CN209931609U - Impact-resistant structure of helmet - Google Patents

Abstract

The utility model discloses a shock resistance structure of helmet, the inboard of helmet inside lining is equipped with makes the inside lining for helmet user head pivoted gleitbretter when the helmet receives the rotatory impact, the gleitbretter be multilayer structure, the gleitbretter is including being close to the skin of inside lining and the inlayer that is close to helmet user head, the gleitbretter still includes the one deck setting and is in between skin and the inlayer and make the inlayer for the gliding intermediate level of inlayer when the helmet receives the rotatory impact. When the helmet is impacted by external force, the outer layer of the slip sheet can slide for a certain distance relative to the inner layer, namely, the whole helmet can rotate for a certain angle relative to the head, so that the impact of the external force on a user is greatly reduced, and the effect of protecting the head of the user is achieved.

Description

Impact-resistant structure of helmet

Technical Field

The utility model belongs to the technical field of the safety protection technique and specifically relates to a structure of shocking resistance of helmet that has buffering protective action when suffering rotatory impact to the helmet.

Background

Helmets are commonly used as safety protection devices, and prior art helmets generally comprise an outer shell and an inner liner disposed inside the outer shell, wherein the outer layer of the outer shell is a rigid shell that prevents penetration, the inner layer of the shell is a liner for absorbing impact energy and dispersing impact load, and the inner liner for wearing the helmet on the head of a user is disposed inside the liner at a distance from the liner. The helmet in the prior art can effectively reduce the harm to the head of a user when the helmet is impacted in the radial direction (namely the normal direction of the outer surface of the helmet), but actually when an impact accident happens, the probability that the helmet bears simple radial impact force is small, more times, the impact force in the tangential direction of the helmet exists besides the radial impact force of the helmet, and under the action of the tangential impact force, the helmet is easy to rotate at a certain angle, so that the head of the user is easy to contort. Recent studies in the field of brain trauma have shown that shear forces generated by rotational impact on the brain are much greater in damaging brain cells than radial forces. Several studies have shown that human Brain tissue is much more sensitive to shear forces than the radial compression forces applied during impact, and that the head is prone to a variety of Mild Brain trauma (Mild trauma Brain trauma) such as Diffuse axial Injury or Subdural Hematoma (Subdura Hematoma) following a rotational impact. On the other hand, prior art helmet anti-rotational impact structures typically have a large radial length and are therefore difficult to fit into a wide range of helmets, are not very compatible or interfere with the comfort of the helmet during wear. Chinese patent publication No. CN 109198767A, published 2019, 1, 15, discloses a protective helmet with an integrated rotation limiter, the helmet comprising an outer liner and an inner liner slidably coupled to an inner surface of the outer liner by at least one return spring. The outer liner includes an inner surface with an inwardly extending shelf. The shelf includes a stop surface. The liner has an outer surface, an inner surface, and a rim connecting the outer surface to the inner surface. The edge faces the stop surface of the shelf. The inner liner is slidably movable relative to the outer liner between a first position in which the rim of the inner liner is separated from the stop surface of the shelf by a gap and a stop position in which a portion of the rim of the inner liner contacts a portion of the stop surface of the shelf. The inner liner of the helmet is slidably coupled to the inner surface of the outer liner by a return spring such that it is slidably movable relative to the outer liner between a first position and a stop position to cushion external rotational impact forces. However, the structure of the buffering helmet is too complex, and therefore, it is a problem to be solved urgently to design an impact-resistant structure of the helmet which has a good buffering effect on external rotation impact force and can not cause head contusion when the helmet is subjected to external rotation impact.

SUMMERY OF THE UTILITY MODEL

The utility model aims at overcoming present helmet and existing to bear the rotatory impact ability of external force relatively poor, the head easily receives the not enough of contusion when receiving the rotatory impact of external force, provides the shock-resistant structure of a helmet, and this helmet has fine cushioning effect to outside rotatory impact force, and the difficult contusion of user's head when receiving the rotatory impact of external force, simultaneously the utility model discloses a helmet protective structure can use on current helmet, and is compatible very strong, can not exert an influence to the travelling comfort that the helmet was worn.

