CN108245238A - A kind of control method of medical rapid blood coagulation diced system - Google Patents
A kind of control method of medical rapid blood coagulation diced system Download PDFInfo
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- CN108245238A CN108245238A CN201611236335.9A CN201611236335A CN108245238A CN 108245238 A CN108245238 A CN 108245238A CN 201611236335 A CN201611236335 A CN 201611236335A CN 108245238 A CN108245238 A CN 108245238A
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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
- 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
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- G—PHYSICS
- G05—CONTROLLING; REGULATING
- G05B—CONTROL OR REGULATING SYSTEMS IN GENERAL; FUNCTIONAL ELEMENTS OF SUCH SYSTEMS; MONITORING OR TESTING ARRANGEMENTS FOR SUCH SYSTEMS OR ELEMENTS
- G05B19/00—Programme-control systems
- G05B19/02—Programme-control systems electric
- G05B19/04—Programme control other than numerical control, i.e. in sequence controllers or logic controllers
- G05B19/042—Programme control other than numerical control, i.e. in sequence controllers or logic controllers using digital processors
- G05B19/0428—Safety, monitoring
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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
- A61B2018/00607—Coagulation and cutting with the same instrument
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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
- A61B2018/00636—Sensing and controlling the application of energy
- A61B2018/00696—Controlled or regulated parameters
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- G—PHYSICS
- G05—CONTROLLING; REGULATING
- G05B—CONTROL OR REGULATING SYSTEMS IN GENERAL; FUNCTIONAL ELEMENTS OF SUCH SYSTEMS; MONITORING OR TESTING ARRANGEMENTS FOR SUCH SYSTEMS OR ELEMENTS
- G05B2219/00—Program-control systems
- G05B2219/20—Pc systems
- G05B2219/26—Pc applications
- G05B2219/2617—Eye, ophthalmic, surgery system
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Abstract
The invention discloses a kind of control methods of medical rapid blood coagulation diced system, belong to the field of medical instrument technology, including cut mode and blood coagulation closed mode, it solves the problems, such as while using manual switch and Foot-controlled switch control surgical instrument blood coagulation, solves and control problem of the both of which to rapid blood coagulation diced system is closed using cutting and blood coagulation.
Description
Technical field
The invention belongs to the field of medical instrument technology.
Background technology
In outer the reach of science history, operative hemorrhage is one of an important factor for obstruction surgery develops, and seeks cutting and adds
The surgical technic or method of hemostasis are always through the development process of surgery, all kinds of surgical devices with cutting or hemostatic function
Tool also releases one after another.Wherein, most representative is exactly the surgical instrument for being cut using high frequency high voltage arc simultaneously electric coagulation hemostasis, it
It is also one of modern surgery operation commonly used equipment.
Invention content
The object of the present invention is to provide a kind of control methods of medical rapid blood coagulation diced system, solve while use
It the problem of manual switch and Foot-controlled switch control surgical instrument blood coagulation, solves and both of which is closed to fast using cutting and blood coagulation
The control problem of rapid hardening blood diced system.
To achieve the above object, the present invention uses following technical scheme:
A kind of control method of medical rapid blood coagulation diced system, includes the following steps:
Step 1:Medical rapid blood coagulation diced system is set up, medical rapid blood coagulation diced system includes controller and doctor
Treat instrument, controller connection medical instrument;
Controller includes button, floor push, manual switch, photoelectric isolating circuit, buffer, loudspeaker, power amplifier, overvoltage guarantor
Protect module, digital analog converter, high-voltage suppling power, inverter circuit, relay, voltage sampling module, current sampling module, radio frequency
Drive module, radiofrequency signal generation module, the second analog-digital converter, the first analog-digital converter, CPU module, is shown NAND gate module
Display screen and identification device, floor push and manual switch are all connected with photoelectric isolation module, photoelectric isolation module, identification device and press
Key is all connected with buffer, buffer, power amplifier, digital analog converter, the second analog-digital converter, the first analog-digital converter, relay, with
NOT gate module and display screen are connect with CPU module;
Loudspeaker connect power amplifier, high-voltage suppling power connection overvoltage protective module, overvoltage protective module connection CPU module, number
Mode converter connects high-voltage suppling power, and high-voltage suppling power is also connected with radio-frequency driven module, the connection of radiofrequency signal generation module
NAND gate module, NAND gate module are also connected with radio-frequency driven module, and radio-frequency driven module is also connected with inverter circuit, relay connection
Inverter circuit, voltage sampling module and current sampling module are arranged at the output terminal of inverter circuit;
Voltage sampling module connects the second analog-digital converter, and current sampling module connects the first analog-digital converter;
Medical instrument passes through conducting wire connection plug;
Step 2:Controller is initialized, and CPU module is opened delay timer and postponed, and waits for the initial of controller
Change and complete;
Step 3:Controller shows initialization interface by display screen;
Step 4:When there is plug to be inserted into socket, controller identifies the Medical treatment device being connect with the plug by identification device
The type of tool;
Step 5:Controller is judged whether there is by key pressing, and reads key information;
Step 10:Controller judges whether there is floor push or manual switch action, and reads foot-operated open by CPU module
Pass or the information of manual switch;
Step 11:Controller performs adjustment power output task, presets 5 according to the size of output power in the controller
Gear, the max-thresholds of 5 gears are respectively power P 1, power P 2, power P 3, power P 4 and power P 5, set 5 resistances
Anti- is respectively impedance R1, impedance R2, impedance R3, impedance R4 and impedance R5, and 1 corresponding impedance of power P is impedance R1, and power P 2 is right
The impedance answered is impedance R2, and 3 corresponding impedance of power P is impedance R3, and 4 corresponding impedance of power P is impedance R4, and power P 5 corresponds to
Impedance for impedance R5, include the following steps:
Step S1:Controller will control medical instrument according to the type of the medical instrument identified in step 4
Pattern be divided into cut mode and blood coagulation closed mode, setting cut mode is represented with CUT patterns, blood coagulation closed mode Seal
Pattern represents;
Step S2:When controller enters CUT patterns according to the type of medical instrument, CUT patterns include the following steps:
Step A1:CUT mode initialisations, include the following steps:
Step B1:User is pressed by the gear of button selection control on a display screen, CPU module by buffer reading
The state of key, and judge the selected gear of user by calculating the number that user pushes button;
Step B2:Controller control relay is closed, and the output terminal of inverter circuit is made to be electrically connected with medical instrument;
Step B3:Controller obtains prompt tone parameter by CPU module, and the prompt tone parameter is PWN data;
Step B4:Controller sets output frequency according to the type of medical instrument;
Step B5:CPU module opens timer, starts timing;
Step A2:Controller performs CUT tasks, includes the following steps:
Step C1:The voltage that controller acquires inverter circuit output terminal by voltage sampling module and current sampling module is believed
Number and current signal, the first analog-digital converter voltage signal is converted into be sent to CPU module after digital voltage data, the second mould
Current signal is converted into being sent to CPU module after digital current data by number converter, CPU module according to digital current data and
Digital voltage data simultaneously passes through the output impedance that Ohm's law calculates inverter circuit output terminal, sets the output impedance and represents
For impedance Ri;
Step C2:Controller judges whether user by button has selected CUT patterns:It is then to perform step C3;It is no, then,
Perform step 12;
Step C3:Controller judges whether user presses manual switch or by foot switch, so as to control medical instrument
Unlatching:It is then to perform step C4;It is no, then, perform step 12;
Step C4:CPU module must be worth to whether the value of specific impedance Ri is less than impedance R1:It is then to perform step C5;It is no, then
Perform step C8;
Step C5:Radiofrequency signal generation module generates high-frequency signal, and gives high frequency signal transmission to NAND gate module, and non-
Door module, which exports high-frequency signal, gives radio-frequency driven module, and CPU module controls high-frequency signal by controlling NAND gate module
Output, the driving power that CPU module controls high-voltage suppling power to provide radio-frequency driven module by controlling digital analog converter,
Radio-frequency driven module exports high-frequency driving voltage according to the high-frequency signal and the driving power, and by high-frequency driving voltage
Inverter circuit is sent to, inverter circuit generates high-frequency driving signal according to high-frequency driving voltage, and passes through relay to Medical treatment device
Tool provides high-frequency driving signal;
Step C6:Controller adjusts output power according to the method for step C5, and output power is made to be no more than power P 1;
Step C7:Whether CPU module judges overtime during counter counts:It is no, then perform step C3;It is that then CPU module is to work(
It puts and sends prompt tone parameter, power amplifier sends out prompt tone by loudspeaker, and performs step 12;
Step C8:Controller judges whether user presses manual switch or by foot switch, so as to control medical instrument
Unlatching:It is then to perform step C9;It is no, then, perform step 12;
Step C9:Whether CPU module is to the value of specific impedance Ri between impedance R1 must be worth and impedance R2 must be worth:It is then to hold
Row step C10;It is no, then perform step C12;
Step C10:Controller adjusts output power according to the method for step C5, makes output power in power P 1 and power P 2
Between;
Step C11:Whether CPU module judges overtime during counter counts:It is no, then perform step C8;Be, then CPU module to
Power amplifier sends prompt tone parameter, and power amplifier sends out prompt tone by loudspeaker, and performs step 12;
Step C12:Controller judges whether user presses manual switch or by foot switch, so as to control medical instrument
Unlatching:It is then to perform step C13;It is no, then, perform step 12;
Step C13:Whether CPU module is to the value of specific impedance Ri between impedance R2 must be worth and impedance R3 must be worth:It is then to hold
Row step C14;It is no, then perform step C16;
Step C14:Controller adjusts output power according to the method for step C5, makes output power in power P 2 and power P 3
Between;
Step C15:Whether CPU module judges overtime during counter counts:It is no, then perform step C12;Be, then CPU module to
Power amplifier sends prompt tone parameter, and power amplifier sends out prompt tone by loudspeaker, and performs step 12;
Step C16:Controller judges whether user presses manual switch or by foot switch, so as to control medical instrument
Unlatching:It is then to perform step C17;It is no, then, perform step 12;
Step C17:Whether CPU module is to the value of specific impedance Ri between impedance R3 must be worth and impedance R4 must be worth:It is then to hold
Row step C18;It is no, then perform step C20;
Step C18:Controller adjusts output power according to the method for step C5, makes output power in power P 3 and power P 4
Between;
Step C19:Whether CPU module judges overtime during counter counts:It is no, then perform step C16;Be, then CPU module to
Power amplifier sends prompt tone parameter, and power amplifier sends out prompt tone by loudspeaker, and performs step 12;
Step C20:Controller judges whether user presses manual switch or by foot switch, so as to control medical instrument
Unlatching:It is then to perform step C21;It is no, then, perform step 12;
Step C21:Whether CPU module is to the value of specific impedance Ri between impedance R4 must be worth and impedance R5 must be worth:It is then to hold
Row step C22;It is no, then perform step C24;
Step C22:Controller adjusts output power according to the method for step C5, makes output power in power P 4 and power P 5
Between;
Step C23:Whether CPU module judges overtime during counter counts:It is no, then perform step C20;Be, then CPU module to
Power amplifier sends prompt tone parameter, and power amplifier sends out prompt tone by loudspeaker, and performs step 12;
Step C24:Controller judges whether user presses manual switch or by foot switch, so as to control medical instrument
Unlatching:It is then to perform step C25;It is no, then, perform step 12;
Step C25:CPU module must be worth to whether the value of specific impedance Ri is more than impedance R5:It is then to perform step C26;It is no,
Then perform step C3;
Step C26:Controller adjusts output power according to the method for step C5, and output power is made to be more than power P 5;
Step C27:Whether CPU module judges overtime during counter counts:It is no, then perform step C24;Be, then CPU module to
Power amplifier sends prompt tone parameter, and power amplifier sends out prompt tone by loudspeaker, and performs step 12;
Step S3:When controller enters Seal patterns according to the type of medical instrument, Seal patterns include the following steps:
