DE1772657B2 - METHOD FOR PRODUCING A FLEXIBLE, ENDLESS, TAPE-SHAPED, LAYERED CARRIER - Google Patents

Description

The invention relates to a method of manufacture a flexible, endless, band-shaped layer carrier.

For example, from GB-PS 6 72 767 known electrophotographic imaging process is carried out on a suitable recording material generates an electrostatic charge image, which with the help of a developing powder, which is in the non-discharged areas of the recording material adheres, can be made visible and fixed.

Since the discovery of the photoconductivity of pure amorphous (gaseous) selenium, selenium has been the in the most widely used material for the recording material in commercial electrophotography become.

For commercial purposes, the selenium is generally applied to a rigid support, such as a non-compliant cylindrical drum used for the automatic Operation of copier machines is well suited. More recently, US Pat. No. 3,146,688 however, a flexible substrate for the photoconductive recording material described, this Layer carrier consists of a flexible tape. Such a flexible layer support is a enlarged reproduction f! uc e get what the achievable reproduction speed increases.

Electrophotographic recording materials used heretofore in the form of a flexible endless belt, however, still have a number of disadvantages. that the electrophotographic recording material in the area of the joint or seam of the Band a decreased sensitivity besiu.i Perner the seam at which the ends of the tape are joined is a mechanically weaker one Area in which after repeated bending stresses a break in the tape can occur. In addition, the radius of curvature of the Tape in the area of the seam from the radius of curvature of the rest of the tape, causing a distortion of the electrophotographic properties in this area

The invention is therefore based on the object of a method for producing an improved flexible To create endless support, wherein a flexible, endless support is to be produced that over its entire scope has uniform mechanical properties and the production of a electrophotographic recording material with uniform sensitivity over the entire surface allowed. Ultimately, the radius of curvature of the substrate produced should be over the entire The circumference remains the same with repeated bending and loading.

This Auigabe is achieved according to the invention in that the ends of an electrically conductive foil tape be placed on a support cathode that an electrically insulating mask by a predetermined Amount protruding beyond each end of the tape to form a restricted channel. that a conductive anode is arranged resting on the channel, that an electrolyte solution through the Channel is passed through in contact with the anode, and that between support cathode and anode a Tension is maintained until a smooth that Seam connecting ends of the tape is formed.

A layer carrier produced by the method according to the invention thus consists of an electrical one conductive foil tape, the ends of which are united with the help of an electrolytic metal deposit. The electrolytic precipitate, which serves as a connecting means, has a strong material connection, so that the connection point does not represent an area of mechanical weakening. The electrolytic The connecting seam is smooth and has mechanical properties that are at least those of the rest of the band material are equivalent.

According to one embodiment of the invention, an anode made of nickel and an electrolyte solution containing a metal cation and nickel sulfamate are used. With the aid of such an electrolyte, satisfactory precipitates are obtained quickly and uniformly. It has been found to be advantageous that the amount by which the mask protrudes beyond the end of the foil tape is chosen to be equal to the thickness of the tape, provided the Reynolds number of the electrolyte inside the channel is less than 2200. In contrast, with a Reynolds number of the electrolyte in the channel of more than 2200, it has been found to be advantageous that the amount by which the mask protrudes beyond each end of the tape is equal to the E ^; n- to twice the thickness of the foil tape is chosen.

This can lead to particularly favorable results

be achieved that a film tape with a thickness of, φ 08 to 0.25 mm is used.

