CN218473047U - Thrombolysis system circuit and ultrasonic thrombolysis system - Google Patents

Abstract

The utility model provides a dissolve bolt system circuit and supersound dissolve bolt system, this dissolve bolt system circuit includes: the pulse excitation circuit is connected with the main circuit, and the control circuit is connected with the main circuit and the pulse excitation circuit; the pulse excitation circuit includes: the half-bridge driving circuit comprises a half-bridge driver, an upper tube driving circuit and a lower tube driving circuit, wherein the upper tube driving circuit and the lower tube driving circuit are connected with the half-bridge driver, the upper tube driving circuit consists of a second switching tube Q2 and a third rectifying diode D3 which are connected in series, and the lower tube driving circuit consists of a third switching tube Q3 and a fourth rectifying diode D4 which are connected in series; third rectifier diode D3, fourth rectifier diode D4 and half-bridge driver electricity are connected, and second switch tube Q2 and the last pipe drive signal pin electricity of half-bridge driver are connected, and third switch tube Q3 and the lower pipe drive signal pin electricity of half-bridge driver are connected. Through the utility model discloses, realized the output voltage range and frequency, the acoustic pressure of thrombolysis system circuit and left out continuously adjustable's purpose.

Description

Thrombolysis system circuit and supersound thrombolysis system

Technical Field

The utility model relates to a dissolve and tie technical field, especially relate to a dissolve and tie system circuit and supersound dissolve and tie system.

Background

Thrombolysis is understood literally as the process of dissolving a thrombus present in a blood vessel. The thrombus inside the blood vessel is formed because of fibrinogen aggregation, so that the purpose of dissolving thrombus can be achieved by injecting a medicament for dissolving fibrinogen into the body. However, in the process of thrombolysis, there is a risk of bleeding, and therefore, it is necessary to select an appropriate thrombolysis method for different thrombi. Currently thrombolysis involves two methods. One of them is local thrombolysis, that is, a thrombolysis catheter is inserted into the local part of the thrombus, and the thrombolysis medicine is injected through the thrombolysis catheter. The advantage of this method is that a larger effect can be achieved with a smaller dose. A disadvantage is an invasive procedure, requiring insertion of a catheter through a wound. Another thrombolytic method is to inject the drug intravenously so that the drug acts systemically. The disadvantage is that a larger dose of the drug is required and the risk of bleeding is greater.

At present, an ultrasonic-assisted thrombus dissolving device is developed based on the development of technology, and thrombus is torn and dissolved by utilizing the cavitation of ultrasonic waves. The cavitation of the ultrasonic wave is closely related to the frequency, sound pressure, sound intensity and other parameters of the ultrasonic wave, the ultrasonic waves with different frequencies, sound pressures and sound intensities can generate cavitation with different intensities, and the cavitation with different intensities can also have different decomposition speeds and decomposition degrees on thrombus.

The frequency, the sound pressure and the pressure intensity sent by a thrombolysis system circuit in thrombolysis equipment in the prior art are mainly divided into two types, one type is fixed frequency, sound pressure and pressure intensity, namely, the thrombolysis system circuit can only send ultrasonic waves with one frequency, sound pressure and pressure intensity, and the thrombolysis equipment with fixed ultrasonic wave frequency, sound pressure and pressure intensity has the defect of low efficiency when used for treatment; meanwhile, different patients have different thrombus severity degrees, and the thrombolytic equipment with fixed ultrasonic frequency, sound pressure and pressure intensity can only be applied to the thrombus degree of a small part of patients. Therefore, the circuit of the thrombolysis system in the prior art cannot adapt to the intensity of the ultrasonic frequency, the sound pressure and the pressure intensity according to the thrombus degrees of different patients, so that the defect that one thrombolysis device cannot be simultaneously suitable for different thrombus degrees exists.

