The field of the application relates to accelerator systems, such as those used in medical systems, and more particularly, to systems and methods for electromagnetic interference containment for accelerator systems.
Radiation therapy involves medical procedures that selectively deliver high doses of radiation to certain areas inside a human body. A radiation machine for providing radiation therapy includes an electron source that provides electrons, and an accelerator that accelerates the electrons to form an electron beam. The electron beam is delivered downstream where it strikes a target to generate radiation. The radiation is then collimated to provide a radiation beam having a certain desired characteristic for treatment purpose.
Radiation may also be used to provide imaging of a patient so that internal tissue may be visualized.
Medical systems that provide radiation, either for treatment or for diagnostic imaging, have a radiation system configured to provide and accelerate electrons for generating radiation. The radiation system may have an electron gun that generates the electrons, an accelerator that accelerates the electrons, and a microwave device (e.g., a Magnetron) configured to provide microwave power for the accelerator. In some cases, the radiation system may also include a modulator for providing input for the magnetron and the electron gun. Use of the radiation system may result in radiated electromagnetic radiation due to high voltage pulses resulted from the operation of the modulator with the magnetron and the electron gun.
An apparatus for attachment to a component of a microwave device, includes: a cage; a shield within the cage, wherein the shield is in a form of a container, and at least a majority of the shield is spaced away from an interior wall of the cage; and a connector at the cage, wherein the connector is configured to connect to a cable connection, and wherein the connector is electrically connected to two terminals within the shield.
Optionally, the shield comprises a first opening for receiving wires from the connector.
Optionally, the shield further comprises a second opening and a third opening for receiving the two terminals respectively.
Optionally, one of the two terminals comprises a cathode terminal.
Optionally, another one of the two terminals comprises a heater terminal.
Optionally, the heater terminal is electrically isolated from the shield.
Optionally, the cathode terminal is electrically connected to the shield.
Optionally, the connector comprises a ground connection to the cage.
Optionally, a voltage between the two terminals has a first voltage value, and a voltage between the shield and the cage has a second voltage value that is higher than the first voltage.
Optionally, the second voltage (e.g., an absolute value of the second voltage) is at least 1000 times larger than the first voltage (e.g, an absolute value of the first voltage).
Optionally, the apparatus further includes a RF absorber contained inside the cage.
Optionally, the shield is coupled to the RF absorber. For example, the shield may be mechanically coupled to the RF absorber.
Optionally, the apparatus further includes a protection circuit contained inside the shield.
Optionally, the protection circuit comprises a capacitor and a voltage limiting device, the capacitor having a first lead and a second lead, the voltage limiting device having a third lead and a fourth lead, wherein the first lead of the capacitor and the third lead of the voltage limiting device are connected to one of the two terminals in the shield (e.g., surrounded by the shield), and wherein the second lead of the capacitor and the fourth lead of the voltage limiting device are connected to another one of the two terminals in the shield.
Optionally, the protection circuit is configured to prevent current from flowing through the protection circuit until a pre-determined voltage is reached.
Optionally, the protection circuit comprises a bipolar or unipolar transient-voltage suppression (TSV) diode.
Optionally, a portion of the shield comprises a dome shape.
Optionally, the microwave device comprises a Magnetron, and wherein the cage is configured to attach to the component of the Magnetron.
An apparatus for coupling to an input connection of an electron gun, the input connection having a heater terminal and a cathode terminal, the apparatus comprising: a connector having a first end and a second end; wherein the first end of the connector is configured to attach to a cable; wherein the second end of the connector is configured to connect to the input connection of the electron gun; and wherein the connector comprises an opening configured to receive the heater terminal of the input connection of the electron gun.
Optionally, the connector has a bullet shape. The connector may have other shapes in other embodiments, which minimizes or at least reduces electric field inside a high voltage insulation.
Optionally, the first end of the connector has a cross sectional dimension that varies non-linearly.
