WO2022237219A1 - Ozone autologous blood retransfusion therapeutic apparatus - Google Patents

Abstract

An ozone autologous blood retransfusion therapeutic apparatus, comprising a blood bag (15) capable of accommodating drawn blood, an ozone gas generation and delivery mechanism capable of delivering required medical ozone to the blood bag (15), and a blood drawing and delivery mechanism capable of realizing blood drawing and delivery. A vibration mechanism is provided on the blood bag (15), ozone gas is sent into the blood bag (15) by means of the ozone gas generation and delivery mechanism, and blood to be mixed is sent into the blood bag (15) by means of the blood drawing and delivery mechanism; the blood in the blood bag (15) and the medical ozone entering the blood bag (15) can be uniformly mixed in vibration by the vibration mechanism, and the blood mixed with the medical ozone in the blood bag (15) can be filtered and then delivered to the body by the blood drawing and delivery mechanism. The therapeutic apparatus can effectively realize uniform mixing of medical ozone and drawn blood, and the whole process is in a completely closed state, thereby reducing the contact with the outside and improving the safety and reliability of treatment.

Description

Oxygen Autologous Blood Return Therapy Apparatus technical field

The invention relates to a therapeutic instrument, in particular to an ozone autologous blood return therapeutic instrument.

Background technique

Oxygen autohemotherapy is to draw a certain volume of venous blood from the patient by the medical staff, add medical ozone gas (O ₃ ) to mix it evenly, and then infuse it back into the patient's body. Ozone can activate the body's immunity to a certain extent and enhance the body's ability to resist infection. Oxygen autologous blood therapy is a characteristic treatment method for the "three high" population, metabolic diseases, immune diseases, chronic pain, sleep disorders, sub-health, etc.

In the current ozone autologous blood treatment, the patient's blood is taken out of the body, ozone gas is injected into the blood taken out of the body for effective mixing, and after mixing, the blood is injected back into the patient's body. In such a treatment process, there are problems of blood contamination, misuse and secondary trauma. Moreover, due to the slow return of blood, part of the blood often coagulates and adheres to the wall of the blood storage bag and its pipeline, and the temperature of the blood in the blood storage bag decreases due to long operation time. In addition, in the current ozone therapy, manual shaking is often used between the extracted blood and medical ozone, resulting in poor mixing effect and difficult to meet the actual use requirements.

Contents of the invention

The purpose of the present invention is to overcome the deficiencies in the prior art, and provide an ozone autologous blood return therapeutic instrument, which can effectively realize the mixing between medical ozone and extracted blood, and the whole process is in a fully closed state, reducing contact with the outside world. Contact, improve the safety and reliability of treatment.

According to the technical solution provided by the present invention, the ozone autologous blood return therapeutic apparatus includes a blood storage bag capable of accommodating and drawing blood, an ozone generation and delivery mechanism capable of delivering required medical ozone to the blood storage bag, and a A blood extraction and delivery mechanism for realizing blood extraction and delivery.

A vibrating mechanism is set on the blood storage bag, and the ozone gas is sent into the blood storage bag through the ozone generation and delivery mechanism, and the blood to be mixed is sent into the blood storage bag through the blood extraction and delivery mechanism; the vibration mechanism can The blood in the blood storage bag and the medical ozone entering the blood storage bag are evenly mixed in vibration, and the uniformly mixed blood in the blood storage bag can be filtered and delivered to the body through the blood pumping and conveying mechanism.

One or more vibrating mechanisms are arranged on the blood storage bag, and the vibrating mechanism includes a vibrating body and vibrating pieces symmetrically distributed on the vibrating body. Correspondingly, the vibrating piece is driven to vibrate simultaneously by the vibration generating body energy.

The ozone generating and conveying mechanism includes an ozone generating part and a gas conveying part adapted to connect with the ozone generating part, and the gas conveying part includes a trioxygen conveying pipe and a The gas transmission power mechanism adapted to the tube, the first end of the trioxygen gas delivery tube is connected and communicated with the ozone gas generating part, the second end of the trioxygen gas delivery tube is connected and communicated with the blood storage bag, and the gas transmission power mechanism It can control the flow rate of the ozone generated by the ozone generating part into the blood storage bag.

The gas conveying power mechanism includes a peristaltic pump, and a water-blocking and ventilating part of the gas conveying pipe that can prevent the blood in the blood storage bag from entering the ozone generating part is provided at the second end of the ozone conveying pipe.

The ozone gas generating part includes a gas generation storage cabinet and an ozone generator stored in the gas generation storage cabinet, and the ozone generator can be adapted and connected with the gas delivery connector on the gas generation storage cabinet. The first end of the oxygen gas delivery pipe can be connected and communicated with the ozone generator in the gas generation storage cabinet through the gas delivery connector.

A vertically distributed transfusion stand is arranged on the gas generation storage cabinet, and the blood storage bag can be hung on the transfusion stand; the gas delivery connectors on the gas generation storage cabinet include luer connectors, pagoda connectors and/or joint pipes.

