CN210472349U - Cervical vertebra intelligence pulls correction trainer - Google Patents

Abstract

The utility model relates to a cervical vertebra intelligence is pull and is corrected trainer, including the elasticity protection pad, the carrier ring, the elasticity gasbag, flexible sheath, the triaxial gyroscope, physiological parameter detection mechanism, flexible carrier post, the booster pump, relief valve and control circuit, the carrier ring is including the carrier segment, the location is detained, at least two of carrier ring and through four at least flexible carrier post interconnect, the cladding of elasticity protection pad is outside the carrier ring, and through two at least elasticity gasbag interconnect between the elasticity protection pad of two adjacent carrier rings, at least one triaxial gyroscope and at least one physiological parameter detection mechanism are all established to the medial surface of every carrier ring, the booster pump, relief valve and control circuit all inlay in flexible sheath. This kind of equipment of this novel tradition, simple structure integrates, the modularization degree is high, and it is nimble convenient to use, and the commonality is good, can realize carrying out the recovered and correction training operation of cervical vertebra according to user's physiological bearing capacity scientific and reasonable, improves the recovered and precision of correcting the training operation of cervical vertebra.

Description

Cervical vertebra intelligence pulls correction trainer

Technical Field

The utility model relates to a cervical vertebra training device, in particular to a cervical vertebra intelligent traction correction training device.

Background

At present, in the rehabilitation activities after operative treatment of diseases such as cervical vertebra hyperosteogeny and the like, and in the correction operation of cervical vertebra shift, deflection and the like caused by congenital or acquired trauma and the like, all the training equipment is needed to be carried out by a special cervical vertebra traction quality mechanism, but in practical use, the currently used training equipment for cervical vertebra disease traction and correction is always equipment such as sheath equipment with the lifting and stretching adjusting capability based on an adjustable bracket and high-pressure gas and a hard positioning sheath with a fixed structure, and the like, although the cervical vertebra correcting devices can meet the requirements of cervical vertebra postoperative rehabilitation training and correcting operation, on one hand, the bearing capacity and the traction capacity are relatively fixed when the cervical vertebra is carried and positioned in different degrees, flexible adjustment can not be carried out according to the cervical vertebra recovery of a patient, and the flexibility of the adjustment of the driving direction of acting force when the cervical vertebra is carried and corrected is relatively poor, on the other hand, the currently used post-operative recovery and orthopedic equipment for cervical spondylosis cannot effectively and accurately detect and measure the physiological parameters of patients, such as the body temperature, the heartbeat, the blood oxygen saturation, the motion state of the training operation, the acting force strength between the equipment and the patients, and the like when the rehabilitation training and orthopedic operation is performed, so that the post-operative recovery and orthopedic operation for cervical spondylosis cannot be scientifically and reasonably performed according to the physiological conditions of the patients, secondary injuries, such as pulling injuries of cervical vertebra tissues of the patients, and the like, are very easy to cause due to improper training and orthopedic acting forces, and in addition, when the current cervical vertebra car equipment is used for post-operative recovery and orthopedic operation for cervical spondylosis, the cervical vertebra is developed in a static fixed positioning mode, so that the situations that after the cervical vertebra is fixed and positioned for a long time, local muscle stiffness, unsmooth blood oxygen circulation and the like seriously affect the postoperative recovery and orthopedic efficiency and quality of cervical spondylosis are easily caused.

Therefore, in order to solve the problem, the development of a novel orthopedic device is urgently needed to meet the requirement of practical use.

