DE1522430C3 - X-ray film intensifying screen - Google Patents

Description

The invention relates to an X-ray film intensifying screen, consisting of a binder, luminescent particles and a dye.

In a known film of this type (see. Document for German Patent 660 874), the dye is in the Binder in dissolved or solid form.

The invention has for its object to form the X-ray film intensifying screen so that for Achieving a great sharpness of the characters that is normal from the luminescent particles on the X-ray film Incident light as little as possible and at angles that differ from the luminescent Particle outgoing light is weakened more than with the film according to the German patent 660 874.

This object is inventively achieved in that the dye cm colloidally in the form of pigment particles in the size between 10 ^-7 and 10 ^-5 is embedded in the binder.

The invention is based on the following considerations:

If the dye is dissolved in the binder, the rays emanating at an angle from the luminescent particles are only absorbed (German patent 660 874). If, on the other hand, the dye is in the form of pigment particles, the light is also scattered by these particles in addition to the absorption of the light. If the particle size as in the counter · of the invention stand (10 ~ ⁷ to 10 ~ ⁵ cm) small compared to the wavelength (λ "s 5 x 10" ⁵ cm), so occurs Rayleigh scattering. In the case of Rayleigh scattering, the light to the more scattered, the shorter the wave

it is I scattering ~ A ⁴ 1. The light emanating from a luminescent particle - usually calcium tungstate - has a measurable intensity in the entire visible spectral range. In the blue area (ie at around 4500 Å), however, the maximum of the intensity lies. The more obliquely the light rays emanating from the luminescent particles, the "redder" (Rayleigh scattering) and the weaker (long light path) these rays become through continued scattering. An X-ray film, however, has a sensitivity that is preferably in the blue spectral range. For this reason alone, the oblique, predominantly red, weak light rays emanating from luminescent particles are hardly able to blacken the X-ray film. In addition, some of the blue components still reach the X-ray film in a roundabout way, but are sometimes bent in such a way that they no longer hit the X-ray film. For this reason, there is a reduction in the intensity of the obliquely running light and thus a further reduction in the blackness of the X-ray film by this light.

The size of the particles according to the invention also has the following meaning:

If the dye in the binder consist of pigment particles that are larger than IO cm ~ ^5, then subject to those particles in the order of the dimensions of the luminescent particles which are about 10 'crn large. This is inexpedient because it disrupts the packing of the luminescent particles; these should be close together. In contrast, the dye particles according to the invention can find a place in the spaces between the luminescent particles.

It is particularly useful if the colloidal dye particles are black.

Preferably the concentration of the colloidal dye in the binder is between 0.01 and 0.2%, in particular it is 0.05%.

An embodiment is shown in the single figure of the drawing.

1 denotes an X-ray film and 2 denotes an X-ray film intensifying screen. In the latter luminescent particles 3 and pigment particles 4 are embedded. The X-ray light falls on the foil in Direction of arrow 5.

1 sheet of drawings

Claims (3)

Patent claims: 1, is composed embedded in a binder, luminescent particles and a dye, characterized in that the dye (4) colloidally cm in the form of pigment particles in the size between 10 "'and 10 ~ ⁵ in the binder radiographic intensifying screen. 2. X-ray film intensifying screen according to claim 1, characterized in that the colloidal dye particles (4) are black. 3. X-ray film intensifying screen according to claim 1 or 2, characterized in that the concentration of the colloidal dye (4) in the binder is between 0.01 and 0.2 ° / ", in particular 0.05 ° / ₀ .