阅读说明：本技术 一种基于以太网及大数据激光医疗控制系统 (Laser medical control system based on Ethernet and big data ) 是由 黎朝 王晓沛 于 2019-10-16 设计创作，主要内容包括：本发明涉及一种基于以太网及大数据激光医疗控制系统,包括主控制器,以太网单元,大数据,人机互联单元,脉冲激光器,脚踏,光耦隔离,继电器驱动电路,所述主控制器通过以太网单元接入大数据,所述主控制器还分别与以太网单元,脉冲激光器,光耦隔离,继电器驱动电路连接,光耦隔离与脚踏连接；本发明通过以太网及大数据链接功能,进而优化脉冲激光器的各项参数,使发射出的激光达到治疗时所需要的参数值；并且将经常使用的激光参数及时存储到以人机互联单元,以备下次使用时直接调用及参考,解决操作上的繁琐问题,提高工作效率；同时主控制器通过以太网单元实现大数据的交换,可以读到客户使用的脉冲激光器的所有数据。(The invention relates to an Ethernet and big data based laser medical control system, which comprises a main controller, an Ethernet unit, big data, a man-machine interconnection unit, a pulse laser, a pedal, an optical coupling isolation and a relay drive circuit, wherein the main controller is connected with the big data through the Ethernet unit and is also connected with the Ethernet unit, the pulse laser, the optical coupling isolation and the relay drive circuit respectively; according to the invention, through the Ethernet and the big data link function, various parameters of the pulse laser are further optimized, so that the emitted laser reaches the parameter value required by treatment; the frequently used laser parameters are timely stored in the man-machine interconnection unit for direct calling and reference in the next use, so that the problem of complexity in operation is solved, and the working efficiency is improved; meanwhile, the main controller realizes the exchange of big data through the Ethernet unit, and can read all data of the pulse laser used by the client.)

1. The utility model provides a based on ethernet and big data laser medical control system which characterized in that:

the device comprises a main controller, an Ethernet unit, big data, a man-machine interconnection unit, a pulse laser, a pedal, an optical coupler isolation and a relay drive circuit, wherein the main controller is connected with the big data through the Ethernet unit, is also respectively connected with the Ethernet unit, the pulse laser, the optical coupler isolation and the relay drive circuit, and is connected with the pedal through the optical coupler isolation;

the main controller is used for normal operation of the whole equipment and realizes the exchange of big data through the Ethernet unit;

the man-machine interconnection unit is used for realizing that: setting power parameters of the pulse laser; storing and calling different treatment schemes of the laser; statistical display of energy, timed treatment parameters; alarming and prompting the abnormal state of the system; prompting by a light-emitting indicator lamp;

the foot switch is closed to control the start and stop of the pulse laser;

and the relay driving circuit is used for driving the pulse laser to work.

2. The ethernet-based and big-data laser medical control system according to claim 1, wherein said relay driving circuit comprises: the LED lamp comprises an AND gate circuit, a triode 3, a triode 4, a transient suppression tube 5, an LED lamp and two relays, wherein the foot switch is connected with the base electrode of the triode 3 through a junction box and a resistor 11, the collector electrode of the triode 3 is respectively connected with a resistor 29 and a 5V power supply, the resistor 29 is connected with the base electrode of the triode 3, the emitter electrode of the triode 3 is grounded through a resistor 13, one end of the transient suppression tube 4 is connected with the resistor 11, and the other end is grounded; the collector of the triode 3 is grounded through two capacitors connected in parallel, the emitter of the triode 3 is also connected with the 9 th pin input end of the AND circuit through a resistor 12, the 10 th pin input end of the AND circuit is connected with a junction box through a resistor 27, the junction box is connected with a main controller, the 10 th pin input end of the AND circuit is also connected with a transient suppression tube 5, the other end of the transient suppression tube 5 is grounded, the 8 th pin output end of the AND circuit is connected with the base of the triode 4 through a resistor 18, the base of the triode 4 is also grounded through a resistor 20, the emitter of the triode 4 is grounded, the collector of the triode 4 is respectively connected with an LED lamp, a first input end of a relay 5, a first input end of a relay 6 and a resistor 16, the LED lamp is connected with a 5V power supply through a resistor 14, the resistor 16 is also respectively connected with a resistor 15 and a second input end, and a second input end of the relay 5 is connected with a second input end of the relay 6.

