CN118402845A - Rotor type myofascial and fascia loosening water jet flow system - Google Patents

Abstract

The invention discloses a rotor type myofascial fascia loosening water jet power system which comprises a jet generating device, a jet pipeline, a handle, a needle type spray head and a liquid containing bottle, wherein the jet pipeline is connected with the handle; the needle type spray head is connected with the front end of the adapter, the rear end of the adapter is connected with the tail end of the jet pipeline, and the jet pipeline is a flexible hose; after the jet pipeline is matched with the adapter, the jet pipeline penetrates through the hollow cavity in the handle and then extends out of the tail end of the handle, and the handle comprises a mechanical adjusting device for controlling the internal pressure of the jet pipeline and the flow velocity of water flow through the extrusion pipeline; a section of pipeline between the tail end and the front end of the jet pipeline is positioned in the jet generating device, a rotor mechanism for extruding the section of pipeline is arranged in the jet generating device, the pipeline is extruded by a rotor to generate vacuum in the pipeline, the traditional Chinese medicine liquid in the liquid containing bottle is pumped to suck the jet pipeline, and jet is realized through a needle type spray head. The invention relates to a water jet flow system suitable for the muscular and bone fascia release technology of people suffering from pain in all age groups.

Description

Rotor type myofascial and fascia loosening water jet flow system

Technical Field

The invention relates to the technical field of medical equipment, in particular to a rotor type myofascial fascia relaxing water jet power system.

Background

Various pains in the neck, shoulder, waist, back, joints, etc. have become the second highest incidence of respiratory tract infections in the world, and inflammation/adhesion of soft tissues (such as muscular fascia) and cartilage tissues are the main "primordial" of various pains. The local adhesion and even the nodule of the musculoskeletal fascia and other tissues can cause the tissue gap to be narrow or disappear, thereby limiting the blood circulation, clamping and pressing the nerves and even limiting the limb movement, and the symptoms of the musculoskeletal fascia and other tissues are integrated with pain, limited movement and nerve dysfunction, so that the physical and mental health and the life quality of a patient are seriously influenced.

The current treatment methods of the disease mainly comprise general treatment and minimally invasive surgery treatment, wherein the general treatment is divided into traditional Chinese medicine treatment, physical therapy and drug treatment, such as traditional massage, acupuncture, radio frequency physiotherapy and the like; minimally invasive surgery is mainly a small needle knife therapy, which is a therapy of physical needling separation by using a small needle knife similar to an acupuncture silver needle. In the treatment process, doctors repeatedly and multipoint pierce the myofascial pain part of the patient through the small needle knife, and the knife tip of the small needle knife is used for cutting tissues which are inflamed or adhered to achieve the purpose of separation, anesthesia is not applied in the treatment, and rehabilitation training is needed to be matched after the treatment.

For the above mentioned treatment methods, the general treatment methods are more, but the curative effect is poor, and most of the treatment methods are temporary treatment and temporary treatment, the illness state is easy to recur after stopping the treatment, and only the relieving effect can be achieved, so that the pathological problem of pain can not be fundamentally solved. While the rigid stripping operation of the small needle knife is still an invasive cutting operation, patients often have severe pain and even painful shock during the operation.

In addition, the rigid cutting of the small needle knife has great stimulation to surrounding tissues, bleeding and inflammatory edema are easy to cause, and if accurate rehabilitation training is not performed after operation, more serious adhesion can be caused again at a cutting interface.

Disclosure of Invention

The invention aims to overcome the defects and the shortcomings of the prior art and provide a rotor type myofascial loosening water jet power system so as to realize flexible separation of tissues such as myofascial and the like, improve the accuracy and applicability of separation operation, and are suitable for pain and discomfort caused by inflammation/adhesion of soft tissues, cartilage tissues and the like and suitable for people suffering from pain in all age groups.

A rotor type myofascial and fascia loosening water jet power system comprises a jet generating device, a jet pipeline, a handle, a needle type spray head and a liquid containing bottle; the needle type spray head is connected with the front end of the adapter, the rear end of the adapter is connected with the tail end of the jet pipeline, and the jet pipeline is a flexible hose; after the jet pipeline is matched with the adapter, the jet pipeline penetrates through the hollow cavity in the handle and then extends out of the tail end of the handle, and the handle comprises a mechanical adjusting device for controlling the internal pressure of the jet pipeline and the flow velocity of water flow by extruding the pipeline; the device is characterized in that a section of pipeline between the tail end and the front end of the jet pipeline is positioned in the jet generating device, a rotor mechanism for extruding the section of pipeline is arranged in the jet generating device and used for extruding the pipeline through a rotor to generate vacuum in the pipeline, pumping the traditional Chinese medicine liquid in the liquid containing bottle to suck the jet pipeline, and jet is realized through a needle type spray head.

