KR102570924B1 - Switch, pulse generator and method of controling pulse generator - Google Patents

Abstract

The pulse generator includes a first charge switch, a second charge switch that is turned on and off at the same time as the first charge switch, a plurality of discharge switches, a plurality of electrically connected to the first charge switch, the second charge switch, and a plurality of discharge switches. A capacitor, a charge trigger electrode configured to turn on or off the first charge switch and the second charge switch, and a discharge trigger electrode configured to turn on or off each of the plurality of discharge switches. When the first charge switch and the second charge switch are turned on, each of the plurality of discharge switches is turned off, and each of the plurality of capacitors is electrically connected in parallel and configured to be charged by DC power, or the first charge switch and the second charge switch When is off, each of the plurality of discharge switches is turned on, so that each of the plurality of capacitors is electrically connected in series.

Description

Control method of switch, pulse generator and pulse control device {SWITCH, PULSE GENERATOR AND METHOD OF CONTROLING PULSE GENERATOR}

The present disclosure relates to a control method of a switch, a pulse generator, and a pulse control device, and more particularly, an interlocking spark gap switch, a pulse generator for generating pulses by alternately turning on a charging circuit and a discharge circuit using the same, and It relates to a control method of a pulse control device.

A high-voltage pulse generating device is used for industrial applications such as generation of nanoparticles by generating plasma at atmospheric pressure, treatment of harmful gases, and production of plasma activated water through underwater discharge. As a device that generates high-voltage pulses, a Marx Generator is known that generates high-voltage pulses by charging multiple capacitors in parallel using a DC power source and connecting multiple capacitors charged through switching in series. there is. Semiconductor element switches are widely used for switching the circuit of the Max generator, but there are limitations in peak current, peak withstand voltage, and current voltage/current rise rate. Instead, a spark gap switch was used. Spark gap switches can be largely classified into self-discharge switches and trigger gap discharge switches. The self-discharge method is a principle in which electricity is voluntarily energized when the voltage applied between the two electrodes of the switch exceeds the gap dielectric breakdown voltage. Although the structure is simple, it is difficult to control the operating voltage or repetition rate. The trigger gap discharge switch can control the operating voltage or repetition rate by adjusting the trigger signal using the trigger electrode in addition to the positive and negative electrodes. Triggering methods include a method of giving an electrical signal and a method of controlling repetition rate and operating voltage while mechanically adjusting the distance between electrodes.

1 shows a conceptual diagram of a conventional max generator. When capacitors (C1 ~ C5) are connected in series, as a method of preventing self-short circuit, large resistors (R1 ~ R8) are inserted between each terminal as shown in Figure 1 to suppress discharge while turning on switches (S1 ~ S4). The voltage charged in the capacitors (C1 ~ C5) is connected in series. At this time, if the resistors (R1 to R8) used are large, there is a problem in that the charging at the rear end is very slow and a high repetition rate cannot be obtained. In addition, the calculated voltage cannot be obtained because the voltages of each stage are not the same during discharge.

Korean Patent Publication No. 10-2022-0038177 Korean Patent Publication No. 10-2018-0042701 Korean Patent Registration No. 10-2427763

Design and test of high-voltage, high-repetition rotary trigger double spark gap switch, Review of Scientific Instruments 92, 014702(2021), Chuhyun Cho et al.

A spark gap switch with a rotation trigger type capable of high repetition, a pulse generator using the same, and a method for controlling the pulse generator. The mechanically connected charge trigger electrode and the discharge trigger electrode are interlocked in one operation to discharge the switch when the charge switch is on. is turned off, and when the charge switch is turned off, the discharge switch is turned on to provide a pulse generator device and a control method for generating high-voltage, high-repetitive voltage pulses.

In one aspect of the present disclosure, a pulse generating device includes a first charging switch; A second charge switch that is turned on and off at the same time as the first charge switch; a plurality of discharge switches; a plurality of capacitors electrically connected to the first charge switch, the second charge switch, and the plurality of discharge switches; a charge trigger electrode configured to turn on or off the first charge switch and the second charge switch according to a positional relationship with the first charge switch and the second charge switch; and a discharge trigger electrode configured to turn on or off each of the plurality of discharge switches according to a positional relationship with the plurality of discharge switches, and configured to mechanically interlock with the charge trigger electrode. When the first charge switch and the second charge switch are turned on, each of the plurality of discharge switches is turned off, so that each of the plurality of capacitors is electrically connected in parallel to be charged by DC power, and the first charge switch and when the second charge switch is off, each of the plurality of discharge switches is turned on, so that each of the plurality of capacitors is electrically connected in series.

In one embodiment, the pulse generating device further comprises a rotating member, a rotating axis of the rotating member coincides with the rotating axes of the charging trigger electrode and the discharge trigger electrode, and the charging trigger electrode according to the rotation of the rotating member. and the discharge trigger electrode rotates so that the charge trigger electrode moves to a position where the first charge switch and the second charge switch are turned on or off, and the discharge trigger electrode moves to a position where the discharge switch is turned on or off. can be configured to

In one embodiment, the controller may further include a control unit configured to control a pulse generation period of the pulse generator by controlling the number of revolutions of the rotation member.

In one embodiment, the rotating member may be a pneumatic motor.

