RU66273U1 - INFLATABLE DESIGN - Google Patents

Abstract

The inflatable structure comprises a hollow fabric base provided with three hydrophilic and vapor-permeable polymer layers sequentially deposited on its inner surface, and contains at least one S-shaped connecting line along which sections of two opposite sides of the outer surface of the hollow fabric base are joined together. Three hydrophilic and vapor permeable layers are lightweight, waterproof, vapor permeable and warm; and the S-shaped connecting line has a small width, which ensures the formation in the hollow fabric base of an enlarged inflated cavity. Two closed ring-shaped connecting lines are formed at the two ends of the continuous S-shaped connecting line, which avoids damage to the inflatable structure as a result of stresses that can be concentrated in the area of the connecting line.

Description

Technical field

This utility model relates to an inflatable structure, and, in more detail, to an inflatable structure comprising a hollow fabric base provided with three hydrophilic and vapor-permeable polymer layers sequentially applied to its inner surface, and contains at least one continuous S-shaped connecting line, along which sections of two opposite sides of the outer surface of the hollow fabric base are connected to each other.

State of the art

People wear warm clothes, such as down jackets, in order to protect themselves from the cold in winter. The down jacket is insulated with loose fluff, in which air is held, isolating the human skin from external cold. However, when the fluff is squeezed under the influence of an external force so that the air held inside it is displaced, this fluff becomes less effective in terms of heat retention. In addition, since the fluff is the internal soft feathers of birds, then it is inevitably associated with possible problems of the presence of an unpleasant odor and bird flu viruses. And some people may be allergic to fluff.

As an alternative to downy clothes, some inflatable designs, such as inflatable clothing items, have been developed. Inflatable clothes usually have inner and outer sides partially connected to each other by various attachment methods to form a closed inflatable cavity in inflatable clothes. Depending on the needs of the user or his preferences for heat preservation, it is possible to conveniently supply or release from the inflatable cavity an appropriate amount of air to isolate the user's body from external cold air.

Traditional inflatable structures typically contain various polymeric materials, which, in general, can be divided into three types. The first type is PVC (polyvinyl chloride) material, which has a relatively low bond strength and, therefore, a minimum thickness of 0.15 to 0.20 mm is required to ensure satisfactory bond strength. Considering the required thickness, the traditional inflatable structure made of PVC materials is quite heavy. PVC materials also have the disadvantage that they are “non-breathable” and, when burned, form dioxin, which makes them dangerous to the environment. As a result, the inflatable structure made of PVC material has gradually lost its market position. The second type is TPU (thermopolymer polyurethane) material, which is thick, heavy, vapor-proof, hard to touch, and its processing is expensive. The third type is the “breathable” TPU material, which has a relatively weak bond strength and low ability to hold air, and its processing requires exceptionally high costs, while the level of marriage is very high.

For traditional inflatable structures, there are also problems in connecting them. Figure 1 presents the first traditional inflatable design, made in the form of an inflatable jacket. As presented, the inflatable structure 1 should have many relatively wide straight connecting strips 11, which are necessary due to the low strength of the connection of the polymer material from which it is made. Through such wide connecting strips 11, warm air surrounding the user's body tends to flow out, and external cold air can easily penetrate into the inflatable structure 1 through the wide connecting strips 11, which reduces the ability of the structure 1 to retain heat. Moreover, at both ends of the direct connecting strips 11 of the traditional inflatable structure 1, as a rule, the stress is concentrated, which causes damage to the two ends and air leakage through them if the inflatable structure 1 is subjected to relatively strong compression.

Figure 2 presents the second traditional inflatable structure 2, also made in the form of an inflatable jacket. The inflatable structure 2 comprises a plurality of annular connecting portions 21 for solving a stress concentration problem. However, due to the weak bond strength of the polymer material of the inflatable structure 2, the annular connecting portions 21 must have a relatively large diameter. Again, warm air surrounding the wearer's body tends to flow out through the large annular connecting portions 21, and external cold air can easily penetrate through the large annular connecting portions 11 into the inflatable structure 2, which reduces the ability of the inflatable structure 2 to retain heat. In addition, the presence of large annular connecting sections 21 inevitably reduces the amount of air held in the inflatable structure 2, which further reduces the ability of the inflatable structure 2 to retain heat.

Therefore, in this utility model, an attempt was made to offer an improved version of the inflatable structure, which is lightweight, waterproof, vapor permeable, reliable and warm.

Utility Model Essence

The main objective of the development of this utility model is to create an inflatable structure that is lightweight, waterproof, and vapor permeable, and has a hardened connecting line that provides an enlarged and durable inflatable cavity, so this design can be used to make lightweight, waterproof, vapor permeable and heat-holding items.