Step D1:Seal mode initialisations, include the following steps:
Step E1:User is pressed by the gear of button selection control on a display screen, CPU module by buffer reading
The state of key, and judge the selected gear of user by calculating the number that user pushes button;
Step E2:Controller control relay is closed, and the output terminal of inverter circuit is made to be electrically connected with medical instrument;
Step E3:Controller obtains the prompt tone parameter by CPU module, and the prompt tone parameter is PWN data;
Step E4:Controller sets output frequency according to the type of medical instrument;
Step E5:CPU module opens timer, starts timing;
Step E6:Controller judges whether the output terminal of inverter opens a way according to the size of impedance Ri:It is that then controller leads to
It crosses loudspeaker and sends out prompt tone, controller stops providing high-frequency driving signal to medical instrument, performs step 12;It is no, then perform step
Rapid E7;
Step E7:Controller obtains the value of impedance Ri;
Step E8:Setup parameter initializes return value, and controller judges whether user has selected Seal patterns:It is then to join
Number initialization return value is equal to 1;No, then parameter initialization return value is equal to O;
Step D2:Controller performs the first Seal tasks, includes the following steps:
Step F1:Judge whether parameter initialization return value is equal to 1:It is then to perform step F2;No, then controller is sent out
Prompt tone, and stop providing high-frequency driving signal to medical instrument, perform step 12;
Step F2:Controller judges whether user presses manual switch or by foot switch, so as to control medical instrument
Unlatching:It is then to perform step F3;No, then controller sends out prompt tone, and stops providing medical instrument in high-frequency drive letter
Number, perform step 12;
Step F3:Controller judges whether the output terminal of inverter circuit is short-circuit according to the size of impedance Ri:It is, then controller
Prompt tone is sent out, and stops providing high-frequency driving signal to medical instrument, performs step 12;It is no, then perform step F4;
Step F4:Controller judges that the value of impedance Ri is no less than the value of impedance R1:It is then to perform step F5;It is no, then it performs
Step F7;
Step F5:Controller adjusts output power according to the method for step C5, and output power is made to be less than power P 1;
Step F6:Whether controller judges overtime during counter counts:It is no, then perform step F2;It is that controller sends out prompting
Sound, and stop providing high-frequency driving signal to medical instrument, perform step 12;
Step F7:Controller judges whether user presses manual switch or by foot switch, so as to control medical instrument
Unlatching:It is then to perform step F8;No, then controller sends out prompt tone, and stops providing medical instrument in high-frequency drive letter
Number, perform step 12;
Step F8:Whether controller judges the value of impedance Ri between the value of impedance R1 and the value of impedance R2:It is no:It is, then
Perform step F9;It is no, then perform step F11;
Step F9:Controller adjusts output power according to the method for step C5, makes output power in power P 1 and power P 2
Between;
Step F10:Whether controller judges overtime during counter counts:It is no, then perform step F7;It is that controller is sent out to carry
Show sound, and stop providing high-frequency driving signal to medical instrument, perform step 12;
Step F11:Controller judges whether user presses manual switch or by foot switch, so as to control medical instrument
Unlatching:It is then to perform step F12;No, then controller sends out prompt tone, and stops providing medical instrument in high-frequency drive letter
Number, perform step 12;
Step F12:Whether the first Seal task return values of setup parameter, controller judge the value of impedance Ri impedance R2's
Between value and the value of impedance R3:It is then to perform step F13;No, then the first Seal tasks return value is equal to 1, performs step D3;
Step F13:Controller adjusts output power according to the method for step C5, makes output power in power P 2 and power P 3
Between;
Step F14:Whether controller judges overtime during counter counts:It is no, then perform step F11;It is that controller is sent out to carry
Show sound, and stop providing high-frequency driving signal to medical instrument, perform step 12;
Step D3:Controller performs the 2nd Seal tasks, includes the following steps:
Step G1:It is no that controller judges that the first Seal tasks return value is equal to 1:It is no, then perform step 12;It is then to perform
Step G2;
Step G2:Controller judges whether user presses manual switch or by foot switch, so as to control medical instrument
Unlatching:It is then to perform step G3;No, then controller sends out prompt tone, and stops providing medical instrument in high-frequency drive letter
Number, perform step 12;
Step G3:Whether controller judges the value of impedance Ri between the value of impedance R3 and the value of impedance R4:It is then to perform
Step G4;It is no, then perform step G6;
Step G4:Controller adjusts output power according to the method for step C5, makes output power in power P 3 and power P 4
Between;
Step G5:Whether controller judges overtime during counter counts:It is no, then perform step G2;It is that controller sends out prompting
Sound, and stop providing high-frequency driving signal to medical instrument, perform step 12;
Step G6:Controller judges whether user presses manual switch or by foot switch, so as to control medical instrument
Unlatching:It is then to perform step G7;No, then controller sends out prompt tone, and stops providing medical instrument in high-frequency drive letter
Number, perform step 12;
Step G7:Controller judges whether medical instrument is over-pressed according to the voltage signal that voltage sampling module acquires:It is, then
Perform step G8;It is no, then perform step G9;
Step G8:Controller adjusts output power according to the method for step C5, reduces output power;Perform step G10;
Step G9:Controller adjusts output power according to the method for step C5, increases output power;
Step G10:Whether controller judges overtime during counter counts:It is no, then perform step G11;It is that then controller is sent out
Prompt tone, and stop providing high-frequency driving signal to medical instrument, perform step 12;
Step G11:Controller judges whether the value of impedance Ri is more than the value of impedance R5:It is then to perform step G12;It is no, then
Perform step G13;
Step G12:Controller is judged whether to have completed the process of blood coagulation closure by the value of impedance Ri, completes blood coagulation and close
During conjunction, the value of impedance Ri levels off to 0;Perform step G6;
Step G13:Controller judges whether user presses manual switch or by foot switch, so as to control medical instrument
Unlatching:It is then to perform step G14;No, then controller stops providing high-frequency driving signal to medical instrument, performs step 12;
Step G14:Controller adjusts output power according to the method for step C5, reduces output power;
Step G15:Whether controller judges overtime during counter counts:It is no, then perform step G13;It is that controller is sent out to carry
Show sound, and stop providing high-frequency driving signal to medical instrument, perform step 12;
Step 12:Perform step 4.
The identification device includes the socket, and the socket includes jack housing and identification wiring board, identifies wiring board
In jack housing;
It identifies that wiring board includes main control chip, recognition unit, power module, LED indication module and serial ports output interface, knows
Other unit, LED indication module and serial ports output interface are connect with main control chip;Power module is main control chip, recognition unit
With LED indication module for power supply, power module output positive supply;
Recognition unit includes the first photovoltaic element, the second photovoltaic element and third photovoltaic element;
First photovoltaic element include resistance R33, photoelectric sensor U9, resistance R34, resistance R35, resistance R36, capacitance C12,
Resistance R16, resistance R20, capacitance C6, resistance R37, resistance R38, photoelectric sensor U11, resistance R39, resistance R40, resistance R41,
Capacitance C9, resistance R26, resistance R31, capacitance C10, resistance R42 and amplifier U10,1 foot of photoelectric sensor U9 pass through resistance R33
Connect positive supply, the 2 feet connection ground wire of photoelectric sensor U9,3 feet of photoelectric sensor U9 by the resistance R34 that is connected in series with and
Resistance R35 connection positive supplies, 3 feet of photoelectric sensor U9 pass through 4 feet of capacitance C12 connection photoelectric sensors U9, photoelectric sensing
For 3 feet of device U9 also by 3 feet of resistance R36 connection amplifiers U10,3 feet of amplifier U10 also pass through resistance R37 connection amplifiers U10's
1 foot, 2 feet of amplifier U10 are by resistance R16 connection positive supplies, the resistance R20 and electricity of 2 feet of amplifier U10 also by being connected in parallel
Hold C6 connection ground wires, 1 foot of amplifier U10 connects the main control chip;1 foot of photoelectric sensor U11 by resistance R38 connections just
Power supply, the 2 feet connection ground wire of photoelectric sensor U11,3 feet of photoelectric sensor U11 pass through the resistance R39 and resistance that are connected in series with
R40 connection positive supplies, 3 feet of photoelectric sensor U11 pass through 4 feet of capacitance C9 connection photoelectric sensors U11, photoelectric sensor
For 3 feet of U11 also by 5 feet of resistance R41 connection amplifiers U10,5 feet of amplifier U10 also pass through the 7 of resistance R42 connection amplifiers U10
Foot, 6 feet of amplifier U10 are by resistance R26 connection positive supplies, the resistance R31 and electricity of 6 feet of amplifier U10 also by being connected in parallel
Hold C10 connection ground wires, 7 feet of amplifier U10 connect the main control chip;
Second photovoltaic element include resistance R13, photoelectric sensor U5, resistance R14, resistance R17, resistance R18, capacitance C5,
Resistance R15, resistance R19, capacitance C7, resistance R22, resistance R23, photoelectric sensor U7, resistance R24, resistance R28, resistance R29,
Capacitance C8, resistance R25, resistance R30, capacitance C11, resistance R32 and amplifier U6,1 foot of photoelectric sensor U5 are connected by resistance R13
Connect positive supply, the 2 feet connection ground wire of photoelectric sensor U5,3 feet of photoelectric sensor U5 pass through the resistance R14 and electricity that are connected in series with
R17 connection positive supplies are hindered, 3 feet of photoelectric sensor U5 pass through 4 feet of capacitance C5 connection photoelectric sensors U5, photoelectric sensor U5
3 feet also by 3 feet of resistance R18 connection amplifiers U6,3 feet of amplifier U6 also pass through 1 foot of resistance R22 connection amplifiers U6, fortune
2 feet of U6 are put by resistance R15 connection positive supplies, 2 feet of amplifier U6 are also connected by the resistance R19 being connected in parallel with capacitance C7
Ground wire, 1 foot of amplifier U6 connect the main control chip;1 foot of photoelectric sensor U7 passes through resistance R23 connection positive supplies, photoelectricity
The 2 feet connection ground wire of sensor U7,3 feet of photoelectric sensor U7 connect positive electricity by the resistance R24 being connected in series with resistance R28
Source, 3 feet of photoelectric sensor U7 also pass through electricity by 4 feet of capacitance C8 connection photoelectric sensors U7,3 feet of photoelectric sensor U7
5 feet of R29 connection amplifiers U6 are hindered, also by 7 feet of resistance R32 connection amplifiers U6,6 feet of amplifier U6 pass through 5 feet of amplifier U6
Resistance R25 connection positive supplies, 6 feet of amplifier U6 also connect ground wire, amplifier U6 with capacitance C11 by the resistance R30 being connected in parallel
7 feet connect the main control chip;
Third photovoltaic element includes resistance R1, photoelectric sensor U1, resistance R2, resistance R4, resistance R5, capacitance C1, resistance
R3, resistance R6, capacitance C2, resistance R21, resistance R7, photoelectric sensor U3, resistance R8, resistance R27, resistance R10, capacitance C3, electricity
1 foot for hindering R9, resistance R11, capacitance C4, resistance R12 and amplifier U2, photoelectric sensor U1 passes through resistance R1 connection positive supplies, light
The 2 feet connection ground wire of electric transducer U1,3 feet of photoelectric sensor U1 connect positive electricity by the resistance R2 being connected in series with resistance R4
Source, 3 feet of photoelectric sensor U1 also pass through electricity by 4 feet of capacitance C1 connection photoelectric sensors U1,3 feet of photoelectric sensor U1
3 feet of R5 connection amplifiers U2 are hindered, for 3 feet of amplifier U2 also by 1 foot of resistance R21 connection amplifiers U2,2 feet of amplifier U2 pass through electricity
R3 connection positive supplies are hindered, 2 feet of amplifier U2 also connect ground wire, 1 foot of amplifier U2 with capacitance C2 by the resistance R6 being connected in parallel
Connect the main control chip;1 foot of photoelectric sensor U3 is connected by resistance R7 connection positive supplies, 2 feet of photoelectric sensor U3
Ground wire, 3 feet of photoelectric sensor U3 connect positive supply with resistance R27 by the resistance R8 being connected in series with, and the 3 of photoelectric sensor U3
Foot also passes through the 5 of resistance R10 connection amplifiers U2 by 4 feet of capacitance C3 connection photoelectric sensors U3,3 feet of photoelectric sensor U3
Foot, for 5 feet of amplifier U2 also by 7 feet of resistance R12 connection amplifiers U2,6 feet of amplifier U2 pass through resistance R9 connection positive supplies, fortune
6 feet for putting U2 also connect ground wire with capacitance C4 by the resistance R11 being connected in parallel, and 7 feet of amplifier U2 connect the main control chip.