The blood extraction and delivery mechanism includes a puncture indwelling needle for puncture, a blood delivery tube adapted to connect with the puncture indwelling needle, and a blood delivery power mechanism adapted to the blood delivery tube, and the blood delivery tube It is connected with the bottom of the blood storage bag; through the cooperation of the blood delivery power mechanism and the blood delivery tube, the blood extracted by the puncture indwelling needle can be sent into the blood storage bag or the blood mixed uniformly in the blood storage bag can be drawn out and sent into the puncture Inside the needle.

It also includes a constant temperature heating mechanism capable of heating the blood flowing through the blood delivery tube, and the blood delivery power mechanism includes a peristaltic pump.

The blood delivery pipe body includes a blood delivery connection main pipe, the first end of the blood delivery connection main pipe is connected and communicated with the blood storage bag, and the second end of the blood delivery connection main pipe is connected with the blood delivery inlet pipe, The blood delivery return pipe is connected and communicated, the blood delivery inlet pipe, the blood delivery return pipe are connected with the puncture indwelling needle;

It also includes a liquid return filter adapted to the blood delivery return pipe. When the blood is sent into the blood storage bag through the blood delivery power mechanism, the blood sequentially passes through the puncture indwelling needle, the blood delivery inlet tube, the blood delivery selection valve, the blood After the delivery connection main pipe enters the blood storage bag; when the blood in the blood storage bag is pumped out by the blood delivery power mechanism, the blood in the blood storage bag passes through the blood delivery connection main pipe and the blood delivery selection valve in sequence, and then enters the blood delivery return pipe. And enter the puncture indwelling needle after passing through the liquid return filter.

A blood-transmitting water-blocking ventilation pipe is arranged on the blood-transporting connection main pipe, and the liquid return filter includes a filter upper cover and a filter lower cover adapted to the filter upper cover. The filter upper pipe head is arranged on the cover body, and the filter lower pipe head is arranged on the filter lower cover body; the filter check valve and the filter membrane for filtering are arranged in the filter lower cover body, and the filter upper pipe head and the filter lower pipe head are arranged. The pipe heads communicate with each other.

The advantages of the present invention are that the blood drawn by the blood extraction and delivery mechanism can be stored in the blood storage bag, and after the ozone generation and delivery mechanism sends the medical ozone into the blood storage bag, the vibration mechanism on the blood storage bag can realize the production of ozone gas. The vibration between the blood and the blood is uniformly mixed, and after uniform mixing, it is returned to the body by the blood pumping and conveying mechanism; the blood conveying power mechanism in the blood pumping and conveying mechanism and the gas conveying power mechanism in the ozone generation and conveying mechanism can be used The speed control in blood delivery and the flow rate control of trioxygen delivery are respectively realized. The blood transported by the blood extraction and delivery mechanism can be heated through the constant temperature heating mechanism. The whole process is fully closed to avoid contact with the outside world and improve the safety of treatment. and reliability.

Description of drawings

Fig. 1 is a perspective view of the present invention.

Fig. 2 is a schematic diagram of the storage cabinet door in an open state according to the present invention.

Fig. 3 is a structural schematic diagram of the present invention.

Fig. 4 is a schematic diagram of the blood delivery tube of the present invention.

Fig. 5 is a cross-sectional view of the liquid return filter of the present invention.

Fig. 6 is a schematic diagram of the filter membrane of the present invention and the housing under the filter.

FIG. 7 is a schematic diagram of the filter membrane separated from the filter lower cover in FIG. 6 .

Fig. 8 is a schematic diagram of setting a blood clot filter in the fluid storage bag according to the present invention.

Explanation of reference signs: 1-gas generating storage cabinet, 2-storage cabinet door, 3-side cooling area, 4-storage cabinet wheel, 5-drawer handle, 6-drawer, 7-Luer connector, 8-pagoda connector , 9-joint pipe, 10-ozone gas delivery tube, 11-gas delivery power mechanism, 12-infusion stand, 13-hanging rod, 14-hanging rod connector, 15-blood storage bag, 16-blood storage bag end line , 17-blood delivery connection main pipe, 18-blood delivery power mechanism, 19-constant temperature heating mechanism, 20-vibration plate, 21-blood delivery selection valve, 23-blood delivery return pipe, 24-liquid return filter, 25- Tube body clip, 26-indwelling needle connector, 27-puncture indwelling needle, 28-oxygen bottle, 29-ozone generator, 30-display screen, 31-button group, 32-blood transport water blocking vent tube, 33- Vibration generating body, 34-cart armrest, 35-height adjustment knob, 36-back cooling area, 37-indwelling needle tube, 38-filter upper cover, 39-filter lower cover, 40-filter upper Tube head, 41-filter lower tube head, 42-filter membrane, 43-filter support rod, 44-filter one-way valve, 45-filter valve seat, 46-water blocking and ventilating part of gas delivery tube, 47-blood storage bag Inner filter screen and 48-blood delivery connection main pipe joint.

Detailed ways

The present invention will be further described below in conjunction with specific drawings and embodiments.

