structure on the interface between charge generating layers and the charge transport layer;
Being planar structure on the interface between described surface oxide layer and the coat, is planar structure on the interface between coat and the charge generating layers, is wave structure on the interface between charge generating layers and the charge transport layer;
Being wave structure on the interface between described surface oxide layer and the coat, is wave structure on the interface between coat and the charge generating layers, is planar structure on the interface between charge generating layers and the charge transport layer;
Being wave structure on the interface between described surface oxide layer and the coat, is planar structure on the interface between coat and the charge generating layers, is wave structure on the interface between charge generating layers and the charge transport layer;
Being planar structure on the interface between described surface oxide layer and the coat, is wave structure on the interface between coat and the charge generating layers, is wave structure on the interface between charge generating layers and the charge transport layer;
Be wave structure on the interface between interface between interface between described surface oxide layer and the coat, coat and the charge generating layers, charge generating layers and the charge transport layer;
Described compound electric charge barrier layer thickness is between the 1-20 micron, and oxidated layer thickness wherein is between the 0.5-16 micron;
Described compound electric charge barrier layer thickness is preferably between the 1-10 micron, and wherein thickness of oxide layer is between the 0.5-4 micron;
The utility model has the advantages that: this optical conductor production technology is simpler, and technology controlling and process is convenient, and properties of product are stable, and qualification rate is higher; Adopt the print quality of exporting behind this optical conductor good, long service life, integrated cost is lower.
Be described in further detail below in conjunction with the organic photoconductor of accompanying drawing the utility model sandwich construction:
Description of drawings
Fig. 1 is the structural representation of the organic photoconductor of a kind of sandwich construction of the utility model;
Fig. 2 is that the cuing open of organic photoconductor of second kind of sandwich construction shown structural representation;
Fig. 3 shows structural representation for the cuing open of organic photoconductor of the third sandwich construction;
Fig. 4 is that the cuing open of organic photoconductor of the 4th kind of sandwich construction shown structural representation;
Fig. 5 is that the cuing open of organic photoconductor of the 5th kind of sandwich construction shown structural representation;
Fig. 6 is that the cuing open of organic photoconductor of the 6th kind of sandwich construction shown structural representation;
Fig. 7 is that the cuing open of organic photoconductor of the 7th kind of sandwich construction shown structural representation;
Among the figure: 1, conducting base, 2, electric charge barrier layer, 21, oxide layer, 22, coat, 3, charge generating layers, 4, charge transport layer, 5, microcellular structure.
Embodiment
As shown in Figure 1, a kind of organic photoconductor of sandwich construction, comprise conducting base 1, and the electric charge barrier layer 2, charge generating layers 3 and the charge transport layer 4 that cover conducting base 1 surface from inside to outside successively, electric charge barrier layer 2 is that the coat 22 by the oxide layer 21 on conducting base 1 surface and pbz polymer material is composited, and has a large amount of microcellular structures in the oxide layer 21 adjacent with coat 22.The pore size of these microcellular structures differs, and is irregular shape and is distributed in the gasification layer 21.If the surface in oxide layer 21 does not apply polymer material layer, then the microcellular structures in the oxide layer 21 being required can be very high, requires pore size to try one's best little and reach unanimity, and therefore, the production cost of this oxide layer is higher, and quality is restive.
Shown in Fig. 1 to 7, have at least on the interface in the interface between interface between interface between oxide layer 21 and coat 22, coat 22 and the charge generating layers 3, charge generating layers 3 and the charge transport layer 4 and have wave structure, this wave structure can improve the diffuse effect of incident light at this, prevent the interference of image, improve the quality of image, and undulatory faying face can improve the adhesion between above-mentioned each layer and the layer, further guarantees the quality of product.
As shown in Figure 1, the interface between described surface oxide layer 21 and the coat 22 is provided with wave structure, is planar structure on the interface between the interface between coat 22 and the charge generating layers 3, charge generating layers 3 and the charge transport layer 4.
As shown in Figure 2, be planar structure on the interface between described surface oxide layer 21 and the coat 22, be wave structure on the interface between coat 22 and the charge generating layers 3, be planar structure on the interface between charge generating layers 3 and the charge transport layer 4.
As shown in Figure 3, be planar structure on the interface between described surface oxide layer 21 and the coat 22, be planar structure on the interface between coat 22 and the charge generating layers 3, be wave structure on the interface between charge generating layers 3 and the charge transport layer 4.
As shown in Figure 4, be wave structure on the interface between described surface oxide layer 21 and the coat 22, be wave structure on the interface between coat 22 and the charge generating layers 3, be planar structure on the interface between charge generating layers 3 and the charge transport layer 4.
As shown in Figure 5, be wave structure on the interface between described surface oxide layer 21 and the coat 22, be planar structure on the interface between coat 22 and the charge generating layers 3, be wave structure on the interface between charge generating layers 3 and the charge transport layer 4.
As shown in Figure 6, be planar structure on the interface between described surface oxide layer 21 and the coat 22, be wave structure on the interface between coat 22 and the charge generating layers 3, be wave structure on the interface between charge generating layers 3 and the charge transport layer 4.
As shown in Figure 7, be wave structure on the interface between the interface between the interface between described surface oxide layer 21 and the coat 22, coat 22 and the charge generating layers 3, charge generating layers 3 and the charge transport layer 4.
In addition, also can all adopt planar structure on above-mentioned surface oxide layer 21 and the interface between interface, charge generating layers 3 and the charge transport layer 4 between the interface between the coat 22, coat 22 and the charge generating layers 3.
In each above-mentioned embodiment, described compound electric charge barrier layer 2 thickness are between the 1-20 micron, and oxide layer 21 thickness wherein are between the 0.5-16 micron; But if reach better effect, then described compound electric charge barrier layer thickness is preferably between the 1-10 micron, and wherein the thickness of oxide layer 21 is between the 0.5-4 micron.

