CA1181536A - Compact x-ray collimator - Google Patents
Compact x-ray collimatorInfo
- Publication number
- CA1181536A CA1181536A CA000446290A CA446290A CA1181536A CA 1181536 A CA1181536 A CA 1181536A CA 000446290 A CA000446290 A CA 000446290A CA 446290 A CA446290 A CA 446290A CA 1181536 A CA1181536 A CA 1181536A
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- Canada
- Prior art keywords
- pair
- elements
- shutter elements
- shutter
- disposed
- Prior art date
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- Expired
Links
- 230000005855 radiation Effects 0.000 claims description 13
- 230000002093 peripheral effect Effects 0.000 claims description 5
- 229910052729 chemical element Inorganic materials 0.000 claims description 2
- 239000000463 material Substances 0.000 description 10
- 230000002745 absorbent Effects 0.000 description 8
- 239000002250 absorbent Substances 0.000 description 8
- 229910000831 Steel Inorganic materials 0.000 description 2
- 238000004519 manufacturing process Methods 0.000 description 2
- 238000000926 separation method Methods 0.000 description 2
- 239000010959 steel Substances 0.000 description 2
- 229910001245 Sb alloy Inorganic materials 0.000 description 1
- 239000011358 absorbing material Substances 0.000 description 1
- XAGFODPZIPBFFR-UHFFFAOYSA-N aluminium Chemical compound [Al] XAGFODPZIPBFFR-UHFFFAOYSA-N 0.000 description 1
- 229910052782 aluminium Inorganic materials 0.000 description 1
- 239000002140 antimony alloy Substances 0.000 description 1
- 238000005266 casting Methods 0.000 description 1
- 238000010276 construction Methods 0.000 description 1
- 239000002826 coolant Substances 0.000 description 1
- 230000000875 corresponding effect Effects 0.000 description 1
- 239000003562 lightweight material Substances 0.000 description 1
- 238000000034 method Methods 0.000 description 1
- 238000000465 moulding Methods 0.000 description 1
- 230000011664 signaling Effects 0.000 description 1
- 239000013077 target material Substances 0.000 description 1
Landscapes
- Apparatus For Radiation Diagnosis (AREA)
Abstract
Abstract of the Disclosure An X-ray collimator comprising an X-ray shielded enclosure having aligned entrance and exit apertures for permitting passage of an X-ray beam, the exit aperture having a generally rectangular configuration defined by edges of two orthogonally disposed pairs of opposing rotatable exit shutter elements. Each of the exit shutter elements has a generally semi-cylindrical configuration and is concentrically disposed about a respective axis of rotation. Each pair of semi-cylindrical exit shutter elements is mounted for opposing rotatable movement within the other pair of semi-cylindrical exit shutter elements. The entrance aperture of the housing may be defined by two orthogonally disposed pairs of opposing shutter plates, one pair thereof being directly linked to an associated pair of semi-cylindrical exit shutter elements for corresponding movement therewith.
Description
53~
Background of the Invention . ~_ 1. Field of the Invention This invention relates generally to radiation collimator devices and is concerned more particularly with an X-ray collimator device having a simplified and compact arrangement of shutter elements.
Background of the Invention . ~_ 1. Field of the Invention This invention relates generally to radiation collimator devices and is concerned more particularly with an X-ray collimator device having a simplified and compact arrangement of shutter elements.
2. Discussion of the Prior Art An X-ray generator usually co'nprises an oil-filled housing having therein an X-ray tube provided with an electron-emitting cathode and a spaced anode target. The cathode generally is disposed to direct a beam of electrons onto a small areaJ known as the "focal spot" area, of the anode with suffi-cient energy to generate X-rays in the target material. As a result, X-rays radiate from the focal spot area in all directions within the tube envelope.
The useful portion of these X-rays pass, in the form of a conical beam, through an X-ray transparent window of a radially aligned port which is recessed in the wall of the housing. Thus, the focal spot area of the anode target ide~lly functions as a point source of the conical X-ray beam emanating from the port of the X-ray generator.
The X-ray beam may be directed, for example, through a selected region of a human patient for a limited interval of time~ and impinge on an aligned surface area of a rectangular film. However, in order to protect the patient from over-exposure to X-radiation, it is required that the irradiated region of ~he patient be no larger than the effective area of the rectangular film. Accordingly, there may 'be mounted over the port of the X-ray generator a collimator device having therein suitable X-ray absorbent shutter elements for providing an adjustable exit aperture of the desired size. In this manner, the conical X-ray 'beam emanating from the port of the X-ray generator may be restricted by the collimator shutter elements to the proper cross-sectional , i3f~
size and configuration for conforming to the effective area o-f ~he rec*angular film.
Some X-ray collimator devices of the prior art have a rectangular exit aperture defined by two orthogonally disposed pairs of opposing pivotal shutter plates. ~iowever, one pair of shutter plates is mounted for opposing pivotal movement in a plane above the other pair of shutter plates. Also, each of the orthogonally disposed pairs of shutter plates may require relative-ly complex drive means for adjusting the respective elements of each pair to provide desired aperture sizes. Consequently, the device having the shutter plates and required drive gearing, including entrance shutter-to-exit shutter linkages, may not lend itself to compactness or economy for situations where a compact and relatively inexpensive collimator is desired.
~ummary of the Invention Accordingly, this invention provides a compact and simplified collimator suitable for relatively inexpensive fabrication having shutter means for providing an X-ray beam conforming to an area of an X-ray film casset*e.
The shutter means comprises two orthogonally disposed pairs of opposing rotatable exit shutter elements, each exit shutter element having an edge dis-posed for forming a portion of the periphery of an exit aperture of the collimator. Each exit shutter element has a generally semi-cylindrical configuration which is substantially concentric with its respective axis of rotation. Each pair of the semi-cylindrical shutter elements is adapted to rotate within the region bounded by the other pair to provide a compact struc-ture. Further, the two pair of shutter elements are identical in construction and may be formed by a relatively inexpensive stamping process thereby reducing the cost of the collimator.
The collimator preferably includes an entrance shutter comprising
The useful portion of these X-rays pass, in the form of a conical beam, through an X-ray transparent window of a radially aligned port which is recessed in the wall of the housing. Thus, the focal spot area of the anode target ide~lly functions as a point source of the conical X-ray beam emanating from the port of the X-ray generator.
The X-ray beam may be directed, for example, through a selected region of a human patient for a limited interval of time~ and impinge on an aligned surface area of a rectangular film. However, in order to protect the patient from over-exposure to X-radiation, it is required that the irradiated region of ~he patient be no larger than the effective area of the rectangular film. Accordingly, there may 'be mounted over the port of the X-ray generator a collimator device having therein suitable X-ray absorbent shutter elements for providing an adjustable exit aperture of the desired size. In this manner, the conical X-ray 'beam emanating from the port of the X-ray generator may be restricted by the collimator shutter elements to the proper cross-sectional , i3f~
size and configuration for conforming to the effective area o-f ~he rec*angular film.
Some X-ray collimator devices of the prior art have a rectangular exit aperture defined by two orthogonally disposed pairs of opposing pivotal shutter plates. ~iowever, one pair of shutter plates is mounted for opposing pivotal movement in a plane above the other pair of shutter plates. Also, each of the orthogonally disposed pairs of shutter plates may require relative-ly complex drive means for adjusting the respective elements of each pair to provide desired aperture sizes. Consequently, the device having the shutter plates and required drive gearing, including entrance shutter-to-exit shutter linkages, may not lend itself to compactness or economy for situations where a compact and relatively inexpensive collimator is desired.
