CN107596572B - Wide spectrum diagnosis and treatment instrument - Google Patents

Abstract

The utility model discloses a broad spectrum diagnosis and treatment instrument, which comprises a casing with a combustion chamber, wherein a power supply component for charging a carbon rod positioned in the combustion chamber is arranged on the casing, and the broad spectrum diagnosis and treatment instrument is characterized in that: at least one pair of feeding mechanisms are arranged in the combustion chamber, each carbon rod is respectively clamped on the corresponding feeding mechanism, the front ends of the carbon rods are driven to be close to each other by the same pair of feeding mechanisms to form an electric arc combustion zone, a plurality of independent drivers are arranged outside the combustion chamber on the shell, and each driver is used for respectively driving the corresponding feeding mechanism. The utility model provides a broad spectrum diagnosis and treatment instrument, wherein the carbon rod is convenient to install, and the carbon rod can be automatically fed along with the consumption of combustion, so that the end part of the carbon rod can be combusted to generate continuous and stable treatment spectrum.

Description

Wide spectrum diagnosis and treatment instrument

Technical Field

The utility model relates to the technical field of medical instruments, in particular to a broad spectrum medical instrument.

Background

The wide spectrum diagnosis and treatment instrument uses carbon rods containing different elements to generate arc discharge, so as to generate a group of combined spectrums containing infrared rays, ultraviolet rays and magnetic pulses besides visible light. The combined spectrum irradiates on the relevant treatment area of the human body to cause the human body to generate various biological effects including biological heat effect, electromagnetic effect, photochemical effect and the like, thereby achieving the treatment purpose of regulating the functions of the human body.

However, in the existing broad spectrum diagnosis and treatment instrument, the carbon rods are gradually consumed in the combustion process, so that the interval between the two carbon rods needs to be regularly adjusted, inconvenience is brought to operation, and the combined spectrum generated by the carbon rods is discontinuous along with different intervals between the carbon rods, so that the treatment effect is affected.

Of course, there is also a broad spectrum medical instrument for automatically adjusting the position of the carbon rod in the prior art, for example, the patent name is an utility model patent of a semiautomatic carbon arc light therapeutic instrument (patent number: ZL 2015209277581.3), which provides a technical scheme that the carbon rod can be automatically adjusted along the axial direction, but the replacement of the carbon rod is more inconvenient, and the adjustment precision of the carbon rod is poor.

The utility model patent with the patent name of a carbon clamping device of a carbon ion therapeutic instrument and an intelligent tracking propulsion system (application publication number: CN 102125730A) provides a technical scheme for clamping and feeding carbon rods by utilizing guide wheels, but the technical scheme also faces the problem that the carbon rod replacement process is inconvenient, and certain diameter deviation exists between different carbon rods and between different positions of the carbon rods, so that the carbon rods are very easy to break.

Disclosure of Invention

The technical problems to be solved by the utility model are as follows: the carbon rod is convenient to install, and can be automatically fed along with the consumption of combustion, so that the end part of the carbon rod can be combusted to generate continuous and stable treatment spectrum.

The technical scheme adopted by the utility model is as follows: the utility model provides a broad spectrum diagnosis and treatment instrument, it includes a casing that has the burning chamber, be equipped with on the casing and make the electrified power module of carbon-point that is located the burning chamber, its characterized in that: at least one pair of feeding mechanisms are arranged in the combustion chamber, each carbon rod is respectively clamped on the corresponding feeding mechanism, the front ends of the carbon rods in the same pair are driven to be close to each other by the feeding mechanisms to form an electric arc combustion zone, a plurality of drivers are arranged outside the combustion chamber on the shell, and each driver respectively drives the corresponding feeding mechanism;

the feeding mechanism comprises two guide wheels which are arranged at intervals along the horizontal direction and a driving wheel which is arranged above the guide wheels along the vertical direction; the two guide wheels and the driving wheels are in rotary fit with the shell through respective rotary shafts;

the rotating shaft corresponding to the driving wheel comprises a driving shaft and a driven shaft;

a thrust spring for pushing one end of the driven shaft away from the hinge point to swing downwards is arranged in the shell;

an insulating sleeve is sleeved outside the driven shaft, and one end, close to the driven shaft, of the thrust spring is abutted against the outer side wall of the insulating sleeve.

