WO2023016523A1 - 协同脉冲发生装置、设备及发生方法 - Google Patents
协同脉冲发生装置、设备及发生方法 Download PDFInfo
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- H—ELECTRICITY
- H03—ELECTRONIC CIRCUITRY
- H03K—PULSE TECHNIQUE
- H03K3/00—Circuits for generating electric pulses; Monostable, bistable or multistable circuits
- H03K3/02—Generators characterised by the type of circuit or by the means used for producing pulses
- H03K3/53—Generators characterised by the type of circuit or by the means used for producing pulses by the use of an energy-accumulating element discharged through the load by a switching device controlled by an external signal and not incorporating positive feedback
- H03K3/57—Generators characterised by the type of circuit or by the means used for producing pulses by the use of an energy-accumulating element discharged through the load by a switching device controlled by an external signal and not incorporating positive feedback the switching device being a semiconductor device
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B18/00—Surgical instruments, devices or methods for transferring non-mechanical forms of energy to or from the body
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B18/00—Surgical instruments, devices or methods for transferring non-mechanical forms of energy to or from the body
- A61B18/04—Surgical instruments, devices or methods for transferring non-mechanical forms of energy to or from the body by heating
- A61B18/12—Surgical instruments, devices or methods for transferring non-mechanical forms of energy to or from the body by heating by passing a current through the tissue to be heated, e.g. high-frequency current
- A61B18/1206—Generators therefor
-
- H—ELECTRICITY
- H03—ELECTRONIC CIRCUITRY
- H03K—PULSE TECHNIQUE
- H03K3/00—Circuits for generating electric pulses; Monostable, bistable or multistable circuits
- H03K3/01—Details
- H03K3/017—Adjustment of width or dutycycle of pulses
-
- H—ELECTRICITY
- H03—ELECTRONIC CIRCUITRY
- H03K—PULSE TECHNIQUE
- H03K5/00—Manipulating of pulses not covered by one of the other main groups of this subclass
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04B—TRANSMISSION
- H04B10/00—Transmission systems employing electromagnetic waves other than radio-waves, e.g. infrared, visible or ultraviolet light, or employing corpuscular radiation, e.g. quantum communication
- H04B10/25—Arrangements specific to fibre transmission
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- H—ELECTRICITY
- H05—ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
- H05K—PRINTED CIRCUITS; CASINGS OR CONSTRUCTIONAL DETAILS OF ELECTRIC APPARATUS; MANUFACTURE OF ASSEMBLAGES OF ELECTRICAL COMPONENTS
- H05K9/00—Screening of apparatus or components against electric or magnetic fields
- H05K9/0007—Casings
- H05K9/002—Casings with localised screening
- H05K9/0022—Casings with localised screening of components mounted on printed circuit boards [PCB]
- H05K9/0024—Shield cases mounted on a PCB, e.g. cans or caps or conformal shields
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- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B18/00—Surgical instruments, devices or methods for transferring non-mechanical forms of energy to or from the body
- A61B2018/00571—Surgical instruments, devices or methods for transferring non-mechanical forms of energy to or from the body for achieving a particular surgical effect
- A61B2018/00577—Ablation
Definitions
- the present application relates to pulse generation and medical device technology, in particular, the present application relates to a cooperative pulse generation device, equipment and generation method.
- Pulse power technology is an electrophysical technology that quickly compresses, converts, or directly releases energy with a relatively high density that is stored slowly to the load.
- pulse power technology continues to expand to the fields of medical treatment, environmental science, plasma science, food processing, electromagnetic compatibility testing and bioengineering, the requirements for pulse generators are also constantly changing.
- the existing pulse generating device has a relatively complex structure and can only generate pulse signals of a specific width, which cannot meet the complex application requirements of pulse technology.
- the present application aims to solve at least one aspect of the above-mentioned technical problems to a certain extent, and proposes a cooperative pulse generating device, equipment and method for generating pulses with different width ranges and forming more pulse combinations.
- the embodiment of the present application provides a coordinated pulse generating device, which is used to generate a pulse signal under the control of a host computer, and the coordinated pulse generating device includes:
- a drive circuit electrically connected to the host computer, and configured to receive the first control signal sent by the host computer and convert the first control signal into a first drive signal, and receive the second control signal sent by the host computer signal and converting the second control signal into a second drive signal;
- a pulse generating circuit including a first power supply, a first pulse generating module electrically connected to the first power supply, a second power supply, and a second pulse generating module electrically connected to the second power supply;
- the first pulse generating module is configured to store the electric energy provided by the first power supply, and discharge it under the control of the first driving signal to form a first pulse signal applied to the load;
- the second pulse generating module is configured to store the electric energy provided by the second power supply, and discharge it under the control of the second driving signal to form a second pulse signal applied to the load;
- the voltage of the second power supply is greater than the voltage of the first power supply, and the width of the second pulse is smaller than the width of the first pulse.
- the embodiment of the present application provides a coordinated pulse generating device, and the coordinated pulse generating device includes:
- a host computer configured to generate the control signal according to an input instruction
- a coordinated pulse generating device according to the first aspect of the present application.
- the embodiment of the present application provides a coordinated pulse generation method, which is used in the coordinated pulse generation device according to the first aspect of the present application, including:
- the first pulse generating module stores the electric energy provided by the first power supply
- the second pulse generating module stores the electric energy provided by the second power supply
- the drive circuit receives the first control signal sent by the host computer and converts the first control signal into a first drive signal, and the drive circuit receives the second control signal sent by the host computer and converts the two control signals into a second drive signal ;as well as
- the first pulse generating module receives the first driving signal and discharges under the control of the first driving signal to form a first pulse signal applied to the load, and the second pulse generating module receives the second driving signal discharging under the control of the second driving signal to form a second pulse signal applied to the load;
- the voltage of the second power supply is greater than the voltage of the first power supply, and the width of the second pulse signal is smaller than the width of the first pulse signal.
- the cooperative pulse generation device, equipment and generation method provided in the embodiments of the present application convert the first control signal and the second control signal sent by the host computer into the first driving signal and the second driving signal respectively through the driving circuit, and the pulse generating circuit according to
- the first driving signal and the second driving signal can selectively form the first pulse signal and/or the second pulse signal with different widths, so as to achieve the purpose of applying the composite pulse signal to the load.
- the composite The function of the pulse is beneficial to improve the ablation effect on tumor cells.
- Fig. 1 is a schematic diagram of the connection between a cooperative pulse generating device provided by an embodiment of the present application, an upper computer and a load;
- FIG. 2 is a schematic structural diagram of another pulse generating circuit in the coordinated pulse generating device provided in the embodiment of the present application;
- Fig. 3 is a schematic diagram of contact between an output module and a load provided by the embodiment of the present application.
- FIG. 4 is a schematic structural diagram of another pulse generating circuit in the coordinated pulse generating device provided in the embodiment of the present application.
- FIG. 5 is a schematic structural diagram of another pulse generating circuit in the coordinated pulse generating device provided in the embodiment of the present application.
- Fig. 6 is the current schematic diagram of the pulse generating circuit shown in Fig. 5 in the charging state
- Fig. 7 is the current schematic diagram of the pulse generating circuit shown in Fig. 5 in the discharge state
- FIG. 8 is a schematic structural diagram of the driving circuit in the coordinated pulse generating device provided by the embodiment of the present application.
- Fig. 9 is a schematic diagram of the distribution of a cooperative pulse generating device provided on a circuit board in the embodiment of the present application.
- Figure 10 is a schematic diagram of the distribution of another coordinated pulse generating device on a circuit board provided by the embodiment of the present application.