The utility model discloses a technical scheme that realizes that above-mentioned purpose adopts is, a shock-resistant structure of helmet, the helmet include the shell, still including setting up the inside lining in the shell, be equipped with the clearance between shell and the inside lining, clearance department between shell and the inside lining is equipped with a plurality of cushion post, the inboard interval ground of inside lining is equipped with the multi-disc and makes the inside lining for helmet user head pivoted gleitbretter when the helmet receives rotatory impact, the gleitbretter be multilayer structure, the gleitbretter is including being close to the skin of inside lining and the inlayer that is close to helmet user head, the gleitbretter still includes that the one deck sets up between skin and the inlayer and make the inlayer for the gliding intermediate level of inlayer when the helmet receives rotatory impact. The utility model discloses a helmet is equipped with the buffering gleitbretter of the anti rotatory impact of multi-disc at the inboard interval of inside lining of helmet, and the gleitbretter has the ascending deformation function of helmet tangential, when the helmet receives external force and assaults, acts on in the external force component in shell tangential and makes the inside lining have for helmet user head pivoted trend, and the utility model discloses a horizontal relative slip between the gleitbretter, in the inlayer of gleitbretter under the motionless prerequisite, the skin of gleitbretter is for the certain distance of inlayer slidable, is whole helmet rotates certain angle for the head promptly to play the effect that the pairing rotation (the tangential of helmet surface) strikeed the buffering, just so by a wide margin has subdued the impact of external force to user's head. Meanwhile, the sliding sheet of the sheet structure occupies less space (namely, the thickness of the sliding sheet is smaller) in the radial direction of the helmet (namely, the normal direction of the outer surface of the helmet), and basically does not influence the size of the inner size of the helmet, so that the sliding sheet can be used on various types of helmets, has strong compatibility, and does not influence the wearing comfort of the helmets. Although the utility model discloses an inner wall of shell can directly be applied to the gleitbretter, nevertheless when being equipped with the clearance between inside lining and the shell, because also have the buffering effect of anti rotatory impact between the inside lining of unsettled setting and the shell, consequently this kind of structure has better anti rotatory impact effect. In addition, the slip sheet of the sheet structure can increase the effective contact area between the slip sheet and the head of a user in the helmet, the structural stability of the slip sheet under the action of tangential force is increased, the buffering amplitude is increased, and the improvement of the buffering performance of the slip sheet under the action of the tangential force is facilitated. Therefore, the utility model provides a present helmet exist bear the rotatory impact ability of external force relatively poor, helmet user head arouses easily after receiving the rotational impact that the Diffuse axon harms (Diffuse axial Injury) or the problem of multiple light-duty Brain trauma (Mill traffic Brain Injury) such as Subdural Hematoma (Subdural Hematoma), has improved helmet user's guard action by a wide margin.

Preferably, the middle layer is a damping layer, and the damping layer is used for reducing the dry friction force between the outer layer and the inner layer, so that the outer layer and the inner layer have sliding property and rebound resilience; the medium used for damping in the damping layer is a semi-fluid structure, and the medium is composed of liquid, colloid and ferrofluid or a mixture of at least two of gas, liquid, solid, colloid and ferrofluid. Although the outer layer and the inner layer of the slip sheet can be directly attached to each other to generate transverse sliding, the collision probability of the helmet is relatively small, the outer layer and the inner layer are attached to each other for a long time and are easy to adhere to each other, and meanwhile, the change range of the friction coefficient of dry friction between the outer layer and the inner layer is large, so that the sliding buffering amplitude of different positions on each slip sheet is easy to be different when the slip sheet is subjected to tangential impact, and the buffering effect is influenced; and the damping layer is arranged between the outer layer and the inner layer, so that the buffering amplitude of each part of the stressed slip sheet is balanced, and the buffering effect of tangential impact resistance is effectively exerted. In addition, the friction between the outer layer and the inner layer is not smaller and better, the impact force of the helmet is difficult to reduce when the helmet is subjected to tangential impact due to the small friction between the outer layer and the inner layer, the shell rotates too fast relative to the head, and the injury to a user can be caused. The sliding property refers to that when a tangential force is applied, the inner layer and the outer layer of the sliding sheet can slide relatively; the rebound resilience is the function of restoring the state of the slip sheet between the inner and outer layers which have slid relatively within a certain range of amplitude when the tangential force disappears.

