CN211106078U - Layered structure for regulating zonal pressure and body-protecting article - Google Patents

Abstract

The utility model discloses a layered structure and a protective articles for use of regulation subregion pressure, a setting just can be according to the different characteristics of human muscle required protection pressure when the motion on close-fitting clothing and protective equipment, effectively protect the layered structure and the protective articles for use of regulation subregion pressure of human organism. The composite layer is arranged on the subarea of the tights or the protective clothing corresponding to the part of the body of a wearer needing to bear different pressure protection, and the pressure applied to the corresponding part by the different subareas is adjusted by changing the elastic modulus of the elastomer layer. When a sporter wearing the tight-fitting clothes or the protective clothing does exercises greatly, the body of the sporter can be effectively protected, excessive vibration of muscles at certain body parts is prevented, and the risk of muscle injury is reduced.

Description

Layered structure for regulating zonal pressure and body-protecting article

Technical Field

The present invention relates to a compression garment and a protective device, and more particularly to a layered structure provided on a compression garment and a protective device for applying different pressures to a certain part of a user's body, a method for manufacturing the same, and a compression garment and a protective device having the same.

Background

With the continuous development of the economic society, the desire of people for pursuing a beautiful life is continuously realized. In order to enhance physical fitness, more and more people participate in various fitness activities, and tights and special protectors for protecting certain parts of the body are favored by many sportsmen in order to reduce the risk of accidents caused by sports.

First, function of tights and protective equipment

Compression clothing and compression protective equipment can produce pressure to the skin of health and muscle, and its effect is as follows:

1. the body which is plump and easy to vibrate is protected, namely the muscle vibration of the part is reduced, so that the risk of injury of the part of the muscle caused by overlarge vibration amplitude in the movement process is reduced.

2. The body to be protected is restrained, and the excessive vibration of the muscles in the movement process is reduced, so that the energy excessive consumption of the muscles caused by frequent vibration is reduced.

3. After wearing the tights or the protectors, the tights or the protectors can provide pressure on the surface of human body muscles to stimulate the proprioception of the brain, so that the wearers have vigilant consciousness that the contact parts of the tights or the protectors need to be protected at any time, thereby reducing the risk of injury in sports.

In summary, for people in sports, some vulnerable parts of their body need to be protected by a tight fitting or protective clothing to give a certain pressure, while other parts can be neglected to be protected in this way. The part to be protected can be divided into areas (for short, partitions) according to the required pressure for partition management.

Second, classification of existing tights and protective equipment products

1. Classification of tights:

tights currently on the market are mainly classified into the following two types:

the first is that the elastic fabric is made of elastic fabric, and when the elastic fabric is cut, the size of the tights is smaller than that of the relevant parts of the body of a wearer, namely after the wearer wears the tights, the fabric of the tights deforms, so that the tights fabric exerts certain pressure on the human body, and the purpose of protecting the body is achieved. For example, the actual leg circumference of a wearer is 50cm and the leg circumference of the legs of the corresponding tights is 45cm, and after the wearer wears the fabric in this position is stretched from 45cm to 50cm, thereby creating pressure on the legs.

The disadvantages of the tights are as follows: because the fabric of the tights is integrated, the pressure generated by each part of the body of the wearer is uniform, and the aim of differential adaptive pressure application cannot be achieved (namely, the tights needs to generate larger pressure on the part needing large pressure protection, and the tights does not need the part needing large pressure protection and has pressure of the tights fabric).

Secondly, on the basis of the former ready-made clothes, the area needing larger pressure protection is hollowed out (the area is simply referred to as subarea hereinafter), then the fabric with larger elastic modulus is cut into the sheet material with the set shape, and the sheet material is spliced on the corresponding subarea by adopting sewing or hot pressing technology (the sheet material is referred to as spliced sheet material hereinafter). For example, the muscles of the front thigh part are easy to vibrate during movement, so that the muscles of the part need to be protected by applying larger pressure, the part is hollowed out, and then the piece materials which are cut in advance and have corresponding shapes and larger elastic modulus are spliced in the subarea.