In view of the above, there is a need for an improved thrombolytic system circuit in the prior art to solve the above problems.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the intensity that the thrombolysis system circuit that exists can not be according to different patients' thrombus degree self-adaptation ultrasonic frequency, acoustic pressure and pressure among the prior art to there is a defect that thrombolysis equipment can not be applicable to different thrombus degrees simultaneously.

In order to achieve the above object, in a first aspect, the present invention provides a thrombolysis system circuit, including:

the pulse excitation circuit is connected with the main circuit, and the control circuit is connected with the main circuit and the pulse excitation circuit;

the pulse excitation circuit includes: the driving circuit comprises a half-bridge driver, an upper tube driving circuit and a lower tube driving circuit, wherein the upper tube driving circuit and the lower tube driving circuit are connected with the half-bridge driver, the upper tube driving circuit consists of a second switching tube Q2 and a third rectifying diode D3 which are connected in series, and the lower tube driving circuit consists of a third switching tube Q3 and a fourth rectifying diode D4 which are connected in series;

third rectifier diode D3, fourth rectifier diode D4 and half-bridge driver electricity are connected, and second switch tube Q2 and the last pipe drive signal pin electricity of half-bridge driver are connected, and third switch tube Q3 and the lower pipe drive signal pin electricity of half-bridge driver are connected.

As a further improvement of the present invention, the main circuit includes: the transformer T1 is provided with a primary winding N1 and a secondary winding, an input circuit and an output circuit which are respectively connected with the primary winding N1 and the secondary winding, and a voltage sampling circuit which is connected with the output circuit;

the transformer T1 and the voltage sampling circuit are respectively and electrically connected with the control circuit.

As a further improvement of the present invention, the output circuit includes: the first rectifying diode D1 and the second rectifying diode D2 are connected in parallel;

the secondary winding includes: a first secondary winding N2 and a second secondary winding N3;

the first rectifier diode D1 is electrically connected to the first secondary winding N2, and the second rectifier diode D2 is electrically connected to the second secondary winding N3.

As a further improvement of the present invention, the control circuit includes:

the PWM controller, a main control circuit MCU unit, an operational amplifier U1 and a first switch tube Q1 which are connected with the PWM controller, and a DAC digital-to-analog converter which is connected with the operational amplifier U1 and the main control circuit MCU unit;

the first switching tube Q1 is electrically connected with the transformer T1, and the operational amplifier U1 is electrically connected with the voltage sampling circuit.

As a further improvement of the present invention, the control circuit further includes: and the current detection resistor R3 is connected with the source electrode of the first switching tube Q1, and the current detection resistor R3 is grounded.

As a further improvement of the present invention, the voltage sampling circuit includes: the first voltage detection resistor R1 and the second voltage detection resistor R2 are connected in series;

the operational amplifier U1 is connected in parallel between the first voltage detection resistor R1 and the second voltage detection resistor R2, and the second voltage detection resistor R2 is grounded.

As a further improvement of the utility model, the thrombolysis system circuit further comprises: the filter impedance matching circuit is connected with the pulse excitation circuit;

the filter impedance matching circuit includes: an inductor L1 and a capacitor C4 connected with the inductor L1 in parallel;

the inductor L1 is electrically connected to the third rectifier diode D3, the fourth rectifier diode D4 and the half-bridge driver, and the capacitor C4 is grounded.

As a further improvement of the present invention, the thrombolysis system circuit further includes: a conduit transducer coupled to the inductor L1 and a filter impedance matching circuit.

In a second aspect, the present invention further discloses an ultrasonic thrombolysis system, including: a thrombolysis system circuit as disclosed in the first aspect.

Compared with the prior art, the beneficial effects of the utility model are that:

the frequency and the duty ratio of a half-bridge driving signal output by the MCU unit of the main control circuit are changed to realize the purpose of controlling the frequency and the duty ratio of an ultrasonic excitation power supply output by the pulse excitation circuit, finally realize the purposes of continuously adjusting the output voltage amplitude, the frequency and the sound pressure of a thrombolysis system circuit and omitting, and improve the flexibility and the high efficiency of the thrombolysis equipment comprising the thrombolysis system circuit in clinical application.