The LED indication module is LED light;The serial ports output interface is 232 interfaces.
Further include plug, the outer surface of the housing of plug be equipped with the first groove, the second groove, third groove, the 4th groove,
5th groove and the 6th groove.
After the plug is inserted into socket, first groove is corresponding with the photoelectric sensor U9, second groove and
The photoelectric sensor U5 is corresponded to, and the third groove is corresponding with the photoelectric sensor U1, the 4th groove and the light
Electric transducer U11 is corresponded to, and the 5th groove is corresponding with the photoelectric sensor U7, the 6th groove and the photoelectric sensing
Device U3 is corresponded to.
The inverter circuit include inductance L2, inductance L3, TVS diode TS1, TVS diode TS2, TVS diode TS3,
Capacitance C115, capacitance C116, capacitance C117, capacitance C119, capacitance C136, capacitance C153, capacitance C135, capacitance C114, short circuit
Conducting wire W1 and short circuit conducting wire W2;1 foot of inductance L2 and 1 foot of inductance L3 are all connected with the radio-frequency driven module, 2 feet of inductance L2
1 foot of capacitance C153 is connected, 2 feet of inductance L2 pass through 2 feet of capacitance C115 connection capacitances C116, the 1 foot connection of capacitance C116
1 foot of TVS diode TS1,2 feet of TVS diode TS1 pass through 1 foot of TVS diode TS2 connection TVS diodes TS3, TVS
1 foot of the 2 feet connection capacitance C136 of diode TS3, the capacitance C117 and capacitance of 1 foot of capacitance C116 also by being connected in series with
1 foot of C119 connection capacitances C136,1 foot of the 2 feet connection capacitance C136 of inductance L3, sets one end of short circuit conducting wire W1 as short circuit
1 foot of conducting wire W1, the other end are 2 feet of short circuit conducting wire W1, set one end of short circuit conducting wire W2 as 1 foot of short circuit conducting wire W2, separately
One end is 2 feet of short circuit conducting wire W2,1 foot of the 2 feet connection short circuit conducting wire W2 of capacitance C136, and 2 feet of capacitance C136 are also connected with short
2 feet of conducting wire W1 are connect, 1 foot of short circuit conducting wire W1 connects the 2 of capacitance C153 by the capacitance C135 being connected in parallel with capacitance C114
Foot, 2 feet of capacitance C153 constitute the output terminal of the inverter circuit with 2 feet of short circuit conducting wire W2;
The output terminal of the inverter circuit connects the relay;
The voltage sampling module is set on the short circuit conducting wire W1, the electric current is set on the short circuit conducting wire W2
Sampling module, the voltage sampling module connect second analog-digital converter by conducting wire, and the current sampling module passes through
Conducting wire connects first analog-digital converter.
The model 74LS165 of the buffer;The model MAX518 of the digital analog converter;Second modulus turns
The model of parallel operation and first analog-digital converter is ad1674;The CPU module is ARM9 processors;The overvoltage protection
The model TCS2802 of module;The photoelectric isolation module is photoelectrical coupler;The display screen is LCD display;The electricity
Pressure sampling module is JDZX16A-10R type voltage transformers, and the model LZZBJ9-12 type electric currents of the current sampling module are mutual
Sensor, the model DSPIC4011 of the radiofrequency signal generation module;The model 74HC00 of NAND gate module;Radio-frequency driven
The model MIC4451 of module;The medical instrument is procedures electrode.
A kind of control method of medical rapid blood coagulation diced system of the present invention, is solved while is opened using manual control
The problem of closing with Foot-controlled switch control surgical instrument blood coagulation is solved using cutting and blood coagulation closure both of which to rapid blood coagulation
The control problem of diced system.
Description of the drawings
Fig. 1 is the principle of the present invention picture frame figure;
Fig. 2 is the schematic diagram block diagram of the identification wiring board of the present invention;
Fig. 3 is the structure diagram of the identification device of the present invention;
Fig. 4 is the schematic diagram of the inverter circuit of the present invention;
Fig. 5 is the schematic diagram of the recognition unit of the present invention;
Fig. 6 is the general flow chart of the present invention;
Fig. 7 is the general flow chart of the CUT patterns of the present invention;
Fig. 8 is the flow chart of the CUT mode initialisations of the present invention;
Fig. 9 is the flow chart of the CUT tasks of the present invention;
Figure 10 is the general flow chart of the Seal patterns of the present invention;
Figure 11 is the flow chart of the Seal mode initialisations of the present invention;
Figure 12 is the flow chart of the first Seal tasks of the present invention;
Figure 13 is the flow chart of the 2nd Seal tasks of the present invention;
In figure:Button 1, floor push 2, photoelectric isolation module 3, buffer 4, loudspeaker 5, power amplifier 6, overvoltage protective module 7,
Digital analog converter 8, high-voltage suppling power 9, inverter circuit 10, relay 11, voltage sampling module 13, current sampling module 14,
Radio-frequency driven module 15, NAND gate module 16, radiofrequency signal generation module 17, the second analog-digital converter 18, the first analog-to-digital conversion
Device 19, CPU module 20, display screen 21, identification device 22, manual switch 23, recognition unit 101, power module 102, master control core
Piece 103, LED indication module 104, serial ports output interface 105, identification wiring board 106, jack housing 107, the first groove 1010,
4th groove 1011, the 5th groove 1017, third groove 1018, the 6th groove 1019, plug 1020, is inserted second groove 1014
Seat 1021.