The disadvantages of the tights are as follows:

1) when the fabric is spliced in a sewing mode, the thickness of the boundary of the subareas is 2-3 times of that of the normal fabric, and the structure enables a wearer to feel poor comfort.

2) Adopt sewing mode concatenation can receive the restriction of subregion place, if involve positions such as crotch portion, armpit depths, sewing machine's syringe needle just can't insert and carry out the sewing.

3) When the partition is spliced by adopting a hot pressing or gluing mode, the boundary of the partitions is easy to separate after long-term use, and the partition cannot be washed by water frequently.

4) The spliced fabric has larger area and less quantity, and the compression area can not be designed at will. The reason is that a splicing mode is adopted, and due to the limitation of a sewing process, a small splicing piece cannot be achieved, and because the smaller the splicing piece is, the more serious the wrinkles around the sewn fabric are, and the poorer the wearing comfort is.

5) When a user wears the tights, all parts of the tights are sleeved on the body parts corresponding to the human body in a closed-loop mode, and the pressure applied to the body parts at the corresponding positions by the splicing sheet materials cannot achieve the effect of preset pressure.

The reason for this is that the fibers of the spliced sheet material are different from the fibers of the body fabric of the tight fitting garment in the structure of non-unity and in the modulus of elasticity. When the pulling-on piece material and the body material are simultaneously subjected to external supporting force generated by the same body part (namely, the pulling-on piece material and the body material are supported by the wearing part of a human body, such as the trouser legs of a tight suit worn on the body of a user and tightened on the legs, the leg circumference is larger than the trouser leg circumference when the tight suit at the corresponding position is in a natural state, the leg part is subjected to pressure applied by the tight suit, and the leg part supports the trouser legs of the tight suit outwards for the tight suit), the splicing piece material and the body material of the tight suit can be mutually constrained in the circumferential direction around the corresponding body part, and the elastic deformation of the splicing piece material is smaller than that of the body material because the elastic modulus of the splicing piece material is larger than that of the body material, so that the body material can be excessively deformed under the action of the same external supporting force in the circumferential direction, and the body material can generate force larger than preset pressure on the corresponding body part, meanwhile, the body fabric which is in transition deformation can generate larger stretching force to the splicing material, so that the pressure generated by the splicing material to the corresponding body part is smaller than the preset pressure.

2. Classification of compression type protectors:

the protective clothing is also made of soft materials, is cylindrical, can be sleeved on a certain limb of a human body, is used for protecting the limb of the human body, and has the same protection principle as the tight-fitting clothing.

Protective clothing in the existing market mainly falls into two types:

the first type is a protective tool using woven fabric, which uses uniform fabric for cutting and sewing, so that the function of zoning pressure cannot be achieved; (principle of same tights)

Second, with knitted fabrics, the problem is:

1) the fabric is thick and heavy, and the wearing comfort is poor.

2) The high and low compression regions and pressure values cannot be designed arbitrarily due to process limitations.

3) The production time of each product is long, and the process cost is high.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model is to provide a setting on close-fitting clothes and protective equipment and can be according to the different characteristics of human muscle required protection pressure when the motion, effectively protect human organism's regulation subregion pressure's lamellar structure and preparation method and protective articles for use.

In order to solve the technical problem, the utility model discloses a technical scheme be:

the utility model discloses an adjust layer structure of subregion pressure on close-fitting clothing and the protective equipment, its characterized in that: the composite layer is formed by combining a surface layer and at least one elastomer layer which is fused into pores of the surface layer in a permeation mode, or is formed by combining the surface layer and at least one solid elastomer layer through gluing, the elastomer layer is in a mesh layer shape with a plurality of holes, a dot matrix layer shape, a queue layer shape or a film layer shape which is formed by combining a plurality of stripes, the composite layer is arranged on a part of a tight-fitting garment or a protective clothing, which corresponds to a part of a wearer body needing to bear different pressure protection, and the pressure applied to the part corresponding to the part by different partitions is adjusted by changing the elastic modulus of the elastomer layer.

