US2871367A - Gamma ray collimating device - Google Patents

Gamma ray collimating device Download PDF

Info

Publication number: US2871367A
Authority: US; United States
Prior art keywords: box; mercury; tube assembly; assembly; slit
Prior art date: 1955-08-01
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.): Expired - Lifetime

Application number

US525480A

Inventor

Luke S Gournay

Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)

ExxonMobil Oil Corp

Original Assignee

Socony Mobil Oil Co Inc

Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)

1955-08-01

Filing date

1955-08-01

Publication date

1959-01-27

1955-08-01 Application filed by Socony Mobil Oil Co Inc filed Critical Socony Mobil Oil Co Inc

1955-08-01 Priority to US525480A priority Critical patent/US2871367A/en

1959-01-27 Application granted granted Critical

1959-01-27 Publication of US2871367A publication Critical patent/US2871367A/en

1976-01-27 Anticipated expiration legal-status Critical

Status Expired - Lifetime legal-status Critical Current

Links

Images

Classifications

- G—PHYSICS
- G21—NUCLEAR PHYSICS; NUCLEAR ENGINEERING
- G21F—PROTECTION AGAINST X-RADIATION, GAMMA RADIATION, CORPUSCULAR RADIATION OR PARTICLE BOMBARDMENT; TREATING RADIOACTIVELY CONTAMINATED MATERIAL; DECONTAMINATION ARRANGEMENTS THEREFOR
- G21F5/00—Transportable or portable shielded containers
- G21F5/02—Transportable or portable shielded containers with provision for restricted exposure of a radiation source within the container
- G21F5/04—Means for controlling exposure, e.g. time, size of aperture
- G—PHYSICS
- G21—NUCLEAR PHYSICS; NUCLEAR ENGINEERING
- G21K—TECHNIQUES FOR HANDLING PARTICLES OR IONISING RADIATION NOT OTHERWISE PROVIDED FOR; IRRADIATION DEVICES; GAMMA RAY OR X-RAY MICROSCOPES
- G21K1/00—Arrangements for handling particles or ionising radiation, e.g. focusing or moderating
- G21K1/02—Arrangements for handling particles or ionising radiation, e.g. focusing or moderating using diaphragms, collimators