Optionally, the mechanical adjusting device comprises a sliding block, a semicircular flange is arranged in the middle of the upper end of the sliding block, a jet pipeline in the handle passes through the inner surface of the handle opposite to the flange from the top of the semicircular flange, a spring is connected to the bottom end of the sliding block, and a key is connected to the upper end of the sliding block; the keys are assembled in key sliding grooves of the handle, and the sliding blocks are arranged in sliding block grooves of the handle; grooves with different depths are formed in the handle, and bosses matched with the grooves are formed on two sides of the lower part of the sliding block; when the boss is controlled to move by the key and is positioned in different grooves, the pipe section of the jet pipeline in the handle can be subjected to extrusion forces of different magnitudes due to the action of a spring at the bottom of the sliding block.

Optionally, the grooves are arranged at intervals along the length direction of the handle, and the depth of the grooves is increased or decreased from one end of the handle to the other end of the handle.

Optionally, the handle includes handle upper shell and handle inferior valve, the button is adorned in the handle upper shell, slider and spring are adorned in the handle inferior valve, handle upper shell and handle inferior valve pass through convex-concave structure cooperation location.

Optionally, the front ends of the upper handle shell and the lower handle shell are respectively provided with a semicircular external thread part, and are connected with the threaded cover after being in butt joint; after the jet pipeline is matched with the adapter, the jet pipeline penetrates through the threaded cover to be arranged in the hollow cavity in the handle, and the adapter is positioned in the hollow cavity in the handle.

Optionally, the jet pipeline, the handle, the needle type spray head and the adapter and the liquid containing bottle are disposable consumables.

Optionally, the jet generating device comprises a jet generating pump and a motor; the jet flow generating pump comprises two oppositely spaced roller discs arranged in a pump head shell, a rotating shaft connected with the two roller discs, and at least two rotors positioned between the roller discs and rotationally arranged around the rotation center of the rotating shaft, wherein two ends of the rotating shaft are connected with a shaft hole of the pump head shell through bearings, the rotating shaft is connected with a motor, and a gap through which a jet flow pipeline passes is formed between the rotors and the pump head shell; when the rotor rotates, the rotor can extrude the jet pipeline contacted with the rotor to generate vacuum in the pipeline, the medicine liquid in the liquid containing bottle is pumped to be sucked into the jet pipeline, and jet is realized through the needle type spray head.

Optionally, the pump head shell comprises a pump head upper shell capable of lifting, a pump head lower shell is arranged at the lower end of the pump head upper shell, the pump head upper shell and the pump head lower shell form a pump head front shell, and the pump head front shell and the pump head rear shell form the pump head shell together; the eccentric wheel is arranged on the pump head, the front end of the eccentric wheel is provided with a cylinder, the cylinder penetrates through the rear shell of the pump head to be connected with the upper shell of the pump head, the eccentric wheel is connected with the rocker, the eccentric wheel can be controlled to rotate by rotating the rocker, and the lifting of the upper shell of the pump head is realized by rotating and driving the eccentric wheel.

Optionally, a slot is formed in the upper shell of the pump head, a pull-up sliding block capable of moving up and down is arranged on the upper shell of the pump head, grooves are symmetrically formed in two sides of the bottom of the upper shell of the pump head, a pull-up button is arranged in the grooves and can slide up and down in the grooves, and the pull-up button is symmetrically arranged on the upper shell of the pump head after being fastened and connected with the pull-up sliding block; the pull-up key is pushed to control the pull-up sliding block to slide up and down, and the V-shaped groove at the bottom of the pull-up key is used for pressing the clamping pressure of the jet pipeline at the two ends of the pipeline section extruded by the rotor inside the pump head, so that the jet pipeline is positioned and fastened.

Optionally, the electronic control device comprises a shell, wherein the shell comprises an upper shell of the pump body and a lower shell of the pump body; the motor extension shaft penetrates through the lower shell of the pump body and is connected with a rotating shaft in the pump head; the motor is connected with the motor controller, the motor controller is connected with the fan and the display screen, and is connected with an external communication interface and a power interface, the fan is used for radiating the direct current motor, the power interface is used for being connected with an external power supply, and the communication interface is used for communicating with external equipment; the motor, the motor controller and the fan are all arranged in corresponding positioning grooves of the shell; a display screen is arranged on the upper shell of the pump body so as to carry out pressure regulation operation and display preset numerical values in real time.