Optionally, the heater terminal comprises a pin.
Optionally, the cathode terminal of the electron gun comprises a cylindrical connector, and wherein the second end of the connector has an outer cross sectional dimension sized to fit within the cylindrical connector of the electron gun.
Optionally, the second end of the connector comprises a coil (e.g., a canted coil), and wherein the coil is configured to circumferentially engage the cylindrical connector of the electron gun.
Optionally, the connector comprises a first section with the opening, wherein the first section is configured for connection with a first wire from the cable.
Optionally, the connector comprises a second section configured for connection with a second wire from the cable, wherein the second section is electrically coupled to a circular structure circumferentially disposed around the first section.
Optionally, the connector comprises a first section with first plurality of connection terminals for connection with respective cathode wires from the cable.
Optionally, the connector comprises a second section with a second plurality of connection terminals for connection with respective heater wires from the cable.
Optionally, the first section comprises the opening.
Optionally, the second section is electrically coupled to a circular structure circumferentially disposed around the first section.
Optionally, the apparatus further includes a tube disposed around the component of the electron gun.
Optionally, the tube may slide (i.e., is slidable) relative to the component of the electron gun.
Optionally, the tube has a wall with a first opening and a second opening.
Optionally, the first opening and the second opening are at respective opposite sides of the tube.
Optionally, the tube is configured to contain potting material.
Optionally, the apparatus further includes a seal structure disposed at one end of the tube, the seal structure having an opening for receiving the cable, wherein the seal structure has a curvilinear inner surface, and wherein a distance between the curvilinear inner surface and the cable varies non-linearly as a function of a position along a longitudinal axis of the cable.
An apparatus for attachment to a component of a microwave device includes: a cage configured to provide EMI shielding; and a shield within the cage, wherein the shield is configured to provide corona shielding; wherein the shield comprises a cavity for accommodating two terminals.
Other and further aspects and features will be evident from reading the following detailed description.
The drawings illustrate the design and utility of embodiments, in which similar elements are referred to by common reference numerals. These drawings are not necessarily drawn to scale. In order to better appreciate how the above-recited and other advantages and objects are obtained, a more particular description of the embodiments will be rendered, which are illustrated in the accompanying drawings. These drawings depict only exemplary embodiments and are not therefore to be considered limiting in the scope of the claims.
Various embodiments are described hereinafter with reference to the figures. It should be noted that the figures are not drawn to scale and that elements of similar structures or functions are represented by like reference numerals throughout the figures. It should also be noted that the figures are only intended to facilitate the description of the embodiments. They are not intended as an exhaustive description of the invention or as a limitation on the scope of the invention. In addition, an illustrated embodiment needs not have all the aspects or advantages shown. An aspect or an advantage described in conjunction with a particular embodiment is not necessarily limited to that embodiment and can be practiced in any other embodiments even if not so illustrated, or if not so explicitly described.
In the illustrated embodiments, the radiation source 22 is a treatment radiation source for providing treatment energy. In other embodiments, in addition to being a treatment radiation source, the radiation source 22 can also be a diagnostic radiation source for providing diagnostic energy for imaging purpose. In such cases, the system 10 will include an imager, such as the imager 80, located at an operative position relative to the source 22 (e.g., under the support 14). In further embodiments, the radiation source 22 may be a treatment radiation source for providing treatment energy, wherein the treatment energy may be used to obtain images. In such cases, in order to obtain imaging using treatment energies, the imager 80 is configured to generate images in response to radiation having treatment energies (e.g., MV imager). In some embodiments, the treatment energy is generally those energies of 160 kilo-electron-volts (keV) or greater, and more typically 1 mega-electron-volts (MeV) or greater, and diagnostic energy is generally those energies below the high energy range, and more typically below 160 keV. In other embodiments, the treatment energy and the diagnostic energy can have other energy levels, and refer to energies that are used for treatment and diagnostic purposes, respectively. In some embodiments, the radiation source 22 is able to generate X-ray radiation at a plurality of photon energy levels within a range anywhere between approximately 10 keV and approximately 20 MeV. In further embodiments, the radiation source 22 can be a diagnostic radiation source. In such cases, the system 10 may be a diagnostic system with one or more moving parts. In the illustrated embodiments, the radiation source 22 is carried by the arm gantry 12. Alternatively, the radiation source 22 may be located within a bore (e.g., coupled to a ring gantry).
