DE1563173C - Device for generating a direct current corona discharge current - Google Patents

Description

The invention relates to a device for generating a direct current corona discharge current, especially for loading. Areas in electrographic processes, with. one to one AC voltage source connected discharge electrode and a control grid in the corona discharge current, which is connected to a source of constant potential.

In known devices of this type (cf. US Pat. No. 2,777,957, Fi g. 1,14) the is The current supplied to the discharge electrode is rectified, for which purpose it is necessary to switch between the alternating ' voltage source and the discharge electrode a high voltage rectifier and a smoothing device to switch. Because the rectifier is dimensioned for the full power of the discharge electrode must be, requires the use of a direct current corona discharge current instead of an alternating current corona discharge current, a considerable one additional effort. The control grid has in these known devices as well as in the known ones Devices (see. U.S. Patent 2,879,395, Fig. 1), which with an alternating current corona discharge current work, the task of reducing the surface charge of those exposed to the corona discharge To limit the area to a value that cannot lead to a breakdown.

The invention is based on the object of a device for generating a. DC corona discharge current to create that is both simple and cheap. Starting from a device of the type mentioned, this object is achieved according to the invention in that in the A rectifier is provided via the control grid to the current path leading to the source of constant potential is.

With such an arrangement of the rectifier, only one low-voltage rectifier is required. In addition, only part of the total current drawn from the high-voltage source needs to be rectified to become, namely about 10%, which is why the rectifier only for a power of about 1% or less of the power of the rectifier in the known devices to be dimensioned needs. The resulting simplification and cheaper is considerable. Another benefit is in the additional stabilizing effect of the control grid on the spatial distribution of the corona flow to see. Finally, it is also advantageous that in the inventive arrangement of the

ίο rectifier the control grid also has a controller the phase and amplitude of the pulsating direct current corona discharge current.

In one embodiment of the invention, the rectifier is designed as a layer of a rectifying substance on the control grid, which is a particularly simple and inexpensive solution. The rectifying material can for example consist of unsensitized zinc oxide in a synthetic resin binder. In this case only negative ¹

ao ions are allowed to pass through. Of course, other materials can also be used for the rectifier layer, see above ^; that passage of the current of any desired polarity can be achieved.

According to a further embodiment of the invention, the rectifier can also be in the form of a suitable component be connected between the control grid and the source of constant potential, so that conventional control grids can be used.

Two exemplary embodiments of the invention are included Hand outlined drawing. It shows in a schematic representation:

F i g. 1 shows a vertical section and the circuit diagram of a first embodiment

■ F i g. 2 shows a vertical section and the circuit diagram of a second embodiment.

Like F i g. 1 shows, is a high voltage AC power source 2 is connected on the one hand to a corona discharge electrode 6 via a switch 4. The high voltage source 2 is on the other hand with an electrically conductive carrier layer 8 as a whole associated with 10 designated xerographic plate. On the carrier layer 8 is a photoconductive one Layer 12 is provided. Between the corona discharge electrode 6 and the plate 10 is an electrical conductive control grid 14 arranged, which via a rectifier 18 and a switch 24 with a source of constant potential, namely earth. When the corona discharge electrode 6 is activated by closing the switch 4, the grid 14 directs the alternating current equal to that from the discharge electrode 6 to the plate

. 10 would like to flow, thereby reducing the photoconductive Layer 12 with a homopolar electrostatic Charge of predetermined polarity is charged. Various methods are known to achieve a uniform To achieve charge of the photoconductive layer. These known methods, for example use a control grid or screen or relative movement between the discharge electrode and the xerographic plate 10 can be applied here.

During the positive half-cycle of the discharge current, the ions or charges that are applied to the Strike control grid 14, derived via the rectifier 18 to earth.

If, however, the corona current is negative, the rectifier 18 blocks, so that the control grid 14 very is quickly charged to a space potential that

corresponds to its location. When charging is complete, charge trapping ceases so that the charge carrier flow can pass through control grid 14 and impinge on photoconductive layer 12. At most of the frequencies found in alternating current, the control grid 14 generates a pulsating direct current corona discharge current. As FIG. 1 shows, the corona discharge electrode 6 is partially surrounded by a grounded, metallic screen 20, which serves to further stabilize the corona discharge at relatively high corona levels. The total voltage applied to the rectifier 18 is limited to approximately 200 to 300 volts. Usually only about 10 ^fl / o of that current which is drawn from the AC voltage source 2 flows through the rectifier 18. It follows that the rectifier 18 only needs to control about 1% or less of the power that would have to be controlled if it were would be connected in series with the AC voltage source 2.

The inventive device works just as well when the rectifier 18 is reversed in the Cable run is laid. The charge on the photoconductive layer 12 then has the opposite Polarity on. It has been found that the rectifier 18 is normally the alternating Corona discharge current not fully rectified. To get full rectification, a bias voltage source 22 constant potential is provided in the embodiment, which by means of the Switch 24 can be placed in the current path of the rectifier.

Fig. 2 shows another embodiment of the device according to the invention. Corresponding parts are provided with the same reference numbers. The only difference between this embodiment and that according to FIG. 1 is that instead of the separate rectifier 18 between the control grid 14 and earth, a rectifying layer 26 is provided on the grounded control grid 14. In the exemplary embodiment, this layer consists of unsensitized zinc oxide in a synthetic resin binder. However, other substances can also be used for this purpose. The polarity of the charges which are applied to the photoconductive layer 12 depends on the choice of the layer material. In the case of unsensitized zinc oxide in synthetic resin, only negative charges can pass through the control grid 14. A bias voltage source 22 can be placed in the current path of the control grid 14 by means of the switch 24. With regard to the arrangement and design of the high-voltage AC voltage source 2, the discharge electrode 6, the switch 4 located between the two and the electrically conductive carrier layer 8 of the xerographic plate 10, there are no differences compared to the embodiment according to FIG. 1.

As already mentioned, the use is according to the invention Device not limited to electrographic processes. You can also for example be arranged in a housing in which the control grid 14 is the only opening forms on the outside. By means of such a device • air ions of a certain polarity can be generated that are required, for example, in air conditioning systems that have a dust trap. It is for that A person skilled in the art can use the device according to the invention in other fields of application without difficulties to use.

It is also possible, for example, to use a thyristor to adjust the phase position of the pulse to synchronize with a network or to modulate the pulse width. Furthermore, the usual High voltage transformer can be replaced by a piezoelectric voltage source, whereby even greater economy of the device is achieved. A high voltage piezoelectric source can also be used when the device is remote from a source of electrical power Energy is to be operated.

1 sheet of drawings

Claims (3)

Patent claims: 1. Device for generating a direct current corona discharge current, in particular for charging surfaces in electrographic processes, with one connected to an alternating voltage source connected discharge electrode and a control grid in the corona discharge current that is connected to a source of constant potential is connected, characterized in that in the current path leading via the control grid (14) to the source of constant potential (22; earth) a rectifier (18; 26) is provided. 2. Apparatus according to claim 1, characterized in that the rectifier as a layer (26) is formed from a rectifying material on the control grid (14). 3. Device according to claim 1, characterized in that that the rectifier (18) between the control grid (14) and the source constant Potential (22; earth) is provided.