The rotor type myofascial and fascia relaxing water jet power system provided by the invention has the following beneficial effects:

1) The needle type spray head can quickly and accurately reach the lesion position under the assistance of the ultrasonic navigator, the electric control pressure can be adopted, the medical liquid injection can be completed without the need of a doctor to adjust a needle-holding hand in the treatment process, the positioning accuracy of tissue loosening can be improved, and the problem of closed operation access can be effectively solved;

2) The jet flow generating pump with the rapid disengaging device is adopted, the pipeline is provided in a sterile state, the pump body is sterilized by ethylene oxide, and the pump body can not directly contact water flow in the pipeline in the working process, only the disposable consumable part is required to be replaced for each treatment, so that the safety and sterility requirements of clinical pain treatment operation are effectively met, and the operation is convenient;

3) The water jet pipeline is connected with the ultra-minimally invasive needle type spray head by adopting an adapter, so that the connection tightness and the tightness are effectively improved, the leakage is prevented, and the pressure of the water jet is ensured to be stable;

4) The needle type spray head is designed into a flexible guide needle type structure with the diameter less than or equal to 0.3mm, so that the problem of closed operation access is solved, simultaneously, the separation of ultra-minimally invasive (needle penetration millimeter-level damage) is realized, simultaneously, the wound caused in the treatment process is smaller, the bleeding is less, and the selective separation of water jet is utilized by adjusting the jet pressure, so that the muscular-bone fascia is effectively realized, and meanwhile, the overlarge wound damage is not caused to the surrounding tissue structure.

Drawings

FIG. 1 is an exploded view of a rotor-type myofascial opening water jet power system of the present invention.

Fig. 2 is an exploded view of a portion of the handle and nozzle of the rotor-type myofascial opening water jet power system of the present invention.

Fig. 3 is a partial cross-sectional view of a handle and nozzle of the rotor-type myofascial opening hydraulic system of the present invention.

Fig. 4 is an exploded view of a portion of the pump head of the rotor-type myofascial opening water jet power system of the present invention.

Fig. 5 is a partial cross-sectional view of a pump head of a rotor-type myofascial opening water jet power system of the present invention.

Fig. 6 is a schematic external view of a rotor-type myofascial opening water jet power system of the present invention.

Wherein:

1. handle 2, jet generating pump

3. Liquid bottle 4, DC brush motor

5. Display screen 6 and foot pad

7. Power interface 8, pump body lower outer shell

9. Fan 10, external communication interface

11. Motor controller 12 and pump body upper shell

13. Needle-type spray head 14, screw cap

15. Luer adapter 16 and upper handle shell

17. Handle lower shell 18, slider

19. Button 20, pump head lower shell

21. Roller disc 22 and pump head upper shell

23. Rocker 24, roller bearing

25. Pump head rear shell 26, rotary shaft

27. Rotor 28, eccentric wheel

29. Rear cover 30, pull-up slider

31. Pull-up button 32, jet flow pipeline

Detailed Description

So that the manner in which the above recited objects, features and advantages of the present invention can be understood in detail, a more particular description of the invention, briefly summarized below, may be had by reference to the appended drawings.

It should be noted that, without conflict, the embodiments of the present invention and features of the embodiments may be combined with each other.

The water jet technology has become a new advanced surgical technology due to the advantages of no thermal injury, less bleeding amount, tissue selective protection and separation, and the like. Therefore, the water jet flow system is applied to the treatment of pain and discomfort caused by inflammation/adhesion of soft tissues, cartilage tissues and the like, and is suitable for the muscular and bone fascia release technology of people suffering from pain in all age groups.

As shown in fig. 1-6, an embodiment of the present invention provides a rotor type myofascial and fascia loosening water jet power system, which comprises a jet generating device, a jet pipeline 32, a handle 1, a needle-type spray head 13 and a liquid containing bottle 3; the needle type spray head 13 is connected with the front end of an adapter (preferably a luer adapter 15 is adopted), the rear end of the adapter is connected with the tail end of a jet pipeline 32, and the jet pipeline 32 is a flexible hose; after being matched with the adapter, the jet pipeline 32 passes through the hollow cavity in the handle 1 and then extends out of the tail end of the handle 1, wherein the handle 1 comprises a mechanical adjusting device for controlling the internal pressure of the jet pipeline and the flow rate of water flow by extruding the pipeline; a section of pipeline between the tail end and the front end of the jet pipeline 32 is positioned in the jet generating device, a rotor mechanism for extruding the section of pipeline is arranged in the jet generating device and is used for extruding the pipeline through a rotor so as to generate vacuum in the pipeline, pumping medical liquid medicine in the liquid containing bottle 3 to suck the jet pipeline, and jet is realized through a needle type spray head.

In a preferred embodiment, the handle 1 comprises an upper handle shell 16 and a lower handle shell 17, and the upper handle shell 16 and the lower handle shell 17 are buckled to form the handle 1.

In a preferred embodiment, the mechanical adjusting device comprises a sliding block 18, a semicircular flange is arranged in the middle of the upper end of the sliding block, a jet pipeline in the handle passes through the inner surface of the handle opposite to the flange from the top of the semicircular flange, a spring is connected to the bottom end of the sliding block, and a key 19 is connected to the upper end of the sliding block; the keys are assembled in key sliding grooves of the handle, and the sliding blocks are arranged in sliding block grooves of the handle; grooves with different depths are formed in the handle, and bosses matched with the grooves are formed on two sides of the lower part of the sliding block; when the boss is controlled to move by the key and is positioned in different grooves, the pipe section of the jet pipeline in the handle can be subjected to extrusion forces of different magnitudes due to the action of a spring at the bottom of the sliding block. Referring to fig. 2, the needle-type spray head 13 is connected with the front end of the luer adapter 15, the rear end of the luer adapter 15 is connected with the end of the jet pipeline 32, after the jet pipeline 32 is matched with the luer adapter 15, the needle-type spray head passes through the inner hollow cavity formed by the upper handle shell 16 and the lower handle shell 17 after being assembled, is tightly attached to the surface of the semicircular flange in the middle of the top of the sliding block 18, and then extends out of the round hole at the tail end of the upper handle shell 16 to be connected with a subsequent structure.