Definitions

This invention relates to the collimation of rays emitted by radioactive substances and relates more particularly to a device for the collimation of gamma rays.
collimation of rays from radioactive sources has been accomplished in the past in numerous different ways.
Some collimation devices have utilized absorbing or shielding materials such as lead, iron and tungsten alloys.
lead shielded collimation devices is the background which exists due to the inherent radio activity of the lead.
Other collimation devices have utilized Geiger-Muller counters connected in coincidence circuits.
Counters in coincidence circuits are connected together to form a counting system which will register acount only when a single ray penetrates each counter. substantially simultaneously or each counter of thesystem is penetrated by separate rays simultaneously. It will be appreciated that in a coincidence system wherein a plurality of counters are arranged with their longitudinal axes parallel and in a common plane there is a substantial lessening of the possibilities that a single ray will penetrate each of the counters substantially simultaneously or that each of the counters in the system will be penetrated by separate random rays simultaneously. As a practical matter it has been found that in a coincidence system as just discussed, the counting rate for the system is reduced approximately one hundred fold for each counter which is added to the system.
an apparatus containing an air-filled slit which forms an exclusive path for gamma rays from a radioactive source through a body of mercury to one or more radiation detectors.
the radiation detectors are contained within an enclosure which, like the air-filled slit, is surrounded by the body of mercury.
Figure 1 is a view in perspective of a preferred form of collimating device constructed in accordance with my invention.
Figure 2 is a top view of the device of Figure 1.
Figure 3 is a front view of the device of Figure 1.
Figure 4 is a side view of the device of Figure 1.
mercury is superior to those materials previously used for shielding rays from radioactive substances in collimation devices.
Mercury shielding provides greater efliciency in collimation than lead shielding without a sacrifice in intensity of gamma radiation at the point where the gamma rays are counted.
a lead shielded device providing the same degree of shielding as a mercury shielded device requires a longer collimation slit and more lead since lead does not absorb the radiation as readily as mercury.
Use of a longer collimation slit permits more rays to scatter and reflect resulting in fewer rays actually reaching the radiation detectors.
a system using mercury as the shielding material has less background radiation than systems using other decay elements for shielding due to the fact that the inherent radioactivity of mercury is less than that of other decay elements.
box 5 comprises top 6, bottom 7, back 8, front 9, and sides 10 and 15.
Box 5 is formed of a structurally rigid material which is transparent to gamma rays and chemically inert to mercury.
the ma-' terial may be a polymethyl methacrylate such as is sold under the trademark Lucite. This material is transparent to light rays, and the box as illustrated in the drawing is constructed of transparent materials. How ever, such transparency is not required and a material opaque to such rays may be used.
Valve 20' is posi tioned in top 6 to permit the introduction of mercury into the box.
Valve 21 is positioned in side 10 near bottom 7 to provide means for withdrawing mercury from the box.
valves 20 and 21 in box 5 may be varied as desired so long as means are provided fbor mercury to be introduced into and withdrawn from the Tube assembly 22 as shown comprises tubes 23 and 24 which are joined together with their longitudinal axes parallel to each other. Tubes 23 and 24 are joined together in a plane which is perpendicular to a plane pass,-
tube assembly 22 is sealed from the'inside of box 5 and is accessible from the outside of the box through the end of the tube assembly terminating in side 10'.
the end of the tube assembly terminating at side 15 may extend through side 15 as does the end of the assembly terminating in side 10, thus permitting radiation detectors to be inserted through either end of the tube assembly.
the number of tubes in the tube assembly may be varied as desired depending upon how many radiation detectors are used as counters.
each tube in the assembly will accommodate one radiation detector, such as a Geiger-Muller tube.
the tube assembly is constructed of a material which is transparent to gamma rays and chemically inert to the'liquid shield ing medium used. It may be formed of the same material which is used in constructing box 5.
Front side 25 of tube assembly 22, a flat surface formed on tube 24, is parallel to the longitudinal axes of the tubes and is perpendicular to a plane passing through the ,longitudinal axes of the tubes.
Air-filled slit assembly 30 is supported within box 5 between side of tube assembly 22 and the inside plane surface of front 9.
Slit assembly is provided with top 31, bottom 32 and the sides 33 and 34.
the internal plane surfaces of top 31, bottom 32, and the sides 33 and 34 form the boundaries of a slit 35 passing through the slit assembly.
Top 31 and bottom 32 are parallel to and equidistant from a plane passing through the longitudinal axes of tubes 23 and 24.
the slit assembly is constructed of stainless steel sheet material, although it will be recognized that it may be constructed of any structurally rigid material which will retain its shape when used in relatively thin sheet form and will not be afiected by the mercury surrounding the slit assembly. It is desirable that the maximum amount of radiation reaching the detectors from the segment of the sample pass through slit 35 rather than through the material of which the slit assembly itself is constructed.
the material used to form the slit assembly will probably have a linear coefficient of absorption much less than that of mercury. Accordingly, it is important that the thickness of the material be no more than required for physical rigidity of the assembly.
