CN119097513B - A decompression type fixed headrest for postoperative rehabilitation of craniosynostosis - Google Patents

Abstract

The present invention complies with the technical field of postoperative rehabilitation, and mentions a decompression type fixed headrest for postoperative rehabilitation of craniosynostosis. It comprises a flexible pillow, wherein the flexible pillow is rotatably connected with mirror-distributed rollers, the mirror-distributed rollers are all fixedly connected and wrapped with cables, the mirror-distributed rollers are all provided with a first elastic element between the mirror-distributed rollers and the flexible pillow, the mirror-distributed rollers are all fixedly connected with gears, the flexible pillow is fixedly connected with an air injection cylinder, the mirror-distributed cables are all fixedly connected with face-attached airbags, the mirror-distributed face-attached airbags are all fixedly connected with head-protecting airbags, and the air injection cylinder is sealed and slidably connected with a mirror-distributed first piston shaft. The present invention uses the power of a child lying on his side to inject gas into the face-attached airbag, so that the face-attached airbag expands to support the child's cheek height to rise, and then supports the child's head to rise synchronously, reducing the force between the head and the flexible pillow, and reducing the pressure on the child's head wound.

Description

A decompression type fixed headrest for postoperative rehabilitation of craniosynostosis

Technical Field

The present invention relates to the technical field of postoperative rehabilitation, and mainly mentions a decompression type fixed headrest for postoperative rehabilitation of craniosynostosis.

Background Art

Craniosynostosis, medically known as craniosynostosis or craniosynostosis, is a congenital skull developmental abnormality in which one or more cranial sutures close prematurely, preventing normal brain and skull growth. Normally, an infant's skull is made up of multiple bones connected by cartilage. These connecting sutures are called cranial sutures. Their existence allows the skull to expand as the brain grows. In craniosynostosis, the cranial sutures ossify prematurely, resulting in the skull being unable to expand normally, which affects the normal development of the brain. The most common types include sagittal suture closure, coronal suture closure, lambdoid suture closure, frontal suture closure and complex craniosynostosis. The surgical incision for coronal suture closure often uses a wing-shaped incision. The incision starts in front of one ear, extends upward along the hairline, then crosses the top of the head, and then goes down to in front of the other ear, leaving surgical wounds on both sides of the skull and the top of the head.

After coronal suture closure surgery, wounds will remain on both sides and the top of the head. In the subsequent postoperative rehabilitation, it is necessary to avoid applying pressure to the wounds. However, when children are resting, they are very likely to lie on their side in an unconscious state. However, the existing method can only support the child's head with a headrest to prevent the child from being harmed by external pressure when lying on his back, but it cannot form decompression protection for the pressure on the side of the child's head when lying on his side. The child's own weight of the head directly acts on the side of the head, so that the head's own gravity acts on the wound on the side of the head. The wound is under pressure due to the head's own gravity, which delays the healing of the wound.

Summary of the invention

In order to overcome the shortcomings mentioned in the above background technology, the present invention provides a decompression type fixed headrest for postoperative rehabilitation of craniosynostosis.

The technical solution is as follows: A decompression fixed headrest for postoperative rehabilitation of craniosynostosis, comprising a flexible pillow, wherein the flexible pillow is rotatably connected with mirror-distributed rollers, the mirror-distributed rollers are all fixedly connected and wrapped with cables, a first elastic element is arranged between the mirror-distributed rollers and the flexible pillow, the mirror-distributed rollers are all fixedly connected with gears, an air injection cylinder is fixedly connected to one side of the flexible pillow close to the mirror-distributed gears, the mirror-distributed cables are all fixedly connected with face-attached airbags, the mirror-distributed face-attached airbags are all fixedly connected with head protection airbags, and the air injection cylinder seals the A first piston shaft with a mirror-distributed first piston shaft is slidably connected, and the mirror-distributed first piston shaft cooperates with the gas injection cylinder to form a closed cavity. The distal ends of the mirror-distributed first piston shaft are fixedly connected with racks, and the mirror-distributed racks are respectively meshed with adjacent gears. The mirror-distributed face-attached airbag and the gas injection cylinder are jointly and fixedly connected with a first gas injection pipe. The mirror-distributed first piston shaft cooperates with the gas injection cylinder to form a closed cavity, which is connected with the mirror-distributed face-attached airbag through the first gas injection pipe. The mirror-distributed head protection airbag is provided with a fixing component for fixing itself.