^ Pie invention will be referred to below on the basis of

'Embodiments and under Brjug described in more detail on the drawing. In this shows

1 shows a schematic representation of a device suitable for forming a smooth connecting seam at the ends of a film strip,
FIG. 2 shows a section along the line 2-2 in FIG. 1,
Fig.3 a cross section comparable to Fig.2 and

F i g. 4 is a perspective view of the FIG. 3 device shown.
As can be seen in FIG. 1, a device for

'inventive formation of a seam provided with a container 10, which for receiving a Electrolyte 11 is used. With this electrolyte it can

* For example, the solution mentioned with a Act metal cation and nickel sulfamate. A heating element Ϊ2 is provided on the bottom of the container 10, which is used to set the temperature of the electrolyte. The electrolyte 11 is supplied through a line 13 pumped by a pump 14 to a deposition or electrolyzer 16 which has an anode 20 and a cathode 22 includes. Then the solution is returned to the container 10, which is also called Reservoir is used. A direct current source 24 is connected to the anode and the cathode, the Current is controllable. The line 13 and the connections provided for it should be made of one material that keeps the organic pollution of the system to a minimum. To this end polyvinyl chloride tubes and telephone connections are suitable.

The anode 20, which consists of the metal to be deposited, has the shape of a channel at its lower part 26 placed over the ends of a film tape 30 along which a seam will be formed target. The electrolyte closes along the seam, which is sealed off from the atmosphere. around a to achieve a high linear flow velocity and thus a faster deposition.

The ends of the foil strip 30 running parallel to one another are on the upper side of the cathode 22 arranged, which serves as a support for the seam to be formed. It should be noted that the flat shape of the Support cathode 22 a flat and smooth seam is achieved on the side facing the cathode. the Ends of the tape are held in place during electroplating, for example by pins 31 iF i g. 4) on the support cathode, which engage in holes at the ends of the tape.

In order to control the metal deposition on the strip ends and in the sense of a smooth seam formation, two mask parts 35 are provided adjustable over the edges along the seam. It should be noted that the edges of the mask parts protrude beyond the tape ends by a certain distance h. This distance h changes with the Reynolds number of the electrolyte and with the strip thickness in the manner described above. It is believed that this creates an area of reduced electrolyte flow, thereby reducing deposition in the area of the seam edges where the electric fields are normally stronger.

An elastic cushion 38 is provided as a seal between the anode 20 and the mask parts 35. It consists of a suitable material, such as B. silicone

1 1 U..I.

In Fig. 3 and 4 is a preferred embodiment a deposition device shown in which instead of the solid anode according to Figure 2 or several pieces of the metal to be deposited are provided. The conductive plates 60 are in the Side walls of a housing 61 embedded, which is made of a suitable electrical insulating material, such as. B. Typical substances for the plates are made up of silicone rubber, which does not chemically interact with the electrolyte

ίο are supposed to react are titanium, platinum and prolytic graphite

Between the plates 60 there is an elongated metal piece 62 which metal ions for the solution supplying It should be noted that as intended in the example shown in Figure 2 embodiment, two parts of the mask 35 such that it by an amount beyond the ends of the band 30 h protrude. A metal frame 68 embedded in the housing 61 forms a rigid structure which enables a pressure effect sufficient to form a seal on both sides of the belt. In this way, an endless flexible belt is provided with a seam that is smooth and flat on both sides.
The best material for the tape is metal.

However, high conductivity is not required and almost any structurally suitable material which is more conductive than the photoconductive recording material can be used. Substances with a specific resistance of approx. 10 ⁸ ohm cm are generally sufficient as a support for a photoconductive layer. However, it is more beneficial to use fabrics with a resistance of less than about 10 ⁵ ohm cm. Suitable materials are brass, aluminum, copper, nickel, zinc, chromium, steel, corrosion-resistant steel, paper, plastic, glass and other foils with a conductive coating, for example ar.s tin oxide, non-coated conductive plastics, types of rubber, etc. The tape preferably has a thickness of approx. 0.08 to 0.25 mm.

The first step in carrying out the method of the invention is to prepare the tape. It is important if a good connection is to be achieved at the seam. The ends of the band are cleaned by passing them between grinding wheels, the surface of which is free of organic Fats are. A typical abrasive is an aqueous slurry of alumina or other suitable inorganic substances. This type of cleaning enables oily to be removed Film and smooth the cut edges so that maximum adhesion during electrodeposition is achieved. Suitable electrochemical cleaning methods can also be used. For example, electrolytic cleaning is in

alkaline or acidic solutions, by etching, rinsing, etc. possible. It is understandable that the Cleaning prior to placing the tape in a coating device or in a liquid process must be done in conjunction with the coating device.

