CN117653915A

CN117653915A - Infrared polarized light therapeutic instrument

Info

Publication number: CN117653915A
Application number: CN202311663807.9A
Authority: CN
Inventors: 何永正; 王帅辉; 周冬亮; 李昊威
Original assignee: Xiangyu Medical Co ltd
Current assignee: Xiangyu Medical Co ltd
Priority date: 2023-12-06
Filing date: 2023-12-06
Publication date: 2024-03-08

Abstract

The invention relates to the technical field of infrared polarized light physiotherapy, and discloses an infrared polarized light therapeutic apparatus, which comprises a host machine and an optical fiber transmission device which is connected with the host machine in a pluggable manner; wherein, the host is internally provided with a host controller and a light source component for outputting physiotherapy light signals; the optical fiber transmission device comprises an optical fiber for transmitting physiotherapy optical signals; the treatment head is connected with the optical fiber and used for outputting physiotherapy optical signals; and a handle controller in communication with the host controller; the handle controller is used for outputting optical power information determined according to the type of the optical fiber transmission device to the host controller; wherein the types at least comprise single-beam optical fibers and double-beam optical fibers; the host controller is used for controlling the light source component to output physiotherapy light signals with corresponding power according to the light power information. The infrared polarized light therapeutic instrument in the application ensures physiotherapy effect on the basis of changing different types of optical fiber transmission devices at any time.

Description

Infrared polarized light therapeutic instrument

Technical Field

The invention relates to the technical field of infrared polarized light physiotherapy, in particular to an infrared polarized light therapeutic instrument.

Background

The infrared polarized light therapeutic equipment is a physiotherapy equipment, and adopts photoelectric technology to make the special light energy whose spectrum range is 600 nm-1600 nm be acted on the correspondent pain position and acupoint of human body so as to regulate the stability of human body internal environment and physiological balance so as to attain the goal of curing and preventing diseases.

Along with development and application of infrared polarized light therapeutic instrument, in the therapeutic physiotherapy process to the patient, also produce more diversified demands to infrared polarized light therapeutic instrument gradually, correspondingly, the physiotherapy function that infrared polarized light therapeutic instrument can realize also has great promotion space to satisfy patient's physiotherapy demand.

Disclosure of Invention

The invention aims to provide an infrared polarized light therapeutic apparatus, which can ensure that the power of a physiotherapy light signal output by an optical fiber transmission device can meet physiotherapy requirements and ensure physiotherapy effects on the basis that different types of optical fiber transmission devices can be replaced at any time.

In order to solve the technical problems, the invention provides an infrared polarized light therapeutic apparatus, which comprises a host machine and an optical fiber transmission device which is connected with the host machine in a pluggable manner;

wherein, the host is internally provided with a host controller and a light source component for outputting physiotherapy light signals;

the optical fiber transmission device comprises an optical fiber for transmitting the physiotherapy optical signal; the treatment head is connected with the optical fiber and used for outputting the physiotherapy light signal; and a handle controller in communication with the host controller;

the handle controller is used for outputting optical power information determined according to the type of the optical fiber transmission device to the host controller; wherein the types include at least single-beam optical fibers and dual-beam optical fibers;

the host controller is used for controlling the light source assembly to output the physiotherapy light signal with the corresponding power according to the light power information.

In an alternative embodiment of the present application, the optical fiber transmission device includes a transmission part integrated with the optical fiber and the cable, and a handle part having the handle controller built therein; the cable is used for communication connection between the handle controller and the host controller;

a first pluggable structure is arranged at one end, away from the handle part, of the transmission part, and a second pluggable structure is arranged on the host; the first plug structure and the second plug structure can be connected in a plug-in manner;

when the first plug structure of the transmission part and the second plug structure of the host are connected in a plug manner, one end of the optical fiber is connected with the output end of the light source assembly, and one end of the cable is connected with the host controller in a communication manner.

In an optional embodiment of the present application, a micro switch is disposed in the second plug structure;

when the first plug structure and the second plug structure are connected in a plug-in mode, the micro switch is closed;

when the first plug structure and the second plug structure are disconnected with each other, the micro switch is disconnected.