A clamping space for clamping the carbon rod and driving the carbon rod to move along the axial direction of the carbon rod is formed between the driving wheel and the guide wheel, and a rotating shaft corresponding to the driving wheel is connected with an output shaft of the driver. The carbon rod can be well clamped by means of the two guide wheels and the driving wheel, and the carbon rod can be driven to be stably fed along the axial direction.

All the rotating shafts in the same feeding mechanism are connected with the output shaft of the driver through gear sets. The guide wheel is also connected with the output shaft of the driver through the gear set, so that the pushing force is improved, and the slipping of the carbon rod is avoided.

One end of the driving shaft is connected with an output shaft of the driver, one end of the driven shaft is hinged with the other end of the driving shaft along the vertical direction, the driving wheel is arranged on the other end of the driven shaft, which is away from the driving shaft, when the driving wheel or the driven shaft is acted by the upward acting force along the vertical direction, the driven shaft drives the driving wheel to swing around the hinge point, and the width of the clamping space along the vertical direction is enlarged or reduced along with the swing of the driving wheel. Through the drive wheel of adjustable design, the use of the carbon-point of different diameters of being convenient for improves the commonality, can avoid the carbon-point too tight fracture or too loose problem of skidding moreover. In addition, the end part of the carbon rod, which is installed in the initial stage of carbon rod installation, can be inserted into the clamping space through the swinging of the driving wheel.

One end of the thrust spring is propped against the inner wall of the shell, and the other end of the thrust spring is propped against the outer side wall of the driven shaft.

The driving shaft is made of insulating materials, the driven shaft and the driving wheel are made of conductive materials, and the power supply assembly is electrically connected with the carbon rod through the driven shaft and the driving wheel in sequence. By using the drive wheel as a conductor, no additional conductive tracks are necessary, thus saving installation space.

The shell is provided with a feeding mechanism for supplying carbon rods of each feeding mechanism, and the feeding mechanism drives the carbon rods to move towards the corresponding positions of the feeding mechanisms along the axis direction of the carbon rods until the front ends of the carbon rods are inserted into the clamping spaces of the feeding mechanisms. The new carbon rod can be conveniently added through the feeding mechanism.

The feeding mechanism comprises a driving wheel with a driving motor and a first sensor, a guide channel for inserting the carbon rod into the casing is arranged at a position, close to the driving wheel, on the casing, the guide channel points to the position where the feeding mechanism is located, and when the carbon rod is inserted into the guide channel until touching the first sensor, the driving motor drives the carbon rod to move to the front end of the carbon rod along the length direction of the guide channel through the driving wheel, and the front end of the carbon rod is inserted into a clamping space of the feeding mechanism.

After the structure is adopted, compared with the prior art, the broad spectrum diagnosis and treatment instrument has the following advantages: firstly, carbon-point simple to operate, and can be applicable to the carbon-point of different diameters, therefore the commonality is strong, secondly, can not cause the carbon-point centre gripping to break or too loose the slip in the carbon-point centre gripping process, and consequently carbon-point in-process stability is good, efficient, finally, can be convenient for the interpolation of carbon-point through the feed supplement mechanism, and it can not accomplish the back at the complete back of adding new carbon-point of complete combustion of preceding carbon-point, and consequently the middle time interval of change carbon-point is short, and equipment downtime maintenance time is short, and effective frequency of use is high.

Another technical problem to be solved by the utility model is: the method for installing the carbon rod in the broad spectrum medical instrument can enable the carbon rod to be installed conveniently.

The technical scheme adopted by the utility model is as follows: the utility model provides a mounting method based on carbon rod in above-mentioned broad spectrum diagnosis and treatment appearance, its characterized in that: it comprises the following steps:

step 1, inserting a carbon rod into a corresponding guide channel;

step 2, extending the front end of the carbon rod along the length direction of the guide channel until the front end of the carbon rod contacts with the first sensor;

step 3, a first sensor sends out a detection signal, and a controller on the shell controls a driving motor to work according to the received detection signal, wherein the driving motor drives a carbon rod to move towards the position of the feeding mechanism along the length direction of the guide channel through a driving wheel;

step 4, inserting the front end of the carbon rod into a clamping space of the feeding mechanism and triggering a second sensor;

step 5, the controller controls the driver to work through a detection signal sent by the second sensor, and the driver drives the front end of the carbon rod to move towards the arc combustion area along the axis direction of the front end of the carbon rod through the driving wheel;

step 6, stopping the driver when the front end of the carbon rod moves to a set position in the arc burning zone;

and 7, sequentially repeating the steps 1 to 6 until all the carbon rods are installed.