In one embodiment, any one of the first charge switch and the second charge switch and each discharge switch overlap when viewed in the direction of the rotation axis,

The charge trigger electrode and the discharge trigger electrode may have a bar-shape extending in one direction and may be orthogonal to each other with respect to the rotation axis.

In one embodiment, the first charge switch includes two first insulator plates facing each other and the rotation axis coincides with the rotation center, and a first charging electrode pair disposed on each of the first insulator plates and facing each other, The second charging switch includes second charging electrode pairs disposed on each of the first insulator plates and facing each other, wherein the second charging electrode pair and the first charging electrode pair are symmetrically disposed around the rotation axis. can do. Each of the discharge switches may include two second insulator plates facing each other with a rotational center coincident with the rotation axis, and a pair of discharge electrodes disposed on the second insulator plates and facing each other.

In one embodiment, the charging trigger electrode is configured to pass between the first charging electrode pair and the second charging electrode pair according to rotation of the rotating member, and the discharge trigger electrode is configured to pass between the charging electrode pair according to rotation of the rotating member. It may be configured to pass between the discharge electrode pairs.

In one aspect of the present disclosure, a pulse generating device includes a first charging switch; a second charge switch turned on and off at the same time as the first charge switch; a plurality of discharge switches; a plurality of capacitors electrically connected to the first charge switch, the second charge switch, and the plurality of discharge switches; a charge trigger electrode configured to turn on or off the first charge switch and the second charge switch; a discharge trigger electrode configured to turn on or off each of the plurality of discharge switches; and a rotating member for rotating the charge trigger electrode and the discharge trigger electrode, and a method for controlling the same includes receiving a user's input; and rotating the rotating member based on the user's input. The rotating of the rotating member may include moving the charge trigger electrode to a position where the first charge switch and the second charge switch are turned on and simultaneously moving the discharge trigger electrode to a position where the discharge switch is turned off. charging the plurality of capacitors by electrically connecting each of the plurality of capacitors in parallel; and moving the charge trigger electrode to a position where the first charge switch and the second charge switch are turned off and simultaneously moving the discharge trigger electrode to a position where each of the plurality of discharge switches is turned on, so that each of the plurality of capacitors is turned on. The step of discharging the plurality of capacitors by electrically connecting them in series.

In one embodiment, the user's input, when considering the charging step and the discharging step as one pulse, corresponds to the frequency of the pulse, and the rotating member corresponds to the frequency The method may include calculating the number of revolutions of the rotation member and rotating the rotation member according to the calculated number of rotations.

In one aspect of the present disclosure, the switch includes a first charging switch; a second charge switch turned on and off at the same time as the first charge switch; a plurality of discharge switches; a charge trigger electrode configured to turn on or off the first charge switch and the second charge switch; a discharge trigger electrode configured to operate in conjunction with the charge trigger and turn on or off each of the plurality of discharge switches; and a rotating member rotating the charge trigger electrode and the discharge trigger electrode. As the phase shift member rotates, the charge trigger electrode is moved to a position where the first charge switch and the second charge switch are turned on, and the discharge trigger electrode is moved to a position where the discharge switch is turned off, or the rotation member is moved to a position where the discharge switch is turned off. According to the rotation of , the charge trigger electrode is moved to a position where the first charge switch and the second charge switch are turned off, and at the same time the discharge trigger electrode is moved to a position where each of the plurality of discharge switches is turned on.

By operating the charge trigger electrode and the discharge trigger electrode in one operation, the circuit can be completely separated after charging. The repetition frequency of the pulse can be freely changed according to the number of revolutions of the charge trigger electrode and the discharge trigger electrode. It can be variously applied to a plasma activated water production device using gas discharge under atmospheric pressure, a nanoparticle production device, and a shock wave generating device through underwater discharge.

1 shows a conceptual diagram of a conventional max generator.
2 shows a conceptual diagram of a pulse generating device, according to an embodiment of the present invention.
3A to 3D are structural diagrams of a portion of a pulse generating device according to an embodiment of the present invention.
4a to 4d are diagrams for explaining the operation of a switch according to an embodiment of the present invention.
5A is a conceptual diagram of a discharge switch of a pulse generator according to an embodiment of the present invention.
5B is a conceptual diagram of a charging switch of a pulse generator according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, embodiments of the present disclosure will be described in detail so that those skilled in the art can easily carry out the present disclosure. However, the present disclosure may be embodied in many different forms and is not limited to the embodiments described herein.

And in order to clearly describe the present disclosure in the drawings, parts irrelevant to the description are omitted, and similar reference numerals are attached to similar parts throughout the specification.

Throughout the specification, when a certain component is said to "include", it means that it may further include other components without excluding other components unless otherwise stated.

It should be understood that the techniques described in this disclosure are not intended to be limited to the specific embodiments, and include various modifications, equivalents, and/or alternatives of the embodiments of this disclosure.

The expression "configured to (or configured to)" used in the present disclosure means, depending on the situation, for example, "suitable for", "having the capacity to" Can be used interchangeably with ", designed to", "adapted to", "made to", or "capable of". The term " "Configured (or set to)" may not necessarily imply only "specifically designed to" hardware. Instead, in some circumstances, the expression "device configured to" means that the device is different from other In conjunction with a device or component, it can mean "capable of" For example, the phrases "processor configured (or configured) to perform A, B, and C", "perform A, B, and C" A "module configured (or set) to do" is a dedicated processor (e.g., an embedded processor) for performing the corresponding operation, or a general-purpose processor capable of performing the corresponding operation by executing one or more software programs stored in a memory device (generic-purpose processor). processor) (eg, CPU or application processor).