As shown in Fig. 1, Fig. 2 and Fig. 3: In order to effectively realize the mixing between medical ozone and the extracted blood, reduce the contact with the outside world, and improve the safety and reliability of the treatment, the present invention includes a device that can accommodate the extracted blood The blood storage bag 15, the ozone generation and delivery mechanism capable of delivering required medical ozone to the blood storage bag 15, and the blood extraction and delivery mechanism capable of realizing blood extraction and delivery;

A vibrating mechanism is set on the blood storage bag 15, and the ozone gas is sent into the blood storage bag 15 through the ozone generation and delivery mechanism, and the blood to be mixed is sent into the blood storage bag 15 through the blood extraction delivery mechanism; The vibration mechanism can evenly mix the blood in the blood storage bag 15 with the medical ozone entering the blood storage bag 15 in vibration, and the uniformly mixed blood in the blood storage bag 15 can be filtered and delivered to the body through the blood pumping and delivery mechanism .

Specifically, the blood storage bag 15 needs to be made of materials that meet medical standards. The blood storage bag 15 is bag-shaped and can be made of flexible medical materials. The specific size of the blood storage bag 15 can be selected according to actual needs. The medical ozone gas can be sent into the blood storage bag 15 through the ozone generation and delivery mechanism, and the blood extracted from the body can be delivered into the blood storage bag 15 through the blood extraction delivery mechanism.

In the embodiment of the present invention, a vibration mechanism is provided on the blood storage bag 15, and the vibration mechanism can realize the vibration of the blood in the blood storage bag 15. During the vibration process, the vibration between the blood in the blood storage bag 15 and the ozone can be realized After uniform mixing, the blood in the blood storage bag 15 is drawn out by the blood pumping and transporting mechanism and transported to the body. During all the processes of blood extraction, mixing of blood with ozone gas, and delivery of the mixed blood back into the body, all processes are in a closed environment, without contact with the outside world, avoiding pollution caused by contact with the outside world, effectively improving data security. Safety and reliability.

Further, one or more vibrating mechanisms are provided on the blood storage bag 15, and the vibrating mechanism includes a vibrating body 33 and vibrating pieces 20 symmetrically distributed on the vibrating body 33, and the vibrating pieces in the vibrating mechanism 20 corresponds to the two sides of the blood storage bag 15, and the vibrating piece 20 can be driven to vibrate simultaneously by the vibration generator 33.

In the embodiment of the present invention, one or more vibrating mechanisms can be set on the blood storage bag 15, the number of the vibrating mechanisms and the positions of the vibrating mechanisms on the blood storage bag 15 can be selected according to needs, so as to realize the vibration control in the blood storage bag 15. The effective vibration of the blood, and then realize the uniform mixing of blood and ozone. After the vibrating mechanism is placed on the blood storage bag 15, the vibrating mechanism can maintain the working state, that is, keep vibrating the blood in the blood storage bag 15. Of course, the vibrating mechanism can also be kept in the working state according to the required time, which can be selected according to the needs. .

During specific implementation, there is a vibration source that can generate vibration in the vibration generating body 33, and the vibration plate 20 is arranged on both sides of the vibration generating body 33, and the vibration generating body 33 can be connected with the side of the blood storage bag 15, so that the vibration can be The sheet 20 corresponds to the two sides of the blood storage bag 15 . The vibration generated by the vibration generator 33 can be transmitted to the blood storage bag 15 through the vibrating plate 20 , so as to effectively vibrate the blood in the blood storage bag 15 . When one or more vibration mechanisms vibrate at the same time, the disorder and non-direction of the vibration of one or more vibration mechanisms can be used to uniformly mix blood and ozone. The vibration source in the vibration generating body 33 can adopt the existing commonly used forms, such as vibration motors, etc., which can be selected according to the needs, and will not be repeated here. By cooperating with the blood storage bag 15 by the vibration mechanism, the convenience of uniform mixing of blood and ozone in the blood storage bag 15 can be improved and the cost can be reduced.

Further, the ozone generation and delivery mechanism includes an ozone generation part and a gas delivery part that is fitted and connected with the ozone generation part, and the gas delivery part includes a ozone delivery tube 10 and is connected to the The gas delivery power mechanism 11 adapted to the ozone gas delivery tube 10, the first end of the ozone gas delivery tube 10 is connected and communicated with the ozone gas generating part, and the second end of the ozone gas delivery tube 10 is connected to the blood storage bag 15 Connected and communicated, the flow rate of the ozone gas generated by the ozone gas generating part into the blood storage bag 15 can be controlled through the gas delivery power mechanism 11 .

In the embodiment of the present invention, the required trioxygen gas can be obtained through the trioxygen gas generating part, and the specific situation of the trioxygen gas can be selected according to needs, which are well known to those skilled in the art, and will not be repeated here. The trioxygen gas obtained by the trioxygen gas generating part can be sent into the blood storage bag 15 through the gas delivery part. In order to control the process of gas delivery, the gas delivery power mechanism 11 cooperates with the trioxygen gas delivery pipe 10. During specific implementation, the gas delivery power mechanism 11 can use a peristaltic pump, or other methods that can provide trioxygen gas delivery power and can The form of controlling the flow rate can be specifically selected according to needs, and will not be repeated here. When the gas delivery power mechanism 11 adopts a peristaltic pump, the gas delivery power mechanism 11 is correspondingly connected with the ozone gas delivery tube 10, and when the working state of the gas delivery power mechanism 11 is controlled, it is possible to prevent the ozone gas from entering the blood storage bag 15 Effective control of flow rate, etc.

