The present invention relates to a photomultiplier tube for detecting weak light incident on a faceplate by multiplying electrons emitted from the faceplate, a photomultiplier tube unit having photomultiplier tubes arranged, and a radiation detector employing a lot of arranged photomultiplier tubes and/or photomultiplier tube units.
Japanese patent Kokai publication No. Hei 5-290793 discloses a photomultiplier tube in which an electron multiplier is accommodated in a hermetically sealed vessel. The vessel has a metal side tube having a flange at an upper end. The flange is welded and fixed to an upper surface of a faceplate, thereby ensuring airtightness of the vessel. The flange of the side tube is welded to the faceplate, while the side tube is heated.
However, the following problem arises as to a conventional photomultiplier tube. Referring to
In view of the foregoing, it is an object of the present invention to provide a photomultiplier tube having an increased effective sensitive area of the faceplate and an increased fix area of the side tube to the faceplate.
It is another object of the present invention to provide a photomultiplier tube unit having an increased effective sensitive area of the faceplate.
It is further object of the present invention to provide a photomultiplier tube unit facilitating a gain control (current gain) of each electron multiplier in the side tube.
It is still further object to provide a radiation detector having improved performances over the entire detector based on the enlarged effective sensitive area of the faceplate.
The present invention features a photomultiplier tube having: a photocathode for emitting electrons in response to light incident on a faceplate; an electron multiplier provided in an hermetically sealed vessel for multiplying electrons emitted from the photocathode; and an anode for generating an output signal based on electrons multiplied by the electron multiplier. The hermetically sealed vessel includes: a stem plate having stem pins for fixing the electron multiplier and the anode thereon; a metal side tube enclosing the electron multiplier and the anode, the metal side tube having an open end to which the stem plate is fixed; and the faceplate fixed to another open end of the side tube, the faceplate being made from glass. A side face of the faceplate protrudes out of an outer side wall of the side tube.
In the above photomultiplier tube, a side surface of the glass faceplate protrudes out of the outer side wall of the metal side tube by a predetermined length. Accordingly, the area for receiving light passing through a photocathode 3a on the glass faceplate 3 is increased. The above overhang structure of the faceplate 3 is provided on the basis of refractive index of glass. The above structure is directed to receive light which a conventional photomultiplier tube is not capable of receiving. When the metal side tube is fused to the glass faceplate, the fusing method described above is adopted due to joint between glass and metal. The overhanging part of the faceplate is effective at ensuring a reliable operation to fuse the faceplate and the overhanging part. As described above, when the metal side tube is used, the overhanging structure of the faceplate is effective means for increasing a fused area and ensure enlarged light receiving area. The thicker the faceplate is, the more effectively the overhanging structure of the faceplate functions during light reception.
The side tube of the photomultiplier tube according to the present invention has an edge portion on an upper end thereof, the edge portion is to be embedded in a photocathode side of the faceplate. In this case, the edge portion of the side tube is embedded in the glass faceplate so as to strike thereon. Therefore, the side tube conforms to the faceplate well, and hermetic seal between the side tube and the faceplate is enhanced. The edge portion provided in the side tube extends upwardly from the side tube rather than extends laterally from the side tube like a flange. When embedding the edge portion into the glass faceplate as close as possible to a side surface of the faceplate, it is possible to increase the effective sensitive surface area of the glass faceplate as much as possible.
The tip end of the edge portion of the photomultiplier tube may curve toward one of an interior and an exterior of the side tube. The above structure increases a surface are of the edge portion embedded in the faceplate, and improves and enhances the hermetic seal at a joint between the side tube and the faceplate.
In the photomultiplier tube according to the present invention, the edge portion preferably has a knife-edged tip end. This structure enables an end of the side tube to penetrate the faceplate easily. When the glass faceplate is fused to the side tube, an assembly operation and reliability is improved.
When an end of the side tube is fused to the faceplate, the edge portion is heated while being contact with a photocathode side of the faceplate, the contact part of the faceplate is melted due to heat conducted from the edge portion, a pressing force is applied across the edge portion and the faceplate to embed the edge portion into the photocathode side of the faceplate.
In the photomultiplier tube according to present invention, the faceplate has a reflecting member on a side face of the faceplate. In a conventional photomultiplier tube, some of light incident on the faceplate leaks out of a side face of the side tube. Because such light is reflected by the reflecting member provided on the side face, the amount of light incident on the photocathode is increased. The light receiving efficiency at the faceplate is improved.