In the illustrated embodiments, the control system 18 includes a processing unit 54, such as a processor, coupled to a control 40. The control system 18 may also include a monitor 56 for displaying data and an input device 58, such as a keyboard or a mouse, for inputting data. The operation of the radiation source 22 and the gantry 12 are controlled by the control 40, which provides power and timing signals to the radiation source 22, and controls a rotational speed and position of the gantry 12, based on signals received from the processing unit 54. Although the control 40 is shown as a separate component from the gantry 12 and the processing unit 54, in alternative embodiments, the control 40 can be a part of the gantry 12 or the processing unit 54.
In some embodiments, the system 10 may be a treatment system configured to deliver treatment radiation beam towards the patient 20 at different gantry angles. During a treatment procedure, the source 22 rotates around the patient 20 and delivers treatment radiation beam from different gantry angles towards the patient 20. While the source 22 is at different gantry angles, the collimator 24 is operated to change the shape of the beam to correspond with a shape of the target tissue structure. For example, the collimator 24 may be operated so that the shape of the beam is similar to a cross sectional shape of the target tissue structure. In another example, the collimator 24 may be operated so that different portions of the target tissue structure receive different amount of radiation (as in an IMRT procedure).
During use, the first cable 270 is configured to receive a high voltage from the modulator 218, and transmit the high voltage to the Magnetron 216. Similarly, the second cable 280 is configured to receive a high voltage from the modulator 218, and transmit the high voltage to the electron gun 220. To contain electromagnetic interference from the transmission of the high voltage by the first cable 270, the first apparatus 250 is provided at the interface between the first cable 270 and the Magnetron 216. Similarly, to contain electromagnetic interference from the transmission of the high voltage by the second cable 280, the second apparatus 260 for containing electromagnetic interference is provided at the interface between the second cable 280 and the electron gun 220.
In some embodiments, the first apparatus 250 includes a cage for EMI containment, and the second apparatus 260 includes an electron gun shield also for EMI containment. The first apparatus 250 will be described with reference to
As shown in the figure, the modulator 218 is connected to the first apparatus 250 via the first cable 270 having a first connector 272 and a second connector 274. The first connector 272 of the first cable 270 is configured to couple to a corresponding connector at the modulator 218. The second connector 274 of the first cable 270 is configured to connect to the first apparatus 250. In the illustrated embodiments, the first connector 272 of the first cable 270 is detachably coupled to the connector at the modulator 218, and the second connector 274 of the first cable 270 is detachably coupled to the first apparatus 250. In other embodiments, the first connector 272 may be fixedly or permanently coupled to the connector at the modulator 218, and/or the second connector 274 may be fixedly or permanently coupled to the first apparatus 250.
The modulator 218 is also connected to the second apparatus 260 via the second cable 280 having a first connector 282 and a second connector 284. The connector 282 of the second cable 280 is configured to couple to a corresponding connector at the modulator 218. The second connector 284 of the second cable 280 is configured to connect to the second apparatus 260.
The cables 270, 280 are flexible. Each of the cables 270, 280 is configured to hold off 75 kV (or other values) DC, and are shielded by an external braided shield. The braided shield is circumferentially (360°) coupled to the ground of the modulator 218 via the connector, thereby containing any radiated emissions. The chassis of the modulator 218, the cage of the first apparatus 250, and the electron gun shield at the second apparatus 260 are grounded, sharing a common ground.
