Power transmission circuit
Patent Information
- Authority / Receiving Office
- JP · JP
- Patent Type
- Patents
- Current Assignee / Owner
- HAMAMATSU PHOTONICS KK
- Filing Date
- 2025-06-04
- Publication Date
- 2026-06-09
AI Technical Summary
In high-voltage power supplies, accurately transmitting power and signals from a low-potential side to a high-potential side is challenging due to the need for filters that can change the characteristics of insulating materials, leading to inaccurate signal reception.
A power transmission circuit using isolation transformers and time-separated signal transmission periods to transmit power and signals independently, eliminating the need for filters in insulating environments.
Enables accurate power and signal transmission across high-voltage differences without the need for additional filters, ensuring reliable operation in insulating oil or resin environments.
Smart Images

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Abstract
Description
[Technical Field]
[0001] This disclosure relates to a power transmission circuit. [Background technology]
[0002] In high-voltage power supplies that generate high voltages of several hundred kilovolts, a power transmission circuit is used that transmits power from the low-voltage side to the power supply element mounted on the high-voltage side substrate, and also transmits instruction signals to the control element mounted on the high-voltage side (for example, Patent Document 1). In the power transmission circuit disclosed in Patent Document 1, in addition to power transmission, an ON / OFF signal from a transmission switch provided on the low-voltage side is transmitted to the high-voltage side. [Prior art documents] [Patent Documents]
[0003] [Patent Document 1] Japanese Patent Publication No. 2008-41318 [Overview of the Initiative] [Problems that the invention aims to solve]
[0004] The frequency of the transmitted power is, for example, several hundred kHz, while the frequency of the transmitted signal is higher than the power frequency, for example, several MHz. Therefore, when transmitting power and signal simultaneously, it is necessary to separate them by installing a filter on the high-voltage side. In high-voltage power supplies, to ensure the dielectric strength between the low-voltage side and the high-voltage side, methods such as impregnating a part of the high-voltage power supply with insulating oil or coating a part of the high-voltage power supply with insulating resin are sometimes employed. However, in these cases, the characteristics of the filter change in the insulating oil and insulating resin, which may prevent the signal from being accurately received on the high-voltage side.
[0005] The purpose of this disclosure is to provide a power transmission circuit that can accurately transmit power and signals from a low-potential side to a high-potential side. [Means for solving the problem]
[0006] A power transmission circuit relating to one aspect of the present disclosure is a power transmission circuit connected to a circuit that boosts voltage from a low potential side to a high potential side, comprising: a first transformer which is an isolation transformer including a low-voltage side winding which is a primary winding connected to the low potential side and a high-voltage side winding which is a secondary winding connected to the high potential side; a low-voltage side inverter circuit whose output terminal is connected to the low-voltage side winding; a low-voltage side control circuit connected to the input terminal of the low-voltage side inverter circuit and driving the low-voltage side inverter circuit; a second transformer which includes a primary winding, a first secondary winding and a second secondary winding, the primary winding being connected to the high-voltage side winding; and the first The power transmission circuit comprises a rectifier circuit connected to a secondary winding and a high-voltage side control circuit connected to the second secondary winding and operating based on a first signal, wherein the low-voltage side control circuit drives the low-voltage side inverter circuit to generate a high-voltage side voltage, which is transmitted to the rectifier circuit via the first transformer and the second transformer in a first period of power transmission, and the low-voltage side control circuit drives the low-voltage side inverter circuit to generate a first signal, which is transmitted to the high-voltage side control circuit via the first transformer and the second transformer in a second period of power transmission separate from the first period of power transmission.
[0007] In the power transmission circuit described in [1] above, power can be transmitted from the low potential side to the high potential side by transmitting the voltage generated by the low-voltage side inverter circuit as the high-voltage side voltage through the first transformer. Furthermore, the first signal can be transmitted from the low potential side to the high potential side by transmitting the first signal through the first transformer which is also used for power transmission. Power transmission takes place in a first period, and the first signal transmission takes place in a second period. In other words, the high-voltage side voltage transmitted in power transmission and the first signal transmitted in the first signal transmission are transmitted in a time-separated state. As a result, there is no need to provide a filter to separate the high-voltage side voltage and the first signal, so that the high-voltage side control circuit can accurately receive the first signal on the high potential side, even in insulating oil and insulating resin. Furthermore, by transmitting the high-voltage side voltage to a rectifier circuit connected to the first secondary winding, the high-voltage side voltage can be rectified to generate a power supply voltage that can be supplied to, for example, a power supply element located on the high potential side. In addition, by providing a second transformer between the first transformer and the rectifier circuit and the high-voltage side control circuit, it is possible to suppress the formation of an unexpected common impedance between the first transformer and the rectifier circuit and the high-voltage side control circuit.
[0008] A power transmission circuit relating to one aspect of the present disclosure may be the power transmission circuit described in [1], wherein a waveform shaping circuit for improving the distortion of the first signal is connected between the second secondary winding and the high-voltage side control circuit. In this case, a waveform shaping circuit for improving the distortion of the first signal is connected between the second secondary winding and the high-voltage side control circuit. This allows the high-voltage side control circuit to receive the first signal more accurately by improving the distortion of the first signal before it is input to the high-voltage side control circuit.
[0009] A power transmission circuit relating to one aspect of the present disclosure may be [3] "a power transmission circuit according to [1] or [2], further comprising a high-voltage inverter circuit whose output terminal is connected between the high-voltage side winding of the first transformer and the primary winding of the second transformer, and whose input terminal is connected to the high-voltage side control circuit, wherein the low-voltage side control circuit performs an operation separate from the driving of the low-voltage side inverter circuit based on a second signal, and performs a second signal transmission in which the second signal generated by the high-voltage side control circuit driving the high-voltage side inverter circuit is transmitted to the low-voltage side control circuit via the first transformer, in a third period separate from the first and second periods." In this case, the second signal can be transmitted from the high-potential side to the low-potential side by transmitting the second signal via a first transformer common to both power transmission and the first signal transmission. This enables bidirectional signal transmission between the low-potential side and the high-potential side in conjunction with the first signal transmission. Furthermore, since the second signal is transmitted during the third period, it is transmitted in a temporally separated state from the high-voltage side voltage and the first signal. As a result, even in insulating oil and insulating resin, the low-voltage side control circuit can accurately receive the second signal on the low-potential side.
[0010] A power transmission circuit relating to one aspect of this disclosure may be [4] "the power transmission circuit according to any one of [1] to [3], wherein the first transformer is a loosely coupled transformer." In this case, for example, the leakage inductance increases compared to a tightly coupled transformer, so that in defining the resonant frequency, the leakage inductance becomes dominant over the excitation inductance in the region where the load resistance is sufficiently small compared to the reactance value of the excitation inductance at the resonant frequency, making it easier to define the resonant frequency. This makes it easier to set the frequency of the voltage transmitted in power transmission and the frequency of the first signal based on the resonant frequency.
[0011] A power transmission circuit relating to one aspect of the present disclosure may be [5] "a power transmission circuit according to any one of [1] to [4], further comprising: a second low-voltage side control circuit provided on the low-voltage side and generating the first signal separately from the low-voltage side control circuit; a light-emitting element connected to the second low-voltage side control circuit; an optical fiber including an input terminal optically coupled to the light-emitting element and arranged to connect the low-voltage side and the high-voltage side; a photodetector element optically coupled to the output terminal of the optical fiber on the high-voltage side; an output terminal connected to the high-voltage side control circuit; and an amplifier including a pair of input terminals, one of which is connected to the photodetector element, and the other input terminal of which is connected to the reference potential on the high-voltage side." In this case, the first signal generated in the second low-voltage side control circuit is converted from electricity to light in the light-emitting element and transmitted from the low-voltage side to the high-voltage side by the optical fiber. The transmitted first signal is photoelectrically converted by the photodetector element on the high-voltage side, amplified by the amplifier, and output to the high-voltage side control circuit. The other of the pair of input terminals of the amplifier is connected to a reference potential on the high-potential side, and the output terminal is connected to a high-voltage control circuit. The reference potential of the high-voltage control circuit is the same as the reference potential on the high-potential side. As a result, the amplifier can transmit the first signal within the high-potential region. With this configuration, by securing a signal transmission route separate from the first and second transformers, it is possible to address situations where the transmission amount is insufficient with only the first signal transmission.