Drawings

Fig. 1 is a schematic structural block diagram of a thrombolysis system circuit shown in the present invention;

fig. 2 is a schematic circuit diagram of the thrombolysis system circuit shown in the present invention.

Detailed Description

The present invention is described in detail with reference to the embodiments shown in the drawings, but it should be understood that these embodiments are not intended to limit the present invention, and those skilled in the art should understand that the functions, methods, or structural equivalents or substitutions made by these embodiments are within the scope of the present invention.

Referring to fig. 1, the present embodiment provides a thrombolysis system circuit, which includes: the system comprises a control circuit 10, a main circuit 50 and a pulse excitation circuit 60 which are connected with the Output end (namely, output end) of the control circuit 10, a filter impedance matching circuit 70 connected with the Output end of the pulse excitation circuit 60, a conduit transducer 80 connected with the Output end of the filter impedance matching circuit 70, a PC system 20 connected with the control circuit 10, a temperature acquisition circuit 30 connected with the Input end (namely, input end) of the PC system 20, and a conduit thermocouple 40 connected with the Input end of the temperature acquisition circuit 30. Wherein, the output end of the main circuit 50 is connected with the pulse excitation circuit 60.

In particular, PC system 20 may be understood as a computer operating system, including human-machine interface and key controls. The information required to be controlled (for example, the transmitting frequency, the transmitting voltage amplitude, the transmitting energy duty ratio, etc. of the thrombolysis system circuit) is transmitted to the MCU unit of the main control circuit in the control circuit 10 through the touch screen input system (i.e., the whole circuit system formed by the thrombolysis system circuit). The control circuit 10 is connected to the PC system 20, the main circuit 50 and the pulse excitation circuit 60 at the same time. Specifically, control circuit 10 is coupled to the output of PC system 20, the input of main circuit 50, and the input of pulse driver circuit 60. The MCU unit of the main control circuit in the control circuit 10 receives the control command from the PC system 20 to enable the main circuit 50 and adjust the amplitude of the output voltage of the main circuit 50. The MCU unit of the main control circuit in the control circuit 10 receives the control command from the PC system 20 to control the half-bridge driver in the pulse excitation circuit 60, so as to output the required pulse excitation power with adjustable frequency and duty ratio, thereby improving the flexibility and efficiency of the thrombolysis system circuit and the thrombolysis apparatus containing the same in clinical application.

The main circuit 50 is connected with the output end of the control circuit 10, so as to control the enabling switch and the output voltage amplitude of the main circuit 50 through the control circuit 10. The main circuit 50 is connected to the input of the pulse excitation circuit 60, so as to provide a stable voltage with positive and negative symmetry for the pulse excitation circuit 60. The pulse excitation circuit 60 is connected with the output end of the control circuit 10, so as to control the enabling switch, the output pulse excitation frequency and the duty ratio of the pulse excitation circuit 60 through the control circuit 10. The pulse excitation circuit 60 is coupled to an input of the filtered impedance matching circuit 70 to provide a pulse excitation signal to the filtered impedance matching circuit 70. The filtering impedance matching circuit 70 is connected to the input end of the catheter transducer 80, so that after the pulse excitation source output by the pulse excitation circuit 60 is filtered and impedance-matched by the filtering impedance matching circuit 70, one or more piezoelectric ceramics (not shown) included in the catheter transducer are excited to work, so as to output ultrasonic waves through the piezoelectric ceramics, and thus, the cavitation effect of the ultrasonic waves is utilized to perform thrombolysis treatment on thrombus in a focus area under the coordination of thrombolytic drugs.

