DE2800394A1 - SINGLE-STAGE EXPOSURE AND DEVELOPMENT PROCESS AND ELECTRON RADIOGRAPHIC DEVICE WITH SINGLE-STAGE EXPOSURE AND DEVELOPMENT - Google Patents

Description

X / p 9215

XONICS, INC., 6849 Hayvenhurst Avenue, Van Nuys, Calif. 91406, USA

One-step exposure and development process as well as electron radiographic One-step exposure and development setup

Summary: The subject of the invention is an electron radiographic Device for producing x-ray images by producing a visible image on a dielectric plate in the Imaging chamber. A pair of electrodes are provided, between which there is a gap filled with liquid; the liquid can take various forms and electrophoretic toner particles are dispersed in the liquid. A dielectric plate is placed on an electrode and X-rays are directed past the object onto the liquid to generate electrons and to generate positive ions in the gap. The electrons and the positive ions are applied to the corresponding electrodes through an attached to the electrodes applied electric field directed. The toner particles are directed onto the dielectric plate by the electrostatic charges and placed on it to create the visible image. The liquid

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Accounts: Bayerische Vereinsbank (BLZ 750 200 73) 5 839 300 Postscheck München 893 69-801

Place of jurisdiction is Regensburg

₅ 2 280039A

speed is impermeable to X-rays and electrically non-conductive and can be a solvent with a gas component or a nonionic metal component dissolved therein, or a liquefied gas.

The invention relates to electron radiographic devices, as shown, for example, in U.S. Patents 3,873,833 and 3,965,352 and, in particular, to new and improved apparatus in which the visible image is generated in the imaging chamber where exposure and development take place in one operation.

In the conventional electron radiographic devices, a dielectric receiving plate disposed on one of the electrode surfaces in a gap between a pair of electrodes. An x-ray source is on the gap on the x-ray receiving object directed past, and incoming x-ray photons create electrons and positive ions in an x-ray opaque Fluid in the gap that is attracted to the respective electrodes. Charges are deposited on the dielectric containment device collected and yielded a latent electrostatic image of the object; this picture is converted into a visual picture according to the conventional one Xerography technique developed, where the density of the deposited toner particles is a function of the size of the electrostatic charge.

In these known devices, the mounting plate with the electrostatic image is moved from the imaging chamber into a development chamber, where the toner particles are deposited, after which the toner with the mounting plate by taking appropriate precautions, e.g. heating,

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Resin encapsulation or lamination is bound. These facilities require separate places for the imaging chamber and the developing chamber as well as a device to the recording plate with the electrostatic Transport the image without damaging the static image.

The object of the invention is to provide a new and improved electron racliographic To provide means for allowing X-ray exposure and development of a visible image in the imaging chamber

visible

and in which the development of the / image is carried out at about the same time occurs with the X-ray exposure, resulting in no transfer the plate carrying only the electrostatic image is required on a separate developer station.

In accordance with the present invention, both a radiographic method proposed as a radiographic device, with a dielectric receiving plate in a gap between an anode and a Cathode, an X-ray absorbing and electro * Nine and positive ion emitting liquid is present in the gap, and a plurality of electrophoretic particles in the liquid are dispersed, which acts as a toner. At the time the X-ray source is acted upon by pulses, an electrical energy source is connected to the electrodes and generates an electrical energy Field in the gap that moves the electrons and positive ions to opposite electrodes, creating an electrostatic image on the receiving plate is produced. The electrophoretic particles are selectively attracted to the dielectric plate by the electrostatic charges and result in the visible image on the plate. The plate with the visible image is removed from the gap and the toner particles can be fixed in place, e.g., by heating, encapsulating in resin, lamination, or the like.

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1 ₄ 28UÜ39A

Further features of the invention are the subject of the subclaims.

The invention is explained below in conjunction with the drawing an exemplary embodiment explained. Show it:

Figure 1 is a vertical sectional view of an x-ray imaging system according to a preferred embodiment of the invention, and

Figure 2 is a timing diagram illustrating a preferred mode of operation of the system according to Fig. 1 represents.

An imaging system that is used in particular to create x-ray images the chest is suitable, has an X-ray source 10, which is at a distance from a recording housing !! offset and arranged so that the person to be photographed or the object to be photographed is placed between the X-ray source and the housing, preferably against the plate 13 of the housing.