the length of the slit assembly which for purposes of this description will be considered as the distance from front side 25 of tube assembly 22 to the inside plane surface of front 9, may be varied in accordance with the degree of collimation desired. Increasing the length of the slit assembly will increase the collimation obtained, while decreasing the length of the slit assembly will decrease the degree of collimation obtained.
the width of the slit assembly which is its dimension taken along the length of the tube assembly, may be varied as desired in accordance with the active length of the detectors used.
the thickness of the slit assembly i.
That dimension of the assembly taken along a line parallel to side 25 and perpendicular to a plane passing through the longitudinal axes of tubes 23 and 24, may be varied as desired depending on the thickness of the segment of the radioactive source to be examined.
One open end of the slit assembly bears tightly against the inside plane surface of front 9, while the other open end bears tightly against front side 25 on tube 24.
the end of the slit assembly terminating at front 9 may, if desired, pass through the front and terminate flush with the outside plane surface of the front.
valve 20 With tube assembly 22 and slit assembly 36 securely mounted within box 5, the box is filled through valve 20 with mercury. Valve 21 is closed during the filling process. The mercury surrounds but does not enter the tube and slit assemblies.
the detectors are inserted into the tube assembly and the segment of the radioactive source to be studied is placed in front of the slit assembly adjacent to front 9. Those rays emitted by the segment of the radioactive source which are traveling in essentially the same direction and approximately parallel with the slit pass through the slit to the detectors where they are counted.
the rays emitted by the other segments of the radioactive source and the rays from the segment being studied which are not traveling in a direction essentially parallel to the slit all pass into the mercury where they are absorbed. Thus, only a selected group of rays from the segment being studied are permitted to reach the detectors for counting.
a substantially enclosed box a body of mercury contained within said box substantially filling said box, a valve positioned in the top of said box to permit'the introduction of said mercury into said box, a valve positioned in said box near the bottom thereof to permit the withdrawal of said mercury from said box, a tube assembly comprising at least one hollow cylindrical tube secured within said box approximately midway between the top and the bottom of said box and having at least one end opening through a side of said box to permit the introduction of gamma ray detecting means into said tube assembly, said tube assembly being sealed with the inside surfaces of said box to exclude said mercury from said assembly, a slit assembly secured between said tube assembly and the inside surface of the front of said box, said slit assembly being sealed to exclude said mercury to provide an exclusive air-filled path for gamma rays from the front of said box through said mercury to said tube assembly.
an enclosure box formed of a material transparent to gamma rays and chemically inert to mercury, a body of mercury contained within and substantially filling said box, a valve secured in the top of said box to permit the introduction of said mercury into said box, a valve secured in said box near the bottom thereof to permit the withdrawal of said mercury from said box, a tube assembly comprising two hollow cylindrical tubes formed of a material transparent to gamma rays and chemically inert to mercury secured in said box between the sides thereof approximately midway between the top and bottom of said box, one end of said tube assembly passing through and sealed with one side of said box and the other end of said tube assembly being sealed to the inside plane surface of the other side of said box, the front side of said tube assembly having a plane surface formed thereon, and an air-filled slit assembly having one end secured and sealed to the front plane surface of said tube assembly and the other end secured and sealed to the inside plane surface of the front side of said box.
an enclosure box formed of a material transparent to gamma rays and chemically inert to mercury, a body of mercury contained within and sub stantially filling said box, a valve secured in the top of said box to permit the introduction of said mercury into said box, a valve secured in a side of said box near the bottom thereof to permit the withdrawal of said mercury from said box, a tube assembly adapted to receive a detector for gamma rays and comprising at least one hollow cylindrical tube formed of a material transparent to gamma rays and chemically inert to mercury, said tube assembly being secured in said box between two sides thereof substantially midway between and parallel to the bottom and top of said box, one end of said tube assembly opening through and sealed around its periphery with one side of said box and the other end of said tube assembly terminating in sealed relationship with the inside plane surface of the other side of said box, said tube assembly having formed on the front thereof a plane surface parallel to the inside
an enclosure box formed of a material transparent to gamma rays and chemically inert to mercury, a body of mercury contained within and substantially filling said box, a valve secured in the top of said box to permit the introduction of said mercury into said box, a valve secured in a side of said box near the bottom thereof to permit the withdrawal of said mercury from said box, a tube assembly adapted to receive gamma ray detector means and secured between two sides of said box substantially parallel to and midway between the top and bottom of said box, said tube assembly comprising two hollow cylindrical tubes joined together in a plane parallel to the longitudinal axes of said tubes and perpendicular to a plane passing through the longitudinal axes of said tubes, the front side of said tube assembly being provided with a plane surface formed parallel to the longitudinal axes of said tubes and perpendicular to a plane passing through the longitudinal axes of said tubes, one end of said tube assembly being in sealed relationship with the inside plane surface of one side of