As a preferred embodiment, the head protection airbag is arc-shaped and has a hollow structure inside.

As a preference, the fixing assembly includes a second piston shaft with a mirror distribution, the second piston shafts with a mirror distribution are respectively fixedly connected to a side of the adjacent head protection airbag away from the adjacent face airbag, the second piston shafts with a mirror distribution are slidably connected together with a docking shell, a second elastic element is arranged between the second piston shafts with a mirror distribution, the second elastic element is located inside the docking shell, and the second piston shafts with a mirror distribution are all provided with a locking assembly for locking themselves.

As a preferred embodiment, the locking assembly includes a linear array of sawtooth blocks, the sawtooth blocks of the linear array are fixedly connected to the adjacent second piston shafts, the docking shell is slidably connected to a limiting shaft on one side of the sawtooth blocks close to the adjacent linear array, the sawtooth blocks of the linear array are limitedly cooperated with the adjacent limiting shafts, a third elastic element is arranged between the limiting shaft and the docking shell, and the docking shell is provided with a detection assembly for detecting the distance between the mirror-distributed face-attaching airbags.

Preferably, the detection component includes an elastic telescopic rod, which is fixedly connected to the outside of the gas injection cylinder, and the second piston shaft distributed in a mirror image cooperates with the docking shell to form a closed cavity, and the docking shell and the fixed part of the elastic telescopic rod are fixedly connected with a second gas injection pipe, the closed cavity is connected to the second gas injection pipe, and the fixed part of the elastic telescopic rod is connected to the second gas injection pipe, and the gas injection cylinder is provided with a self-adjusting component for adjusting the initial pressure in the face-sticking airbag.

Preferably, the self-adjusting component includes a third piston shaft, the third piston shaft is fixedly connected to the telescopic end of the elastic telescopic rod, the middle part of the gas injection cylinder is fixedly connected and connected to the adjustment cylinder, and the third piston shaft is sealed and slidably connected to the adjustment cylinder.

As a preferred embodiment, it also includes a mirror-distributed resistance component, which is used to increase the resistance of the adjacent first piston shaft sliding along the gas injection cylinder, and the resistance component is arranged on the adjacent first piston shaft. The resistance component includes a resistance plate, and the resistance plate is fixedly connected to the side of the flexible pillow close to the adjacent first piston shaft. The first piston shaft is hinged with a hinge rod, and the hinge rod is provided with a one-way pulley, and the one-way pulley is in contact with the adjacent resistance plate. The first piston shaft is provided with an adjustment component for adjusting the resistance of the adjacent one-way pulley and the adjacent resistance plate.

Preferably, the resistance plate has a thickness that gradually decreases from one end close to the adjacent first piston shaft to the other end, and the contact surface between the resistance plate and the adjacent one-way pulley is a rough surface.

Preferably, the adjustment assembly includes a swivel, which is rotatably connected to one end of the adjacent first piston shaft close to the adjacent hinged rod, the swivel and the adjacent hinged rod are rotatably connected, a fourth elastic element is arranged between the swivel and the adjacent hinged rod, and a limit assembly for locking the adjacent swivel is arranged at one end of the first piston shaft close to the adjacent resistance plate.

As a preference, the limiting assembly includes an insert shaft, the insert shaft is threadedly connected to the adjacent swivel, the first piston shaft is provided with an annular array of limiting holes, and the limiting holes in the annular array are all matched with the adjacent insert shaft.

Compared with the prior art, the present invention has the following advantages: 1. Gas is injected into the face-attached airbag through the power of the child lying on his side, so that the face-attached airbag expands to support the child's cheek to rise in height, thereby supporting the child's head to rise synchronously, reducing the force between the head and the flexible pillow, thereby reducing the pressure on the child's head wound, avoiding the mass of the head from directly acting on the wound, and slowing down the healing rate of the wound.

2. The two second piston shafts are locked by the limit shaft, so that the face airbag and the head airbag are attached to the cheeks and both sides of the child's head to protect the child's head.

3. By adding the gas in the regulating tube to the face airbag, the expansion degree of the face airbag is maintained, and at the same time the initial expansion degree of the face airbag is increased to prevent the face airbag from being unable to support the child's head to the required height when the child is lying on his side due to a large head and heavy body.