It will be understood that the prior art documents described in this disclosure are incorporated herein by reference in their entirety, and that a person having general knowledge in the art can apply the contents described in the prior art documents to the parts briefly described in this disclosure. .

2 shows a conceptual diagram of a pulse generating device 200, according to one embodiment of the present invention. Referring to FIG. 2, the pulse generator 200 includes a first charge switch Sc1, a second charge switch Sc2, a plurality of discharge switches Sd1, Sd2, ..., Sdn, and a plurality of capacitors C1. , C2, ..., Cn), charge trigger electrodes (not shown) for turning on/off the first charge switch Sc1 and the second charge switch Sc2, and discharge switches Sd1, Sd2, ... , Sdn) may include a discharge trigger electrode (not shown) for turning on/off.

In one embodiment, the first charge switch Sc1 and the second charge switch Sc2 may include a spark gap switch. The first charge switch Sc1 and the second charge switch Sc2 may be configured to be turned on and off at the same time. That is, when the first charge switch Sc1 is in an on state (ie short circuit), the second charge switch Sc2 is also in an on state (ie short circuit) and the first charge switch Sc1 is in an off state (ie open state). ), the second charge switch Sc2 is also off (ie, open). In one embodiment, the first charge switch Sc1 may include two electrodes facing each other. The second charge switch Sc2 may include two electrodes facing each other.

In one embodiment, each of the discharge switches Sd1, Sd2, ..., Sdn may include a spark gap switch. Each of the discharge switches Sd1, Sd2, ..., Sdn may include two electrodes facing each other. The discharge switches Sd1, Sd2, ..., and Sdn may be operated to turn on/off opposite to those of the first and second charge switches Sc1 and Sc2. For example, when the discharge switches Sd1, Sd2, ..., Sdn are in an on state, the first and second charge switches Sc1 and Sc2 are in an off state, and the discharge switches Sd1, Sd2, ..., When Sdn is in an off state, the first and second source switches Sc1 and Sc2 may operate to be in an on state.

In one embodiment, the plurality of capacitors (C1, C2, ..., Cn) are electrically connected to the first and second charge switches (Sc1, Sc2) and discharge switches (Sd1, Sd2, ..., Sdn) do. The plurality of capacitors (C1, C2, ..., Cn) is an electrical connection between the plurality of capacitors (C1, C2, ..., Cn) the first and second charge switch (Sc1, Sc2) and the discharge switch It may be configured to change according to the on/off state of (Sd1, Sd2, ..., Sdn). In one embodiment, when the first charge switch Sc1 and the second charge switch Sc2 are turned on, each of the plurality of discharge switches Sd1, Sd2, ..., Sdn is turned off, and the plurality of capacitors C1 and C2 are turned off. , ..., Cn) may be electrically connected in parallel. In a configuration in which each of the plurality of capacitors C1, C2, ..., Cn is electrically connected in parallel, each of the plurality of capacitors C1, C2, ..., Cn may be charged by the power supply (DC HV). there is. When the first charge switch Sc1 and the second charge switch Sc2 are off, each of the plurality of discharge switches Sd1, Sd2, ..., Sdn is turned on, and the plurality of capacitors C1, C2, ... , Cn) may be electrically connected in series. In a configuration in which each of the plurality of capacitors C1, C2, ..., Cn is electrically connected in series, the plurality of capacitors C1, C2, ..., Cn may be discharged. For example, in a configuration in which each of the plurality of capacitors C1, C2, ..., Cn is electrically connected in series, the final switch SO may spontaneously turn on to output a pulse. A pulse may be generated by charging and discharging the plurality of capacitors C1, C2, ..., Cn.

The on/off of the first and second charge switches Sc1 and Sc2 by the charge trigger electrode and the on/off of the discharge switches Sd1, Sd2, ... and Sdn by the discharge trigger electrode will be described later.

According to the present disclosure, a plurality of capacitors (C1, C2, ..., Cn) can be simultaneously and quickly charged by a pair of charging switches (first and second charging switches Sc1 and Sc2). When the charging of the plurality of capacitors (C1, C2, ..., Cn) is completed, the power supply and the circuit may be automatically disconnected. A pair of charge switches are turned off and a plurality of discharge switches (Sd1, Sd2, ..., Sdn) are turned on, and a plurality of capacitors (C1, C2, ..., Cn) are connected in series to generate high voltage. . Compared to the conventional method using a resistor (FIG. 1), charging and discharging can be performed quickly at regular intervals, and the power can be completely separated from the power after charging to more completely protect the power when discharging.

3A to 3D are structural diagrams of a portion of a pulse generating device according to an embodiment of the present invention.

Referring to Figures 3a, 3b and 3d, the pulse generator includes a rotating member 310, a control unit 320, a rotating shaft 325 of the rotating member, first and second charging switches Sc1 and Sc2, a plurality of discharge It includes switches Sd1, Sd2, ..., Sdn, a charge trigger electrode 330, and a discharge trigger electrode 340, 350, 360, 370.