Specific embodiment
A kind of control method of medical rapid blood coagulation diced system, includes the following steps:
Step 1:Medical rapid blood coagulation diced system is set up, medical rapid blood coagulation diced system includes controller and doctor
Treat instrument 25, controller connection medical instrument 25;
Controller includes button 1, floor push 2, manual switch 23, photoelectric isolation module 3, buffer 4, loudspeaker 5, power amplifier
6th, overvoltage protective module 7, digital analog converter 8, high-voltage suppling power 9, inverter circuit 10, relay 11, voltage sampling module 13,
Current sampling module 14, radio-frequency driven module 15, NAND gate module 16, radiofrequency signal generation module 17, the second analog-digital converter
18th, the first analog-digital converter 19, CPU module 20, display screen 21 and identification device 22, floor push 2 and manual switch 23 connect
Photoelectric isolation module 3 is connect, photoelectric isolation module 3, identification device 22 and button 1 are all connected with buffer 4, buffer 4, power amplifier 6, number
Mode converter 8, the second analog-digital converter 18, the first analog-digital converter 19, relay 11, NAND gate module 16 and display screen 21 are equal
It is connect with CPU module 20;
Loudspeaker 5 connect power amplifier 6, and high-voltage suppling power 9 connects overvoltage protective module 7, and overvoltage protective module 7 connects CPU moulds
Block 20, digital analog converter 8 connect high-voltage suppling power 9, and high-voltage suppling power 9 is also connected with radio-frequency driven module 15, radiofrequency signal
Generation module 17 connects NAND gate module 16, and NAND gate module 16 is also connected with radio-frequency driven module 15, and radio-frequency driven module 15 is also
Inverter circuit 10 is connected, relay 11 connects inverter circuit 10, and voltage sampling module 13 and current sampling module 14 are arranged at
The output terminal of inverter circuit 10;
Voltage sampling module 13 connects the second analog-digital converter 18, and current sampling module 14 connects the first analog-digital converter
19;
Medical instrument 25 passes through conducting wire connection plug 1020;
Step 2:Controller is initialized, and CPU module 20 is opened delay timer and postponed, and waits for the first of controller
Beginningization is completed;
Step 3:Controller shows initialization interface by display screen 21;
Step 4:When there is plug 1020 to be inserted into socket 1021, controller passes through the identification of identification device 22 and the plug
The type of the medical instrument 25 of 1020 connections;
Step 5:Controller judges whether there is button 1 and presses, and reads 1 information of button;
Step 10:Controller judges whether there is floor push 2 or manual switch 23 acts, and passes through CPU module 20 and read
The information of floor push 2 or manual switch 23;
Step 11:Controller performs adjustment power output task, presets 5 according to the size of output power in the controller
Gear, the max-thresholds of 5 gears are respectively power P 1, power P 2, power P 3, power P 4 and power P 5, set 5 resistances
Anti- is respectively impedance R1, impedance R2, impedance R3, impedance R4 and impedance R5, and 1 corresponding impedance of power P is impedance R1, and power P 2 is right
The impedance answered is impedance R2, and 3 corresponding impedance of power P is impedance R3, and 4 corresponding impedance of power P is impedance R4, and power P 5 corresponds to
Impedance for impedance R5, include the following steps:
Step S1:Controller will carry out medical instrument 25 according to the type of medical instrument 25 identified in step 4
The pattern of control is divided into cut mode and blood coagulation closed mode, and setting cut mode represents that blood coagulation closed mode is used with CUT patterns
Seal patterns represent;
Step S2:When controller enters CUT patterns according to the type of medical instrument 25, CUT patterns include the following steps:
Step A1:CUT mode initialisations, include the following steps:
Step B1:User passes through buffer 4 by the gear of the selection control on display screen 21 of button 1, CPU module 20
It reads the state of button 1, and pushes button 1 number by calculating user and judge the selected gear of user;
Step B2:Controller control relay 11 is closed, and the output terminal of inverter circuit 10 is made to be electrically connected with medical instrument 25;
Step B3:Controller obtains prompt tone parameter by CPU module 20, and the prompt tone parameter is PWN data;
Step B4:Controller sets output frequency according to the type of medical instrument 25;
Step B5:CPU module 20 opens timer, starts timing;
Step A2:Controller performs CUT tasks, includes the following steps:
Step C1:Controller acquires 10 output terminal of inverter circuit by voltage sampling module 13 and current sampling module 14
Voltage signal is converted into being sent to CPU moulds after digital voltage data by voltage signal and current signal, the first analog-digital converter 19
Current signal is converted into being sent to CPU module 20 after digital current data by block 20, the second analog-digital converter 18, CPU module 20
According to digital current data and digital voltage data and pass through the output impedance that Ohm's law calculates 10 output terminal of inverter circuit,
It sets the output impedance and is expressed as impedance Ri;
Step C2:Controller judges whether user by button 1 has selected CUT patterns:It is then to perform step C3;It is no, then
Perform step 12;
Step C3:Controller judges whether user presses manual switch 23 or by foot switch 2, so as to control Medical treatment device
The unlatching of tool 25:It is then to perform step C4;It is no, then perform step 12;
Step C4:Whether CPU module 20 is less than the value of specific impedance Ri the value of impedance R1:It is then to perform step C5;It is no,
Then perform step C8;
Step C5:Radiofrequency signal generation module 17 generates high-frequency signal, and by high frequency signal transmission to NAND gate module 16,
NAND gate module 16 exports high-frequency signal to radio-frequency driven module 15, and CPU module 20 is controlled by controlling NAND gate module 16
The output of high-frequency signal processed, CPU module 20 control high-voltage suppling power 9 to radio-frequency driven mould by controlling digital analog converter 8
The driving power that block 15 provides, radio-frequency driven module 15 export high-frequency drive according to the high-frequency signal and the driving power
Voltage, and high-frequency driving voltage is sent to inverter circuit 10, inverter circuit 10 generates high-frequency drive according to high-frequency driving voltage
Signal, and pass through relay 11 and provide high-frequency driving signal to medical instrument 25;
Step C6:Controller adjusts output power according to the method for step C5, and output power is made to be no more than power P 1;
Step C7:Whether CPU module 20 judges overtime during counter counts:It is no, then perform step C3;It is, then CPU module 20
Prompt tone parameter is sent to power amplifier 6, power amplifier 6 sends out prompt tone by loudspeaker 5, and performs step 12;
Step C8:Controller judges whether user presses manual switch 23 or by foot switch 2, so as to control Medical treatment device
The unlatching of tool 25:It is then to perform step C9;It is no, then perform step 12;
Step C9:Whether CPU module 20 is to the value of specific impedance Ri between the value of impedance R1 and the value of impedance R2:It is, then
Perform step C10;It is no, then perform step C12;
Step C10:Controller adjusts output power according to the method for step C5, makes output power in power P 1 and power P 2
Between;
Step C11:Whether CPU module 20 judges overtime during counter counts:It is no, then perform step C8;It is, then CPU module
20 send prompt tone parameter to power amplifier 6, and power amplifier 6 sends out prompt tone by loudspeaker 5, and performs step 12;
Step C12:Controller judges whether user presses manual switch 23 or by foot switch 2, so as to control medical treatment
The unlatching of instrument 25:It is then to perform step C13;It is no, then perform step 12;
Step C13:Whether CPU module 20 is to the value of specific impedance Ri between the value of impedance R2 and the value of impedance R3:It is, then
Perform step C14;It is no, then perform step C16;
Step C14:Controller adjusts output power according to the method for step C5, makes output power in power P 2 and power P 3
Between;
Step C15:Whether CPU module 20 judges overtime during counter counts:It is no, then perform step C12;It is, then CPU module
20 send prompt tone parameter to power amplifier 6, and power amplifier 6 sends out prompt tone by loudspeaker 5, and performs step 12;
Step C16:Controller judges whether user presses manual switch 23 or by foot switch 2, so as to control medical treatment
The unlatching of instrument 25:It is then to perform step C17;It is no, then perform step 12;
Step C17:Whether CPU module 20 is to the value of specific impedance Ri between the value of impedance R3 and the value of impedance R4:It is, then
Perform step C18;It is no, then perform step C20;
Step C18:Controller adjusts output power according to the method for step C5, makes output power in power P 3 and power P 4
Between;
Step C19:Whether CPU module 20 judges overtime during counter counts:It is no, then perform step C16;It is, then CPU module
20 send prompt tone parameter to power amplifier 6, and power amplifier 6 sends out prompt tone by loudspeaker 5, and performs step 12;
Step C20:Controller judges whether user presses manual switch 23 or by foot switch 2, so as to control medical treatment
The unlatching of instrument 25:It is then to perform step C21;It is no, then perform step 12;
Step C21:Whether CPU module 20 is to the value of specific impedance Ri between the value of impedance R4 and the value of impedance R5:It is, then
Perform step C22;It is no, then perform step C24;
Step C22:Controller adjusts output power according to the method for step C5, makes output power in power P 4 and power P 5
Between;
Step C23:Whether CPU module 20 judges overtime during counter counts:It is no, then perform step C20;It is, then CPU module
20 send prompt tone parameter to power amplifier 6, and power amplifier 6 sends out prompt tone by loudspeaker 5, and performs step 12;
Step C24:Controller judges whether user presses manual switch 23 or by foot switch 2, so as to control medical treatment
The unlatching of instrument 25:It is then to perform step C25;It is no, then perform step 12;
Step C25:Whether CPU module 20 is more than the value of specific impedance Ri the value of impedance R5:It is then to perform step C26;
It is no, then perform step C3;
Step C26:Controller adjusts output power according to the method for step C5, and output power is made to be more than power P 5;
Step C27:Whether CPU module 20 judges overtime during counter counts:It is no, then perform step C24;It is, then CPU module
20 send prompt tone parameter to power amplifier 6, and power amplifier 6 sends out prompt tone by loudspeaker 5, and performs step 12;
Step S3:When controller enters Seal patterns according to the type of medical instrument 25, Seal patterns include following step
Suddenly:
Step D1:Seal mode initialisations, include the following steps:
Step E1:User passes through buffer 4 by the gear of the selection control on display screen 21 of button 1, CPU module 20
It reads the state of button 1, and pushes button 1 number by calculating user and judge the selected gear of user;
Step E2:Controller control relay 11 is closed, and the output terminal of inverter circuit 10 is made to be electrically connected with medical instrument 25;
Step E3:Controller obtains the prompt tone parameter by CPU module 20, and the prompt tone parameter is PWN data;
Step E4:Controller sets output frequency according to the type of medical instrument 25;
Step E5:CPU module 20 opens timer, starts timing;
Step E6:Controller judges whether the output terminal of inverter opens a way according to the size of impedance Ri:It is that then controller leads to
It crosses loudspeaker 5 and sends out prompt tone, controller stops providing high-frequency driving signal to medical instrument 25, performs step 12;It is no, then it performs
Step E7;
Step E7:Controller obtains the value of impedance Ri;
Step E8:Setup parameter initializes return value, and controller judges whether user has selected Seal patterns:It is then to join
Number initialization return value is equal to 1;No, then parameter initialization return value is equal to O;
Step D2:Controller performs the first Seal tasks, includes the following steps:
Step F1:Judge whether parameter initialization return value is equal to 1:It is then to perform step F2;No, then controller is sent out
Prompt tone, and stop providing high-frequency driving signal to medical instrument 25, perform step 12;
Step F2:Controller judges whether user presses manual switch 23 or by foot switch 2, so as to control Medical treatment device
The unlatching of tool 25:It is then to perform step F3;No, then controller sends out prompt tone, and stops providing medical instrument 25 high frequency drive
Dynamic signal, performs step 12;
Step F3:Controller judges whether the output terminal of inverter circuit 10 is short-circuit according to the size of impedance Ri:It is then to control