4. The one-way pulley slides along the adjacent resistance plate to generate resistance to the movement of the first piston shaft, so that the child needs to overcome a certain resistance when turning from supine to side-lying, thereby inhibiting the child's side-lying movement and reducing the probability of the child lying on his side.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG1 is a schematic diagram of a three-dimensional structure of the present invention;

FIG2 is a schematic diagram of the three-dimensional structure of the roller and the cable of the present invention;

FIG3 is a schematic diagram of the three-dimensional structure of the gas injection cylinder and the first piston shaft of the present invention;

FIG4 is a schematic diagram of the three-dimensional structure of the second piston shaft and the docking shell of the present invention;

FIG5 is a schematic cross-sectional view of the three-dimensional structure of the docking shell of the present invention;

FIG6 is a schematic cross-sectional view of the three-dimensional structure of the regulating cylinder of the present invention;

FIG7 is a schematic diagram of the three-dimensional structure of the hinged rod and the one-way pulley of the present invention;

FIG. 8 is a schematic diagram of the three-dimensional structure of the swivel and the fourth elastic element of the present invention.

Explanation of the accompanying drawings: 1-flexible pillow, 2-roller, 3-cable, 4-first elastic element, 5-gear, 6-injection cylinder, 7-face airbag, 8-head protection airbag, 9-first piston shaft, 10-rack, 11-first air injection pipe, 201-second piston shaft, 202-docking shell, 203-second elastic element, 301-sawtooth block, 302-limiting shaft, 303-third elastic element, 401-elastic telescopic rod, 402-second air injection pipe, 403-third piston shaft, 404-adjusting cylinder, 501-resistance plate, 502-hinged rod, 503-one-way pulley, 504-swivel, 505-fourth elastic element, 506-insertion shaft, 507-limiting hole.

DETAILED DESCRIPTION

The following descriptions are merely preferred embodiments of the present invention and are not intended to limit the protection scope of the present invention.

The wounds after coronal suture closure surgery will remain on both sides and the top of the head. In the subsequent postoperative rehabilitation, it is necessary to avoid applying pressure to the wounds. During the resting process, children are very likely to lie on their side in an unconscious state. At this time, the weight of the child's head directly acts on the side of the head, causing the head's own gravity to act on the wound on the side of the head. At this time, the wound is under pressure due to the head's own gravity, delaying the healing of the wound. The existing method can only support the child's head through a headrest, so that it is not harmed by external pressure when lying on its back, but it cannot form decompression protection for the pressure on the side of the child's head when lying on its side, thereby affecting the healing of the wound.

Embodiment 1: A decompression fixed headrest for postoperative rehabilitation of craniosynostosis, please refer to Figures 1 to 4, including a flexible pillow 1, the left and right sides of the flexible pillow 1 are rotatably connected with rollers 2, the two mirror-distributed rollers 2 are fixedly connected and wrapped with cables 3, two mirror-distributed first elastic elements 4 are arranged between the two mirror-distributed rollers 2 and the flexible pillow 1, the first elastic elements 4 are torsion springs, the first elastic elements 4 are used to drive the adjacent rollers 2 to reset, the first elastic elements 4 are initially in a torsion state, the rear sides of the two mirror-distributed rollers 2 are fixedly connected with gears 5, the rear side of the flexible pillow 1 is fixedly connected with an air injection cylinder 6, the two mirror-distributed cables 3 are fixedly connected with face-fitting airbags 7, the rear sides of the two mirror-distributed face-fitting airbags 7 are fixedly connected with head protection airbags 8, the head protection airbags 8 are arc-shaped, which is convenient for adapting to the contour of the head, and the interior is a hollow structure, so that the postoperative wound is located in the head protection airbag 8 to avoid direct contact between the head protection airbag 8 and the postoperative wound, the air injection cylinder 6 is sealingly and slidably connected with two mirror-distributed first piston shafts 9, the two mirror-distributed The first piston shaft 9 cooperates with the gas injection cylinder 6 to form a closed cavity. The far ends of the two mirror-distributed first piston shafts 9 are fixedly connected with racks 10. The two mirror-distributed racks 10 are respectively meshed with adjacent gears 5. The gears 5 drive the adjacent first piston shafts 9 to slide along the gas injection cylinder 6 through the adjacent racks 10. The two mirror-distributed face-attached airbags 7 and the gas injection cylinder 6 are jointly fixedly connected with a first gas injection pipe 11. The two mirror-distributed first piston shafts 9 cooperate with the gas injection cylinder 6 to form a closed cavity through the first gas injection pipe 11 and the mirror-distributed face-attached airbags 7. The two face-sticking airbags 7 of the cloth are connected, and the first piston shaft 9 slides inward along the gas injection cylinder 6, and the gas in the closed cavity formed by the two first piston shafts 9 and the gas injection cylinder 6 is pushed into the two face-sticking airbags 7 through the first gas injection tube 11, so that the face-sticking airbags 7 expand to support the child's cheeks to rise, thereby driving the child's head to rise synchronously, reducing the force between the head and the flexible pillow, avoiding the mass of the head from directly acting on the wound, and slowing down the healing rate of the wound. The two mirror-distributed head protection airbags 8 are provided with fixing components for fixing themselves.