In order to obtain the above advantages, the faceplate of the photomultiplier tube according to the present has at least a part of a face extending parallel to an axial direction of the side tube. Alternatively, the faceplate has a convex face on at least one part of the side face. The side face is inclined a predetermined angle with respect to an axial direction of the side tube so that an area of a light receiving side of the faceplate is wider than an area of a side of the faceplate facing the photocathode.
A photomultiplier tube unit according to the present invention has a plurality of photomultiplier tubes that are juxtaposed, each of the plurality of the photomultiplier tubes having a photocathode for emitting electrons in response to light incident on a faceplate; an electron multiplier provided in an hermetically sealed vessel for multiplying electrons emitted from the photocathode; and an anode for generating an output signal based on electrons multiplied by the electron multiplier. The hermetically sealed vessel includes: a stem plate having stem pins for fixing the electron multiplier and the anode thereon; a metal side tube enclosing the electron multiplier and the anode, the side tube having one open end to which the stem plate is fixed; and the faceplate fixed to another open end of the side tube, the faceplate being made from glass. The plurality of photomultiplier tube are juxtaposed to integrate the faceplates together and space the side tube away from the other.
In the unit, when the side tubes are arranged, the neighboring side tubes are spaced away from each other while the faceplates are integral with each other. As a result, the faceplates extend over a gap between the neighboring side tubes. Therefore, an effective sensitive area of the faceplate is increased. The faceplates are maintained at the same potential due to the integrated structure of the faceplates. And, the neighboring faceplates are spaced away from each other, which facilitates gain control (current gain) at each electron multiplier section. For example, when a negative high voltage is applied to the photocathode, fine gain adjustment is necessary for each electron multiplier section in order to maintain a constant gain for four intervals between the electron multiplier sections. The unit described above enables this gain control.
In the photomultiplier tube unit according to present invention, the plurality of side tubes are secured to a faceplate while each of the plurality of side tubes is spaced away from each other. When this structure is adopted, integration of the faceplate is performed by a single faceplate. The faceplate obtains uniform quality, which contributes to improved reliability of the unit.
The neighboring side faces of the faceplates are secured together, contacting each other. When the above structure is adopted, a lot of different combinations of a single photomultiplier tube are available by joining the neighboring faceplates together on a single photomultiplier tube. As a result, the photomultiplier tube according to the present invention can be used for any size of a unit.
The neighboring side face of the faceplates are secured through an electrically conductive reflecting member. When the above structure is adopted, electrical conductivity between the neighboring faceplates is ensured. The amount of light incident on the photocathode is increased due to light reflected by the reflecting member. Therefore, light receiving efficiency on the faceplate is improved.
A radiation detector according to the present invention has a scintillator for emitting fluorescent light in response to radiation generated from an object; a plurality of photomultiplier tubes arranged in a manner that faceplates of the photomultiplier tubes face the scintillator, each of the photomultiplier tubes generating an electrical charge based on the fluorescent light emitted from the scintillator; and a position calculating processor for processing an output from the photomultiplier tube and generating a signal for indicating a position of radiation generated in the object. Each of the plurality of photomultiplier tubes has a photocathode for emitting electrons in response to light incident on a faceplate; an electron multiplier provided in an hermetically sealed vessel for multiplying electrons emitted from the photocathode; and an anode for producing an output signal based on electrons multiplied by the electron multiplier. The hermetically sealed vessel includes: a stem plate having stem pins for securing the electron multiplier and the anode thereon; a metal side tube enclosing the electron multiplier and the anode, the side tube having one open end to which the stem plate is fixed; and the faceplate fixed to another open end of the side tube, the faceplate being made from glass. The plurality of side tubes is juxtaposed. The faceplates are integrated with each other. One of the side tubes is spaced away from another of the side tubes.
In the radiation detector, when the side tubes are arranged, the neighboring side tubes are spaced away from each other while the faceplates are integral with each other. As a result, the faceplates extend over a gap between the neighboring side tubes. Therefore, an effective sensitive area of the faceplate is increased. The faceplates are maintained at the same potential due to the integrated structure of the faceplates. And, the neighboring faceplates are spaced away from each other, which facilitates gain control (current gain) at each electron multiplier section. For example, when a negative high voltage is applied to the photocathode, fine gain adjustment is necessary for each electron multiplier section in order to maintain a constant gain for four intervals between the electron multiplier sections. The radiation detector described above enables this gain control, thereby improving the performance over the radiation detector.