~ummary of the Invention Accordingly, this invention provides a compact and simplified collimator suitable for relatively inexpensive fabrication having shutter means for providing an X-ray beam conforming to an area of an X-ray film casset*e.
The shutter means comprises two orthogonally disposed pairs of opposing rotatable exit shutter elements, each exit shutter element having an edge dis-posed for forming a portion of the periphery of an exit aperture of the collimator. Each exit shutter element has a generally semi-cylindrical configuration which is substantially concentric with its respective axis of rotation. Each pair of the semi-cylindrical shutter elements is adapted to rotate within the region bounded by the other pair to provide a compact struc-ture. Further, the two pair of shutter elements are identical in construction and may be formed by a relatively inexpensive stamping process thereby reducing the cost of the collimator.
The collimator preferably includes an entrance shutter comprising
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two orthogonally disposed pairs of entrance shutter elements, one pair thereof being pivotally movable to define a portion of the entrance aperture. Each of the movable entrance shutter elements is directly linked to an associated exit shutter element for correspond-ing movement therewith.
In accordance with the present invention~ there is provided a radiation collimator comprising: (a) a housing; (b) a pair of op-posing shutter elements, each one thereof having a radiation absorb-ing surface and a gear disposed in stationary relationship thereto, such gear having a surface disposed in a plane orthogonal to the radiation absorbing surface and having engageable teeth disposed along an edge of such gear orthogonal to the surface of the gear, such gear having a shaft normal to the surface of the gear and rotat-ably mounted to the housing, such pair of opposing shutter elements being mounted within the housing with the teeth of one of the gears of one of the shutter elements engaged with the teeth of the gear of the other one of the shutter elements; (c) a pair of entrance shutter elements pivotally mounted to the housing; and (d) a pair of linkage arms, such arms being connected to the pair of shutter elements at a first portion thereof and being connected to the surface of the gears at a second portion thereof and wherein such arms are pivotally con-nected to housing at a point between such first and second portions thereof.
In accordance with the present invention, there is fur-ther provided a beam limiting device comprising: two orthogonal pairs of opposing shutter elements disposed for defining a beam collimating aperture having an axial centerline, each of said elements having cylindrically curved wall portions disposed orthogonally to said 53~;
axial centerline and longitudinal edge portions disposed for defin-ing respective peripheral portions of said aperture; and means dis-posed adjacent at least one arcuate end of each of said cylindri-- 3a -;36 cally curved wall portions for rotating each of said shutter elements about its longitudinal axis and moving said longitudinal edge portions relative to one another for adjusting the size of the aperture.
In accordance with the present invention~ there is further provided a beam limiting device comprising: two orthogonal pairs of opposing cylindrically curved shutter elements disposed for defining a rectangular aper-ture the elements of each of said pairs having respective longitudinal edge portions disposed in opposing relationship with one another between said cylindrically curved elements of the other pair and supported in spaced en-circling relationship with respective arcuate ends thereof; and means disposed adjacent at least one arcuate end of each of the elements of said pairs for rotating said each of the elements in respective opposing directions about its longitudinal centerline and adjusting the size of said aperture.
In accordance with the present invention, there is further provided a beam limiting device comprising: a radiation shielded housing in-cluding an entrance wall having disposed therein entrance aperture means for permitting passage of a radiation beam into the housing; exit shutter means disposed in the housing for providing collimation of said beam and including two orthogonal pairs of opposing cylindrically curved shutter elements, the ele-ments of each pair having respective longitudinal edge portions disposed in opposing relationship between the cylindrically curved elements of the other pair and supported in spaced enveloping relationship with respective arcuate ends thereof; and means disposed adjacent at least one arcuate end of each of the shutter elements of said respective pairs for rotating said each of the elements in respective opposing directions and adjusting the size of said aperture.
In accordance with the present invention, there is further ;3~
provided a radiation collimator comprising:
(a) a housing;
(b) a first and a second pair of shutter elements disposed within the housing, the first pair of shutter elements being rotatably mounted with respect to the housing about a first pair of parallel axes and the second pair of shutter elements being rotatably mounted with respect to the housing about a second pair of parallel axes, the first pair of parallel axes being perpen-dicular to the second pair of parallel axes, each one of such shutter elements having a concave surface with a pair of edge portions thereof parallel to the axis of rotation of such shutter element, one of such edge portions thereof defining a different peripheral portion of an aperture, one of the pair of edge portions of the surfaces of the first pair of shutter elements being adapted to rotate within a space disposed between the surfaces of the second pair of shutter elements and one of the pair of edge portions of the surfaces of the second pair of shutter elements being adapted to rotate within a space disposed between the surfaces of the first pair of shutter elements.
Brief Description of the Drawings For a more complete understanding of this invention reference is made in the following detailed description to the drawings wherein:
Figure 1 is a pictorial view, partly in section, showing a col-limator embodying this invention attached in operative relationship to the housing of an X-ray generator;
Figure 2 is an isometric view of the collimator shown in Figure l;
Figure 3 is a schematic view showing the structural relationship of a pair of the movable entrance shutter elements and the two pairs of exit shutter elements shown in Figure 2;
Figure 4 is a fron~ sectional view showing the relationship of 5;~36 each of the exit shutter elements in a fully open position~ such cross section being taken along line 4-4 in Figure 5;
Figure 5 is a side sectional view taken along the line 5-5 shown in Figure 4 and looking in the direction of the arrows with the movable pair of entrance shutter elements and the pair of exit shutter elemen~s coupled thereto in a fully open position;
Figure 6 is a front sectional elevation view similar to Figure
two orthogonally disposed pairs of entrance shutter elements, one pair thereof being pivotally movable to define a portion of the entrance aperture. Each of the movable entrance shutter elements is directly linked to an associated exit shutter element for correspond-ing movement therewith.
In accordance with the present invention~ there is provided a radiation collimator comprising: (a) a housing; (b) a pair of op-posing shutter elements, each one thereof having a radiation absorb-ing surface and a gear disposed in stationary relationship thereto, such gear having a surface disposed in a plane orthogonal to the radiation absorbing surface and having engageable teeth disposed along an edge of such gear orthogonal to the surface of the gear, such gear having a shaft normal to the surface of the gear and rotat-ably mounted to the housing, such pair of opposing shutter elements being mounted within the housing with the teeth of one of the gears of one of the shutter elements engaged with the teeth of the gear of the other one of the shutter elements; (c) a pair of entrance shutter elements pivotally mounted to the housing; and (d) a pair of linkage arms, such arms being connected to the pair of shutter elements at a first portion thereof and being connected to the surface of the gears at a second portion thereof and wherein such arms are pivotally con-nected to housing at a point between such first and second portions thereof.
In accordance with the present invention, there is fur-ther provided a beam limiting device comprising: two orthogonal pairs of opposing shutter elements disposed for defining a beam collimating aperture having an axial centerline, each of said elements having cylindrically curved wall portions disposed orthogonally to said 53~;
axial centerline and longitudinal edge portions disposed for defin-ing respective peripheral portions of said aperture; and means dis-posed adjacent at least one arcuate end of each of said cylindri-- 3a -;36 cally curved wall portions for rotating each of said shutter elements about its longitudinal axis and moving said longitudinal edge portions relative to one another for adjusting the size of the aperture.
In accordance with the present invention~ there is further provided a beam limiting device comprising: two orthogonal pairs of opposing cylindrically curved shutter elements disposed for defining a rectangular aper-ture the elements of each of said pairs having respective longitudinal edge portions disposed in opposing relationship with one another between said cylindrically curved elements of the other pair and supported in spaced en-circling relationship with respective arcuate ends thereof; and means disposed adjacent at least one arcuate end of each of the elements of said pairs for rotating said each of the elements in respective opposing directions about its longitudinal centerline and adjusting the size of said aperture.