Rotating member 310 has a rotating shaft 325 . The rotating member 310 may rotate the charge trigger electrode 330 and the discharge trigger electrode 340 , 350 , 360 , and 370 . The rotation axis 325 of the rotation member 310 may coincide with the rotation axis of the charge trigger electrode 330 and the discharge trigger electrode 340 , 350 , 360 , and 370 . That is, the rotation axis 325 of the rotation member 310 may be the same as the rotation axis of the charge trigger electrode 330 and the discharge trigger electrodes 340 , 350 , 360 , and 370 . Accordingly, when the rotating shaft 325 rotates, the charging trigger electrode 330 and the discharging trigger electrode 340 , 350 , 360 , and 370 may rotate.

In one embodiment, the rotating member 310 includes a motor. The motor may include a hydraulic, electric, or pneumatic motor. In one embodiment, the motor may be a pneumatic motor. The pneumatic motor may not be affected by pulse noise that may occur when the plurality of capacitors C1, C2, ..., Cn of the pulse generator 200 are charged/discharged.

In one embodiment, the controller 320 may be configured to control the rotating member 310 . The controller 320 may include a user interface (not shown), a processor (not shown), and a memory (not shown). The pulse generating device may receive a user's input through a user interface. The processor may rotate the rotating member 310 based on a user's input. The processor considers one cycle of charge and discharge of the plurality of capacitors (C1, C2, ..., Cn) as one pulse, and when the user's input is a frequency, the rotation of the rotating member 310 corresponding to the frequency The rotation number may be calculated and the rotating member 310 may be rotated according to the calculated number of rotations. In one embodiment, the number of rotations of the rotating member 310 corresponding to the frequency may be stored in the memory.

In one embodiment, the first charging switch Sc1 may include two facing first charging electrode pairs 332 and 334 . The second charging switch Sc2 may include two facing second charging electrode pairs 336 and 338 . The charge trigger electrode 330 is configured to turn on or off the first charge switch Sc1 and the second charge switch Sc2 according to the positional relationship with the first charge switch Sc1 and the second charge switch Sc2. It can be. In one embodiment, when the charging trigger electrode 330 rotates according to the rotation of the rotation axis 325 and is positioned between the first charging electrode pair 332 and 334 and the second charging electrode pair 336 and 338, The first charge switch Sc1 and the second charge switch Sc2 may be turned on. When the charging trigger electrode 330 is not positioned between the first charging electrode pair 332 and 334 and the second charging electrode pair 336 and 338 by rotating according to the rotation of the rotating shaft 325, the first charging switch (Sc1) and the second charge switch (Sc2) may be turned off. That is, according to the rotation of the rotating member 310, the charging trigger electrode 330 rotates, and accordingly, the first charging switch Sc1 and the second charging switch Sc2 may repeat the on state and the off state. there is.

In one embodiment, the plurality of discharge switches (Sd1, Sd2, ..., Sdn) may include two opposing discharge electrode pairs (342, 344, 352, 354, 362, 364, 372, 374). there is. The discharge trigger electrodes 340, 350, 360, and 370 turn on or off the discharge switches Sd1, Sd2, ..., Sdn according to the positional relationship with the discharge switches Sd1, Sd2, ..., Sdn. It can be configured as a list. In one embodiment, each of the discharge trigger electrodes 340, 350, 360, and 370 rotates according to the rotation of the rotation axis 325 to form the discharge electrode pair 342 and 344, the discharge electrode pair 352 and 354, and the discharge electrode. When positioned between the pairs 362 and 364 and the discharge electrode pairs 372 and 374, the discharge switches Sd1, Sd2, ..., Sdn may be turned on. Each of the discharge trigger electrodes 340, 350, 360, and 370 rotates according to the rotation of the rotation shaft 325 to form discharge electrode pairs 342 and 344, discharge electrode pairs 352 and 354, and discharge electrode pairs 362 and 364. ), when not positioned between the discharge electrode pairs 372 and 374, the discharge switches Sd1, Sd2, ..., Sdn may be turned off. That is, as the rotating member 310 rotates, the discharge trigger electrodes 340, 350, 360, and 370 rotate, and accordingly, the discharge switches Sd1, Sd2, ..., Sdn are turned on and off. can be repeated.

In one embodiment, any one of the first charge switch Sc1 and the second charge switch Sc2 and each discharge switch Sd1, Sd2, ..., Sdn overlap when viewed from the direction of the rotation axis 325. It can be. The charge trigger electrode 330 and the discharge trigger electrodes Sd1, Sd2, ..., Sdn have a bar-shaped extension in one direction and are orthogonal to each other with respect to the rotation axis 325. It can be. In one embodiment, at least a portion of the charging trigger electrode 330 passing between the first charging electrode pair 332 and 334 and the second charging electrode pair 336 and 338 is formed of an electrical conductor and the other portion is formed of an insulator. It can be. Discharge trigger electrodes 340, 350, 360, 370 passing between the discharge electrode pairs 342 and 344, the discharge electrode pairs 352 and 354, the discharge electrode pairs 362 and 364, and the discharge electrode pairs 372 and 374 ), at least a portion of which may be formed as an electrical conductor and the other portion as an insulator.

As shown in FIG. 3D , the charge trigger electrode 330 is disposed between the first charge switch Sc1 and the second charge switch Sc2 to enable the first charge switch Sc1 and the second charge switch Sc2. When turned on, the discharge trigger electrodes 340 and 370 are disposed at positions to turn off the discharge switches Sd1 and Sdn, respectively, thereby turning off the discharge switches Sd1 and Sdn.