Device sends out prompt tone, and stops providing high-frequency driving signal to medical instrument 25, performs step 12;It is no, then perform step F4;
Step F4:Controller judges whether the value of impedance Ri is less than the value of impedance R1:It is then to perform step F5;It is no, then it holds
Row step F7;
Step F5:Controller adjusts output power according to the method for step C5, and output power is made to be less than power P 1;
Step F6:Whether controller judges overtime during counter counts:It is no, then perform step F2;It is that controller sends out prompting
Sound, and stop providing high-frequency driving signal to medical instrument 25, perform step 12;
Step F7:Controller judges whether user presses manual switch 23 or by foot switch 2, so as to control Medical treatment device
The unlatching of tool 25:It is then to perform step F8;No, then controller sends out prompt tone, and stops providing medical instrument 25 high frequency drive
Dynamic signal, performs step 12;
Step F8:Whether controller judges the value of impedance Ri between the value of impedance R1 and the value of impedance R2:It is then to perform
Step F9;It is no, then perform step F11;
Step F9:Controller adjusts output power according to the method for step C5, makes output power in power P 1 and power P 2
Between;
Step F10:Whether controller judges overtime during counter counts:It is no, then perform step F7;It is that controller is sent out to carry
Show sound, and stop providing high-frequency driving signal to medical instrument 25, perform step 12;
Step F11:Controller judges whether user presses manual switch 23 or by foot switch 2, so as to control medical treatment
The unlatching of instrument 25:It is then to perform step F12;No, then controller sends out prompt tone, and stops providing height to medical instrument 25
Frequency drive signal performs step 12;
Step F12:Whether the first Seal task return values of setup parameter, controller judge the value of impedance Ri impedance R2's
Between value and the value of impedance R3:It is then to perform step F13;No, then the first Seal tasks return value is equal to 1, performs step D3;
Step F13:Controller adjusts output power according to the method for step C5, makes output power in power P 2 and power P 3
Between;
Step F14:Whether controller judges overtime during counter counts:It is no, then perform step F11;It is that controller is sent out to carry
Show sound, and stop providing high-frequency driving signal to medical instrument 25, perform step 12;
Step D3:Controller performs the 2nd Seal tasks, includes the following steps:
Step G1:Controller judges whether the first Seal tasks return value is equal to 1:It is no, then perform step 12;It is then to hold
Row step G2;
Step G2:Controller judges whether user presses manual switch 23 or by foot switch 2, so as to control Medical treatment device
The unlatching of tool 25:It is then to perform step G3;No, then controller sends out prompt tone, and stops providing medical instrument 25 high frequency drive
Dynamic signal, performs step 12;
Step G3:Whether controller judges the value of impedance Ri between the value of impedance R3 and the value of impedance R4:It is then to perform
Step G4;It is no, then perform step G6;
Step G4:Controller adjusts output power according to the method for step C5, makes output power in power P 3 and power P 4
Between;
Step G5:Whether controller judges overtime during counter counts:It is no, then perform step G2;It is that controller sends out prompting
Sound, and stop providing high-frequency driving signal to medical instrument 25, perform step 12;
Step G6:Controller judges whether user presses manual switch 23 or by foot switch 2, so as to control Medical treatment device
The unlatching of tool 25:It is then to perform step G7;No, then controller sends out prompt tone, and stops providing medical instrument 25 high frequency drive
Dynamic signal, performs step 12;
Step G7:Controller judges whether medical instrument 25 is over-pressed according to the voltage signal that voltage sampling module 13 acquires:
It is then to perform step G8;It is no, then perform step G9;
Step G8:Controller adjusts output power according to the method for step C5, reduces output power;Perform step G10;
Step G9:Controller adjusts output power according to the method for step C5, increases output power;
Step G10:Whether controller judges overtime during counter counts:It is no, then perform step G11;It is that then controller is sent out
Prompt tone, and stop providing high-frequency driving signal to medical instrument 25, perform step 12;
Step G11:Controller judges whether the value of impedance Ri is more than the value of impedance R5:It is then to perform step G12;It is no, then
Perform step G13;
Step G12:Controller is judged whether to have completed the process of blood coagulation closure by the value of impedance Ri, completes blood coagulation and close
During conjunction, the value of impedance Ri levels off to 0;Perform step G6;
Step G13:Controller judges whether user presses manual switch 23 or by foot switch 2, so as to control medical treatment
The unlatching of instrument 25:It is then to perform step G14;No, then controller stops providing high-frequency driving signal to medical instrument 25, holds
Row step 12;
Step G14:Controller adjusts output power according to the method for step C5, reduces output power;
Step G15:Whether controller judges overtime during counter counts:It is no, then perform step G13;It is that controller is sent out to carry
Show sound, and stop providing high-frequency driving signal to medical instrument 25, perform step 12;
Step 12:Perform step 4.
The identification device 22 includes the socket 1021, and the socket 1021 includes jack housing 107 and identification circuit
Plate 106, identification wiring board 106 are set in jack housing 107;
Identify that wiring board 106 includes main control chip 103, recognition unit 101, power module 102,104 and of LED indication module
Signal output interface 105, recognition unit 101, LED indication module 104 and signal output interface 105 connect with main control chip 103
It connects;Power module 102 is powered for main control chip 103, recognition unit 101 and LED indication module 104, and power module 102 exports just
Power supply;
Recognition unit 101 includes the first photovoltaic element, the second photovoltaic element and third photovoltaic element;
First photovoltaic element include resistance R33, photoelectric sensor U9, resistance R34, resistance R35, resistance R36, capacitance C12,
Resistance R16, resistance R20, capacitance C6, resistance R37, resistance R38, photoelectric sensor U11, resistance R39, resistance R40, resistance R41,
Capacitance C9, resistance R26, resistance R31, capacitance C10, resistance R42 and amplifier U10,1 foot of photoelectric sensor U9 pass through resistance R33
Connect positive supply, the 2 feet connection ground wire of photoelectric sensor U9,3 feet of photoelectric sensor U9 by the resistance R34 that is connected in series with and
Resistance R35 connection positive supplies, 3 feet of photoelectric sensor U9 pass through 4 feet of capacitance C12 connection photoelectric sensors U9, photoelectric sensing
For 3 feet of device U9 also by 3 feet of resistance R36 connection amplifiers U10,3 feet of amplifier U10 also pass through resistance R37 connection amplifiers U10's
1 foot, 2 feet of amplifier U10 are by resistance R16 connection positive supplies, the resistance R20 and electricity of 2 feet of amplifier U10 also by being connected in parallel
Hold C6 connection ground wires, 1 foot of amplifier U10 connects the main control chip 103;1 foot of photoelectric sensor U11 is connected by resistance R38
Connect positive supply, the 2 feet connection ground wire of photoelectric sensor U11,3 feet of photoelectric sensor U11 by the resistance R39 that is connected in series with and
Resistance R40 connection positive supplies, 3 feet of photoelectric sensor U11 pass through 4 feet of capacitance C9 connection photoelectric sensors U11, photoelectric sensing
For 3 feet of device U11 also by 5 feet of resistance R41 connection amplifiers U10,5 feet of amplifier U10 also pass through resistance R42 connection amplifiers U10
7 feet, 6 feet of amplifier U10 by resistance R26 connection positive supplies, 6 feet of amplifier U10 also by the resistance R31 that is connected in parallel and
Capacitance C10 connection ground wires, 7 feet of amplifier U10 connect the main control chip 103;
Second photovoltaic element include resistance R13, photoelectric sensor U5, resistance R14, resistance R17, resistance R18, capacitance C5,
Resistance R15, resistance R19, capacitance C7, resistance R22, resistance R23, photoelectric sensor U7, resistance R24, resistance R28, resistance R29,
Capacitance C8, resistance R25, resistance R30, capacitance C11, resistance R32 and amplifier U6,1 foot of photoelectric sensor U5 are connected by resistance R13
Connect positive supply, the 2 feet connection ground wire of photoelectric sensor U5,3 feet of photoelectric sensor U5 pass through the resistance R14 and electricity that are connected in series with
R17 connection positive supplies are hindered, 3 feet of photoelectric sensor U5 pass through 4 feet of capacitance C5 connection photoelectric sensors U5, photoelectric sensor U5
3 feet also by 3 feet of resistance R18 connection amplifiers U6,3 feet of amplifier U6 also pass through 1 foot of resistance R22 connection amplifiers U6, fortune
2 feet of U6 are put by resistance R15 connection positive supplies, 2 feet of amplifier U6 are also connected by the resistance R19 being connected in parallel with capacitance C7
Ground wire, 1 foot of amplifier U6 connect the main control chip 103;1 foot of photoelectric sensor U7 passes through resistance R23 connection positive supplies, light
The 2 feet connection ground wire of electric transducer U7,3 feet of photoelectric sensor U7 are connected just by the resistance R24 being connected in series with resistance R28
Power supply, 3 feet of photoelectric sensor U7 are also passed through by 4 feet of capacitance C8 connection photoelectric sensors U7,3 feet of photoelectric sensor U7
5 feet of resistance R29 connection amplifiers U6, also by 7 feet of resistance R32 connection amplifiers U6,6 feet of amplifier U6 lead to 5 feet of amplifier U6
Resistance R25 connection positive supplies are crossed, 6 feet of amplifier U6 also connect ground wire, amplifier by the resistance R30 being connected in parallel with capacitance C11
7 feet of U6 connect the main control chip 103;
Third photovoltaic element includes resistance R1, photoelectric sensor U1, resistance R2, resistance R4, resistance R5, capacitance C1, resistance
R3, resistance R6, capacitance C2, resistance R21, resistance R7, photoelectric sensor U3, resistance R8, resistance R27, resistance R10, capacitance C3, electricity
1 foot for hindering R9, resistance R11, capacitance C4, resistance R12 and amplifier U2, photoelectric sensor U1 passes through resistance R1 connection positive supplies, light
The 2 feet connection ground wire of electric transducer U1,3 feet of photoelectric sensor U1 connect positive electricity by the resistance R2 being connected in series with resistance R4
Source, 3 feet of photoelectric sensor U1 also pass through electricity by 4 feet of capacitance C1 connection photoelectric sensors U1,3 feet of photoelectric sensor U1
3 feet of R5 connection amplifiers U2 are hindered, for 3 feet of amplifier U2 also by 1 foot of resistance R21 connection amplifiers U2,2 feet of amplifier U2 pass through electricity
R3 connection positive supplies are hindered, 2 feet of amplifier U2 also connect ground wire, 1 foot of amplifier U2 with capacitance C2 by the resistance R6 being connected in parallel
Connect the main control chip 103;1 foot of photoelectric sensor U3 is connected by resistance R7 connection positive supplies, 2 feet of photoelectric sensor U3
Ground wire, 3 feet of photoelectric sensor U3 connect positive supply, photoelectric sensor U3 with resistance R27 by the resistance R8 being connected in series with
3 feet by 4 feet of capacitance C3 connection photoelectric sensors U3,3 feet of photoelectric sensor U3 also pass through resistance R10 connection amplifiers U2
5 feet, for 5 feet of amplifier U2 also by 7 feet of resistance R12 connection amplifiers U2,6 feet of amplifier U2 pass through resistance R9 connection positive electricity
Source, 6 feet of amplifier U2 also connect ground wire with capacitance C4 by the resistance R11 being connected in parallel, and 7 feet of amplifier U2 connect the master control
Chip 103;
The model STC89C52 of the main control chip 103;
The LED indication module 104 is LED light;The signal output interface 105 is 232 interfaces.
The outer surface of the housing of the plug 1020 be equipped with the first groove 1010, the second groove 1014, third groove 1018,
4th groove 1011, the 5th groove 1017 and the 6th groove 1019.
After the plug 1020 is inserted into socket 1021, first groove 1010 is corresponding with the photoelectric sensor U9, institute
It is corresponding with the photoelectric sensor U5 to state the second groove 1014, the third groove 1018 is corresponding with the photoelectric sensor U1,
4th groove 1011 is corresponding with the photoelectric sensor U11, the 5th groove 1017 and U7 pairs of the photoelectric sensor
Should, the 6th groove 1019 is corresponding with the photoelectric sensor U3.