In accordance with the present invention, there is further provided a beam limiting device comprising: a radiation shielded housing in-cluding an entrance wall having disposed therein entrance aperture means for permitting passage of a radiation beam into the housing; exit shutter means disposed in the housing for providing collimation of said beam and including two orthogonal pairs of opposing cylindrically curved shutter elements, the ele-ments of each pair having respective longitudinal edge portions disposed in opposing relationship between the cylindrically curved elements of the other pair and supported in spaced enveloping relationship with respective arcuate ends thereof; and means disposed adjacent at least one arcuate end of each of the shutter elements of said respective pairs for rotating said each of the elements in respective opposing directions and adjusting the size of said aperture.
In accordance with the present invention, there is further ;3~
provided a radiation collimator comprising:
(a) a housing;
(b) a first and a second pair of shutter elements disposed within the housing, the first pair of shutter elements being rotatably mounted with respect to the housing about a first pair of parallel axes and the second pair of shutter elements being rotatably mounted with respect to the housing about a second pair of parallel axes, the first pair of parallel axes being perpen-dicular to the second pair of parallel axes, each one of such shutter elements having a concave surface with a pair of edge portions thereof parallel to the axis of rotation of such shutter element, one of such edge portions thereof defining a different peripheral portion of an aperture, one of the pair of edge portions of the surfaces of the first pair of shutter elements being adapted to rotate within a space disposed between the surfaces of the second pair of shutter elements and one of the pair of edge portions of the surfaces of the second pair of shutter elements being adapted to rotate within a space disposed between the surfaces of the first pair of shutter elements.
Brief Description of the Drawings For a more complete understanding of this invention reference is made in the following detailed description to the drawings wherein:
Figure 1 is a pictorial view, partly in section, showing a col-limator embodying this invention attached in operative relationship to the housing of an X-ray generator;
Figure 2 is an isometric view of the collimator shown in Figure l;
Figure 3 is a schematic view showing the structural relationship of a pair of the movable entrance shutter elements and the two pairs of exit shutter elements shown in Figure 2;
Figure 4 is a fron~ sectional view showing the relationship of 5;~36 each of the exit shutter elements in a fully open position~ such cross section being taken along line 4-4 in Figure 5;
Figure 5 is a side sectional view taken along the line 5-5 shown in Figure 4 and looking in the direction of the arrows with the movable pair of entrance shutter elements and the pair of exit shutter elemen~s coupled thereto in a fully open position;
Figure 6 is a front sectional elevation view similar to Figure
4 but having the pair of exit shutter elements shown in a partly open position;
Figure 7 is a side sectional elevation view similar to Figure 5 but having the pair of exit shutter elements shown in a substantially closed position;
Figure 8 is a bottom plan view looking into the exit end of the collimator shown in Figure 1, with the exit shutter elements in a fully open position;
Figures 9a-9d are respective diagrammatic views showing the operational relationship of the exit shutter elements comprising the exit shutter shown in Figure 3 in various positions.
Figure 10 is a plan view of exit shutter element suita~le for use in the collimator shown in Figure 1 at a stamping stage in the manufacture thereof and prior to forming; and Figure 11 is an isometric view of the stamped exit shutter element shown in Figure 10 subsequent to forming for use in the collimator shown in Figure 1.
Description of the Preferred Embodiment Referring to the drawings wherein like characters of reference designate like parts, there is shown in Figure 1 an X-ray apparatus 10 which includes an X-ray generator 12 having a hollow cylindrical casing 14 wherein an X-ray tube 16 is longitudinally disposed. Casing 14 generally is filled with a dielectric coolant, such as oil, for example, and is provided with exter-nally extending cable terminals 18 and 20, respectively, which provide means for applying respective electrical potentials to the electrodes of X-ray tube 16.
Within the envelope 22 of X-ray ~ube 16, an electron emitting cathode 24 is disposed to direct a beam of electrons onto a small focal spot area 26 of an anode target 28, which may be of the rotating type, for example.
Electrons in the beam impingè on the focal spot area 26 with sufficient energy to generate X-rays which radiate therefrom in all directions. Consequently, the casing 14 generally is lined with suitable material, such as lead, for example, for absorbing a major portion of the unused X-rays emanating from the focal spot area 26.
The useful portion of the X-rays, thus produced, radiate from the focal spot area 26 in a concical-shaped beam which passes through an X-ray transparent window 30 of a radially aligned port 32. The port 32 is cup-shaped and recessed in the cylindrical wall of casing 14 such that the window 30 is disposed in close proximity to the focal spot area 26 of anode target 28. Thus, the focal spot area 26 functions as a point source of the conical X-ray beam passing through the adjacent window 30 of port 32. However, off-focus X-radiation generated in portions of the anode target 28 outside of the focal spot area 26 also may pass through the window 30 of port 32, usually at an angle with the axial centerline of the conical X-ray beam emanating from focal spot area 26. Mounted over the port 32 of generator 12, in a well-known manner, is an X-ray collimator 34 embodying this invention.
As shown in Figure 2, the collimator 34 includes an X-ray shielded enclosure or housing 36 provided with spaced opposing front and rear walls,
Figure 7 is a side sectional elevation view similar to Figure 5 but having the pair of exit shutter elements shown in a substantially closed position;
Figure 8 is a bottom plan view looking into the exit end of the collimator shown in Figure 1, with the exit shutter elements in a fully open position;
Figures 9a-9d are respective diagrammatic views showing the operational relationship of the exit shutter elements comprising the exit shutter shown in Figure 3 in various positions.
Figure 10 is a plan view of exit shutter element suita~le for use in the collimator shown in Figure 1 at a stamping stage in the manufacture thereof and prior to forming; and Figure 11 is an isometric view of the stamped exit shutter element shown in Figure 10 subsequent to forming for use in the collimator shown in Figure 1.
Description of the Preferred Embodiment Referring to the drawings wherein like characters of reference designate like parts, there is shown in Figure 1 an X-ray apparatus 10 which includes an X-ray generator 12 having a hollow cylindrical casing 14 wherein an X-ray tube 16 is longitudinally disposed. Casing 14 generally is filled with a dielectric coolant, such as oil, for example, and is provided with exter-nally extending cable terminals 18 and 20, respectively, which provide means for applying respective electrical potentials to the electrodes of X-ray tube 16.
Within the envelope 22 of X-ray ~ube 16, an electron emitting cathode 24 is disposed to direct a beam of electrons onto a small focal spot area 26 of an anode target 28, which may be of the rotating type, for example.
Electrons in the beam impingè on the focal spot area 26 with sufficient energy to generate X-rays which radiate therefrom in all directions. Consequently, the casing 14 generally is lined with suitable material, such as lead, for example, for absorbing a major portion of the unused X-rays emanating from the focal spot area 26.
The useful portion of the X-rays, thus produced, radiate from the focal spot area 26 in a concical-shaped beam which passes through an X-ray transparent window 30 of a radially aligned port 32. The port 32 is cup-shaped and recessed in the cylindrical wall of casing 14 such that the window 30 is disposed in close proximity to the focal spot area 26 of anode target 28. Thus, the focal spot area 26 functions as a point source of the conical X-ray beam passing through the adjacent window 30 of port 32. However, off-focus X-radiation generated in portions of the anode target 28 outside of the focal spot area 26 also may pass through the window 30 of port 32, usually at an angle with the axial centerline of the conical X-ray beam emanating from focal spot area 26. Mounted over the port 32 of generator 12, in a well-known manner, is an X-ray collimator 34 embodying this invention.