In the drawings:
The following description will be made for explaining preferred embodiments of a photomultiplier tube, a photomultiplier tube unit, and a radiation detector according to the present invention in details, referring to the accompanying drawings.
A metal evacuating tube 6 is provided in the center of the stem plate 4. The evacuating tube 6 is used to evacuate the vessel 5 by a vacuum pump (not shown) after the assembly of the photomultiplier tube 1 is over. The evacuating tube 6 is also used for introducing alkali metal vapor into the vessel 5 during the production of the photocathode 3a.
A stacked electron multiplier 7 in a block shape is disposed inside the vessel 5. The electron multiplier 7 has an electron multiplying section 9 in which ten stages of flat dynodes 8 are stacked. Stem pins 10 formed from Kovar metal penetrate the stem plate 4 and support the electron multiplier 7 in the vessel 5. The tip of each stem pin 10 is electrically connected to each dynode 8. Pinholes 4a are formed in the stem plate 4, enabling the stem pins 10 to penetrate the stem plate 4. Each of the pinholes 4a is filled with a tablet 11 formed from Kovar glass, which forms a hermetic seal between the stem pins 10 and the stem plate 4. Each stem pin 10 is fixed to the stem plate 4 by the tablet 11. The stem pins 10 are classified into two groups: one group for the dynodes, and the other group for an anode.
The anodes 12 are positioned below the electron multiplying section 9 in the electron multiplier 7. The anodes 12 are fixed to the top ends of the anode pins 10. A flat focusing electrode 13 is disposed between the photocathode 3a and the electron multiplying section 9 above the top stage of the electron multiplier 7. A plurality of slit-shaped openings 13a is formed in the focusing electrode plate 13. The openings 13a extend in one direction. Slit-shaped electron multiplying holes 8a are formed in the dynode 8. The number of electron multiplying holes 8a is the same as that of the openings 13a. The electron multiplying holes 8a are arranged parallel to each other in one direction. The electron multiplying holes 8a extend in a direction substantially orthogonal to the surface of the dynodes 8.
Electron multiplying paths L are formed by arranging the electron multiplying holes 8a in each dynode 8 along the direction of the stack. A plurality of channels is formed in the electron multiplier 7 by associating the path L with the corresponding opening 13a in the focusing electrode plate 13. The anodes 12 are configured in an 8×8 arrangement, so that each anode 12 corresponds to a predetermined number of channels. Since the anode 12 is connected to the corresponding anode pin 10, output signals can be extracted through each anode pin 10.
Hence, the electron multiplier 7 has a plurality of linear channels. A predetermined voltage is applied across the electron multiplying section 9 and anodes 12 by the stem pin 10 connected to a bleeder circuit (not shown). The photocathode 3a and the focusing electrode plate 13 are maintained at the same potential. The potential of each dynode 8 is decreasing from the top of the dynode toward the anodes 12. Accordingly, incident light on the faceplate 3 is converted to electrons at the photocathode 3a. The electrons are guided into a certain channel by the electron lens effect generated by the focusing electrode plate 13 and the first stage of the dynode 8 on the top of the electron multiplier 7. The electrons guided into the channel are multiplied through each stage of the dynodes 8 while passing through the electron multiplying paths L. The electrons are collected by the anodes 12 to be outputted as an output signal.
Referring to
By eliminating an overhang such as a flange at the lower end of the photomultiplier tube 1, it is possible to reduce the external dimensions of the photomultiplier tube 1, though the above structure of the photomultiplier tube 1 and the side tube 2 may be improper for resistance-welding. Further, when several photomultiplier tubes 1 are arranged in a unit for a given application, it is possible to minimize dead space between the neighboring photomultiplier tubes 1 as much as possible by placing the neighboring side tubes 2 of the photomultiplier tubes 1 close together. Laser welding is employed to bond the stem plate 4 and side tube 2 together in order to achieve a low height structure of the photomultiplier tube 1 and to enable high-density arrangements of the photomultiplier tube 1 in a unit.
The above laser welding is one example for fusing the stem plate 4 and side tube 2. When the side tube 2 and the stem plate 4 are welded together using the laser welding, it is unnecessary to apply pressure across the junction F between the side tube 2 and stem plate 4 in contrast to resistance welding. Hence, no residual stress is induced at the junction F, avoiding cracks from occurring at this junction during the usage. The usage of the laser welding greatly improves the durability and hermetic seal of the photomultiplier tube 1. Laser welding and electron beam welding prevent generation of heat at the junction F, compared to the resistance welding. Hence, when the photomultiplier tube 1 is assembled, there is very little effect of heat on the components in the vessel 5.