- Fig. 11 is a schematic structural diagram of a cooperative pulse generating device with a shielding structure provided in an embodiment of the present application
- Fig. 12 is a schematic diagram of a pulse signal generated before no shielding structure is set in the prior art
- FIG. 13 is a schematic diagram of a pulse signal generated after setting the shielding structure provided by the embodiment of the present application.
- FIG. 14 is a schematic flowchart of a method for generating a coordinated pulse provided in an embodiment of the present application.
- FIG. 15 is a schematic flowchart of step S2 in the method for generating coordinated pulses provided by the embodiment of the present application;
- FIG. 16 is a schematic flow chart of step S3 in the method for generating coordinated pulses provided by the embodiment of the present application.
- FIG. 17 is a schematic structural diagram of a driving circuit provided by an embodiment of the present application.
- FIG. 18 is a schematic structural diagram of another driving circuit provided by an embodiment of the present application.
- the inventors of the present application found that when electroablation technology is used to ablate tumor cells, multiple pulses with different pulse widths are used in combination, and in some cases better ablation effects can be achieved than a single pulse. For example, when microsecond pulses act on tumor cells, although they have a larger ablation area, the ablation rate for tumor cells, especially malignant tumor cells with high distortion is low; when nanosecond pulses act on tumor cells, although there is Higher ablation rate, but smaller ablation area. The combined use of microsecond pulses and nanosecond pulses can significantly improve the ablation effect of tumor cells.
- microsecond or millisecond pulses during the duration of nanosecond pulse-induced irreversible electroporation to utilize cell membrane perforation.
- the electric field of microsecond or millisecond pulses penetrates into the cell interior and further induces apoptosis. Achieve better ablation than nanosecond, microsecond or millisecond pulses alone.
- the coordinated pulse generation device, equipment and generation method provided by the present application aim to solve at least one aspect of the above technical problems to a certain extent.
- the embodiment of the present application provides a coordinated pulse generating device, which can be used to generate pulse signals according to control signals under the control of the host computer 1.
- the signal output by the coordinated pulse generating device is also called coordinated pulse or compound pulse.
- the coordinated pulse generating device provided in this embodiment includes a driving circuit 2 and a pulse generating circuit 3 electrically connected to the driving circuit 2 , and the driving circuit 2 is electrically connected to the host computer 1 .
- the drive circuit 2 is electrically connected to the host computer 1, and is configured to receive the first control signal sent by the host computer 1 and convert the first control signal into a first drive signal, receive the second control signal sent by the host computer 1 and convert the first control signal The second control signal is converted into a second driving signal.
- the pulse generation circuit 3 includes a first power supply, a first pulse generation module 31 electrically connected to the first power supply, a second power supply and a second pulse generation module 32 electrically connected to the second power supply;
- the first pulse generation module 31 is configured as The electric energy provided by the first power supply is stored, and discharged under the control of the first driving signal to form the first pulse signal applied to the load 4;
- the second pulse generating module 32 is configured to perform the electric energy provided by the second power supply stored, and discharged under the control of the second drive signal to form a second pulse signal applied to the load 4 .
- the voltage of the second power supply is greater than the voltage of the first power supply
- the width of the second pulse is smaller than the width of the first pulse
- the time when the second pulse generating module 32 receives the second driving signal is the same as that of the first pulse generating module 31 The timing of receiving the first driving signal is different.
- the time when the second pulse generating module 32 receives the second driving signal is different from the time when the first pulse generating module 31 receives the first driving signal, which means that when the second pulse generating module 32 receives the second driving signal, The first pulse generating module 31 will not receive the first driving signal, and when the first pulse generating module 31 receives the first driving signal, the second pulse generating module 32 will not receive the second driving signal, that is, the first pulse signal and the second pulse signal will not be formed at the same time, so as to avoid mutual interference between the first pulse signal and the second pulse signal.
- the cooperative pulse generating device converts the first control signal and the second control signal sent by the host computer 1 into the first driving signal and the second driving signal respectively through the driving circuit 2, and the pulse generating circuit 3 converts the first driving signal and the second driving signal according to the first driving
- the signal and the second driving signal can selectively form the first pulse signal and/or the second pulse signal with different widths, so as to realize the purpose of applying the composite pulse signal to the load 4 .
- the load 4 as an example of tumor cells
- the effect of the compound pulse is beneficial to improve the ablation effect on tumor cells.
- the first pulse signal can be set as a microsecond pulse signal or a millisecond pulse signal
- the second pulse signal can be set as a nanosecond pulse signal.
- the pulse generating circuit 3 includes a first leakage module 5 and a second leakage module 6 .
- the first leakage module 5 is electrically connected to the first pulse generation module 31 and the ground respectively, and is configured to connect the first pulse generation module 31 to the ground under the control of the first leakage signal so as to connect the first pulse generation module 31 to the ground. 31 to discharge the residual power.
- the second leakage module 6 is electrically connected to the second pulse generation module 32 and the ground respectively, and is configured to connect the second pulse generation module 32 to the ground under the control of the second leakage signal so as to connect the second pulse generation module 32 to the ground. 32 to discharge the residual electricity.
- the first leakage module 5 is a first relay
- the second leakage module 6 is a second relay
- the first relay is turned on when receiving the first leakage signal , so that the first pulse generating module 31 is connected to the ground, so that the residual electricity in the first pulse generating module 31 can be released to the ground.
- the residual electricity in the second pulse generating module 32 can also be released to the ground.
- the first leakage signal and the second leakage signal may be that the relay is manually touched to be turned on, or the relay may be turned on through an electrical signal or the like.
- the leakage module may also use other devices capable of functioning as switches, such as transistors, key-type switches, and the like.
- the discharge operation is usually carried out when the cooperative pulse generating device stops working, so as to prevent the residual power in the cooperative pulse generating circuit 3 from causing adverse reactions when the power is turned on next time, and it can also avoid the failure of the cooperative pulse generating circuit. 3 cause electric shock during shutdown.
- the coordinated pulse generating device can also perform a power leakage operation when starting up, so as to further avoid adverse reactions caused by the residual electricity in the same pulse generator when starting up.
- the pulse generating circuit 3 further includes an output module 7, and the output module 7 is connected to the first pulse generating module 31 and the second pulse generating module 32 respectively. electrically connected, and configured to apply the first pulse signal and/or the second pulse signal to the load 4 under the control of the trigger instruction.
- the load 4 can be a certain position of a living body, such as a cancerous position of a cancer patient, or an external tissue, Organs, cell groups, etc.
- the output module 7 is used to control the application of the first pulse signal and/or the second pulse signal to the load 4, thereby realizing the controllability of the pulse acting on the load 4 and improving the pulse effect .
- the output module 7 includes a trigger unit 71 and at least a pair of electrodes 72 electrically connected to the trigger unit 71, and the trigger unit 71 is respectively connected to the first pulse
- the generating module 31 is electrically connected to the second pulse generating module 32, and the electrode 72 is used to contact the load 4; the trigger unit 71 is configured to be turned on when triggered by a trigger instruction so that the first pulse signal and/or the second pulse signal are transmitted to Electrode 72.
- the output module 7 further includes a trigger switch 73, and the trigger switch 73 is associated with the trigger unit 71.
- the trigger switch 73 can be a foot switch
- the trigger unit 71 can be a relay.
- the trigger action is a trigger command, so that the trigger unit 71 (that is, the relay) is activated by the The trigger command is triggered to be turned on, so that the first pulse signal and/or the second pulse signal are output to the electrode 72 to act on the load 4 in contact with the electrode 72 .