Preferably, one surface of the outer layer of the slip sheet close to the inner liner is fixed with the inner liner in a mode of adhesive, sticking film, hooking, heat fusion or integral molding; the inner layer of the sliding sheet is provided with a pad on one side close to the head of a user of the helmet, and the pad is made of fabric, foam, fiber or thermoplastic plastics. Set up the pad on the gleitbretter inlayer, the sense of touch and be favorable to increasing the gas permeability of head to the helmet when can change helmet user and wear the helmet, improve the travelling comfort that the helmet was worn.

Preferably, the outer layer and the inner layer have the same projection size in the radial direction of the helmet, an elastic film is arranged on the periphery of the middle layer, and the elastic film seals the periphery of the middle layer between the outer layer and the inner layer; one end of the elastic film close to the outer layer extends to the periphery of the outer layer and at least covers part of the peripheral surface of the outer layer, and one end of the elastic film close to the inner layer extends to the periphery of the inner layer and at least covers part of the peripheral surface of the inner layer. The gleitbretter skin is the same with inlayer at the radial ascending projection size of helmet and is the same with the size of inlayer, set up the elastic film in the periphery in intermediate level, this elastic film can stretch and the intermediate level of cladding semifluid column structure all the time when the gleitbretter appears small amplitude slip to play effectual protection to the intermediate level of semifluid column, especially when the gleitbretter adopts rectangular form structure, at this moment the size of gleitbretter width direction is less, the contact surface of gleitbretter both sides and external environment is great relatively and receive external environment influence easily. Therefore, the damping medium of the middle layer can always keep the effectiveness in the long-time use process of the helmet, and the influence of external dust and the like on the performance of the middle layer due to the entering of the external dust and the like into the middle layer is avoided; meanwhile, the helmet is subjected to slight tangential force, and the sliding sheet is easy to reset due to the additional tensile force of the elastic film when sliding in a small amplitude, so that the integrity of the whole structure of the sliding sheet is maintained.

Preferably, the elastic film positioned at the periphery of the middle layer is provided with a groove surrounding the middle layer, and the groove is arranged on the outer wall or the inner wall of the elastic film. When the helmet is subjected to strong tangential impact force, the groove surrounding the sliding sheet on the elastic film can be easily torn, and the relative sliding between the inner layer and the outer layer of the sliding sheet can not be influenced, so that the tangential impact resistance buffering function of the sliding sheet can not be influenced.

Preferably, the inner layer is an elastic body, one surface of the inner layer, which is close to the middle layer, is provided with an inner layer elastic support, one end of the inner layer elastic support is integrally connected with the inner layer, the other end of the inner layer elastic support penetrates through the middle layer, and the end part of the inner layer elastic support is abutted to the outer layer. For the sliding sheet with the relatively large thickness of the middle layer, the inner layer elastic support is arranged on the inner layer of the elastic body and extends towards the middle layer, so that the distance between the inner layer and the outer layer of the sliding sheet can be kept stable, the relative sliding performance between the inner layer and the outer layer of the sliding sheet is prevented from being influenced due to the fact that the middle layer of the sliding sheet is extruded for a long time to generate permanent compression deformation after the helmet is used, and the impact resistance of the sliding sheet is prevented from being reduced; simultaneously can also make the gleitbretter have the radial ascending elastic deformation function of helmet, further slow down the impact of the radial impact force of helmet to user's head, in addition, the resilience of gleitbretter can be increased in the setting of elastic support. Because the inner layer elastic strut is only abutted to the outer layer, the elastic strut can move relative to the outer layer, and therefore the buffer function of the slip sheet for resisting tangential impact is not influenced.