Referring to fig. 2, specifically, a cylindrical boss is disposed at the bottom of the slider 18, and a spring is connected with the bottom of the slider in an interference manner. Rectangular bosses are arranged at the lower parts of two sides of the sliding block 18, and can slide in a hollow cavity in the lower handle shell 17 after being inserted into rectangular grooves formed in the front end of the lower handle shell 17, and elongated rectangular bosses are oppositely arranged at two sides of the top end of the sliding block 18, penetrate through the grooves of the upper handle shell 16 and are in interference fastening connection with the grooves at the bottom of the key 19 so as to achieve the purpose of fastening; by pressing the push button 19, the slider 18 can slide in the hollow cavity inside the handle lower housing 17 in the longitudinal direction of the handle lower housing.

Optionally, the hollow cavity inside the lower handle casing 17 is provided with a plurality of rectangular grooves with different depths or heights, which are matched with the sliding block 18 and are arranged at intervals, and the rectangular grooves are arranged along the length direction of the rectangular grooves, optionally, the rectangular grooves are arranged at intervals along the length direction of the handle, and the depths of the rectangular grooves are sequentially increased or sequentially decreased from one end of the handle to the other end of the handle. After the rectangular bosses on two sides of the lower part of the sliding block vertically leave the corresponding rectangular grooves downwards, the sliding guide can be controlled to move forwards and backwards through the keys 19, when the rectangular bosses on two sides of the lower part of the sliding block are embedded into the corresponding rectangular grooves, the sliding block 18 can be positioned, the extrusion of the jet pipeline 32 can be realized by pushing the keys 19, and therefore, the mechanical adjustment of the pressure and the flow velocity of water flow is realized.

In a preferred embodiment, the top of the key 19 is designed with a continuous small groove for increasing friction. Optionally, a rectangular boss is provided at the bottom of the upper handle housing 16 near the front end and is matched with a rectangular positioning groove provided at the front end of the lower handle housing 17, the front ends of the upper handle housing 16 and the lower handle housing 17 are connected with a threaded cover 14 having internal threads after being matched and butted, and the threaded cover 14 is fastened and connected with external threads at the front ends of the upper handle housing 16 and the lower handle housing 17.

The center of the screw cap 14 is provided with a hole, the needle-type spray head 13 passes through the hole and is connected with the front end of the luer adapter 15, and the luer adapter 15 is positioned in a positioning cavity formed by butt-joint matching of an upper self-joint positioning groove and a lower self-joint positioning groove formed by the inner sides of the near front ends of the upper handle shell 16 and the lower handle shell 17.

Preferably, the front end of the luer adapter 15 is in screw thread fastening connection with the needle nozzle 13, and the rear end of the luer adapter 15 is provided with a cylindrical slender round table which is in interference connection with the tail end of the jet pipeline 32. After the needle type spray head 13 and the luer adapter 15 are in threaded fastening fit, the luer adapter 15 is matched with front end positioning grooves of the handle upper shell 16 and the handle lower shell 17, and threaded fastening connection is realized through the threaded cover 14; after the connection of the jet pipeline 32 is realized through the luer adapter 15, the jet pipeline is extended out of the tail end of the handle upper shell 16 to connect with a subsequent structure after passing through a groove structure formed by a rectangular boss at the upper end of the sliding block 18, namely, the jet pipeline is extended out of a round hole at the tail end of the handle upper shell 16 to connect with the subsequent structure after passing through an internal hollow cavity formed by assembling the handle upper shell 16 and the handle lower shell 17.

According to the application, through the design of the key 19 and the slide block 18, the mechanical step adjustment of pressure and water flow speed can be controlled, after the liquid medicine flows out of the liquid containing bottle 3 and enters the jet pipeline 32, the bottom of the slide block 18 is connected with a spring, the upper part is connected with the key 19, the slide block 18 can be matched with different wedge-shaped grooves by pushing the key 19 to move, and the flange at the upper end of the slide block 18 can squeeze the jet pipeline 32, so that the cross section area of the pipeline 32 is adjusted, and finally, the real-time mechanical adjustment of pressure and flow speed is realized.