In an optional embodiment of the present application, when the host controller receives a physiotherapy starting instruction, the host controller detects and obtains the switch state of the micro switch;

if the switch state is the closed state, the host controller establishes communication connection by sending a handshake signal to the controller.

In an alternative embodiment of the present application, after the host controller and the handle controller successfully establish a communication connection, the method further includes:

the host controller sends a heartbeat instruction to the controller according to a set period so as to determine whether the host controller and the controller are in normal communication or not;

and if the continuous set times determine that the communication between the host controller and the controller is disconnected, sending out a communication abnormality alarm prompt.

In an alternative embodiment of the present application, a physical button connected to the handle controller is further provided on the handle portion, for inputting a start physiotherapy command and an emergency stop command, so as to start a start physiotherapy process and control an emergency stop interruption of the physiotherapy process.

In an alternative embodiment of the present application, when the duration of the physical key being pressed reaches a preset duration, the handle controller starts responding to a start physiotherapy command or an emergency stop command.

In an optional embodiment of the present application, the host controller is further configured to record, in real time, an accumulated light emitting duration of the light source assembly;

when the accumulated light emitting time length of the light source assembly reaches a time length threshold value, detecting the brightness of the light signal output by the light source assembly by utilizing a built-in light intensity sensor of the host;

and if the brightness of the light signal output by the light source assembly is lower than a brightness threshold value, sending out a warning prompt for replacing the light source.

In an optional embodiment of the present application, the host controller is specifically configured to write, into a flash, an updated cumulative lighting duration of the light source assembly every interval set duration, and when a current page of the flash is full, backup the latest cumulative lighting duration, erase the flash in a full page, and rewrite the latest cumulative lighting duration into the erased flash.

In an alternative embodiment of the present application, at least two of the light source modules are disposed in the host.

The invention provides an infrared polarized light therapeutic apparatus, which comprises a host machine and an optical fiber transmission device which is connected with the host machine in a pluggable manner; wherein, the host is internally provided with a host controller and a light source component for outputting physiotherapy light signals; the optical fiber transmission device comprises an optical fiber for transmitting physiotherapy optical signals; the treatment head is connected with the optical fiber and used for outputting physiotherapy optical signals; and a handle controller in communication with the host controller; the handle controller is used for outputting optical power information determined according to the type of the optical fiber transmission device to the host controller; wherein the types at least comprise single-beam optical fibers and double-beam optical fibers; the host controller is used for controlling the light source component to output physiotherapy light signals with corresponding power according to the light power information.

The host and the optical fiber transmission device in the infrared polarized light therapeutic instrument are connected in a pluggable mode, so that the optical fiber transmission device on the host can replace optical fiber transmission devices of single-beam optical fibers, double-beam optical fibers or other types of optical fibers based on actual physiotherapy requirements, and further the more diversified physiotherapy requirements of patients are met; on this basis, further consider to the optical fiber transmission device of different grade type, the power size demand to the physiotherapy light signal of light source module output in the host computer also is different, for this reason, further built-in handle controller in optical fiber transmission device in this application, through the communication connection between the host computer controller in this handle controller and the host computer for the host computer controller can control the light source module and provide the physiotherapy light signal of suitable power for different grade type optical fiber transmission device, and then guarantees on the basis that can change different grade type optical fiber transmission device at any time, can also guarantee that the power size of physiotherapy light signal of optical fiber transmission device output can satisfy physiotherapy demand, guarantees physiotherapy effect.

Drawings

For a clearer description of embodiments of the invention or of the prior art, the drawings that are used in the description of the embodiments or of the prior art will be briefly described, it being apparent that the drawings in the description below are only some embodiments of the invention, and that other drawings can be obtained from them without inventive effort for a person skilled in the art.

Fig. 1 is a schematic structural diagram of an infrared polarized light therapeutic apparatus according to an embodiment of the present application;

fig. 2 is a schematic structural diagram of a host in an infrared polarized light therapeutic apparatus according to an embodiment of the present application;

fig. 3 is a schematic flow chart of establishing communication connection between a host controller and a handle controller according to an embodiment of the present application.

