CN203379209U - Laser treatment device - Google Patents

Abstract

The utility model discloses a laser treatment device which comprises a first power module, a second power module, a constant-temperature control module, a luminous power detection module, a display module, a laser output module, a signal control module, a voltage conversion module, a first temperature detector and a power switching circuit. The first power module is connected with the second power module through the power switching circuit, and the second power module is connected with the first temperature detector, the constant-temperature control module, the signal control module, the laser output module and the voltage conversion module. The signal control module is connected with the display module, the constant-temperature control module, the first temperature detector, the luminous power detection module, the laser output module and the voltage conversion module. The laser output module is connected with the constant-temperature control module and the luminous power detection module. The voltage conversion module is connected with the display module and the luminous power detection module. The laser treatment device has the advantages that the output luminous power range is wide, and the power supply modes are various.

Description

Laser therapeutic equipment

Technical field

This utility model belongs to the treatment technology field, particularly a kind of laser therapeutic equipment.

Background technology

In clinical practice for the requirement of therapeutic equipment multipurpose, miniaturization increasingly.Multipurpose means more the output of wide region luminous power, and miniaturization requires that equipment volume is less, weight is lighter so that mobile and carry; The semiconductor laser treatment apparatus that in currently available technology, output is 15W can not be satisfied with in clinical practice the requirement for therapeutic equipment, and its output reference optical power is narrow, power supply mode is single, the essential external power source that connects in use procedure, under occasion for some without the external power source access, equipment just can't be used.

The utility model content

Technical problem to be solved in the utility model is to provide the variation of a kind of power supply mode and laser therapeutic equipment that still can the continual cure operation under the occasion without the external power source access.

For solving the problems of the technologies described above, this utility model provides a kind of laser therapeutic equipment, comprising: the first power module, second source module, thermostatic control module, optical power detecting module, display module, Laser output module, signal controlling module, voltage transformation module, the first hygrosensor and power supply switch circuit; Described the first power module is connected with described second source module by described power supply switch circuit; Described second source module is connected with described the first hygrosensor, described thermostatic control module, described signal controlling module, described Laser output module and described voltage conversion module respectively; Described signal controlling module is connected with described display module, described thermostatic control module, described the first hygrosensor, described optical power detecting module, described Laser output module and described voltage transformation module respectively; Described Laser output module is connected with described thermostatic control module, described optical power detecting module respectively; Described voltage transformation module is connected with described display module, described optical power detecting module respectively.

Further, described the first power module comprises: the AC-DC Switching Power Supply.

Further, described second source module comprises: at least one battery, charge-discharge control circuit and battery protecting circuit; Described battery is connected with described charge-discharge control circuit, described battery protecting circuit and described the first hygrosensor respectively; Described charge-discharge control circuit is connected with described power supply switch circuit, described voltage transformation module and described thermostatic control module respectively.

Further, described signal controlling module comprises: the first single-chip microcomputer, second singlechip; Described the first single-chip microcomputer is connected with described display module, described the first hygrosensor, described Laser output module and described voltage transformation module respectively; Described second singlechip is connected with described thermostatic control module respectively; Described the first single-chip microcomputer is connected with described second singlechip.

Further, described Laser output module comprises: laser instrument, constant current source driving circuit and Laser Power Devices; Described laser instrument is connected with described Laser Power Devices, described thermostatic control module respectively; Described constant current source driving circuit is connected with described Laser Power Devices, described the first single-chip microcomputer respectively.

Further, described thermostatic control module comprises: constant temperature control circuit, semiconductor cooler, the second hygrosensor and heat-sink unit; Described constant temperature control circuit is connected with second singlechip, described semiconductor cooler and described charge-discharge control circuit respectively; Described the second hygrosensor is connected with described second singlechip, described laser instrument respectively; Described semiconductor cooler is placed in described laser instrument bottom for refrigeration; Described heat-sink unit is connected with described charge-discharge control circuit, and is placed in described semiconductor cooler bottom for heat radiation.