To achieve the above and other objectives, the inflatable structure according to the present utility model comprises a hollow fabric base having an inner surface and an outer surface; hydrophilic and vapor-permeable solvent-based polymer layer deposited on

the inner surface of the hollow fabric base; a low-modulus hydrophilic and vapor-permeable polymer layer located on top of the hydrophilic and vapor-permeable solvent-based layer; a low-melting hydrophilic and vapor-permeable polymer layer located on top of the low-modulus hydrophilic and vapor-permeable polymer layer surrounding the inflatable cavity; at least one continuous connecting S-shaped line along which sections of the outer surfaces of two opposite sides of the hollow fabric base are connected to each other, which allows you to limit the total thickness of the inflated hollow fabric base, and at each of the two ends of the S-shaped connecting line is formed ring-shaped connecting line; and an inflating valve mounted on a hollow fabric basis for communication with the inflated cavity, so that air can be supplied or discharged from the inflated cavity through the inflating valve. In the construction described above, the inflatable structure according to the present utility model is suitable for the manufacture of various light, waterproof, vapor permeable, durable and warm garments.

Brief Description of the Drawings

The design and technical means used in this utility model to achieve the above and other purposes can be better understood by means of the following detailed description with reference to preferred embodiments and accompanying drawings, in which

Figure 1 is a perspective view of a first traditional inflatable structure made in the form of an inflatable jacket;

Figure 2 is a perspective view of a second traditional inflatable structure made in the form of an inflatable jacket;

Figure 3 is an image of an inflatable structure according to a preferred embodiment of the present utility model, in perspective;

Figure 4 is an enlarged image of figure 3 in section along the line 4-4;

5 is a view illustrating some uses of an inflatable structure according to the present utility model in a perspective view;

6 is a view illustrating another use case of an inflatable structure according to the present utility model in a perspective view; and

7 is a view illustrating another use case of an inflatable structure according to the present utility model.

Preferred Embodiments

Referring to FIG. 3, which shows an image of an inflatable structure 3 according to the present utility model, and FIG. 4, which shows an enlarged image of FIG. 3 in cross section along line 4-4.

As shown, the inflatable structure 3 comprises a hollow fabric base 31 having an inner surface 311 and an outer surface 312, and may be made of a material selected from the group consisting of nylon, nylon 66, and tetoron (polyester fiber); a hydrophilic and vapor-permeable solvent-based polymer layer 32 deposited on the inner surface 311 of the hollow fabric base 31 and having high permeability to increase the bond strength between the hydrophilic and vapor-permeable polymer layer 32 of the solvent base and the inner surface 311 of the hollow fabric base 31; low-modulus hydrophilic and vapor-permeable polymer layer 33, located on top of the hydrophilic and vapor-permeable polymer layer 32 to give a hollow cloth

basis of 31 softness and pleasantness to the touch; a low-melting hydrophilic and vapor-permeable polymer layer 34, located on top of the low-modulus hydrophilic and vapor-permeable polymer layer 33 to form an inflatable cavity 36; at least one continuous S-shaped connecting line 35; and a valve 37 for inflation.

The low-melting hydrophilic vapor-permeable polymer layer 34 has a low melting point, and can, therefore, be easily processed to form a high-strength compound at the joint site. Three hydrophilic vapor-permeable polymer layers 32, 33, and 34 have a total thickness of 0.03 mm to 0.05 mm. Preferably, the three hydrophilic vapor-permeable polymer layers 32, 33, and 34 have a total thickness of 0.05 mm. Due to the small thickness, the three polymer layers 32, 33, 34 together have a relatively low weight of about 60-70 g / m ² .

The continuous S-shaped connecting line 35 has two ends, each of which forms a closed ring-shaped connecting line 351, and is made by high-frequency welding, ultrasonic welding, or thermal connection, so that the portions of the outer surface 312 of the opposite sides of the hollow fabric base 31 are connected along S -shaped connecting line 35, which allows you to limit the total thickness of the inflated hollow fabric base 31. The S-shaped connecting line 35 is preferably formed by high frequency welding, resulting in a joint strength of up to 150 N / 5 cm. Closed ring-shaped lines 351 formed at the two ends of the 8-shaped connecting line 35 contribute to a uniform voltage distribution. Namely, the presence of two closed ring-shaped connecting lines 351 will allow to avoid stress concentration at some individual points at which damage to the inflatable structure 3 according to the present utility model is possible if it is subjected to relatively high compression. In addition, the S-shaped connecting line 35 has a width of 1 to 2 mm, preferably 2 mm. Since the width of the S-shaped connecting line 35 is small, the total volume of the inflated cavity 36

increases, which, in turn, increases the ability of the inflatable structure 3 to retain heat.

On the hollow fabric base 31 there is an inflating valve 37 for communicating with the inflated cavity 36. According to the user's personal preference for keeping heat out of the inflated cavity 36, the necessary amount of air can be supplied or discharged through the inflating valve 37.