Detailed Description

The infrared polarized light therapeutic apparatus is mainly composed of a host machine and an optical fiber transmission device; the optical fiber transmission device mainly comprises a light source component for transmitting and outputting the physiotherapy light signals output by the light source component and acting on the affected part of a patient.

The main machine in the traditional infrared polarized light therapeutic apparatus is fixedly connected with the end part of the optical fiber transmission device; in case of failure of the optical fiber transmission device, the whole infrared polarized light therapeutic instrument is not available.

For this reason, provide an infrared polarized light therapeutic instrument in this application, but wherein, but plug connection between optic fibre transmission device and the host computer for optic fibre transmission device can be changed at any time according to actual need, for infrared polarized light therapeutic instrument's use is convenient, more can satisfy the function that multiple different optic fibre transmission device used instead, and guarantees different optic fibre transmission device's physiotherapy effect, thereby promotes infrared polarized light therapeutic instrument's performance to a certain extent.

In order to better understand the aspects of the present invention, the present invention will be described in further detail with reference to the accompanying drawings and detailed description. It will be apparent that the described embodiments are only some, but not all, embodiments of the invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

As shown in fig. 1 to 3, fig. 1 is a schematic structural diagram of an infrared polarized light therapeutic apparatus according to an embodiment of the present application; fig. 2 is a schematic structural diagram of a host in an infrared polarized light therapeutic apparatus according to an embodiment of the present application; fig. 3 is a schematic flow chart of establishing communication connection between a host controller and a handle controller according to an embodiment of the present application.

In one specific embodiment of the present application, an infrared polarized light therapeutic apparatus may include:

a host 10 and an optical fiber transmission device connected with the host 10 in a pluggable manner;

wherein, the host 10 is internally provided with a host 10 controller and a light source component for outputting physiotherapy light signals;

the optical fiber transmission device comprises an optical fiber for transmitting physiotherapy optical signals; a treatment head 24 connected with the optical fiber for outputting physiotherapy light signals; and a handle controller in communication with the host 10 controller;

the handle controller is used for outputting optical power information determined according to the type of the optical fiber transmission device to the host controller; the type of the optical fiber transmission device at least comprises a single-beam optical fiber and a double-beam optical fiber;

the host controller is used for controlling the light source component to output physiotherapy light signals with corresponding power according to the light power information.

In the infrared polarized light therapeutic apparatus of this embodiment, the optical fiber transmission device is connected to the host 10 in a pluggable manner; therefore, in the actual use process, if the optical fiber transmission device has faults, the new optical fiber transmission device can be replaced at any time without disassembling the host 10, thereby providing convenience for the physiotherapy process of the infrared polarized light therapeutic instrument. In practical applications, each infrared polarized light therapeutic apparatus may be configured with a plurality of optical fiber transmission devices for standby use.

Furthermore, it is further contemplated that the need for infrared polarized light therapy apparatus is not the same based on different patient conditions. For example, for patients with more pain sites, a single optical fiber transmission device needs to sequentially perform physiotherapy treatment on each pain site of the patient, so that the working efficiency of physiotherapy treatment is relatively low; and in some cases, the synchronous physiotherapy effect of acupuncture points on a plurality of different parts is better, but for the infrared polarized light therapeutic instrument which can only output a single Shu Liliao light signal, the treatment requirement is difficult to meet, and a plurality of infrared polarized light therapeutic instruments are often required to work cooperatively, so that great inconvenience is obviously caused to the physiotherapy treatment process.

For this reason, for the infrared polarized light therapeutic apparatus provided in the present application, a plurality of different types of optical fiber transmission devices may be further configured on the basis of configuring a plurality of optical fiber transmission devices for each host computer 10.