Technical Field

The invention relates to laser medical equipment, in particular to a laser medical control system based on Ethernet and big data.

Background

Before the invention is researched and developed, equipment and instruments for treatment by using laser in the market cannot meet the function of linking Ethernet big data, so that the most effective treatment on diseases can not be carried out by fully utilizing the special data function of laser treatment data analysis.

Disclosure of Invention

The invention aims to provide a medical control system based on Ethernet and big data laser, so that various parameters of a pulse laser are optimized through the Ethernet and big data link function, and the emitted laser can reach the parameter values required by treatment; the frequently used laser parameters are timely stored in the man-machine interconnection unit for direct calling and reference in the next use, so that the problem of complexity in operation is solved, and the working efficiency is improved; meanwhile, the main controller realizes the exchange of big data through the Ethernet unit, and can read all data of the pulse laser used by the client.

In order to achieve the purpose, the invention has the following technical scheme:

the invention relates to a medical treatment control system based on Ethernet and big data laser,

the device comprises a main controller, an Ethernet unit, big data, a man-machine interconnection unit, a pulse laser, a pedal, an optical coupler isolation and a relay drive circuit, wherein the main controller is connected with the big data through the Ethernet unit, is also respectively connected with the Ethernet unit, the pulse laser, the optical coupler isolation and the relay drive circuit, and is connected with the pedal through the optical coupler isolation;

the main controller is used for normal operation of the whole equipment and realizes the exchange of big data through the Ethernet unit;

the man-machine interconnection unit is used for realizing that: setting power parameters of the pulse laser; storing and calling different treatment schemes of the laser; statistical display of energy, timed treatment parameters; alarming and prompting the abnormal state of the system; prompting by a light-emitting indicator lamp;

the foot switch is closed to control the start and stop of the pulse laser;

and the relay driving circuit is used for driving the pulse laser to work.

Wherein the relay drive circuit includes: the LED lamp comprises an AND gate circuit, a triode 3, a triode 4, a transient suppression tube 5, an LED lamp and two relays, wherein the foot switch is connected with the base electrode of the triode 3 through a junction box and a resistor 11, the collector electrode of the triode 3 is respectively connected with a resistor 29 and a 5V power supply, the resistor 29 is connected with the base electrode of the triode 3, the emitter electrode of the triode 3 is grounded through a resistor 13, one end of the transient suppression tube 4 is connected with the resistor 11, and the other end is grounded; the collector of the triode 3 is grounded through two capacitors connected in parallel, the emitter of the triode 3 is also connected with the 9 th pin input end of the AND circuit through a resistor 12, the 10 th pin input end of the AND circuit is connected with a junction box through a resistor 27, the junction box is connected with a main controller, the 10 th pin input end of the AND circuit is also connected with a transient suppression tube 5, the other end of the transient suppression tube 5 is grounded, the 8 th pin output end of the AND circuit is connected with the base of the triode 4 through a resistor 18, the base of the triode 4 is also grounded through a resistor 20, the emitter of the triode 4 is grounded, the collector of the triode 4 is respectively connected with an LED lamp, a first input end of a relay 5, a first input end of a relay 6 and a resistor 16, the LED lamp is connected with a 5V power supply through a resistor 14, the resistor 16 is also respectively connected with a resistor 15 and a second input end, and a second input end of the relay 5 is connected with a second input end of the relay 6.