Further, at the second end of the ozone gas delivery tube 10, a gas delivery tube water-blocking and ventilating part 46 capable of preventing the blood in the blood storage bag 15 from entering the ozone gas generating part is provided. In the embodiment of the present invention, the water-blocking and ventilating part 46 for gas delivery can specifically adopt an existing commonly used water-blocking and ventilating film, and the water-blocking and ventilating part 46 of the gas delivery tube can prevent the blood in the blood storage bag 15 from overflowing and then be transported by trioxygen gas The tube 10 enters into the ozone generating part to improve the reliability of the ozone generating part.

Further, the ozone generating unit includes a gas generation storage cabinet 1 and an ozone generator 29 stored in the gas generation storage cabinet 1, and the ozone generator 29 can be connected with the gas generation storage cabinet 1. The gas delivery connector is adapted and connected, and the first end of the ozone gas delivery pipe 10 can be connected and communicated with the ozone generator 29 in the gas generation storage cabinet 1 through the gas delivery connector.

In the embodiment of the present invention, the gas generating storage cabinet 1 is in the shape of a rectangular cabinet, and the specific shape can be selected according to needs. Oxygen cylinder 28 is set in the gas generation storage cabinet 1, and the specific quantity of oxygen cylinder 28 can be selected according to needs, and oxygen cylinder 28 can adopt existing commonly used form specifically, is as the criterion to satisfying the storage to oxygen. The oxygen supply to the ozone generator 29 can be realized by the oxygen bottle 28, and the ozone generator 29 utilizes the oxygen energy to prepare the required medical ozone, and is connected and communicated with the ozone gas delivery pipe 10 through the gas delivery connector, and then The ozone gas generated by the ozone generator 29 can enter the ozone gas delivery tube 10 under the action of the gas delivery power mechanism 11 , and finally be delivered into the blood storage bag 15 .

The bottom of the gas generation storage cabinet 1 is provided with a number of storage cabinet wheels 4, through which the entire gas generation storage cabinet 1 can be easily moved. After the ozone generator 29 is set in the gas generation storage cabinet 1, the side heat dissipation area 3 is set at the bottom of the gas generation storage cabinet 1 side, and the back heat dissipation area 36 is set at the back of the gas generation storage cabinet 1 to dissipate heat from the sides. Area 3 and the back heat dissipation area 36 can all adopt the existing commonly used heat dissipation forms, such as direct heat dissipation forms such as grilles, which can be selected according to needs, and will not be repeated here.

For ease of use, a storage cabinet door 2 is provided on the gas generation storage cabinet 1, the storage cabinet door 2 is hinged on the gas generation storage cabinet 1, and the storage cabinet door 2 adopts an openable form, that is, the storage cabinet door 2 can be opened Or close the gas generation storage cabinet 1. A drawer 6 is also arranged above the storage cabinet door 2, and a drawer handle 5 is provided on the drawer 6. The drawer 6, the storage cabinet door 2 and the gas generation storage cabinet 1 can all adopt existing commonly used matching forms, specifically for those skilled in the art. It is well known and will not be repeated here. The back side of the gas generation storage cabinet 1 is also provided with a trolley handrail 34, through which the entire gas generation storage cabinet 1 can be pushed conveniently. Display screen 30 and button group 31 are also arranged on the upper end face of gas generation storage cabinet 1, some required information can be displayed by display screen 30, the setting of working parameters can be carried out by button group 31, display screen 30 can adopt existing Commonly used forms, such as using a touch screen, can be selected according to needs.

In the embodiment of the present invention, in order to comprehensively control the treatment process, a treatment controller is also provided in the gas generation storage cabinet 1. The treatment controller can be an existing commonly used microprocessor, such as a single-chip microcomputer, etc., specifically according to It needs to be selected, so I won't go into details here. The treatment controller is electrically connected with the display screen 30, the button group 31, the ozone generator 29 and the gas delivery power mechanism 11, and the operation of the gas delivery power mechanism 11 can be set in the treatment controller through the display screen 30 and/or the button group 31. The state, such as setting the flow rate and concentration of the trioxygen gas, and the specific process of controlling the gas delivery power mechanism 11 can adopt the existing commonly used forms, which will not be repeated here.

During specific implementation, it is also possible to monitor the blood flow and the total amount of blood entering the blood storage bag 15 and the gas volume and gas concentration of medical ozone entering the blood storage bag 15, the blood flow and the total amount of blood entering the blood storage bag 15 It can be controlled by the blood extraction and delivery mechanism, and the gas volume and gas concentration entering the blood storage bag 15 can be controlled by the ozone generation and delivery mechanism. Specifically, existing commonly used control forms can be adopted, which are well known to those skilled in the art. I won't repeat them here.