The different types of optical fiber transmission devices in this embodiment may include single-beam optical fibers, double-beam optical fibers, and multiple-beam optical fibers; the single-beam optical fiber is an optical fiber structure with only one input end and one output end, wherein the optical fiber is used for transmitting physiotherapy optical signals in an optical fiber transmission device; the optical fiber in the optical fiber transmission device is of a Y-shaped optical fiber structure with one input end and two output ends, when the physiotherapy optical signals are input from the input ends of the optical fiber, two physiotherapy optical signals can be formed in the optical fiber in a split mode and respectively output from two treatment heads 24 connected with the two output ends; similarly, the multi-beam optical fiber refers to an optical fiber structure with only one input end and a plurality of output ends, and after the physiotherapy optical signals are input into the optical fiber, a plurality of physiotherapy optical signals can be formed in a certain way, and the physiotherapy optical signals are output from the treatment heads 24 respectively connected with the output ends. Therefore, for different types of optical fiber transmission devices, single-path or multi-path physiotherapy optical signals can be synchronously output, and the corresponding types of optical fiber transmission devices can be connected with the host 10 based on actual needs.

It can be understood that, for the optical fiber transmission device of the dual-beam optical fiber or the multi-beam optical fiber, the physiotherapy light signals output by the light source assembly are incident into the optical fiber transmission device, and the powers of the physiotherapy light signals output by each treatment head 24 are necessarily reduced by multiple relative to the power of the single Shu Liliao light signal output by only one treatment head 24 in the process of branching to form the multi-beam physiotherapy light signals, which may cause the power of the physiotherapy light signals output by each output end of the optical fiber to be insufficient and thus the physiotherapy effect cannot be ensured.

For this reason, in order to ensure the physiotherapy effect when the plurality of physiotherapy optical signals are simultaneously output by the plurality of treatment heads 24, a handle controller is further built in the optical fiber transmission device, and the handle controller can be in communication connection with a host 10 controller in the host 10; therefore, after the optical fiber transmission device is connected with the host 10, the handle controller can send the optical power information corresponding to the optical fiber transmission device where the handle controller is located to the host 10 controller, and the optical power information is that the total power value of the physiotherapy optical signal which can ensure the physiotherapy effect and is output by the treatment head 24 of the optical fiber transmission device to the light rays output by the light source assembly. After the controller of the host 10 obtains the total power value, the controller can automatically regulate and control the output power value of the corresponding light source component under each intensity level of each treatment head 24, and thereby control the light source component to output a physiotherapy light signal of the corresponding power value according to the intensity level; thus, each treatment head 24 in the optical fiber transmission device can be ensured to output physiotherapy light signals meeting physiotherapy requirements.

In addition, it should be noted that, in the present application, the plurality of treatment heads 24 provided with the infrared polarized light treatment apparatus include, but are not limited to, a single-beam double-beam optical fiber and a single-beam multiple-beam type, and even if the two-beam optical fibers are the same, the optical fiber transmission device for realizing different physiotherapy effects or different physiotherapy modes can also correspond to different output power values. Therefore, according to different types of optical fiber transmission devices, the total power value output by the light source assembly to be set is also different; in practical application, the total power value of the physiotherapy light signal output by the appropriate light source assembly is regulated and controlled according to the type of the optical fiber transmission device, so that the performance parameters required by the treatment output of the treatment head 24 of each optical fiber transmission device can be met at the same time, and the energy consumption can be saved.

It can be understood that, in the present application, it is also considered that the total power value corresponding to each type of the optical fiber transmission device is prestored in the controller of the host 10; in the actual physiotherapy process, the type of the optical fiber transmission device can be manually input by an operator, and the host 10 controller can directly search the corresponding total power value according to the input type of the optical fiber transmission device and control the output power of the light source assembly accordingly, so that a handle controller is not required to be built in the optical fiber transmission device, and the physiotherapy effect of each treatment head 24 of different types of optical fiber transmission devices is ensured. This requires operators themselves to be familiar with the type of optical fibre transmission device and must require that the total power for each type of optical fibre transmission device be entered in advance, which once not entered, also causes problems with the unavailability of the optical fibre transmission device. Thus, incorporating a handle controller in a fiber optic transmission device is a preferred embodiment in this application.

In addition, in the infrared polarized light therapeutic apparatus of the present application, the number of output physiotherapy optical signals is not limited to increase the number of branches of the output end of the optical fiber in the optical fiber transmission device, in another alternative embodiment of the present application, two or more light source assemblies may be further disposed in the host 10, and each light source assembly may be connected with one optical fiber transmission device, so as to further increase the number of physiotherapy optical signals that the optical fiber transmission device may output at the same time.