SUMMERY OF THE UTILITY MODEL

Aiming at the defects in the prior art, the utility model provides an intelligent traction and correction training device for cervical vertebra, which has simple structure, integration, high modularization degree, flexible and convenient use and good universality, on one hand, the device can provide effective traction and guide acting force in the motion direction and the physiological direction of the cervical vertebra according to the use requirement, continuously and effectively guide and restrain the motion and the natural physiological state of the cervical vertebra, and effectively provide good bearing positioning capability and traction and correction capability for the cervical vertebra, thereby achieving the purposes of meeting the requirement that the normal physiological activity of the cervical vertebra is not influenced, playing good auxiliary quality and rehabilitation effect on cervical vertebra diseases, cervical vertebra deflection and the like, on the other hand, adding proper amount of elastic resistance in the motion direction of the cervical vertebra, thereby achieving the purpose of strengthening training of organ tissues such as muscle tissues, nervous systems and bones at the cervical vertebra, the efficiency of cervical vertebra disease rehabilitation and cervical vertebra correction is further improved, simultaneously in carrying out bearing location, correction and strengthening training to the cervical vertebra, can carry out accurate collection to physiological parameters such as user's blood oxygen content, heartbeat, motion state, body temperature in step to the realization is according to the carrying capacity scientific and reasonable of user's physiology carrying capacity cervical vertebra rehabilitation and correction training operation, improves the recovered and accuracy of correcting training operation of cervical vertebra, avoids causing the circumstances such as cervical vertebra tissue strain to take place because of the atress is improper.

In order to achieve the above purpose, the present invention is realized by the following technical solution:

an intelligent traction correction training device for cervical vertebra comprises elastic protection pads, bearing rings, elastic air bags, flexible sheaths, a three-axis gyroscope, a physiological parameter detection mechanism, telescopic bearing columns, a booster pump, a pressure release valve and a control circuit, wherein each bearing ring comprises bearing sections and positioning buckles, at least two bearing sections are connected with each other through the positioning buckles to form a closed annular structure, at least two bearing rings are coaxially distributed from top to bottom, the two adjacent bearing rings are connected with each other through at least four telescopic bearing columns, the telescopic bearing columns are uniformly distributed around the axis of the bearing rings and are hinged with the bearing rings, the axis of each telescopic bearing column and the axis of each bearing ring form an included angle of 0-90 degrees, the elastic protection pads are covered outside the bearing rings, the elastic protection pads of the two adjacent bearing rings are connected with each other through at least two elastic air bags, and the elastic air bags are sequentially connected end to end and are covered outside the telescopic bearing columns, elastic air bag all communicates with booster pump and relief valve each other through the air duct respectively, the triaxial gyroscope, physiological parameter detection mechanism quantity is unanimous with carrier ring quantity, at least one triaxial gyroscope and at least one physiological parameter detection mechanism are all established to the medial surface of every carrier ring, and the triaxial gyroscope, physiological parameter detection mechanism all encircles carrier ring axis equipartition, the triaxial gyroscope, physiological parameter detection mechanism all is connected with control circuit electrical connection, the booster pump, relief valve and control circuit all inlay in flexible sheath, and control circuit's operation interface inlays in flexible sheath surface, the booster pump, the flexible sheath side surface that the relief valve corresponds is equipped with a plurality of gas ports, flexible sheath is airtight cavity structures, and with elastic protection pad surface interconnect.

Furthermore, the bearing section of the bearing ring is of a hollow tubular structure, and the bearing section and the positioning buckle are hinged with each other through a ratchet mechanism.

Furthermore, a plurality of air cavities which are independent mutually are arranged in the elastic air bags, the axes of the air cavities are distributed in parallel with the axis of the bearing ring, at least one air cavity is arranged in each elastic air bag, the air cavities are connected with the air guide tube through control valves, and the control valves are electrically connected with the control circuit.

Furthermore, the physiological parameter detection mechanism comprises a bearing shell, a data acquisition circuit and a detection sensor, wherein the bearing shell is of a closed cavity structure, the data acquisition circuit is embedded in the bearing shell and is electrically connected with the detection sensor and the control circuit, the detection sensor is embedded in the outer surface of the bearing shell, and the optical axis of the detection sensor is perpendicular to and intersected with the axis of the bearing ring.

Furthermore, the detection sensor comprises any one or more of an optical heart rate sensor, a temperature sensor, a galvanic skin response sensor, a blood oxygen saturation SPO2 sensor, a bioelectrical impedance sensor and a pressure sensor.

Furthermore, when the telescopic bearing columns are connected with the bearing rings, each bearing section of each bearing ring is mutually connected with two telescopic bearing columns, the axial lines of the two telescopic bearing columns connected with the same bearing section form an included angle of 0-90 degrees, and in each telescopic bearing column between every two adjacent bearing rings, when one end of each telescopic bearing column is hinged with the outer surface of the bearing ring on the side close to the upper part, the other end of each telescopic bearing column is hinged with the inner surface of the bearing ring on the side close to the lower part; when one end of each telescopic bearing column is hinged to the inner surface of the bearing ring on the side close to the upper part, the other end of each telescopic bearing column is hinged to the outer surface of the bearing ring on the side close to the lower part, and the two ends of each two adjacent telescopic bearing columns are distributed at intervals with the connecting positions of the bearing rings.