During specific work, the mixing ratio can be preset in the treatment controller, and the specific mixing ratio can be selected according to needs, such as when the total amount of blood in the blood storage bag 15 is 100ml, the gas that enters the medical ozone in the blood storage bag 15 The optimum concentration is 20%; the specific conditions of the blood volume, gas volume and gas concentration in the blood storage bag 15 can be selected according to needs, and will not be repeated here. Of course, during specific use, the treatment controller can also monitor the blood flow, total blood volume, gas volume and gas concentration in the blood storage bag 15 in real time, and display and output the blood flow, total blood volume, and gas concentration in the current state through the display screen 30. Gas volume and gas concentration.

During specific implementation, the volume of blood entering the blood storage bag 15 and the gas volume of medical ozone can be obtained through corresponding sensor sampling. And enter the gas amount of the medical ozone in the blood storage bag 15. Of course, a liquid level gauge can also be set in the blood storage bag 15, and the blood volume in the blood storage bag 15 can be monitored by using the liquid level gauge. The liquid level gauge is electrically connected with the treatment controller, and the treatment controller can display the output through the display screen Liquid level value monitored by a level gauge.

Further, a vertically distributed transfusion stand 12 is set on the gas generation storage cabinet 1, and the blood storage bag 15 can be hung on the transfusion stand 12; the gas delivery connector on the gas generation storage cabinet 1 includes a Luer Joint 7, pagoda joint 8 and/or joint pipe 9.

In the embodiment of the present invention, the transfusion rack 12 is vertically distributed on the back side of the gas generation storage cabinet 1, and the transfusion rack 12 can adopt a telescopic form. At this time, a height adjustment knob 35 is set on the transfusion rack 12. The manner of realizing the height adjustment through the height adjustment knob 35 is consistent with the prior art, which is well known to those skilled in the art and will not be repeated here. A hanging rod connector 14 is arranged on the upper end of the infusion stand 12, a plurality of hanging rods 13 are arranged on the hanging rod connector 14, a blood storage bag end line 16 is arranged at the end of the blood storage bag 15, and the blood storage bag 15 passes through the blood storage bag end line 16 can be hung on a hanging rod 13, and after the blood storage bag 15 is hung on the hanging rod 13, it can form the form of transfusion.

The specific forms of the Luer connector 7 and the pagoda connector 8 are consistent with the prior art, and are well known to those skilled in the art. According to the specific form of the first end of the trioxygen gas delivery tube 10, it can be selected to be connected with the Luer connector 7, the pagoda connector 8 or the connector tube 9, so that the convenience of selection can be provided. Joint pipe 9 is a common joint form. Of course, other required joint forms can also be provided on the gas generating storage cabinet 1, which can be selected and determined according to needs, and will not be repeated here.

Further, the blood extraction and delivery mechanism includes a puncture indwelling needle 27 for puncturing, a blood delivery tube adapted to connect with the puncture indwelling needle 27, and a blood delivery power mechanism 18 adapted to the blood delivery tube, The blood delivery tube is connected to the bottom of the blood storage bag 15; through the cooperation of the blood delivery power mechanism 18 and the blood delivery tube, the blood extracted by the puncture indwelling needle 27 can be sent into the blood storage bag 15 or the blood storage bag Send in the puncture indwelling needle 27 after the blood that mixes homogeneously in 15 is drawn out.

In the embodiment of the present invention, the puncture and indwelling needle 27 can adopt the existing commonly used form. The puncture and indwelling needle 27 can be used to realize the required blood vessel puncture, and can be indwelled after the puncture. The puncture and indwelling needle 27 is used to perform specific puncture and indwelling processes Consistent with the prior art, the details are well known to those skilled in the art, and will not be repeated here. The puncture indwelling needle 27 can be connected and communicated with the blood storage bag 15 through the blood delivery tube body, wherein the blood delivery tube body can be connected with the bottom of the blood storage bag 15, and the direction of blood delivery through the blood delivery tube body can be controlled by the blood delivery power mechanism 18 , that is, it can be realized that the blood is drawn into the blood storage bag 15 by puncturing the indwelling needle 27, or the blood mixed with the oxygen gas in the blood storage bag 15 is injected back into the body.

During specific implementation, it also includes a constant temperature heating mechanism 19 capable of heating the blood flowing through the blood delivery tube, and the blood delivery power mechanism 18 includes a peristaltic pump. In the embodiment of the present invention, the blood in the blood delivery tube can be heated at a constant temperature by the constant temperature heating mechanism 19. The temperature of the blood heated by the constant temperature heating mechanism 19 should be close to the normal body temperature of the human body. Heating and other forms can be used as long as the blood in the blood delivery tube can be heated stably, and can be selected according to needs, and will not be repeated here. During specific implementation, the blood delivery power mechanism 18 can adopt an existing commonly used peristaltic pump, and use the peristaltic ability and direction of peristalsis of the peristaltic pump to control the delivery direction and specific delivery speed of blood through the blood delivery tube.