The surface layer is made of elastic materials of knitting or tatting; the elastomer layer is TPE, TPU or other high polymer elastic materials.

The surface layer is made of nylon, polyester ammonia, rubber band silk or other elastic fabrics and is separately cut and fixedly connected with the sheet materials on the corresponding subarea of the tights or the protective gear, or the surface layer is the elastic fabrics on the tights or the protective gear.

The composite layer has a modulus of elasticity greater than the modulus of elasticity of the facing layer therein.

The elastic magnitude of the elastomer layer is varied by setting one or more of the texture shape, the degree of openness, and the thickness of the elastomer layer.

The utility model discloses a setting is adjusted zone pressure's on close-fitting clothing and protective equipment lamellar structure's preparation method, its characterized in that adopts following step:

1) determining a pressure difference part which is to be protected by a tight-fitting garment or a protective tool and has different protection pressures and the three-dimensional shape of the pressure difference part on a human body;

2) dividing areas corresponding to the pressure difference parts on the tights or the protective clothing according to the pressure difference, and selectively arranging a layered structure with a set shape and a set elastic modulus in a plurality of areas with high required protective pressure;

3) the layered structure is manufactured by the following method:

a. placing a solid or molten high-molecular elastic material on a surface layer made of a knitted or woven elastic fabric, and penetrating the high-molecular elastic material into pores of the surface layer in a hot pressing or soaking mode to form a composite layer which is formed by integrating an elastic body layer and the surface layer; or a composite layer which is formed by tightly combining at least one solid elastomer layer made of high polymer elastic materials and a surface layer made of knitted or woven elastic fabrics through an adhesive process;

b. cutting the composite layer into sheet materials with corresponding shapes according to the shape of the layered structure required by each subarea, and then fixedly connecting each sheet material on the corresponding subarea;

alternatively, the first and second electrodes may be,

c. placing the solid or molten macromolecular elastic material on the relevant subarea on the tights or the protective equipment, and infiltrating the macromolecular elastic material into the pores of the main fabric of the tights or the protective equipment corresponding to the subarea by adopting a hot pressing or soaking mode to form a composite layer which is formed by integrating an elastomer layer and the main fabric of the subarea;

alternatively, the first and second electrodes may be,

d. at least one solid elastomer layer made of high molecular elastic material is arranged on a relevant subarea of the tights or the protective clothing, and the elastomer layer is fixedly connected with the main surface material of the corresponding subarea through an adhesive process.

The preparation method of the utility model is characterized in that: the shape of the elastomer layer is a mesh layer shape with a plurality of holes, a lattice layer shape, a queue layer shape formed by combining a plurality of stripes or a film layer shape; the elastic modulus of the elastomer layer is adjusted by setting one or more of the texture shape, the density degree and the thickness of the elastomer layer.

The utility model discloses a close-fitting clothing, including the main surface fabric of elastic fabric preparation, its characterized in that: be equipped with a plurality of subregion on the main panel material, every subregion corresponds a human body position that needs great pressure protection, is equipped with on every subregion the utility model discloses a laminated structure.

The utility model discloses a close-fitting clothes, its characterized in that: the subareas comprise main surface material parts corresponding to trapezius and levator scapulae of the neck, pectoralis major and anterior serratus of the chest, latissimus dorsi of the back, rectus abdominis and extraabdominal oblique muscles of the abdomen, deltoid muscle of the shoulder, biceps brachii and triceps brachii of the upper arm, phalangeal muscle group of the forearm, rectus femoris and quadriceps femoris of the thigh and tibialis anterior muscle of the lower leg, tibialis posterior muscle and calves triceps surae.