In the application, the mechanical step adjustment of the pressure and the water flow speed is that the part of the jet pipeline 32 in the handle 1 passes through the gap formed by the upper handle shell 16 and the semicircular flange in the middle of the sliding block 18, and the semicircular working surface of the flange fully fits with the extrusion jet pipeline 32. The cylindrical bosses at the bottom of the sliding block 18 are in interference connection with the springs to provide upward elastic force, in the process that the sliding block 18 moves in the cavity inside the shell 17, the elastic force provided by the springs can enable the rectangular bosses at two sides of the sliding block 18 to rebound upward, so that clearance fit is realized with rectangular grooves with different depths in the cavity inside the shell 17, and due to the fact that the depths of the rectangular grooves are different, the depth of the matched positions of the sliding block 18 is also different, the clearance formed by the semicircular flanges at the middle part of the sliding block 18 and the shell 16 on the handle is different, so that the semicircular working surfaces of the flanges squeeze jet flow pipelines 32 with different degrees, the cross-sectional area of the jet flow pipelines 32 is adjusted, and mechanical stepping adjustment of pressure and water flow velocity is realized.

In one embodiment, referring to fig. 3, the jet generating device comprises a jet generating pump 2, and a motor connected with the jet generating pump 2, preferably a direct current brush motor 4 is adopted; the jet generating pump 2 comprises a pump head lower shell 20, two rotary roller discs 21 which are arranged oppositely and spaced, a pump head upper shell 22, a rotary roller bearing 24, a pump head rear shell 25, a rotary shaft 26 connected with the two rotary roller discs 21, and a plurality of rotors 27 (preferably three, uniformly arranged around the center) which are arranged between the rotary roller discs 21 and rotate around the rotation center of the rotary shaft; the jet flow generating pump 2 is connected with the handle 1 and the liquid containing bottle 3 through the jet flow pipeline 32, corresponding medical liquid is stored in the liquid containing bottle 3, and the jet flow pipeline 32 is spliced with the liquid containing bottle during use.

In one embodiment, the gap or space formed between the pump head upper shell 22 and the pump head lower shell 20 for the jet pipeline to pass through is realized by forming a matched groove, such as a V-shaped groove, on the bottom of the pump head upper shell 22 and the upper part of the pump head lower shell 20, as shown in fig. 4, a rotor 27 is arranged at the middle position of the gap or space formed between the pump head upper shell 22 and the pump head lower shell 20 for the jet pipeline to pass through, a gap formed between the pump head upper shell 22 and the rotor 27 for the jet pipeline to pass through is formed, and the rotating shaft 26 is driven to rotate by the direct current brush motor 4, so that the rotor 27 is driven to rotate.

The rear part of the pump head upper shell 22 is provided with a trapezoid groove, the front part of the pump head rear shell 25 is provided with a trapezoid convex groove, and the pump head upper shell 22 and the pump head rear shell 25 are connected through the trapezoid groove in an inserting mode.

Wherein further, an eccentric wheel 28 is arranged at the upper part of the jet generating pump 2, an elongated cylinder is arranged at the front end of the eccentric wheel 28, and the cylinder is inserted into a trapezoid groove at the rear part of the pump head upper shell 22 after passing through a circular through hole (passing through a trapezoid convex groove) at the upper end of the pump head rear shell 25, so that the positioning is realized; the disc at the rear of the eccentric wheel 28 is in clearance fit with the rectangular groove at the rear of the pump head rear shell 25 so as to realize connection, as shown in fig. 5, fig. 5 shows a structural diagram of the rear of the pump head rear shell 25, the eccentric wheel 28 is in fastening connection with the rocker 23 through threads, and the eccentric wheel can be controlled to rotate by rotating the rocker 23, so that the lifting of the pump head upper shell 22 is realized through eccentric wheel driving, and the subsequent installation and detachment of the jet pipeline 32 are carried out. Wherein, be provided with back lid 29, back lid 29 installs in the eccentric wheel 28 rear portion, the trompil is gone up with pump head backshell 25 to back lid 29, and the two passes through bolt-up connection to realize the fastening connection of eccentric wheel 28 on the pump head.

The pump head lower shell 20 and the pump head rear shell 25 are provided with holes, and are fastened and connected through bolts, further, round grooves are respectively formed in the lower ends of the pump head lower shell 20 and the pump head rear shell 25, two roller bearings 24 are respectively assembled in the corresponding round grooves, a rotating shaft 26 is connected with the two roller discs 21, interference connection of the two roller bearings is achieved through shaft holes in the roller discs 21, and two ends of the rotating shaft 26 are respectively matched with the two roller bearings 24.

Optionally, the rotor 27 is fastened and connected to the roller disc 21 through threads, and the roller bearing 24, the roller disc 21 and the rotor 27 are integrally installed on the jet generating pump 2, and then the structure formed by the two is located in a hollow cavity formed by the pump head lower shell 20 and the pump head upper shell 22 after being assembled.