The inverter circuit 10 includes inductance L2, inductance L3, TVS diode TS1, TVS diode TS2, TVS diode
TS3, capacitance C115, capacitance C116, capacitance C117, capacitance C119, capacitance C136, capacitance C153, capacitance C135, capacitance C114,
Short circuit conducting wire W1 and short circuit conducting wire W2;1 foot of inductance L2 and 1 foot of inductance L3 are all connected with the radio-frequency driven module 15, inductance
1 foot of the 2 feet connection capacitance C153 of L2,2 feet of inductance L2 are by 2 feet of capacitance C115 connection capacitances C116, and the 1 of capacitance C116
1 foot of foot connection TVS diode TS1,2 feet of TVS diode TS1 pass through the 1 of TVS diode TS2 connection TVS diodes TS3
Foot, 1 foot of the 2 feet connection capacitance C136 of TVS diode TS3,1 foot of capacitance C116 also by the capacitance C117 that is connected in series with and
1 foot of capacitance C119 connection capacitances C136,1 foot of the 2 feet connection capacitance C136 of inductance L3, set one end of short circuit conducting wire W1 as
1 foot of short circuit conducting wire W1, the other end are 2 feet of short circuit conducting wire W1, set one end of short circuit conducting wire W2 as the 1 of short circuit conducting wire W2
Foot, the other end are 2 feet of short circuit conducting wire W2, and 2 feet of capacitance C136 connect 1 foot of short circuit conducting wire W2, and 2 feet of capacitance C136 also connect
2 feet of short circuit conducting wire W1 are connect, 1 foot of short circuit conducting wire W1 connects capacitance C153 by the capacitance C135 being connected in parallel with capacitance C114
2 feet, 2 feet of capacitance C153 and 2 feet of short circuit conducting wire W2 constitute the output terminal of the inverter circuit 10;
The output terminal of the inverter circuit 10 connects the relay 11;
The voltage sampling module 13 is set on the short circuit conducting wire W1, the electricity is set on the short circuit conducting wire W2
Sampling module 14 is flowed, the voltage sampling module 13 connects second analog-digital converter 18, the current sampling by conducting wire
Module 14 connects first analog-digital converter 19 by conducting wire.
The model 74LS165 of the buffer 4;The model MAX518 of the digital analog converter 8;Second modulus
The model of converter 18 and first analog-digital converter 19 is ad1674;The CPU module 20 is ARM9 processors;It is described
The model TCS2802 of overvoltage protective module 7;The photoelectric isolation module 3 is photoelectrical coupler;The display screen 21 is LCD
Display screen 21;The voltage sampling module 13 be JDZX16A-10R type voltage transformers, the model of the current sampling module 14
For LZZBJ9-12 type current transformers, the model DSPIC4011 of the radiofrequency signal generation module 17;NAND gate module 16
Model 74HC00;The model MIC4451 of radio-frequency driven module 15;The medical instrument 25 is procedures electrode.
When plug 1020 dispatches from the factory, producer is first by the first groove 1010, the second groove 1014, third groove 1018,
Four grooves 1011,1019 equal painted white of the 5th groove 1017 and the 6th groove, then producer is recessed by the first groove 1010, second
One or more of slot 1014, third groove 1018, the 4th groove 1011, the 5th groove 1017 and the 6th groove 1019 are painted
Black, in this way, the first groove 1010, the second groove 1014, third groove 1018, the 4th groove 1011,1017 and of the 5th groove
The color combination of 6th groove 1019 is formed specifically identifying coding, and black 1, white is 0, each medical instrument 22
An identification coding is preset, producer connects the pairing corresponding with plug 1020 of medical instrument 22 according to identification coding
It connects;The medical instrument 22 is surgical instrument.
After plug 1020 is inserted into socket 1021, photoelectric sensor U9, photoelectric sensor U5, photoelectric sensor U1, photoelectricity
It is recessed that sensor U11, photoelectric sensor U7 and photoelectric sensor U3 detect the first groove 1010, the second groove 1014, third respectively
Slot 1018, the 4th groove 1011, the 5th groove 1017 and the 6th groove 1019 color, and according to the first groove 1010, second
Groove 1014, third groove 1018, the 4th groove 1011, the 5th groove 1017 and the 6th groove 1019 color generation number of colours
Word signal is sent to main control chip 103, black 1, and white is 0, and main control chip 103 is generated according to the color digital signal to be known
It does not encode, and it is any to pass through identification coding judgement 1020 corresponding medical instrument 22 of plug.
Claims (6)
1. a kind of control method of medical rapid blood coagulation diced system, it is characterised in that:Include the following steps:
Step 1:Medical rapid blood coagulation diced system is set up, medical rapid blood coagulation diced system includes controller and Medical treatment device
Tool (25), controller connection medical instrument (25);
Controller includes button (1), floor push (2), manual switch (23), photoelectric isolation module (3), buffer (4), loudspeaker
(5), power amplifier (6), overvoltage protective module (7), digital analog converter (8), high-voltage suppling power (9), inverter circuit (10), relay
(11), voltage sampling module (13), current sampling module (14), radio-frequency driven module (15), NAND gate module (16), radio frequency letter
Number generation module (17), the second analog-digital converter (18), the first analog-digital converter (19), CPU module (20), display screen (21) and
Identification device (22), floor push (2) and manual switch (23) are all connected with photoelectric isolation module (3), photoelectric isolation module (3),
Identification device (22) and button (1) are all connected with buffer (4), buffer (4), power amplifier (6), digital analog converter (8), the second modulus
Converter (18), the first analog-digital converter (19), relay (11), NAND gate module (16) and display screen (21) with CPU moulds
Block (20) connects;
Loudspeaker (5) connection power amplifier (6), high-voltage suppling power (9) connection overvoltage protective module (7), overvoltage protective module (7) connection
CPU module (20), digital analog converter (8) connection high-voltage suppling power (9), high-voltage suppling power (9) are also connected with radio-frequency driven mould
Block (15), radiofrequency signal generation module (17) connection NAND gate module (16), NAND gate module (16) are also connected with radio-frequency driven mould
Block (15), radio-frequency driven module (15) are also connected with inverter circuit (10), relay (11) connection inverter circuit (10), voltage sampling
Module (13) and current sampling module (14) are arranged at the output terminal of inverter circuit (10);
Voltage sampling module (13) connects the second analog-digital converter (18), and current sampling module (14) connects the first analog-digital converter
(19);
Medical instrument (25) passes through conducting wire connection plug (1020);
Step 2:Controller is initialized, and CPU module (20) is opened delay timer and postponed, and waits for the initial of controller
Change and complete;
Step 3:Controller shows initialization interface by display screen (21);
Step 4:When there is plug (1020) to be inserted into socket (1021), controller passes through identification device (22) identification and the plug
(1020) type of the medical instrument (25) of connection;
Step 5:Controller judges whether there is button (1) and presses, and reads button (1) information;
Step 10:Controller judges whether there is floor push (2) or manual switch (23) action, and passes through CPU module (20) reading
Take the information of floor push (2) or manual switch (23);
Step 11:Controller performs adjustment power output task, presets 5 shelves according to the size of output power in the controller
Position, the max-thresholds of 5 gears are respectively power P 1, power P 2, power P 3, power P 4 and power P 5, set 5 impedances
Respectively impedance R1, impedance R2, impedance R3, impedance R4 and impedance R5,1 corresponding impedance of power P are impedance R1, and power P 2 corresponds to
Impedance for impedance R2,3 corresponding impedance of power P is impedance R3, and 4 corresponding impedance of power P is impedance R4, and power P 5 is corresponding
Impedance is impedance R5, is included the following steps:
Step S1:Controller will carry out medical instrument (25) according to the type of medical instrument (25) identified in step 4
The pattern of control is divided into cut mode and blood coagulation closed mode, and setting cut mode represents that blood coagulation closed mode is used with CUT patterns
Seal patterns represent;
Step S2:When controller enters CUT patterns according to the type of medical instrument (25), CUT patterns include the following steps:
Step A1:CUT mode initialisations, include the following steps:
Step B1:User passes through caching by the gear of button (1) selection control on display screen (21), CPU module (20)
Device (4) reads the state of button (1), and passes through and calculate user and push button the number of (1) to judge the selected gear of user;
Step B2:Controller control relay (11) is closed, and the output terminal and medical instrument (25) for making inverter circuit (10) are electrically connected
It connects;
Step B3:Controller obtains prompt tone parameter by CPU module (20), and the prompt tone parameter is PWN data;
Step B4:Controller sets output frequency according to the type of medical instrument (25);
Step B5:CPU module (20) opens timer, starts timing;
Step A2:Controller performs CUT tasks, includes the following steps:
Step C1:Controller acquires inverter circuit (10) output terminal by voltage sampling module (13) and current sampling module (14)
Voltage signal and current signal, the first analog-digital converter (19) is sent to after voltage signal is converted into digital voltage data
CPU module (20), the second analog-digital converter (18) are sent to CPU module after current signal is converted into digital current data
(20), CPU module (20) according to digital current data and digital voltage data and passes through Ohm's law and calculates inverter circuit
(10) output impedance of output terminal sets the output impedance and is expressed as impedance Ri;
Step C2:Controller judges whether user by button (1) has selected CUT patterns:It is then to perform step C3;It is no, then it holds
Row step 12;
Step C3:Controller judges whether user presses manual switch (23) or by foot switch (2), so as to control Medical treatment device
The unlatching of tool (25):It is then to perform step C4;It is no, then perform step 12;
Step C4:Whether CPU module (20) is less than the value of specific impedance Ri the value of impedance R1:It is then to perform step C5;It is no, then
Perform step C8;
Step C5:Radiofrequency signal generation module (17) generates high-frequency signal, and gives high frequency signal transmission to NAND gate module (16),
NAND gate module (16), which exports high-frequency signal, gives radio-frequency driven module (15), and CPU module (20) is by controlling NAND gate module
(16) output of high-frequency signal is controlled, CPU module (20) controls high-voltage suppling power by controlling digital analog converter (8)
(9) driving power provided radio-frequency driven module (15), radio-frequency driven module (15) is according to the high-frequency signal and the drive
High-frequency driving voltage is sent to inverter circuit (10), inverter circuit (10) basis by dynamic power supply to export high-frequency driving voltage
High-frequency driving voltage generates high-frequency driving signal, and passes through relay (11) and provide high-frequency driving signal to medical instrument (25);
Step C6:Controller adjusts output power according to the method for step C5, and output power is made to be no more than power P 1;
Step C7:Whether CPU module (20) judges overtime during counter counts:It is no, then perform step C3;It is, then CPU module (20)