Referring to FIGS. 3A and 3D , the first charge switch Sc1 and the second charge switch Sc2 are configured to be turned on/off by one charge trigger electrode 330 . The first charge switch Sc1 and the second charge switch Sc2 may be symmetrically disposed with respect to the rotation axis 325 . One electrode 332 of the first charging electrode pair 332, 334, one electrode 336 of the second charging electrode pair 336, 338, and one electrode 336 of the first charging electrode pair 332, 334 The electrode 334 of and one electrode 338 of the second charging electrode pairs 336 and 338 may be disposed on one plane. In addition, each of the discharge switches Sd1, Sd2, ..., Sdn is configured to be turned on/off by one discharge trigger electrode 340, 350, 360, 370, respectively. For example, the discharge switch (Sd1) by the discharge trigger electrode 340, the discharge switch (Sd2) by the discharge trigger electrode 350, the discharge switch (Sd3) by the discharge trigger electrode 360, the discharge The switch Sdn is configured to be turned on/off, respectively, by the discharge trigger electrode 370. As shown in FIG. 3A, the discharge switches Sd1, Sd2, ..., Sdn may be formed one by one alternately left and right.

Referring to FIG. 3B , the discharge switches Sd1, Sd2, ..., Sdn may be formed to gather on one side. That is, the discharge switches Sd1, Sd2, ..., Sdn may be formed to overlap each other when viewed from the direction of the rotation axis 325.

Referring to FIG. 3C, the two discharge switches Sd1 and Sd2, Sd3 and Sd4, and (Sdn-1 and Sdn) are a discharge trigger electrode 340, a discharge trigger electrode 350, and a discharge trigger electrode 370, respectively. ) may be configured to be turned on/off by That is, two discharge switches can be simultaneously turned on/off by one discharge trigger electrode.

In one embodiment, at least a portion (331a, 331b) of the charging trigger electrode 330 passing between the first charging electrode pair (332, 334) and the second charging electrode pair (336, 338) is an electrical conductor, The outer portion may be formed of an insulator. End portions 371a and 371b of the discharge trigger electrode 370 disposed between the pair of discharge switch electrodes 372, 374 or 372-1 and 374-1 may be conductors, and the remaining portions may be insulators. Although not indicated by reference numerals, at least a portion of the discharge trigger electrodes 340 and 350 passing between the discharge electrode pairs 342 and 344, the discharge electrode pairs 352 and 354, and the discharge electrode pairs 362 and 364 are electrically As a conductor, other parts may be formed as an insulator.

In one embodiment, the distance between the first charging electrode pair (332, 334) and the second charging electrode pair (336, 338) is the discharging electrode pair (342, 344), the discharging electrode pair (352, 354), the discharging electrode pair (362, 364), it may be greater than the distance between the discharge electrode pairs (372, 374). Accordingly, the thickness of the charge trigger electrode 330 may be thicker than the thickness of the discharge trigger electrodes 340, 350, 360, and 370.

4a to 4d are diagrams illustrating the operation of a pulse generator according to an embodiment of the present invention. Based on FIG. 4A, FIG. 4B shows that the rotation axis 420 rotates 90 degrees in FIG. 4A, FIG. 4C shows that the rotation axis 420 rotates 180 degrees, and FIG. 4D shows that the rotation axis 420 rotates 270 degrees. The charge trigger electrode 430 exists in a different dimension from the discharge trigger electrode 420 and is shown as a dotted line.

Referring to FIGS. 4A to 4D , at least one of the discharge switch electrode 412 and the charge switch electrodes 432 and 434 overlap when viewed from the direction of the rotation axis 420 . Referring to FIG. 4A, the discharge trigger electrode 410 overlaps the discharge switch electrode 412, the charge trigger electrode 430 forms a right angle to the discharge trigger electrode 410, and the charge switch electrodes 432 and 434 do not overlap Accordingly, the discharge switch is in an on state and the charge switch is in an off state. Referring to FIG. 4B, compared to FIG. 4A, the rotating shaft 420 is rotated by 90 degrees, so that the discharge trigger electrode 410 does not overlap the discharge switch electrode 412, and the charge trigger electrode 430 does not overlap the charge switch electrode 430. It overlaps with the electrodes 432 and 434. Accordingly, the discharge switch is off and the charge switch is on. Referring to FIG. 4C, compared to FIG. 4A, the rotating shaft 420 rotates 180 degrees so that the discharge trigger electrode 410 overlaps the discharge switch electrode 412, and the charge trigger electrode 430 overlaps the charge switch electrode. It does not overlap with (432, 434). Accordingly, the discharge switch is in an on state and the charge switch is in an off state. Referring to 4d, compared to FIG. 4a, the rotating shaft 420 rotates 270 degrees so that the discharge trigger electrode 410 does not overlap the discharge switch electrode 412 and the charge trigger electrode 430 does not overlap the charge switch electrode. It overlaps with (432, 434). Accordingly, the discharge switch is off and the charge switch is on. Although not shown, compared to FIG. 4A, when the rotating shaft 420 rotates 360 degrees (one rotation), the discharge trigger electrode 410 and the charge trigger electrode 430 are disposed at the same position as in FIG. 4A.