Drawings

Fig. 1 is a schematic structural diagram of a broad spectrum medical instrument according to the present utility model.

Fig. 2 is a schematic diagram of the front view structure of a broad spectrum medical instrument according to the present utility model.

FIG. 3 is a schematic cross-sectional view in the direction "A-A" in FIG. 2.

Fig. 4 is a schematic side view of a broad spectrum medical instrument according to the present utility model.

FIG. 5 is a schematic cross-sectional view in the direction "B-B" in FIG. 4.

Fig. 6 is a schematic view of the structure of another state of fig. 5.

Wherein, 1, casing, 101, combustion chamber, 2, carbon-point, 3, power supply module, 4, feeding mechanism, 401, leading wheel, 402, drive wheel, 403, clamping space, 404, pivot, 404a, driving shaft, 404b, driven shaft, 405, thrust spring, 5, electric arc combustion zone, 6, driver, 7, gear train, 8, insulating cover, 9, feeding mechanism, 901, driving motor, 902, action wheel, 903, first sensor, 904, guide channel, 10, temperature detect switch, 11, receiving tray.

Wherein d refers to the distance from the center of the driving wheel in the feeding mechanism to the center of the arc burning zone.

Detailed Description

The utility model is further described below with reference to the drawings and the detailed description.

The utility model provides a broad spectrum diagnosis and treatment instrument, which comprises a casing 1 with a combustion chamber 101, wherein a power supply component 3 for electrifying a carbon rod 2 positioned in the combustion chamber 101 is arranged on the casing 1, and is characterized in that: at least one pair of feeding mechanisms 4 are arranged in the combustion chamber 101, each carbon rod 2 is respectively clamped on the corresponding feeding mechanism 4, the front ends of the carbon rods 2 are driven to be close to each other by the same pair of feeding mechanisms 4 to form an arc combustion zone 5, a plurality of independent drivers 6 are arranged outside the combustion chamber 101 on the machine shell 1, and each driver 6 respectively drives the corresponding feeding mechanism 4.

The "a pair" of the above-mentioned pair of feeding mechanisms 4 means not less than two. Preferably, two feeding mechanisms 4 arranged in pairs are arranged in the combustion chamber 101.

The above-described independent actuator 6 means that the actuator 6 has a function of opening and closing independently, and it is needless to say that the linkage is not excluded. When the end distance of two carbon rods 2 becomes larger or the arc combustion zone 5 is offset as a whole due to the fact that one carbon rod 2 burns fast and the other carbon rod 2 burns slow in the process of burning in the arc combustion zone 5, the end distance of the two carbon rods 2 can be corrected and the arc combustion zone 5 is reset to the initial position by adjusting the independent driver 6.

Preferably, when two, three or more pairs of feeding mechanisms 4 are provided in the same combustion chamber 10, two, three or more arc combustion zones 5 exist, and the carbon rods 2 in the same pair of feeding mechanisms 4 are mutually close to form respective arc combustion zones.

The feeding mechanism 4 comprises two guide wheels 401 arranged at intervals along the horizontal direction and a driving wheel 402 arranged above the guide wheels 401 along the vertical direction, a clamping space 403 for clamping the carbon rod 2 and driving the carbon rod 2 to axially move along the self is formed between the driving wheel 402 and the guide wheels 401, the two guide wheels 401 and the driving wheel 402 are in running fit with the casing 1 through respective rotating shafts 404, and the rotating shafts 404 corresponding to the driving wheels 402 are connected with an output shaft of the driver 6.

All the rotating shafts 404 in the same feeding mechanism 4 are connected with the output shaft of the driver 6 through the gear set 7.