The next step is to form a smooth and flat seam through the electrical Deposition of conductive material along the ends of the tape. Typical for electrical deposition suitable metals are nickel, copper, iron, chromium, zinc and the noble metals. Preferred is nickel used because its mechanical properties within a wide range by changing the

r
<i
ri it

Parameters can be set during deposition. Any suitable electrolytic nickel solution can be used. A typical aqueous nickel sulfamate solution is as follows built up

material

Volume or
Parts by weight

reduced electrolyte flow is generated, whereby the amount of deposition is reduced at the edge areas where the electric fields normally occur are stronger. It was also found that the current density and the deposition rate the ends of the tape are reduced as they are a greater distance from the anode within the solution to have. It should be noted that with seam widths from 2 to approx. 30 times the tape thickness in this mask arrangement

Nickel sulphamate concentrate
in water
Nickel chloride
Boric acid

343-600 cm Vl

Some examples of other suitable electrolysis are described in US Pat. No. 2,318,592.

The electrolytic solution is heated to a temperature of approx. 50 ^° C. before it is introduced into the electrolysis device in which the strip ends are aligned for connection to a deposited metal.

The electrolysis device contains an anode, which consists of a metal to be deposited, and two cathodes. A cathode has the shape of the tape ends to be joined together. The other cathode is a flat support cathode on which the tape ends rest. In this way it is possible to achieve a flat and even seam on one side of the tape. On the other side of the hinge, this is done in a manner to be described. The anode and the cathode are connected to a power source which generates a current density of approx. 0.1 to approx. 0.86 amperes / cm ² in the area of the seam.

The pad cathode can be made of any suitable material, such as stainless steel, chrome, and titanium consist of prolytic graphite. This fabric is cleaned and treated to a beneficial effect To secure the adhesion of the electrically deposited or galvanized metal on the tape.

The seam to be formed should be smooth and flat on both sides. To achieve this, the rate of deposition of the metal at the seam must be controlled accordingly. For this purpose, a mask can optionally be brought into the flow path of the electrolyte in such a way that it protrudes over the channel formed by the strip ends and the support cathode. The exact position of the mask in relation to the tape ends depends on factors such as the viscosity of the electrolyte, the density, the flow velocity and the current density. This relationship results from the formula for the Reynolds number N _{r of} the electrolyte along the seam, which reads as follows:

good results have been achieved. For best results, the precipitation zone should be around 12.7 to 4-47 cm Vl 25.4 cm longer than the tape, so that also on the

31.2-47 cmVl edge of the seam uniform flow conditions

to rule. Any excess metal build-up can

be cut off after the seam has been formed, so that a smooth seam results

The mask can be made of any suitable material. Glass is preferred because of its strength, wettability with electrolyte and its non-conductive properties

ίο properties used.

The last process step in the production of a continuous, flexible, electrophotographic recording material is the deposition of a layer of photoconductive insulating material on the conductive surface. Everyone

suitable substance such as B. vitreous selenium as well as any deposition process can be used for this purpose, because these manufacturing steps do not belong directly to the invention. Many suitable deposition methods are in US patents 26 57 152,

27 53 278 and 29 70 906 described. In general, the photoconductive layer is deposited by Vakuurnaufdampfung of selenium onto a substrate, including a temperature of at least about 20 ⁰ C, generally in the range between 40 ⁰ C and 90 ⁰ C, and preferably in

of the order of about 50-C. The deposit the selenium layer is interrupted when the layer has the desired thickness. for example 10 to 200 Microns, preferably about 20 to 50 microns. The deposit is usually at a pressure of

less than approximately 1 micron of mercury.

The following examples serve to illustrate the invention and are not intended to be a restriction be understood.