Further, in one embodiment, the pump head upper shell 22 is provided with a pull-up slider 30 in a slot, the pull-up key 31 and the pull-up slider 30 are fastened and connected through pins, preferably, two sides of the bottom of the pump head upper shell 22 are symmetrically provided with grooves, the pull-up key 31 is integrally installed in the grooves through clearance fit and can slide up and down in the grooves, the pull-up key 31 is symmetrically installed on the pump head upper shell 22 after being fastened and connected with the pull-up slider 30 through pins, and the pull-up key 31 can be controlled to slide up and down in the grooves by pushing the pull-up key 31, so that the positioning and fastening of the subsequent jet pipeline 32 can be performed.

Specifically, after the jet pipeline 32 extends out of the round hole at the tail end of the upper handle shell 16, the jet pipeline 32 passes through a gap formed after the upper pump head shell 22 and the rotor 27 are installed, the pull-up slider 30 is moved up and down by pushing the pull-up key 31, a V-shaped groove is arranged at the bottom of the pull-up slider 30 and is aligned with the pipeline section of the jet pipeline 32 in the jet generating pump 2, namely, the left end and the right end of the pipeline section extruded by the rotor 27 are clamped and pressed, so that fastening and fixing are realized, and the part of the pipeline section of the jet pipeline 32 in the jet generating pump 2 is contacted with the top of the rotor 27 and is positioned in an interference gap between the rotor 27 and the upper pump head shell 22. After the jet pipeline 32 passes through the jet generating pump 2, a sharp plug at the end part of the jet pipeline 32 is fixedly connected with a slot at the bottom of the liquid containing bottle 3.

Further, in one embodiment, the jet generator comprises an electric control device, wherein the electric control device comprises a shell, the shell comprises an upper shell 12 of a pump body and a lower shell 8 of the pump body, the upper shell 12 of the pump body and the lower shell 8 of the pump body are connected through screw threads, and the extension shaft of the direct current brush motor 4 penetrates through a circular groove formed in the lower shell 8 of the pump body and is connected with a rotating shaft 26 in the jet generator pump 2; further, the direct current brush motor 4 is connected with a motor controller 11, the motor controller 11 is connected with a fan 9 and a display screen 5, and is connected with an external communication interface 10 and a power interface 7, the display screen is preferably a touch type LED display screen, the fan is used for radiating heat for the direct current motor, the power interface is used for connecting an external power supply, and the communication interface is used for communicating with external equipment. The direct current brush motor 4, the motor controller 11 and the fan 9 are all arranged in corresponding positioning grooves of the shell; preferably, the pump body upper casing 12 is provided with a display screen 5 for pressure adjustment and real-time display.

Preferably, the external communication interface 10 and the power interface 7 are installed in a groove formed in the rear end of the pump body lower shell 8 and used for connecting an external lead, and the foot pad 6 is installed at the bottom of the pump body lower shell 8 through threaded connection.

The direct current brush motor 4, the motor controller 11, the fan 9, the external communication interface 10, the power interface 7 and the display screen 5 are connected through wires, a through hole is formed in the front portion of the pump body lower shell 8, and a motor shaft flange at the front end of the direct current brush motor 4 penetrates through the through hole and is connected with the rotating shaft 26.

When the pump head is installed, after the pump head upper shell 22 is lifted by rotating the rocker 23, the jet flow pipeline 32 can be fixed in the pump head by pushing the pull-up key, so that the rotor 27 can squeeze and release the jet flow pipeline. Specifically, the rocker 23 is rotated to enable the pump head upper shell 22 to ascend, so that the gap between the pump head upper shell 22 and the rotor 27 is increased, the jet pipeline 32 is installed in the gap between the pump head upper shell 22 and the rotor 27, the jet pipeline 32 is enabled to be in contact with the upper end of the rotor 27, the jet pump 22 can be reset by rotating the rocker again, at the moment, the gap between the rotor 27 and the pump head upper shell 22 is reduced, the reduced gap can enable the jet pipeline 32 to be fully in contact with the rotor 27, the arc-shaped working surface of the rotor 27 can squeeze the jet pipeline to deform, the upward-pulling key 31 is pushed to control the V-shaped groove at the bottom of the upward-pulling sliding block 30 to move up and down, and the clamping jet pipeline 32 is located at two ends of the pump body 2, so that the jet pipeline 32 is prevented from loosening and all movements during operation of the equipment.

In the operation process, a doctor firstly connects a liquid bottle 3 filled with medical liquid medicine with a jet pipeline 32 quickly, after the doctor holds a handle 1 to pierce a needle type spray head 13 into a calibrated point to be loosened, a direct current brush motor 4 is started, the medical liquid medicine is pumped under the common adjustment of a handle key 19 and a touch screen 5, and jet is realized through a subsequent pipeline and the needle type spray head 13.