Further, also comprise alarm module; Described alarm module comprises: detecting unit, indicating member; Described detecting unit, described indicating member are connected with described the first single-chip microcomputer respectively.

Further, described detecting unit comprises: power sense circuit, safety interlocking testing circuit, light temperature sensing circuit, photoelectric current testing circuit and battery charging and discharging state detection circuit; Described the first single-chip microcomputer is connected with described power sense circuit, described safety interlocking testing circuit, described smooth temperature sensing circuit, described photoelectric current testing circuit and described battery charging and discharging state detection circuit respectively; Described indicating member comprises: display lamp and/or speaker; Described the first single-chip microcomputer is connected with described display lamp, described speaker respectively; Described voltage transformation module comprises: electric pressure converter; Described display module is touch-screen display.

Further, described optical power detecting module comprises: signal transmitting circuit, PD detector; Described signal transmitting circuit is connected with described the first single-chip microcomputer, described PD detector and described voltage transformation module respectively; Described PD detector is connected with described laser instrument.

Further, described AC-DC Switching Power Supply is selected bright latitude medical treatment power supply MPS-200-12; Described Laser Power Devices are selected the Laser Power Devices of 200W or 600W; Described semiconductor cooler is selected the 9500/128/040B of Dahe Thermomagnetic Electronic Co., Ltd., Hangzhou; Described laser instrument is selected the K98DA4C-15.00W of Beijing Kai Pulin photoelectricity company limited or the 60.00W laser instrument of German DNS company; Described heat-sink unit is radiator and electric fan; Described radiator is placed in described semiconductor cooler bottom; Described electric fan is placed in described radiator air passage end, and is connected with described charge-discharge control circuit.

A kind of laser therapeutic equipment that this utility model provides, in the actual job process, the first power module is connected with the second source module by power supply switch circuit; The second source module is connected with the first hygrosensor, thermostatic control module, signal controlling module, Laser output module and voltage conversion module respectively; The signal controlling module is connected with display module, thermostatic control module, the first hygrosensor, optical power detecting module, Laser output module and voltage transformation module respectively; The Laser output module is connected with thermostatic control module, optical power detecting module respectively; Modular converter is connected with display module, optical power detecting module respectively; Realized when the first power module can be realized the power supply input, this equipment is charged to battery by charge-discharge control circuit, also by the normal operation of first this equipment of electric power source pair of module, powered simultaneously, when the first power module can't be realized the power supply input (as had a power failure), this equipment is realized continuing power supply by battery discharge procedure, and then realizes the operation of therapeutic equipment continual cure; Simultaneously, this utility model has been realized the luminous power of Laser output module output is carried out to the purpose shown in real time by optical power detecting module and display module.

The accompanying drawing explanation

In order to be illustrated more clearly in this utility model embodiment or technical scheme of the prior art, below will the accompanying drawing of required use in embodiment be briefly described, apparently, accompanying drawing in the following describes is only embodiment more of the present utility model, for those of ordinary skills, under the prerequisite of not paying creative work, can also obtain according to these accompanying drawings other accompanying drawing.

The laser therapeutic equipment theory structure block diagram that Fig. 1 provides for this utility model embodiment.

The schematic diagram of safety interlocking testing circuit in the laser therapeutic equipment that Fig. 2 provides for this utility model embodiment.

The structure principle chart of radiator in the laser therapeutic equipment that Fig. 3 provides for this utility model embodiment.

The structural representation of safety interlock union joint in the laser therapeutic equipment that Fig. 4 provides for this utility model embodiment.

The structural representation of safety interlock Connection Block in the laser therapeutic equipment that Fig. 5 provides for this utility model embodiment.

The specific embodiment

Below in conjunction with the accompanying drawing in this utility model embodiment, the technical scheme in this utility model embodiment is clearly and completely described, obviously, described embodiment is only this utility model part embodiment, rather than whole embodiment.Embodiment based in this utility model, the every other embodiment that those of ordinary skills obtain, belong to the scope that this utility model is protected.