45

example 1

in which L the characteristic linear dimension of the device through which the flow passes y the linear velocity ρ the density and μ the absolute viscosity tst

It was found that for values of N _r less than approx. 2200, the mask should protrude into the area of the tape seam with an amount corresponding to the tape thickness, which applies to the mentioned tape thicknesses.If N _{r is} greater than approx. 2200, this is Ratio of this amount to the band thickness approx. 1: 2.

It is believed that by this arrangement of the mask opposite the band edges an area The brass foil, 0.1 mm thick and 29 cm wide, is placed between a nickel anode and a corrosion-resistant

resistant steel cathode in a device of the in F i g. 2 with their ends clamped at a distance of 3 mm from each other. The in the anode The existing channel has a width of approx. 3.2 mm and a height of approx. 11 mm. A glass mask is arranged in this way

that it protrudes 0.1 mm from the ends of the tape. A cleaning solution made from 10% hydrochloric acid and 90% water is pumped through the device for 3 minutes. After that, water is used to remove Cleaning solution pumped through for 30 seconds

A solution of nickel sulfamate elekfrolytische mi a specific gravity of \ 2 at 50 ⁰ C and Einei viscosity of 3.0 centipoise is at a Geschwin speed of 823 m / min, about 10 to 15 seconds lanj pumped until no more air bubbles vorhandei

are. Then a DC voltage is applied to the device with the positive pole on the cathode 22 and the negative pole at the anode 20 for approx. 15 seconds mi connected to a current density of 0.125 A / cm *, un

to etch the foil so that maximum adhesion can be achieved. After an etching time of 15 seconds, the polarity is switched. After about 40 minutes, the pump is stopped and the tape is removed from the device. The ribbon seam formed is uniformly smooth, and its strength corresponds to the strength of the ribbon. For testing purposes, the tape is subjected to more than 300,000 bends and, in the tensile test, shows a strength of over 422 kgf / cm ² . Changes in the physical properties are not observed.

Example 2

A seam for an endless, flexible belt is produced similarly to Example 1, with the difference that a foil made of corrosion-resistant steel instead of a brass foil and another cleaning solution is used. The results agreed with those from Example 1.

Examples 3 and 4

A 40 micron thick layer of amorphous selenium is placed on the endless belts of Examples 1 and 2 below evaporated under the conditions described above in vacuo. It turns out that the electrophotographic Recording tape has better bending properties and the same electrical properties as normal Has selenium plates. Excellent xerographic copies are made with this flexible tape

The term "nickel" is not intended to refer to chemical or obtain commercially pure nickel because of various impurities or alloying elements can often be present in a substantial proportion without the benefit of the device zn affect. The term "nickel" should therefore also refer to substances that are essentially au; Nickel exist or their physical properties largely return to this metal as a component are lead.

For this purpose 2 sheets of drawings

Claims (5)

Patent claims: 1. A method for producing a flexible, endless, band-shaped substrate, characterized in that the ends of an electrically conductive foil strip (30) are placed on a support cathode (22) that an electrically insulating mask (35) by a predetermined amount (h) extending beyond each end of the tape (30) to form a restricted channel, placing a conductive anode (20) overlying the channel, allowing an electrolyte solution (11) through the channel in contact with the anode (20) ) is passed through, and that a voltage is maintained between the support cathode and anode until a smooth seam connecting the ends of the band (30) is formed 2 The method according to claim 1, characterized in that that an anode (20) made of nickel and an electrolyte solution (11) with a metal cation and Nickel sulfamate is used. 3. The method according to claim 1, characterized in that the amount (h) by which the mask (35) protrudes beyond each end of the tape (30) is equal to the thickness of the tape (30). when the Reynolds number of the electrolyte solution within the channel is less than 2200 4. The method according to claim 1, characterized in that the amount (h) by which the mask (35) protrudes over each end of the tape (30) is equal to 1 to 2 times the thickness of the tape (30) when the Reynolds number of the electrolyte solution in the channel is greater than 2200. 5. The method according to claim 1, characterized in that a film strip (30) with a thickness from 0.08 to 0.25 mm is used.