As shown in Figure 2, the collimator 34 includes an X-ray shielded enclosure or housing 36 provided with spaced opposing front and rear walls,
5~3~
37 and 38, respectively, which are orthogonally disposed to spaced opposing side walls, 39 and 40, respectively. The walls 37-4~ are orthogonally disposed ~o an entrance wall 41 Erom which may protrude an entrance shutter 42. En-trance shutteT 42 extends into the cup-shaped recess of port 32 (Figure 1) to dispose an adjustable entrance aperture 48 formed by the entrance shutter 42 in close proximity with the focal spot area 26 of target 28. The entrance aperture 48 is disposed substantially in alignment with the focal spot area 26, and is adjusted to a size for permitting passage of the X-ray beam emanating therefrom while restricting passage of off-focus X-radiation. Entrance aperture 48 may have a rectangular configuration formed by four orthogonally disposed entrance shutter plates or elements> 43-46, respectively~ made of X-ray absorbent material, such as lead, for example. Alternatively, the respective entrance shutter elements 43-46 may be made of lightweight material, such as aluminum, for example, which is coated with X-ray absorbent material, such as lead, for example. Also, the respective walls 37-41 of housing 36 may be made of suitably rigid material, such as sheet steel, for example, having surfaces provided with a layer of X-ray absorbent material, such as lead, for example. Thus, an economical lightweight housing may be fabricated by stamping and forming the walls 37-41 and lining the surfaces of the resulting structural parts with X-ray absorbing material.
Here the portion of housing 36 opposite the entrance wall 41 is open for permitting unrestricted passage of an X-ray beam collimated by shutter elements disposed within the housing 36, in a manner to be described, to emerge from the collimator 34 with a cross-sectional area conforming to a suitable X-ray receptor (not shown). ~50re particularly~ the emerging colli-mated X-ray beam is provided with a desired cross-sectional size and shape in housing 36 by means of an exit shutter 50 disposed in alignment with the 53~
entrance aperture 48 formed by entrance shutter 42. Exit shutter 50 is com-prised of a first pair of opposing exit shu-tter elements 51 and 52, respective-ly, which are orthogonally disposed with respect to a second pair of opposing exit shutter elemen-ts 53 and 54 respectively. The exit shutter elements 51-54 are orthogonally disposed with respect to the centerline of the exit shutter 50 (i.e. the axis of the collimator disposed normal to the entrance wall 41 and passing through the center of the entrance and exit apertures).
The exit shutter elements 51-54 are curved, with respect to such centerline, concavely when viewed from a region within the exit shutter 50.
Each of the exit shutter elements 51-54 is disposed in registration with a respective one of the entrance shutter elements 43-46. Preferably each of the exit shutter elements 51-54 has a substantially semi-cylindrical surface disposed about a respective longitudinal axis orthogonal to ~he centerline of the collimator. Each one of the exit shutter elements 51-54 is adapted to rotate about its respective longitudinal axis in a manner to be described hereafter. Suffice it to say here however, that the lower longitudinal edge of each one of the exit shutter elements 51-54 defines a respective peripheral portion of the generally rectangular shaped exit aperture. The length of the exit aperture is related to the separation between the lower longitudinal edges of one pair of opposing exit shutter elements 51-54; and the width of the exit aperture is related to the separation between the lower longitudinal edges of the other pair of opposing exit shutter elements.
As shown in Figures 3-8, a pair of opposing exit shutter elements 51 and 52 have respective upper longitudinal edge portions 61 and 62 disposed to rotate arcuately into a region between a pair of orthogonally disposed exit shutter elements 53-54 and below respective upper longitudinal edge portions 63 and 64 thereof. The exit shutter elements 51 and 52 have opposing ~8~53~i lower longitudinal edge portions, 65 and 66, respectively, which define one dimension of a rectangular exit aperture 90; and the exit shutter elements 53 and 54 have opposing longitudinal lower edge portions, 67 and 68, respectively, which define the o~her dimension of rectangular exit aperture 90. The lower edge portion 65 of exit shutter element 51 extends longitudinally beyond respective arcuate ends of the element 51 and is bent orthogonally to form radially extended legs 70 and 71, respectively. Each of the legs 70 and 71 extends radially of a respective spur gear 72 and 73 and is fixedly attached thereto by screws 200, 202 so that the legs 70 and 71 and the spur gears 72, 73 rotate as a single unit, about the longitudinal centerline of semi-cylindrical shutter element 51. The spur gears 72 and 73 have central aper-tures through which respective axle pins 74 and 75 extend and are bearingly mounted in side walls 39 and 40, respectively, of housing 36.
The spur gears 72 and 73 intermesh with respective spur gears 76 and 77 having fixedly attached to their inner surfaces, as by screws 204 and 206, for example, radially extending legs, 78 and 79, respectively. The legs 78 and 79 constitute orthogonally bent end portions of the longitudinal lower edge portion 66 which extends beyond arcuate ends of the exit shutter element 52. The spur gear 76 has a central aperture aligned with a central aperture in spur gear 77 through which respective axle pins 81 and 82 extend and are bearingly mounted in respective side walls 39 and 40 of housing 36.
The spur gear 73 meshes with a combination spur-beveled idler gear assembly 80 which, in turn meshes with a beveled drive gear 82 having extended centrally through it a rotatable shaft 84 bearingly mounted in front wall 37. An exter-n~.lly extended end portion of shaft 84 may have affixed thereto a suitable knob 85 which provide means for manually rotating shaft 84 and the intermeshed gears 72-73 and 76-77 ~o rotate the respective exit shutter elements 51 and . - 10 -3~;
52 in opposing angular directions about their respective axial, or longitudinal centerlines.
As a result, upper longitudinal edge portions 61 and 62 of exit shutter elements 51 and 52, respectively, move arcuately toward or away from one another within the region defined by the orthogonally disposed exit shutter elements 53 and 54, respectively. Also, the opposing lower longitudinal edge portions 65 and 66 are positioned relative to one another for defining an interposed dimension of the rectangular exit aperture 90. The other dimension of rectangular exit aperture 90 is defined by relative positioning of the lower longitudinal edge portions 67 and 68 of exit shutter elements 53 and 54 which move arcuately toward and away from one another in a region defined by orthogonally disposed exit shutter elements 51 and 52, respectively. The exit shutter elements 53 and 54 curve envelopingly around respective adjacent arcuate ends of the shutter elements 51 and 52, and have respective upper longitudinal edge portions 63 and 64 positioned relative to one another in a region over-lying the upper longitudinal edge portions 61 and 62 of shutter elements 51 and 52, respectively.
Upper edge portion 63 extends longitudinally beyond the opposing arcuate ends of exit shutter element 53, and is bent orthogonally to form respective radially extending legs 86 and 87. The legs 86 and 87 extend radial-ly of respective spur gears 88 and 89 to which they are fixedly attached by screw 208, 210 so that legs 86, 87 and spur gears 88, 89 rotate as a single unit about the aligned axial centerlines of gears 88 and 89. Similarly, upper longitudinal edge portion 64 of shutter element 54 extends longitudinally beyond the opposing arcuate ends of the exit shutter element 54, and is bent orthogonally to form respective radially extending legs 91 and 92. The legs 91 and 92 extend radially of respective spur gears 93 and 94 to which they are fixedly attached by screws 212, 214 so that the exit shutter element 52 and the fixedly attached spur gears 93, 94 rotate as a single unit about the align-ed axi.al centerlines of gears 93 and 94. The gears 93 and 94 have aligned central apertures through which respective axle pins 95 and 96 extend and are bearingly mounted in front and rear walls 37 and 38, respectively, of housing 36. Also, the gears 88 and 89 have aligned central apertures through which respective axle pi.ns 97 and 98 extend and are bearingly mounted in the front and rear walls 37 and 38, respectively, of housing 36.