Due to the adoption of the technical scheme, the invention has the advantages that:

1. through Ethernet and big data link function, further optimize every parameter of the pulse laser, make the laser that is launched reach the parameter value that is needed while treating;

2. the frequently used laser parameters are timely stored in the man-machine interconnection unit for direct calling and reference in the next use, so that the problem of complexity in operation is solved, and the working efficiency is improved;

3. the main controller realizes the exchange of big data through the Ethernet unit, and can read all data of the pulse laser used by a client, for example, who uses the pulse laser device, what parameters are used, what difference exists between the treatment scheme used by the client and the standard treatment scheme advanced by the client, so that the use and management of the whole device can be controlled, and the mobile terminal of the mobile phone can see the data by seeing the background in an office and seeing the system of a computer, and the data can be read on the terminal in real time; and observe how much energy we have used, the final effect situation, and what the clinical treatment plan we recommend is, you can see how much difference is between our actual operation and the recommended plan, the clinical effect is needed at last, this data can be referred to when training and debugging the clinical technique; the method can solve the common problem of the pulse laser device, can solve the individual problem of the pulse laser device, and can solve the innovation direction problem of the pulse laser device according to the common problem and the individual problem.

Drawings

FIG. 1 is a block schematic diagram of the working principle of the present invention;

fig. 2 is a schematic diagram of a relay drive circuit of the present invention.

In the figure, R11: a resistor 11; r12: a resistor 12; r13: a resistor 13; r14: a resistor 14; r15: a resistor 15; r16: a resistor 16; r18: a resistor 18; r20: a resistor 20; r27: a resistor 27; r29: a resistor 29; c4, C5: a capacitor; U2C: an AND gate circuit; q3: a triode 3; q4: a triode 4; TVS4 transient suppressor tube 4; TVS5 transient suppressor 5; d3, LED lamp; u5, a relay 5; u6, a relay 6; STOP: an emergency stop signal.

Detailed Description

With reference to figures 1-2 of the drawings,

the invention relates to a medical treatment control system based on Ethernet and big data laser,

the device comprises a main controller, an Ethernet unit, big data, a man-machine interconnection unit, a pulse laser, a pedal, an optical coupler isolation and a relay drive circuit, wherein the main controller is connected with the big data through the Ethernet unit, is also respectively connected with the Ethernet unit, the pulse laser, the optical coupler isolation and the relay drive circuit, and is connected with the pedal through the optical coupler isolation;

the main controller is used for normal operation of the whole equipment and realizes the exchange of big data through the Ethernet unit;

the man-machine interconnection unit is used for realizing that: setting power parameters of the pulse laser; storing and calling different treatment schemes of the laser; statistical display of energy, timed treatment parameters; alarming and prompting the abnormal state of the system; prompting by a light-emitting indicator lamp;

the foot switch is closed to control the start and stop of the pulse laser;

and the relay driving circuit is used for driving the pulse laser to work.

The relay drive circuit includes: the LED lamp comprises an AND gate circuit, a triode 3, a triode 4, a transient suppression tube 5, an LED lamp and two relays, wherein the foot switch is connected with the base electrode of the triode 3 through a junction box and a resistor 11, the collector electrode of the triode 3 is respectively connected with a resistor 29 and a 5V power supply, the resistor 29 is connected with the base electrode of the triode 3, the emitter electrode of the triode 3 is grounded through a resistor 13, one end of the transient suppression tube 4 is connected with the resistor 11, and the other end is grounded; the collector of the triode 3 is grounded through two capacitors connected in parallel, the emitter of the triode 3 is also connected with the 9 th pin input end of the AND circuit through a resistor 12, the 10 th pin input end of the AND circuit is connected with a junction box through a resistor 27, the junction box is connected with a main controller, the 10 th pin input end of the AND circuit is also connected with a transient suppression tube 5, the other end of the transient suppression tube 5 is grounded, the 8 th pin output end of the AND circuit is connected with the base of the triode 4 through a resistor 18, the base of the triode 4 is also grounded through a resistor 20, the emitter of the triode 4 is grounded, the collector of the triode 4 is respectively connected with an LED lamp, a first input end of a relay 5, a first input end of a relay 6 and a resistor 16, the LED lamp is connected with a 5V power supply through a resistor 14, the resistor 16 is also respectively connected with a resistor 15 and a second input end, and a second input end of the relay 5 is connected with a second input end of the relay 6.