Both the constant temperature heating mechanism 19 and the blood delivery power mechanism 18 need to be electrically connected to the treatment controller, that is, the working status of the constant temperature heating mechanism 19 and the blood delivery power mechanism 18 can be controlled by the treatment controller, and the constant temperature heating mechanism 19, blood delivery The control of the working state of the power mechanism 18 is consistent with the prior art, and can be selected according to needs, and will not be repeated here.

As shown in Fig. 1, Fig. 2, Fig. 3 and Fig. 4, the blood delivery tube body includes a blood delivery connection main pipe 17, and the first end of the blood delivery connection main pipe 17 is connected and communicated with the blood storage bag 15, and the blood delivery The second end of the connection main pipe 17 is connected and communicated with the blood delivery inlet tube 22 and the blood delivery return tube 23 through the blood delivery selection valve 21, and the blood delivery inlet tube 22, the blood delivery return tube 23 are connected with the puncture indwelling needle 27 Pass;

It also includes a liquid return filter 24 adapted to the blood delivery return pipe 23. When the blood is sent into the blood storage bag 15 through the blood delivery power mechanism 18, the blood sequentially passes through the puncture indwelling needle 27, the blood delivery inlet tube 22, The blood delivery selection valve 21 and the blood delivery connection main pipe 17 enter the blood storage bag 15; when the blood in the blood storage bag 15 is drawn out by the blood delivery power mechanism 18, the blood in the blood storage bag 15 passes through the blood delivery connection main pipe 17 in sequence 1. After the blood delivery selection valve 21 enters the blood delivery return pipe 23 , and enters the puncture indwelling needle 27 after passing through the return return filter 24 .

In the embodiment of the present invention, the first end of the blood delivery connection main pipe 17 is connected and communicated with the blood storage bag 15, wherein the connection between the blood delivery connection main pipe 17 and the blood storage bag 15 is located at the lower part of the blood storage bag 15. The continuation page transport selection valve 21 can be a medical three-way valve, and the blood transport connection main pipe 17 can be connected and communicated with the blood transport liquid inlet pipe 22 and the blood transport liquid return pipe 23 through the blood transport selection valve 21. During work, the blood transport connection main pipe 17 only communicates with the blood delivery inlet pipe 22 or the blood delivery return pipe 23 through the blood delivery selection valve 21 . The blood delivery inlet tube 22 and the blood delivery return tube 23 can communicate with the puncture indwelling needle 27 .

When it is necessary to extract the blood in the body and send it into the blood storage bag 15, when the blood is sent into the blood storage bag 15 through the blood delivery power mechanism 18, the blood passes through the puncture indwelling needle 27, the blood delivery liquid inlet tube 22, the blood The delivery selection valve 21 and the blood delivery connection main pipe 17 enter the blood storage bag 15 . When the extracted blood is mixed with ozone gas in the blood storage bag 15, when the blood in the blood storage bag 15 is drawn out by the blood delivery power mechanism 18, the blood in the blood storage bag 15 passes through the blood delivery connection main pipe 17, the blood After the delivery selection valve 21, the blood enters the liquid return pipe 23 and enters the puncture indwelling needle 27 after passing through the return liquid filter 24. The gravitational potential energy when the blood storage bag 15 is suspended can make the blood return to the body.

During specific implementation, the puncture indwelling needle 27 is connected and communicated with the indwelling needle connecting tube 37 , and the indwelling needle connecting tube 37 is connected and communicated with the blood delivery inlet tube 22 and the blood delivery return tube 23 through the indwelling needle connector 26 . In addition, a blood-transporting water-blocking ventilating tube 32 is provided on the blood-transporting connection main pipe 17, and a water-blocking ventilating film can be arranged in the blood-transporting water-blocking ventilating tube 32, and the blood-transporting water-blocking ventilating tube 32 is adjacent to the blood transporting connection main pipe 17. The joint with the blood storage bag 15 can discharge the gas in the blood in the blood delivery connection main pipe 17 through the blood delivery water blocking ventilation tube 32 without affecting the normal delivery of blood.

In the embodiment of the present invention, a tube body clamp 25 can be provided on the blood delivery return tube 23, and the tube body clamp 25 can specifically adopt an existing commonly used form, and the blood delivery return tube 23 can be clamped by the tube body clamp 25 , the tube body clip 25 is located between the blood delivery selection valve 21 and the indwelling needle connector 26. When the tube body clip 25 clamps the blood delivery return tube 23, the blood delivery selection valve 21 cannot continuously deliver the blood back to the liquid return tube 23 The blood is transported inside, and the blood cannot be transported to the direction of the blood transport selection valve 21 through the indwelling needle connector 26. The tube clip 25 and the blood delivery return tube 23 can be detachably connected, that is, when the blood delivery return tube 23 needs to be clamped, the tube clip 25 is used to clamp the blood delivery return tube 23 .

As shown in FIG. 8 , it is a schematic diagram of setting a blood clot filter in the blood storage bag 15, wherein, the blood clot filter has at least two pieces of blood storage bag inner filter 47 adapted to the blood storage bag 15, and two pieces of blood storage bag The outer edge of the filter screen 47 in the bag is fixed to the inner wall of the blood storage bag 15, and the filter screens 47 in the blood storage bag are parallel to each other. The filter specification of the filter 47 in the blood storage bag can be selected according to the needs, and the filter specification is based on the ability to filter blood clots, which is well known to those skilled in the art and will not be repeated here.