The utility model discloses a protective equipment, including can cup jointing the flexible sheath that is the tube-shape and is made by elastic fabric on neck, waist, upper arm, forearm, upper limbs or low limbs, its characterized in that: the oblique quadratus and the shoulder levator of the corresponding neck, the abdominal rectus muscle and the abdominal external oblique muscle, the deltoid muscle of the shoulder, the biceps brachii and the triceps brachii of the upper arm, the finger muscle group of the forearm, the rectus femoris of the thigh and the quadriceps femoris or the tibialis anterior muscle, the tibialis posterior muscle and the position corresponding to the triceps cruris muscle on the flexible sheath are arranged in the layered structure.

The utility model discloses specific region on close-fitting clothing or protective equipment sets up the composite bed that elastic modulus is greater than close-fitting clothing or protective equipment main surface fabric elastic modulus, and the sporter who wears this type of close-fitting clothing or protective equipment to the body can effectively protect its flesh when the motion by a wide margin, prevents that the muscle at certain flesh position from excessively vibrating, reduces the muscle damage risk. The utility model discloses a composite bed, preparation simple process, the cost is lower, and close-fitting clothing and the protective equipment that are provided with it carry out the effect of differential pressure formula protection to user's position of the organism very obvious.

Drawings

Fig. 1 is a schematic view of a layered structure.

Fig. 2 is an exploded schematic view of example 1 of the layered structure of fig. 1.

Fig. 3 is an exploded view of example 2 of the layered structure of fig. 1.

Figure 4 is a schematic view of a part of a compression garment where a layered structure may be provided.

Fig. 5 is a schematic view of a portion of the brace on which a layered structure may be disposed.

The reference numbers are as follows:

tight-fitting clothes 1, protective equipment 2, subregion 3, lamellar structure 4, surface course 5, main surface fabric 51, elastomer layer 6, upper arm protective equipment 7, thigh protective equipment 8, waist protective equipment 9.

Detailed Description

A, a layer structure 4

As shown in fig. 1, 2, and 3, the layered structure (hereinafter, referred to as layered structure 4) for adjusting the zoned pressure on the tights and the protector according to the present invention is provided on the tights 1 (also referred to as compression clothes) or the protector 2 (also referred to as compression protector 2) to increase the pressure on the corresponding body part of the user, thereby reducing the risk of muscle damage due to excessive vibration of the body part during exercise.

1. Idea for arranging a layered structure 4

1) First, it is determined which body parts of a human body are developed in muscles and are liable to tremble during exercise, and these body parts require a large protection during exercise as compared with other parts, and when a sporter wears the body suit 1 or the protector 2, the corresponding part of the body suit 1 or the protector 2 should exert a greater pressure on the body part than on other parts, thereby achieving a differential pressure protection.

For example, in the human body, the trapezius and levator scapulae of the neck, the pectoralis major and serratus muscles of the chest, the latissimus dorsi of the back, the rectus abdominis and extraabdominis obliquus of the abdomen, the deltoid muscle of the shoulder, the biceps brachii and triceps brachii of the upper arm, the group of the phalanges of the forearm, the rectus femoris and quadriceps femoris of the thigh, and the tibialis anterior muscle of the crus, the tibialis posterior muscle and the triceps surae of the crus are developed compared with those of other parts (including the joint parts of the knee and elbow which need to be protected in importance), so that these parts should be protected by differential pressure during exercise.

The parts of the body suit 1 or the brace 2 where the muscular development parts and the joint parts to be mainly protected correspond to each other are referred to as zones 3, and the three-dimensional shapes of the zones 3 are determined so as to design a layered structure 4 having a corresponding shape.

2) Each subarea 3 can be further divided into a plurality of smaller subareas 3 according to the pressure difference (the pressure difference refers to different pressure protection on muscles in the subarea 3), and a layered structure 4 with set shape and set elastic modulus is selectively arranged in the plurality of subareas 3 with high required protection pressure. The selectivity means that the layered structure 4 may be provided or the layered structure 4 may be omitted for the partition 3 with a small protective pressure depending on the magnitude of the pressure difference.