Specifically, during operation, the medical liquid medicine is filled in the liquid containing bottle 3, a doctor holds the instrument handle 1, after a loosening site is determined under the assistance of the ultrasonic navigator, the needle type spray head 13 is penetrated into the skin to enable the spray tip to reach the jet flow position, the direct current brush motor 4 is started, the extension shaft of the direct current brush motor 4 rotates to drive the rotating shaft 26 to rotate, the rotating shaft 26 rotates to drive the roller disc 21 to rotate, and the rotor 27 arranged on the roller disc 21 rotates around the central line of the roller disc 21. The squeezing force generated by the arcuate working surface of the rotor 27 squeezes the jet tubing 32, creating a vacuum and drawing the pumped medical fluid into the jet tubing 32.

As the rotor 27 continues to move, the pumped medical fluid has entered the jet flow line 32, at which time the rotor 27 will again squeeze the jet flow line 32 and push the medical fluid out of the pump, and when the rotor 27 is separated from the jet flow line 32, the elastically deformed line portion will return to its original state, forming a negative pressure, thereby sucking new medical fluid. In this way, the rotor 27 inside the jet generating pump 2 is rotated by the rotation of the projecting shaft, which periodically presses and releases the jet pipe 32, thereby forming a continuous stable jet. The rotation speed of the motor can influence the frequency of periodically extruding and releasing the jet flow pipeline 32 on the circular arc surface of the rotor 27, so that the liquid medicine in the liquid containing bottle flows through the jet flow pipeline in the handle 1 in the control and use process of the jet flow pressure by setting the rotation speed of the motor, and the jet flow is completed after the liquid medicine reaches the needle type spray head 13 through the luer adapter 15, so that the needle type spray head 13 is penetrated into a calibrated myofascial loosening site through the auxiliary guidance of the ultrasonic navigator, and the purpose of myofascial loosening is realized.

In the application, after the direct current brush motor 4 is started, jet flow starts to be generated, the rotating speed of the direct current brushless motor 4 can be set through the display screen 5, and the frequency of the pipeline is extruded and released by the arc working surface of the rotor 27 in the jet flow generating pump 2 is controlled and regulated, so that the flow velocity of the jet flow in the pipeline is regulated, and the jet flow pressure control is realized; in addition, the button 19 in the regulating handle 1 acts to enable the semicircular flange in the middle of the flange slide 18 at the upper end of the slide 18 to squeeze the pipeline, so that the cross-sectional area of the pipeline can be controlled, and the jet pressure is controlled, so that the pressure regulation of medical liquid injection is realized, the display screen 5 on the upper shell 12 of the pump body can display the pressure gear and the working state of the equipment in real time, so that a doctor can observe and regulate conveniently, and the treatment accuracy and the operation convenience are improved.

In a preferred embodiment, the needle-type spray head 13 is designed into a flexible and rigid guide needle structure with the diameter less than or equal to 0.3mm, and the wound bleeding is less because the approach wound is less during the treatment process when the operator holds the handle 1 to perform the needle insertion operation. The water jet separation has the characteristic of selective separation, and can effectively loosen the myofascial tissue and meanwhile does not cause excessive damage to surrounding tissues by adjusting jet pressure.

The invention is a special operation tool for muscular and bone fascia release, after the ultra-minimally invasive needle type spray head reaches a calibrated lesion point, pressure injection is controlled by the key 19 on the handle 1 and the display screen on the shell together, an operation doctor can complete liquid medicine injection without adjusting a needle-executing gesture, the position of a needle head is not changed, the positioning accuracy of muscular and bone fascia release can be improved, and the problem of closed operation access is solved.

In the jet flow process of the system, except the disposable consumable part, the disposable consumable part is not in direct contact with the liquid medicine, the water flow cannot be directly contacted, only the disposable consumable part is needed to be replaced for each treatment, the requirements of aseptic operation and disposability can be met, and the requirements of safety and aseptic operation of clinical treatment can be effectively met.

While the fundamental and principal features of the invention and advantages of the invention have been shown and described, it will be apparent to those skilled in the art that the invention is not limited to the details of the foregoing exemplary embodiments, but may be embodied in other specific forms without departing from the spirit or essential characteristics thereof;

The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein.

Furthermore, it should be understood that although the present disclosure describes embodiments, not every embodiment is provided with a separate embodiment, and that this description is provided for clarity only, and that the disclosure is not limited to the embodiments described in detail below, and that the embodiments described in the examples may be combined as appropriate to form other embodiments that will be apparent to those skilled in the art.

Claims (10)

1. The rotor type myofascial loosening water jet power system is characterized by comprising a jet generating device, a jet pipeline, a handle, a needle type spray head and a liquid containing bottle; the needle type spray head is connected with the front end of the adapter, the rear end of the adapter is connected with the tail end of the jet pipeline, and the jet pipeline is a flexible hose; after the jet pipeline is matched with the adapter, the jet pipeline penetrates through the hollow cavity in the handle and then extends out of the tail end of the handle, and the handle comprises a mechanical adjusting device for controlling the internal pressure of the jet pipeline and the flow velocity of water flow by extruding the pipeline; the device is characterized in that a section of pipeline between the tail end and the front end of the jet pipeline is positioned in the jet generating device, a rotor mechanism for extruding the section of pipeline is arranged in the jet generating device and used for extruding the pipeline through a rotor to generate vacuum in the pipeline, pumping the traditional Chinese medicine liquid in the liquid containing bottle to suck the jet pipeline, and jet is realized through a needle type spray head.

