JP6896727B2 - Sportswear with at least one temperature control area - Google Patents

Description

The present invention relates to sportswear having at least one temperature control region, which has the features described in the preamble of claim 1.

Such sportswear is known from EB 1 476 033 B1. It is a web-like partial region that is thickened and contacts the skin, a web-like partial region that forms an outer air channel on the posterior surface and a region that does not contact the skin and forms an inner air channel. Be prepared. Sweat can be absorbed by the web in contact with the skin, inside the sportswear, and expelled by the web and evaporated through the outer air channels. Evaporation causes local cooling. Air can flow between the webs in the inner air channel, which provides temperature compensation. Align the web essentially laterally with respect to the body axis so that it can catch the sweat that runs down. Although it has been proved by the web that the temperature control region can absorb sweat well, it also has a drawback that the air flow in the temperature control region can be realized only parallel to the web. Warmed air cannot rise along the body axis inside the temperature control area.

Therefore, an object of the present invention is, first of all, to improve sportswear having at least one temperature control region of the above type in terms of air flow, while retaining good characteristics regarding sweat absorption and sweat evaporation. It is to be.

As a solution, the present invention proposes sportswear having the characteristics according to claim 1.

According to the present invention, the temperature control regions do not include webs and air channels that are continuously aligned parallel to each other, but instead include a plurality of isolated temperature control elements. Each of them, although separately designed in a known embodiment, has only one web that does not extend over the full width of the temperature control element. The temperature control elements are separated from each other by a lateral separation region in the lateral direction with respect to the vertical body axis.

In the meaning of the present invention, the separation region is an area laterally adjacent to the temperature control element or between two adjacent temperature control elements. As already standard in the prior art, the temperature control elements are vertically separated from each other, especially by laterally extending or sloping inner air channels. The separation region is basically an inner air channel, but linguistic differences make the features of the invention clear with respect to the resulting direction of air flowing upwards and sweat flowing down.

The temperature control element is surrounded by a knitted fabric. An inner channel is formed between the latter, through which air flows. The temperature control element is arranged so that sweat droplets on the skin cannot flow from above to below through the entire temperature control area. This is because sweat is eventually trapped in the underlying sweat collection area, the web on the skin. For this purpose, the temperature control elements positioned at different heights with respect to the vertical body axis are laterally offset from each other. The elements can be arranged in various embodiments, but in all embodiments, skin-contact areas and non-skin-contact areas are alternately arranged or offset from each other so that sweat droplets do not continue to flow down. It is common in that it is arranged. At the same time, the offset temperature control element is a slight obstruction to the rising air. Air on the surface of the skin flows in multiple directions. This is because the air channels in the vertical line continue to be open due to the placement of the temperature control elements with respect to the dispersed separation regions. As a result, the warmed air can rise through the temperature control area. The chimney effect associated with this removes moisture better, thus cooling the skin.

Preferably, the arrangement follows a uniform pattern, but during the formation and arrangement of the temperature control elements, in particular, a separation region is provided to allow vertical air flow on the one hand and sweat flowing down on the other. It may be non-uniform as long as the basic principles of the invention are followed in arranging the laterally offset separation regions so that they can be captured in each row that is sequentially leveled down. Therefore, the temperature control area with the temperature control element is optimally adapted to the area of the body that sweats particularly prominently during sporting activities.

The offset arrangement specifically relates to the vertical body axis. However, this does not necessarily mean that the athlete must be in the exact vertical direction when wearing the sportswear according to the invention, but rather the direction of the air flow, i.e. the warmed air, is the athlete. It is intended to clarify the direction in which it can rise along the surface of the body. Of course, the direction of this airflow has a direction slightly opposed to the direction of gravity in the player's normal movement pattern, and can be not only the direction of the airflow that is exactly vertical, but also the direction of inclination. Multiple flow vanes can be formed in sportswear or within the same temperature control area so that the air flow diffuses. For the present invention, it is only important that the direction of the air flow is not blocked by obstacles present in the flow path formed by the web in the prior art.