The end of the blood delivery connection main pipe 17 connected to the blood storage bag 15 can be provided with a blood delivery connection main pipe joint 48, and the blood delivery connection main pipe joint 48 extends into the blood storage bag 15; At 47 o'clock, the filter screens 47 in the blood storage bag are also distributed in a stacked form, and the liquid outlet end of the blood delivery connection main pipe joint 48 is located above the filter screen 47 in the uppermost blood storage bag, so that blood clots can be effectively filtered . Of course, according to actual needs, the blood storage bag inner filter 47 in the blood storage bag 15 can be selected with different filtering specifications and sizes, and can be specifically selected according to needs.

As shown in Figure 5, Figure 6 and Figure 7, it is a specific schematic diagram of the liquid return filter 24 of the present invention, wherein the liquid return filter 24 includes a filter upper cover 38 and is adapted to the filter upper cover 38 filter lower cover body 39, the filter upper cover body 38 and the filter lower cover body 39 are funnel-shaped, after the filter upper cover body 38 and the filter lower cover body 39 are fitted and connected, a relatively In the enclosed space, the filter upper cover body 38 and the filter lower cover body 39 are coaxially distributed. On the filter upper cover body 38, the filter upper pipe head 40 is set, and the filter lower pipe head 41 is set on the filter lower cover body 39, and the filter upper pipe head 40 passes through the filter upper cover body 38, the filter lower cover The body 39 can communicate with the filter lower pipe head 41, generally, the filter upper pipe head 40 and the filter lower pipe head 41 are also coaxially distributed. The upper filter head 40 and the lower filter head 41 can be fitted and communicated with the blood delivery and return pipe 23 .

A filter valve seat 45 is arranged in the filter lower cover body 39 , and the filter valve seat 45 is supported in the filter lower cover body 39 by several filter support rods 43 . The filter check valve 44 can be installed by the filter valve seat 45, and the filter membrane 42 can be supported by the filter support rod 43, the filter valve seat 45 and the filter check valve 44 can pass through the filter membrane 42, and the filter membrane 42 can adopt In the existing common form, the blood reinjected into the body can be filtered through the filter membrane 42 .

In the embodiment of the present invention, the filter one-way valve 44 is made of medical silica gel, etc., and the filter one-way valve 44 is in the shape of a duckbill. Of course, other shapes can also be used, which can be selected according to needs. Among Fig. 6, filter one-way valve 44 is positioned at the part above filter membrane 42 and has slit, can pass through slit to the blood that flows from filter lower pipe head 41 to filter upper pipe head 40, and when blood flows from filter upper pipe head When 40 flows to the lower tube head 41 of the filter, the pressure of the blood makes the filter one-way valve 44 contract inwardly, and the blood cannot pass through the filter one-way valve 44 .

Therefore, the filter one-way valve 44 allows the liquid to flow through from the lower filter head 41 to the upper filter head 40 , and can block the flow of liquid from the upper filter head 40 to the lower filter head 41 . When the filter check valve 44 is adopted, when the blood delivery return pipe 23 is not clamped by the tube clamp 25, some blood may enter the blood delivery return pipe 23. The blood in the tube 23 cannot pass through the blood delivery selector valve 21 after entering the blood delivery return tube 23, and the blood entering the blood delivery return tube 23 can flow back into the puncture indwelling needle 27 again after being filtered by the filter membrane 42. The filter check valve 44 can automatically realize the one-way filter of blood.

During normal use, blood flows in from the filter upper tube head 40 on the filter upper cover body 38, and the blood entering the liquid return filter 24 cannot pass through the filter check valve 44, but can only pass through the filter check valve 44 outer circle. The filter membrane 42, after being filtered by the filter membrane 42, flows out from the filter lower tube head 41, and then flows to the puncture indwelling needle 27, that is, the blood entering the blood return pipe 23 is filtered by the filter membrane 42 and then flows to the puncture needle. Indwelling needle 27.

Claims (10)

1. An ozone autologous blood return therapeutic instrument, characterized in that it includes a blood storage bag (15) capable of accommodating drawn blood, an ozone generation and delivery mechanism capable of delivering required medical ozone to the blood storage bag (15), and A blood extraction and delivery mechanism that can realize blood extraction and delivery;