The spur gear 88, for example, may be rotatably coupled through a spur gear 101 to a shaft 99, rotatably mounted in front wall 37 of housing 36.
The shaft 99 may be provided with an externally protruding end portion to which may be fixedly attached a suitable knob 100 for manually rotating shaft 99, gear 101, and intermeshed gears 88-89 and 93-94. Thus, the exit shutter elements 53 and 54 may be rotated in respective opposing angular directions about their axial or longitudinal centerlines to travel arcuately around adjacent end portions of exit shutter elements 51 and 52, respectively, and move into or out of the region defined by orthogonally disposed shutter elements 51 and 52, respectively. As a result, in the region defined by orthogonally disposed exit shutter elements 51 and 52, the respective longitudinal edge portions 67 and 68 of the opposing shutter elements 53 and 54 move arcuately toward or away from one another to define the interposed dimension of exit aperture 90.
Accordingly, the respective exit shutter elements 51 and 52 may be adjusted independently of the respective exit shutter elements 53 and 54 to define an interposed dimension of the exit aperture 90 which may be relative-ly large, as shown in Figwre 9A, or which may be relatively small, as shown in Figure 9B. Also, the respective exit shutter elements 53 and 54 may be 53~
adjusted independently of the respective exit shutter elements 5~ and 59 to define all orthogonal dimension of exit aperture 90 which may be relatively large, as shown in Figure ~C, or which may be relatively small, as shown in Figure 9D. This independence of adjustment is achieved by disposing the res-pective pairs of semi-cylindrical exit shwtter elements 51-52 and 53-54 in enfolding relationship with one another. The semi-cylindrical exit shutter elements 51-54 are supported at their respective opposing end portions and rotated about their respective longitudinal axes such that longitudinal edge portions of one pair is enabled to move arcuately within a region defined by the orthogonally disposed elements of the other pair. As a result, longi-tudinal edge portions of the respective pairs of exit shutter elements are en-abled to share a common region between the longitudinal edge portions of the other pair to produce the very compact collimator 34.
Each of the exit shutter elements 51-54 may be made of X-ray absorbent material, such as lead-antimony alloy, for example, or may be made of a thin rigid material coated with X-ray absorbent material, such as sheet steel or molded plastic-laminated with lead3 for example. Thus, each of exit shutter elements 51-54 may be stamped and formed or molded and then laminated.
Accordingly, as shown in Figure 10, an exit shutter element, such as 51, for example, may be stamped out as a blank 122 having a generally rectangular portion 51a. The portion 51a has a longitudinal edge por~ion 65a provided with opposing extensions 70a and 71a, respectively, which are integrally connected to respective spur gear portions 72a and 73a. Subsequently, as shown in Figure 11, the rectangular portion 51a may be provided with an arcuate curvature, as by means of a mandrel, for example, and the extensions 70a and 71a may be folded along respective lines 123 and 124 to dispose the axial centerline of respective spur gear portions 72a and 73a substantially on the longitudinal 3~
centerline 125 of the arcuately curved portion 51a. Alternatively, each of the exit shutter elements, such as 51, for example, may be fabricated integrally with its associated spur gears 72 and 73 in place, as by casting or molding, for example, to provide a very economical means for producing the collimator 34. In either instance, if the fabricated shutter element is not made of X-ray absorbent material, it may be subsequently provided with a lining of X-ray absorbent material, such as lead, for example.
As shown in Figures 3-7, the spur gears 72 and 73 of exit shutter element 51 may be provided with respective eccentrically attached pins 102 and 104 which extend outwardly therefrom. The pin 102 protrudes through a slotted end portion of a yoke link arm 106. Arm 106 is integrally formed with a yoke link crossbar 108 which has a central portion fixedly attached to (here integrally formed with~ an entrance shutter element 43 of entrance shutter 42.
The opposing end portion of crossbar 108 is integrally formed with a relatively short yoke link arm llO. The yoke link crossbar 108 is rotatably supported on a rod 109 having opposing end portions protruding through apertures provided in walls 39 and 41, respectively. Similarly, the pin 104 protrudes through a slotted end portion of a yoke link arm 112. Arm 112 is integrally formed with one end of a yoke link crossbar 114 which has a central portion fixedly attached to entrance shutter element 44 of entrance shutter 42. The opposing end of crossbar 114 is integrally formed with a relatively short yoke link arm 116. The yoke crossbar 114 is rotatably supported on a rod 111 having oppos-ing end portions protruding through side walls 39 and 41, respectively.
Thus, as shown more particularly in Figures 4 and 5, the knobs 85 and 100 may be adjusted to rotate the respective pairs of exit shutter elements 51-52 and 53-54 to a substantially fully open position. Conse~uent-ly, the movable entrance shutter elements 43 and 44 ~Figure 5), respectively, 3~;
are adjusted in accordance with the adjustment of exit shutter elements 51-52 to permit a widely divergent X-ray beam *o enter the housing 36 and to res~rict the off focus X-radiation. Accordingly, the widely divergent beam is collimated within housing 36 by the aperture defining edge portion 65, 66, 67 and 68 of the exit shut-ter elements 51-54 respectively, as indicated by arrows 126-129.
Also, as shol~n in Figures 6 and 7, the knobs 85 and 100 may be adjusted to rotate the respective pairs of exit shutter elements 51-52 and 53-54 to a more nearly closed position. Note that as the exit shutter elements 51-52 are rotated in counterclockwise and clockwise directions, respectively, the arms 106 and 112 cause the pivotally mounted entrance shutter elements 43 and 44 to define a more closed entrance aperture, as shown in Figure 7. As a result the pair of movable entrance shutter elements 43 and 44 are adjusted corres-pondingly to permit passage of a less divergent X-ray beam indicated by arrows 126a - 129a, respectively, having outer dimensions defined by the exit shutter elements while maximi~ing restriction of off-focus X-radiation. Thus, the less divergent X-ray beam entering housing 36 is collimated by the aperture defining edge portions of exit shutter elements 51-54 being suitably positioned for providing the X-ray beam with the desired cross-sectional dimensions.
As shown in Figures 2 and 8, there may be mounted on front wall 37 a front control panel 120 through which the respective shafts 84 and 99 may extend for rotation by respective knobs 85 and 100 externally of the panel.
The control panel 120 also may be provided with respective indicators for signalling when the power is "on", when the X-ray generator 12 is on "hold", and when the respective pairs of exit shutter elements in exit shutter 50 are adjusted. The respective shafts 84 and 99 also may be coupled to respective motors and rotation sensors, such as potentiometers, for example, which are mounted between panel 120 and front wall 37 for automatic operation of the exit L5~
shutter 50.
From the foregoing, it will be apparent that all o~ the objec-tives of this invention have been achieved by the structures shown and described herein. It also will be apparent, however, that various changes may be made by those skilled in the art without departing from the spirit of the invention as expressed in the appended claims. It is to be understood, therefore, that all matter shown and described herein is to be interpreted as illustrative and not in a limiting sense.