- the output module 7 further includes a multiplexing unit 74, which can convert one signal into multiple signals, and each pair of electrodes 72 needs two identical signals.
- the multi-channel signal conversion unit 74 can be set to be expandable. For example, under certain conditions of use, a pair of electrodes 72 can be used, but in other cases, 4, 6 or even more conversion units 74 can be used to It can meet the signal requirements of multiple pairs of electrodes 72 when needed.
- the pulse generating circuit 3 further includes a resistor 8 and a monitoring module 9, and the resistor 8 is connected to the first pulse generating module 31 and the second pulse generating module 9 respectively.
- the module 32 is electrically connected to the ground, and the first pulse signal and/or the second pulse signal are also applied to the resistor 8;
- the monitoring module 9 includes a first monitoring unit 91 and a second monitoring unit 92, and the first monitoring unit 91 is configured to monitor the second The current output by the first pulse signal and/or the second pulse signal is monitored; the second monitoring unit 92 is configured to monitor the voltage applied to the resistor 8 by the first pulse signal and/or the second pulse signal.
- only one of the monitoring units may be used to monitor one of the output voltage or current of the coordinated pulse signal.
- only the first monitoring unit 91 is used, and at this time the first monitoring unit 91 can be configured as a voltage sensor or a current sensor.
- the first monitoring unit 91 is electrically connected to the first pulse generating module 31 and the second pulse generating module 32 respectively, and the second monitoring unit 92 is also connected to the first pulse generating module 31 and the second pulse generating module 31 respectively.
- the generating module 32 is electrically connected. Since the branch circuit where the resistor 8 is located and the branch circuit where the load 4 is located are connected in parallel, the resistor 8 and the load 4 receive the same pulse signal at the same time, and the monitoring module 9 applies the first pulse signal and/or the second pulse signal to The monitoring of the voltage of the resistor 8 and the monitoring of the output current of the first pulse signal and/or the second pulse signal are also performed synchronously.
- the first monitoring unit 91 includes a first Pearson coil
- the second monitoring unit 92 includes a second Pearson coil
- the first Pearson coil is configured to monitor the first pulse signal and/or The current output by the second pulse signal is sensed
- the second Pearson coil is configured to sense the voltage applied to the resistor 8 by the first pulse signal and/or the second pulse signal, so as to realize the first pulse signal and/or the second pulse signal Two pulse signal output current and voltage monitoring.
- a first pulse signal and a second pulse signal with certain parameters are formed, and this pulse is applied to the above-mentioned resistor 8 with corresponding current and voltage.
- the above two Pearson coils can also sense the corresponding current and voltage. When the induction results of the above two Pearson coils meet the parameters of the first pulse signal and the second pulse signal, it is determined that the coordinated pulse generating circuit 3 at this time In the normal working state, once the induction results of the above two Pearson coils deviate from the parameters of the first pulse signal and the second pulse signal, it is determined that the cooperative pulse generating device is in an abnormal working state, so that the operator can find the fault in time and Take appropriate measures.
- the coordinated pulse generating circuit 3 in this embodiment when the coordinated pulse generating circuit 3 in this embodiment is applied to the medical field, that is, when applied to a pulse therapy device, it can be judged in time according to the monitoring results provided by the monitoring module 9 whether the output first pulse and/or the second pulse are Normal, so as to ensure that the output on load 4 is coordinated with the set output parameters.
- the pulse generating circuit 3 includes a first power supply U1, a first pulse generating module 31 electrically connected to the first power supply U1, a second power supply U2 and A second pulse generating module 32 electrically connected to the second power supply U2.
- the first pulse generating module 31 includes an n-level first pulse generating unit 311, the first pulse generating unit 311 is configured to receive and store the electric energy provided by the first power supply U1, and when receiving the first drive When the signal is released, the stored electric energy is released, and x first pulse generating units 311 receiving the first driving signal are discharged to form the first pulse signal applied to the load 4, n is an integer greater than or equal to 1, and x is greater than or equal to An integer equal to 1 and less than or equal to n.
- the second pulse generating module 32 includes an m-level second pulse generating unit 321, the second pulse generating unit 321 is configured to receive and store the electric energy provided by the second power supply U2, and when receiving the second drive The stored electrical energy is released upon signal.
- m is an integer greater than or equal to 1
- y is an integer greater than or equal to 1 and less than or equal to m integer.
- the voltage of the first power supply U1 is referred to as the first voltage
- the voltage of the second power supply U2 is referred to as the second voltage
- the x number of first pulse generating units 311 receiving the first driving signal are all discharged at the first voltage, but in practice, since each of the pulse generating circuits 3 Influenced by factors such as the equivalent impedance of the device, the discharge voltage of the first pulse generating unit 311 is slightly lower than the first voltage. However, the difference between the actual discharge voltage of the first pulse generating unit 311 and the first voltage is usually very small, therefore, during the discharge process of the first pulse generating module 31, the voltage of the first pulse signal applied to the load 4 can be approximated as x times the first voltage.
- the voltage of the second pulse signal applied to the load 4 can be approximately y times the second voltage.
- the actual voltage values when the first pulse generating unit 311 and the second pulse generating unit 321 are discharged will not be explained and illustrated, and the first voltage and the second voltage will be used for description.
- the voltage of the first pulse signal and the voltage of the second pulse signal can be adjusted by setting the number of the first pulse generating unit 311 that is simultaneously discharged and the number of the second pulse generating unit 321 that is simultaneously discharging; In specific implementation, by considering the relationship between the power supply voltage and the actual discharge voltage, the voltage of the generated pulse signal can be adjusted more precisely.
- the pulse combination includes a plurality of first pulse groups, and the interval time t1 between two adjacent first pulse groups, each first pulse group includes a first pulse signal, and two adjacent first pulse groups The interval time t2 between the first pulse signals.
- the pulse combination includes a plurality of second pulse groups, and there is an interval time t3 between two adjacent second pulse groups, and each second pulse group includes b second pulse signals, and two adjacent second pulse groups The time interval between the second pulse signals is t4.
- the pulse combination includes a plurality of first pulse signals and a plurality of second pulse signals, and the first pulse signals and the second pulse signals may be alternately applied to the load 4, or all the first pulse signals may be The second pulse signal is applied to the load 4 after being applied to the load 4, or the second pulse signal is applied to the load 4 after all the second pulse signals are applied to the load 4, or these first pulse signals can form multiple first pulses These second pulse signals form a plurality of second pulse groups, and the first pulse group and the second pulse group are alternately applied to the load 4 .
- the optional framework of the pulse generating circuit 2 in the cooperative pulse generating device has been described, and in the following embodiments, the first pulse generating units of each level in the first pulse generating module 31
- the structure of 311 and the connection relationship of the first pulse generation units 311 of each level, the structure of the second pulse generation units 321 of each level in the second pulse generation module 32 and the connection relationship of the second pulse generation units 321 of each level will be described in detail .
- the first pulse generating unit 311 in the cooperative pulse generating circuit 3 includes a first storage unit 3111, a first switching unit 3112, and a first cut-off unit 3113.
- the second pulse The generating unit 321 includes a second storage unit 3211 , a second switch unit 3212 and a second cut-off unit 3213 .
- the first switch unit 3112 is configured to be turned on under the control of the first drive signal, so that each first storage unit 3111 at the same level as the first switch unit 3112 receiving the first drive signal performs Discharge in series to form the first pulse signal; the first cut-off unit 3113 is configured to only allow the current to flow from the first power supply U1 to the first pulse generating unit 311, or to flow from the first pulse generating unit 311 of the current stage to the next-stage first A pulse generating unit 311 .