[0012] A power transmission circuit relating to one aspect of the present disclosure is [6] "a power transmission circuit connected to a circuit that boosts voltage from a low potential side to a high potential side, comprising: a first transformer which is an isolation transformer including a low-voltage side winding which is a primary winding connected to the low potential side and a high-voltage side winding which is a secondary winding connected to the high potential side; a low-voltage side inverter circuit whose output terminal is connected to the low-voltage side winding; a low-voltage side control circuit connected to the input terminal of the low-voltage side inverter circuit and driving the low-voltage side inverter circuit; a rectifier circuit connected to the high-voltage side winding; a first DC converter which includes an input terminal and an output terminal, the input terminal of which is connected to the rectifier circuit; and the output terminal A power transmission circuit comprising: a second DC converter connected to and operating based on a first signal, wherein the low-voltage side control circuit drives the low-voltage side inverter circuit to generate a high-voltage side voltage, which is transmitted to the second DC converter via the first transformer, the rectifier circuit, and the first DC converter in a first period of time, and the low-voltage side control circuit drives the low-voltage side inverter circuit to generate a first signal, which is transmitted to the second DC converter via the first transformer, the rectifier circuit, and the first DC converter in a second period of time separate from the first period of time.
[0013] In the power transmission circuit described in [6] above, the high-voltage side voltage transmitted by power transmission and the first signal transmitted by the first signal transmission are transmitted in a time-separated state. As a result, there is no need to provide a filter to separate the high-voltage side voltage and the first signal, so that the high-voltage side control circuit can accurately receive the first signal on the high-potential side even in insulating oil and insulating resin. Furthermore, by transmitting the high-voltage side voltage to a rectifier circuit connected to the first secondary winding, the high-voltage side voltage can be rectified to generate a power supply voltage that can be supplied to, for example, a power supply element located on the high-potential side. [Effects of the Invention]
[0014] According to this disclosure, power and signals can be accurately transmitted from a low-potential side to a high-potential side.
Brief Description of the Drawings
[0015] [Figure 1] It is a block diagram of a high - voltage power supply including a power transmission circuit according to one aspect of the present disclosure. [Figure 2] It is a diagram showing an example of a transmission waveform transmitted by power transmission and first - signal transmission. [Figure 3] It is a diagram for explaining the configuration and operation of a series resonance circuit. [Figure 4] (a) of FIG. 4 shows an example of the operation of the low - voltage - side inverter circuit in the first period in the case of a full - bridge circuit. (b) of FIG. 4 shows an example of the operation of the low - voltage - side inverter circuit in the third period in the case of a full - bridge circuit. [Figure 5] (a) of FIG. 5 shows an example of the operation of the low - voltage - side inverter circuit in the first and second periods in the case of a half - bridge circuit. (b) of FIG. 5 shows an example of the operation of the low - voltage - side inverter circuit in the third period in the case of a half - bridge circuit. [Figure 6] It is a block diagram of a high - voltage power supply including a power transmission circuit according to the first modification example. [Figure 7] It is a diagram showing an example of a transmission waveform transmitted in the power transmission circuit according to the first modification example. [Figure 8] (a) of FIG. 8 is a block diagram of a power transmission circuit according to the second modification example. (b) of FIG. 8 is a block diagram of a power transmission circuit according to the third modification example. [Figure 9] It is a block diagram of a power transmission circuit according to the fourth modification example. [Figure 10] It is a block diagram of a power transmission circuit according to the fifth modification example.
Embodiments for Carrying Out the Invention
[0016] Hereinafter, with reference to the drawings, a preferred embodiment of a power transmission circuit according to an embodiment of the present disclosure will be described in detail.
[0017] Figure 1 is a block diagram of a high-voltage power supply 10 including a power transmission circuit 1 relating to one aspect of the present disclosure. The high-voltage power supply 10 is applicable to devices that have an input voltage of several hundred kV, for example, X-ray tubes and electron beam irradiation devices. In this embodiment, the high-voltage power supply 10 will be described as being applied to an X-ray tube XL. The high-voltage power supply 10 comprises a power transmission circuit 1, a high-voltage generation circuit 3, a detection circuit 4, a cathode power supply 51, a filament power supply 52, and a grid power supply 53. The X-ray tube XL includes a cathode electrode CE, a filament FE, and a grid electrode GE. The filament FE generates heat when energized. The cathode electrode CE is heated by the filament FE and emits electrons. The grid electrode GE adjusts the amount of electrons emitted from the cathode electrode CE by forming an electric field between itself and the cathode electrode CE.
[0018] The high-voltage generation circuit 3 is a circuit for generating a high voltage to be supplied to the X-ray tube XL. The high-voltage generation circuit 3 includes an inverter 31, an output transformer 32, and a Cockcroft-Walton circuit 33. The inverter 31 is a circuit composed of multiple transistors. The inverter 31 may be a bridge circuit or a push-pull circuit. In the case of a bridge circuit, the inverter 31 is a half-bridge circuit in which, for example, the source terminal of the high-side FET and the drain terminal of the low-side FET are connected to each other. The inverter 31 converts the input DC voltage into AC voltage. The output transformer 32 includes a primary winding 32a and a secondary winding 32b. The primary winding 32a is connected to the inverter 31. The output transformer 32 is a functional unit that boosts the AC voltage generated in the inverter 31 according to the winding ratio of the primary winding 32a and the secondary winding 32b. The input of the Cockcroft-Walton circuit 33 is connected to the secondary winding 32b. The output of the Cockcroft-Walton circuit 33 is connected to the X-ray tube XL. The Cockcroft-Walton circuit 33 generates a DC voltage by boosting and rectifying the AC voltage output from the output transformer 32. The Cockcroft-Walton circuit 33 boosts and rectifies the magnitude of the AC voltage output from the output transformer 32 to several hundred kV and supplies it to the X-ray tube XL.
[0019] In the high-voltage generation circuit 3, the primary windings 32a of the inverter 31 and the output transformer 32 are located in a low-potential region 6 with a first reference potential G1 as the reference potential. For example, the low-potential region 6 includes a wiring board with the first reference potential G1 as the reference potential, and the inverter 31 and the output transformer 32 are mounted on this wiring board. The first reference potential G1 is, for example, 0V. On the other hand, the output of the Cockcroft-Walton circuit 33 is connected to the X-ray tube XL and defines the reference potential of the high-potential region 7, which is a region with a second reference potential G2 as the reference potential. The second reference potential G2 is, for example, several hundred kV. The high-potential region 7 includes, for example, a wiring board with the second reference potential G2 as the reference potential. In the high-voltage power supply 10, in order to ensure the dielectric breakdown voltage between the low-potential region 6 and the high-potential region 7, means of impregnating a part of the high-voltage power supply 10 with insulating oil, or means of coating or molding a part of the high-voltage power supply 10 with insulating resin may be employed.
[0020] The detection circuit 4 is a circuit that detects the current supplied to the X-ray tube XL and outputs an indicator voltage Va based on the detection result to the power transmission circuit 1. The detection circuit 4 has a detection resistor R1 and an error amplifier 45. The error amplifier 45 includes a pair of input terminals 45a, 45b and an output terminal 45c. One input terminal 45a is connected to the node between the secondary winding 32b and the input of the Cockcroft-Walton circuit 33. The detection resistor R1 is connected between one input terminal 45a and the first reference potential G1. The detection resistor R1 detects the magnitude of the current supplied to the Cockcroft-Walton circuit 33 and converts it into a detection voltage Vb. In other words, the detection circuit 4 detects the magnitude of the current supplied to the X-ray tube XL by detecting the current supplied to the Cockcroft-Walton circuit 33. The detection voltage Vb is input to one input terminal 45a. The other input terminal 45b is input to an externally input set voltage Vc. The set voltage Vc is a voltage that represents the set value of the current supplied to the X-ray tube XL. The error amplifier 45 outputs an indicator voltage Va, which is the amplified difference between the detected voltage Vb and the set voltage Vc, to the power transmission circuit 1.
[0021] The power transmission circuit 1 transmits power from the low-potential region 6 to the cathode power supply 51, filament power supply 52, and grid power supply 53 located in the high-potential region 7, and also transmits instruction signals to control the outputs of the cathode power supply 51, filament power supply 52, and grid power supply 53. The power transmission circuit 1 includes an AD converter 11, a low-voltage side control circuit 12, a low-voltage side inverter circuit 13, a first transformer 14, a second transformer 15, a rectifier circuit 16, a waveform shaping circuit 17, a high-voltage side control circuit 18, and a DA converter 19. The primary windings 14a of the AD converter 11, the low-voltage side control circuit 12, the low-voltage side inverter circuit 13, and the first transformer 14 are located in the low-potential region 6. The secondary winding 14b of the first transformer 14, the second transformer 15, the rectifier circuit 16, the waveform shaping circuit 17, the high-voltage side control circuit 18, and the DA converter 19 are located in the high-potential side region 7.