37 and 38, respectively, which are orthogonally disposed to spaced opposing side walls, 39 and 40, respectively. The walls 37-4~ are orthogonally disposed ~o an entrance wall 41 Erom which may protrude an entrance shutter 42. En-trance shutteT 42 extends into the cup-shaped recess of port 32 (Figure 1) to dispose an adjustable entrance aperture 48 formed by the entrance shutter 42 in close proximity with the focal spot area 26 of target 28. The entrance aperture 48 is disposed substantially in alignment with the focal spot area 26, and is adjusted to a size for permitting passage of the X-ray beam emanating therefrom while restricting passage of off-focus X-radiation. Entrance aperture 48 may have a rectangular configuration formed by four orthogonally disposed entrance shutter plates or elements> 43-46, respectively~ made of X-ray absorbent material, such as lead, for example. Alternatively, the respective entrance shutter elements 43-46 may be made of lightweight material, such as aluminum, for example, which is coated with X-ray absorbent material, such as lead, for example. Also, the respective walls 37-41 of housing 36 may be made of suitably rigid material, such as sheet steel, for example, having surfaces provided with a layer of X-ray absorbent material, such as lead, for example. Thus, an economical lightweight housing may be fabricated by stamping and forming the walls 37-41 and lining the surfaces of the resulting structural parts with X-ray absorbing material.
Here the portion of housing 36 opposite the entrance wall 41 is open for permitting unrestricted passage of an X-ray beam collimated by shutter elements disposed within the housing 36, in a manner to be described, to emerge from the collimator 34 with a cross-sectional area conforming to a suitable X-ray receptor (not shown). ~50re particularly~ the emerging colli-mated X-ray beam is provided with a desired cross-sectional size and shape in housing 36 by means of an exit shutter 50 disposed in alignment with the 53~
entrance aperture 48 formed by entrance shutter 42. Exit shutter 50 is com-prised of a first pair of opposing exit shu-tter elements 51 and 52, respective-ly, which are orthogonally disposed with respect to a second pair of opposing exit shutter elemen-ts 53 and 54 respectively. The exit shutter elements 51-54 are orthogonally disposed with respect to the centerline of the exit shutter 50 (i.e. the axis of the collimator disposed normal to the entrance wall 41 and passing through the center of the entrance and exit apertures).
The exit shutter elements 51-54 are curved, with respect to such centerline, concavely when viewed from a region within the exit shutter 50.
Each of the exit shutter elements 51-54 is disposed in registration with a respective one of the entrance shutter elements 43-46. Preferably each of the exit shutter elements 51-54 has a substantially semi-cylindrical surface disposed about a respective longitudinal axis orthogonal to ~he centerline of the collimator. Each one of the exit shutter elements 51-54 is adapted to rotate about its respective longitudinal axis in a manner to be described hereafter. Suffice it to say here however, that the lower longitudinal edge of each one of the exit shutter elements 51-54 defines a respective peripheral portion of the generally rectangular shaped exit aperture. The length of the exit aperture is related to the separation between the lower longitudinal edges of one pair of opposing exit shutter elements 51-54; and the width of the exit aperture is related to the separation between the lower longitudinal edges of the other pair of opposing exit shutter elements.
As shown in Figures 3-8, a pair of opposing exit shutter elements 51 and 52 have respective upper longitudinal edge portions 61 and 62 disposed to rotate arcuately into a region between a pair of orthogonally disposed exit shutter elements 53-54 and below respective upper longitudinal edge portions 63 and 64 thereof. The exit shutter elements 51 and 52 have opposing ~8~53~i lower longitudinal edge portions, 65 and 66, respectively, which define one dimension of a rectangular exit aperture 90; and the exit shutter elements 53 and 54 have opposing longitudinal lower edge portions, 67 and 68, respectively, which define the o~her dimension of rectangular exit aperture 90. The lower edge portion 65 of exit shutter element 51 extends longitudinally beyond respective arcuate ends of the element 51 and is bent orthogonally to form radially extended legs 70 and 71, respectively. Each of the legs 70 and 71 extends radially of a respective spur gear 72 and 73 and is fixedly attached thereto by screws 200, 202 so that the legs 70 and 71 and the spur gears 72, 73 rotate as a single unit, about the longitudinal centerline of semi-cylindrical shutter element 51. The spur gears 72 and 73 have central aper-tures through which respective axle pins 74 and 75 extend and are bearingly mounted in side walls 39 and 40, respectively, of housing 36.
The spur gears 72 and 73 intermesh with respective spur gears 76 and 77 having fixedly attached to their inner surfaces, as by screws 204 and 206, for example, radially extending legs, 78 and 79, respectively. The legs 78 and 79 constitute orthogonally bent end portions of the longitudinal lower edge portion 66 which extends beyond arcuate ends of the exit shutter element 52. The spur gear 76 has a central aperture aligned with a central aperture in spur gear 77 through which respective axle pins 81 and 82 extend and are bearingly mounted in respective side walls 39 and 40 of housing 36.
The spur gear 73 meshes with a combination spur-beveled idler gear assembly 80 which, in turn meshes with a beveled drive gear 82 having extended centrally through it a rotatable shaft 84 bearingly mounted in front wall 37. An exter-n~.lly extended end portion of shaft 84 may have affixed thereto a suitable knob 85 which provide means for manually rotating shaft 84 and the intermeshed gears 72-73 and 76-77 ~o rotate the respective exit shutter elements 51 and . - 10 -3~;
52 in opposing angular directions about their respective axial, or longitudinal centerlines.
As a result, upper longitudinal edge portions 61 and 62 of exit shutter elements 51 and 52, respectively, move arcuately toward or away from one another within the region defined by the orthogonally disposed exit shutter elements 53 and 54, respectively. Also, the opposing lower longitudinal edge portions 65 and 66 are positioned relative to one another for defining an interposed dimension of the rectangular exit aperture 90. The other dimension of rectangular exit aperture 90 is defined by relative positioning of the lower longitudinal edge portions 67 and 68 of exit shutter elements 53 and 54 which move arcuately toward and away from one another in a region defined by orthogonally disposed exit shutter elements 51 and 52, respectively. The exit shutter elements 53 and 54 curve envelopingly around respective adjacent arcuate ends of the shutter elements 51 and 52, and have respective upper longitudinal edge portions 63 and 64 positioned relative to one another in a region over-lying the upper longitudinal edge portions 61 and 62 of shutter elements 51 and 52, respectively.
Upper edge portion 63 extends longitudinally beyond the opposing arcuate ends of exit shutter element 53, and is bent orthogonally to form respective radially extending legs 86 and 87. The legs 86 and 87 extend radial-ly of respective spur gears 88 and 89 to which they are fixedly attached by screw 208, 210 so that legs 86, 87 and spur gears 88, 89 rotate as a single unit about the aligned axial centerlines of gears 88 and 89. Similarly, upper longitudinal edge portion 64 of shutter element 54 extends longitudinally beyond the opposing arcuate ends of the exit shutter element 54, and is bent orthogonally to form respective radially extending legs 91 and 92. The legs 91 and 92 extend radially of respective spur gears 93 and 94 to which they are fixedly attached by screws 212, 214 so that the exit shutter element 52 and the fixedly attached spur gears 93, 94 rotate as a single unit about the align-ed axi.al centerlines of gears 93 and 94. The gears 93 and 94 have aligned central apertures through which respective axle pins 95 and 96 extend and are bearingly mounted in front and rear walls 37 and 38, respectively, of housing 36. Also, the gears 88 and 89 have aligned central apertures through which respective axle pi.ns 97 and 98 extend and are bearingly mounted in the front and rear walls 37 and 38, respectively, of housing 36.
The spur gear 88, for example, may be rotatably coupled through a spur gear 101 to a shaft 99, rotatably mounted in front wall 37 of housing 36.