The shape and the elastic modulus of the plurality of layered structures 4 may be the same or different depending on the magnitude of the pressure difference.

The partition 3 is preferably of a closed-loop structure, that is, the layered structure in the partition 3 is arranged around the circumference of the corresponding body part, so that the pressure protection applied to the body part is more uniform and effective.

2. Constitution of the layered structure 4

The layered structure 4 is a composite layer consisting of a facing layer 5 and at least one elastomer layer 6, the composite layer having the following two arrangements:

1) the prefabricated composite sheet material is then compounded with the main surface material 51 of the tights 1 or the protector 2

Production of composite sheet (see FIG. 2):

the solid macromolecule elastic material is placed on a surface layer 5 made of knitting or weaving elastic fabric, the macromolecule elastic material is melted by a hot pressing process and is immersed into the pores (namely, longitude and latitude meshes formed by surface layer fibers) of the surface layer 5 to form a composite layer which is formed by integrating an elastic body layer 6 and the surface layer 5.

Or, the melted (semi-liquid or liquid) macromolecule elastic material is placed on the surface layer 5 made of knitting or weaving elastic fabric, and the macromolecule elastic material is immersed into the pores of the surface layer 5 by adopting the pressurizing and soaking process to form a composite layer which is formed by integrating the elastic body layer 6 and the surface layer 5.

Or, a composite layer formed by closely bonding at least one solid elastomer layer 6 made of a high molecular elastic material and a surface layer 5 made of a knitted or woven elastic fabric by a gluing process.

The composite layer is cut into composite sheet materials with corresponding shapes according to the shape of the layered structure 4 required by each subarea 3, and then each composite sheet material is fixedly connected to the main surface material 51 of the corresponding subarea 3 on the tights 1 or the protective equipment 2, preferably to the inner side surface of the main surface material 51.

The fixing method comprises sewing, gluing and hot pressing.

The shape of the elastomer layer 6 is set according to the shape of the body part to be protected and the required protection pressure, and may be a mesh layer shape having a plurality of holes (which may be round holes, square holes, rectangular holes or rhombic holes), a lattice layer shape composed of a plurality of punctiform polymer elastic materials, a queue layer shape composed of a plurality of stripes (a plurality of transverse stripes, vertical stripes or oblique stripes composed of polymer elastic materials are arranged side by side), or a film layer shape composed of polymer elastic materials fused into the holes of the surface layer 5 in a tiling way.

The elastic layer 6 may be a smooth surface or a surface with different textures, and the magnitude of the elastic modulus may be adjusted by setting one or more of the texture shape, the density degree and the thickness of the elastic layer 6 singly or in combination.

Namely: the pressure applied by the different zones 3 to the body part corresponding thereto is adjusted by varying the modulus of elasticity of the elastomer layer 6.

Note: elastic modulus refers to the ability of an object to resist elastic deformation. The greater the modulus of elasticity, the greater the resistance of the object to elastic deformation and, therefore, the less elastic. If the springs A and B are stretched to the same extent, but the force applied to A is greater than that applied to B, i.e., A has a greater resistance to elastic deformation, and therefore, A has a greater modulus of elasticity and a lesser elasticity.

The surface layer 5 is made of knitted or woven elastic materials, such as nylon, polyester, rubber band or other elastic fabrics.

The high polymer elastic material is TPE, TPU or other high polymer elastic materials.

The elastic modulus of the composite layer formed of the composite sheet, the body suit 1 or the protector 2 main surface material 51 is larger than the elastic modulus of the surface layer 5 and larger than the elastic modulus of the main surface material 51 in the corresponding region.