[0022] In the power transmission circuit 1, power transmission and the first signal transmission take place between the low-potential region 6 and the high-potential region 7. In the power transmission circuit 1, the first signal transmission takes place by, for example, UART (Universal Asynchronous Receiver / Transmitter) communication, with the low-voltage side control circuit 12 acting as the master and the high-voltage side control circuit 18 acting as the slave. Figure 2 shows an example of a transmission waveform transmitted by power transmission and the first signal transmission. The transmission waveform D1 includes a first period T1 and a second period T2. The low-voltage side control circuit 12 performs power transmission during the first period T1. In power transmission, the low-voltage side control circuit 12 drives the low-voltage side inverter circuit 13 to generate the high-voltage side voltage V1, which is then transmitted to the rectifier circuit 16 via the first transformer 14 and the second transformer 15. The high-voltage side voltage V1 is a high frequency in which the magnitude of the voltage changes periodically between a low level and a high level, and the frequency of the high-voltage side voltage V1 is, for example, 100 kHz. The low-voltage side control circuit 12 performs the first signal transmission in a second period T2, which is separate from the first period T1. In the first signal transmission, the low-voltage side control circuit 12 transmits the first signal S1 via the low-voltage side inverter circuit 13, the first transformer 14, and the second transformer 15. The first signal S1 is a signal used by the high-voltage side control circuit 18 to control the outputs of the cathode power supply 51, the filament power supply 52, and the grid power supply 53. The first signal S1 is a high-frequency signal whose voltage magnitude changes between low and high levels according to the transmission waveform, and the frequency of the first signal S1 is greater than the frequency of the high-voltage side voltage V1, for example, 1 MHz. The high-voltage side voltage V1 transmitted in power transmission and the first signal S1 transmitted in the first signal transmission are transmitted in a time-separated state. In other words, in the power transmission circuit 1, the high-voltage side voltage V1 and the first signal S1 are transmitted using time division multiplexing (TDM).
[0023] Of the power transmission circuit 1, the low-voltage side control circuit 12, the low-voltage side inverter circuit 13, the first transformer 14, the second transformer 15, and the rectifier circuit 16 constitute the power transmission path 8. First, the configuration of the power transmission path 8 will be explained.
[0024] The output terminal 12b of the low-voltage control circuit 12 is connected to the input terminal of the low-voltage inverter circuit 13. The low-voltage control circuit 12 is, for example, an FPGA (Field-Programmable Gate Array). The low-voltage inverter circuit 13 is a bridge circuit composed of multiple transistors, for example, a half-bridge circuit. The low-voltage control circuit 12 drives the low-voltage inverter circuit 13 at a frequency of, for example, 100 kHz to generate the high-voltage side voltage V1.
[0025] The first transformer 14 includes a primary winding 14a and a secondary winding 14b. The primary winding 14a is located in the low-potential region 6 and can therefore be referred to as the low-voltage winding. The secondary winding 14b is located in the high-potential region 7 and can therefore be referred to as the high-voltage winding. The first transformer 14 is an isolation transformer that insulates the low-potential region 6 and the high-potential region 7. The primary winding 14a is connected to the output terminal of the low-voltage inverter circuit 13. A series resonant capacitor Cs is connected between one end of the primary winding 14a and the output of the low-voltage inverter circuit 13.
[0026] Figure 3(a) is a schematic circuit diagram illustrating the parasitic components present between the primary winding 14a and the low-voltage inverter circuit 13. As shown in Figure 3(a), the leakage inductance La of the first transformer 14 is connected in series with the series resonant capacitor Cs. The excitation inductance Lp of the first transformer 14 is connected in parallel with the primary winding 14a. The series resonant capacitor Cs, the leakage inductance La, and the excitation inductance Lp constitute a series resonant circuit RC (LLC resonant circuit). In Figure 3(a), the load resistor R is connected in parallel with the excitation inductance Lp. L It is connected.
[0027] The first transformer 14 is a loosely coupled transformer. Compared to a tightly coupled transformer, a loosely coupled transformer has a lower coupling coefficient between the primary winding 14a and the secondary winding 14b, resulting in a larger leakage inductance La. Two resonant frequencies are defined in a series resonant circuit RC. Resonant frequency f0 is the resonant frequency defined by the excitation inductance Lp, the leakage inductance La, and the series resonant capacitor Cs. Resonant frequency f1 is the resonant frequency defined by the leakage inductance La and the series resonant capacitor Cs. The resonant frequency f1 of the series resonant circuit RC is expressed by equation (1). f1=1 / 2×π×SQRT(La×Cs)…(1) In equation (1), SQRT represents the square root. As shown in equation (1), at the resonant frequency f1, the leakage inductance La is dominant over the excitation inductance Lp, so the resonant frequency f1 is determined based on the series resonant capacitor Cs and the leakage inductance La. At the resonant frequency f1, the load resistance R is relative to the reactance value of the excitation inductance Lp at the resonant frequency f1. L In this region, the magnitude of the leakage inductance La becomes sufficiently small compared to the excitation inductance Lp. At this point, the load resistance R L The size is set based on equation (2). 2πf1Lp>>R L …(2) When equation (2) is true, a series resonance is established between the series resonant capacitor Cs and the excitation inductance Lp, resulting in highly efficient power transmission.
[0028] Figure 3(b) shows the frequency characteristics of a series resonant circuit RC. The horizontal axis of Figure 3(b) represents the drive frequency (Hz), and the vertical axis represents the relative output magnitude of the output voltage of the series resonant circuit RC. In this embodiment, the resonant frequency f1 of the series resonant circuit RC coincides with the frequency of the high-voltage side voltage V1. Based on the frequency characteristics shown in Figure 3(b), the frequency of the first signal S1 is set such that the magnitude of the output of the first signal S1 is, for example, 1 / 10 of the magnitude of the output of the high-voltage side voltage V1.
[0029] Refer again to Figure 1. The second transformer 15 includes a primary winding 15a, a first secondary winding 15b, and a second secondary winding 15c. The primary winding 15a is connected to the secondary winding 14b of the first transformer 14. The first secondary winding 15b is connected to the input terminal of the rectifier circuit 16. The second secondary winding 15c is connected to the input terminal of the waveform shaping circuit 17. The second transformer 15 prevents the formation of an unexpected common impedance between the first transformer 14, the rectifier circuit 16, and the high-voltage side control circuit 18. In power transmission, the high-voltage side voltage V1 is transmitted from the primary winding 15a to the first secondary winding 15b and then to the rectifier circuit 16.
[0030] The rectifier circuit 16 generates a DC power supply voltage Vcc from the high-voltage side voltage V1 transmitted from the second transformer 15. The rectifier circuit 16 includes, for example, a rectifier diode and a smoothing capacitor. The high-voltage side voltage V1 is converted into the power supply voltage Vcc by being rectified in the rectifier diode and smoothed in the smoothing capacitor. The power supply voltage Vcc becomes the power supply voltage for driving elements (for example, the cathode power supply 51, the filament power supply 52, and the grid power supply 53, and the high-voltage side control circuit 18) located on the high-potential side region 7.
[0031] Next, we will explain the differences between the configuration of the first signal transmission path 9 and the power transmission path 8. Of the power transmission circuit 1, the AD converter 11, the low-voltage side control circuit 12, the low-voltage side inverter circuit 13, the first transformer 14, the second transformer 15, the waveform shaping circuit 17, the high-voltage side control circuit 18, and the DA converter 19 constitute the first signal transmission path 9.
[0032] The input of the AD converter 11 is connected to the output terminal 45c of the error amplifier 45. The AD converter 11 converts the instruction voltage Va from an analog signal to a digital signal.
[0033] The input terminal 12a of the low-voltage side control circuit 12 is connected to the output terminal of the AD converter 11. When the low-voltage side control circuit 12 receives a digital signal of the instruction voltage Va from the AD converter 11, it generates a first signal S1. The low-voltage side control circuit 12 drives the low-voltage side inverter circuit 13 at a different frequency (e.g., 1 MHz) than that used for power transmission and transmits the first signal S1 to the first transformer 14. The first signal S1 is then transmitted from the primary winding 14a to the secondary winding 14b of the first transformer 14, thereby transmitting it from the low-potential side region 6 to the high-potential side region 7. In other words, the transmission of the high-voltage side voltage V1 from the low-potential side region 6 to the high-potential side region 7 (power transmission) and the transmission of the first signal S1 from the low-potential side region 6 to the high-potential side region 7 (first signal transmission) are carried out via a common first transformer 14.