   A vibrating mechanism is provided on the blood storage bag (15), and the ozone gas is sent into the blood storage bag (15) through the ozone generation and delivery mechanism, and the blood to be mixed is sent into the blood storage bag through the blood extraction delivery mechanism (15); through the vibration mechanism, the blood in the blood storage bag (15) can be evenly mixed with the medical ozone entering the blood storage bag (15) in vibration, and the blood storage bag (15) can be drawn by the blood delivery mechanism. ) and the blood evenly mixed with medical ozone is filtered and delivered to the body.
2. The ozone autologous blood return therapeutic apparatus according to claim 1, characterized in that: one or more vibration mechanisms are set on the blood storage bag (15), and the vibration mechanisms include vibration generating bodies (33) and symmetrically distributed on the blood storage bag (15). The vibrating plate (20) on the vibration generating body (33), the vibrating plate (20) in the vibration mechanism corresponds to the two sides of the blood storage bag (15), and the vibrating plate (20) can be driven by the vibration generating body (33) 20) Simultaneous vibration.
3. The ozone autogenous blood return therapeutic instrument according to claim 1, characterized in that: the ozone generating and conveying mechanism includes an ozone generating part and a gas conveying part adapted to connect with the ozone generating part, so The gas conveying part comprises a trioxygen gas conveying pipe (10) and a gas conveying power mechanism (11) adapted to the trioxygen gas conveying pipe (10), the first end of the trioxygen gas conveying pipe (10) is connected to the three The oxygen gas generating part is connected and communicated, the second end of the trioxygen gas delivery tube (10) is connected and communicated with the blood storage bag (15), and the trioxygen gas generating part can be controlled by the gas delivery power mechanism (11). Oxygen enters the flow rate of the blood storage bag (15).
4. The ozone autologous blood return therapeutic apparatus according to claim 3, characterized in that: the gas delivery power mechanism (11) includes a peristaltic pump, and an energy-blocking reservoir is arranged at the second end of the ozone gas delivery tube (10). The blood in the blood bag (15) enters the water-blocking and ventilating part (46) of the gas delivery tube in the ozone generating part.
5. According to claim 3 or 4, the ozone autologous blood return treatment instrument is characterized in that: the ozone gas generating part includes a gas generating storage cabinet (1) and three gas generating storage cabinets (1) Oxygen generator (29), described ozone generator (29) can be connected with the gas conveying connector on the gas storage cabinet (1), and the first end of trioxygen gas conveying pipe (10) passes through described The gas delivery connector can be connected and communicated with the ozone generator (29) in the gas generation storage cabinet (1).
6. According to claim 5, the Oxygen autologous blood return treatment instrument is characterized in that: a vertically distributed infusion stand (12) is arranged on the gas generation storage cabinet (1), and the blood storage bag (15) can be hung on the On the infusion stand (12); the gas delivery connector on the gas generation storage cabinet (1) includes a luer connector (7), a pagoda connector (8) and/or a connector tube (9).
7. The ozone autologous blood return therapeutic apparatus according to claim 1, characterized in that: the blood extraction and delivery mechanism includes a puncture indwelling needle (27) for puncturing, a blood delivery system adapted to connect with the puncture indwelling needle (27) The tube body and the blood delivery power mechanism (18) adapted to the blood delivery tube body, the blood delivery tube body is connected with the bottom of the blood storage bag (15); through the blood delivery power mechanism (18) and the blood delivery tube Body cooperates, can send in the blood storage bag (15) through the blood that puncture indwelling needle (27) extracts or send in the puncture indwelling needle (27) after the blood mixed uniformly in the blood storage bag (15) is drawn out.
8. According to claim 7, the ozone autologous blood return therapeutic apparatus is characterized in that: it also includes a constant temperature heating mechanism (19) capable of heating the blood flowing through the blood delivery tube, and the blood delivery power mechanism includes a peristaltic pump.
9. According to claim 7 or 8, the ozone autologous blood return treatment instrument is characterized in that: the blood delivery tube body includes a blood delivery connection main pipe (17), and the first end of the blood delivery connection main pipe (17) is connected to the storage tank. The blood bag (15) is connected and communicated, and the second end of the blood delivery connection main pipe (17) is connected and communicated with the blood delivery inlet pipe (22) and the blood delivery return pipe (23) through the blood delivery selection valve (21), The blood delivery liquid inlet pipe (22), the blood delivery liquid return pipe (23) are connected with the puncture indwelling needle (27);

   It also includes a liquid return filter (24) adapted to the blood transport return pipe (23). When the blood is sent into the blood storage bag (15) through the blood transport power mechanism (18), the blood passes through the puncture retention needle ( 27), the blood delivery inlet pipe (22), the blood delivery selection valve (21), the blood delivery connection main pipe (17) and enters into the blood storage bag (15); the blood storage bag ( When the blood in 15) is pumped out, the blood in the blood storage bag (15) passes through the blood delivery connecting main pipe (17) and the blood delivery selection valve (21) in sequence, then enters the blood delivery return pipe (23), and passes through the return liquid After filter (24), enter in the puncture indwelling needle (27).
10. According to claim 9, the three-oxygen autologous blood return treatment instrument is characterized in that: a blood-transporting water-blocking ventilation pipe (32) is arranged on the said blood-transporting connection main pipe (17);

    The liquid return filter (24) includes a filter upper cover (38) and a filter lower cover (39) adapted to the filter upper cover (38), and the filter upper cover (38) ) on the filter upper pipe head (40), the filter lower pipe head (41) is set on the filter lower cover body (39); filter check valve (44) and filter check valve (44) are set in the filter lower cover body (39) and The filter membrane (42) used for filtration, the filter upper pipe head (40) and the filter lower pipe head (40) communicate with each other.

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