Referring to fig. 2, fig. 2 is a specific circuit diagram of the control circuit 10, the main circuit 50, the pulse excitation circuit 60, the filter impedance matching circuit 70, and the catheter transducer 80 according to the present invention. The main circuit 50 includes: an input circuit 501, a transformer T1, an output circuit 502, and a voltage sampling circuit 503. The transformer T1 has a primary winding and a secondary winding, the input circuit 501 and the output circuit 502 are respectively connected to the primary winding N1 and the secondary winding (i.e., the first secondary winding N2 and the second secondary winding N3), and the voltage sampling circuit 503 is connected to the output circuit 502.

Specifically, referring to fig. 2, the input circuit 501 provides an input voltage Vin to the main circuit 50, the capacitor C1 is an input energy storage capacitor, an anode of the capacitor C1 is connected in parallel with an input end of the voltage Vin, and a cathode of the capacitor C1 is grounded. The primary winding N1 of the transformer T1 is connected to the input circuit 501. The primary winding N1 is connected to the input circuit 501 and the drain of the first switching tube Q1. The secondary winding of the transformer T1 includes: the first secondary winding N2 and the second secondary winding N3, and the first secondary winding N2 and the second secondary winding N3 are connected to the output circuit 502. The output circuit 502 includes a first rectifying diode D1 and a second rectifying diode D2 connected in parallel for the purpose of outputting a voltage HV + and a voltage HV-, respectively. The anode of the first rectifier diode D1 is connected in series with the first secondary winding N2 of the transformer T1, the cathode of the second rectifier diode D2 is connected in series with the second secondary winding N3 of the transformer T1, and the other end of the first secondary winding N2 is connected in series with the other end of the second secondary winding N3 and grounded. The capacitor C2 and the capacitor C3 are respectively output energy storage filter capacitors, the anode of the capacitor C2 is connected with the first rectifier diode D1 in parallel, the cathode of the capacitor C3 is connected with the second rectifier diode D2 in parallel, and the cathode of the capacitor C2 and the anode of the capacitor C3 are connected with the other end of the first secondary winding N2 and the other end of the second secondary winding N3 and are grounded. The primary winding N1 of the transformer T1 is connected to the input circuit 501 to achieve the purpose of storing energy of the input circuit 501; the first secondary winding N2 and the second secondary winding N3 of the transformer T1 are respectively connected to the output circuit 502 to achieve the purpose of releasing energy to the output circuit 502. The positive and negative symmetrical voltages of HV + and HV-are provided to the pulse driver circuit 60 through the first and second rectifier diodes D1 and D2 of the output circuit 502. The voltage sampling circuit 503 includes a voltage detection resistor R1 and a voltage detection resistor R2 connected in series, and the other end of the voltage detection resistor R2 is grounded. The first voltage detection resistor R1 is connected in parallel with the first rectifying diode D1 to detect the voltage value outputted from the first rectifying diode D1, and the second voltage detection resistor R2 is connected in parallel with the second rectifying diode D2 to detect the voltage value outputted from the second rectifying diode D2.