- the second switch unit 3212 is configured to be turned on under the control of the second drive signal, so that the second storage units 3211 of the same level in the second switch unit 3212 that receive the second drive signal perform connected in series and discharged to form a second pulse signal;
- the second cut-off unit 3213 is configured to only allow the current to flow from the second power supply U2 to the second pulse generating unit 321, or to flow from the second pulse generating unit 321 of the current stage to the second pulse generating unit 321 of the next stage.
- Two pulse generating units 321 Two pulse generating units 321 .
- the two ends of the first storage units 3111 at each level are electrically connected to the two ends of the first power supply U1 respectively, and the control terminals of the first switch units 3112 at each level are configured to receive the first driving signal,
- the first terminal and the second terminal of the first switch unit 3112 of each level are respectively electrically connected to the first terminal of the first storage unit 3111 of the current level and the second terminal of the first storage unit 3111 of the next level;
- the two ends of 3211 are respectively electrically connected to the two ends of the second power supply U2, the control ends of the second switch units 3212 of each level are configured to receive the second driving signal, and the first ends and second ends of the second switches of each level are respectively connected to The first end of the second storage unit 3211 of the current level is electrically connected to the second end of the second storage unit 3211 of the next level.
- the first storage unit 3111 includes a first capacitor
- the second storage unit 3211 includes a second capacitor.
- the first switching unit 3112 includes a first solid state switching device
- the second switching unit 3212 includes a second solid state switching device.
- the first cut-off unit 3113 includes a first cut-off device and a second cut-off device
- the second cut-off unit 3213 includes a third cut-off device and a fourth cut-off device.
- the first cut-off device includes a first diode
- the second cut-off device includes a second diode
- the third cut-off device includes a third diode
- the fourth cut-off device includes a fourth diode.
- a capacitor is used as a storage unit
- a solid-state switching device is used as a switching unit
- a diode is used as a cut-off device.
- the solid-state switching device can be realized by using a metal oxide semiconductor field effect transistor (MOSFET), an insulated gate bipolar transistor (IGBT) or a transistor.
- MOSFET metal oxide semiconductor field effect transistor
- IGBT insulated gate bipolar transistor
- the first pulse generating module 31 includes a 4-stage first pulse generating unit 311
- the second pulse generating module 32 includes a 4-stage second pulse generating unit 321, that is, both n and m equal to 4. It should be noted that this is only an illustration, and is not intended to limit the number of stages of the first pulse generating unit 311 in the first pulse generating module 31 and the number of stages of the second pulse generating unit 321 in the second pulse generating module 32 .
- the first switching unit 3112 from the first stage to the fourth stage that is, the first solid-state switching devices from the first stage to the fourth stage are respectively a solid-state switching device S 1-1 , a solid-state switching device S 1-2 , a solid-state switching device devices S 1-3 and solid state switching devices S 1-4 .
- the first storage units of the first to fourth stages are respectively capacitors C 1-1 , capacitors C 1-2 , capacitors C 1-3 and capacitors C 1-4 ;
- the first cut-off devices of the first to fourth stages are respectively Diode D 1-1 , diode D 1-2 , diode D 1-3 , and diode D 1-4 ;
- the second cut-off devices of the first to fourth stages are diode D 2-1 , diode D 2-2 , diode D 2-3 and diode D 2-4 .
- the second switching unit 3212 from the first stage to the fourth stage that is, the second transistors from the first stage to the fourth stage are respectively solid-state switching device S 2-1 , solid-state switching device S 2-2 , The solid-state switching device S 2-3 and the solid-state switching device S 2-4 ;
- the first to fourth-level second storage units 3211 are capacitors C 2-1 , capacitors C 2-2 , capacitors C 2-3 and capacitors C 2-4 ;
- the third cut-off devices from the first to fourth stages are diode D 3-1 , diode D 3-2 , diode D 3-3 and diode D 3-4 ;
- the cut-off devices are respectively diode D 4-1 , diode D 4-2 , diode D 4-3 and diode D 4-4 .
- both the first power supply U1 and the second power supply U2 are voltage sources, when the solid-state switching device S 1-1 , the solid-state switching device S 1-2 , the solid-state switching device S 1-3 and the solid-state switching device S 1-4
- the capacitor C 2-1 , the capacitor C 2-2 , the capacitor C 2-3 and the capacitor C 2-4 are connected in parallel and are all electrically connected to the first end and the second end of the second power supply U2, that is, they are all connected to the second power supply U2.
- the positive and negative electrodes are electrically connected.
- the solid-state switching device S 2-1 , the solid-state switching device S 2-2 , the solid-state switching device S 2-3 and the solid-state switching device S 2-4 all receive the second driving signal
- the solid-state switching device S 2-1 , the solid-state switching device S 2-2 , the solid-state switching device S 2-3 and the solid-state switching device S 2-4 are all in the conduction state
- the capacitor C 2-1 , the capacitor C 2-2 , the capacitor C 2-3 and capacitor C 2-4 are connected in series
- capacitor C 2-1 , capacitor C 2-2 , capacitor C 2-3 and capacitor C 2-4 are discharged at the same time, and the discharge voltage is the second voltage , so the voltage of the formed second pulse signal is 4 times the second voltage.
- the drive circuit 2 includes an electro-optic conversion module 21, a signal processing module 23, and an optical fiber 22 connected to the electro-optic conversion module 21 and the signal processing module 23, wherein the electro-optic conversion
- the module 21 is electrically connected to the host computer 1
- the signal processing module 23 is electrically connected to the pulse generating circuit 3 .
- the electro-optic conversion module 21 is configured to receive the first control signal and the second control signal, convert the first control signal into a first driving optical signal, convert the second control signal into a second driving optical signal, and convert the first driving optical signal
- the optical signal and the second driving optical signal are transmitted to the signal processing module 23 through the optical fiber 22 .
- the signal processing module 23 is configured to receive the first driving optical signal and the second driving optical signal, convert the first driving optical signal into a first driving electrical signal, convert the second driving optical signal into a second driving electrical signal, and The first driving electrical signal is processed to obtain a first driving signal, the second driving electrical signal is processed to obtain a second driving signal, and the first driving signal and the second driving signal are transmitted to the pulse generating circuit 3 .
- the drive circuit 2 obtained in this embodiment obtains the drive signal by converting the control signal into a drive light signal, and then photoelectrically converts and processes the drive light signal, so that the weak current part can be isolated from the strong current pulse generating circuit 3, Therefore, the electromagnetic interference of the pulse generating circuit 3 on the weak current part is reduced, and the accuracy of the driving signal is improved, thereby improving the accuracy of the pulse signal.
- the electro-optical conversion module 21 includes a buffer unit 211 , a first signal amplification unit 212 and a first conversion unit 213 .
- the buffer unit 211 is configured to receive the control signal and buffer the control signal.
- the buffer unit 211 may be a multi-way buffer, and the multi-way buffer includes k signal buffer channels 2111, and each signal buffer channel 2111 is used to input a control signal and store the control signal, k is an integer greater than 1.
- the multi-way buffer can be an eight-way buffer with a model number of 74LVC245.
- other models and buffers with other numbers of signal buffer channels can also be selected according to specific implementation requirements.
- the k signal buffering channels 2111 may receive the control signal and obtain the driving signal through subsequent processing by multiple units.
- the first signal amplifying unit 212 is electrically connected to the buffer unit 211 and configured to amplify the buffered control signal.
- the first signal amplifying unit 212 may include k first amplifying subunits 2121, each first amplifying subunit 2121 is electrically connected to a signal buffer channel 2111, and the first amplifying subunit 2121 uses It is used to amplify the control signal stored by the corresponding signal buffer channel 2111.