Preferably, the outer layer is an elastic body, an outer layer elastic strut is arranged on one surface of the outer layer, which is close to the middle layer, one end of the outer layer elastic strut is integrally connected with the outer layer, the other end of the outer layer elastic strut penetrates through the middle layer, and the end part of the outer layer elastic strut is abutted to the inner layer. The outer layer can be provided with elastic struts corresponding to the elastic struts arranged on the inner layer.

Preferably, the inner layer is provided with an inner layer elastic support column near the middle layer, the outer layer is provided with an outer layer elastic support column near the middle layer, and the outer layer elastic support column and the inner layer elastic support column are arranged in the middle layer in a staggered mode. The elastic support column can be independently arranged on the inner layer, can also be independently arranged on the outer layer, can be arranged on the inner layer and the outer layer, and is arranged in the middle layer in a staggered manner when the inner layer and the outer layer are arranged.

Preferably, the outer layer elastic support and the inner layer elastic support have the same structure, and are all one or a combination of a cylinder shape, a prism shape, a cone shape, a pyramid shape, a truncated cone shape and a truncated pyramid shape.

Preferably, the sliding sheet is in a circular, oval or polygonal shape or a combination shape thereof, the lining is a connection structure of two lining belts, the connection structure comprises a U-shaped lining belt positioned at the top of the head and an annular lining belt encircling the side periphery of the head, and the sliding sheet is attached to the inner side of the lining belt.

Preferably, the impact-resistant structure of the helmet further comprises a U-shaped buffer strip, one end of the U-shaped buffer strip is connected with the lining, the other end of the U-shaped buffer strip is connected with one end of the connecting strip, the other end of the connecting strip is provided with a buckle head, the inner side of the shell is provided with a buckle hole matched with the buckle head, and the buckle head is correspondingly clamped with the buckle hole; the U-shaped buffer strips are two and are respectively arranged on the annular lining belts on the left side and the right side of the rear part of the helmet, two binding strips are correspondingly arranged at the joints of the U-shaped buffer strips and the lining, and the other ends of the binding strips are connected with the head lock. The lining is connected with the shell into a whole through the U-shaped buffer strip and the connecting strip and is used for limiting excessive slippage between the lining and the shell, and preventing the shell from rotating excessively relative to the lining when the shell receives rotating impact, so that the shell is controlled to rotate in a certain range relative to the lining; on the other hand U-shaped buffering strip can constitute the buffer gear between inside lining and the shell, plays the cushioning effect receiving tangential force, further promotes the buffering effect that the helmet received when revolving force strikes, and the fixed mode of buckle head and buckle hole adaptation can make things convenient for the dismouting. The utility model discloses a U-shaped buffering strip sets up in the helmet rear portion left and right sides, and U-shaped buffering strip and the junction of inside lining and the junction of strake and inside lining are in on the same position, and the effect of head lock is the elasticity of adjustment strake, and the protection of head when strake and head clearance fit do benefit to properly receiving the rotatory impact of external force.

The utility model has the advantages that: set up the gleitbretter through the inside lining inboard at the helmet, utilize in the gleitbretter, relative slip between the skin, can subdue the tangential component of helmet when receiving external force impact by a wide margin, reduced the impact that external force caused to the user by a wide margin, it is relatively poor to have solved present helmet existence and bear the rotatory impact ability of external force, the head easily receives the not enough of contusion when receiving external force rotatory impact, the utility model discloses a helmet protection architecture can use on current helmet, and compatibility is very strong, can not exert an influence to the travelling comfort that the helmet was worn, has improved the protective action of helmet to the user by a wide margin.

