DE1764273B1 - POSSIBLE COLLIMATOR BLOCK FOR THE DIRECTIONAL BLOCKING OF DIFFUSED ROENTGEN OR GAMMA RADIATION AND PROCESS FOR ITS MANUFACTURING - Google Patents

Description

The invention relates to a multi-hole collimator block for the directional masking of diffuse X-ray or gamma radiation, consisting of a multiplicity of elongated, tubular, open at the end faces Hollow bodies, which are arranged with their lateral surfaces abutting one another next to one another are.

The invention also relates to a method for producing such a collimator block.

In medicine, methods for diagnosing or treating the human body are often used applied, which require the use of short-wave radiation. It is essentially about an x-ray or gamma radiation.

It is common practice to use the X-rays emitted diverging from a source or the diffuse radiation from a gamma emitter, e.g. B. Co ₆₀ to bundle before use with the help of a collimator. This collimator, which usually has a honeycomb-like appearance, and is therefore often referred to as a "honeycomb block", is made by joining a large number of thin plates that are provided with a large number of openings. Since these openings are arranged one behind the other, the incoming radiation can pass through them and is thereby bundled up to a certain distance after leaving the openings.

In a known collimator block, as it is used in X-ray photography, exist thin plates of the block made of a material which easily absorbs the X-rays, d. H. made of a high density material. This material is usually lead, gold, platinum, molybdenum, tungsten or tungsten alloys.

The manufacture of a collimator block from the aforementioned thin plates requires as essential operations are drilling a large number of holes and joining them together perforated platelets.

When using a hard and at the same time brittle material such. B. tungsten, is the perforation these platelets are associated with considerable difficulties, which not only increase the processing time, but also cause a shortening of the service life of the drilling tools.

When using a soft material, ζ. Β. Lead or gold, the difficulty is with drilling closely spaced openings in that the webs between the openings often cause deformation tend.

As a result, a high level of precision cannot be achieved in the manufacture of the openings. For this reason, the strength of the webs between the openings of a collimator block cannot be reduced too much. However, a reduction in the web thickness is generally aimed at, since thus increasing the permeability for the X-ray radiation.

It is also known to assemble a collimator block from a plurality of elongated, open at the end faces tubular hollow bodies, which are arranged next to one another with their lateral surfaces lying against one another are to form. A drawing process is suitable, for example, for the production of these hollow bodies Gold or platinum, but the use of these materials stands in the way of the high price.

The invention is therefore based on the object to provide a collimator between the Throughput openings allow the execution of very small web thicknesses, but only a small one Requires manufacturing effort, but still guarantees the desired precision.

This object is achieved according to the invention in a multi-hole collimator block of the type mentioned at the beginning solved in that the hollow body consists of tightly wound tungsten wire or tape.

ίο The hollow bodies are preferably made by winding made of tungsten wire or tungsten tape over a mandrel and after removing the mandrel attached to each other by a binder. The method according to the invention enables the use of tungsten without any processing difficulties or high wear Tools must be accepted. The hollow body can therefore individually in the desired Length are prefabricated, the wall thickness of the hollow body can be made so small that after joining the hollow body to a collimator block has a small web thickness between the openings arises. It is obvious that the inventive collimator block both the advantage of a high beam throughput as well as compared to the known manufacturing processes decisive, price-reducing advantages are given, because the invention allows production with high efficiency and enables mass production.

The openings of the collimator block do not need to be in the form of a circle, any other polygonal or rectangular cross-sectional shape can also be selected.

This in turn has the advantage that ζ. Β. with a square or rectangular cross-sectional shape the hollow body has a larger contact surface when joining the hollow body to form a collimator block arises, whereby the entire collimator block has a higher strength.

It is of course also possible to give the hollow bodies themselves greater strength in that the wire or tape used to wind the hollow body has a polygonal cross-section, e.g. B.

a rectangular one, so that a larger contact surface between the individual turns of the hollow body arises.