Please refer to Figures 4 and 5. The fixing component includes two second piston shafts 201 with mirror distribution. The two second piston shafts 201 with mirror distribution are respectively fixedly connected to the rear sides of adjacent head protection airbags 8. The two second piston shafts 201 with mirror distribution are slidably connected with a docking shell 202. A second elastic element 203 is arranged between the second piston shafts 201 with mirror distribution. The second elastic element 203 is a tension spring. The second elastic element 203 is used to drive the two second piston shafts 201 to reset. The second elastic element 203 is located inside the docking shell 202. The two second piston shafts 201 with mirror distribution are both provided with a locking component for locking themselves.

Please refer to Figures 4 and 5. The locking assembly includes a linear array of sawtooth blocks 301, which are fixedly connected to adjacent second piston shafts 201. The docking shell 202 is slidably connected to a limiting shaft 302 on one side of the sawtooth blocks 301 close to the adjacent linear array. The sawtooth blocks 301 of the linear array are limitedly matched with adjacent limiting shafts 302. The sawtooth blocks 301 lock the adjacent second piston shafts 201 through the limiting shafts 302, so that the face-attaching airbags 7 and the head-protecting airbags 8 are attached to the cheeks and both sides of the head of the child. A third elastic element 303 is arranged between the limiting shaft 302 and the docking shell 202. The third elastic element 303 is a tension spring. The third elastic element 303 is used to drive the adjacent limiting shafts 302 to reset. The docking shell 202 is provided with a detection component for detecting the distance between the mirror-distributed face-attaching airbags 7.

Please refer to Figures 2 to 4 and 6. The detection component includes an elastic telescopic rod 401, which is fixedly connected to the outside of the gas injection cylinder 6. The second piston shaft 201 and the docking shell 202, which are distributed in a mirror image, cooperate to form a closed cavity. The volume of the child's head is detected by the distance that the two second piston shafts 201 slide along the docking shell 202. The docking shell 202 and the fixed part of the elastic telescopic rod 401 are fixedly connected with a second gas injection tube 402. The fixed part of the elastic telescopic rod 401 is provided with an elastic retractable end for resetting its telescopic end. Spring, the elastic coefficient of the third elastic element 303 is greater than the elastic coefficient of the spring in the fixed part of the elastic telescopic rod 401, the closed cavity is connected with the second gas injection pipe 402, the fixed part of the elastic telescopic rod 401 is connected with the second gas injection pipe 402, the second piston shaft 201 slides back along the docking shell 202, so that the gas in the fixed part of the elastic telescopic rod 401 enters the closed cavity, and the telescopic end of the elastic telescopic rod 401 slides inward along its fixed part, and the gas injection cylinder 6 is provided with a self-adjusting component for adjusting the initial pressure in the face-fitting airbag 7.

Please refer to Figure 6. The self-adjusting component includes a third piston shaft 403, which is fixedly connected to the telescopic end of the elastic telescopic rod 401. The middle part of the gas injection cylinder 6 is fixedly connected and connected to the regulating cylinder 404. The third piston shaft 403 is sealed and slidably connected with the regulating cylinder 404. The telescopic end of the elastic telescopic rod 401 drives the third piston shaft 403 to slide inward along the regulating cylinder 404, so that the gas in the regulating cylinder 404 flows through the gas injection cylinder 6 and enters the two face-attaching airbags 7 along the first gas injection pipe 11, and the horizontal connection of the docking shell 202 is realized. The cross-sectional area is larger than the cross-sectional area of the air injection cylinder 6, so that when the child's head is fixed and the distance between the face airbags 7 increases, the reduction in the gas in the face airbag 7 is less than the injection amount of the gas in the adjusting cylinder 404 into the face airbag 7 by the third piston shaft 403. By replenishing the gas in the adjusting cylinder 404 into the face airbag 7, the expansion degree of the face airbag 7 is maintained, and at the same time the initial expansion degree of the face airbag 7 is increased, to prevent the child's head from being too big and too heavy, and the face airbag from being unable to support the child's head to the required height when lying on the side.