The inflatable structure 3 according to the present utility model can be used for the manufacture of various objects, such as, for example, an inflatable cap 4, inflatable headphones 5, an inflatable jacket 6, inflatable gloves 7 and inflatable pants 8, as shown in FIG. 5, an inflatable sleeping bag 9 as shown in Fig.6, and an inflatable blanket 10, as presented in Fig.7. If we consider as an example an inflatable jacket 6 made of an inflatable structure 3 according to the present utility model, then, since moisture coming from the user's body freely penetrates through the fabric base 31 and is absorbed by the solvent-based hydrophilic and vapor-permeable polymer layer 32, due to the movement water between the low-modulus hydrophilic and vapor-permeable polymer layer 33 and the low-melting hydrophilic and vapor-permeable layer 34, moisture absorbed by the hydrophilic and vapor-permeable polymer layer 32 on the basis of solvent, eventually falls into the outer atmosphere. Thus, the user will not suffer from heat, while the warm air surrounding the user's body will remain inside the inflatable jacket 6. On the other hand, the user's body is isolated from the external cold wind and rainwater by the inflatable jacket 6 without the risk of penetration through three polymer layers 32, 33, and 34. Thus, the inflatable jacket 6 is windproof, waterproof, vapor permeable, durable and warm. The inflatable jacket 6 can be equipped with three valves 61 in each of the two armpits, which will ensure the evaporation of sweat from the armpits.

In the inflatable structure 3 according to the present utility model, a polymer-based hydrophilic and vapor-permeable solvent-based layer 32 is used, which can be joined by high-frequency welding to provide increased bond strength of up to 150 N / 5 cm, thereby increasing the service life of the inflatable structure. In addition, the three polymer hydrophilic layers 32, 33, and 34 provide high vapor permeability of more than 5000 g / m ² and high moisture resistance of more than 10000 M / M, have a total thickness of less than 0.05 mm and low weight of 60-70 g / m ² . Three polymer layers 32, 33, 34 are also soft to the touch, which makes the inflatable structure 3 according to the present utility model comfortable to use. Three polymer layers 32, 33, 34 can be applied to the hollow fabric base 31 by any conventional processing method at a low processing cost. Moreover, a continuous S-shaped connecting line 35 with two closed ring-shaped connecting lines 351 formed at its two ends evenly distributes any voltage without causing stress concentration in some separate sections, and the inflatable structure 3 is resistant to damage if it is subjected relatively large compression. Small width - less than 2 mm - of the S-shaped connecting line 35 provides an increased volume of the inflated cavity 36 in the hollow fabric base 31 and, accordingly, increased heat-holding properties.

Briefly, the inflatable structure 3 according to the present utility model comprises a hollow fabric base 31 on which three hydrophilic and vapor-permeable polymer layers are applied, and connected on two opposite sides along at least one narrow but strong continuous S-shaped connecting line 35 with two closed ring-shaped connecting lines 351 formed at its two ends, so that the hollow fabric base 31 is light in weight, durable, waterproof, vapor permeable and has the greatest inflation directly cavity, which allows for highest heat properties, resulting in an inflatable structure 3 according to the present utility model has commercial value and meets the needs of the market.

Claims (10)

1. An inflatable structure comprising: a hollow fabric base having an inner surface and an outer surface; a hydrophilic and vapor-permeable solvent-based polymer layer deposited on the inner surface of the hollow fabric base; a low-modulus hydrophilic and vapor-permeable polymer layer located on top of the hydrophilic and vapor-permeable solvent-based polymer layer; a low-melting hydrophilic and vapor-permeable polymer layer located on top of the low-modulus hydrophilic and vapor-permeable polymer layer surrounding the inflatable cavity; at least one continuous S-shaped connecting line along which portions of the outer surface of two opposite sides of the hollow fabric base are connected together in order to limit the total inflatable thickness of the hollow fabric base, and a closed ring-shaped is formed on each of the two ends of the S-shaped connecting line connecting line; and an inflation valve mounted on a hollow fabric basis for communicating with the inflation cavity, so that air can enter or exit the inflation cavity through the inflation valve; as a result, the inflatable structure can be used for the manufacture of various heat-holding items. 2. The inflatable structure according to claim 1, in which the hollow fabric base is made of a material selected from the group consisting of nylon, nylon 66, and tetoron. 3. The inflatable structure according to claim 1, in which the solvent-based layer, the low-modulus layer and the low-melting hydrophilic and vapor-permeable polymer layer have a total thickness of from 0.03 mm to 0.05 mm 4. The inflatable structure according to claim 3, in which the solvent-based layer, the low-modulus layer, and the low-melting hydrophilic and vapor-permeable polymer layer have a total thickness of 0.05 mm. 5. The inflatable structure according to claim 1, in which the continuous S-shaped connecting line is made by a method selected from the group consisting of high-frequency welding, ultrasonic welding and thermal connection. 6. The inflatable structure according to claim 5, in which the continuous S-shaped connecting line is made by high-frequency welding. 7. The inflatable structure according to claim 1, in which a continuous S-shaped connecting line has a width of from 1 to 2 mm 8. The inflatable structure according to claim 7, in which a continuous S-shaped connecting line has a width of 2 mm 9. The inflatable structure according to claim 1, in which the heat-holding objects are selected from the group consisting of inflatable hats, inflatable headphones, inflatable jackets, inflatable gloves, inflatable pants, inflatable sleeping bags and inflatable blankets. 10. The inflatable structure according to claim 9, in which the inflatable jacket is equipped with at least one valve near each armpit.