[0034] The first signal S1, for example, has one value for each period. The number of bits in this value is, for example, 8 bits, and its magnitude changes between 00000000 and 11111111. For example, a high level in the first signal S1 represents '1', and a low level represents '0'. The low-voltage control circuit 12 sets each value of the first signal S1 between 0000 and 1111 based on the magnitude of the instruction voltage Va.
[0035] A termination resistor R2 is provided in parallel with the primary winding 15a between the secondary winding 14b of the first transformer 14 and the primary winding 15a of the second transformer 15. The termination resistor R2 is provided to suppress reflection of the first signal S1. In the first signal transmission, the first signal S1 is transmitted from the primary winding 15a to the second secondary winding 15c, after reflection is suppressed at the termination resistor R2, and then transmitted to the waveform shaping circuit 17. Furthermore, in addition to the termination resistor R2, a CR circuit, which consists of the termination resistor R2 and a capacitor connected in series, may be provided in parallel with the primary winding 15a. When a CR circuit is provided in parallel with the primary winding 15a, AC termination can be achieved when the magnitude of the first signal changes while maintaining the waveform quality of the first signal S1.
[0036] The input terminal of the waveform shaping circuit 17 is connected to the second secondary winding 15c of the second transformer 15. The waveform shaping circuit 17 improves the distortion of the first signal S1 and then transmits the first signal S1 to the high-voltage side control circuit 18. The waveform shaping circuit 17 is, for example, a low-pass filter with a cutoff frequency higher than the signal transmission bandwidth, and removes harmonic components of the first signal S1 that do not contribute to the transmitted signal. The input terminal of the waveform shaping circuit 17 is connected to the power supply voltage Vcc generated by the rectifier circuit 16. The amplitude of the voltage generated in the second secondary winding 15c changes depending on the load conditions of the rectifier circuit 16. The waveform shaping circuit 17 has a differential configuration at its input terminal with the power supply voltage Vcc as the reference. As a result, the waveform shaping circuit 17 receives the first signal S1 stably regardless of the load conditions.
[0037] The first input terminal 18a of the high-voltage side control circuit 18 is connected to the output terminal of the waveform shaping circuit 17. Based on the first signal S1 with improved distortion, the high-voltage side control circuit 18 generates a cathode control signal Sc for controlling the cathode power supply 51, a filament control signal Sf for controlling the filament power supply 52, and a grid control signal Sg for controlling the grid power supply 53. The cathode control signal Sc, the filament control signal Sf, and the grid control signal Sg are, for example, the input voltages of each power supply 51 to 53. The high-voltage side control circuit 18 may control the output voltage values output from each power supply 51 to 53 by controlling the input voltages of each power supply 51 to 53. Based on the values of the first signal S1, the high-voltage side control circuit 18 generates the cathode control signal Sc, the filament control signal Sf, and the grid control signal Sg. In other words, the high-voltage side control circuit 18 serially / parallel converts the first signal S1 into the cathode control signal Sc, the filament control signal Sf, and the grid control signal Sg. For example, the first value of the first signal S1 may correspond to the cathode control signal Sc, the second value to the filament control signal Sf, and the third value to the grid control signal Sg. The magnitudes of the cathode control signal Sc, the filament control signal Sf, and the grid control signal Sg may be set based on a lookup table associated with each value of the first signal S1.
[0038] The input terminal 19a of the DA converter 19 is connected to the first output terminal 18b of the high-voltage side control circuit 18. The DA converter 19 includes a first output terminal 19b, a second output terminal 19c, and a third output terminal 19d. The first output terminal 19b is connected to the input terminal 51a of the cathode power supply 51. The second output terminal 19c is connected to the input terminal 52a of the filament power supply 52. The third output terminal 19d is connected to the input terminal 53a of the grid power supply 53. The DA converter 19 converts the cathode control signal Sc input from the high-voltage side control circuit 18 into an analog signal and outputs it to the cathode power supply 51 from the first output terminal 19b. The DA converter 19 converts the filament control signal Sf input from the high-voltage side control circuit 18 into an analog signal and outputs it to the filament power supply 52 from the second output terminal 19c. The DA converter 19 converts the grid control signal Sg input from the high-voltage side control circuit 18 into an analog signal and outputs it to the grid power supply 53 from the third output terminal 19d.
[0039] The first output terminal 51b of the cathode power supply 51 is connected to the cathode electrode CE of the X-ray tube XL. The cathode power supply 51 supplies an output voltage controlled by the high-voltage control circuit 18 to the cathode electrode CE. The first output terminal 52b of the filament power supply 52 is connected to the filament FE of the X-ray tube XL. The filament power supply 52 supplies an output voltage controlled by the high-voltage control circuit 18 to the filament FE. The first output terminal 53b of the grid power supply 53 is connected to the grid electrode GE of the X-ray tube XL. The grid power supply 53 supplies an output voltage controlled by the high-voltage control circuit 18 to the grid electrode GE.
[0040] Refer to Figure 2 again. The transmission waveform D1 transmitted from the low-voltage control circuit 12 to the high-voltage control circuit 18 includes a third period T3 between the first period T1 and the second period T2. In the transmission waveform D1, the first period T1 is again followed after the second period T2. The third period T3 is a period for consuming the power remaining in the power transmission path 8 due to power transmission. This removes ringing components on the power transmission path 8. In other words, the third period T3 is a stabilization period. Power consumption in the third period T3 is performed, for example, by a dummy resistor. A circuit in which a dummy resistor and a switching element are connected in series is provided between the first secondary winding 15b of the second transformer 15 and the second reference potential G2, and a signal to turn on the switching element may be transmitted from the low-voltage control circuit 12 or the high-voltage control circuit 18 after the end of the first period T1.
[0041] Alternatively, power consumption during the third period T3 may be achieved, for example, by forming a short-circuit network in the low-voltage side inverter circuit 13. Figure 4 is a diagram illustrating an example of the operation of the low-voltage side inverter circuit 13. As shown in Figure 4, the low-voltage side inverter circuit 13 may be composed of a full-bridge circuit with transistors TR1 to TR4. Each of transistors TR1 to TR4 includes a first current terminal and a second current terminal. Figure 4(a) shows an example of the operation of the low-voltage side inverter circuit 13 during the first period T1 in the case of a full-bridge circuit. During the first period T1, periods in which transistors TR1 and TR4 are simultaneously ON and periods in which transistors TR2 and TR3 are simultaneously ON alternate. During the period in which transistors TR1 and TR4 are simultaneously ON, the inverter current I F1 The current flows from the second current terminal TR1b of transistor TR1, through the primary winding 14a, to the first current terminal TR4a of transistor TR4. Then, the inverter current I F1 The current flows from the second current terminal TR4b of transistor TR4 to the first reference potential G1. During the period when transistors TR2 and TR3 are simultaneously ON, the inverter current IF2 flows from the second current terminal TR3b of the transistor TR3, through the primary winding 14a, to the first current terminal TR2a of the transistor TR2. And the inverter current I F2 flows from the second current terminal TR2b of the transistor TR2 to the first reference potential G1.
[0042] Fig. 4(b) shows an example of the operation of the low-voltage side inverter circuit 13 in the third period T3 in the case of a full-bridge circuit. In the third period T3, for example, when the transistors TR2 and TR4 are simultaneously turned on, a short-circuit network is formed. The inverter current I F3 flows from the second current terminal TR2b of the transistor TR2, through the first reference potential G1, to the second current terminal TR4b of the transistor TR4. The inverter current I F3 flows from the first current terminal TR4a of the transistor TR4, through the primary winding 14a, to the first current terminal TR2a of the transistor TR2. By forming such a short-circuit network, it becomes easier to consume the resonance energy accumulated in the first period T1. Thereby, the disturbance of the waveform at the start of the second period T2 is suppressed, and stable communication can be realized.