Referring to fig. 2, the control circuit 10 is connected to the transformer T1 to control the energy storage and release of the transformer T1. The control circuit 10 is connected to the voltage sampling circuit 503 to control the amplitude of the output voltage HV + and the voltage HV-and stabilize the output. The control circuit 10 is connected to the pulse excitation circuit 60 to control the frequency and duty ratio of the ultrasonic excitation power source output by the pulse excitation circuit 60. The control circuit 10 includes: the main control circuit MCU unit (i.e., the main control circuit MCU shown in fig. 2), the PWM controller, the first switching tube Q1, the current detection resistor R3, the operational amplifier U1, and the DAC digital-to-analog converter (i.e., the DAC shown in fig. 2). The drain of the first switching tube Q1 is connected in series with the primary winding N1 of the transformer T1, the source of the first switching tube Q1 is connected in series with the current detection resistor R3, and the gate of the first switching tube Q1 is connected in series with the PWM controller. The other end of the current detection resistor R3 is grounded. If the first switch tube Q1 is conducted, the purpose of charging the primary winding N1 is achieved through the input voltage Vin; if the first switching tube Q1 is turned off, the transformer T1 releases energy to the output circuit 502 through the first secondary winding N2. The PWM controller is connected to the first switching tube Q1 to send a PWM signal to the first switching tube Q1, so as to control the on/off of the first switching tube Q1. The MCU unit of the main control circuit is connected with the PWM controller to achieve the purpose of controlling the enabling switch of the PWM controller. If the output circuit 502 needs to regulate voltage, the control circuit 10 sends the digital voltage regulating signal sent by the MCU unit of the main control circuit to the DAC. The DAC digital-to-analog converter is connected with the negative electrode (i.e. the inverting input end) of the operational amplifier U1, so that after the DAC digital-to-analog converter receives the digital voltage regulating signal sent by the master control circuit MCU unit, the voltage regulating reference signal of the DAC digital-to-analog converter is input to the operational amplifier U1 from the inverting input end. The positive electrode (i.e., the non-inverting input terminal) of the operational amplifier U1 is connected in parallel between the first voltage detection resistor R1 and the second voltage detection resistor R2 included in the voltage sampling circuit 503, so as to transmit the actual feedback voltage VFB collected by the output voltage HV + of the voltage sampling circuit 503 to the non-inverting input terminal of the operational amplifier U1. The output end of the operational amplifier U1 is connected with a feedback pin and a compensation pin of the PWM controller, so that the purpose of digital regulation of output voltages HV + and HV-is realized.

Referring to fig. 2, the pulse driver circuit 60 includes a half-bridge driver, and a top tube driver circuit and a bottom tube driver circuit connected to the half-bridge driver. The upper tube driving circuit is composed of a second switching tube Q2 and a third rectifying diode D3 which are connected in series, and the lower tube driving circuit is composed of a third switching tube Q3 and a fourth rectifying diode D4 which are connected in series. The drain of the second switching tube Q2 is connected to the output of the voltage HV + (i.e., the first rectifying diode D1), the source of the second switching tube Q2 is connected to the anode of the third rectifying diode D3, and the gate of the second switching tube Q2 is connected to the upper tube driving signal pin of the half-bridge driver. The source of the third switching tube Q3 is connected to the output of the voltage HV + (i.e., the second rectifying diode D2), the drain of the third switching tube Q3 is connected to the cathode of the fourth rectifying diode D4, and the gate of the third switching tube Q3 is connected to the lower tube driving signal pin of the half-bridge driver. The cathode of the third rectifying diode D3 is connected to the anode of the fourth rectifying diode D4 and electrically connected to the filter impedance matching circuit 70. The main control circuit MCU unit is connected with the half-bridge driver, so that the frequency and the duty ratio of the ultrasonic excitation power supply output by the pulse excitation circuit 60 are controlled by changing the frequency and the duty ratio of the half-bridge driving signal output by the main control circuit MCU unit, and the purpose of finally realizing the output voltage amplitude, the frequency and the sound pressure of the thrombolysis system circuit and omitting continuous adjustment is realized, so that the effects of improving the flexibility and the efficiency of the thrombolysis system circuit in clinical application are achieved.

For example, the first switching tube Q1, the second switching tube Q2 and the third switching tube Q3 in this embodiment are all NMOS devices.

Referring to fig. 2, the filter impedance matching circuit 70 includes: an inductor L1 and a capacitor C4 connected in parallel with the inductor L1. One end of the inductor L1 is connected to the negative electrode of the third rectifying diode D3 and the positive electrode of the fourth rectifying diode D4 in the pulse excitation circuit 60; the other end of the inductor L1 is connected with the anode of the capacitor C4; the other end of the cathode of the capacitor C4 is grounded. One end of the conduit transducer 80 is connected in series with the inductor L1, and the other end of the conduit transducer 80 is connected to the negative electrode of the capacitor C4 and commonly grounded. After the inductor L1 and the capacitor C4 are matched, filtering and impedance matching can be performed on the ultrasonic excitation power THV output by the pulse excitation circuit 60, so that the output ultrasonic excitation power enables the adaptive catheter transducer 80 to reach an optimal working state.