The rotating shaft 404 corresponding to the driving wheel 402 includes a driving shaft 404a and a driven shaft 404b, one end of the driving shaft 404a is connected with an output shaft of the driver 6, one end of the driven shaft 404b is hinged with the other end of the driving shaft 404a along the vertical direction, the driving wheel 402 is mounted on the other end of the driven shaft 404b, which is away from the driving shaft 404a, when the driving wheel 402 or the driven shaft 404b receives the upward force along the vertical direction, the driven shaft 404b drives the driving wheel 402 to swing around the hinge point, and the width of the clamping space 403 along the vertical direction expands or contracts along with the swing of the driving wheel 402.

A thrust spring 405 for pushing one end of the driven shaft 404b away from the hinge point to swing downwards is arranged in the casing 1, one end of the thrust spring 405 abuts against the inner wall of the casing 1, and the other end of the thrust spring 405 abuts against the outer side wall of the driven shaft 404 b.

The driving shaft 404a is made of an insulating material, the driven shaft 404b and the driving wheel 402 are made of conductive materials, and the power supply assembly 3 is electrically connected with the carbon rod 2 through the driven shaft 404b and the driving wheel 402 in sequence.

The driven shaft 404b is sleeved with an insulating sleeve 8, and one end, close to the driven shaft 404b, of the thrust spring 405 is abutted against the outer side wall of the insulating sleeve 8.

The shell 1 is provided with a feeding mechanism 9 for feeding the carbon rods 2 of each feeding mechanism 4, and the feeding mechanism 9 drives the carbon rods 2 to move towards the corresponding positions of the feeding mechanisms 4 along the axis direction of the feeding mechanism 9 until the front ends of the carbon rods 2 are inserted into the clamping spaces 403 of the feeding mechanisms 4.

The feeding mechanism 9 comprises a driving wheel 902 with a driving motor 901 and a first sensor 903, a guiding channel 904 for inserting the carbon rod 2 into the casing 1 is arranged on the casing 1 near the driving wheel 902, the guiding channel 904 points to the feeding mechanism 4, and when the carbon rod 2 is inserted into the guiding channel 904 to touch the first sensor 903, the driving motor 901 drives the carbon rod 2 to move along the length direction of the guiding channel 904 through the driving wheel 902 until the front end of the carbon rod 2 is inserted into the clamping space 403 of the feeding mechanism 4.

Preferably, a temperature control switch 10 for detecting the position of the end of the carbon rod 2 in the arc burning zone 5 is arranged in the burning chamber 101. The temperature control switch 10 detects the temperature of the arc burning zone 5 to judge the distance between the two carbon rods 2, and then sends out a control signal to accelerate or slow down the feeding mechanism 4.

Preferably, a receiving tray 11 is disposed below the arc combustion zone 5 in the combustion chamber 101, for receiving the carbon rod 2 remaining after combustion.

Preferably, a heat dissipation fan is arranged on the casing 1, and the heat dissipation fan accelerates the air flow in the combustion chamber 101 to cool the combustion chamber 101, so as to realize the temperature control of the combustion chamber.

Because the carbon rod 2 has high voltage electricity in the working process, in order to be safe to operate, the other end of the carbon rod 2, which is positioned in the arc burning zone 5, cannot touch the shell 1 after moving in place, thereby achieving the purpose of electricity safety. Therefore, the length of the carbon rod 2 is preferably smaller than the distance d between the midpoint position of the arc burning zone 5 and the center point position of the driving wheel 902 in the feeding mechanism 9. The above-mentioned midpoint position of the arc burning zone 5 refers to the position of the midpoint of the arc burning zone 5 along the length direction of the carbon rod 2 in the drawing.