Prompt tone parameter is sent to power amplifier (6), power amplifier (6) sends out prompt tone, and perform step 12 by loudspeaker (5);
Step C8:Controller judges whether user presses manual switch (23) or by foot switch (2), so as to control Medical treatment device
The unlatching of tool (25):It is then to perform step C9;It is no, then perform step 12;
Step C9:Whether CPU module (20) is to the value of specific impedance Ri between the value of impedance R1 and the value of impedance R2:It is then to hold
Row step C10;It is no, then perform step C12;
Step C10:Controller adjusts output power according to the method for step C5, make output power power P 1 and power P 2 it
Between;
Step C11:Whether CPU module (20) judges overtime during counter counts:It is no, then perform step C8;It is, then CPU module
(20) prompt tone parameter is sent to power amplifier (6), power amplifier (6) sends out prompt tone, and perform step 12 by loudspeaker (5);
Step C12:Controller judges whether user presses manual switch (23) or by foot switch (2), so as to control medical treatment
The unlatching of instrument (25):It is then to perform step C13;It is no, then perform step 12;
Step C13:Whether CPU module (20) is to the value of specific impedance Ri between the value of impedance R2 and the value of impedance R3:It is then to hold
Row step C14;It is no, then perform step C16;
Step C14:Controller adjusts output power according to the method for step C5, make output power power P 2 and power P 3 it
Between;
Step C15:Whether CPU module (20) judges overtime during counter counts:It is no, then perform step C12;It is, then CPU module
(20) prompt tone parameter is sent to power amplifier (6), power amplifier (6) sends out prompt tone, and perform step 12 by loudspeaker (5);
Step C16:Controller judges whether user presses manual switch (23) or by foot switch (2), so as to control medical treatment
The unlatching of instrument (25):It is then to perform step C17;It is no, then perform step 12;
Step C17:Whether CPU module (20) is to the value of specific impedance Ri between the value of impedance R3 and the value of impedance R4:It is then to hold
Row step C18;It is no, then perform step C20;
Step C18:Controller adjusts output power according to the method for step C5, make output power power P 3 and power P 4 it
Between;
Step C19:Whether CPU module (20) judges overtime during counter counts:It is no, then perform step C16;It is, then CPU module
(20) prompt tone parameter is sent to power amplifier (6), power amplifier (6) sends out prompt tone, and perform step 12 by loudspeaker (5);
Step C20:Controller judges whether user presses manual switch (23) or by foot switch (2), so as to control medical treatment
The unlatching of instrument (25):It is then to perform step C21;It is no, then perform step 12;
Step C21:Whether CPU module (20) is to the value of specific impedance Ri between the value of impedance R4 and the value of impedance R5:It is then to hold
Row step C22;It is no, then perform step C24;
Step C22:Controller adjusts output power according to the method for step C5, make output power power P 4 and power P 5 it
Between;
Step C23:Whether CPU module (20) judges overtime during counter counts:It is no, then perform step C20;It is, then CPU module
(20) prompt tone parameter is sent to power amplifier (6), power amplifier (6) sends out prompt tone, and perform step 12 by loudspeaker (5);
Step C24:Controller judges whether user presses manual switch (23) or by foot switch (2), so as to control medical treatment
The unlatching of instrument (25):It is then to perform step C25;It is no, then perform step 12;
Step C25:Whether CPU module (20) is more than the value of specific impedance Ri the value of impedance R5:It is then to perform step C26;It is no,
Then perform step C3;
Step C26:Controller adjusts output power according to the method for step C5, and output power is made to be more than power P 5;
Step C27:Whether CPU module (20) judges overtime during counter counts:It is no, then perform step C24;It is, then CPU module
(20) prompt tone parameter is sent to power amplifier (6), power amplifier (6) sends out prompt tone, and perform step 12 by loudspeaker (5);
Step S3:When controller enters Seal patterns according to the type of medical instrument (25), Seal patterns include the following steps:
Step D1:Seal mode initialisations, include the following steps:
Step E1:User passes through caching by the gear of button (1) selection control on display screen (21), CPU module (20)
Device (4) reads the state of button (1), and passes through and calculate user and push button the number of (1) to judge the selected gear of user;
Step E2:Controller control relay (11) is closed, and the output terminal and medical instrument (25) for making inverter circuit (10) are electrically connected
It connects;
Step E3:Controller obtains the prompt tone parameter by CPU module (20), and the prompt tone parameter is PWN data;
Step E4:Controller sets output frequency according to the type of medical instrument (25);
Step E5:CPU module (20) opens timer, starts timing;
Step E6:Controller judges whether the output terminal of inverter opens a way according to the size of impedance Ri:It is that then controller passes through loudspeaker
(5) prompt tone is sent out, controller stops providing high-frequency driving signal to medical instrument (25), performs step 12;It is no, then it performs
Step E7;
Step E7:Controller obtains the value of impedance Ri;
Step E8:Setup parameter initializes return value, and controller judges whether user has selected Seal patterns:It is, then at the beginning of parameter
Beginningization return value is equal to 1;No, then parameter initialization return value is equal to O;
Step D2:Controller performs the first Seal tasks, includes the following steps:
Step F1:Judge whether parameter initialization return value is equal to 1:It is then to perform step F2;No, then controller sends out prompting
Sound, and stop providing high-frequency driving signal to medical instrument (25), perform step 12;
Step F2:Controller judges whether user presses manual switch (23) or by foot switch (2), so as to control Medical treatment device
The unlatching of tool (25):It is then to perform step F3;No, then controller sends out prompt tone, and stops providing medical instrument (25) high
Frequency drive signal performs step 12;
Step F3:Controller judges whether the output terminal of inverter circuit (10) is short-circuit according to the size of impedance Ri:It is, then controller
Prompt tone is sent out, and stops providing high-frequency driving signal to medical instrument (25), performs step 12;It is no, then perform step F4;
Step F4:Controller judges whether the value of impedance Ri is less than the value of impedance R1:It is then to perform step F5;It is no, then perform step
Rapid F7;
Step F5:Controller adjusts output power according to the method for step C5, and output power is made to be less than power P 1;
Step F6:Whether controller judges overtime during counter counts:It is no, then perform step F2;It is that controller sends out prompt tone,
And stop providing high-frequency driving signal to medical instrument (25), perform step 12;
Step F7:Controller judges whether user presses manual switch (23) or by foot switch (2), so as to control Medical treatment device
The unlatching of tool (25):It is then to perform step F8;No, then controller sends out prompt tone, and stops providing medical instrument (25) high
Frequency drive signal performs step 12;
Step F8:Whether controller judges the value of impedance Ri between the value of impedance R1 and the value of impedance R2:It is then to perform step
F9;It is no, then perform step F11;
Step F9:Controller adjusts output power according to the method for step C5, makes output power between power P 1 and power P 2;
Step F10:Whether controller judges overtime during counter counts:It is no, then perform step F7;It is that controller sends out prompt tone,
And stop providing high-frequency driving signal to medical instrument (25), perform step 12;
Step F11:Controller judges whether user presses manual switch (23) or by foot switch (2), so as to control medical treatment
The unlatching of instrument (25):It is then to perform step F12;No, then controller sends out prompt tone, and stops carrying medical instrument (25)
For high-frequency driving signal, step 12 is performed;
Step F12:The first Seal task return values of setup parameter, controller judge impedance Ri value whether impedance R2 value and
Between the value of impedance R3:It is then to perform step F13;No, then the first Seal tasks return value is equal to 1, performs step D3;
Step F13:Controller adjusts output power according to the method for step C5, make output power power P 2 and power P 3 it
Between;
Step F14:Whether controller judges overtime during counter counts:It is no, then perform step F11;It is that controller sends out prompting
Sound, and stop providing high-frequency driving signal to medical instrument (25), perform step 12;
Step D3:Controller performs the 2nd Seal tasks, includes the following steps:
Step G1:Controller judges whether the first Seal tasks return value is equal to 1:It is no, then perform step 12;It is then to perform step
Rapid G2;
Step G2:Controller judges whether user presses manual switch (23) or by foot switch (2), so as to control Medical treatment device
The unlatching of tool (25):It is then to perform step G3;No, then controller sends out prompt tone, and stops providing medical instrument (25) high
Frequency drive signal performs step 12;
Step G3:Whether controller judges the value of impedance Ri between the value of impedance R3 and the value of impedance R4:It is then to perform step
G4;It is no, then perform step G6;
Step G4:Controller adjusts output power according to the method for step C5, makes output power between power P 3 and power P 4;
Step G5:Whether controller judges overtime during counter counts:It is no, then perform step G2;It is that controller sends out prompt tone,
And stop providing high-frequency driving signal to medical instrument (25), perform step 12;
Step G6:Controller judges whether user presses manual switch (23) or by foot switch (2), so as to control Medical treatment device
The unlatching of tool (25):It is then to perform step G7;No, then controller sends out prompt tone, and stops providing medical instrument (25) high
Frequency drive signal performs step 12;
Step G7:Controller judges whether medical instrument (25) is over-pressed according to the voltage signal that voltage sampling module (13) acquires:
It is then to perform step G8;It is no, then perform step G9;
Step G8:Controller adjusts output power according to the method for step C5, reduces output power;Perform step G10;
Step G9:Controller adjusts output power according to the method for step C5, increases output power;
Step G10:Whether controller judges overtime during counter counts:It is no, then perform step G11;It is that then controller sends out prompting
Sound, and stop providing high-frequency driving signal to medical instrument (25), perform step 12;
Step G11:Controller judges whether the value of impedance Ri is more than the value of impedance R5:It is then to perform step G12;It is no, then it performs
Step G13;
Step G12:Controller is judged whether to have completed the process of blood coagulation closure by the value of impedance Ri, completes blood coagulation and be closed
When, the value of impedance Ri levels off to 0;Perform step G6;
Step G13:Controller judges whether user presses manual switch (23) or by foot switch (2), so as to control medical treatment
The unlatching of instrument (25):It is then to perform step G14;No, then controller stops providing medical instrument (25) in high-frequency drive letter
Number, perform step 12;
Step G14:Controller adjusts output power according to the method for step C5, reduces output power;
Step G15:Whether controller judges overtime during counter counts:It is no, then perform step G13;It is that controller sends out prompting
Sound, and stop providing high-frequency driving signal to medical instrument (25), perform step 12;
Step 12:Perform step 4.