Further, flexible carrier post is any one in electric telescopic handle and the pneumatic telescopic handle, and when wherein flexible carrier post was electric telescopic handle, then flexible carrier post and control circuit electrical connection, flexible carrier post when pneumatic telescopic handle, then flexible carrier post is for passing through air duct and booster pump intercommunication.

Furthermore, the control circuit is a circuit system based on an industrial single chip microcomputer, and at least one indicator light and a plurality of operation keys are arranged on an operation interface of the control circuit.

This novel this kind of equipment of tradition, moreover, the steam generator is simple in structure, integrate, the modularization degree is high, it is nimble convenient to use, the commonality is good, on the one hand can be as required according to the use, direction of motion at the cervical vertebra, physiological direction provides effectual traction and guide force, it leads and retrains to last effectual motion and the natural physiological state for the cervical vertebra, effectual bearing the weight of positioning ability and the correction ability of traction to provide the cervical vertebra, thereby reach and play good auxiliary quality and rehabilitation effect to cervical vertebra disease, cervical vertebra skew etc., on the other hand can increase appropriate amount elastic resistance for cervical vertebra direction of motion, thereby reach and carry out intensive training to organ tissues such as cervical vertebra position musculature, nervous system and skeleton, further improve the efficiency of cervical vertebra disease rehabilitation and cervical vertebra correction, simultaneously in bearing the location to the cervical vertebra, correct and intensive training, can be synchronous to user's blood oxygen content, The physiological parameters such as heartbeat, motion state, body temperature and the like are accurately collected, so that the cervical vertebra rehabilitation and correction training operation is scientifically and reasonably carried out according to the physiological bearing capacity of a user, the precision of the cervical vertebra rehabilitation and correction training operation is improved, and the cervical vertebra tissue strain and other situations caused by improper stress are avoided.

Drawings

The present invention will be described in detail with reference to the accompanying drawings and specific embodiments.

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic structural view of a physiological parameter detecting mechanism;

FIG. 3 is a schematic structural view of a connection structure of the bearing section and the telescopic bearing column;

fig. 4 is a schematic side view of a connection structure of the bearing section and the telescopic bearing column.

Detailed Description

In order to make the technical means, creation features, achievement purposes and functions of the present invention easy to understand, the present invention is further described below with reference to the following embodiments.

The intelligent traction, rectification and training device for cervical vertebra as shown in fig. 1-4 comprises an elastic protection pad 1, bearing rings 2, elastic air bags 3, a flexible sheath 4, a three-axis gyroscope 5, a physiological parameter detection mechanism 6, telescopic bearing columns 7, a booster pump 8, a pressure release valve 9 and a control circuit 10, wherein the bearing rings 1 comprise at least two bearing sections 201 and positioning buckles 202, the two adjacent bearing sections 201 are connected with each other through the positioning buckles 202 to form a closed annular structure, the at least two bearing rings 2 are coaxially distributed from top to bottom, the two adjacent bearing rings 2 are connected with each other through at least four telescopic bearing columns 7, the telescopic bearing columns 7 are uniformly distributed around the axis of the bearing ring 2 and are mutually hinged with the bearing ring 2, the axis of the telescopic bearing column 7 and the axis of the bearing ring 2 form an included angle of 0-90 degrees, the elastic protection pad 1 is coated outside the bearing ring 2, and the elastic protection pads 1 of the two adjacent bearing rings 2 are connected with each other through at least two elastic air bags 3, and each elastic air bag 3 is sequentially connected end to end and is wrapped outside the telescopic bearing column 7, and the elastic air bags 3 are respectively communicated with the booster pump 8 and the pressure release valve 9 through the air guide tubes 11.