Based on the above discussion, the communication connection between the host 10 controller and the handle controller may be a wireless communication connection or a wired communication connection, and the wired communication connection is more stable than the wireless communication connection, and the confirmation of the ID address of the optical fiber transmission device is not required. To this end, in an alternative embodiment of the present application, an optical fiber transmission device may include:

a transmission section 22 integrated with an optical fiber and a cable, and a handle section 23 incorporating a handle controller; the cable is used for communication connection between the handle controller and the host 10 controller;

the transmission part 22 is provided with a first plug structure 21 at one end away from the handle part 23, and a second plug structure is arranged on the host 10; the first plug structure 21 and the second plug structure 11 can be connected in a plug-in manner;

when the first plug structure 21 of the transmission part 22 is connected with the second plug structure 11 of the host 10 in a plug-in manner, one end of the optical fiber is connected with the output end of the light source assembly, and one end of the cable is connected with the controller of the host 10 in a communication manner.

When the handle controller is correctly connected with the host 10 through the cable, the MCU of the handle controller can be automatically initialized, parameter transmission between the handle controller and the host 10 controller is started, information data such as the type and the power of the optical fiber transmission device which is currently inserted into the host 10 are output to the host 10 controller, and the host 10 controller can directly change the current output power value of the light source component after receiving the corresponding parameters.

As shown in fig. 1, in the transmission part 22 of the optical fiber transmission device, the optical fiber and the cable may be arranged in parallel, a first plug structure 21 is arranged at a first end of the transmission part 22, and a handle part 23 is arranged at a second end of the transmission part 22, and the handle part 23 is connected with the treatment head 24; after the optical fiber and the cable of the transmission part 22 extend from the first end to the second end of the transmission part 22, the cable is connected with a handle controller built in the handle part 23 at the handle part 23, and the optical fiber is connected with the treatment head 24 through the handle part 23; in addition, the second plug structure 11 on the host 10 can be connected with the first plug structure 21 at the end of the transmission part 22 in a plug manner, while the end of the optical fiber and the end of the cable respectively extend into the first plug structure 21, and correspondingly, the second plug structure 11 is also respectively provided with an optical fiber port 12 connected with the output end of the light source assembly and a cable port 13 connected with the controller of the host 10; thus, when the first plug structure 21 and the second plug structure 11 are connected in a plug manner, the end portion of the optical fiber can be inserted into the optical fiber port 12 on the host 10, so that the end portion of the optical fiber is connected with the output end of the light source assembly, and the end portion of the cable can be inserted into the cable port 13 on the host 10, that is, the cable is connected with the host 10 controller.

On the basis, in order to more accurately determine the connection state of the mutual plug connection between the first plug structure 21 and the second plug structure 11, in another alternative embodiment of the present application, a micro switch may be further disposed in the second plug structure 11;

when the first plug structure 21 and the second plug structure 11 are connected in a plug-in manner, the micro switch is closed;

when the first plug structure 21 and the second plug structure 11 are disconnected from each other, the micro switch is turned off.

It can be understood that the micro switch can be connected with the host 10 controller, so that the host 10 controller can determine whether the optical fiber transmission device is inserted into the second plug structure 11 through the micro switch, and if so, the host 10 controller can be further connected with the handle controller in the optical fiber transmission device in a communication manner.

After the end part of the optical fiber transmission device is inserted into the host, if the first plug structure is correctly inserted into the second plug structure 11, the micro switch is triggered to be closed; the host controller receives the closing signal and changes the switch state zone bit Inflag of the corresponding micro switch in the host controller into True; if the first plug structure is not inserted or not correctly inserted into the second plug structure 11, the micro switch cannot be triggered to be closed, the host controller considers that the optical fiber transmission device is not inserted, and the switch state flag bit InFlag in the host controller is changed into False.

Thus, based on the discussion above, in one particular embodiment of the present application, the communication flow between the host controller and the handle controller may include:

s11: the host controller receives a physiotherapy starting instruction;

s12: the host controller judges whether the switch state of the micro switch is a closed state, if so, the S13 is entered; if not, entering S14;

s13: the host controller establishes communication connection by sending a handshake signal to the controller;

s14: the output fiber optic transmission device is not plugged in a signal.