- the "corresponding signal buffer channel 2111" mentioned in this embodiment refers to the signal buffer channel 2111 electrically connected to the first amplifying subunit 2121, and the corresponding in the subsequent embodiments also refers to the formation of electrical connection or communication between the two connection, which will not be described in detail in subsequent embodiments.
- the first conversion unit 213 is electrically connected to the first signal amplifying unit 212 and the optical fiber 22 respectively, and is configured to perform electro-optic conversion on the amplified control to obtain a driving optical signal, and send it through the optical fiber 22 to Signal processing module 23.
- the first conversion unit 213 is an optical signal transmitter
- the optical signal transmitter includes k electrical-optical conversion channels 2311, and each electrical-optical conversion channel 2311 is electrically connected to a first amplification subunit 2121 connected, the electro-optical conversion channel 2311 is used to convert the control signal amplified by the corresponding first amplification subunit 2121 into a driving optical signal, and transmit the driving optical signal to the signal processing module 23 through the optical fiber 22 .
- the optical signal transmitter may be a fiber optic transmitter.
- the electro-optical conversion module 21 mentioned above is used to buffer the control signal first, which is beneficial to increase the transmission speed of the driving circuit 2, and then amplifies the control signal to enhance the control signal to reduce the Effect of electromagnetic interference on control signals.
- the signal processing module 23 includes a second converting unit 231 and a second signal amplifying unit 232 .
- the second conversion unit 231 is connected to the optical fiber 22 and configured to receive the driving light signal and convert the driving light signal into a driving electrical signal.
- the second conversion unit 231 is an optical signal receiver, and the optical signal receiver includes k photoelectric conversion channels 2311, and each photoelectric conversion channel 2311 is used to receive a driving optical signal and drive the The optical signal is converted into an electrical driving signal.
- the optical signal receiver is a fiber optic receiver.
- each photoelectric conversion channel 2311 is connected to one electro-optic conversion channel 2311 through optical fiber communication.
- the second signal amplifying unit 232 is electrically connected to the second converting unit 231 and configured to amplify the driving electrical signal to obtain a driving signal.
- the second signal amplifying unit 232 includes k second amplifying subunits 2321, and each second amplifying subunit 2321 is electrically connected to a photoelectric conversion channel 2311 of a second converting unit 231, and the second The amplifying subunit is used for amplifying the corresponding driving electrical signal to obtain the driving signal.
- the above-mentioned signal processing module 23 is used to amplify the driving electric signal, so that the control signal is further enhanced to reduce the influence of electromagnetic interference on the control signal.
- the signal processing module 23 may further include a first filtering unit 233 and a second filtering unit 234 .
- the first filtering unit 233 is electrically connected to the second converting unit 231 and the second signal amplifying unit 232 respectively, and is configured to perform a first filtering process on the driving electric signal.
- the first filtering unit 233 includes k first filtering subunits 2331, each first filtering subunit 2331 is electrically connected to a photoelectric conversion channel 2311, and the first filtering subunit 2331 is used for The driving electric signal converted by the corresponding photoelectric conversion channel 2311 is subjected to a first filtering process.
- the first filter unit 233 is an RC filter circuit.
- the second filter unit 234 is electrically connected to the second signal amplifying unit 232 and the pulse generating circuit 3 respectively, and is configured to perform a second filter process on the drive signal, and convert the drive signal after the second filter process to sent to the pulse generating circuit 3.
- the second filtering unit 234 includes k second filtering subunits 2341, each second filtering subunit 2341 is electrically connected to a second amplifying subunit 2321, and the second filtering subunit 2341 uses The second filtering process is performed on the driving electrical signal obtained by the amplification process of the corresponding second amplification sub-unit 2321 , and the driving signal after the second filtering process is sent to the pulse generating circuit 3 .
- the second filter unit 234 is an RC filter circuit.
- the pulses formed by the pulse generating circuit 3 Before the above two filter units are added, the pulses formed by the pulse generating circuit 3 have a large tail, but after the above two filter units are added, high-frequency interference can be eliminated, and the pulses formed by the pulse generating circuit 3 have no tail. It can be seen that the driving circuit 2 provided in this embodiment can further reduce the influence of electromagnetic interference on the driving signal by adding the above two filtering units.
- the pulse generating device in this embodiment also includes a circuit board PCB, the circuit board PCB includes a first part 10 and a second part 20 positioned on one side of the first part 10, the drive circuit 2 is arranged on the first part 10, and the pulse The generating circuit 3 is arranged in the second part 20 .
- the circuit board includes a first circuit board PCB1 and a second circuit board PCB1 , the driving circuit 2 is disposed on the first circuit board PCB1 , and the pulse generating circuit 3 is disposed on the second circuit board PCB2 .
- the pulse generating circuit 3 and the driving circuit 2 can be separated as much as possible by making the driving circuit 2 and the pulse generating circuit 3 on different parts of the circuit board PCB, or on different circuit boards. This design is because if the wiring of the driving circuit 2 and the wiring of the pulse generating circuit 3 intersect each other, it will cause strong electromagnetic coupling and increase the parasitic parameters between the electronic components, so that there will be relatively large gaps in the driving circuit 2. The large interference causes the signal distortion in the drive circuit 2, and further reduces the quality of the pulse waveform generated by the main circuit. The separation of the pulse generating circuit 3 from the driving circuit 2 can significantly reduce the interference of the pulse generating circuit 3 on the driving circuit 2 .
- the pulse generating device in this embodiment further includes a shielding structure M connected to the circuit board PCB, and the driving circuit 2 is located in the shielding structure M.
- the shielding structure M is a metal shield, and the metal shield is fixed on the circuit board PCB so that the electro-optic conversion module 21 is located in the metal shield, or the metal shield is fixed on the first circuit board PCB so that the electro-optical conversion module 21 Located in a metal shield.
- the pulse signal formed by the pulse generating circuit 3 has a waveform collapse phenomenon, but in the equipment pulse generating device provided by this embodiment, after the shielding structure M is set , the waveform collapse phenomenon of the pulse signal formed by the pulse generating circuit 3 is obviously improved.
- the embodiment of the present application also provides a coordinated pulse generating device. As shown in FIG. A first control signal and a second control signal are generated according to an input command.
- the coordinated pulse generating device provided in this embodiment includes the beneficial effects of the coordinated pulse generating circuit 3 in the above-mentioned embodiments, which will not be repeated here.
- the upper computer 1 can be a computer
- the input instruction can be the parameters of the first control signal and the second control signal, for example, it can be the voltage, cycle, and duration of the active level of the first control signal and the second control signal. etc.
- the input instructions may also be parameters of the first drive signal and the second drive signal, for example, may be the voltage, cycle, pulse width, etc. of the first drive signal and the second drive signal.
- the coordinated pulse generating device provided in this embodiment is the electrical ablation device proposed in this application that can output microsecond pulse/millisecond signal and nanosecond pulse cooperatively
- the first pulse signal is a microsecond pulse signal or a millisecond pulse signal
- the second The pulse signal is a nanosecond pulse signal.
- the input instruction can be the required pulse width, quantity, voltage, etc., or it can be the parameters of the tumor tissue, and the corresponding relationship between the parameters of the tumor tissue and the parameters of the required pulse is stored in the electroablation device, and passed
- the combination of nanosecond pulses and microsecond pulses/millisecond pulses generated according to the parameters of the tumor tissue is applied to the tumor tissue, which can effectively improve the ablation effect of the tumor tissue.