When the child needs to sleep after craniosynostosis surgery, the staff pulls the two second piston shafts 201 distributed in a mirror image to slide along the docking shell 202 in reverse, and the second elastic element 203 is stretched at the same time. At this time, the second piston shaft 201 drives the sawtooth blocks 301 of the linear array thereon to move synchronously, and the sawtooth blocks 301 of the linear array squeeze the adjacent limiting shafts 302, and the limiting shafts 302 slide along the docking shell 202, so that the third elastic element 303 is stretched, so that the distance between the two face-attaching airbags 7 distributed in a mirror image and the two head-protecting airbags 8 distributed in a mirror image are the same as the distance between the sides of the child's head, and then the two mirror image distributed airbags are stopped from sliding. The second piston shaft 201, and then the third elastic element 303 are reset, and the adjacent limiting shaft 302 is driven to reset, so that the limiting shaft 302 contacts the adjacent serrated block 301, and the limiting shaft 302 locks the adjacent second piston shaft 201, and then the two face-sticking airbags 7 are fitted to the child's cheeks, and at the same time, the two head protection airbags 8 are fitted to both sides of the head, and the surgical wound is located in the hollow of the head protection airbags 8. The two second piston shafts 201 are locked by the limiting shaft 302, and then the face-sticking airbags 7 and the head protection airbags 8 are fitted to the child's cheeks and both sides of the head to protect the child's head. At this time, the protection of the child's head is initially completed.

When the face airbag 7 and the head airbag 8 are fixed to the child's head, due to the increase in the distance between the two face airbags 7, the two first elastic elements 4 distributed in mirror images on both sides are reset to drive the adjacent rollers 2 to rotate, and the rollers 2 reel in the adjacent cables 3. At the same time, the rollers 2 drive the adjacent gears 5 to rotate, and the gears 5 drive the first piston shafts 9 to slide along the gas injection cylinder 6 through the rack 10, so that the two first piston shafts 9 distributed in mirror images slide in opposite directions, thereby causing the gas in the two face airbags 7 distributed in mirror images to flow back into the gas injection cylinder 6. At this time, the two face airbags 7 distributed in mirror images shrink, and at the same time, the two second piston shafts 201 distributed in mirror images are pulled outward along the docking shell 202. At this time, the volume of the closed cavity formed by the second piston shafts 201 distributed in mirror images and the docking shell 202 increases, and the elastic expansion The gas in the fixed part of the retractable rod 401 enters along the second gas injection pipe 402 into the closed cavity formed by the second piston shaft 201 and the docking shell 202 which are distributed in a mirror image. The telescopic end of the elastic telescopic rod 401 slides inward along its fixed part. The telescopic end of the elastic telescopic rod 401 drives the third piston shaft 403 thereon to slide inward along the adjusting cylinder 404. The third piston shaft 403 pushes the gas in the adjusting cylinder 404 to enter the gas injection cylinder 6. The gas in the gas injection cylinder 6 enters along the first gas injection pipe 11 into the two face-attached airbags 7 which are distributed in a mirror image. The gas in the face-attached airbags 7 increases, so that the gas in the two face-attached airbags 7 returns to the initial expansion degree. At the same time, the face-attached airbags 7 further expand on the original volume to prevent the face-attached airbags 7 from being unable to support the child's head to the required height when the child is lying on his side due to a large head and a heavy body.

Children are very likely to lie on their side when sleeping, which causes pressure on the surgical wounds on both sides of the child's head, which is not conducive to the recovery of the wounds. When the child lies on his side, the child's head will drive the two face-sticking airbags 7 distributed in a mirror image thereon to change their positions. The two face-sticking airbags 7 are deflected from a horizontally symmetrical distribution to a vertically symmetrical distribution. At this time, the face-sticking airbags 7 are deflected and pull the adjacent cables 3, and the cables 3 drive the adjacent rollers 2 to rotate. At the same time, the two adjacent mirror-distributed first elastic elements 4 are twisted, and the rotation of the rollers 2 drives the adjacent gears 5 to rotate, and the gears 5 drive the adjacent The adjacent rack 10 moves, and the rack 10 drives the adjacent first piston shaft 9 to be pushed inward along the gas injection cylinder 6. The gas in the gas injection cylinder 6 is driven by the driving force and enters the two face-attached airbags 7 along the first gas injection pipe 11. At this time, the volume of the gas in the face-attached airbags 7 increases, thereby driving the face-attached airbags 7 to gradually expand, so that the face-attached airbags 7 expand to support the child's cheeks. The height of the child's cheeks rises, and then the child's head is supported to rise synchronously, reducing the force of the flexible pillow 1 on the head, reducing the pressure on the wound on the child's head, avoiding the mass of the head directly acting on the wound, and slowing down the healing rate of the wound.