In this way, when the rotating shaft 420 rotates once, the charge switch and the discharge switch are turned on/off twice (ie, pulses are generated twice). Accordingly, it will be appreciated that the number of pulses per minute can be adjusted by adjusting the number of revolutions per minute of the rotating member. For example, by rotating the rotating member at 30,000 rpm, pulses can be generated at a frequency of 1 kHz.

In one embodiment, the positional relationship of the discharge trigger electrode 410, the charge trigger electrode 430, the discharge switch electrode 412, and the charge switch electrodes 432 and 434 is such that the charge switch and the discharge switch are not turned on or off at the same time. However, it will be understood that various adjustments are made.

In one embodiment, at least one of the discharge switch electrode 412 and the charge switch electrodes 432 and 434 may not overlap when viewed from the direction of the rotation axis 420 . For example, the discharge switch electrode 412 and the charge switch electrodes 432 and 434 may be spaced apart at a predetermined angle along an arc centered on the rotation axis 420 . The discharge trigger electrode 410 and the charge trigger electrode 430 may not be perpendicular or form different angles.

For example, the discharge switch electrode 412 and the charge switch electrodes 432 and 434 may be spaced apart from each other by 90 degrees along an arc centered on the rotation axis 420 . In this case, the discharge trigger electrode 410 and the charge trigger electrode 430 may be parallel.

5A is a conceptual diagram of a discharge switch of a pulse generator according to an embodiment of the present invention.

In one embodiment, the discharge switch Sd may include two electrodes 512 and 513 facing each other. The discharge switch Sd may include two opposing insulator plates 511 and 513 and discharging electrode pairs 512 and 513 disposed on the insulator plates 511 and 513 and facing each other. Each of the insulator plates 511 and 513 is configured not to be affected by rotation of the rotating shaft 520 . When the rotating shaft 520 rotates, the insulator plates 511 and 513 are fixed and do not rotate. The center of rotation of the rotation shaft 520 and the discharge trigger electrode 510 coincide, and the discharge trigger electrode 510 is configured to rotate together by the rotation of the rotation shaft 520 .

5B is a conceptual diagram of a charging switch of a pulse generator according to an embodiment of the present invention.

In one embodiment, the first charging switch Sc1 may include first charging electrode pairs 532 and 534 facing each other. The second charge switch Sc2 may include second charge electrode pairs 536 and 538 facing each other. The first charging switch Sc1 may include two facing insulator plates 531 and 533 and first charging electrode pairs 532 and 534 disposed on the insulator plates 531 and 533 and facing each other. The second charge switch Sc2 may include second charge electrode pairs 536 and 538 disposed on the insulator plates 531 and 533 and facing each other. The second charging electrode pairs 536 and 538 and the first charging electrode pairs 532 and 534 may be symmetrically disposed around the rotation axis 520 . Each of the insulator plates 531 and 533 is configured not to be affected by rotation of the rotation shaft 520 . When the rotating shaft 520 rotates, the insulator plates 531 and 533 are fixed and do not rotate. The rotating shaft 520 and the charging trigger electrode 530 coincide with the center of rotation, and the charging trigger electrode 530 is configured to rotate together by the rotation of the rotating shaft 520 .

Although not shown, in one embodiment, the discharge trigger electrode 510 and/or the charge trigger electrode 530 may also have a structure in which a conductor is formed on an insulator.

It will be appreciated that the switch used in the above-described pulse generating device may be used independently and may be combined with other circuits or devices. The switch includes a second charge switch that is turned on and off at the same time as the first charge switch, a charge trigger electrode configured to turn on or off a plurality of discharge switches, the first charge switch and the second charge switch, and a charge trigger. and a rotating member configured to rotate the discharge trigger electrode, the charge trigger electrode, and the discharge trigger electrode configured to operate in conjunction with and turn on or off each of the plurality of discharge switches. As the rotating member rotates, the charge trigger electrode is moved to a position where the first charge switch and the second charge switch are turned on, and the discharge trigger electrode is moved to a position where the discharge switch is turned off, or according to the rotation of the rotary member, the charge trigger electrode is moved. The electrode may be configured to be moved to a position to turn off the first charge switch and the second charge switch, and the discharge trigger electrode to be moved to a position to turn on each of the plurality of discharge switches.

The above-described pulse generator has a configuration in which a plurality of capacitors are electrically connected in series or in parallel according to on/off of the discharge switch and the charge switch. Accordingly, it will be appreciated that the capacitor may be replaced by other circuit components, such as resistors, inductors, loads, and the like.

In the pulse generator, when the charge switch is on and the discharge switch is off, the plurality of capacitors are electrically connected in parallel and charged, and when the charge switch is off and the discharge switch is on, the plurality of capacitors are electrically connected in series. and perform the discharging operation. At this time, the time required for charging and the time required for discharging may be different. It will be understood that the positional relationship of the discharge switch and/or the charge switch can be adjusted according to the time required for charging and the time required for discharging.

As described above, although the embodiments have been described with limited drawings, those skilled in the art can apply various technical modifications and variations based on the above. For example, the described techniques may be performed in an order different from the method described, and/or components of the described system, structure, device, circuit, etc. may be combined or combined in a different form than the method described, or other components may be used. Or even if it is replaced or substituted by equivalents, appropriate results can be achieved.

Therefore, other implementations, other embodiments, and equivalents of the claims are within the scope of the following claims.