- the embodiment of the present application also provides a coordinated pulse generation method, as shown in Figure 1 and Figure 14, the coordinated pulse generation method includes:
- the first pulse generating module 31 stores the electric energy provided by the first power supply
- the second pulse generating module 32 stores the electric energy provided by the second power supply. It should be noted that the charging process of the first pulse generating module 31 and the charging process of the second pulse generating module 32 can be carried out simultaneously, or only the first pulse generating module 31 or the second pulse generating module 32 can be charged, or The charging process of the first pulse generating module 31 and the charging process of the second pulse generating module 32 are not performed simultaneously.
- the driving circuit 2 receives the first control signal sent by the upper computer 1 and converts the first control signal into a first driving signal, and the driving circuit 2 receives the second control signal sent by the upper computer 1 and converts the second control signal into a second drive signal.
- the first pulse generating module 31 receives the first driving signal and discharges under the control of the first driving signal to form the first pulse signal applied to the load 4, and the second pulse generating module 32 receives the second driving signal at the second Discharging is performed under the control of the driving signal to form a second pulse signal applied to the load 4 .
- the voltage of the second power supply is greater than the voltage of the first power supply
- the width of the second pulse signal is smaller than the width of the first pulse signal
- the time when the second pulse generating module 32 receives the second driving signal is the same as that of the first pulse signal. The time at which the pulse generating module 31 receives the first driving signal is different.
- the first control signal and the second control signal sent by the host computer 1 are converted into the first driving signal and the second driving signal by the driving circuit 2 respectively, and the pulse generating circuit 3 is driven according to the first driving signal.
- the signal and the second driving signal can selectively form the first pulse signal and/or the second pulse signal with different widths, so as to realize the purpose of applying the composite pulse signal to the load 4.
- the composite pulse signal The role is conducive to improving the ablation effect on tumor cells.
- the n-stage first pulse generating units 311 included in the first pulse generating module 31 receive and store the electric energy provided by the first power supply U1, and the m-stages included in the second pulse generating module 32
- the second pulse generating unit 321 receives and stores the electric energy provided by the second power supply U2, n is an integer greater than or equal to 1, and m is an integer greater than or equal to 1.
- step S1 includes: each first switch unit 3112 is turned off when receiving the third driving signal, so that the first storage units 3111 of each level are connected in parallel to the first power supply U1 to receive the electric energy provided by the first power supply U1 and To store; each second switch unit 3212 is turned off when receiving the fourth driving signal, so that the second storage units 3211 of each level are connected in parallel to the second power supply U2 to receive and store the electric energy provided by the second power supply U2.
- the charging process of the first pulse generating module 31 is as follows: when the solid-state switching device S 1-1 , the solid-state switching device S 1-2 , the solid-state switching device S 1-3 And when the solid-state switching device S 1-4 receives the third driving signal, the solid-state switching device S 1-1 , the solid-state switching device S 1-2 , the solid-state switching device S 1-3 and the solid-state switching device S 1-4 are all in off state.
- diode D 1-1 , diode D 1-2 , diode D 1-3 and diode D 1-4 , diode D 2-1 , diode D 2-2 , diode D 2-3 and diode D 2-4 It has a one-way conduction function, so that the capacitor C 1-1 , capacitor C 1-2 , capacitor C 1-3 and capacitor C 1-4 are connected in parallel and are all electrically connected to the first end and the second end of the first power supply U1 , that is, both are electrically connected to the positive pole and the negative pole of the first power supply U1. Until the potential differences between the capacitors C 1-1 , C 1-2 , C 1-3 , and C 1-4 are all at the first voltage, the first pulse generating module 31 completes charging.
- the solid-state switching device S 2-1 , the solid-state switching device S 2-2 , the solid-state switching device S 2-3 and the solid-state switching device S 2-4 are all off state, diode D 3-1 , diode D 3-2 , diode D 3-3 , diode D 3-4 , diode D 4-1 , diode D 4-2 , diode D 4-3 and diode D 4-4 have One-way conduction function, so that the capacitor C 2-1 , capacitor C 2-2 , capacitor C 2-3 and capacitor C 2-4 are connected in parallel and are all electrically connected to the first terminal and the second terminal of the second power supply U2, That is, both are electrically connected to the positive
- the first driving signal and the second driving signal are both high level, while the third driving signal and the fourth driving signal are both low level, that is, as long as the first pulse generating module 31 does not receive
- the first power supply U1 is in the state of charging the first capacitors of each level or maintaining the voltage difference between the two ends of the first capacitors of each level as the first voltage.
- the second power supply U2 is in the state of charging the second capacitors of each level or maintaining the voltage difference between the two ends of the second capacitors of each level as the second voltage .
- the level of each driving signal can also be set adaptively.
- step S2 includes:
- the electro-optical conversion module 21 receives the first control signal and the second control signal, converts the first control signal into a first driving light signal, converts the second control signal into a second driving light signal, and converts the first driving light signal
- the signal and the second driving optical signal are transmitted to the signal processing module 23 through the optical fiber 22;
- the signal processing module 23 receives the first driving optical signal and the second driving optical signal, converts the first driving optical signal into a first driving electrical signal, converts the second driving optical signal into a second driving electrical signal, and The first driving electrical signal is processed to obtain a first driving signal, the second driving electrical signal is processed to obtain a second driving signal, and the first driving signal is transmitted to the first pulse generating module 31, and the second driving signal is transmitted to to the second pulse generating module 32 .
- the cooperative pulse generation method provided in this embodiment converts the control signal into a driving optical signal, and then performs photoelectric conversion and processing on the driving optical signal to obtain the driving signal, so that the weak current circuit can be isolated from the strong current pulse generating circuit 3 , so as to reduce the electromagnetic interference of the pulse generating circuit 3 on the weak current circuit, improve the accuracy of the driving signal, and thereby improve the accuracy of the pulse signal.
- step S3 includes:
- S301 x number of first pulse generating units 311 receive a first driving signal, and discharge under the control of the first driving signal to form a first pulse signal.
- S302 y second pulse generating units 321 receive a second driving signal, and discharge under the control of the second driving signal to form a second pulse signal.
- the solid-state switching device S 2-1 , the solid-state switching device S 2-2 , the solid-state switching device S 2-3 and the solid-state switching device S 2-4 all receive the second control signal
- the solid-state switching device S 2-1 , solid-state switching device S 2-2 , solid-state switching device S 2-3 and solid-state switching device S 2-4 are all in the conduction state
- capacitor C 2-1 , capacitor C 2-2 , and capacitor C 2- 3 and capacitor C 2-4 are connected in series
- capacitor C 2-1 , capacitor C 2-2 , capacitor C 2-3 and capacitor C 2-4 are discharged at the same time, and the discharge voltage is the second voltage, thus forming
- the voltage of the second pulse is 4 times the second voltage.
- step S303 specifically includes: applying the first pulse and/or the second pulse to the Load 4.
- the output module 7 please refer to the above-mentioned embodiment of the cooperative pulse generating device, which will not be repeated here.
- the coordinated pulse generation method provided in this embodiment further includes: converting the first pulse signal and/or The second pulse signal is applied to the resistor 8, and at the same time, the current and voltage applied to the resistor 8 by the first pulse signal and/or the second pulse signal are monitored.
- the resistor 8 and the monitoring module 9 please refer to the above-mentioned embodiment of the cooperative pulse generating device, and details are not repeated here.
- the method for generating coordinated pulses further includes: receiving The first leakage signal and under the control of the first leakage signal, the first pulse generation module 31 is connected to the ground to release the residual power in the first pulse generation module 31; Under the control of the second leakage signal, the second pulse generating module 32 is connected to the ground so as to discharge the residual electricity in the second pulse generating module 32 .