As shown in
The connector 420 (e.g., receptacle) is configured to detachably connect to the cable connector 274 (e.g., plug) at an end of the first cable 270. The connector 420 is attached to the cage 400, and provides a connection point for the cable connector 274 so that a 360° ground is provided when the connector 274 of the first cable 270 is plugged to the connector 420.
In some embodiments, the cage 400 may be perforated to allow air flow to achieve convection cooling, and to allow for ozone generated by the high voltage to dissipate. Perforations diameter may be less than 1/100 wavelength of the highest desired attenuation frequency in order to minimize or at least reduce RF leakage. In other embodiments, the perforations diameter may have other values, and may be more than 1/100 wavelength of the highest desired attenuation frequency.
As shown in the figure, the shield 410 is in a form of a container, and at least a majority of the shield 410 is spaced away from an interior wall of the cage 400. As shown in the figure, a portion (e.g., the top portion) of the shield 410 has a dome shape. In other embodiments, the shield 410 may have other shapes. Also, in some embodiments, the shield 410 is sized and shaped to prevent arching condition from developing during use of the apparatus 250. In addition, in some embodiments, the shield 410 may have a first shield portion and a second shield portion that is detachably coupled to the first shield portion. The second shield portion may be opened to allow inspection and/or servicing of the components inside the shield 410. In some cases, the second shield portion may be the top portion (lid) of the shield 410.
As shown in
As shown in
The apparatus 250 also includes a protection circuit 450 inside the shield 410. The protection circuit 450 is configured to protect the Magnetron terminals (e.g., filaments) from excessive voltage during normal pulsing and during arc conditions. In particular, the protection circuit 450 is configured to prevent current from flowing through the protection circuit 450 until a pre-determined voltage is reached. In one implementation, the protection circuit 450 includes a voltage limiting device (such as a transient-voltage-suppression diode, spark gap, Zener diode, varistor, etc.), and a capacitor both connected in parallel to the Magnetron's terminals. Also, in other embodiments, the protection circuit 450 may include a bipolar or unipolar transient-voltage suppression (TSV) diode. In some embodiments, the protection circuit 450 is provided a threshold voltage, wherein when the voltage at the protection circuit 450 reaches such threshold voltage, the protection circuit 450 will start conducting. The threshold voltage may be selected to be at a level that is above the heater voltage, but below a level that may result in damage to the system, particularly the damage threshold voltage of the capacitor. In some cases, the threshold voltage of the TVS diode may be selected to be as close to the damage threshold of the system as tolerances will allow, in order to prevent the TVS diode from conducting too often on small amplitude voltage transients and being damaged form heating. The capacitance of the capacitor may be selected to be as high as practical to maximize reduction of voltage transients. The voltage rating of the capacitor may be selected to be sufficiently high that a TVS diode will not conduct on small spikes (which would not damage other parts of the system). The type of capacitor may be chosen to provide low inductance and high energy density. In one implementation the heater voltage is 6.7 volts and the damage threshold voltage of the capacitor is above 100 volts. Also, the capacitor may be made from a ceramic dielectric and has a capacitance of 100 microfarads.
As shown in the figure, the connector 420 at the first apparatus 250 has four wires 504a-504d that go through a channel 460 (extending between the wall of the cage 400 and the shield 410), and enter into a cavity of the shield 410 through the first opening 412 at the side of the shield 410. The wires 504a-504d may be extensions of the wires 510a-510d from the cable 270, or they may be separate wires that are connected to the wires 510a-510d from the cable 270. Two (i.e., 504a, 504b) of the four wires connect to the cathode terminal 500 of the Magnetron 216, and another two (i.e., 504c, 504d) of the four wires connect to the heater terminal 502 of the Magnetron 216. Also, in some embodiments, the terminals 500, 502 of the Magnetron 216 may be rods (e.g., threaded rods). These rods may protrude up into the cavity of the shield 410 through the openings 414a, 414b at the bottom of the shield 410. The rods of the Magnetron 216 may be mechanically connected to the shield 410 to support the shield 410, but only the cathode terminal 500 is connected electrically to the shield 410. The rod that is the heater terminal 502 may be electrically isolated form the shield 410 by an insulator bushing or other type of insulator. In the implementation shown, the wires 504a-504d from the connector 420 have respective ring terminals 520 on their respective ends, and these ring terminals 520 are attached to the threaded rod (terminals 500, 502 of the Magnetron 216) by nuts 522a, 522b.