Referring to Fig. 1, a kind of laser therapeutic equipment that this utility model embodiment provides comprises: the first power module, second source module, thermostatic control module, optical power detecting module, display module, Laser output module, signal controlling module, voltage transformation module 109, the first hygrosensor 301 and power supply switch circuit 100.Wherein, the first power module is connected with the second source module by power supply switch circuit 100; The second source module is connected with the first hygrosensor 301, thermostatic control module, signal controlling module, Laser output module and voltage conversion module 109 respectively; The signal controlling module is connected with display module, thermostatic control module, the first hygrosensor 301, optical power detecting module, Laser output module and voltage transformation module 109 respectively; The Laser output module is connected with thermostatic control module, optical power detecting module respectively; Voltage transformation module 109 is connected with display module, optical power detecting module respectively.

In the present embodiment, the first power module comprises: AC-DC Switching Power Supply 101; Preferably, AC-DC Switching Power Supply 101 is selected the bright latitude medical treatment in Taiwan power supply MPS-200-12, the output of 12V single channel, and power is 200W, efficiency is 84%, is of a size of 177.8*107.2*35.5mm.

In the present embodiment, the second source module comprises: at least one battery 201, charge-discharge control circuit 202 and battery protecting circuit 203.Wherein, battery 201 is connected with charge-discharge control circuit 202, battery protecting circuit 203 and the first hygrosensor 301 respectively; Charge-discharge control circuit 202 is connected with power supply switch circuit 100, voltage transformation module 901, thermostatic control module and Laser output module respectively.Preferably, battery 201 is selected the 4 strings 3 ferric phosphate lithium cell group also that is nominally 3.2V, 3Ah, and the nominal value after its combination is 12.8V, 9Ah.

In the present embodiment, the signal controlling module comprises: the first single-chip microcomputer 801(core control single chip computer), second singlechip 802(thermostatic control single-chip microcomputer).Wherein, the first single-chip microcomputer 801 is connected with display module, alarm module, Laser output module respectively and voltage transformation module 901 connections; Second singlechip 802 is connected with the thermostatic control module.Simultaneously, the first single-chip microcomputer 801 is connected with second singlechip 802.

In the present embodiment, the Laser output module comprises: laser instrument 601, constant current source driving circuit 602 and Laser Power Devices 603.Wherein, laser instrument 601 is connected with Laser Power Devices 603, thermostatic control module respectively; Constant current source driving circuit 602 is connected with Laser Power Devices 603, the first single-chip microcomputer 801 respectively.

In the present embodiment, the thermostatic control module comprises: constant temperature control circuit 402, semiconductor cooler 403, the second hygrosensor 401 and heat-sink unit.Wherein, constant temperature control circuit 402 is connected with second singlechip 802, semiconductor cooler 403 and charge-discharge control circuit 202 respectively; The second hygrosensor 401 is connected with second singlechip 802, laser instrument 601 respectively; Semiconductor cooler 403 is placed in laser instrument 601 bottoms for refrigeration; Heat-sink unit is connected with charge-discharge control circuit 202, and is placed in semiconductor cooler 403 bottoms for heat radiation.Preferably, heat-sink unit is radiator and electric fan, and radiator is placed in semiconductor cooler 403 bottoms, and electric fan is placed in the radiator air passage end, and is connected with charge-discharge control circuit 202, for thermal current is blowed to outside air.

In the present embodiment, the optical power detecting module comprises: signal transmitting circuit 605, PD detector 604.Wherein, signal transmitting circuit 605 is connected with the first single-chip microcomputer 801, PD detector 604 respectively; PD detector 604 is connected with laser instrument 601.In actual application, after the laser beam that PD detector 604 reception laser instrument 601 send, the signal of telecommunication of its generation send processing through the change of signal transmitting circuit 605, be sent on the first single-chip microcomputer 801, carry out transferring to display module after calculation process through the first single-chip microcomputer 801 again, and then realize that display module shows the luminous power of current lasers 601 outputs.