In this embodiment, three-axis gyroscope 5, the quantity of physiological parameter detection mechanism 6 is unanimous with carrier ring 2 quantity, at least one three-axis gyroscope 5 and at least one physiological parameter detection mechanism 6 are all established to every carrier ring 2's medial surface, and three-axis gyroscope 5, physiological parameter detection mechanism 6 all encircles carrier ring 2 axis equipartition, three-axis gyroscope 5, physiological parameter detection mechanism 6 all is connected with control circuit 10 electrical, booster pump 8, relief valve 9 and control circuit 10 all inlay in flexible sheath 4, and control circuit 10's operation interface inlays in flexible sheath 4 surface, booster pump 8, the flexible sheath 4 side surface that relief valve 9 corresponds is equipped with a plurality of gas transmission ports 12, flexible sheath 4 is airtight cavity structures, and with 1 surface interconnect of elasticity protection pad.

The bearing section 201 of the bearing ring 2 is a hollow tubular structure, and the bearing section 201 and the positioning buckle 202 are hinged to each other through a ratchet mechanism 203.

Meanwhile, a plurality of mutually independent air cavities 13 are arranged in the elastic air bags 3, the axes of the air cavities 13 are distributed in parallel with the axis of the bearing ring 1, at least 3 air cavities 13 are arranged in each elastic air bag 3, the air cavities 13 are mutually connected with the air guide tube 11 through a control valve 14, and the control valve 14 is electrically connected with the control circuit 10.

Meanwhile, the physiological parameter detection mechanism 6 comprises a bearing shell 61, a data acquisition circuit 62 and a detection sensor 63, the bearing shell 61 is of a closed cavity structure, the data acquisition circuit 62 is embedded in the bearing shell 61 and is electrically connected with the detection sensor 63 and the control circuit 10, the detection sensor 63 is embedded on the outer surface of the bearing shell 61, the optical axis of the detection sensor 63 is perpendicular to and intersected with the axis of the bearing ring 2, and the detection sensor 63 comprises any one or more of an optical heart rate sensor, a temperature sensor, a galvanic reaction sensor, a blood oxygen saturation SPO2 sensor, a bioelectrical impedance sensor and a pressure sensor.

It should be particularly pointed out that, when the telescopic carrying columns 7 are connected with the carrying ring 2, each carrying section 201 of the carrying ring 2 is connected with two telescopic carrying columns 7, and the axes of the two telescopic carrying columns 7 connected with the same carrying section 201 form an included angle of 0-90 degrees, in each telescopic carrying column 7 between two adjacent carrying rings 2, when one end of each telescopic carrying column is hinged with the outer surface of the carrying ring 2 close to the upper side, the other end is hinged with the inner surface of the carrying ring 2 close to the lower side; when 7 one ends of flexible carrier post with be close to 2 internal surfaces of carrier ring on one side of the top articulated, then the other end with be close to 2 external surfaces of carrier ring on one side of the below articulated, and the mutual interval distribution between two ends and the carrier ring 2 hookup location of two adjacent flexible carrier posts 7, flexible carrier post 7 is any one of electric telescopic handle and pneumatic telescopic handle, and when wherein flexible carrier post 7 is electric telescopic handle, then flexible carrier post 7 and control circuit 10 electrical connection, flexible carrier post 7 when pneumatic telescopic handle, then flexible carrier post 7 is for passing through air duct 11 and booster pump 8 intercommunication.

In addition, the control circuit 10 is a circuit system based on an industrial single chip microcomputer, and at least one indicator light 15 and a plurality of operation keys 16 are arranged on an operation interface of the control circuit 10.

This is novel in the concrete implementation, at first as required to elasticity protection pad, carrier ring, elasticity gasbag, flexible sheath, triaxial gyroscope, physiological parameter detection mechanism, flexible carrier post, booster pump, relief valve and control circuit equipment reserve.

In carrying out orthopedic rehabilitation operation to the cervical vertebra, at first with each carrier ring distribution in same with the carrier ring axis parallel straight line orientation on detain and open, then detain the closure with the location behind patient's cervical vertebra position with the carrier ring cladding, make the carrier ring be closed structure and whole cladding in the cervical vertebra outside, make simultaneously the physiological parameter detection mechanism of carrier ring internal surface and the elasticity protection pad of cladding outside the carrier ring and patient cervical vertebra position skin contact, at last with control circuit and outside power supply electrical connection, can accomplish with neotype installation location.