In other embodiments, the openings 414a, 414b may be at other locations of the shield 410. Also, in other embodiments, the number of openings 414 may be different from two. For example, there may be only one opening for allowing both terminals 500, 502 to extend therethrough into the cavity of the shield 410. In addition, in other embodiments, the number of openings at the shield 410 for receiving the wires 504 from the connector 420 and for receiving the terminals 500, 502 of the Magnetron 216 may be different from the examples described. For example, in other embodiments, the shield 410 may have only a single opening for receiving the wires 504 from the connector 420, as well as the terminals 500, 502 of the Magnetron 216.
As shown in
In other embodiments, the capacitor 530 and voltage limiting device 532 may be soldered onto a circuit board, and the circuit board may be attached to the terminals 500, 502 of the Magnetron 216. However, traces on the circuit board may increase the resistance to the voltage limiting device 532 and the capacitor 530, and may prevent them from performing their functions properly. Thus, it may be desirable to directly connect the capacitor 530 and voltage limiting device 532 to the terminals 500, 502 of the Magnetron 216, e.g., via ring lugs as described earlier.
Also, in some embodiments, the protection circuit 450 is placed as close to the terminals 500, 502 of the Magnetron 216 as possible, but not inside the Magnetron 216. In other embodiments, the protection circuit 450 may be placed at other locations, such as inside the modulator.
In some embodiments, the cable 270 has a length selected to provide a desired capacitance matching (between that of the modulator 218 and that of the Magnetron 216), and to tune the RF waveform shape or pulse shape of the Magnetron 216. Such feature may eliminate the need for utilizing matching capacitors within the cage 400. Elimination of the capacitors within the cage 400 may also have the benefit of reducing the number of parts need to be fastened, associated costs, and reliability risk. Furthermore, elimination of the capacitors within the cage 400 may reduce the size of the cage 400, reduce corona discharge, reduce ozone generation, and reduce the risk of dielectric break down. In other embodiments, instead of using a cable length for capacitance matching, capacitors may be provided to perform such function. The capacitors may be placed inside the cage 400 or inside the modulator.
During use, the Magnetron 216 uses interaction of a stream of electrons, guided by a magnetic field provided by the magnet(s) 440 (which may be permanent magnet(s) or electromagnet(s)), to produce electromagnetic waves (e.g., microwave radiation). The cathode is heated by current passing through it, causing it to produce electrons. The electrons are accelerated away from the cathode by a negative high voltage pulse which gives them kinetic energy. The electrons are deflected by magnetic field from the permanent magnet into circular paths. The electrons pass by RF resonant cavities within the magnetron, and transfer some of their kinetic energy to electric and magnetic fields within these cavities. The electric and magnetic fields in the cavities are coupled to the rest of the RF system through the magnetron's output waveguide port. The microwaves may then be directed to the accelerator 212. The cage 400 is configured to maintain a desired high voltage clearance from the Magnetron high voltage feed-through at a certain voltage (e.g., at 45 kV or other levels) to grounded surface, and utilizes the shield 410 in the cage 400, so that shield discharge is minimized or at least reduced within the cage 400. In some cases, during operation, a voltage between the two terminals 500, 502 has a first voltage value, and a voltage between the shield 410 and the cage 400 has a second voltage value that is higher than the first voltage. For example, the second voltage may be at least 1000 times larger than the first voltage.