Claims (17)

delete delete delete delete a first charging switch;
a second charge switch turned on and off at the same time as the first charge switch;
a plurality of discharge switches;
a plurality of capacitors electrically connected to the first charge switch, the second charge switch, and the plurality of discharge switches;
rotating member;
a charge trigger electrode configured to turn on or off the first charge switch and the second charge switch according to a positional relationship with the first charge switch and the second charge switch; and
A discharge trigger electrode configured to turn on or off each of the plurality of discharge switches according to a positional relationship with the plurality of discharge switches, configured to mechanically interlock with the charge trigger electrode,
When the first charge switch and the second charge switch are turned on, each of the plurality of discharge switches is turned off, so that each of the plurality of capacitors is electrically connected in parallel to be charged by DC power,
When the first charge switch and the second charge switch are off, each of the plurality of discharge switches is turned on, so that each of the plurality of capacitors is electrically connected in series,
A rotation axis of the rotation member coincides with rotation axes of the charge trigger electrode and the discharge trigger electrode, so that the charge trigger electrode and the discharge trigger electrode rotate according to the rotation of the rotation member, so that the charge trigger electrode rotates with the first charging electrode. A switch and the second charge switch are moved to a position to turn on or off, and the discharge trigger electrode is configured to move to a position to turn on or turn off the discharge switch,
Any one of the first charge switch and the second charge switch and each discharge switch overlap when viewed in the direction of the rotation axis,
The charge trigger electrode and the discharge trigger electrode have a bar-shaped extension in one direction and are configured to be orthogonal to each other with respect to the rotation axis,
pulse generator. According to claim 5,
and a controller configured to control a pulse generating period of the pulse generating device by controlling the number of revolutions of the rotating member. According to claim 5,
The rotating member is a pneumatic motor, the pulse generator. a first charging switch;
a second charge switch turned on and off at the same time as the first charge switch;
a plurality of discharge switches;
a plurality of capacitors electrically connected to the first charge switch, the second charge switch, and the plurality of discharge switches;
rotating member
a charge trigger electrode configured to turn on or off the first charge switch and the second charge switch according to a positional relationship with the first charge switch and the second charge switch; and
A discharge trigger electrode configured to turn on or off each of the plurality of discharge switches according to a positional relationship with the plurality of discharge switches, configured to mechanically interlock with the charge trigger electrode,
When the first charge switch and the second charge switch are turned on, each of the plurality of discharge switches is turned off, so that each of the plurality of capacitors is electrically connected in parallel to be charged by DC power,
When the first charge switch and the second charge switch are off, each of the plurality of discharge switches is turned on, so that each of the plurality of capacitors is electrically connected in series,
A rotation axis of the rotation member coincides with rotation axes of the charge trigger electrode and the discharge trigger electrode, so that the charge trigger electrode and the discharge trigger electrode rotate according to the rotation of the rotation member, so that the charge trigger electrode rotates with the first charging electrode. A switch and the second charge switch are moved to a position to turn on or off, and the discharge trigger electrode is configured to move to a position to turn on or turn off the discharge switch,
The first charging switch includes two first insulator plates facing each other and having a center of rotation coincident with the rotation axis, and first charging electrode pairs disposed on each of the first insulator plates and facing each other,
The second charging switch includes second charging electrode pairs disposed on each of the first insulator plates and facing each other, wherein the second charging electrode pair and the first charging electrode pair are symmetrically disposed around the rotation axis. do,
Each of the discharge switches includes two second insulator plates facing each other with a center of rotation coincident with the rotation axis, and a pair of discharge electrodes disposed on each second insulator plate and facing each other,
pulse generator. According to claim 8,
The charging trigger electrode is configured to pass between the first charging electrode pair and the second charging electrode pair according to rotation of the rotating member,
The discharge trigger electrode is configured to pass between the discharge electrode pair according to rotation of the rotating member. According to claim 8,
and a controller configured to control a pulse generating period of the pulse generating device by controlling the number of revolutions of the rotating member. According to claim 8,
The rotating member is a pneumatic motor, the pulse generator. a first charging switch; a second charge switch turned on and off at the same time as the first charge switch; a plurality of discharge switches; a plurality of capacitors electrically connected to the first charge switch, the second charge switch, and the plurality of discharge switches; a charge trigger electrode configured to turn on or off the first charge switch and the second charge switch; a discharge trigger electrode configured to turn on or off each of the plurality of discharge switches; and a rotating member for rotating the charge trigger electrode and the discharge trigger electrode.
The axis of rotation of the rotating member coincides with the axis of rotation of the charge trigger electrode and the discharge trigger electrode,
Any one of the first charge switch and the second charge switch and each discharge switch overlap when viewed in the direction of the rotation axis,
The charge trigger electrode and the discharge trigger electrode have a bar-shape extending in one direction and are configured to be orthogonal to each other with respect to the rotation axis,
The method,
receiving a user's input; and
Rotating the rotating member based on the user's input;
Rotating the rotating member,
By simultaneously moving the charge trigger electrode and the discharge trigger electrode, the charge trigger electrode is moved to a position where the first charge switch and the second charge switch are turned on, and the discharge trigger electrode is moved to a position where the discharge switch is turned off. charging the plurality of capacitors by electrically connecting each of the plurality of capacitors in parallel; and