A take-up supply roll 16, an image chamber 17 and a toner melting station 19 are provided in the housing 11. Hinged doors 20, 21 provide access to the interior of the housing. The dielectric Take-up plate 25 is fed from roller 16 through imaging chamber 17 and melting station 19 via drive rollers and idler rollers and exits the housing through an exit slot 26. The take-up plate can be advanced by motorized rollers or by hand will. However, other configurations of the imaging chamber can also be used, also those which can be taken from the prior art described above can be used. As a fixation device a heater-fuser is shown, but it can also other devices for fixing toner particles to the receiving plate can be used, for example a coating with a other plate and resin encapsulating the toner; that can fix

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outside or inside the housing.

The mapping chamber 17 has a vessel 30 with a U-shaped passage 31, which is inside a channel-shaped part 32 of the housing 11 is arranged; heat-insulating material 33 is preferably arranged around the vessel 30. In the preferred embodiment, one is Cooling unit 34 connected to vessel 30 to maintain the vessel and contents at a temperature below ambient. The electrodes 37 and 38 are fastened in the vessel 30 at a distance from one another and form a gap 39 between them.

The plate 13 of the housing, the insulating material 33 and the wall of the The vessel 30 between the X-ray source and the electrode 37, as well as the electrode 37 itself, should be made of materials with low X-ray absorption exist. Corresponding materials for the electrodes 37 are given in the aforementioned US Pat. No. 3,774,029. To the electrodes 37, 38, a high-voltage source 40 is connected via lines 42, 43 Rollers 44, 45 are held in place.

A liquid 50 is introduced into the passage 31 of the vessel 30, which fills the gap 39. This liquid is an X-ray impermeable, electrically non-conductive liquid, it is with the embodiment shown neopentane with xenon dissolved therein. Other suitable liquids are, for example, aliphatic hydrocarbons, ZoB. Hexane. The housing 11 is preferably made airtight and filled with xenon at atmospheric pressure to prevent contamination of the neopentane solvent by atmospheric constituents. The amount of gas that can be dissolved in the solvent increases with decreasing temperature of the solvent, and it has been found that the amount of xenon that can be dissolved in neopentane, thereby

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can be kept about twice the value that the neopentane on a temperature of -20 is kept. However, the system can also be operated at room temperature, in which case a cooling unit and thermal insulation is not required, preferably by keeping the chamber and the gap with liquid at a pressure higher than ambient will. The amount of gas that can be dissolved in the solvent increases as the partial pressure of the gas in the housing 11 is increased. One has found that the amount of xenon that can be dissolved in neopentane doubles by doubling the xenon pressure in the housing 11 can be, for example with the aid of a pressure source 52 which is connected to the housing via the line 53. Both the reduced Temperature as well as the increased pressure can be used to increase the xenon concentration in the liquid.

Another suitable liquid absorber is tetramethyltin Sn (CH ₃ ). Which absorbs X-rays without the need for dissolved xenon or the like. There is therefore no need for cooling or pressure charging.

Electrophoretic toner particles 55 are dispersed in the liquid 39. The electrophoretic particles can be conventional, e.g. organometallic pigments or metal oxides as base or core be with a dielectric coating. Preferably, the liquid 39 with the toner particles 55 through the gap with the aid of a Liquid circulation system 56 set in circulation, which includes a pump and may have a container to maintain a fresh supply of particle-carrying liquid in the gap between the electrodes

A control circuit 60 is connected to the electrode supply source 40 and to the Supply source 61 placed for the X-ray tube 10. Preferably the X-ray tube so pulsed by the control circuit that the

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to ^ 8 ί J ü 3 9 4

desired radiation for exposure is obtained, and the supply source for the gap is switched on at the time the X-ray tube is pulsed and can be switched on for a short period of time after X-ray pulse are maintained, typically a few milliseconds. A typical timing diagram for the operation of the control circuit 60 is shown in FIG.

The electron radiographic system with the electrophoretic toner particles in the gap works similarly to the systems according to the patent specifications mentioned at the beginning. The incoming x-ray photons will absorbed by the liquid in the gap, generating electrons (negative ions) and positive ions. In the electric field between the electrodes the electrons move to the anode and the positive ions to the cathode. The dielectric plate is the anode, and the negative Ions are collected on the dielectric plate in an image pattern that reflects the spatial density changes of the absorbed X-rays is equivalent to. The positive ions are attracted to the cathode.

The electrode and X-ray supply sources are switched off, and the Imaging chamber has a latent electrostatic image of negative polarity on the dielectric plate. This latent electrostatic Image creates an electric field in the liquid-filled gap, which attracts positively charged toner particles to the dielectric plate, which represent a visible radiographic image. The plate is then removed and the toner image fixed, making a permanent radiography is obtained. Conversely, the dielectric containment device can be placed on the cathode with the positive ions on it are collected and negatively charged toner particles are attracted for visualization.