In the illustrated embodiments, the shield 410 is a conductor around the terminals 500, 502 from the Magnetron 216. The voltage inside the shield 410 is relatively small. For example, the voltage between the terminals 500, 502 inside the shield 410 may be anywhere from 2 V to 20 V (e.g., 6 V). Outside the shield 410, high voltage gradients exist, but field lines are relatively smooth with no sharp edges. In some cases, the size (e.g., cross sectional dimension) of the shield 410 is designed so that the high voltage gradients not too large (e.g., above a certain threshold criteria).
The apparatus 250 is advantageous because it provides EMI containment at the interface between the Magnetron 216 and the cable 270. The apparatus 250 is easy to manufacture and is easy to install. The apparatus 250 also obviates the need to build complex sheet metal enclosure, which is expensive to build, and is labor intensive (because it may require use of many fasteners to assemble). Complex sheet metal enclosure is also complicated to assemble, and makes servicing of the components difficult. In addition, EMI cage created using complex sheet metals may require conductive tape to seal the seams at the EMI cage. On the other hand, the apparatus 250 obviates the need to use conductive tape.
It should be noted that the apparatus 250 is not limited to being used with the Magnetron 216, and that the apparatus 250 may be used with other electromagnetic wave generator. Thus, in other embodiments, the apparatus 250 may be implemented at an interface between any cable and any electromagnetic wave generator.
In the illustrated embodiments, the connector 710 has a bullet shape. In particular, the connector 710 has an outer curvilinear surface that reduces in cross sectional dimension as a function of a longitudinal length of the apparatus 260. This configuration is advantageous because it prevents or reduces the chance of formation of high field region. In other embodiments, the connector 710 may have other shapes. Also, in the illustrated embodiments, the first end 712 of the connector 710 has a cross sectional dimension that varies non-linearly. In other embodiments, the first end 712 of the connector 710 may not vary non-linearly, and may instead vary linearly, may be constant, or may have other profiles. In some cases, the connector 710 may have a profile with an arc, wherein the radius of the arc is selected to minimize or at least reduce an electric field inside a potting material.
In the illustrated embodiments, the second end 714 of the connector 710 includes a coil 728 (e.g., a canted coil), and the coil 728 is configured to circumferentially engage the cylindrical connector 802 of the electron gun 220 when the cylindrical connector 802 is placed over the coil 728.
As shown in
As shown in
As shown in
During installation of the apparatus 260, potting material may be inserted into the opening 782 to fill the space defined by the interior wall of the tube 780. As the potting material is being inserted into the opening 782, air may be pushed out of the opening 784. After the potting material has been inserted, the tube 780 is configured to contain the potting material. The potting material has relatively high dielectric breakdown threshold (also known as high dielectric strength), and is configured to prevent or at least reduce arching between the connector 710 and the surrounding tube 780. The potting material may also prevent corona from occurring. The filling of the tube with potting material should be done in such a way as to reduce bubbles in the potting material (which may cause dielectric breakdown of the insulation potting material).
The apparatus 260 further includes a first seal structure 790 disposed at one end 792 of the tube 780. The first seal structure 790 has an opening 791 for receiving the cable 280. The first seal structure 790 has a curvilinear inner surface, and a distance between the curvilinear inner surface and the cable 280 varies non-linearly as a function of a position along a longitudinal axis of the cable 280. This configuration is advantageous because it prevents or reduces the chance of formation of high field region. As shown in the figure, the first seal structure 790 has a funnel shape. In other embodiments, the first seal structure 790 may have other configurations. For example, in other embodiments, the first seal structure 790 may not have a curvilinear inner surface, and may have a linear surface instead. Also, in other embodiments, a distance between the inner surface of the first seal structure 790 and the cable 280 may vary linearly as a function of a position along the longitudinal axis of the cable 280, or may be constant. In some cases, the curved surface of the seal structure 790 prevents or at least reduces high field region and electric fields in the potting material from developing.