When the staff observes that the child lies on his side, the child is turned to a supine position. At this time, the first elastic element 4 is reset, driving the adjacent roller 2 to reset. The roller 2 resets and reels the adjacent cable 3. At the same time, the roller 2 drives the adjacent gear 5 to reset and rotate. The gear 5 drives the first piston shaft 9 to reset through the adjacent rack 10. The first piston shaft 9 slides along the gas injection cylinder 6, so that the gas in the two mirror-distributed face-attached airbags 7 partially flows to the closed cavity formed by the cooperation of the two first piston shafts 9 and the gas injection cylinder 6. When the child goes out and lies on his side again, the above steps are repeated.

Embodiment 2: Based on Embodiment 1, please refer to Figures 2 and 7, and also include two resistance components with mirror distribution, the resistance component is used to increase the resistance of the adjacent first piston shaft 9 sliding along the gas injection cylinder 6, the resistance component is arranged on the adjacent first piston shaft 9, the resistance component includes a resistance plate 501, the thickness of the resistance plate 501 gradually decreases from the middle to the outside of the flexible pillow 1, the resistance plate 501 is fixedly connected to the rear side of the flexible pillow 1, the first piston shaft 9 is hinged with a hinge rod 502, the hinge rod 502 is provided with a one-way pulley 503, and the one-way pulley 503 cannot rotate when sliding along the resistance plate 501 to the middle of the flexible pillow 1 The one-way pulley 503 can rotate when it slides along the resistance plate 501 from the middle of the flexible pillow 1 to the outside. The one-way pulley 503 is in contact with the adjacent resistance plate 501, and the contact surface between the resistance plate 501 and the adjacent one-way pulley 503 is a rough surface. The first piston shaft 9 is provided with an adjustment component for adjusting the resistance of the adjacent one-way pulley 503 and the adjacent resistance plate 501. The one-way pulley 503 slides along the adjacent resistance plate 501 through friction, thereby generating resistance to the movement of the first piston shaft 9, so that the child needs to overcome a certain resistance when turning from supine to side-lying, thereby inhibiting the child's side-lying movement and reducing the probability of the child lying on his side.

Please refer to Figure 8. The adjustment component includes a swivel 504, which is rotatably connected to one end of the adjacent first piston shaft 9 close to the adjacent hinged rod 502. The swivel 504 is rotatably connected to the adjacent hinged rod 502. A fourth elastic element 505 is arranged between the swivel 504 and the adjacent hinged rod 502. The fourth elastic element 505 is a torsion spring. The fourth elastic element 505 is used to increase the fit between the one-way pulley 503 and the adjacent resistance plate 501. A limiting component for locking the adjacent swivel 504 is arranged at one end of the first piston shaft 9 close to the adjacent resistance plate 501. Torsion is applied to the adjacent fourth elastic element 505 by rotating the swivel 504. The torque of the fourth elastic element 505 increases the fit between the adjacent one-way pulley 503 and the adjacent resistance plate 501 through the adjacent hinged rod 502, thereby adjusting the sliding friction of the one-way pulley 503 along the adjacent resistance plate 501.

Please refer to Figure 8. The limiting assembly includes an insertion shaft 506, which is threadedly connected to the adjacent swivel 504. The first piston shaft 9 is provided with a ring array of limiting holes 507. The ring array of limiting holes 507 are all limitedly matched with the adjacent insertion shaft 506. The insertion shaft 506 passes through the swivel 504 and enters the adjacent limiting hole 507, thereby locking the adjacent swivel 504 and maintaining the torque of the adjacent fourth elastic element 505 unchanged.