[0043] As shown in Fig. 5, the low-voltage side inverter circuit 13 may be constituted by a half-bridge circuit formed by transistors TR1 to TR4. Each of the transistors TR1 to TR4 includes a first current terminal and a second current terminal. Fig. 5(a) shows an example of the operation of the low-voltage side inverter circuit 13 in the first period T1 and the second period T2 in the case of a half-bridge circuit. In the first period T1, for power transmission, the ON periods of the transistor TR1 and the ON periods of the transistor TR2 are alternately repeated. In the second period T2, for signal transmission, the ON periods of the transistor TR3 and the ON periods of the transistor TR4 are alternately repeated. In the period when the ON periods of the transistor TR1 and the ON periods of the transistor TR2 are alternately repeated, the inverter current I F1The current flows from the second current terminal TR1b of transistor TR1 through the primary winding 14a to the first reference potential G1. During the period when the ON period of transistor TR3 and the ON period of transistor TR4 alternate, the inverter current I F2 The current flows from the second current terminal TR3b of transistor TR3 through the primary winding 14a to the first reference potential G1. A damping resistor DR1 may be connected between the second current terminal TR3b of transistor TR3 and the primary winding 14a. The connection of the damping resistor DR1 helps to reduce high-frequency components while maintaining the waveform quality of the first signal S1, thereby contributing to noise suppression.
[0044] Figure 5(b) shows an example of the operation of the low-voltage side inverter circuit 13 during the third period T3 in the case of a half-bridge circuit. During the third period T3, for example, transistors TR2 and TR4 are turned ON, forming a short-circuit network including the damping resistor DR1. The inverter current I in the short-circuit network F3 The current flows from the second current terminal TR4b of transistor TR4 to the first reference potential G1. By forming a short-circuit network including such a power-consuming element, the resonant energy accumulated in the first period T1 is more easily dissipated. This suppresses waveform distortion at the start of the second period T2, enabling stable communication.
[0045] The low-voltage side control circuit 12 transmits the transmission waveform D1, causing power transmission in the first period T1, power consumption in the third period T3, and the first signal transmission in the second period T2 to be repeated in the order of the first period T1, the third period T3, and the second period T2. The low-voltage side control circuit 12, which is the master side, and the high-voltage side control circuit 18, which is the slave side, have a function to synchronize with the first period T1, the second period T2, and the third period T3, respectively. The synchronization function is, for example, a function to detect the start of the first period T1, the second period T2, and the third period T3, respectively, by counters included in the low-voltage side control circuit 12 and the high-voltage side control circuit 18.
[0046] The low-voltage control circuit 12 may switch between a first mode and a second mode depending on an external input. In the first mode, the low-voltage control circuit 12 repeatedly performs power transmission in the first period T1, power consumption in the third period T3, and first signal transmission in the second period T2, in the order of the first period T1, the third period T3, and the second period T2. In the second mode, under normal circumstances, the low-voltage control circuit 12 repeatedly performs only power transmission in the first period T1. At a predetermined timing, the low-voltage control circuit 12 performs power transmission in the first period T1, power consumption in the third period T3, and first signal transmission in the second period T2 in sequence only once during a single transmission. [Mechanism of Action and Effects]
[0047] In the power transmission circuit 1, power can be transmitted from the low-potential region 6 to the high-potential region 7 by transmitting the voltage generated by the low-voltage side inverter circuit 13 as the high-voltage side voltage V1 via the first transformer 14. Furthermore, the first signal S1 can be transmitted from the low-potential region 6 to the high-potential region 7 by transmitting the first signal S1 via the first transformer 14 which is also used for power transmission. Power transmission takes place during the first period T1, and the first signal transmission takes place during the second period T2. In other words, the high-voltage side voltage V1 transmitted in power transmission and the first signal S1 transmitted in the first signal transmission are transmitted in a time-separated state. As a result, there is no need to provide a filter to separate the high-voltage side voltage V1 and the first signal S1, and the high-voltage side control circuit 18 can accurately receive the first signal S1 on the high-voltage side, even in insulating oil and insulating resin. Furthermore, by transmitting the high-voltage side voltage V1 to the rectifier circuit 16 connected to the first secondary winding 15b, the high-voltage side voltage V1 is rectified, and a power supply voltage Vcc can be generated that is supplied to power supply elements such as power supplies 51-53 located in the high-potential side region 7 and to the group of circuits operating in the high-potential side region 7. In addition, by providing a second transformer 15 between the first transformer 14, the rectifier circuit 16 and the high-voltage side control circuit 18, it is possible to suppress the formation of an unexpected common impedance between the first transformer 14 and the rectifier circuit 16 and the high-voltage side control circuit 18.
[0048] A waveform shaping circuit 17 is connected between the second secondary winding 15c and the high-voltage side control circuit 18 to improve the distortion of the first signal S1. In this case, by improving the distortion of the first signal S1 before it is input to the high-voltage side control circuit 18, the high-voltage side control circuit 18 can receive the first signal S1 more accurately.
[0049] The first transformer 14 is a loosely coupled transformer. In this case, for example, the leakage inductance La increases compared to a tightly coupled transformer. As a result, in defining the resonant frequency f0, in the region where the load resistance is sufficiently small compared to the reactance value of the excitation inductance at the resonant frequency, the leakage inductance La becomes dominant over the excitation inductance Lp, making it easier to define the resonant frequency f0. Therefore, it becomes easier to set the frequency of the voltage transmitted in power transmission and the frequency of the first signal S1 based on the resonant frequency f0. [Differentiation]
[0050] While embodiments of this disclosure have been described above, this disclosure is not necessarily limited to the embodiments described above, and various modifications are possible without departing from its essence. [First variation]
[0051] Figure 6 is a block diagram of a high-voltage power supply 10A according to the first modified example. Only the differences from the high-voltage power supply 10 according to the embodiment will be described. The high-voltage power supply 10A includes a power transmission circuit 1A instead of the power transmission circuit 1. In addition to power transmission and the first signal transmission, the power transmission circuit 1A performs a second signal transmission from the high-voltage side control circuit 18 to the low-voltage side control circuit 12. In addition to the configuration of the power transmission circuit 1, the power transmission circuit 1A includes a second DA converter 21, a second waveform shaping circuit 22, a third transformer 23, a high-voltage side inverter circuit 24, and a second AD converter 25. The second DA converter 21, the second waveform shaping circuit 22, and the third transformer 23 are located in the low-potential side region 6. The high-voltage side inverter circuit 24 and the second AD converter 25 are located in the high-potential side region 7. In power transmission circuit 1A, as in power transmission circuit 1, a termination resistor R2 is provided in parallel with the primary winding 15a of the second transformer 15. Alternatively, a CR circuit, in which the termination resistor R2 and a capacitor are connected in series, may be provided in parallel with the primary winding 15a.
[0052] The second signal S2 transmitted in the second signal transmission is, for example, a digital signal of the detected output voltage values of the cathode power supply 51, the filament power supply 52, and the grid power supply 53. The frequency of the second signal S2 is greater than the frequency of the high-voltage side voltage V1, for example, 1 MHz. The second signal S2, like the first signal S1, has, for example, one period as one value. The number of bits for each value is, for example, 8 bits, and the magnitude changes between 00000000 and 11111111. The low-voltage side control circuit 12 performs an operation separate from the driving of the low-voltage side inverter circuit 13 based on the second signal S2. For example, it outputs the detected output voltage values of the cathode power supply 51, the filament power supply 52, and the grid power supply 53 to the outside via the second DA converter 21.
[0053] The configuration of the second signal transmission path 20, which performs the second signal transmission, will be explained in terms of how it differs from the first signal transmission path 9. Of the power transmission circuit 1A, the second AD converter 25, the high-voltage side control circuit 18, the high-voltage side inverter circuit 24, the first transformer 14, the third transformer 23, the second waveform shaping circuit 22, the low-voltage side control circuit 12, and the second DA converter 21 constitute the second signal transmission path 20.
[0054] The second AD converter 25 includes a first input terminal 25a, a second input terminal 25b, and a third input terminal 25c. The first input terminal 25a is connected to the second output terminal 51c of the cathode power supply 51. The second input terminal 25b is connected to the second output terminal 52c of the filament power supply 52. The third input terminal 25c is connected to the second output terminal 53c of the grid power supply 53. The second AD converter 25 converts the output voltage of the cathode power supply 51 into a digital signal and outputs the digital signal from output terminal 25d to the high-voltage side control circuit 18. The second AD converter 25 converts the output voltage of the filament power supply 52 into a digital signal and outputs the digital signal from output terminal 25d to the high-voltage side control circuit 18. The second AD converter 25 converts the output voltage of the grid power supply 53 into a digital signal and outputs the digital signal from output terminal 25d to the high-voltage side control circuit 18.
[0055] The digital signals of the output voltage of the cathode power supply 51, the output voltage of the filament power supply 52, and the output voltage of the grid power supply 53 are input to the second input terminal 18c of the high-voltage side control circuit 18. The high-voltage side control circuit 18 generates a second signal S2 by arranging each digital signal in chronological order. In other words, the high-voltage side control circuit 18 performs parallel / serial conversion of the digital signals of the output voltage of the cathode power supply 51, the output voltage of the filament power supply 52, and the output voltage of the grid power supply 53 into a second signal S2. The high-voltage side control circuit 18 outputs the second signal S2 to the high-voltage side inverter circuit 24 from the second output terminal 18d.