2. The rotor-type myofascial opening water jet power system according to claim 1, wherein the mechanical adjusting device comprises a slider, a semicircular flange is arranged in the middle of the upper end of the slider, the jet pipeline in the handle passes through the inner surface of the handle opposite to the semicircular flange from the top of the semicircular flange, the bottom end of the slider is connected with a spring, and the upper end of the slider is connected with a key; the keys are assembled in key sliding grooves of the handle, and the sliding blocks are arranged in sliding block grooves of the handle; grooves with different depths are formed in the handle, and bosses matched with the grooves are formed on two sides of the lower part of the sliding block; when the boss is controlled to move by the key and is positioned in different grooves, the pipe section of the jet pipeline in the handle can be subjected to extrusion forces of different magnitudes due to the action of a spring at the bottom of the sliding block.

3. The system according to claim 2, wherein the grooves are spaced apart along the length of the handle and have a depth that increases or decreases sequentially from one end of the handle to the other.

4. The rotor-type myofascial and fascia-loosening water jet power system according to claim 2, wherein the handle comprises an upper handle shell and a lower handle shell, the key is installed in the upper handle shell, the slider and the spring are installed in the lower handle shell, and the upper handle shell and the lower handle shell are cooperatively positioned through a convex-concave structure.

5. The rotor-type myofascial loosening water jet power system as claimed in claim 4, wherein the front ends of the upper and lower handle shells are respectively provided with a semicircular external screw thread part, and are connected with the screw cap after being butted; after the jet pipeline is matched with the adapter, the jet pipeline penetrates through the threaded cover to be arranged in the hollow cavity in the handle, and the adapter is positioned in the hollow cavity in the handle.

6. The rotor-type myofascial and fascia-loosening water jet power system according to claim 1, wherein the jet pipeline, the handle, the needle-type spray head, the adapter and the liquid bottle are disposable consumables.

7. The trochanter myofascial opening water jet power system of claim 1, wherein the jet generating device comprises a jet generating pump and a motor; the jet flow generating pump comprises two oppositely spaced roller discs arranged in a pump head shell, a rotating shaft connected with the two roller discs, and at least two rotors positioned between the roller discs and rotationally arranged around the rotation center of the rotating shaft, wherein two ends of the rotating shaft are connected with a shaft hole of the pump head shell through bearings, the rotating shaft is connected with a motor, and a gap through which a jet flow pipeline passes is formed between the rotors and the pump head shell; when the rotor rotates, the jet pipeline contacted with the rotor can be extruded to generate vacuum in the pipeline.

8. The rotor-type myofascial loosening water jet power system as claimed in claim 7, wherein the pump head housing comprises a pump head upper housing which can be lifted, a pump head lower housing is arranged at the lower end of the pump head upper housing, the pump head upper housing and the pump head lower housing form a pump head front housing, and the pump head front housing and the pump head rear housing form the pump head housing together; the eccentric wheel is arranged on the pump head, the front end of the eccentric wheel is provided with a cylinder, the cylinder penetrates through the rear shell of the pump head to be connected with the upper shell of the pump head, the eccentric wheel is connected with the rocker, the eccentric wheel can be controlled to rotate by rotating the rocker, and the lifting of the upper shell of the pump head is realized by rotating and driving the eccentric wheel.

9. The rotor type myofascial and fascia loosening water jet power system according to claim 8, wherein the pump head upper shell is provided with a slot, a pull-up sliding block capable of moving up and down is arranged on the pump head upper shell, grooves are symmetrically arranged on two sides of the bottom of the pump head upper shell, a pull-up key is arranged in the grooves and can slide up and down in the grooves, and the pull-up key is symmetrically arranged on the pump head upper shell after being fixedly connected with the pull-up sliding block; the pull-up key is pushed to control the pull-up sliding block to slide up and down, and the V-shaped groove at the bottom of the pull-up key is used for pressing the clamping pressure of the jet pipeline at the two ends of the pipeline section extruded by the rotor inside the pump head, so that the jet pipeline is positioned and fastened.

10. The rotor-type myofascial opening water jet power system of claim 7, comprising an electrical control device comprising a housing comprising an upper pump housing and a lower pump housing; the motor extension shaft penetrates through the lower shell of the pump body and is connected with a rotating shaft in the pump head; the motor is connected with the motor controller, the motor controller is connected with the fan and the display screen, and is connected with an external communication interface and a power interface, the fan is used for radiating the direct current motor, the power interface is used for being connected with an external power supply, and the communication interface is used for communicating with external equipment; the motor, the motor controller and the fan are all arranged in corresponding positioning grooves of the shell; a display screen is arranged on the upper shell of the pump body so as to carry out pressure regulation operation and display preset numerical values in real time.