Description

Jan. 27, 1959 L. S. GOURNAY cum RAY COLLDIATING bsvrcs Filed Aug. 1, 1955 f i 7 I L "i F IG. 3.

FIG. 4.

LUKE S. GOURNAY INVENTOR.

A TTUR'NE Y United States Patent GAMMA RAY COLLIMATING DEVICE Luke S. Gournay, Oxnard, Califl, assignor, by mes ne to Socony Mobil Oil Company, Inc., New

assignments, York, N. Y., a corporation of'New York This invention relates to the collimation of rays emitted by radioactive substances and relates more particularly to a device for the collimation of gamma rays.

In the study of radioactive substances, it is frequently necessary that selected segments of the radioactive source be studied separately. To make such studies it is required that the segments to be studied be isolated so that they may be examined without interference from other segments of the same radioactive source. Isolation of the selected segments may be effected by collimation of the rays emitted by the segments in question or, in other words, by the shielding of. all rays emitted by the source except those rays which. are traveling in essentially the same direction from the segment in question.

Collimation of rays from radioactive sources has been accomplished in the past in numerous different ways. Some collimation devices have utilized absorbing or shielding materials such as lead, iron and tungsten alloys. One disadvantage of lead shielded collimation devices is the background which exists due to the inherent radio activity of the lead. Other collimation devices have utilized Geiger-Muller counters connected in coincidence circuits.

Counters in coincidence circuits are connected together to form a counting system which will register acount only when a single ray penetrates each counter. substantially simultaneously or each counter of thesystem is penetrated by separate rays simultaneously. It will be appreciated that in a coincidence system wherein a plurality of counters are arranged with their longitudinal axes parallel and in a common plane there is a substantial lessening of the possibilities that a single ray will penetrate each of the counters substantially simultaneously or that each of the counters in the system will be penetrated by separate random rays simultaneously. As a practical matter it has been found that in a coincidence system as just discussed, the counting rate for the system is reduced approximately one hundred fold for each counter which is added to the system.

It is an object of this invention to collimate rays emitted by a radioactive source. It is another object of this invention to provide apparatus which will permit a small segment of a large radioactive source to be examined independently of other segments of the same source. It is another object of this invention to provide apparatus for the collimation of high energy gamma radiation such that the gamma rays reaching a radiation detector are all traveling in essentially the same direction. Other objects of the invention will become apparent from the following detailed description.

In accordance with the invention, there is provided an apparatus containing an air-filled slit which forms an exclusive path for gamma rays from a radioactive source through a body of mercury to one or more radiation detectors. The radiation detectors are contained within an enclosure which, like the air-filled slit, is surrounded by the body of mercury.

In the drawings Figure 1 is a view in perspective of a preferred form of collimating device constructed in accordance with my invention. I

Figure 2 is a top view of the device of Figure 1.

Figure 3 is a front view of the device of Figure 1.

Figure 4 is a side view of the device of Figure 1.

It has been found that mercury is superior to those materials previously used for shielding rays from radioactive substances in collimation devices. Mercury shielding provides greater efliciency in collimation than lead shielding without a sacrifice in intensity of gamma radiation at the point where the gamma rays are counted. A lead shielded device providing the same degree of shielding as a mercury shielded device requires a longer collimation slit and more lead since lead does not absorb the radiation as readily as mercury. Use of a longer collimation slit permits more rays to scatter and reflect resulting in fewer rays actually reaching the radiation detectors. In addition, a system using mercury as the shielding material has less background radiation than systems using other decay elements for shielding due to the fact that the inherent radioactivity of mercury is less than that of other decay elements.

Referring to the drawings, box 5 comprises top 6, bottom 7, back 8, front 9, and

sides

10 and 15. Box 5 is formed of a structurally rigid material which is transparent to gamma rays and chemically inert to mercury. With the use of mercury as a shielding medium, the ma-' terial may be a polymethyl methacrylate such as is sold under the trademark Lucite. This material is transparent to light rays, and the box as illustrated in the drawing is constructed of transparent materials. How ever, such transparency is not required and a material opaque to such rays may be used. Valve 20' is posi tioned in top 6 to permit the introduction of mercury into the box. Valve 21 is positioned in side 10 near bottom 7 to provide means for withdrawing mercury from the box. The positions of

valves

20 and 21 in box 5 may be varied as desired so long as means are provided fbor mercury to be introduced into and withdrawn from the Tube assembly 22 as shown comprises

tubes

23 and 24 which are joined together with their longitudinal axes parallel to each other. Tubes 23 and 24 are joined together in a plane which is perpendicular to a plane pass,-