[0056] The input terminal of the high-voltage inverter circuit 24 is connected to the second output terminal 18d of the high-voltage control circuit 18. The output terminal of the high-voltage inverter circuit 24 is connected to the secondary winding 14b of the first transformer 14. The high-voltage control circuit 18 drives the high-voltage inverter circuit 24 at a frequency of, for example, 1 MHz to transmit the second signal S2 to the first transformer 14. A series resonant capacitor Cs2 is connected between the output terminal of the high-voltage inverter circuit 24 and the secondary winding 14b. The resonant frequency f1 of the series resonant circuit RC can be calculated including the value of the series resonant capacitor Cs2. A damping resistor may be connected between the series resonant capacitor Cs2 and the high-voltage inverter circuit 24. By connecting a damping resistor, the waveform quality of the second signal S2 can be maintained while reducing high-frequency components, thereby contributing to noise suppression.
[0057] The second signal S2 is transmitted from the secondary winding 14b to the primary winding 14a of the first transformer 14, thereby transmitting from the high-potential region 7 to the low-potential region 6. In other words, the second signal transmission is performed via the first transformer 14, which is common to both the first signal transmission and power transmission.
[0058] The secondary winding 23b of the third transformer 23 is connected to the primary winding 14a of the first transformer 14. The primary winding 23a of the third transformer 23 is connected to the input terminal of the second waveform shaping circuit 22. The second signal S2 is transmitted from the secondary winding 23b to the primary winding 23a of the third transformer 23. The third transformer 23 can suppress the formation of an unexpected common impedance between the first transformer 14 and the second waveform shaping circuit 22.
[0059] The input terminal of the second waveform shaping circuit 22 is connected to the primary winding 23a of the third transformer 23. The second waveform shaping circuit 22 improves the distortion of the second signal S2 and then transmits the second signal S2 to the low-voltage side control circuit 12. The second waveform shaping circuit 22 is, for example, a low-pass filter having a cutoff frequency higher than the signal transmission bandwidth, and removes harmonic components of the second signal S2 that do not contribute to the transmitted signal.
[0060] The second input terminal 12c of the low-voltage side control circuit 12 is connected to the output terminal of the second waveform shaping circuit 22. The low-voltage side control circuit 12 extracts the digital signals of the output voltage of the cathode power supply 51, the output voltage of the filament power supply 52, and the output voltage of the grid power supply 53 from the second signal S2 with improved distortion, and outputs them to the second DA converter 21.
[0061] The input terminal of the second DA converter 21 is connected to the second output terminal 12d of the low-voltage side control circuit 12. The second DA converter 21 converts the digital signals of the output voltage of the cathode power supply 51, the filament power supply 52, and the grid power supply 53 into analog signals and outputs them to the outside of the high-voltage power supply 10A. The output of the second DA converter 21 fluctuates depending on the magnitude of the digital signals of the output voltage of the cathode power supply 51, the filament power supply 52, and the grid power supply 53. For this reason, the low-voltage side control circuit 12 can be considered to be controlling the output of the second DA converter 21 by the second signal S2.
[0062] Figure 7 shows an example of a transmission waveform transmitted in power transmission circuit 1A. In power transmission circuit 1A, a second transmission waveform D2 is transmitted from the low-voltage side control circuit 12 to the high-voltage side control circuit 18. The second transmission waveform D2 includes a second period T2 followed by a fourth period T4. While the low-voltage side control circuit 12 transmits the second transmission waveform D2 to the high-voltage side control circuit 18, it does not perform power transmission or signal transmission during the fourth period T4. In power transmission circuit 1A, a third transmission waveform D3 is transmitted from the high-voltage side control circuit 18 to the low-voltage side control circuit 12. The third transmission waveform D3 is included in the fourth period T4. The low-voltage side control circuit 12 transmits the second transmission waveform D2 to the high-voltage side control circuit 18, thereby performing power transmission in the first period T1, power consumption in the third period T3, and the first signal transmission in the second period T2, in the order of the first period T1, the third period T3, and the second period T2. Subsequently, the high-voltage side control circuit 18 transmits the third transmission waveform D3 to the low-voltage side control circuit 12, thereby performing the second signal transmission in the fourth period T4. As a result, in the power transmission circuit 1A, power transmission in the first period T1, power consumption in the third period T3, the first signal transmission in the second period T2, and the second signal transmission in the fourth period T4 are repeatedly performed in the order of the first period T1, the third period T3, the second period T2, and the fourth period T4.
[0063] In the power transmission circuit 1A, the low-voltage side control circuit 12 and the high-voltage side control circuit 18 may switch between the first mode and the second mode in response to an external input. In the first mode, the low-voltage side control circuit 12 and the high-voltage side control circuit 18 repeatedly perform power transmission in the first period T1, power consumption in the third period T3, the first signal transmission in the second period T2, and the second signal transmission in the fourth period T4, in the order of the first period T1, the third period T3, the second period T2, and the fourth period. In the second mode, under normal circumstances, the low-voltage side control circuit 12 repeatedly performs only power transmission in the first period T1. At predetermined timings, the low-voltage control circuit 12 and the high-voltage control circuit 18 perform power transmission, power consumption, first signal transmission, and second signal transmission only once during a single transmission, in the order of the first period T1, the third period T3, the second period T2, and the fourth period T4.
[0064] In the power transmission circuit 1A described above, the second signal S2 is transmitted from the high-potential region 7 to the low-potential region 6 by transmitting the second signal S2 via the first transformer 14, which is common to both power transmission and the first signal transmission. This enables bidirectional signal transmission between the low-potential region 6 and the high-potential region 7, in conjunction with the first signal transmission. Furthermore, since the second signal S2 is transmitted during the fourth period T4, it is transmitted in a temporally separated state from the high-voltage side voltage V1 and the first signal S1. As a result, even in the insulating oil and insulating resin, the low-voltage side control circuit 12 can accurately receive the second signal S2 in the low-potential region 6. [Second variation, third variation]
[0065] Figure 8(a) is a block diagram of the power transmission circuit 1B according to the second modified example. Note that in Figure 8, the power supplies 51-53, the X-ray tube XL, the high-voltage generation circuit 3, and the detection circuit 4 are omitted from the description. Terminals to which voltage is input from the outside are shown as VoltageInput, and terminals to which voltage is output to the outside are shown as VoltageOutput. Power transmission circuit 1B differs from power transmission circuit 1 in that it includes a first low-voltage side inverter circuit 13A and a second low-voltage side inverter circuit 13B instead of the low-voltage side inverter circuit 13. In power transmission circuit 1, a common low-voltage side inverter circuit 13 is driven in power transmission and the first signal transmission. In contrast, in power transmission circuit 1B, the first low-voltage side inverter circuit 13A is driven at, for example, 100kHz in power transmission. In the first signal transmission, the second low-voltage inverter circuit 13B is driven at a frequency higher than the driving frequency of the first low-voltage inverter circuit 13A, for example, 1 MHz. In the example of Figure 8(a), a damping resistor R3 is provided between the output terminal of the second low-voltage inverter circuit 13B and the primary winding 14a of the first transformer 14. The damping resistor R3 suppresses the oscillation of the first signal S1. Figure 8(b) is a block diagram of a power transmission circuit 1C according to a third modified example. The power transmission circuit 1C differs from the power transmission circuit 1A only in that it includes a first low-voltage inverter circuit 13A and a second low-voltage inverter circuit 13B instead of the low-voltage inverter circuit 13. In the power transmission circuit 1C, the first low-voltage inverter circuit 13A is driven at, for example, 100 kHz during power transmission. In the second signal transmission, the second low-voltage inverter circuit 13B is driven at a frequency higher than the driving frequency of the first low-voltage inverter circuit 13A, for example, 1 MHz. In the power transmission circuits 1B and 1C, as with power transmission circuit 1, a termination resistor R2 may be provided in parallel with the primary winding of the second transformer 15. Alternatively, a CR circuit, in which the termination resistor R2 and a capacitor are connected in series, may be provided in parallel with the primary winding of the second transformer 15. Also, in power transmission circuit 1C, as with power transmission circuit 1A, a damping resistor may be connected between the series resonant capacitor Cs2 and the high-voltage inverter circuit 24. [Fourth variation]
[0066] In the power transmission circuits of the embodiments and modifications described above, in addition to the first signal transmission path 9 and the second signal transmission path 20, a new signal transmission path may be added. Figure 9 is a block diagram of the power transmission circuit 1D according to the fourth modification. The power transmission circuit 1D differs from the power transmission circuit 1A only in that it includes a third signal transmission path 30 and a fourth signal transmission path 40.