In the present embodiment, for improving the security performance of therapeutic equipment in the operation engineering, also comprise alarm module; Wherein, alarm module comprises: detecting unit 701, indicating member 702.Simultaneously, detecting unit 701, indicating member 702 are connected with the first single-chip microcomputer 801 by the security alarm interface respectively.Preferably, detecting unit comprises: power sense circuit, battery charging and discharging state detection circuit, safety interlocking testing circuit, light temperature sensing circuit, photoelectric current testing circuit, foot switch connection detection circuit and optical fiber connection detection circuit.Wherein, the first single-chip microcomputer 801 is connected with each circuit in above-mentioned detecting unit respectively, with the signal of telecommunication of each testing circuit output of Real-time Obtaining, and delivers to indicating member and carry out safe indication after software or hardware handles.Indicating member 702 is display lamp and/or speaker and the indication of other software operation information.The first single-chip microcomputer 801 also is connected with above-mentioned display lamp, speaker and the indication of other software operation information respectively.

In the present embodiment, referring to Fig. 2, the safety interlocking testing circuit comprises: safety interlock S1, current-limiting resistance S3 and optical coupling sheet S2.Wherein, safety interlock S1 is connected with the first single-chip microcomputer 801 by optical coupling sheet S2 and realizes that security of system detects.Optical coupling sheet S2 is electrically connected to (safety interlock S1, optical coupling sheet S2 also are connected with ground wire respectively) by current-limiting resistance S3 with extraneous power supply.

The present embodiment is in practical work process, second singlechip 802 gathers the magnitude of voltage on the second hygrosensor 401 by built-in ADC, and then laser instrument 601 real time temperature numerical value, and obtained Temperature numerical is transferred to the first single-chip microcomputer 801, the first single-chip microcomputer 801 is by software program design temperature threshold value, when obtained Temperature numerical surpasses the design temperature threshold value, the first single-chip microcomputer 801 transfers to alarm module by alarm signal and realizes reporting to the police.Simultaneously, second singlechip 802 also by obtained Temperature numerical respectively correspondence transfer to constant temperature control circuit 402, and then controlled by 402 pairs of semiconductor coolers of constant temperature control circuit, 403 output refrigeration work consumptions, finally laser instrument 601 operating temperatures are controlled, realized that laser instrument 601 Output optical power are stable.Simultaneously, the heat produced in laser instrument 601 work process passes through radiators by semiconductor cooler 403, and finally by the electric fan that is placed in the radiator air passage end, heat is blowed to external environment.And the present embodiment is connected Real-time Collection battery 201 operating temperature numerical signals by the first hygrosensor 301 with the first single-chip microcomputer 801, and this signal is transferred to the first single-chip microcomputer 801, the first single-chip microcomputer 801 is by the design temperature threshold value, when the Temperature numerical of gathered battery 201 surpasses the temperature threshold of setting, the first single-chip microcomputer 801 stops charging by voltage transformation module 901 control instructions and then control charge-discharge control circuit 202, realizes battery 201 safety, stablizes operation.

In the present embodiment, display module is the touch-screen display 501 consisted of LCDs and touch screen (resistance-type); And be connected with the first single-chip microcomputer 801 by the touch screen display interface, realize the accurate control of operator to therapeutic equipment.

In the present embodiment, voltage transformation module 901 comprises: electric pressure converter.Wherein, electric pressure converter is connected with charge-discharge control circuit 202 conversion that realizes magnitude of voltage.