When orthopedic operation is carried out, the control circuit drives the telescopic bearing columns, the booster pump and the physiological parameter detection mechanism to operate respectively, the telescopic bearing columns operate to adjust the positions of the bearing rings, the lowermost bearing ring abuts against the shoulders of a patient through the elastic protection pad, the uppermost bearing ring abuts against the lower jaw and the head of the patient through the elastic protection pad, the physiological parameter detection mechanism detects the pressure between a human body and the bearing rings, the situation that the cervical vertebrae of the patient are strained or unstably positioned due to the fact that the telescopic bearing columns operate is avoided, then the booster pump injects high-pressure gas into the elastic air bags, the elastic air bags assist the telescopic bearing columns to carry out bearing positioning on the cervical vertebrae of the patient through the high-pressure gas inside the elastic air bags, and meanwhile, external cold air and the like are prevented from causing stimulation to the cervical vertebrae of the patient.

Then the current position relation of each bearing ring is detected by a three-axis gyroscope, the detection result is combined with the physiological structure of the cervical vertebra of a human body and the training requirement of cervical vertebra rehabilitation operation after medical activities, the pressure in a corresponding air cavity in a telescopic bearing column and an elastic air bag corresponding to the corresponding part of the cervical vertebra of a patient is adjusted, forced bearing and positioning are provided for the corresponding part of the cervical vertebra of the patient, the motion direction and the training strength of the cervical vertebra training are regulated and controlled, the requirement of the cervical vertebra bearing recovery and correction operation is met, and when the bearing recovery and correction operation is carried out, physiological parameters of the patient are collected by a physiological parameter detection mechanism, so that the discomfort of the patient caused by overlarge bearing capacity is avoided;

finally, when carrying out bearing positioning and orthopedic operation on the cervical vertebra of a patient, the physiological parameter detection mechanism and the three-axis gyroscope are used for detecting the motion state of the neck of the patient, then according to the detected motion state data, the physiological structure of the cervical vertebra of the human body and the training requirement of the cervical vertebra rehabilitation operation after medical activity are combined, and the corresponding dynamic adjustment is carried out by the stroke of the telescopic bearing column corresponding to the corresponding part of the cervical vertebra of the patient and the corresponding pressure in the air cavity in the elastic air bag along with the detected motion state parameter of the cervical vertebra while the training requirement of the cervical vertebra rehabilitation operation after the physiological structure of the human body and the medical activity of the patient is ensured, thereby meeting the requirement of the normal physiological activity of the cervical vertebra of the patient, meanwhile, in the dynamic adjustment, the aim of strengthening exercise on the cervical vertebra muscle tissue and the like of the patient can be achieved by means of the stroke of the telescopic bearing column, avoid

This novel this kind of equipment of tradition, moreover, the steam generator is simple in structure, integrate, the modularization degree is high, it is nimble convenient to use, the commonality is good, on the one hand can be as required according to the use, direction of motion at the cervical vertebra, physiological direction provides effectual traction and guide force, it leads and retrains to last effectual motion and the natural physiological state for the cervical vertebra, effectual bearing the weight of positioning ability and the correction ability of traction to provide the cervical vertebra, thereby reach and play good auxiliary quality and rehabilitation effect to cervical vertebra disease, cervical vertebra skew etc., on the other hand can increase appropriate amount elastic resistance for cervical vertebra direction of motion, thereby reach and carry out intensive training to organ tissues such as cervical vertebra position musculature, nervous system and skeleton, further improve the efficiency of cervical vertebra disease rehabilitation and cervical vertebra correction, simultaneously in bearing the location to the cervical vertebra, correct and intensive training, can be synchronous to user's blood oxygen content, The physiological parameters such as heartbeat, motion state, body temperature and the like are accurately collected, so that the cervical vertebra rehabilitation and correction training operation is scientifically and reasonably carried out according to the physiological bearing capacity of a user, the precision of the cervical vertebra rehabilitation and correction training operation is improved, and the cervical vertebra tissue strain and other situations caused by improper stress are avoided.