Simultaneously moving the charge trigger electrode and the discharge trigger electrode to move the charge trigger electrode to a position where the first charge switch and the second charge switch are turned off and the discharge trigger electrode to turn on each of the plurality of discharge switches moving into position, electrically connecting the plurality of capacitors in series to discharge the plurality of capacitors,
A control method of a pulse generator. According to claim 12,
The user's input corresponds to the frequency of the pulse when the charging step and the discharging step are considered as one pulse,
The step of rotating the rotating member comprises calculating the number of rotations of the rotating member corresponding to the frequency and rotating the rotating member according to the calculated number of rotations. a first charging switch; a second charge switch turned on and off at the same time as the first charge switch; a plurality of discharge switches; a plurality of capacitors electrically connected to the first charge switch, the second charge switch, and the plurality of discharge switches; a charge trigger electrode configured to turn on or off the first charge switch and the second charge switch; a discharge trigger electrode configured to turn on or off each of the plurality of discharge switches; and a rotating member for rotating the charge trigger electrode and the discharge trigger electrode.
The axis of rotation of the rotating member coincides with the axis of rotation of the charge trigger electrode and the discharge trigger electrode,
The first charging switch includes two first insulator plates facing each other and having a center of rotation coincident with the rotation axis, and first charging electrode pairs disposed on each of the first insulator plates and facing each other,
The second charging switch includes second charging electrode pairs disposed on each of the first insulator plates and facing each other, wherein the second charging electrode pair and the first charging electrode pair are symmetrically disposed around the rotation axis. do,
The method,
receiving a user's input; and
Rotating the rotating member based on the user's input;
Rotating the rotating member,
By simultaneously moving the charge trigger electrode and the discharge trigger electrode, the charge trigger electrode is moved to a position where the first charge switch and the second charge switch are turned on, and the discharge trigger electrode is moved to a position where the discharge switch is turned off. charging the plurality of capacitors by electrically connecting each of the plurality of capacitors in parallel; and
Simultaneously moving the charge trigger electrode and the discharge trigger electrode to move the charge trigger electrode to a position where the first charge switch and the second charge switch are turned off and the discharge trigger electrode to turn on each of the plurality of discharge switches moving into position, electrically connecting the plurality of capacitors in series to discharge the plurality of capacitors,
A control method of a pulse generator. According to claim 14,
The user's input corresponds to the frequency of the pulse when the charging step and the discharging step are considered as one pulse,
The step of rotating the rotating member comprises calculating the number of rotations of the rotating member corresponding to the frequency and rotating the rotating member according to the calculated number of rotations. a first charging switch;
a second charge switch turned on and off at the same time as the first charge switch;
a plurality of discharge switches;
a charge trigger electrode configured to turn on or off the first charge switch and the second charge switch;
a discharge trigger electrode configured to operate in conjunction with the charge trigger electrode and turn each of the plurality of discharge switches on or off; and
A switch including a rotating member for rotating the charge trigger electrode and the discharge trigger electrode,
The axis of rotation of the rotating member coincides with the axis of rotation of the charge trigger electrode and the discharge trigger electrode,
Any one of the first charge switch and the second charge switch and each discharge switch overlap when viewed in the direction of the rotation axis,
The charge trigger electrode and the discharge trigger electrode have a bar-shape extending in one direction and are configured to be orthogonal to each other with respect to the rotation axis,
As the rotating member rotates, the charge trigger electrode and the discharge trigger electrode move simultaneously, the charge trigger electrode moves to a position where the first charge switch and the second charge switch are turned on, and the discharge trigger electrode moves to a position where the first charge switch and the second charge switch are turned on. The charge trigger electrode and the discharge trigger electrode are simultaneously moved to a position where the discharge switch is turned off or the rotation member rotates, and the charge trigger electrode turns off the first charge switch and the second charge switch. position and the discharge trigger electrode is configured to be moved to a position to turn on each of the plurality of discharge switches. a first charging switch;
a second charge switch turned on and off at the same time as the first charge switch;
a plurality of discharge switches;
a charge trigger electrode configured to turn on or off the first charge switch and the second charge switch;
a discharge trigger electrode configured to operate in conjunction with the charge trigger electrode and turn each of the plurality of discharge switches on or off; and
A switch including a rotating member for rotating the charge trigger electrode and the discharge trigger electrode,
The axis of rotation of the rotating member coincides with the axis of rotation of the charge trigger electrode and the discharge trigger electrode,
The first charging switch includes two first insulator plates facing each other and having a center of rotation coincident with the rotation axis, and first charging electrode pairs disposed on each of the first insulator plates and facing each other,
The second charging switch includes second charging electrode pairs disposed on each of the first insulator plates and facing each other, wherein the second charging electrode pair and the first charging electrode pair are symmetrically disposed around the rotation axis. do,
As the rotating member rotates, the charge trigger electrode and the discharge trigger electrode move simultaneously, the charge trigger electrode moves to a position where the first charge switch and the second charge switch are turned on, and the discharge trigger electrode moves to a position where the first charge switch and the second charge switch are turned on. The charge trigger electrode and the discharge trigger electrode are simultaneously moved to a position where the discharge switch is turned off or the rotation member rotates, and the charge trigger electrode turns off the first charge switch and the second charge switch. position and the discharge trigger electrode is configured to be moved to a position to turn on each of the plurality of discharge switches.

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