2) Directly combining the macromolecule elastic material with the main fabric 51 of the tights 1 or the protective equipment 2 to form a composite layer

The difference from the setting mode is that: directly placing a solid or molten polymer elastic material on the relevant subarea 3 on the body suit 1 or the supporter 2, and impregnating the polymer elastic material into the pores of the main surface material 51 of the body suit 1 or the supporter 2 corresponding to the subarea 3 by hot pressing or impregnation to form a composite layer (shown in fig. 3) in which the elastomer layer 6 and the main surface material 51 of the subarea 3 are integrally fused; alternatively, at least one solid elastomer layer 6 made of a polymer elastic material is placed on the corresponding sub-area 3 of the body suit 1 or the protector 2, and the elastomer layer 6 is fixed to the main surface material 51 of the corresponding sub-area 3 by a bonding process.

The polymer elastic material is the same as that used in the above-described arrangement.

The shape and elastic modulus of the elastic layer 6 are adjusted in the same manner as in the above-described arrangement.

3. Advantages of the layered structure 4

1) The boundary of the subarea 3 provided with the layered structure 4 is smooth, so that people can not feel foreign body feeling, and therefore, compared with the boundary structure of the spliced sheet material in the prior art, the boundary structure has very good comfort.

2) The arrangement position of the layered structure 4 is not limited by the sewing manufacturing process, so the manufacturing process is simple and convenient.

3) In the layered structure 4, the elastomer layer 6 made of a polymer elastic material is impregnated into the main fabric 51 of the tight-fitting garment 1 or the protector 2 by hot-pressing and is fused with the main fabric 51, and therefore, it is wear-resistant, wash-resistant, and has a long service life.

4) The composite layer constituting the layered structure 4 is based on the main surface material 51 of the tight fitting garment 1 or the protector 2 without damaging the fibers. When the user wears the tight fitting garment 1 or the protector 2,

the body part generates a supporting force, the pressure generated by the main surface material 51 of the tights 1 or the supporter 2 to the body part is substantially the same in the circumferential direction around the body part, and the pressure of the upper section 3 of the tights 1 or the supporter 2 to the body part of the corresponding area is the superposition of the pressure applied by the main surface material 51 of the area and the elastic body layer 6 to the body part. This makes it possible to increase the pressure of the divided areas 3 on the body part without changing the normal pressure applied to other parts by the main fabric 51 of the tight fitting garment 1 or the protector 2.

5) In the case of the protectors 2 for the specific parts, such as the upper arm protector 7 and the thigh protector 8, the same pressure is applied to the corresponding body part in the related art, and after a heavy exercise, the protectors 2 are liable to slip off due to the shape of the corresponding body part. Adopt on these protective equipment 2 the utility model discloses a lamellar structure 4 can prevent effectively that protective equipment 2 landing when the user moves, for example, the leg that lies in between the rectus femoris muscle, the sartorius thigh on thigh protective equipment 8 encloses the position that is slightly thin and sets up this lamellar structure 4, just can apply great pressure to this position, can prevent effectively that thigh protective equipment 8 from landing.

Second, tights 1

As shown in fig. 1 and 4, the main fabric 51 of the tight fitting garment 1 is made of an elastic fabric as in the prior art.

On the main surface 51, several zones 3 are arranged, each zone 3 corresponding to a body part requiring greater pressure protection, such as: trapezius and levator scapulae of the neck, pectoralis major and serratus anterior muscles of the chest, latissimus dorsi of the back, rectus abdominis and extraabdominis obliquus of the abdomen, deltoid muscle of the shoulder, biceps brachii and triceps brachii of the upper arm, phalangeal muscle group of the forearm, rectus femoris and quadriceps femoris of the thigh, tibialis anterior muscle of the lower leg, tibialis posterior muscle and calves triceps surae, etc. The layered structure 4 of the invention described above is then arranged in each sub-area 3 according to the pressure level to be protected.

Third, protective clothing 2

As shown in fig. 1 and 5, the main surface material 51 of the protector 2 is made of an elastic fabric as in the prior art.