The carbon rod installation method based on the broad spectrum diagnosis and treatment instrument is characterized by comprising the following steps of: it comprises the following steps:

step 1, inserting a carbon rod 2 into a corresponding guide channel 904;

step 2, the front end of the carbon rod 2 extends into the first sensor 903 along the length direction of the guide channel 904;

step 3, a first sensor 903 sends out a detection signal, a controller on the casing 1 controls a driving motor 901 to work according to the received detection signal, and the driving motor 901 drives a carbon rod 2 to move towards the position of a feeding mechanism 4 along the length direction of a guide channel 904 through a driving wheel 902; of course, preferably, in the above step 3, if the carbon rod 2 is present in the arc combustion zone 5, the first sensor 903 does not send out a detection signal, if the carbon rod is not present in the arc combustion zone 5, the first sensor 903 sends out a detection signal, the controller on the casing 1 controls the driving motor 901 to operate according to the received detection signal, and the driving motor 901 drives the carbon rod 2 to move towards the position of the feeding mechanism 4 along the length direction of the guide channel 904 through the driving wheel 902

Step 4, inserting the front end of the carbon rod 2 into the clamping space 403 of the feeding mechanism 4 and triggering a second sensor; the second sensor may be an infrared sensor installed in the casing, or a contact sensor installed in the casing for detecting the swing of the driven shaft 404b after the carbon rod contacts the driving wheel 402, and of course, since the position between the first sensor and the feeding mechanism is fixed after the installation of the device is completed, the second sensor may also be a stroke sensor of the driving motor 901, and the stroke of the carbon rod is determined by calculating the stroke of the driving motor 901.

Step 5, the controller controls the driver 6 to work through a detection signal sent by the second sensor, and the driver 6 drives the front end of the carbon rod 2 to move towards the arc burning zone 5 along the axis direction of the front end through the driving wheel 402;

step 6, stopping the operation of the driver 6 when the front end of the carbon rod 2 moves to a set position in the arc burning zone 5;

and 7, sequentially repeating the steps 1 to 6 until all the carbon rods 2 are installed.

In the above steps, when the power supply assembly 3 is electrified to make the carbon rod 2 work and burn, the driver 6 drives the carbon rod 2 to feed slowly, so as to compensate the consumption of the carbon rod 2 in burning.

Of course, in the normal use process of the broad spectrum medical instrument, the situation that part of the carbon rods 2 burn fast and part of the carbon rods burn slow may exist, if the carbon rods 2 in any one feeding mechanism in the same pair of feeding mechanisms 4 burn completely, all the carbon rods on all the feeding mechanisms in the same pair are powered off, and then the carbon rods 2 are accelerated to be pushed to fall off. Taking two feeding mechanisms 4 in the same pair as an example, when the carbon rod 2 on one feeding mechanism 4 burns and falls off, the residual carbon rod on the other feeding mechanism is powered off, and then the driver 6 drives the residual carbon rod 2 on the feeding mechanism 4 to feed to the position where the opposite feeding mechanism 4 is located, so that the residual carbon rod 2 falls into the receiving tray 11 at the bottom after being separated from the constraint of the feeding mechanism 4.

The foregoing description of the preferred embodiments of the present utility model is provided for illustration and is not to be construed as limiting the claims. The present utility model is not limited to the above embodiments, and the specific structure thereof is allowed to be changed, and all changes made within the scope of the utility model as independently claimed are within the scope of the utility model.

Claims (9)

1. A broad spectrum medical instrument, which comprises a casing (1) with a combustion chamber (101), wherein a power supply component (3) for charging a carbon rod (2) positioned in the combustion chamber (101) is arranged on the casing (1), and the broad spectrum medical instrument is characterized in that: at least one pair of feeding mechanisms (4) are arranged in the combustion chamber (101), each carbon rod (2) is respectively clamped on the corresponding feeding mechanism (4), the front ends of the carbon rods (2) in the same pair are driven to be close to each other by the feeding mechanisms (4) to form an electric arc combustion zone (5), a plurality of drivers (6) are arranged on the casing (1) and are arranged outside the combustion chamber (101), and each driver (6) respectively drives the corresponding feeding mechanism (4);

the feeding mechanism (4) comprises two guide wheels (401) which are arranged at intervals along the horizontal direction and a driving wheel (402) which is arranged above the guide wheels (401) along the vertical direction; the two guide wheels (401) and the driving wheels (402) are in rotary fit with the machine shell (1) through respective rotary shafts (404);

the rotating shaft (404) corresponding to the driving wheel (402) comprises a driving shaft (404 a) and a driven shaft (404 b);

a thrust spring (405) for pushing one end of the driven shaft (404 b) away from the hinge point to swing downwards is arranged in the shell (1);

an insulating sleeve (8) is sleeved outside the driven shaft (404 b), and one end, close to the driven shaft (404 b), of the thrust spring (405) abuts against the outer side wall of the insulating sleeve (8).