Drawings

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

FIG. 2 is a schematic cross-sectional view of a sliding sheet according to embodiment 1 of the present invention;

fig. 3 is a schematic cross-sectional structure diagram of a sliding sheet according to embodiment 2 of the present invention;

fig. 4 is a schematic cross-sectional structure of a sliding sheet according to embodiment 3 of the present invention;

fig. 5 is a schematic cross-sectional structure of a sliding sheet according to embodiment 4 of the present invention;

fig. 6 is a schematic bottom view of the helmet of the present invention.

In the figure: 1. the novel plastic pipe comprises a shell, 2. an inner liner, 3. a sliding sheet, 4. an outer layer, 5. an inner layer, 6. an intermediate layer, 7. a liner, 8. an elastic film, 9. an inner layer elastic strut, 10. an outer layer elastic strut, 11. a buffer column, 12. a U-shaped inner liner belt, 13. an annular inner liner belt, 14. a U-shaped buffer strip, 15. a connecting strip, 16. a buckle head, 17. a buckle hole, 18. a binding strip, 19. a head lock and 20. a groove.

Detailed Description

The following provides a further description of the embodiments of the present invention with reference to the accompanying drawings.

Example 1

In embodiment 1 as shown in fig. 1 and 2, an impact-resistant structure of a helmet includes an outer shell 1, and further includes an inner liner 2 disposed in the outer shell, a gap is provided between the outer shell and the inner liner, a plurality of buffer posts 11 are disposed in the gap between the outer shell and the inner liner, a plurality of sliding pieces 3 are disposed at intervals on the inner side of the inner liner, the sliding pieces are configured to rotate the inner liner relative to the head of a user when the helmet is subjected to rotational impact, each sliding piece has an oval multi-layer structure, and includes an outer layer 4 close to the inner liner and an inner layer 5 close to the head of the user, and each sliding piece further includes an intermediate layer 6 disposed between the outer layer and the inner layer and configured to slide the outer layer relative to the inner layer when the helmet is subjected to.

The intermediate level of this embodiment is the damping layer, the damping layer is used for reducing the dry friction between skin and the inlayer, makes have gliding nature and resilience between skin and the inlayer, and the medium that is used for the damping in the damping layer is the glue solution of semifluid form, has certain resilience under the prerequisite that has mobility, and the thickness of intermediate level is 0.35 millimeter. The medium in the damping layer can also be composed of liquid, colloid, ferrofluid, etc., or a mixture of at least two of gas, liquid, solid, colloid and ferrofluid.

The outer layer and the inner layer of the slip sheet have the same projection size in the radial direction of the helmet, and one surface of the outer layer of the slip sheet, which is close to the inner liner, is fixed with the inner liner in a mode of an adhesive; the sliding sheet and the lining can be fixed by sticking film, hooking, heat fusion or the like, or can be a structure formed on the lining in an integrated way.

The lining of the embodiment is a connection structure of two lining belts, and comprises a U-shaped lining belt 12 positioned at the top of the head and an annular lining belt 13 (see fig. 6, the annular lining belt is not fully drawn in the figure, and the slip sheet is circular) encircling the side wall part of the head, the slip sheet is respectively attached to the inner sides of the U-shaped lining belt and the annular lining belt, and the connection structure is arranged between the U-shaped lining belt and the helmet shell and between the annular lining belt and the helmet shell.

The anti-impact structure of the helmet further comprises a U-shaped buffer strip 14, one end of the U-shaped buffer strip is connected with the lining, the other end of the U-shaped buffer strip is connected with one end of a connecting strip 15, the other end of the connecting strip is provided with a buckle head 16, the inner side of the shell is provided with a buckle hole 17 matched with the buckle head, and the buckle head is correspondingly clamped with the buckle hole; the U-shaped buffer strips are two and are respectively arranged on the annular lining belts on the left side and the right side of the rear part of the helmet, two binding strips 18 are correspondingly arranged at the joints of the U-shaped buffer strips and the lining, and the other ends of the binding strips are connected with a head lock 19.

Example 2

The inner layer of the slider of example 2 is provided with a pad 7 (see figure 3) on the side adjacent to the head of the helmet user, said pad being made of fabric, or alternatively of foam, fabric or thermoplastic material, the thickness of the middle layer being 0.7 mm, the rest being the same as in example 1.