Generally, it is a flexible sheath that can be sleeved on the neck, waist, upper arm, forearm, upper limb or lower limb to form a tube, such as an upper arm supporter 7, a thigh supporter 8, a waist supporter 9, and the like.

On the main surface 51, several zones 3 are arranged, each zone 3 corresponding to a body part requiring greater pressure protection, such as: trapezius and levator scapulae of the neck, rectus abdominis and external oblique muscles of the abdomen, deltoid muscles of the shoulder, biceps brachii and triceps brachii of the upper arm, phalangeal muscle group of the forearm, rectus femoris and quadriceps femoris of the thigh or tibialis anterior, tibialis posterior and triceps cruris of the lower leg, etc. The layered structure 4 of the invention described above is then arranged in each sub-area 3 according to the pressure level to be protected.

Claims (8)

1. A layered structure for regulating zonal pressure, comprising: the composite layer is composed of a surface layer (5) and at least one elastomer layer (6) which is fused into pores of the surface layer (5) in a permeation mode, or is composed of the surface layer (5) and at least one solid elastomer layer (6) through adhesive bonding, the elastomer layer (6) is in a mesh layer shape with a plurality of holes, a lattice layer shape, a queue layer shape composed of a plurality of stripes or a film layer shape, the composite layer is arranged on a tights (1) or a protective clothing (2) and corresponds to the part of the body of a wearer which needs to bear different pressure protection, and the pressure applied to the part corresponding to the different partition (3) is adjusted by changing the elastic modulus of the elastomer layer (6).

2. The zonal pressure regulating laminate structure of claim 1, wherein: the surface layer (5) is made of elastic materials of knitting or tatting; the elastomer layer (6) is TPE, TPU or other high polymer elastic materials.

3. The zonal pressure regulating laminate structure of claim 2, wherein: the surface layer (5) is made of nylon, polyester ammonia, rubber band yarn or other elastic fabrics and is separately cut and fixedly connected with the sheet material on the corresponding subarea (3) of the tights (1) or the protective clothing (2), or the surface layer (5) is the fabric of the tights (1) or the elastic fabric on the protective clothing (2).

4. The zonal pressure regulating laminate structure of claim 3, wherein: the elastic modulus of the composite layer is larger than that of the surface layer (5) in the composite layer.

5. The zonal pressure regulating laminate structure of claim 1, wherein: the elasticity of the elastomer layer (6) is changed by setting one or more of the texture shape, the density degree and the thickness of the elastomer layer (6).

6. A compression garment comprising a main panel (51) of elastic fabric, characterized in that: -a plurality of zones (3) are provided on the main fabric (51), each zone (3) corresponding to a body part requiring a greater pressure protection, and-a layered structure (4) according to any one of claims 1 to 5 is provided on each zone (3).

7. The compression garment of claim 6, wherein: the subarea (3) comprises main surface materials (51) parts corresponding to trapezius and scapular levator muscles of the neck, pectoralis major and anterior serratus muscles of the chest, latissimus dorsi of the back, rectus abdominis and extraabdominal oblique muscles of the abdomen, deltoid muscles of the shoulder, biceps brachii and triceps brachii of the upper arm, phalangeal muscle group of the forearm, rectus femoris and quadriceps femoris of the thigh and tibialis anterior muscles of the lower leg, tibialis posterior muscles and calves triceps surae.

8. The utility model provides a protective equipment, is the tube-shape and by the flexible sheath of elastic fabric preparation including can cup jointing on neck, waist, upper arm, forearm, upper limbs or low limbs, its characterized in that: the layered structure (4) according to any one of claims 1 to 5 is provided at a position corresponding to the trapezius and levator scapulae of the neck, rectus abdominis and external obliquus abdominis of the abdomen, deltoid of the shoulder, biceps brachii and triceps brachii of the upper arm, phalangeal muscle group of the forearm, rectus femoris and quadriceps femoris of the thigh or tibialis anterior, tibialis posterior and triceps surae of the lower leg on the flexible sheath.

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