2. A broad spectrum medical instrument as in claim 1 wherein: a clamping space (403) for clamping the carbon rod (2) and driving the carbon rod (2) to move along the axial direction of the carbon rod is formed between the driving wheel (402) and the guide wheel (401), and a rotating shaft (404) corresponding to the driving wheel (402) is connected with an output shaft of the driver (6).

3. A broad spectrum medical instrument as claimed in claim 2, wherein: all the rotating shafts (404) in the same feeding mechanism (4) are connected with the output shaft of the driver (6) through a gear set (7).

4. A broad spectrum medical instrument as claimed in claim 2, wherein: one end of the driving shaft (404 a) is connected with an output shaft of the driver (6), one end of the driven shaft (404 b) is hinged with the other end of the driving shaft (404 a) along the vertical direction, the driving wheel (402) is arranged on the other end of the driven shaft (404 b) deviating from the driving shaft (404 a), when the driving wheel (402) or the driven shaft (404 b) is acted by the upward acting force along the vertical direction, the driven shaft (404 b) drives the driving wheel (402) to swing around a hinge point, and the width of the clamping space (403) along the vertical direction is enlarged or reduced along with the swing of the driving wheel (402).

5. A broad spectrum medical instrument as in claim 4 wherein: one end of the thrust spring (405) is abutted against the inner wall of the casing (1), and the other end of the thrust spring (405) is abutted against the outer side wall of the driven shaft (404 b).

6. A broad spectrum medical meter as in claim 5 wherein: the driving shaft (404 a) is made of an insulating material, the driven shaft (404 b) and the driving wheel (402) are made of conductive materials, and the power supply assembly (3) is electrically connected with the carbon rod (2) through the driven shaft (404 b) and the driving wheel (402) in sequence.

7. A broad spectrum medical instrument as claimed in claim 2, wherein: the feeding mechanism (9) for feeding the carbon rods (2) of each feeding mechanism (4) is arranged on the machine shell (1), and the feeding mechanism (9) drives the carbon rods (2) to move towards the corresponding positions of the feeding mechanisms (4) along the axis direction of the machine shell until the front ends of the carbon rods (2) are inserted into the clamping spaces (403) of the feeding mechanisms (4).

8. A broad spectrum medical instrument as in claim 7 wherein: the feeding mechanism (9) comprises a driving wheel (902) with a driving motor (901) and a first sensor (903), a guide channel (904) for inserting the carbon rod (2) into the casing (1) is arranged at a position, close to the driving wheel (902), on the casing (1), the guide channel (904) points to the position where the feeding mechanism (4) is located, and when the carbon rod (2) is inserted into the guide channel (904) to touch the first sensor (903), the driving motor (901) drives the carbon rod (2) to move along the length direction of the guide channel (904) to the front end of the carbon rod (2) to be inserted into a clamping space (403) of the feeding mechanism (4) through the driving wheel (902).

9. A method for installing a carbon rod in a broad spectrum medical instrument according to any of the preceding claims 1 to 8, characterized by: it comprises the following steps:

step 1, inserting a carbon rod (2) into a corresponding guide channel (904);

step 2, extending the front end of the carbon rod (2) along the length direction of the guide channel (904) until the front end contacts with the first sensor (903);

step 3, a first sensor (903) sends out a detection signal, a controller on a machine shell (1) controls a driving motor (901) to work according to the received detection signal, and the driving motor (901) drives a carbon rod (2) to move towards the position of a feeding mechanism (4) along the length direction of a guide channel (904) through a driving wheel (902);

step 4, inserting the front end of the carbon rod (2) into a clamping space (403) of the feeding mechanism (4) and triggering a second sensor;

step 5, the controller controls the driver (6) to work through a detection signal sent by the second sensor, and the driver (6) drives the front end of the carbon rod (2) to move towards the arc combustion zone (5) along the axis direction of the front end through the driving wheel (402);

step 6, stopping the operation of the driver (6) when the front end of the carbon rod (2) moves to a set position in the arc burning zone (5);

and 7, sequentially repeating the steps 1 to 6 until all the carbon rods (2) are installed.