- the first leakage module 5 and the second leakage module 6 please refer to the above-mentioned embodiment of the cooperative pulse generating device, which will not be repeated here.
- the cooperative pulse generating device, equipment and generation method provided in the embodiment of the present application convert the first control signal and the second control signal sent by the host computer into the first control signal and the second control signal respectively through the drive circuit.
- a driving signal and a second driving signal, the pulse generating circuit can selectively form the first pulse signal and/or the second pulse signal with different widths according to the first driving signal and the second driving signal, thereby realizing that the composite pulse signal is applied to
- the purpose of the load taking the load as an example of tumor cells, the effect of the compound pulse is conducive to improving the ablation effect on tumor cells.
- first and second are used for descriptive purposes only, and cannot be understood as indicating or implying relative importance or implicitly specifying the quantity of indicated technical features. Thus, a feature defined as “first” and “second” may explicitly or implicitly include one or more of these features. In the description of the present application, unless otherwise specified, "plurality” means two or more.
- connection should be understood in a broad sense, for example, it can be a fixed connection or a detachable connection. Connected, or integrally connected; it can be directly connected, or indirectly connected through an intermediary, and it can be the internal communication of two elements. Those of ordinary skill in the art can understand the specific meanings of the above terms in this application in specific situations.
Abstract
Description
Claims (24)
- 一种协同脉冲发生装置,用于在上位机的控制下生成脉冲信号,包括:驱动电路,与所述上位机电连接,且被配置为接收所述上位机发送的第一控制信号并将所述第一控制信号转换为第一驱动信号,接收所述上位机发送的第二控制信号并将所述第二控制信号转换为第二驱动信号;脉冲发生电路,包括第一电源、与所述第一电源电连接的第一脉冲发生模块、第二电源以及与所述第二电源电连接的第二脉冲发生模块;所述第一脉冲发生模块被配置为将所述第一电源提供的电能进行存储,且在所述第一驱动信号的控制下进行放电以形成施加至负载的第一脉冲信号;所述第二脉冲发生模块被配置为将所述第二电源提供的电能进行存储,且在所述第二驱动信号的控制下进行放电以形成施加至所述负载的第二脉冲信号;其中,所述第二电源的电压大于所述第一电源的电压,所述第二脉冲的宽度小于所述第一脉冲的宽度。
- 根据权利要求1所述的协同脉冲发生装置,其中,所述脉冲发生电路还包括:第一泄电模块,分别与所述第一脉冲发生模块和地电连接,且被配置为在第一泄电信号的控制下将所述第一脉冲发生模块与地导通以将所述第一脉冲发生模块中的残留电量进行释放;第二泄电模块,分别与所述第二脉冲发生模块和地电连接,且被配置为在第二泄电信号的控制下将所述第二脉冲发生模块与地导通以将所述第二脉冲发生模块中的残留电量进行释放。
- 根据权利要求1所述的协同脉冲发生装置,其中,所述脉冲发生电路还包括:输出模块,包括触发单元和与所述触发单元电连接的至少一对电极, 所述触发单元分别与所述第一脉冲发生模块和所述第二脉冲发生模块电连接,所述电极与所述负载接触,所述触发单元被配置为在被所述触发指令触发时导通使得所述第一脉冲信号和/或所述第二脉冲信号传输至所述电极。
- 根据权利要求1所述的协同脉冲发生装置,其中,所述脉冲发生电路还包括:电阻,分别与所述第一脉冲发生模块、所述第二脉冲发生模块以及地电连接,所述第一脉冲信号和/或所述第二脉冲信号还施加到所述电阻;监测模块,包括第一监测单元和第二监测单元,所述第一监测单元被配置为对所述第一脉冲信号和所述第二脉冲信号输出的电流进行监测;所述第二监测单元被配置为对所述第一脉冲信号和所述第二脉冲信号施加至所述电阻的电压进行监测。
- 根据权利要求1所述的协同脉冲发生装置,还包括电路板,其中,所述电路板包括第一部分和位于所述第一部分一侧的第二部分,所述驱动电路设置在所述第一部分,所述脉冲发生电路设置在所述第二部分;或者,所述电路板包括第一电路板和第二电路板,所述驱动电路设置在所述第一电路板,所述脉冲发生电路设置在所述第二电路板。
- 根据权利要求1所述的协同脉冲发生装置,还包括:屏蔽结构,设置在所述电路板上,且所述驱动电路位于所述屏蔽结构内。
- 根据权利要求1所述的协同脉冲发生装置,其中,所述第一脉冲信号为微秒脉冲信号或毫秒脉冲信号,所述第二脉冲信号为纳秒脉冲信号。
- 根据权利要求1所述的协同脉冲发生装置,其中,所述驱动电路包括电光转换模块、信号处理模块以及分别与所述电光转换模块和所述信号处理模块电连接的光纤,其中,所述电光转换模块与所述上位机电连接,所述信号处理模块与所述脉冲发生电路电连接;所述电光转换模块被配置为接收所述上位机发送的控制信号,并将所 述控制信号转化为驱动光信号并通过所述光纤发送至所述信号处理模块;所述信号处理模块被配置为接收所述驱动光信号并将所述驱动光信号转换为驱动电信号,并对所述驱动电信号进行处理以获得驱动信号并将所述驱动信号传输至所述脉冲发生电路。
- 根据权利要求8所述的协同脉冲发生装置,其中,所述电光转换模块包括:缓存单元,与所述上位机电连接,且被配置为接收所述控制信号并对所述控制信号进行缓存;第一信号放大单元,与所述缓存单元电连接,且被配置为对缓存的所述控制信号进行放大处理;第一转换单元,分别与所述第一信号放大单元和所述传输结构电连接,且被配置为对放大处理后的所述控制进行电光转换以获得驱动光信号,并通过所述传输结构发送至所述信号处理模块。