The shaft 99 may be provided with an externally protruding end portion to which may be fixedly attached a suitable knob 100 for manually rotating shaft 99, gear 101, and intermeshed gears 88-89 and 93-94. Thus, the exit shutter elements 53 and 54 may be rotated in respective opposing angular directions about their axial or longitudinal centerlines to travel arcuately around adjacent end portions of exit shutter elements 51 and 52, respectively, and move into or out of the region defined by orthogonally disposed shutter elements 51 and 52, respectively. As a result, in the region defined by orthogonally disposed exit shutter elements 51 and 52, the respective longitudinal edge portions 67 and 68 of the opposing shutter elements 53 and 54 move arcuately toward or away from one another to define the interposed dimension of exit aperture 90.
Accordingly, the respective exit shutter elements 51 and 52 may be adjusted independently of the respective exit shutter elements 53 and 54 to define an interposed dimension of the exit aperture 90 which may be relative-ly large, as shown in Figwre 9A, or which may be relatively small, as shown in Figure 9B. Also, the respective exit shutter elements 53 and 54 may be 53~
adjusted independently of the respective exit shutter elements 5~ and 59 to define all orthogonal dimension of exit aperture 90 which may be relatively large, as shown in Figure ~C, or which may be relatively small, as shown in Figure 9D. This independence of adjustment is achieved by disposing the res-pective pairs of semi-cylindrical exit shwtter elements 51-52 and 53-54 in enfolding relationship with one another. The semi-cylindrical exit shutter elements 51-54 are supported at their respective opposing end portions and rotated about their respective longitudinal axes such that longitudinal edge portions of one pair is enabled to move arcuately within a region defined by the orthogonally disposed elements of the other pair. As a result, longi-tudinal edge portions of the respective pairs of exit shutter elements are en-abled to share a common region between the longitudinal edge portions of the other pair to produce the very compact collimator 34.
Each of the exit shutter elements 51-54 may be made of X-ray absorbent material, such as lead-antimony alloy, for example, or may be made of a thin rigid material coated with X-ray absorbent material, such as sheet steel or molded plastic-laminated with lead3 for example. Thus, each of exit shutter elements 51-54 may be stamped and formed or molded and then laminated.
Accordingly, as shown in Figure 10, an exit shutter element, such as 51, for example, may be stamped out as a blank 122 having a generally rectangular portion 51a. The portion 51a has a longitudinal edge por~ion 65a provided with opposing extensions 70a and 71a, respectively, which are integrally connected to respective spur gear portions 72a and 73a. Subsequently, as shown in Figure 11, the rectangular portion 51a may be provided with an arcuate curvature, as by means of a mandrel, for example, and the extensions 70a and 71a may be folded along respective lines 123 and 124 to dispose the axial centerline of respective spur gear portions 72a and 73a substantially on the longitudinal 3~
centerline 125 of the arcuately curved portion 51a. Alternatively, each of the exit shutter elements, such as 51, for example, may be fabricated integrally with its associated spur gears 72 and 73 in place, as by casting or molding, for example, to provide a very economical means for producing the collimator 34. In either instance, if the fabricated shutter element is not made of X-ray absorbent material, it may be subsequently provided with a lining of X-ray absorbent material, such as lead, for example.
As shown in Figures 3-7, the spur gears 72 and 73 of exit shutter element 51 may be provided with respective eccentrically attached pins 102 and 104 which extend outwardly therefrom. The pin 102 protrudes through a slotted end portion of a yoke link arm 106. Arm 106 is integrally formed with a yoke link crossbar 108 which has a central portion fixedly attached to (here integrally formed with~ an entrance shutter element 43 of entrance shutter 42.
The opposing end portion of crossbar 108 is integrally formed with a relatively short yoke link arm llO. The yoke link crossbar 108 is rotatably supported on a rod 109 having opposing end portions protruding through apertures provided in walls 39 and 41, respectively. Similarly, the pin 104 protrudes through a slotted end portion of a yoke link arm 112. Arm 112 is integrally formed with one end of a yoke link crossbar 114 which has a central portion fixedly attached to entrance shutter element 44 of entrance shutter 42. The opposing end of crossbar 114 is integrally formed with a relatively short yoke link arm 116. The yoke crossbar 114 is rotatably supported on a rod 111 having oppos-ing end portions protruding through side walls 39 and 41, respectively.
Thus, as shown more particularly in Figures 4 and 5, the knobs 85 and 100 may be adjusted to rotate the respective pairs of exit shutter elements 51-52 and 53-54 to a substantially fully open position. Conse~uent-ly, the movable entrance shutter elements 43 and 44 ~Figure 5), respectively, 3~;
are adjusted in accordance with the adjustment of exit shutter elements 51-52 to permit a widely divergent X-ray beam *o enter the housing 36 and to res~rict the off focus X-radiation. Accordingly, the widely divergent beam is collimated within housing 36 by the aperture defining edge portion 65, 66, 67 and 68 of the exit shut-ter elements 51-54 respectively, as indicated by arrows 126-129.
Also, as shol~n in Figures 6 and 7, the knobs 85 and 100 may be adjusted to rotate the respective pairs of exit shutter elements 51-52 and 53-54 to a more nearly closed position. Note that as the exit shutter elements 51-52 are rotated in counterclockwise and clockwise directions, respectively, the arms 106 and 112 cause the pivotally mounted entrance shutter elements 43 and 44 to define a more closed entrance aperture, as shown in Figure 7. As a result the pair of movable entrance shutter elements 43 and 44 are adjusted corres-pondingly to permit passage of a less divergent X-ray beam indicated by arrows 126a - 129a, respectively, having outer dimensions defined by the exit shutter elements while maximi~ing restriction of off-focus X-radiation. Thus, the less divergent X-ray beam entering housing 36 is collimated by the aperture defining edge portions of exit shutter elements 51-54 being suitably positioned for providing the X-ray beam with the desired cross-sectional dimensions.
As shown in Figures 2 and 8, there may be mounted on front wall 37 a front control panel 120 through which the respective shafts 84 and 99 may extend for rotation by respective knobs 85 and 100 externally of the panel.
The control panel 120 also may be provided with respective indicators for signalling when the power is "on", when the X-ray generator 12 is on "hold", and when the respective pairs of exit shutter elements in exit shutter 50 are adjusted. The respective shafts 84 and 99 also may be coupled to respective motors and rotation sensors, such as potentiometers, for example, which are mounted between panel 120 and front wall 37 for automatic operation of the exit L5~
shutter 50.
From the foregoing, it will be apparent that all o~ the objec-tives of this invention have been achieved by the structures shown and described herein. It also will be apparent, however, that various changes may be made by those skilled in the art without departing from the spirit of the invention as expressed in the appended claims. It is to be understood, therefore, that all matter shown and described herein is to be interpreted as illustrative and not in a limiting sense.
Claims (8)
PROPERTY OR PRIVILEGE IS CLAIMED ARE DEFINED AS FOLLOWS:
1. A radiation collimator comprising:
(a) a housing;
(b) a pair of opposing shutter elements, each one thereof having a radiation absorbing surface and a gear disposed in station-ary relationship thereto, such gear having a surface disposed in a plane orthogonal to the radiation absorbing surface and having en-gageable teeth disposed along an edge of such gear orthogonal to the surface of the gear, such gear having a shaft normal to the surface of the gear and rotatably mounted to the housing, such pair of oppos-ing shutter elements being mounted within the housing with the teeth of one of the gears of one of the shutter elements engaged with the teeth of the gear of the other one of the shutter elements;
(c) a pair of entrance shutter elements pivotally mounted to the housing; and (d) a pair of linkage arms, such arms being connected to the pair of shutter elements at a first portion thereof and being connected to the surface of the gears at a second portion thereof and wherein such arms are pivotally connected to housing at a point between such first and second portions thereof.