On the other hand, the utility model also discloses an supersound thrombolysis equipment, include: the thrombolysis system circuit.

For details, reference is made to the above-mentioned embodiment of the thrombolysis system circuit, and details are not repeated herein.

The above list of details is only for the practical implementation of the present invention, and they are not intended to limit the scope of the present invention, and all equivalent implementations or modifications that do not depart from the technical spirit of the present invention should be included in the scope of the present invention.

It is obvious to a person skilled in the art that the invention is not restricted to details of the above-described exemplary embodiments, but that it can be implemented in other specific forms without departing from the spirit or essential characteristics of the invention. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (9)

1. A thrombolysis system circuit, comprising:

the pulse excitation circuit is connected with the main circuit, and the control circuit is connected with the main circuit and the pulse excitation circuit;

the pulse excitation circuit includes: the half-bridge driving circuit comprises a half-bridge driver, an upper tube driving circuit and a lower tube driving circuit, wherein the upper tube driving circuit and the lower tube driving circuit are connected with the half-bridge driver, the upper tube driving circuit consists of a second switching tube Q2 and a third rectifying diode D3 which are connected in series, and the lower tube driving circuit consists of a third switching tube Q3 and a fourth rectifying diode D4 which are connected in series;

third rectifier diode D3 fourth rectifier diode D4 with the half-bridge driver links electrically, and second switch tube Q2 links electrically with the top tube drive signal pin of half-bridge driver, and third switch tube Q3 links electrically with the lower tube drive signal pin of half-bridge driver.

2. The thrombolysis system circuit of claim 1, wherein the primary circuit comprises: the transformer T1 is provided with a primary winding N1 and a secondary winding, an input circuit and an output circuit which are respectively connected with the primary winding N1 and the secondary winding, and a voltage sampling circuit which is connected with the output circuit;

the transformer T1 and the voltage sampling circuit are respectively and electrically connected with a control circuit.

3. The thrombolysis system circuit of claim 2, wherein the output circuit comprises: a first rectifying diode D1 and a second rectifying diode D2 which are connected in parallel;

the secondary winding includes: a first secondary winding N2 and a second secondary winding N3;

the first rectifier diode D1 is electrically connected to the first secondary winding N2, and the second rectifier diode D2 is electrically connected to the second secondary winding N3.

4. The thrombolysis system circuit of claim 2, wherein the control circuit comprises:

the PWM controller, a main control circuit MCU unit, an operational amplifier U1 and a first switch tube Q1 which are connected with the PWM controller, and a DAC digital-to-analog converter which is connected with the operational amplifier U1 and the main control circuit MCU unit;

the first switching tube Q1 is electrically connected with the transformer T1, and the operational amplifier U1 is electrically connected with the voltage sampling circuit.

5. The thrombolysis system circuit of claim 4, wherein the control circuit further comprises: and the current detection resistor R3 is connected with the source electrode of the first switching tube Q1, and the current detection resistor R3 is grounded.

6. The thrombolysis system circuit of claim 4, wherein the voltage sampling circuit comprises: the first voltage detection resistor R1 and the second voltage detection resistor R2 are connected in series;

the operational amplifier U1 is connected in parallel between the first voltage detection resistor R1 and the second voltage detection resistor R2, and the second voltage detection resistor R2 is grounded.

7. The thrombolysis system circuit according to claim 1, further comprising: the filter impedance matching circuit is connected with the pulse excitation circuit;

the filter impedance matching circuit includes: an inductor L1 and a capacitor C4 connected with the inductor L1 in parallel;

the inductor L1 is electrically connected to the third rectifying diode D3, the fourth rectifying diode D4 and the half-bridge driver, and the capacitor C4 is grounded.

8. The thrombolysis system circuit according to claim 7, further comprising: a conduit transducer coupled to the inductor L1 and a filter impedance matching circuit.

9. An sonothrombolysis system comprising: the thrombolysis system circuit of any one of claims 1-8.

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