, ing through the longitudinal axes of the tubes and is parallel to the longitudinal axes of the tubes. One end of the tube assembly is joined to side 15 such that said end is closed or sealed by the inside plane surface of side 15. The other end of the tube assembly is secured to side 10 and passes through and terminates flush with the outside plane surface of side 10. Thus, tube assembly 22 is sealed from the'inside of box 5 and is accessible from the outside of the box through the end of the tube assembly terminating in side 10'. If desired, the end of the tube assembly terminating at side 15 may extend through side 15 as does the end of the assembly terminating in side 10, thus permitting radiation detectors to be inserted through either end of the tube assembly. The number of tubes in the tube assembly may be varied as desired depending upon how many radiation detectors are used as counters. The number of detectors to be used will afie ct the countingrate. As previously pointed out, the addition of each detector in a coincidence circuit system reduces the counting rate for the system. Each tube in the assembly will accommodate one radiation detector, such as a Geiger-Muller tube. The tube assembly is constructed of a material which is transparent to gamma rays and chemically inert to the'liquid shield ing medium used. It may be formed of the same material which is used in constructing box 5.

Front side 25 of tube assembly 22, a flat surface formed on tube 24, is parallel to the longitudinal axes of the tubes and is perpendicular to a plane passing through the ,longitudinal axes of the tubes. Air-filled slit assembly 30 is supported within box 5 between side of tube assembly 22 and the inside plane surface of front 9. Slit assembly is provided with top 31, bottom 32 and the

sides

33 and 34. The internal plane surfaces of top 31, bottom 32, and the

sides

33 and 34 form the boundaries of a slit 35 passing through the slit assembly. Top 31 and bottom 32 are parallel to and equidistant from a plane passing through the longitudinal axes of

tubes

23 and 24. In the embodiment of the invention illustrated the slit assembly is constructed of stainless steel sheet material, although it will be recognized that it may be constructed of any structurally rigid material which will retain its shape when used in relatively thin sheet form and will not be afiected by the mercury surrounding the slit assembly. It is desirable that the maximum amount of radiation reaching the detectors from the segment of the sample pass through slit 35 rather than through the material of which the slit assembly itself is constructed. The material used to form the slit assembly will probably have a linear coefficient of absorption much less than that of mercury. Accordingly, it is important that the thickness of the material be no more than required for physical rigidity of the assembly.

The length of the slit assembly, which for purposes of this description will be considered as the distance from front side 25 of tube assembly 22 to the inside plane surface of front 9, may be varied in accordance with the degree of collimation desired. Increasing the length of the slit assembly will increase the collimation obtained, while decreasing the length of the slit assembly will decrease the degree of collimation obtained. The width of the slit assembly, which is its dimension taken along the length of the tube assembly, may be varied as desired in accordance with the active length of the detectors used. The thickness of the slit assembly, i. e., that dimension of the assembly taken along a line parallel to side 25 and perpendicular to a plane passing through the longitudinal axes of

tubes

23 and 24, may be varied as desired depending on the thickness of the segment of the radioactive source to be examined. One open end of the slit assembly bears tightly against the inside plane surface of front 9, while the other open end bears tightly against front side 25 on tube 24. The end of the slit assembly terminating at front 9 may, if desired, pass through the front and terminate flush with the outside plane surface of the front.

With tube assembly 22 and slit assembly 36 securely mounted within box 5, the box is filled through valve 20 with mercury. Valve 21 is closed during the filling process. The mercury surrounds but does not enter the tube and slit assemblies. The detectors are inserted into the tube assembly and the segment of the radioactive source to be studied is placed in front of the slit assembly adjacent to front 9. Those rays emitted by the segment of the radioactive source which are traveling in essentially the same direction and approximately parallel with the slit pass through the slit to the detectors where they are counted. The rays emitted by the other segments of the radioactive source and the rays from the segment being studied which are not traveling in a direction essentially parallel to the slit all pass into the mercury where they are absorbed. Thus, only a selected group of rays from the segment being studied are permitted to reach the detectors for counting.