The therapeutic equipment that the present embodiment provides, in practical work process, AC-DC Switching Power Supply 101 is connected with charge-discharge control circuit 202 by power supply switch circuit 100, being connected in external power source (being AC power supplies) situation, can realize the charging of 101 pairs of batteries 201 of AC-DC Switching Power Supply and the power supply of whole therapeutic equipment; There is no, in external power source (being AC power supplies) situation, can to realize by the discharge process of battery 201 power supply of whole therapeutic equipment; Simultaneously, charge-discharge control circuit 202, by being connected with DC-DC translation interface in electric pressure converter, becomes system required voltage value (3.3V, 5V, 12V) by voltage transitions; Charge-discharge control circuit 202, by being connected with constant temperature control circuit 402, provides the 12V power supply; Charge-discharge control circuit 202, by being connected with electric fan, provides the 12V power supply.And the first single-chip microcomputer 801 is connected with constant current source driving circuit 602, display module and alarm module respectively, and by built-in DA output, on the one hand for photoelectric current numerical value is set, and then laser optical power numerical value is set, control on the other hand touch-screen display 501 signals and receive and respond demonstration, and by each testing circuit, equipment connection is carried out to safety detection, finally realize the safe bright dipping of laser instrument 601.

Simultaneously, in the embodiment that this utility model provides, for reaching the portable purposes such as the therapeutic equipment volume is little, lightweight, can select following device as this utility model installation component:

1, AC-DC Switching Power Supply 101 is selected the bright latitude medical treatment in Taiwan power supply MPS-200-12, the output of 12V single channel, and power is 200W, efficiency is 84%, is of a size of 177.8*107.2*35.5mm.

2, Laser Power Devices 603 select Ericsson PMC8818TS(Sweden to manufacture) or 600W Switching Power Supply (programmable current output 0-60A), its input voltage range of the PMC8818TS of Ericsson is 8.3-16Vdc, programmable Voltage-output, 0.75-5.5Vdc, 16A, conversion efficiency, up to 96%, is of a size of 33*10.92*8.52mm.Simultaneously, because of its Ultra-High Efficiency, it is upper that Laser Power Devices 603 can directly be mounted on PCB, adopts the air flow automatic heat radiation.

3, semiconductor cooler 403 is selected Dahe Thermomagnetic Electronic Co., Ltd., Hangzhou's product, and its serial number is 9500/128/040B.

4, laser instrument 601 is selected Beijing Kai Pulin photoelectricity company limited product, and its product ID is K98DA4C-15.00W; Perhaps select the 60.00W laser instrument of German DNS company.

5, radiator is square aluminum air-cooled radiator (referring to Fig. 3), and its parameter is of a size of 92*110*67.

6, safety interlock is selected detection and the test instrunment special connector-lemo metal connector that model is TGG.1B.304.CLAD52Z; Wherein, referring to Fig. 4-5, the union joint of detection and test instrunment special connector-lemo metal connector partly passes through 1,2,3,4 pin-strappings, and be fixedly connected with the formation safety interlock with the Connection Block mechanical type.

7, the managing chip of charge-discharge control circuit is selected the linear(Linear) LTC4008 of company, its input voltage is 6-28V, and output voltage is 3-28V, and minimum pressure drop is 0.5V, and voltage accuracy is ± 0.8%, the charging current maximum can reach 4A.

The embodiment that this utility model provides is by above-mentioned efficient device, making the laser therapeutic equipment volume after assembling is only 215 (W) * 245 (L) * 315 (H) mm, complete machine weight is only 4KG, its laser instrument 601 output power ranges can reach 1W-60W, the power stage of enough drive laser 60W, above device architecture and performance have realized the characteristics of therapeutic equipment miniaturization, portable and Output optical power wide ranges.

It should be noted last that, the above specific embodiment is only unrestricted in order to the technical solution of the utility model to be described, although with reference to example, this utility model is had been described in detail, those of ordinary skill in the art is to be understood that, can modify or be equal to replacement the technical solution of the utility model, and not breaking away from the spirit and scope of technical solutions of the utility model, it all should be encompassed in the middle of claim scope of the present utility model.

Claims (10)

1. a laser therapeutic equipment, it is characterized in that, comprising: the first power module, second source module, thermostatic control module, optical power detecting module, display module, Laser output module, signal controlling module, voltage transformation module, the first hygrosensor and power supply switch circuit;

Described the first power module is connected with described second source module by described power supply switch circuit;

Described second source module is connected with described the first hygrosensor, described thermostatic control module, described signal controlling module, described Laser output module and described voltage conversion module respectively;

Described signal controlling module is connected with described display module, described thermostatic control module, described the first hygrosensor, described optical power detecting module, described Laser output module and described voltage transformation module respectively;

Described Laser output module is connected with described thermostatic control module, described optical power detecting module respectively;

Described voltage transformation module is connected with described display module, described optical power detecting module respectively.