A human-computer interaction interface can be arranged on a host in the infrared polarized light therapeutic apparatus, and a user can input a physiotherapy starting instruction to a host controller through the human-computer interaction interface; the host controller can detect and judge the current switch state of the micro switch according to the physiotherapy starting instruction. When the switch state flag bit InFlag is False, if an instruction for starting the light source output is received, the light source output cannot be started normally at the moment, and a voice prompt 'the optical fiber transmission device is not connected correctly and the treatment cannot be started' can be triggered. When the switch state flag bit InFlag is True, normal communication connection can be established between the host controller and the handle controller.

485 protocol communication may be used for the host controller and the handle controller to establish a communication connection. As shown in fig. 3, in the process of establishing communication connection, the host controller firstly sends a handshake instruction to the handle controller and starts timing at the same time, if the handle controller can be in normal communication connection with the host controller, a piece of confirmation instruction information is returned to the host controller within T1 seconds, wherein the confirmation instruction information can include parameter information such as the type of the optical fiber transmission device, total power of physiotherapy light signals output by a required light source assembly, start-stop control and the like; if the handle controller does not reply the confirmation instruction information within T1 seconds, the establishment of communication between the handle controller and the host controller is unsuccessful; after T1 seconds, the host controller sends a handshake instruction to the handle controller again until the handshake instruction is sent for three times, namely, the confirmation instruction information replied by the handle controller is not received, namely, the communication is not successfully established for three times, the information of abnormal communication of the handle controller can be sent out directly through a man-machine interaction interface on the host computer at the moment, a user is prompted to detect the connection condition of the handle controller, after the medical staff is checked, the communication connection instruction can be re-established through the man-machine interaction interface input on the host computer, and the host controller can send the handshake instruction to the handle controller again according to the mode. In the process of establishing communication connection, the host can output a prompt signal to remind medical staff of the operation of the hand controller in parameter transmission-! And treatment cannot be initiated until parameter transmission is completed.

Further, in order to ensure the effectiveness of the physiotherapy treatment by outputting the physiotherapy light signal by the infrared polarized light therapeutic apparatus, after the host controller and the handle controller are successfully connected by communication, the method further comprises:

if the continuous set times determine that the communication between the host controller and the controller is disconnected, a communication abnormality alarm prompt is sent.

In this embodiment, after the handshake instruction between the host controller and the handle controller is successfully communicated, the host controller starts timing, and sends a heartbeat instruction (the number accumulated value is accumulated sequentially for the first time by 1) to the handle controller every T2 seconds, and after the handle controller receives the heartbeat instruction, the handle controller returns to the host controller after adding 1 to the received value. If three continuous communication is abnormal, the handle controller is considered to be disconnected, the handle controller is prompted to be connected abnormally, the handle start-stop key is temporarily unavailable, and the following is checked! But does not affect the normal use of the present time.

And after the equipment is electrified for the first time or the optical fiber transmission device is detected to be pulled out and the heartbeat communication is abnormal, and the optical fiber transmission device is detected to be connected again, the host controller can send a handshake instruction to the handle controller again, so that the parameter setting is kept consistent after the optical fiber transmission device is replaced.

Based on the above discussion, further considering that in the normal output of the physiotherapy light signal by the light source assembly, during the physiotherapy treatment process of the treatment head, sudden unexpected situations may occur, and the control of the interruption of the physiotherapy treatment process is required, in order to ensure that the interruption of the physiotherapy treatment process can be rapidly and conveniently implemented, in another optional embodiment of the present application, a physical key connected to the handle portion may be further provided on the handle portion, for inputting a start physiotherapy signal and an interruption signal, so as to start the start physiotherapy process and control the interruption of the physiotherapy process.

In practical application, the handle controller is connected with a physical button, and after the treatment angle is adjusted, medical staff can directly press the physical button to control the starting or stopping of physiotherapy on the basis that the host is electrified and the host controller and the handle controller are confirmed to establish normal communication connection, and does not need to move to control icons corresponding to human-computer interaction interfaces such as a display screen of the host.