(a) a housing;
(b) a pair of opposing shutter elements, each one thereof having a radiation absorbing surface and a gear disposed in station-ary relationship thereto, such gear having a surface disposed in a plane orthogonal to the radiation absorbing surface and having en-gageable teeth disposed along an edge of such gear orthogonal to the surface of the gear, such gear having a shaft normal to the surface of the gear and rotatably mounted to the housing, such pair of oppos-ing shutter elements being mounted within the housing with the teeth of one of the gears of one of the shutter elements engaged with the teeth of the gear of the other one of the shutter elements;
(c) a pair of entrance shutter elements pivotally mounted to the housing; and (d) a pair of linkage arms, such arms being connected to the pair of shutter elements at a first portion thereof and being connected to the surface of the gears at a second portion thereof and wherein such arms are pivotally connected to housing at a point between such first and second portions thereof.
2. A beam limiting device comprising:
two orthogonal pairs of opposing shutter elements disposed for defining a beam collimating aperture having an axial centerline, each of said elements having cylindrically curved wall portions dis-posed orthogonally to said axial centerline and longitudinal edge portions disposed for defining respective peripheral portions of said aperture; and means disposed adjacent at least one arcuate end of each of said cylindrically curved wall portions for rotating each of said shutter elements about its longitudinal axis and moving said longit-udinal edge portions relative to one another for adjusting the size of the aperture.
two orthogonal pairs of opposing shutter elements disposed for defining a beam collimating aperture having an axial centerline, each of said elements having cylindrically curved wall portions dis-posed orthogonally to said axial centerline and longitudinal edge portions disposed for defining respective peripheral portions of said aperture; and means disposed adjacent at least one arcuate end of each of said cylindrically curved wall portions for rotating each of said shutter elements about its longitudinal axis and moving said longit-udinal edge portions relative to one another for adjusting the size of the aperture.
3. A beam limiting device comprising:
two orthogonal pairs of opposing cylindrically curved shut-ter elements disposed for defining a rectangular aperture, the ele-ments of each of said pairs having respective longitudinal edge por-tions disposed in opposing relationship with one another between said cylindrically curved elements of the other pair and supported in spaced encircling relationship with respective arcuate ends thereof;
and means disposed adjacent at least one arcuate end of each of the elements of said pairs for rotating said each of the elements in respective opposing directions about its longitudinal centerline and adjusting the size of said aperture.
two orthogonal pairs of opposing cylindrically curved shut-ter elements disposed for defining a rectangular aperture, the ele-ments of each of said pairs having respective longitudinal edge por-tions disposed in opposing relationship with one another between said cylindrically curved elements of the other pair and supported in spaced encircling relationship with respective arcuate ends thereof;
and means disposed adjacent at least one arcuate end of each of the elements of said pairs for rotating said each of the elements in respective opposing directions about its longitudinal centerline and adjusting the size of said aperture.
4. A beam limiting device as set forth in claim 3 wherein said means includes a respective gear disposed adjacent said arcuate ends of each of the elements and having axes of rotation substantial-ly aligned with said longitudinal axes of the elements.
5. A beam limiting device as set forth in claim 4 wherein said gears are fixedly attached to said cylindrically curved elements for rotation as respective unitary structures.
6. A beam limiting device comprising:
a radiation shielded housing including an entrance wall having disposed therein entrance aperture means for permitting pas-sage of a radiation beam into the housing;
exit shutter means disposed in the housing for providing collimation of said beam and including two orthogonal pairs of op-posing cylindrically curved shutter elements, the elements of each pair having respective longitudinal edge portions disposed in oppos-ing relationship between the cylindrically curved elements of the other pair and supported in spaced enveloping relationship with respective arcuate ends thereof; and means disposed adjacent at least one arcuate end of each of the shutter elements of said respective pairs for rotating said each of the elements in respective opposing directions and adjusting the size of said aperture.
a radiation shielded housing including an entrance wall having disposed therein entrance aperture means for permitting pas-sage of a radiation beam into the housing;
exit shutter means disposed in the housing for providing collimation of said beam and including two orthogonal pairs of op-posing cylindrically curved shutter elements, the elements of each pair having respective longitudinal edge portions disposed in oppos-ing relationship between the cylindrically curved elements of the other pair and supported in spaced enveloping relationship with respective arcuate ends thereof; and means disposed adjacent at least one arcuate end of each of the shutter elements of said respective pairs for rotating said each of the elements in respective opposing directions and adjusting the size of said aperture.
7. A beam limiting device as set forth in claim 6 wherein said entrance aperture means comprises an entrance shutter having two orthogonal pairs of opposing entrance shutter elements disposed for defining a rectangular entrance aperture, the respective entrance shutter elements of one of said pairs being supported for movement relative to one another and directly connected to corresponding shut-ter elements of the exit shutter means for corresponding adjustment therewith.
8. A radiation collimator comprising:
(a) a housing;
(b) a first and a second pair of shutter elements disposed within the housing, the first pair of shutter elements being rotat-ably mounted with respect to the housing about a first pair of paral-lel axes and the second pair of shutter elements being rotatably mounted with respect to the housing about a second pair of parallel axes, the first pair of parallel axes being perpendicular to the second pair of parallel axes, each one of such shutter elements hav-ing a concave surface with a pair of edge portions thereof parallel to the axis of rotation of such shutter element, one of such edge portions thereof defining a different peripheral portion of an aper-ture, one of the pair of edge portions of the surfaces of the first pair of shutter elements being adapted to rotate within a space dis-posed between the surfaces of the second pair of shutter elements and one of the pair of edge portions of the surfaces of the second pair of shutter elements being adapted to rotate within a space dis-posed between the surfaces of the first pair of shutter elements.
(a) a housing;
(b) a first and a second pair of shutter elements disposed within the housing, the first pair of shutter elements being rotat-ably mounted with respect to the housing about a first pair of paral-lel axes and the second pair of shutter elements being rotatably mounted with respect to the housing about a second pair of parallel axes, the first pair of parallel axes being perpendicular to the second pair of parallel axes, each one of such shutter elements hav-ing a concave surface with a pair of edge portions thereof parallel to the axis of rotation of such shutter element, one of such edge portions thereof defining a different peripheral portion of an aper-ture, one of the pair of edge portions of the surfaces of the first pair of shutter elements being adapted to rotate within a space dis-posed between the surfaces of the second pair of shutter elements and one of the pair of edge portions of the surfaces of the second pair of shutter elements being adapted to rotate within a space dis-posed between the surfaces of the first pair of shutter elements.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CA000446290A CA1181536A (en) | 1980-06-19 | 1984-01-27 | Compact x-ray collimator |
Applications Claiming Priority (4)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| US06/161,108 US4380820A (en) | 1980-06-19 | 1980-06-19 | Compact X-ray collimator |
| CA000375662A CA1170789A (en) | 1980-06-19 | 1981-04-16 | Compact x-ray collimator |
| CA000446290A CA1181536A (en) | 1980-06-19 | 1984-01-27 | Compact x-ray collimator |
| US161,108 | 1993-12-02 |
Related Parent Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CA000375662A Division CA1170789A (en) | 1980-06-19 | 1981-04-16 | Compact x-ray collimator |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CA1181536A true CA1181536A (en) | 1985-01-22 |
Family
ID=27167030
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CA000446290A Expired CA1181536A (en) | 1980-06-19 | 1984-01-27 | Compact x-ray collimator |
Country Status (1)
| Country | Link |
|---|---|
| CA (1) | CA1181536A (en) |
-
1984
- 1984-01-27 CA CA000446290A patent/CA1181536A/en not_active Expired
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