2. a kind of control method of medical rapid blood coagulation diced system as described in claim 1, it is characterised in that:The knowledge
Other device (22) includes the socket (1021), and the socket (1021) includes jack housing (107) and identification wiring board
(106), identification wiring board (106) is in jack housing (107);
Identification wiring board (106) includes main control chip (103), recognition unit (101), power module (102), LED indication module
(104) and signal output interface (105), recognition unit (101), LED indication module (104) and signal output interface (105) are equal
It is connect with main control chip (103);Power module (102) is main control chip (103), recognition unit (101) and LED indication module
(104) it powers, power module (102) output positive supply;
Recognition unit (101) includes the first photovoltaic element, the second photovoltaic element and third photovoltaic element;
First photovoltaic element includes resistance R33, photoelectric sensor U9, resistance R34, resistance R35, resistance R36, capacitance C12, resistance
R16, resistance R20, capacitance C6, resistance R37, resistance R38, photoelectric sensor U11, resistance R39, resistance R40, resistance R41, capacitance
C9, resistance R26, resistance R31, capacitance C10, resistance R42 and amplifier U10,1 foot of photoelectric sensor U9 are connected by resistance R33
Positive supply, the 2 feet connection ground wire of photoelectric sensor U9,3 feet of photoelectric sensor U9 pass through the resistance R34 and resistance that are connected in series with
R35 connection positive supplies, 3 feet of photoelectric sensor U9 pass through 4 feet of capacitance C12 connection photoelectric sensors U9, photoelectric sensor U9
3 feet also by 3 feet of resistance R36 connection amplifiers U10,3 feet of amplifier U10 also by 1 foot of resistance R37 connection amplifiers U10,
2 feet of amplifier U10 are by resistance R16 connection positive supplies, the resistance R20 and capacitance C6 of 2 feet of amplifier U10 also by being connected in parallel
Ground wire is connected, 1 foot of amplifier U10 connects the main control chip (103);1 foot of photoelectric sensor U11 is connected by resistance R38
Positive supply, the 2 feet connection ground wire of photoelectric sensor U11,3 feet of photoelectric sensor U11 pass through the resistance R39 and electricity that are connected in series with
R40 connection positive supplies are hindered, 3 feet of photoelectric sensor U11 pass through 4 feet of capacitance C9 connection photoelectric sensors U11, photoelectric sensor
For 3 feet of U11 also by 5 feet of resistance R41 connection amplifiers U10,5 feet of amplifier U10 also pass through the 7 of resistance R42 connection amplifiers U10
Foot, 6 feet of amplifier U10 are by resistance R26 connection positive supplies, the resistance R31 and electricity of 6 feet of amplifier U10 also by being connected in parallel
Hold C10 connection ground wires, 7 feet of amplifier U10 connect the main control chip (103);
Second photovoltaic element includes resistance R13, photoelectric sensor U5, resistance R14, resistance R17, resistance R18, capacitance C5, resistance
R15, resistance R19, capacitance C7, resistance R22, resistance R23, photoelectric sensor U7, resistance R24, resistance R28, resistance R29, capacitance
C8, resistance R25, resistance R30, capacitance C11, resistance R32 and amplifier U6,1 foot of photoelectric sensor U5 by resistance R13 connections just
Power supply, the 2 feet connection ground wire of photoelectric sensor U5,3 feet of photoelectric sensor U5 pass through the resistance R14 and resistance that are connected in series with
R17 connection positive supplies, 3 feet of photoelectric sensor U5 by 4 feet of capacitance C5 connection photoelectric sensors U5, photoelectric sensor U5's
For 3 feet also by 3 feet of resistance R18 connection amplifiers U6,3 feet of amplifier U6 also pass through 1 foot of resistance R22 connection amplifiers U6, amplifier
2 feet of U6 also connect ground by the resistance R19 being connected in parallel by resistance R15 connection positive supplies, 2 feet of amplifier U6 with capacitance C7
Line, 1 foot of amplifier U6 connect the main control chip (103);1 foot of photoelectric sensor U7 passes through resistance R23 connection positive supplies, light
The 2 feet connection ground wire of electric transducer U7,3 feet of photoelectric sensor U7 are connected just by the resistance R24 being connected in series with resistance R28
Power supply, 3 feet of photoelectric sensor U7 are also passed through by 4 feet of capacitance C8 connection photoelectric sensors U7,3 feet of photoelectric sensor U7
5 feet of resistance R29 connection amplifiers U6, also by 7 feet of resistance R32 connection amplifiers U6,6 feet of amplifier U6 lead to 5 feet of amplifier U6
Resistance R25 connection positive supplies are crossed, 6 feet of amplifier U6 also connect ground wire, amplifier by the resistance R30 being connected in parallel with capacitance C11
7 feet of U6 connect the main control chip (103);
Third photovoltaic element includes resistance R1, photoelectric sensor U1, resistance R2, resistance R4, resistance R5, capacitance C1, resistance R3, electricity
Hinder R6, capacitance C2, resistance R21, resistance R7, photoelectric sensor U3, resistance R8, resistance R27, resistance R10, capacitance C3, resistance R9,
Resistance R11, capacitance C4, resistance R12 and amplifier U2,1 foot of photoelectric sensor U1 pass through resistance R1 connection positive supplies, photoelectric sensing
The 2 feet connection ground wire of device U1,3 feet of photoelectric sensor U1 connect positive supply, light by the resistance R2 being connected in series with resistance R4
3 feet of electric transducer U1 also pass through resistance R5 by 4 feet of capacitance C1 connection photoelectric sensors U1,3 feet of photoelectric sensor U1
3 feet of amplifier U2 are connected, for 3 feet of amplifier U2 also by 1 foot of resistance R21 connection amplifiers U2,2 feet of amplifier U2 pass through resistance R3
Positive supply is connected, 2 feet of amplifier U2 also connect ground wire, the 1 foot connection of amplifier U2 with capacitance C2 by the resistance R6 being connected in parallel
The main control chip (103);1 foot of photoelectric sensor U3 is connected by resistance R7 connection positive supplies, 2 feet of photoelectric sensor U3
Ground wire, 3 feet of photoelectric sensor U3 connect positive supply with resistance R27 by the resistance R8 being connected in series with, and the 3 of photoelectric sensor U3
Foot also passes through the 5 of resistance R10 connection amplifiers U2 by 4 feet of capacitance C3 connection photoelectric sensors U3,3 feet of photoelectric sensor U3
Foot, for 5 feet of amplifier U2 also by 7 feet of resistance R12 connection amplifiers U2,6 feet of amplifier U2 pass through resistance R9 connection positive supplies, fortune
6 feet for putting U2 also connect ground wire with capacitance C4 by the resistance R11 being connected in parallel, and 7 feet of amplifier U2 connect the main control chip
(103);
The model STC89C52 of the main control chip (103);
The LED indication module (104) is LED light;The signal output interface (105) is 232 interfaces.
3. a kind of control method of medical rapid blood coagulation diced system as claimed in claim 2, it is characterised in that:It is described to insert
The outer surface of the housing of head (1020) is equipped with the first groove (1010), the second groove (1014), third groove (1018), the 4th recessed
Slot (1011), the 5th groove (1017) and the 6th groove (1019).
4. a kind of control method of medical rapid blood coagulation diced system as claimed in claim 3, it is characterised in that:It is described to insert
After head (1020) is inserted into socket (1021), first groove (1010) is corresponding with the photoelectric sensor U9, and described second is recessed
Slot (1014) is corresponding with the photoelectric sensor U5, and the third groove (1018) is corresponding with the photoelectric sensor U1, described
4th groove (1011) is corresponding with the photoelectric sensor U11, the 5th groove (1017) and U7 pairs of the photoelectric sensor
Should, the 6th groove (1019) is corresponding with the photoelectric sensor U3.
5. a kind of control method of medical rapid blood coagulation diced system as claimed in claim 4, it is characterised in that:It is described inverse
Become circuit (10) including inductance L2, inductance L3, TVS diode TS1, TVS diode TS2, TVS diode TS3, capacitance C115,
Capacitance C116, capacitance C117, capacitance C119, capacitance C136, capacitance C153, capacitance C135, capacitance C114, short circuit conducting wire W1 and short
Meet conducting wire W2;1 foot of inductance L2 and 1 foot of inductance L3 are all connected with the radio-frequency driven module (15), the 2 feet connection electricity of inductance L2
Hold 1 foot of C153,2 feet of inductance L2 pass through 2 feet of capacitance C115 connection capacitances C116,1 foot connection TVS, bis- poles of capacitance C116
1 foot of pipe TS1,2 feet of TVS diode TS1 pass through 1 foot of TVS diode TS2 connection TVS diodes TS3, TVS diode
1 foot of the 2 feet connection capacitance C136 of TS3,1 foot of capacitance C116 are also connected by the capacitance C117 being connected in series with capacitance C119
1 foot of capacitance C136,1 foot of the 2 feet connection capacitance C136 of inductance L3, sets one end of short circuit conducting wire W1 as short circuit conducting wire W1's
1 foot, the other end are 2 feet of short circuit conducting wire W1, set one end of short circuit conducting wire W2 as 1 foot of short circuit conducting wire W2, and the other end is short
2 feet of conducting wire W2,1 foot of the 2 feet connection short circuit conducting wire W2 of capacitance C136 are connect, 2 feet of capacitance C136 are also connected with short circuit conducting wire W1
2 feet, 1 foot of short circuit conducting wire W1 connects 2 feet of capacitance C153, capacitance by the capacitance C135 that is connected in parallel with capacitance C114
2 feet of C153 constitute the output terminal of the inverter circuit (10) with 2 feet of short circuit conducting wire W2;
The output terminal of the inverter circuit (10) connects the relay (11);
The voltage sampling module (13) on the short circuit conducting wire W1 is set, the electric current is set on the short circuit conducting wire W2
Sampling module (14), the voltage sampling module (13) connect second analog-digital converter (18), the electric current by conducting wire
Sampling module (14) connects first analog-digital converter (19) by conducting wire.
6. a kind of control method of medical rapid blood coagulation diced system as claimed in claim 5, it is characterised in that:It is described slow
The model 74LS165 of storage (4);The model MAX518 of the digital analog converter (8);Second analog-digital converter (18)
Model with first analog-digital converter (19) is ad1674;The CPU module (20) is ARM9 processors;The overvoltage
The model TCS2802 of protection module (7);The photoelectric isolation module (3) is photoelectrical coupler;The display screen (21) is
LCD display (21);The voltage sampling module (13) be JDZX16A-10R type voltage transformers, the current sampling module
(14) model LZZBJ9-12 type current transformers, the model DSPIC4011 of the radiofrequency signal generation module (17);
The model 74HC00 of NAND gate module (16);The model MIC4451 of radio-frequency driven module (15);The medical instrument (25)
For procedures electrode.
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Publication number | Priority date | Publication date | Assignee | Title |
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CN114271932A (en) * | 2021-12-28 | 2022-04-05 | 南京艾力芬医疗器械有限公司 | Wireless high-frequency surgical system host |
CN116570364A (en) * | 2023-05-06 | 2023-08-11 | 北京万洁天元医疗器械股份有限公司 | High-frequency operation equipment, gear adjusting method and device |
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2016
- 2016-12-28 CN CN201611236335.9A patent/CN108245238A/en active Pending
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
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CN114271932A (en) * | 2021-12-28 | 2022-04-05 | 南京艾力芬医疗器械有限公司 | Wireless high-frequency surgical system host |
CN116570364A (en) * | 2023-05-06 | 2023-08-11 | 北京万洁天元医疗器械股份有限公司 | High-frequency operation equipment, gear adjusting method and device |
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