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Other processes can also occur. Ions leading to an electrode migrate can hit a neutral toner particle and attach to it, causing the charged toner particle to permeate the electric field moves towards an electrode and on the receiving plate hits. This is not an effective or particularly effective mode of operation because it requires a large amount of toner in the liquid is to ensure ion-toner collisions, and the toner must be selected so that charges are easily bound to it.

Toner particles can also act as X-ray absorbers, wherein correspondingly charged toner particles are generated, which are moved against the electrodes, hit the receiving plate and a present a visible image. This is another ineffective and undesirable operation. A large amount of toner is required for that Toner must be heavy to be a good X-ray absorber so that it is difficult to keep in suspension, and it is proportionate high x-ray dose required to generate an image.

Areas that are heavily exposed to the X-ray photons become heavily developed by the toner and appear dark compared to areas on the dielectric plate where there is less x-ray exposure was present. In all embodiments of the present invention, the toner particles are preferably relatively small, typically on the order of microns. The liquid absorber should also be electrically non-conductive in the gap and should have one

13 Electrical resistivity greater than 10 ohm-centimeters in operation o have a lower specific resistance for the Liquid discharges the X-ray induced electrostatic image so that a visible image can be obtained is very difficult. The liquid should be impervious to X-rays or radiopaque, i.e. the fluid should be incoming

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Absorb X-ray siralphoions and generate electrons and positive ions. Also, the absorbent Aiome the riUssigkeii to an atomic number of at least 17 and preferably 35 mindesiens have ₀ With respect to the liquid absorber is vorerwiilinie the
See U.S. Patent 3,965,352.

H (! : I ■ ··, H / Ü Π '. ⁷

Claims (8)

280039A claims 1. Radiographic equipment for operation in conjunction with a X-ray source with a pair of electrodes representing anode and cathode, which form a gap between them, with a device for positioning a dielectric plate in this gap on one of the electrodes, the plate being removable from the gap, one X-ray absorber and emitter for electrons and positive ions in the gap between anode and cathode, the emitter being one for X-ray impermeable, electrically non-conductive liquid, with an atomic number of at least 17, and with a device to allegen an electrical supply source to the electrodes, to electrons against the anode and positive ions against the cathode to attract, characterized in that a plurality of electrophoretic particles (55) are present in the liquid (50), and that a switching arrangement (60) acts on the X-ray source (10) with pulses and at the same time actuates the device (40), to create an electric field in the liquid (50) between the electrodes (37, 38) so that electrons and positive ions for Anode and cathode are attracted, which subsequently attract charged particles (55) to the dielectric plate (25), so that a visible Image is formed on the plate. 2. Radiographic device according to claim 1, characterized in that a device (56) is provided which sets the liquid (50) with the electrophoretic particles (55) through the gap (39) in circulation. 3. Radiographic device according to claim 2, characterized in that that a device (19) the electrophoretic particles (55) fixed to the dielectric plate (25). 809828/0877 ORIGINAL INSPECTED 280Q394 4. Radiographic device according to claim 3, characterized in that that transport rollers move the plate (25) from the gap (39) to the fixing device (19), 5. Method of creating a visible image on a dielectric Plate, characterized in that the dielectric plate is arranged on an electrode in a gap between anode and cathode, wherein the electrodes are positioned in the vicinity of an object to be imaged, allowing X-rays to pass through the object and one of the electrodes can be guided that incoming x-rays to be absorbed in the gap in that an / X-rays in the gap impermeable, electrically non-conductive liquid with an atomic number of at least 17 and electrophoretically ^ particles, the electrons and generate positive ions in the liquid, keep electrons or negatively charged ions to the anode and positively charged ions are attracted to the cathode by applying a potential is applied to the electrodes at the time the X-rays are absorbed, with the ions subsequently then attract the electrophoretic particles to the dielectric plate so that a visible image is formed, and that the dielectric Plate with the deposited electrophoretic particles is removed from the gap. 6. The method according to claim 5, characterized in that the electrophoretic Particles are fixed on the dielectric plate. 7. The method according to claim 5, characterized in that the liquid with the electrophoretic particles is put into circulation through the gap. 6098 28/0877 7800394 8. The method according to claim 7, characterized in that the dielectric Plate with the electrophoretic particles on it is heated so that the particles are bound to the plate. 9. The method according to claim 5, characterized in that first electrons and moving positive ions to the respective electrodes with an applied potential forming an electrostatic charge image generated on the dielectric plate, and that then electrophoretic particles without applied potential to the dielectric Plate can be moved to form a visible image. 8 (J W μ / B / 0 8 7 7