After the face-fitting airbag 7 and the head-protecting airbag 8 are fixed to the child's head, the staff rotates the two swivels 504 according to the age of the child. The swivels 504 rotate along the adjacent first piston shaft 9, and the swivels 504 drive the adjacent fourth elastic element 505 to twist. The twisted fourth elastic element 505 drives the adjacent one-way pulley 503 to further fit the adjacent resistance plate 501 through the adjacent hinged rod 502, thereby increasing the supporting force of the resistance plate 501 on the adjacent one-way pulley 503, thereby increasing the friction force of the one-way pulley 503 sliding along the resistance plate 501. After the swivel 504 is rotated to the required position, the staff rotates the plug shaft 506 into the swivel 504, and at the same time makes the plug shaft 506 enter the limiting hole 507 behind the first piston shaft 9, so that the plug shaft 506 limits and locks the swivel 504. At this time, the adjustment is completed, and the fourth elastic element 505 is twisted by the swivel 504, so that the torsional force of the fourth elastic element 505 drives the one-way pulley 503 to further fit the resistance plate 501, thereby increasing the supporting force of the resistance plate 501 on the adjacent one-way pulley 503, and then increasing the friction force of the one-way pulley 503 sliding along the resistance plate 501.

When the rack 10 drives the adjacent first piston shaft 9 to be pushed inwardly along the gas injection cylinder 6, the first piston shaft 9 pulls the hinge rod 502 thereon to move synchronously, and the hinge rod 502 pulls the adjacent one-way pulley 503 to slide synchronously along the adjacent resistance plate 501. At this time, the one-way pulley 503 does not rotate, and the one-way pulley 503 slides frictionally along the adjacent resistance plate 501, thereby generating resistance to the movement of the first piston shaft 9, so that the child needs to overcome a certain resistance when turning from supine to side-lying, thereby inhibiting The child's side-lying movement reduces the probability of the child lying on his side. At the same time, as the one-way pulley 503 gradually slides along the resistance plate 501, the height of the resistance plate 501 gradually increases, and the resistance plate 501 squeezes the adjacent one-way pulley 503, so that the one-way pulley 503 drives the adjacent hinged rod 502 to deflect along the adjacent first piston shaft 9, so that the fourth elastic element 505 is further twisted, and then the sliding friction of the one-way pulley 503 along the resistance plate 501 is gradually increased, thereby further inhibiting the child from lying on his side.

When the first piston shaft 9 is reset along the gas injection cylinder 6, the first piston shaft 9 drives the adjacent hinged rod 502 to reset synchronously, and the hinged rod 502 drives the one-way pulley 503 to reset synchronously. At this time, the one-way pulley 503 can rotate, so that the one-way pulley 503 rotates and moves along the adjacent resistance plate 501 to reset.

The above descriptions are merely embodiments of the present invention and are not intended to limit the patent scope of the present invention. Any equivalent structure or equivalent process transformation made using the contents of the present invention specification, or directly or indirectly applied in other related technical fields, are also included in the patent protection scope of the present invention.

Claims (10)

1. The utility model provides a fixed headrest of decompression type for craniocerebral suture early closure postoperative rehabilitation, its characterized in that, including flexible pillow (1), flexible pillow (1) internal rotation is connected with mirror image distribution's commentaries on classics roller (2) all fixedly connected with hawser (3) are twined to mirror image distribution commentaries on classics roller (2) all with be provided with first elastic element (4) between flexible pillow (1), mirror image distribution changeing roller (2) all fixedly connected with gear (5), flexible pillow (1) is close to mirror image distribution one side fixedly connected with of gear (5) annotates gas cylinder (6), mirror image distribution's hawser (3) all fixedly connected with face-attached gasbag (7), mirror image distribution's all fixedly connected with head-protecting gasbag (8), the first piston axle (9) of mirror image distribution are sealed sliding connection to gas cylinder (6) first piston axle (9) and gas cylinder (6) cooperation form airtight cavity, mirror image distribution's one side fixedly connected with gas cylinder (6) is close to one side fixedly connected with gas cylinder (7), mirror image distribution (7) all fixedly connected with face-attached gasbag (8), the closed cavity is communicated with the face-attached air bags (7) in mirror image distribution through the first air injection pipe (11), and fixing components for fixing the head-protecting air bags (8) in mirror image distribution are arranged on the head-protecting air bags.

2. The pressure reduction type fixed headrest for craniotomy rehabilitation according to claim 1, wherein the head protection air bag (8) is arc-shaped and has a hollow structure inside.

3. The pressure reduction type fixed headrest for craniosynostosis postoperative rehabilitation according to claim 1, wherein the fixing component comprises mirror image distributed second piston shafts (201), the mirror image distributed second piston shafts (201) are respectively and fixedly connected to one sides, far away from the adjacent face-attached air bags (7), of the adjacent head-protecting air bags (8), the mirror image distributed second piston shafts (201) are jointly and slidably connected with a butt joint shell (202), second elastic elements (203) are arranged between the mirror image distributed second piston shafts (201), the second elastic elements (203) are located inside the butt joint shell (202), and the mirror image distributed second piston shafts (201) are all provided with locking components for locking the head-protecting air bags.