[0067] The third signal transmission path 30 comprises a second low-voltage side control circuit 26, a light-emitting element 27, an optical fiber 28, a photodiode (photodetector) 29, a PD drive circuit 44, and an amplifier 34. The second low-voltage side control circuit 26 and the light-emitting element 27 are located in the low-potential side region 6. The photodiode 29, PD drive circuit 44, and amplifier 34 are located in the high-potential side region 7.
[0068] In the power transmission circuit 1D, the second transformer 15 defines a second high-potential region 71, which is a floating region, and a third high-potential region 72, which has the second reference potential G2 as its reference potential, within the high-potential region 7.
[0069] The input terminal of the second low-voltage control circuit 26 is connected to the output terminal of the AD converter 11. The second low-voltage control circuit 26 generates the first signal S1 separately from the low-voltage control circuit 12. The light-emitting element 27 is connected to the output terminal of the second low-voltage control circuit 26. The light-emitting element 27 converts the first signal S1 into light energy. The input terminal of the optical fiber 28 is optically coupled to the light-emitting element 27. The optical fiber 28 is arranged in parallel with the first transformer 14 and is positioned to connect the low-potential region 6 and the high-potential region 7. The first signal S1, converted into light energy, is transmitted from the low-potential region 6 to the high-potential region 7 by the optical fiber 28.
[0070] The photodiode 29 is optically coupled to the output terminal of the optical fiber 28 in the second high-potential region 71. The first signal S1 transmitted by the optical fiber 28 is photoelectrically converted by the photodiode 29 in the third high-potential region 72. The PD drive circuit 44 transmits the first signal S1, which has been photoelectrically converted by the photodiode 29, to the amplifier 34.
[0071] The amplifier 34 includes a pair of input terminals 34a and 34b and an output terminal 34c. One input terminal 34a is connected to the photodiode 29 via the PD drive circuit 44. The other input terminal 34b is connected to the second reference potential G2. The output terminal 34c is connected to the high-voltage side control circuit 18. The amplifier 34 amplifies the first signal S1 and outputs the first signal S1 to the high-voltage side control circuit 18. Through this third signal transmission path 30, the first signal S1 is transmitted from the second low-voltage side control circuit 26 to the high-voltage side control circuit 18.
[0072] The fourth signal transmission path 40 comprises a second low-voltage side control circuit 26, a photodiode 35, an optical fiber 36, a light-emitting element 37, an LED driving circuit 38, and an amplifier 39. The second low-voltage side control circuit 26 and the photodiode 35 are located in the low-potential side region 6. The light-emitting element 37, the LED driving circuit 38, and the amplifier 39 are located in the high-potential side region 7.
[0073] One input terminal 39a of the amplifier 39 is connected to the high-voltage side control circuit 18. The other input terminal 39b is connected to the second reference potential G2. The output terminal 39c is connected to the light-emitting element 37 via the LED driving circuit 38. The amplifier 39 amplifies the second signal S2 and outputs the second signal S2 to the light-emitting element 37 via the LED driving circuit 38. The light-emitting element 37 is optically coupled to the input end of the optical fiber 36 in the third high-potential side region 72. The output end of the optical fiber 36 is optically coupled to the photodiode 35 in the low-potential side region 6. The photodiode 35 is connected to the second low-voltage side control circuit 26. The second signal S2 converted into light energy in the light-emitting element 37 is transmitted by the optical fiber 36 from the high-potential side region 7 to the low-potential side region 6. The second signal S2 transmitted by the optical fiber 36 is photoelectrically converted by the photodiode 35 and output to the second low-voltage side control circuit 26. Through the fourth signal transmission path 40 described above, the second signal S2 is transmitted from the high-voltage side control circuit 18 to the second low-voltage side control circuit 26.
[0074] In the power transmission circuit 1D described above, the first signal S1 generated by the second low-voltage side control circuit 26 is converted by light-emitting element 37 and transmitted from the low-potential side region 6 to the high-potential side region 7 via optical fiber 36. The transmitted first signal S1 is photoelectrically converted by a photodetector in the high-potential side region 7, amplified by amplifier 34, and output to the high-voltage side control circuit 18. The other input terminal 34b of amplifier 34 is connected to the second reference potential G2, and the output terminal 34c is connected to the high-voltage side control circuit 18. The reference potential of the high-voltage side control circuit 18 is the same as the second reference potential G2. As a result, amplifier 34 can transmit the first signal S1 within the third high-potential side region 72, which uses the second reference potential G2 as its reference potential. With this configuration, by securing a signal transmission route separate from the first transformer 14 and the second transformer 15, it is possible to address situations where the transmission amount is insufficient with only the first signal transmission. In addition, in the power transmission circuit 1D, a damping resistor may be connected between the series resonant capacitor Cs2 and the high-voltage side inverter circuit 24, similar to the power transmission circuit 1A. [Fifth variation]
[0075] The third signal transmission path 30 and the fourth signal transmission path 40 described in the fourth modified example may be applied to other circuits. Figure 10 is a block diagram of a power transmission circuit 1E according to the fifth modified example. In addition to the third signal transmission path 30 and the fourth signal transmission path 40, the power transmission circuit 1E includes a low-voltage side control circuit 12, a low-voltage side inverter circuit 13, a first transformer 14, a rectifier circuit 16A, an isolated DC-DC converter 50 (first DC converter), a non-isolated DC-DC module 42 (second DC converter), and a second high-voltage side control circuit 43. The power transmission circuit 1E includes an isolated DC-DC converter 50 instead of the second transformer 15. The isolated DC-DC converter 50 includes an input terminal 50a and an output terminal 50b, and the input terminal 50a and the output terminal 50b are isolated from each other. The rectifier circuit 16A is provided between the secondary winding 14b of the first transformer 14 and the input terminal 50a of the isolated DC-DC converter 50. In the power transmission circuit 1E, amplifier 34 is an isolated amplifier in which the input terminals 34a, 34b and the output terminal 34c are isolated. Similarly, amplifier 39 is an isolated amplifier in which the input terminals 39a, 39b and the output terminal 39c are isolated.
[0076] In the power transmission circuit 1E, for example, the high-voltage side voltage V1 may be rectified in the rectifier circuit 16A, and after the magnitude of the DC voltage is converted in the isolated DC-DC converter 50, it may be used as the power supply voltage for the non-isolated DC-DC module 42. The power supply voltage for amplifier 34 may be supplied from Vcc generated by the rectifier circuit 16A. The power supply voltage for amplifier 39 may be supplied from the output terminal 50b of the isolated DC-DC converter 50.
[0077] The isolated DC-DC converter 50 separates the second reference potential G2 into a third reference potential G21 and a fourth reference potential G22 in the high-potential region 7. The input terminal 50a of the isolated DC-DC converter 50 is connected to the third reference potential G21. The output terminal 50b of the isolated DC-DC converter 50 is connected to the first input terminal 42a of the non-isolated DC-DC module 42. The output terminal 50b of the isolated DC-DC converter 50 is connected to the fourth reference potential G22.
[0078] In the power transmission circuit 1E, the low-voltage side control circuit 12, the low-voltage side inverter circuit 13, the first transformer 14, the rectifier circuit 16A, the isolated DC-DC converter 50, and the non-isolated DC-DC module 42 constitute the first signal transmission path 9. The non-isolated DC-DC module 42 is located in the third high-potential side region 72. The non-isolated DC-DC module 42 receives the first signal S1 from the isolated DC-DC converter 50. The non-isolated DC-DC module 42 supplies the output voltage it generates internally to the X-ray tube XL. In the example of Figure 10, surge absorbers Z are provided between each terminal of the non-isolated DC-DC module 42 and between each terminal and the fourth reference potential G22. The surge absorbers Z improve the surge withstand voltage of the non-isolated DC-DC module 42, for example.