- 根据权利要求9所述的协同脉冲发生装置,其中,所述缓存单元为多路缓冲器,所述多路缓冲器包括k个信号缓存通道,每个所述信号缓存通道用于输入一路所述控制信号且对所述控制信号进行存储,k为大于1的整数;所述第一信号放大单元包括k个第一放大子单元,每个所述第一放大子单元与一个所述信号缓存通道电连接,所述第一放大子单元用于对由相应所述信号缓存通道存储的所述控制信号进行放大处理;所述第一转换单元为光信号发射器,所述光信号发射器包括k个电光转换通道,每个所述电光转换通道与一个所述第一放大子单元电连接,所述电光转换通道用于将相应的所述第一放大子单元放大处理后的所述控制信号转换为所述驱动光信号,且将所述驱动光信号通过所述传输结构传输至所述信号处理模块。
- 根据权利要求8所述的协同脉冲发生装置,其中,所述信号处理模块包括:第二转换单元,与所述传输结构连接,且被配置接收所述驱动光信号 并将所述驱动光信号转换为所述驱动电信号;第二信号放大单元,与所述第二转换单元电连接,且被配置为将所述驱动电信号进行放大处理以获得所述驱动信号。第一滤波单元,分别与所述第二转换单元和所述第二信号放大单元电连接,且被配置为对所述驱动电信号进行第一滤波处理;第二滤波单元,分别与所述第二信号放大单元和所述脉冲发生电路电连接,且被配置为对所述驱动信号进行第二滤波处理,并将第二滤波处理后的所述驱动信号发送至所述脉冲发生电路。
- 根据权利要求11所述的协同脉冲发生装置,其中,所述第二转换单元为光信号接收器,所述光信号接收器包括k个光电转换通道,每个所述光电转换通道用于接收一个所述驱动光信号且将所述驱动光信号转换为所述驱动电信号,k为大于1的整数;所述第一滤波单元包括k个第一滤波子单元,每个所述第一滤波子单元与一个所述光电转换通道电连接,所述第一滤波子单元用于对由相应所述光电转换通道进行转换而获得的所述驱动电信号进行第一滤波处理;所述第二信号放大单元包括k个第二放大子单元,每个所述第二放大子单元与一个所述第一滤波子单元电连接,所述第二放大子单元用于对由相应所述第一滤波子单元进行第一滤波处理的所述驱动电信号进行放大处理以获得所述驱动信号;所述第二滤波单元包括k个第二滤波子单元,每个所述第二滤波子单元与一个所述第二放大子单元电连接,所述第二滤波子单元用于对由相应所述第二放大子单元进行放大处理而获得的所述驱动信号进行第二滤波处理,并将第二滤波后的所述驱动信号发送至所述脉冲发生电路。
- 根据权利要求1所述的协同脉冲发生装置,其中,所述第一脉冲发生模块包括n级第一脉冲发生单元,所述第一脉冲发生单元被配置为接收所述第一电源以第一电压提供的电能并进行存储,并在接收到第一控制信号时对存储的电能进行释放,以使x个接收所述第一控制信号的所述第一脉冲发生单元进行放电以形成施加至负载的第一脉 冲,n为大于或等于1的整数,x为大于或等于1且小于或等于n的整数;所述第二脉冲发生模块包括m级第二脉冲发生单元,所述第二脉冲发生单元被配置为接收所述第二电源以第二电压提供的电能并进行存储,并在接收到第二控制信号时对存储的电能进行释放,以使y个接收到所述第二控制信号的所述第二脉冲发生单元进行放电以形成施加至所述负载的第二脉冲,m为大于或等于1的整数,y为大于或等于1且小于或等于m的整数;所述第二电压大于所述第一电压,所述第二脉冲的宽度小于所述第一脉冲的宽度。
- 根据权利要求13所述的协同脉冲发生装置,其中,所述第一脉冲发生单元包括第一存储单元、第一开关单元以及第一截止单元;所述第一开关单元被配置为接收所述第一控制信号并在所述第一控制信号的控制下导通,以使与接收到所述第一控制信号的所述第一开关单元同级的各所述第一存储单元串联并进行放电以形成所述第一脉冲;所述第一截止单元被配置为仅允许充电电流由所述第一电源流向所述第一脉冲发生单元,或者由本级所述第一脉冲发生单元流向下一级所述第一脉冲发生单元,且仅允许放电电流由本级所述第一脉冲发生单元流向下一级所述第一脉冲发生单元;所述第二脉冲发生单元包括第二存储单元、第二开关单元以及第二截止单元;所述第二开关单元被配置为接收所述第二控制信号并在所述第二控制信号的控制下导通,以使接收到所述第二控制信号的所述第二开关单元中同级的各所述第二存储单元串联并进行放电以形成所述第二脉冲;所述第二截止单元被配置为仅允许充电电流由所述第二电源流向所述第二脉冲发生单元,或者由本级所述第二脉冲发生单元流向下一级所述第二脉冲发生单元,且仅允许放电电流由本级所述第二脉冲发生单元流向下一级所述第二脉冲发生单元。
- 根据权利要求14所述的协同脉冲发生装置,其中,所述第一截止单元包括第一截止器件和第二截止器件,第1级第一截止器件分别与所述第一电源的第一端和第1级第一存储单元的第一端电连接,第i级第一截止器件分别与第i-1级第一存储单元的第一端、第i级第一存储单元的第一端以及第i-1级第一截止器件电连接,各级第二截止器件分别与本级第一存储单元的第二端、本级第一开关的第二端以及下一级第二截止器件电连接,i为大于或等于2的整数;所述第二截止单元包括第三截止器件和第四截止器件,第1级第三截止器件分别与所述第二电源的第一端和第1级第二存储单元的第一端电连接,第j级第三截止器件与分别与第j-1级第二存储单元的第一端、第j级第二存储单元的第一端以及第j-1级第三截止器件电连接,各级第四截止器件分别与本级第二存储单元的第二端、本级第二开关的第二端以及下一级第四截止器件电连接,j为大于或等于2的整数。
- 根据权利要求14所述的协同脉冲发生装置,其中,各级所述第一存储单元的两端分别与所述第一电源的两端电连接,各级所述第一开关单元的控制端被配置为接收所述第一控制信号,各级所述第一开关的第一端和第二端分别与本级所述第一存储单元的第一端以及下一级所述第一存储单元的第二端电连接;各级所述第二存储单元的两端分别与所述第二电源的两端电连接,各级所述第二开关单元的控制端被配置为接收所述第二控制信号,各级所述第二开关的第一端和第二端分别与本级所述第二存储单元的第一端以及下一级所述第二存储单元的第二端电连接。
- 根据权利要求15所述的协同脉冲发生装置,其中,所述第一存储单元包括第一电容,所述第二存储单元包括第二电容;所述第一开关单元包括第一固态开关器件,所述第二开关单元包括第二固态开关器件;所述第一截止器件包括第一二极管,所述第二截止器件包括第二二极管,所述第三截止器件包括第三二极管,所述第四截止器件包括第四二极 管。
- 一种协同脉冲发生设备,包括:上位机,被配置为根据输入的指令生成第一控制信号和第二控制信号;以及权利要求1-17中任一项所述的协同脉冲发生装置。
- 根据权利要求18所述的协同脉冲发生设备,其中,所述协同脉冲发生设备为电消融设备;所述协同脉冲发生装置生成的第一脉冲信号为微秒脉冲信号或毫秒脉冲信号,生成的所述第二脉冲信号为纳秒脉冲信号。
- 一种协同脉冲发生方法,用于权利要求1-17中任一项所述的协同脉冲发生装置,包括:第一脉冲发生模块将第一电源提供的电能进行存储,第二脉冲发生模块将第二电源提供的电能进行存储;驱动电路接收上位机发送的第一控制信号并将所述第一控制信号转换为第一驱动信号,驱动电路接收上位机发送的第二控制信号并将所述二控制信号转换为第二驱动信号;以及第一脉冲发生模块接收所述第一驱动信号并在所述第一驱动信号的控制下进行放电以形成施加至负载的第一脉冲信号,所述第二脉冲发生模块接收所述第二驱动信号在所述第二驱动信号的控制下进行放电以形成施加至所述负载的第二脉冲信号;其中,所述第二电源的电压大于所述第一电源的电压,所述第二脉冲信号的宽度小于所述第一脉冲信号的宽度。
- 根据权利要求20所述的协同脉冲发生方法,其中,所述第二脉冲发生模块接收所述第二驱动信号的时间与所述第一脉冲发生模块接收所述第一驱动信号的时间不同。
- 根据权利要求20所述的协同脉冲发生方法,还包括:接收第一泄电信号并在所述第一泄电信号的控制下将所述第一脉冲发生模块与地导通,以将所述第一脉冲发生模块中的残留电量进行释放;以及接收第二泄电信号并在第二泄电信号的控制下将所述第二脉冲发生模块与地导通,以将所述第二脉冲发生模块中的残留电量进行释放。
- 根据权利要求20所述的协同脉冲发生方法,其中,将所述第一脉冲信号和/或所述第二脉冲信号施加至负载,包括:在触发指令的控制下将所述第一脉冲和/或所述第二脉冲施加到所述负载。
- 根据权利要求20所述的协同脉冲发生方法,还包括:对所述第一脉冲信号和/或所述第二脉冲信号输出的电流和/或电压进行监测。
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