4; cover such modifications as fall within the scope of the appended claims.

I claim:

1. In an apparatus for the collimation of gamma rays the combination of a substantially enclosed box, a body of mercury contained within said box substantially filling said box, a valve positioned in the top of said box to permit'the introduction of said mercury into said box, a valve positioned in said box near the bottom thereof to permit the withdrawal of said mercury from said box, a tube assembly comprising at least one hollow cylindrical tube secured within said box approximately midway between the top and the bottom of said box and having at least one end opening through a side of said box to permit the introduction of gamma ray detecting means into said tube assembly, said tube assembly being sealed with the inside surfaces of said box to exclude said mercury from said assembly, a slit assembly secured between said tube assembly and the inside surface of the front of said box, said slit assembly being sealed to exclude said mercury to provide an exclusive air-filled path for gamma rays from the front of said box through said mercury to said tube assembly.

2. In an apparatus for the collimation of gamma rays the combination of an enclosed box formed of a material transparent to gamma rays and chemically inert to mercury, a body of mercury contained within and substantially filling said box, a valve secured in the top of said While the invention has been described in connection I with certain specific embodiments thereof, it will now be understood that further modifications will suggest themselves to those skilled in the art and it is intended to box to permit the introduction of said mercury into said box, a valve secured in said box near the bottom thereof to permit the withdrawal of said mercury from said box, a tube assembly comprising at least one hollow cylindrical tube formed of a material transparent to gamma rays and chemically'inert to mercury secured in said box between the sides thereof approximately midway between the top and bottom of said box, one end of said tube assembly passing through and sealed with one side of said box and the other end of said tube assembly being sealed to the inside plane surface of the other side of said box, the front side of said tube assembly having a plane surface formed thereon, and an air-filled slit assembly having one end secured and sealed to the front plane surface of said tube assembly and the other end secured and sealed to the inside plane surface of the front side of said box.

3. In an apparatus for the collimation of gamma rays the combination of an enclosed box formed of a material transparent to gamma rays and chemically inert to mercury, a body of mercury contained within and substantially filling said box, a valve secured in the top of said box to permit the introduction of said mercury into said box, a valve secured in said box near the bottom thereof to permit the withdrawal of said mercury from said box, a tube assembly comprising two hollow cylindrical tubes formed of a material transparent to gamma rays and chemically inert to mercury secured in said box between the sides thereof approximately midway between the top and bottom of said box, one end of said tube assembly passing through and sealed with one side of said box and the other end of said tube assembly being sealed to the inside plane surface of the other side of said box, the front side of said tube assembly having a plane surface formed thereon, and an air-filled slit assembly having one end secured and sealed to the front plane surface of said tube assembly and the other end secured and sealed to the inside plane surface of the front side of said box. 7

4. In an apparatus for the collimation of gamma rays the combination of an enclosed box formed of a material transparent to gamma rays and chemically inert to mercury, a body of mercury contained within and sub stantially filling said box, a valve secured in the top of said box to permit the introduction of said mercury into said box, a valve secured in a side of said box near the bottom thereof to permit the withdrawal of said mercury from said box, a tube assembly adapted to receive a detector for gamma rays and comprising at least one hollow cylindrical tube formed of a material transparent to gamma rays and chemically inert to mercury, said tube assembly being secured in said box between two sides thereof substantially midway between and parallel to the bottom and top of said box, one end of said tube assembly opening through and sealed around its periphery with one side of said box and the other end of said tube assembly terminating in sealed relationship with the inside plane surface of the other side of said box, said tube assembly having formed on the front thereof a plane surface parallel to the inside plane surface of the front of said box, and an air-filled slit assembly secured between said plane surface on said tube assembly and said inside plane surface of the front side of said box to provide an exclusive defined path for gamma rays from the front side of said box through said mercury to said tube assembly.