Example 3

The inner layer of embodiment 3 is an elastic body made of latex, the thickness of the middle layer is 0.9 mm, one surface of the inner layer, which is close to the middle layer, is provided with an inner layer elastic strut 9, the inner layer elastic strut is in a circular truncated cone shape, one end of the inner layer elastic strut is integrally connected with the inner layer, the other end of the inner layer elastic strut penetrates through the middle layer, the end of the inner layer elastic strut is abutted to the outer layer (see fig. 4), the elastic strut can also adopt one or a combination structure of a cylinder, a prism, a cone, a pyramid and a truncated pyramid, and the rest is the same as that of embodiment 1 or embodiment 2.

Example 4

The outer layer and the inner layer of the embodiment 4 have the same projection size in the radial direction of the helmet, the thickness of the middle layer is 1.8 mm, the periphery of the middle layer is provided with an elastic film 8 (see fig. 5) made of latex, and the elastic film seals the periphery of the middle layer between the outer layer and the inner layer; the one end that the elastic film is close to the skin extends to the outer periphery and covers outer peripheral face, and the one end that the elastic film is close to the inlayer extends to the periphery of inlayer and covers the outer peripheral face of inlayer. The outer layer of the embodiment is made of latex, an outer layer elastic strut 10 is arranged on one surface of the outer layer close to the middle layer, the outer layer elastic strut is conical, one end of the outer layer elastic strut is integrally connected with the outer layer, the other end of the outer layer elastic strut penetrates through the middle layer, and the end part of the outer layer elastic strut is abutted to the inner layer; the elastic film located on the outer periphery of the intermediate layer is provided with grooves 20 surrounding the intermediate layer, the grooves being provided on the outer wall of the elastic film, the rest being the same as in embodiment 1 or embodiment 2 or embodiment 3.

Example 5

The thickness of the middle layer of example 5 is 2.5 millimeters, and the outer layer and the inner layer are all equipped with elastic support, and wherein outer layer elastic support and inner layer elastic support dislocation set in the middle layer. The outer layer elastic support column and the inner layer elastic support column have the same structure and are cylindrical, and the rest is the same as that of the embodiment 1, the embodiment 2 or the embodiment 3.

The utility model discloses a helmet is equipped with the buffering gleitbretter of anti rotatory impact in the inside lining inboard of helmet, and the gleitbretter has the ascending deformation function of helmet tangential, when the helmet received external force and assaults, acts on in the external force that the ascending component of shell tangential makes the inside lining have for helmet user head pivoted trend, and the utility model discloses an in the gleitbretter, horizontal relative slip between the skin, under the inlayer motionless prerequisite of gleitbretter relatively, the skin of gleitbretter can slide certain distance for the inlayer, whole helmet rotates certain angle for the head promptly to play the effect of pairing rotation impact buffering, just so subducted the impact of external force to user's head by a wide margin. Meanwhile, the sliding sheet of the sheet structure occupies less space in the radial direction of the helmet, and basically does not influence the size of the inner size of the helmet, so that the sliding sheet can be used on various types of helmets, has strong compatibility, and does not influence the wearing comfort of the helmets. Thus, the utility model provides a present helmet exist bear the rotatory impact ability of external force relatively poor, helmet user head receives the problem of injury after receiving the rotatory impact easily, has improved helmet to user's guard action by a wide margin.

In addition to the above embodiments, the technical features or technical data of the present invention can be selected and combined again within the scope disclosed in the claims and the specification of the present invention to constitute new embodiments, which can be realized by those skilled in the art without creative efforts, and therefore, the embodiments of the present invention not described in detail should be regarded as specific embodiments of the present invention and within the protection scope of the present invention.