When the invention works: by utilizing the man-machine interconnection unit, medical staff can compare the man-machine interconnection unit with the Ethernet and the big data, select the optimal scheme to set parameters of a laser mode, treatment frequency, laser energy and pulse width of the laser output by the pulse laser therapy machine, and can timely store the set parameters into the Ethernet unit to form big data set content at any time for next calling; after the microprocessor of the pulse laser therapeutic machine processes data according to the request input by the man-machine interconnection unit, the microprocessor of the pulse laser therapeutic machine adjusts and sets various parameters of the laser output by the pulse laser therapeutic machine, and can detect whether the set parameters are accurate or not in real time and achieve the expected setting effect.

The relay drive circuit of the pulse laser, U5 and U6 represent two relays, and output ends of the two relays are respectively connected to a zero line and a live line of a pulse laser power supply in series, so that simultaneous on and off are realized, and the phenomenon that the work of the whole system is influenced when one relay breaks down is avoided. Besides the input/output port I/O control of the main controller, each path of signal is controlled by a foot pedal emergency STOP signal STOP which is also controllable to the relays U5 and U6, so that the purpose of simultaneously performing emergency STOP on software and hardware is achieved. The selected emergency stop foot switch is of a normally closed type, the high level is effective, when the emergency stop is triggered, the Q3 is not conducted, the level of the 9 th pin input end of the AND gate circuit is pulled down, and then the I/O signal and the input/output port I/O signal of the main controller pass through the AND gate, the output is also of a low level, the Q4 is not conducted, the relays U5 and U6 are in an open circuit state, and the power supply of the pulse laser is disconnected;

in addition, 5V transient suppression tubes TVS4 and TVS5 are connected to the interface of the foot switch emergency STOP signal STOP and the input/output port I/O signal interface of the main controller on one hand, so as to prevent static accumulation from damaging the device; on the other hand, when the Q4 is turned on, the LTD lamp D3 is turned on as a circuit working state indication, so that troubleshooting is facilitated when an abnormality occurs in the system.

An Ethernet unit: ethernet (Ethernet) refers to the baseband lan specification created by Xerox corporation and jointly developed by Xerox, Intel, and DEC corporation, and is the most common communication protocol standard employed by existing lans today. Ethernet networks use CSMA/CD (carrier sense multiple access and collision detection) technology and operate on multiple types of cables at a rate of 10M/S. Ethernet is similar to the IEEE802.3 family of standards;

ethernet is a baseband local area network technology developed in the 70 s of the 20 th century, and uses coaxial cable as a network medium, and adopts a carrier multiple access and collision detection (CSMA/CD) mechanism, so that the data transmission rate reaches 10 MBPS.

Big data: big data (big data), which refers to a data set that cannot be captured, managed and processed by a conventional software tool within a certain time range, is a massive, high-growth-rate and diversified information asset that needs a new processing mode to have stronger decision-making power, insight discovery power and process optimization capability.

The big data of the invention refers to a data set which is continuously stored by an Ethernet server and a man-machine interconnection unit, and the content comprises the following contents: all data of the pulse laser used by the client, such as who is using the pulse laser device, what parameters are used (including parameters of laser mode, treatment frequency, laser energy size and pulse width of the laser output by the pulse laser therapeutic machine), and what difference exists between the treatment scheme used by the client and the standard treatment scheme advanced by the client.

Model number DMT80600_03WT manufactured by Beijing Diwen technologies, Inc.;

a main controller: deje corporation, model number: STM32F407VET 6;

the optical coupler isolation is realized by adopting an optical coupler. The structure of the optical coupler is equivalent to packaging the light emitting diode and the phototriode together. The optical coupling isolation circuit ensures that the two isolated circuits are not electrically and directly connected, and mainly prevents interference caused by the electrical connection, particularly between a low-voltage control circuit and an external high-voltage circuit.

It should be understood that the above-described embodiments of the present invention are merely examples for clearly illustrating the present invention, and are not intended to limit the embodiments of the present invention. Other variations and modifications will be apparent to persons skilled in the art in light of the above description. Not all embodiments are exhaustive. All obvious changes and modifications which are obvious to the technical scheme of the invention are covered by the protection scope of the invention.