5. In an apparatus for the collimation of gamma rays the combination of an enclosed box formed of a material transparent to gamma rays and chemically inert to mercury, a body of mercury contained within and substantially filling said box, a valve secured in the top of said box to permit the introduction of said mercury into said box, a valve secured in a side of said box near the bottom thereof to permit the withdrawal of said mercury from said box, a tube assembly adapted to receive gamma ray detector means and secured between two sides of said box substantially parallel to and midway between the top and bottom of said box, said tube assembly comprising two hollow cylindrical tubes joined together in a plane parallel to the longitudinal axes of said tubes and perpendicular to a plane passing through the longitudinal axes of said tubes, the front side of said tube assembly being provided with a plane surface formed parallel to the longitudinal axes of said tubes and perpendicular to a plane passing through the longitudinal axes of said tubes, one end of said tube assembly being in sealed relationship with the inside plane surface of one side of said box, the other end of said tube assembly opening through and sealed around its periphery with the other side of said box to permit the introduction of gamma ray detector means into said assembly, and an air-filled stainless steel slit assembly secured at one end in sealed relationship to said plane surface on the front side of said tube assembly and secured at the other end in sealed relationship to the inside plane surface of the front of said box, said slit assembly being rectangular in cross section in a 'plane parallel to the plane surface on the front of said tube assembly, and said slit assembly being adapted to provide an exclusive path for gamma rays from the front side of said box through said body of mercury to said tube assembly.

Pajes June 2, 1953 Stewart et al Apr. 13, 1954

US525480A 1955-08-01 1955-08-01 Gamma ray collimating device Expired - Lifetime US2871367A (en)

Priority Applications (1)

Application Number	Priority Date	Filing Date	Title
US525480A US2871367A (en)	1955-08-01	1955-08-01	Gamma ray collimating device

Applications Claiming Priority (1)

Application Number	Priority Date	Filing Date	Title
US525480A US2871367A (en)	1955-08-01	1955-08-01	Gamma ray collimating device

Publications (1)

Publication Number	Publication Date
US2871367A true US2871367A (en)	1959-01-27

Family

ID=24093439

Family Applications (1)

Application Number	Title	Priority Date	Filing Date
US525480A Expired - Lifetime US2871367A (en)	1955-08-01	1955-08-01	Gamma ray collimating device

Country Status (1)

Country	Link
US (1)	US2871367A (en)

Cited By (7)

* Cited by examiner, † Cited by third party
Publication number	Priority date	Publication date	Assignee	Title
US3256440A (en) *	1961-12-20	1966-06-14	Stark Virgil	Devices for protection against radioactive fallout
US3805081A (en) *	1971-04-16	1974-04-16	Licentia Gmbh	Collimator for high energy radiation
US3944836A (en) *	1973-04-10	1976-03-16	C.G.R. -Mev	Auxiliary collimating device for obtaining irradiation fields of any shape for high energy radiotherapy apparatus
US4446570A (en) *	1981-07-17	1984-05-01	Siemens Gammasonics, Inc.	Collimator for a radiation detector and method of making same
US4481419A (en) *	1981-10-29	1984-11-06	Siemens Gammasonics, Inc.	Attenuation zone plate
US4791300A (en) *	1986-08-25	1988-12-13	Qtr Corporation	Miniature gamma camera
US4856042A (en) *	1986-07-08	1989-08-08	Thomson-Cgr	Diaphragm for electromagnet radiation beam and its use in a collimation device for this beam

Citations (2)

* Cited by examiner, † Cited by third party
Publication number	Priority date	Publication date	Assignee	Title
US2640936A (en) *	1950-02-07	1953-06-02	Pajes Wolf Szmul	Method and apparatus for indicating the movement of material
US2675479A (en) *	1952-06-27	1954-04-13	Isotope Products Ltd	Method and apparatus for radiography

1955
- 1955-08-01 US US525480A patent/US2871367A/en not_active Expired - Lifetime

Patent Citations (2)