Claims (10)

1. An impact-resistant structure for a helmet comprising an outer shell (1), characterized in that: the helmet further comprises an inner liner (2) arranged in the shell, a gap is formed between the shell and the inner liner, a plurality of buffer columns (11) are arranged in the gap between the shell and the inner liner, a plurality of slip sheets (3) which enable the inner liner to rotate relative to the head of a helmet user when the helmet is subjected to rotary impact are arranged on the inner side of the inner liner at intervals, each slip sheet is of a multilayer structure and comprises an outer layer (4) close to the inner liner and an inner layer (5) close to the head of the helmet user, and each slip sheet further comprises a middle layer (6) which is arranged between the outer layer and the inner layer and enables the outer layer to slide relative to the inner layer when the helmet is subjected.

2. An impact-resistant structure for helmets according to claim 1, wherein: the middle layer is a damping layer, a medium used for damping in the damping layer is a semifluid structure, and the damping layer is used for reducing dry friction force between the outer layer and the inner layer, so that the outer layer and the inner layer have sliding property and resilience.

3. An impact-resistant structure for helmets according to claim 1, wherein: one surface of the outer layer of the slip sheet close to the inner liner is fixed with the inner liner in a mode of adhesive, sticking film, hooking, heat fusion or integral forming; and a pad (7) is arranged on one surface of the inner layer of the sliding sheet, which is close to the head of a user of the helmet.

4. An impact-resistant structure for helmets according to claim 1, wherein: the outer layer and the inner layer have the same projection size in the radial direction of the helmet, an elastic film (8) is arranged on the periphery of the middle layer, and the elastic film seals the periphery of the middle layer between the outer layer and the inner layer; one end of the elastic film close to the outer layer extends to the periphery of the outer layer and at least covers part of the peripheral surface of the outer layer, and one end of the elastic film close to the inner layer extends to the periphery of the inner layer and at least covers part of the peripheral surface of the inner layer.

5. An impact-resistant structure for helmets according to claim 1, wherein: the inlayer be the elastomer, the inlayer is close to intermediate level one side and is equipped with inlayer elastic support (9), inlayer elastic support's one end and inlayer body coupling, inlayer elastic support's the other end passes the intermediate level, its tip and outer butt.

6. An impact-resistant structure for helmets according to claim 1, wherein: the outer elastomer that is, outer near the intermediate level one side be equipped with outer elastic support post (10), outer elastic support post's one end and outer body coupling, outer elastic support post's the other end pass the intermediate level, its tip and inlayer butt.

7. An impact-resistant structure for helmets according to claim 1, wherein: the inlayer is close to the intermediate level one side and is equipped with inlayer elastic support, and the skin is close to the intermediate level one side and is equipped with outer elastic support, and outer elastic support and inlayer elastic support dislocation set in the intermediate level.

8. An impact-resistant structure for helmets according to claim 7 wherein: the structure of the outer layer elastic support is the same as that of the inner layer elastic support, and the outer layer elastic support and the inner layer elastic support are all one or a combination of a cylinder shape, a prism shape, a cone shape, a pyramid shape, a truncated cone shape and a truncated pyramid shape.

9. An impact-resistant structure for helmets according to claim 1, wherein: the slip sheet is circular, oval or polygonal, the lining is a connection structure of two lining belts and comprises a U-shaped lining belt (12) positioned at the top of the head and an annular lining belt (13) encircling the side wall part of the head, and the slip sheet is attached to the inner side of the lining belt.

10. An impact-resistant structure for a helmet as claimed in claim 9, wherein: the anti-impact structure of the helmet further comprises a U-shaped buffer strip (14), one end of the U-shaped buffer strip is connected with the lining, the other end of the U-shaped buffer strip is connected with one end of a connecting strip (15), the other end of the connecting strip is provided with a buckle head (16), the inner side of the shell is provided with a buckle hole (17) matched with the buckle head, and the buckle head is correspondingly clamped with the buckle hole; the U-shaped buffer strips are two and are respectively arranged on the annular lining belts at the left side and the right side of the rear part of the helmet, two binding strips (18) are correspondingly arranged at the joints of the U-shaped buffer strips and the lining, and the other ends of the binding strips are connected with a head lock (19).

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