Further, in order to further avoid misoperation caused by physical key multiple false touches of the handle portion, in another optional embodiment of the present application, the method further includes:

when the pressed time of the physical key reaches the preset time, the handle controller starts responding to the physiotherapy starting instruction or the scram instruction.

Specifically, after the host controller and the handle controller are successfully connected in a communication manner, if the duration of the physical key pressed reaches the preset duration, that is, the operator inputs a physiotherapy starting instruction, the handle controller responds to the physiotherapy starting instruction and sends a physiotherapy starting signal to the host controller, and after the host controller receives the physiotherapy starting signal, the light source assembly is controlled to output a physiotherapy light signal;

when the light source component normally outputs the physiotherapy light signal, if the pressed time of the physical key reaches the preset time, the operator inputs a scram instruction, the handle controller responds to the scram instruction and sends scram information to the host controller, and the host controller controls the light source component to immediately stop outputting the physiotherapy light signal.

In this embodiment, when the physical key connected to the handle controller is operated, the handle controller needs to be continuously pressed for longer than a preset period of time, for example, 3 seconds, so that the handle controller responds to the processing, and thus, misoperation caused by false touch can be prevented.

In addition, the physical key on the handle controller and the control button displayed on the interface on the display screen of the host can be in linkage operation, if the current equipment is in a standby and non-starting state, the interface of the display screen displays the interface before treatment, at the moment, the physical key is pressed down, treatment can be started, and meanwhile, the interface of the display screen can jump to the display interface in treatment. If the current equipment is in a treatment state, the interface displays the interface in treatment, at the moment, the physical key is pressed, the treatment output can be stopped, and meanwhile, the interface can jump to the display interface before treatment.

Based on any embodiment, further considering that the light source component inevitably has loss along with the extension of the service time, the output power of the light source component is reduced, and the effect of physiotherapy treatment is difficult to ensure. To this end, in another alternative embodiment of the present application, it may further include:

the host controller is also used for recording the accumulated lighting time length of the light source component in real time;

when the accumulated luminous duration of the light source component reaches a duration threshold, detecting the brightness of the light signal output by the light source component by utilizing a light intensity sensor arranged in the host;

and if the brightness of the light signal output by the light source assembly is lower than the brightness threshold value, sending out a warning prompt for replacing the light source.

It should be noted that the light source belongs to a consumable, and the output light power is reduced with a high probability after the operation time is longer than 500 hours. In this embodiment, the host controller determines whether the light source assembly can be used continuously by recording the total operation duration of the light source assembly and the light signal intensity detection output by the light source assembly. When the accumulated time length of the light source component reaches a time length threshold, for example, after 500 hours, a human-computer interaction interface on the host computer can pop up a prompt box for replacing the corresponding channel light source to be replaced, at the moment, a medical staff can select to replace the light source component or ignore the light source component, and at the moment, no forced requirement is required. If the light source component is selected to be replaced, the man-machine interaction interface of the host machine automatically enters the light source replacement interface, and at the moment, the light source replacement operation can be performed according to a prompting flow displayed by the man-machine interaction interface. If the selection is ignored, treatment can continue with the device (at which point the intensity value of the light signal output by the light source assembly meets the minimum required brightness threshold). In the process that the light source assembly outputs the physiotherapy light signal, the light intensity sensor can detect the light signal brightness output by the light source assembly in real time, if the light signal brightness is lower than a brightness threshold value, the equipment is automatically stopped, the man-machine exchange interface automatically enters the light source exchange interface, the light source exchange is completed according to a prompting step, after the light source exchange is completed, the light signal brightness is automatically detected after clicking and determining, and the accumulated light emitting duration used by the light source assembly stored after the light source exchange is detected is cleared.

Further, recording the cumulative lighting time period of the light source assembly for the host controller may include:

and writing the updated accumulated lighting time length of the light source component into the flash by the host controller every time interval set time length, backing up the latest accumulated lighting time length when the current page of the flash is full, performing full-page erasing on the flash, and re-writing the latest accumulated lighting time length into the erased flash.