2. equipment according to claim 1, is characterized in that, described the first power module comprises: the AC-DC Switching Power Supply.

3. equipment according to claim 1, is characterized in that, described second source module comprises: at least one battery, charge-discharge control circuit and battery protecting circuit;

Described battery is connected with described charge-discharge control circuit, described battery protecting circuit and described the first hygrosensor respectively;

Described charge-discharge control circuit is connected with described power supply switch circuit, described voltage transformation module and described thermostatic control module respectively.

4. equipment according to claim 2, is characterized in that, described signal controlling module comprises: the first single-chip microcomputer, second singlechip;

Described the first single-chip microcomputer is connected with described display module, described the first hygrosensor, described Laser output module and described voltage transformation module respectively;

Described second singlechip is connected with described thermostatic control module;

Described the first single-chip microcomputer is connected with described second singlechip.

5. equipment according to claim 4, is characterized in that, described Laser output module comprises: laser instrument, constant current source driving circuit and Laser Power Devices;

Described laser instrument is connected with described Laser Power Devices, described thermostatic control module respectively;

Described constant current source driving circuit is connected with described Laser Power Devices, described the first single-chip microcomputer respectively.

6. equipment according to claim 5, is characterized in that, described thermostatic control module comprises: constant temperature control circuit, semiconductor cooler, the second hygrosensor and heat-sink unit;

Described constant temperature control circuit is connected with second singlechip, described semiconductor cooler and described charge-discharge control circuit respectively;

Described the second hygrosensor is connected with described second singlechip, described laser instrument respectively;

Described semiconductor cooler is placed in described laser instrument bottom for refrigeration;

Described heat-sink unit is connected with described charge-discharge control circuit, and is placed in described semiconductor cooler bottom for heat radiation.

7. equipment according to claim 6, is characterized in that, also comprises alarm module;

Described alarm module comprises: detecting unit, indicating member;

Described detecting unit, described indicating member are connected with described the first single-chip microcomputer respectively.

8. equipment according to claim 7, is characterized in that, described detecting unit comprises: power sense circuit, safety interlocking testing circuit, light temperature sensing circuit, photoelectric current testing circuit and battery charging and discharging state detection circuit;

Described the first single-chip microcomputer is connected with described power sense circuit, described safety interlocking testing circuit, described smooth temperature sensing circuit, described photoelectric current testing circuit and described battery charging and discharging state detection circuit respectively;

Described indicating member comprises: display lamp and/or speaker;

Described the first single-chip microcomputer is connected with described display lamp, described speaker respectively;

Described voltage transformation module comprises: electric pressure converter;

Described display module is touch-screen display.

9. according to the described equipment of claim 5-8 any one, it is characterized in that, described optical power detecting module comprises:

Signal transmitting circuit, PD detector;

Described signal transmitting circuit is connected with described the first single-chip microcomputer, described PD detector and described voltage transformation module respectively;

Described PD detector is connected with described laser instrument.

10. equipment according to claim 9 is characterized in that:

Described AC-DC Switching Power Supply is selected bright latitude medical treatment power supply MPS-200-12;

Described Laser Power Devices are selected the Laser Power Devices of 200W or 600W;

Described semiconductor cooler is selected the 9500/128/040B of Dahe Thermomagnetic Electronic Co., Ltd., Hangzhou;

Described laser instrument is selected the K98DA4C-15.00W of Beijing Kai Pulin photoelectricity company limited or the 60.00W laser instrument of German DNS company;

Described heat-sink unit is radiator and electric fan;

Described radiator is placed in described semiconductor cooler bottom;

Described electric fan is placed in described radiator air passage end, and is connected with described charge-discharge control circuit.

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