Those skilled in the art should understand that the present invention is not limited by the above embodiments. The foregoing embodiments and description have been made only for the purpose of illustrating the principles of the invention. The present invention can be further modified and improved without departing from the spirit and scope of the present invention. Such changes and modifications are intended to be within the scope of the claimed invention. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (7)

1. The utility model provides a training device is corrected in traction of cervical vertebra intelligence which characterized in that: the intelligent cervical vertebra traction correction training device comprises an elastic protection pad, a bearing ring, elastic air bags, a flexible sheath, a three-axis gyroscope, a physiological parameter detection mechanism, a telescopic bearing column, a booster pump and a pressure release valve, wherein the bearing ring comprises a bearing section and a positioning buckle, at least two bearing sections are connected with each other through the positioning buckle and form a closed annular structure, at least two bearing rings are coaxially distributed from top to bottom, the two adjacent bearing rings are connected with each other through at least four telescopic bearing columns, the telescopic bearing columns are uniformly distributed around the axis of the bearing ring and are hinged with the bearing ring, the axis of the telescopic bearing column and the axis of the bearing ring form an included angle of 0-90 degrees, the elastic protection pad is coated outside the bearing ring, and the elastic protection pads of the two adjacent bearing rings are connected with each other through at least two elastic air bags, and each elastic air bag is connected end to end in proper order and the cladding is outside flexible carrier post, the elastic air bag all communicate with booster pump and relief valve each other through the air duct respectively, triaxial gyroscope, physiological parameter detection mechanism quantity unanimous with carrier ring quantity, at least one triaxial gyroscope and at least one physiological parameter detection mechanism are all established to the medial surface of every carrier ring, and triaxial gyroscope, physiological parameter detection mechanism all encircle carrier ring axis equipartition, booster pump, relief valve all inlay in flexible sheath, flexible sheath side surface that booster pump, relief valve correspond be equipped with a plurality of gas ports, flexible sheath be airtight cavity structures to with elastic protection pad surface interconnect.

2. The intelligent traction, rectification and training device for the cervical vertebra according to claim 1, is characterized in that: the bearing section of the bearing ring is of a hollow tubular structure, and the bearing section and the positioning buckle are hinged with each other through a ratchet mechanism.

3. The intelligent traction, rectification and training device for the cervical vertebra according to claim 1, is characterized in that: the elastic air bags are internally provided with a plurality of air cavities which are mutually independent, the axes of the air cavities are distributed in parallel with the axis of the bearing ring, and each elastic air bag is internally provided with at least one air cavity which is mutually connected with the air guide tube through a control valve.

4. The intelligent traction, rectification and training device for the cervical vertebra according to claim 1, is characterized in that: the physiological parameter detection mechanism comprises a bearing shell, a data acquisition circuit and a detection sensor, wherein the bearing shell is of a closed cavity structure, the data acquisition circuit is embedded in the bearing shell and is electrically connected with the detection sensor, the detection sensor is embedded in the outer surface of the bearing shell, and the optical axis of the detection sensor is perpendicular to and intersected with the axis of the bearing ring.

5. The intelligent traction, rectification and training device for the cervical vertebra according to claim 4, is characterized in that: the detection sensor comprises any one or more of an optical heart rate sensor, a temperature sensor, a galvanic skin response sensor, a blood oxygen saturation SPO2 sensor, a bioelectrical impedance sensor and a pressure sensor.

6. The intelligent traction, rectification and training device for the cervical vertebra according to claim 1, is characterized in that: when the telescopic bearing columns are connected with the bearing rings, each bearing section of each bearing ring is mutually connected with two telescopic bearing columns, the axes of the two telescopic bearing columns connected with the same bearing section form an included angle of 0-90 degrees, and in each telescopic bearing column between every two adjacent bearing rings, when one end of each telescopic bearing column is hinged with the outer surface of the bearing ring on one side close to the upper part, the other end of each telescopic bearing column is hinged with the inner surface of the bearing ring on one side close to the lower part; when one end of each telescopic bearing column is hinged to the inner surface of the bearing ring on the side close to the upper part, the other end of each telescopic bearing column is hinged to the outer surface of the bearing ring on the side close to the lower part, and the two ends of each two adjacent telescopic bearing columns are distributed at intervals with the connecting positions of the bearing rings.

7. The intelligent traction, rectification and training device for the cervical vertebra according to claim 1, is characterized in that: the telescopic bearing column is any one of an electric telescopic rod and a pneumatic telescopic rod, and when the telescopic bearing column is the pneumatic telescopic rod, the telescopic bearing column is communicated with the booster pump through the air duct.

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