The tightly fitting hollow bodies of a collimator block are adhered by a binding agent ζ. B. achieved a copper paste. Of course, the binding agent can also consist of other metal pastes. Ceramic binders made from aluminum, zirconium and titanium oxides or organic binders are generally used Epoxy resin binder.

The collimator block is usually used for parallel masking diffuse x-ray or gamma radiation. For this reason, the hollow bodies are arranged next to one another in an axially parallel manner. If a non-parallel order of the rays is desired, this is Invention also applicable. For this purpose, the hollow bodies are arranged according to the desired order aligned and in turn connected with the help of a binding agent and to form a collimator block summarized.

Thus, a collimator block according to the invention not only allows any cross-sectional shape of the passage openings for the radiation, but also a deformation-free definition of the openings

in the Koilimatorblock, as well as a uniform, precise Alignment of the hollow body axes in any desired direction.

With regard to the aforementioned manufacturing problems of a collimator block of known designs tion, the collimator block according to the invention now avoids the need for drilling openings in thin plates. Since the openings are only made by winding a tungsten wire or Tungsten tape are made into a hollow body via a mandrel, there is the advantage of that the production is made much easier and cheaper.

In addition, the transverse and longitudinal webs can open between the openings of a collimator block a thickness of 40 to 60 μm can be reduced. Through this is a significantly higher throughput capacity for given the radiation.

The invention is explained in more detail below in exemplary embodiments with reference to the drawings. It represents

F i g. 1 is a perspective view of the collimator block according to the invention,

FIG. 2 shows an enlarged perspective view of three hollow bodies of the collimator block according to FIG Fig.l,

F i g. 3 shows a perspective view of a further embodiment of the hollow bodies of a collimator block.

Fig.2 shows three hollow bodies 1. Each hollow body has a circular cross-section and is made of a tungsten wire with a circular shape Wrapped cross-section. The subsequent windings of a hollow body are close to one another.

The manufacture of the hollow body takes place by placing a tungsten wire with a circular cross-section of 0.2 mm diameter heated to about 800 ° C. The wire, which has become flexible as a result, will open a molybdenum mandrel (not shown) wound so that consecutive, adjacent turns come to lie close together. When the wrap has grown to a length of 20 mm, will the mandrel pulled out. The hollow body produced in this way has an opening diameter of 3.1 mm and an outer diameter of 3.5 mm. A large number of the hollow bodies produced in this way are like F i g. 1 shows a rectangular block with an edge length of 95 mm and a depth of 20 mm stacked. The center-to-center distance of the openings in the hollow bodies is approximately 3.5 mm.

In this production stage, a binder 3 (see FIG. 2) is now in the intermediate joints of the Hollow body 1 introduced. The binder in this case is a copper paste made from copper powder and a butyl acetate solution.

The block produced so far is then heated ^{to a temperature of up to 1200 ° C. in a hydrogen atmosphere.} As a result, the copper component of the binding agent melts and penetrates into the spaces between the adjacent hollow bodies. After cooling, the hollow bodies 1 are firmly connected to form a closed collimator block 2 (see FIG. 1).

Fig. 3 shows a modified embodiment of the invention, in which the hollow body 4 with a square Cross-section can be wound from a tape with a rectangular cross-section, which is then subsequently be joined together by means of a binding agent 5 to form a collimator block.

Claims (3)

Patent claims: 1. Multi-hole collimator block for directional suppression of diffuse X-ray or gamma radiation, that of a multitude of elongated, tubular, open at the end faces Hollow bodies, which are arranged with their lateral surfaces abutting one another next to one another are, characterized in that the hollow body (1 or 4) made of tightly wound tungsten wire or band. 2. Multi-hole collimator block according to claim 1, characterized in that the hollow body (4) have a polygonal or rectangular cross-section. 3. A method for producing a multi-hole collimator block according to claim 1 or 2, at the tubular hollow body joined together with their lateral surfaces adjoining one another to form the block are, characterized in that tungsten wire or tungsten tape is wound on a mandrel and that the so produced Hollow bodies are attached to one another by a binding agent after the mandrel has been removed. 1 sheet of drawings COPY