[0079] Of the power transmission circuit 1E, the low-voltage side control circuit 12, the low-voltage side inverter circuit 13, the first transformer 14, and the second high-voltage side control circuit 43 constitute a fifth signal transmission path 60. The second high-voltage side control circuit 43 is located in the second high-potential side region 71. The first terminal 43a of the second high-voltage side control circuit 43 is connected to the secondary winding 14b of the first transformer 14. The second terminal 43b of the second high-voltage side control circuit 43 is connected to the PD drive circuit 44 and the LED drive circuit 38. The second high-voltage side control circuit 43 may, for example, supply the power supply voltage to the PD drive circuit 44 and the LED drive circuit 38. Although not shown in Figure 10, in the fifth signal transmission path 60, for example, the second high-voltage side control circuit 43 may transmit a signal from the low-voltage side control circuit 12 to the second high-voltage side control circuit 43 for calibrating the amplifiers 34 and 39. Alternatively, in the fifth signal transmission path 60, the second high-voltage side control circuit 43 may detect the fault condition of the amplifiers 34 and 39 and transmit the detected signal to the low-voltage side control circuit 12.
[0080] In the power transmission circuit 1E, amplifiers 34 and 39 are arranged to straddle the second high-potential region 71 and the third high-potential region 72. The output terminal 34c of amplifier 34 is connected to the second input terminal 42b of the non-isolated DC-DC module 42 in the third high-potential region 72. One input terminal 39a of amplifier 39 is connected to the output terminal 42c of the non-isolated DC-DC module 42 in the third high-potential region 72. The other input terminal 39b of amplifier 39 is connected to the fourth reference potential G22.
[0081] Amplifier 34 transmits the first signal S1 transmitted by the third signal transmission path 30 from the second high-potential region 71 to the third high-potential region 72. The first signal S1 generated by the second low-voltage control circuit 26 is transmitted by the optical fiber 28 from the low-potential region 6 to the second high-potential region 71. The first signal S1 is photoelectrically converted by the photodiode 29 in the second high-potential region 71. PD drive circuit 44 transmits the first signal S1, which has been photoelectrically converted by the photodiode 29, to amplifier 34. Amplifier 34 transmits the first signal S1 from the second high-potential region 71 to the third high-potential region 72 and outputs it to the non-isolated DC-DC module 42.
[0082] The amplifier 39 transmits the second signal S2 input from the non-isolated DC-DC module 42 from the third high-potential region 72 to the second high-potential region 71. The second signal S2 is transmitted from the second high-potential region 71 to the low-potential region 6 via the optical fiber 36. The second signal S2 is photoelectrically converted by the photodiode 35 and output to the second low-voltage control circuit 26.
[0083] In this modified power transmission circuit 1E, power is transmitted from the low-potential region 6 to the high-potential region 7 by transmitting the voltage generated by the low-voltage side inverter circuit 13 as the high-voltage side voltage V1 via the first transformer 14. In addition, the first signal S1 is transmitted from the low-potential region 6 to the high-potential region 7 by transmitting the first signal S1 via the first transformer 14 which is also used for power transmission. Power transmission takes place during the first period T1, and the first signal transmission takes place during the second period T2. As a result, there is no need to provide a filter to separate the high-voltage side voltage V1 and the first signal S1, so that the second high-voltage side control circuit 43 can accurately receive the first signal S1 in the high-potential region 7 even in insulating oil and insulating resin.
[0084] The power transmission circuit according to the present invention is not limited to the embodiments and variations described above, but is shown in the claims and is intended to include all modifications in the sense and scope equivalent to the claims.
[0085] In the above embodiment, a waveform shaping circuit 17 is connected between the second secondary winding 15c and the high-voltage side control circuit 18, but the waveform shaping circuit 17 can be omitted if necessary. Furthermore, although the above embodiment illustrates the case where the first transformer 14 is a loosely coupled transformer, the first transformer 14 may be an isolation transformer other than a loosely coupled transformer. [Explanation of symbols]
[0086] 1, 1A, 1B, 1C, 1D, 1E…Power transmission circuit, 12…Low voltage side control circuit, 13…Low voltage side inverter circuit, 14…First transformer, 15…Second transformer, 14a…Primary winding of the first transformer (low voltage side winding), 14b…Secondary winding of the first transformer (high voltage side winding), 15a…Primary winding of the second transformer, 15b…First secondary winding of the second transformer, 15c…Second secondary winding of the second transformer, 16, 16A…Rectifier circuit, 17…Waveform shaping circuit, 18…High voltage side control circuit, 24…High voltage side inverter circuit, 27, 37…Light-emitting element Child, 28, 36... Optical fiber, 29... Photodiode (photodetector), 34, 39... Amplifier, 42... Non-isolated DCDC module (second DC converter), 50... Isolated DCDC converter (first DC converter), 6... Low potential side region (low potential side), 7... High potential side region (high potential side), G1... First reference potential, G2... Second reference potential, G21... Third reference potential, G22... Fourth reference potential, S1... First signal, S2... Second signal, T1... First period, T2... Second period, T4... Fourth period (third period), V1... High voltage side voltage.
Claims
1. A power transmission circuit connected to a circuit that boosts the voltage from a low potential to a high potential, A first transformer, which is an isolation transformer, includes a low-voltage side winding, which is a primary winding connected to the low-potential side, and a high-voltage side winding, which is a secondary winding connected to the high-potential side. A low-voltage side inverter circuit, the output terminal of which is connected to the low-voltage side winding, A low-voltage control circuit is connected to the input terminal of the low-voltage inverter circuit and drives the low-voltage inverter circuit, A second transformer comprising a primary winding, a first secondary winding, and a second secondary winding, wherein the primary winding is connected to the high-voltage side winding, A rectifier circuit connected to the first secondary winding, A high-voltage side control circuit connected to the second secondary winding and operating based on the first signal, Equipped with, The low-voltage control circuit drives the low-voltage inverter circuit to generate a high-voltage voltage, which is then transmitted to the rectifier circuit via the first transformer and the second transformer in a power transmission operation that is performed during a first period. A power transmission circuit that performs a first signal transmission, in which the first signal generated by the low-voltage side control circuit driving the low-voltage side inverter circuit is transmitted to the high-voltage side control circuit via the first transformer and the second transformer, during a second period separate from the first period.
2. The power transmission circuit according to claim 1, wherein a waveform shaping circuit for improving distortion of the first signal is connected between the second secondary winding and the high-voltage side control circuit.
3. The high-voltage inverter circuit further comprises an output terminal connected between the high-voltage side winding of the first transformer and the primary winding of the second transformer, and an input terminal connected to the high-voltage side control circuit. The low-voltage side control circuit performs an operation separate from the driving of the low-voltage side inverter circuit based on a second signal. The power transmission circuit according to claim 1 or 2, wherein the second signal transmission, in which the high-voltage side control circuit drives the high-voltage side inverter circuit to generate the second signal, is transmitted to the low-voltage side control circuit via the first transformer, is performed in a third period separate from the first period and the second period.
4. The power transmission circuit according to claim 1 or 2, wherein the first transformer is a loosely coupled transformer.
5. A second low-voltage side control circuit is provided on the low-potential side and generates the first signal separately from the low-voltage side control circuit, A light-emitting element connected to the second low-voltage control circuit, An optical fiber, which includes an input terminal optically coupled to the light-emitting element and is arranged to connect the low-potential side and the high-potential side, The output end of the optical fiber and the photodetector optically coupled at the high-potential side, The power transmission circuit according to claim 1 or 2, further comprising: an amplifier including an output terminal connected to the high-voltage side control circuit and a pair of input terminals, wherein one input terminal of the pair of input terminals is connected to the photodetector element and the other input terminal of the pair of input terminals is connected to the high-potential side reference potential.
6. A power transmission circuit connected to a circuit that boosts the voltage from a low potential to a high potential, A first transformer, which is an isolation transformer, includes a low-voltage side winding, which is a primary winding connected to the low-potential side, and a high-voltage side winding, which is a secondary winding connected to the high-potential side. A low-voltage side inverter circuit, the output terminal of which is connected to the low-voltage side winding, A low-voltage control circuit is connected to the input terminal of the low-voltage inverter circuit and drives the low-voltage inverter circuit, A rectifier circuit connected to the aforementioned high-voltage side winding, A first DC converter, which includes an input terminal and an output terminal, the input terminal of which is connected to the rectifier circuit, A second DC converter connected to the output terminal and operating based on the first signal, Equipped with, The low-voltage control circuit drives the low-voltage inverter circuit to generate a high-voltage voltage, which is then transmitted to the second DC converter via the first transformer, the rectifier circuit, and the first DC converter during a first period of power transmission. A power transmission circuit that performs a first signal transmission, in which the first signal generated by the low-voltage side control circuit driving the low-voltage side inverter circuit is transmitted to the second DC converter via the first transformer, the rectifier circuit, and the first DC converter, during a second period separate from the first period.