The side tube 2 is formed by pressing a flat plate made from metal such as Kovar and stainless steel into an approximately rectangular cylindrical shape having a thickness of approximately 0.25 mm and a height of approximately 7 mm. The glass faceplate 3 is fixed to the open end A of the side tube 2 by fusion. As shown in
When fixing the side tube 2 with an edge portion 20 having the above shape to the glass faceplate 3, the metal side tube 2 is placed on a rotating platform (not shown) with a bottom surface of the glass faceplate 3 being in contact the tip 20b of the edge portion 20. Next, the metal side tube 2 is heated by a high-frequency heating device while the glass faceplate 3 is pressed downwardly to the side tube 2 by a pressure jig. At this time, the heated edge portion 20 of the side tube 2 gradually melts and penetrates the glass faceplate 3. As a result, the edge portion 20 is embedded into the glass faceplate 3, ensuring a hermetic seal at the juncture between the glass faceplate 3 and side tube 2.
The edge portion 20 extends upwardly from the side tube 2 rather than extends laterally from the side tube 2 like a flange. When embedding the edge portion 20 into the glass faceplate 3 as close as possible to a side surface 3c, it is possible to increase the effective sensitive surface area of the glass faceplate 3 to nearly 100% and to minimize the dead area of the glass faceplate 3 to nearly 0%.
Referring to
When the metal side tube 2 is fused to the glass faceplate 3, the fusing method described above is adopted due to joint between glass and metal. The overhanging part 3A of the faceplate 3 is effective at ensuring an area required to fuse the faceplate 3 and the overhanging part 3A. A longer length L of the protrusion 3A avoids deformation of the side face 3c of the faceplate 3 during the fusion to the side tube 2, thereby ensuring the shape of the side face 3c without deformation.
Referring to
As described above, any one of the side faces 3e-3g is suitable for improving the light receiving efficiency. In particular, the side faces 3c, and 3e are appropriate for the faceplates 3 to arrange closely to each other.
Next, a preferred embodiment of a photomultiplier tube unit and a radiation detector according to the present invention will be described.
As shown in
As shown in
A position calculating processor 49 is provided in the casing 44 for performing calculations based on electrical charges from each photomultiplier tube 1. The position calculating processor 49 generates an X signal, a Y signal, and a Z signal to form a three-dimensional image on a display (not shown). Gamma rays emitted from the affected part of the patient P are converted to predetermined fluorescent light by the scintillator 46. Each of the photomultiplier tubes 1 converts the energy of this fluorescent light into electrical charges. The position calculating processor 49 generates positions signals based on the electrical charges. In this way, it is possible to monitor the distribution of radiation energy from the object on the display for use in diagnoses.
While the above description has been given for the gamma camera 40 as one example of a radiation detector, another radiation detector used in nuclear medicine diagnoses is a Positron CT (commonly designated as PET). This apparatus also includes many the photomultiplier tubes 1.
Further, the group of photomultiplier tubes G has the photomultiplier tubes 1 arranged in a matrix. As shown in
Next, the matrix-shaped photomultiplier tube unit S will be described in detail.
As shown in
Referring to
In order to assemble the unit S, the neighboring side faces 3c of the faceplates 3 may be fixed to each other through a reflecting member 21 such as aluminum, MgO, and teflon tape. This structure increases the amount of light which is reflected by the reflecting member 21 and strikes on the photocathode 3a, thereby improving the light receiving efficiency on the faceplate.
As another embodiment of a unit S1 in which many photomultiplier tubes 1 are arranged,
The present invention is not limited to the embodiments described above. For example,
A photomultiplier tube, a photomultiplier tube unit, and a radiation detector according to the present invention have a lot of different applications in imaging devices for a low luminescent object, such as gamma cameras.
This is a Continuation of application Ser. No. 10/275,654 which is a National Phase of Application No. PCT/JP 00/02927 filed May 8, 2000. The disclosure of the prior application is hereby incorporated by reference herein in its entirety.
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Number | Date | Country | |
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20080001541 A1 | Jan 2008 | US |
Number | Date | Country | |
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Parent | 10275654 | US | |
Child | 11898028 | US |