* Cited by examiner, † Cited by third party
Publication number	Priority date	Publication date	Assignee	Title
US2640936A (en) *	1950-02-07	1953-06-02	Pajes Wolf Szmul	Method and apparatus for indicating the movement of material
US2675479A (en) *	1952-06-27	1954-04-13	Isotope Products Ltd	Method and apparatus for radiography

Cited By (7)

* Cited by examiner, † Cited by third party
Publication number	Priority date	Publication date	Assignee	Title
US3256440A (en) *	1961-12-20	1966-06-14	Stark Virgil	Devices for protection against radioactive fallout
US3805081A (en) *	1971-04-16	1974-04-16	Licentia Gmbh	Collimator for high energy radiation
US3944836A (en) *	1973-04-10	1976-03-16	C.G.R. -Mev	Auxiliary collimating device for obtaining irradiation fields of any shape for high energy radiotherapy apparatus
US4446570A (en) *	1981-07-17	1984-05-01	Siemens Gammasonics, Inc.	Collimator for a radiation detector and method of making same
US4481419A (en) *	1981-10-29	1984-11-06	Siemens Gammasonics, Inc.	Attenuation zone plate
US4856042A (en) *	1986-07-08	1989-08-08	Thomson-Cgr	Diaphragm for electromagnet radiation beam and its use in a collimation device for this beam
US4791300A (en) *	1986-08-25	1988-12-13	Qtr Corporation	Miniature gamma camera

Publication	Publication Date	Title
US4278885A (en)	1981-07-14	Apparatus for measuring the concentrations of elements in a material by the capture gamma method
US4291228A (en)	1981-09-22	Detector shape and arrangement for positron annihilation imaging device
US2871367A (en)	1959-01-27	Gamma ray collimating device
US3524062A (en)	1970-08-11	Apparatus for measuring the moisture content and density of the soil
GB1100931A (en)	1968-01-24	Method and apparatus for automatic standardization in liquid scintillation spectrometry
US3786253A (en)	1974-01-15	Gamma and neutron scintillator
US3243589A (en)	1966-03-29	Backscatter flaw detection system
US3600578A (en)	1971-08-17	Reactor power level sensing device using cherenkov radiation
US3185843A (en)	1965-05-25	Collimator system for beta radiation thickness gauge sensor
GB1044713A (en)	1966-10-05	Method and device for neutron radiography
US3248541A (en)	1966-04-26	Radioactivity device for measurement of properties of materials
Barnaby et al.	1968	Performance of a high sensitivity liquid scintillation whole-body counter
Jahns et al.	1967	A line-source phantom for testing the performance of scintillation cameras
DE1193617B (en)	1965-05-26	Large area counter for the exclusive measurement of soft quantum radiation emitted from a sample
JPH0448560Y2 (en)	1992-11-16
US3824396A (en)	1974-07-16	Method and apparatus for checking positions of bottom end walls of blind holes formed in a part and in particular in a graphite block
US3612875A (en)	1971-10-12	Mossbauer spectrometer
US3098944A (en)	1963-07-23	Gamma proportional counter containing high z gas and low z moderator
US3889125A (en)	1975-06-10	Radiation shield for x-ray fluorescence analytical device
Christaller	1967	Experimental peak/total ratios of a 4 ″× 4 ″NaI (Tl) crystal
US3693012A (en)	1972-09-19	Passive source of secondary radiation with a source-shield grid
US2912591A (en)	1959-11-10	Radiation protection device
US3263080A (en)	1966-07-26	Radiation dosimeter for measuring exposure to high and low energy radiation
US3404274A (en)	1968-10-01	Method for measuring the shielding effectiveness of a heterogeneous structure for shielding against fundamental charged particles
Cooper et al.	1968	An Anticoincidence-Shielded Ge (Li) Gamma-Ray Spectrometer for High Sensitivity Counting

US2871367A - Gamma ray collimating device - Google Patents

Info

Links

Images

Classifications

Definitions

Description

Priority Applications (1)

Applications Claiming Priority (1)

Publications (1)

Family

ID=24093439

Family Applications (1)

Country Status (1)

Cited By (7)

Citations (2)

Patent Citations (2)

Cited By (7)

Similar Documents