In the process of actually recording the operation time of the light source assembly, accumulating the operation time of the light source into the flash every 5 minutes, and performing full page erasing only after the current page of the flash is fully written because the erasing times of the flash are limited and frequent storage is performed. The last time of flash memory is written into a certain address of the next page for backup before erasing, so that the sudden power failure is prevented in the erasing process, and the data is prevented from being lost. After the equipment is electrified, firstly reading the running time of the light source stored in the flash, and if the running time exceeds 500 hours, popping up a prompt box for replacing the light source of the corresponding channel on the interface.

In summary, in the infrared polarized light therapeutic apparatus of the present application, the host and the optical fiber transmission device are connected in a pluggable manner, so that the optical fiber transmission device on the host can replace the optical fiber transmission device of a single-beam optical fiber, a double-beam optical fiber or other types of optical fibers based on the actual physiotherapy requirement, thereby meeting the more diversified physiotherapy requirement of patients; on this basis, further consider to the optical fiber transmission device of different grade type, the power size demand to the physiotherapy light signal of light source module output in the host computer also is different, for this reason, further built-in handle controller in optical fiber transmission device in this application, through the communication connection between the host computer controller in this handle controller and the host computer for the host computer controller can control the light source module and provide the physiotherapy light signal of suitable power for different grade type optical fiber transmission device, and then guarantees on the basis that can change different grade type optical fiber transmission device at any time, can also guarantee that the power size of physiotherapy light signal of optical fiber transmission device output can satisfy physiotherapy demand, guarantees physiotherapy effect.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements is inherent to. Without further limitation, an element defined by the phrase "comprising one … …" does not exclude the presence of other like elements in a process, method, article, or apparatus that comprises the element. In addition, the parts of the above technical solutions provided in the embodiments of the present application, which are consistent with the implementation principles of the corresponding technical solutions in the prior art, are not described in detail, so that redundant descriptions are avoided.

The principles and embodiments of the present invention have been described herein with reference to specific examples, the description of which is intended only to facilitate an understanding of the method of the present invention and its core ideas. It should be noted that it will be apparent to those skilled in the art that various modifications and adaptations of the invention can be made without departing from the principles of the invention and these modifications and adaptations are intended to be within the scope of the invention as defined in the following claims.

Claims

1. The infrared polarized light therapeutic apparatus is characterized by comprising a host machine and an optical fiber transmission device which is connected with the host machine in a pluggable manner;

2. The infrared polarized light therapeutic apparatus according to claim 1, wherein the optical fiber transmission device comprises a transmission portion in which the optical fiber and the cable are integrated, and a handle portion in which the handle controller is built; the cable is used for communication connection between the handle controller and the host controller;

3. The infrared polarized light therapeutic apparatus according to claim 2, wherein a micro switch is provided in the second plug structure;

4. The infrared polarized light therapeutic apparatus according to claim 3, wherein when the host controller receives a start physiotherapy instruction, the host controller detects and obtains the on-off state of the micro switch;

5. The infrared polarized light therapy apparatus of claim 2, further comprising, after successful establishment of a communication connection between the host controller and the handle controller:

6. The infrared polarized light therapeutic apparatus according to claim 1, wherein the handle portion is further provided with physical keys connected to the handle controller for inputting a start physiotherapy command and a scram command to start a start physiotherapy process and control a scram interruption of the physiotherapy process.

7. The infrared polarized light therapy apparatus of claim 6, wherein the handle controller begins to respond to a start physiotherapy command or an emergency stop command when the physical key is pressed for a predetermined period of time.

8. The infrared polarized light therapeutic apparatus according to claim 1 wherein said host controller is further configured to record in real time the cumulative lighting time period of said light source assembly;

9. The infrared polarized light therapeutic apparatus according to claim 8, wherein the host controller is configured to write the updated cumulative lighting time period of the light source module into a flash at a set time period, and when a current page of the flash is full, back up the latest cumulative lighting time period, erase the flash in full pages, and rewrite the latest cumulative lighting time period into the erased flash.

10. The infrared polarized light therapeutic apparatus according to claim 1, wherein at least two of the light source modules are provided in the main unit.