4. A pressure reduction type fixed headrest for rehabilitation after craniosynostosis operation according to claim 3, characterized in that the locking assembly comprises a linear array of saw-tooth blocks (301), the linear array of saw-tooth blocks (301) are fixedly connected to adjacent second piston shafts (201), a limiting shaft (302) is slidingly connected to one side of the butt joint shell (202) close to the adjacent linear array of saw-tooth blocks (301), the linear array of saw-tooth blocks (301) are in limiting fit with the adjacent limiting shaft (302), a third elastic element (303) is arranged between the limiting shaft (302) and the butt joint shell (202), and the butt joint shell (202) is provided with a detection assembly for detecting the distance between mirror images and distributing the face-attaching air bags (7).

5. The pressure reduction type fixed headrest for craniosynostosis postoperative rehabilitation according to claim 4, wherein the detection assembly comprises an elastic telescopic rod (401), the elastic telescopic rod (401) is fixedly connected to the outside of the air injection tube (6), the second piston shaft (201) distributed in a mirror image mode is matched with the butt joint shell (202) to form a closed cavity, the butt joint shell (202) is fixedly connected with a second air injection tube (402) through a fixing portion of the elastic telescopic rod (401), the closed cavity is communicated with the second air injection tube (402), the fixing portion of the elastic telescopic rod (401) is communicated with the second air injection tube (402), and the self-adjusting air injection tube (6) is provided with an assembly for adjusting initial pressure in the face attaching air bag (7).

6. The pressure reducing type fixed headrest for craniosynostosis postoperative rehabilitation according to claim 5, wherein the self-adjusting assembly comprises a third piston shaft (403), the third piston shaft (403) is fixedly connected to the telescopic end of the elastic telescopic rod (401), the middle part of the air injection cylinder (6) is fixedly connected and communicated with an adjusting cylinder (404), and the third piston shaft (403) is in sealing sliding connection with the adjusting cylinder (404).

7. The pressure reduction type fixed headrest for craniosynostosis postoperative rehabilitation according to claim 6, further comprising a resistance component in mirror image distribution, wherein the resistance component is used for increasing the sliding resistance of adjacent first piston shafts (9) along the air injection cylinder (6), the resistance component is arranged on the adjacent first piston shafts (9), the resistance component comprises a resistance plate (501), the resistance plate (501) is fixedly connected to one side, close to the adjacent first piston shafts (9), of the flexible pillow (1), the first piston shafts (9) are hinged with a hinge rod (502), the hinge rod (502) is provided with a unidirectional pulley (503), the unidirectional pulley (503) is attached to the adjacent resistance plate (501), and the first piston shafts (9) are provided with an adjusting component for adjusting the resistance of the adjacent unidirectional pulley (503) and the adjacent resistance plate (501).

8. The pressure reduction type fixed headrest for craniosynostosis postoperative rehabilitation according to claim 7, characterized in that the thickness of the resistance plate (501) gradually decreases from one end close to the adjacent first piston shaft (9) to the other end, and the joint surface of the resistance plate (501) and the adjacent unidirectional pulley (503) is a rough surface.

9. The pressure reduction type fixed headrest for craniosynostosis postoperative rehabilitation according to claim 8, characterized in that the adjusting assembly comprises a swivel (504), the swivel (504) is rotatably connected to one end of the first piston shaft (9) adjacent to the hinge rod (502), the swivel (504) is rotatably connected to the hinge rod (502) adjacent to the hinge rod, a fourth elastic element (505) is arranged between the swivel (504) and the hinge rod (502) adjacent to the swivel, and a limiting assembly for locking the swivel (504) adjacent to the first piston shaft (9) is arranged at one end of the first piston shaft adjacent to the resistance plate (501) adjacent to the hinge rod.

10. The pressure reduction type fixed headrest for craniosynostosis postoperative rehabilitation according to claim 9, characterized in that the limiting assembly comprises an inserting shaft (506), the inserting shaft (506) is connected to the adjacent rotating ring (504) in a penetrating and threaded manner, the first piston shaft (9) is provided with limiting holes (507) of an annular array, and the limiting holes (507) of the annular array are in limiting fit with the adjacent inserting shaft (506).