Claims (11)

1. the organic photoconductor of a sandwich construction, comprise conducting base (1), and the electric charge barrier layer (2), charge generating layers (3) and the charge transport layer (4) that cover conducting base (1) surface from inside to outside successively, it is characterized in that: described electric charge barrier layer (2) is to be composited by the oxide layer (21) on conducting base (1) surface and the coat (22) of pbz polymer material, has a large amount of microcellular structures in the oxide layer (21) adjacent with coat (22).
2. the organic photoconductor of a kind of sandwich construction according to claim 1 is characterized in that: have at least on the interface in the interface between the interface between the interface between described oxide layer (21) and coat (22), coat (22) and the charge generating layers (3), charge generating layers (3) and the charge transport layer (4) to have wave structure.
3. the organic photoconductor of a kind of sandwich construction according to claim 2, it is characterized in that: the interface between described surface oxide layer (21) and the coat (22) is provided with wave structure, and is planar structure on the interface between the interface between coat (22) and the charge generating layers (3), charge generating layers (3) and the charge transport layer (4).
4. the organic photoconductor of a kind of sandwich construction according to claim 2, it is characterized in that: be planar structure on the interface between described surface oxide layer (21) and the coat (22), on the interface between coat (22) and the charge generating layers (3) is wave structure, is planar structure on the interface between charge generating layers (3) and the charge transport layer (4).
5. the organic photoconductor of a kind of sandwich construction according to claim 2, it is characterized in that: be planar structure on the interface between described surface oxide layer (21) and the coat (22), on the interface between coat (22) and the charge generating layers (3) is planar structure, is wave structure on the interface between charge generating layers (3) and the charge transport layer (4).
6. the organic photoconductor of a kind of sandwich construction according to claim 2, it is characterized in that: be wave structure on the interface between described surface oxide layer (21) and the coat (22), on the interface between coat (22) and the charge generating layers (3) is wave structure, is planar structure on the interface between charge generating layers (3) and the charge transport layer (4).
7. the organic photoconductor of a kind of sandwich construction according to claim 2, it is characterized in that: be wave structure on the interface between described surface oxide layer (21) and the coat (22), on the interface between coat (22) and the charge generating layers (3) is planar structure, is wave structure on the interface between charge generating layers (3) and the charge transport layer (4).
8. the organic photoconductor of a kind of sandwich construction according to claim 2, it is characterized in that: be planar structure on the interface between described surface oxide layer (21) and the coat (22), on the interface between coat (22) and the charge generating layers (3) is wave structure, is wave structure on the interface between charge generating layers (3) and the charge transport layer (4).
9. the organic photoconductor of a kind of sandwich construction according to claim 2 is characterized in that: be wave structure on the interface between the interface between the interface between described surface oxide layer (21) and the coat (22), coat (22) and the charge generating layers (3), charge generating layers (3) and the charge transport layer (4).
10. according to the organic photoconductor of any one sandwich construction in the claim 1 to 9, it is characterized in that: described compound electric charge barrier layer (2) thickness is 1---and between 20 microns, oxide layer wherein (21) thickness is 0.5---between 16 microns.
11. the organic photoconductor according to any one sandwich construction in the claim 1 to 9 is characterized in that: described compound electric charge barrier layer (2) thickness is preferably in 1---between 10 microns, wherein the thickness of oxide layer (21) is 0.5---between 4 microns.
CN2009200471945U 2009-07-06 2009-07-06 Multilayer-structure organic photo conductor Expired - Lifetime CN201449517U (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN2009200471945U CN201449517U (en) 2009-07-06 2009-07-06 Multilayer-structure organic photo conductor

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN2009200471945U CN201449517U (en) 2009-07-06 2009-07-06 Multilayer-structure organic photo conductor

Publications (1)

Publication Number Publication Date
CN201449517U true CN201449517U (en) 2010-05-05

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Application Number Title Priority Date Filing Date
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Country Status (1)

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CN (1) CN201449517U (en)

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AV01 Patent right actively abandoned

Granted publication date: 20100505

Effective date of abandoning: 20090706