The apparatus 260 also includes a second seal structure 794 disposed at the opposite end 796 of the tube 780.
The cable 280 is shield at its exterior. The cable 280 is electrically grounded to the modulator 218 at one end of the cable 280, and is electrically grounded to the tube 780 at the other end of the cable 280. The cable 280 at the electron gun connection end is shielded circumferentially (360°), providing containment of EMI.
Also, as shown in
In some embodiments, a protection circuit (identical or similar to the protection circuit 450) may be provided for the gun heater. The protection circuit may be installed inside the modulator, or may be installed at other locations. Regardless of where the protection circuit is implemented, it may be considered as being coupled to the apparatus 260 or may be considered as a component of the apparatus 260.
During installation of the apparatus 260, the connector 710 with the cable 280 attached thereto is initially manually connected to the heater and cathode terminals 702, 704 of the electron gun 220. In one technique, the connector 710 is pushed towards the input connection 700 of the electron gun 220 so that pin 800 of the electron gun 220 is inside the opening 720 of the connector 710, and the cylindrical connector 802 of the electron gun 220 is circumferentially surrounding the coil 728 at the end 714 of the connector 710. In the illustrated embodiments, after the connector 710 is connected to the input connection 700 of the electron gun 220, the end 714 of the connector 710 is flushed with the cylindrical connector 802 at the electron gun 220. This feature prevents or at least reduces high field region and electric fields in the potting material from developing.
After the connector 710 is attached to the heater and cathode terminals of the electron gun 220, the tube 780 is then translated along its longitudinal axis to cover the connection made. When the tube 780 has been desirably positioned, the strain relief connector 830 may then be operated to secure the cable 280 relative to the seal structure 790 and to the tube 780. Next, potting material may then be inserted into the cavity in the tube 780 through opening 784 to fill the cavity in the tube 780.
In the illustrated embodiments, the electron gun's feed-through is physically connected and potted directly to the shielded high voltage cable 280, thereby eliminating bulk, length, and cost of existing connector. The connection may be accomplished using hard-wiring, or using detachable couplers. Also, the above apparatus 260 is advantageous because it allows the above installation technique to be easy to carry out without requiring significant training on the installer. The above apparatus 260 and installation technique are advantageous because they allow reliable connections to be made while reducing risk of installation errors. In addition, the apparatus 260 is also advantageous because it provides a compact connection with the electron gun 220, thereby eliminating the need to use long and bulky electron gun connector (which creates unnecessary risk of failure because long and bulky electron gun connector may get hit easier). Furthermore, in the above embodiments, after the potting material has been inserted and has set, the connector 710 cannot be unplugged from the electron gun 220 (at least not without breaking the potting material). This provides added securement and added reliability to the connection.
In the above embodiments, a single modulator 218 is configured to provide pulses to the Magnetron 216 and the electron gun 220. In other embodiments, separate modulators may be configured to provide pulses to the Magnetron 216 and the electron gun 220, respectively.
Also, in other embodiments, EMI shielding enclosure may be integrated into one or more covers. For example, one or more mechanical covers covering the permanent magnet of the Magnetron 216, the Magnetron 216, the electron gun 220, the modulator 218, other components of a radiation system, or any combination of the foregoing, may be used to implement EMI shielding or at least a part of a EMI shielding.
Furthermore, in other embodiments, the Magnetron 216 and/or the electron gun 220 may be placed inside the modulator 218 or inside an extension of the modulator 218, so that all EMI sources are contained in one enclosure. This configuration will eliminate the need for shielded cables and connectors.
Although particular embodiments have been shown and described, it will be understood that it is not intended to limit the claimed inventions to the preferred embodiments, and it will be obvious to those skilled in the art that various changes and modifications may be made without department from the spirit and scope of the claimed inventions. The specification and drawings are, accordingly, to be regarded in an illustrative rather than restrictive sense. The claimed inventions are intended to cover alternatives, modifications, and equivalents.
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