The direction in which the sweat droplets flow down extends in the opposite direction to the direction of the air flow. According to the present invention, this direction is blocked to capture the flowing sweat. Obstacles formed by temperature control elements arranged laterally offset need not be present in each row of temperature control elements. The sequence of unobstructed columns is separated by at least a pair of columns offset from each other, where sweat is captured.

The temperature control region can also be created by knitting and by adhesively joining the elements to the fabric or other woven or knitted fabric.

The shape and arrangement of the temperature control elements can be selected in a variety of embodiments, but all embodiments are such that the sweat droplets are captured again as quickly as possible without being disturbed and run off. In addition, the areas that come into contact with the skin and the areas that do not come into contact with the skin are arranged alternately or offset from each other.

In horizontal projection, the temperature control element can be, for example, Y-shaped, V-shaped, X-shaped, double Y-shaped. This is because such a shape is immediately suitable for capturing droplets and at the same time is only a slight obstruction to the air passing laterally and rising. The temperature control area on the garment is variable over the entire extension range, including all individual temperature control elements, to provide various additional advantages. For example, the temperature control region can be extended in the vertical direction. This achieves a noticeable chimney effect, thus transferring air from below as much as possible, which is transferred to the upper part of the shirt collar or trouser waistband, from which the air is expelled.

Preferably, the knitted fabric structure is a knitted fabric that forms a temperature control region and is specially designed for this purpose or coupled to the base fabric of sportswear. To stand up against the body axis and form the structure shown in the drawings below
-Linear column offset-Linear uniform offset of individual meshes-Non-uniform offset of individual meshes-Alternating column offsets of mesh regions resulting in preform-Alternating arrangement of individual meshes Uniform offsets-alternate non-uniform offsets of individual meshes,
The following measures can be taken while knitting.

The present invention will be described in more detail with reference to the drawings.

Schematic notched perspective view of the temperature control area of sportswear. Top view of a temperature control region having a temperature control element. Top view of another configuration of a temperature control region having a temperature control element. Top view of another configuration of a temperature control region having a temperature control element. Top view of another configuration of a temperature control region having a temperature control element. Schematic top view of the woven temperature control area. FIG. 1 is a perspective view of a temperature control region according to FIG.

FIG. 1 shows a temperature control region 10.1 in a knitted fabric structure 11.1 which can be a woven fabric or a knitted fabric. For example, the temperature control region 10.1 is arranged in sportswear and is formed on a body part where particularly intense sweating occurs during exercise.

In an exemplary illustration, the temperature control region 10.1 comprises uniformly arranged individual temperature control elements 12.1. Each temperature control element 12.1 itself has at least one area. In this area, the woven or knitted fabric has less elasticity and / or is shirred by a shorter tensile region 15.1. As a result, the temperature control element 12.1 has a U-shape or a V-shape in the inner cross section of the garment facing the wearer's skin 200. As a result, so-called web 14.1 is generated inside the knitted fabric structure 11.1. Sweat is trapped in the tip area of the web 14.1 in contact with the skin 200 and absorbed by the knitted fabric. An inner air channel 13.1 is formed between the webs 14.1 in contact with the skin 200, through which air can flow through the inner air channel 13.1 on the skin surface.

The captured sweat is partially passed through the knitted fabric hygroscopic side wall of the web 14.1 toward the upper surface of the temperature control region 12.1 up to the peripheral region 17.1 of the temperature control region 12.1. Be transferred. Peripheral area 17.1 is maintained at a specific distance from skin surface 200 by web 14.1. Here, sweat can evaporate particularly well. Cooling by evaporation cools the air in the inner air channel located below the surrounding area 17.1.

The channel-shaped structure stands on the rear surface of the web 14.1 to form the outer air channel 18.1. Evaporation occurs through this outer channel 18.1.

Since the outer air channel 18.1 is not completely covered by the tensile region 15.1, the captured sweat also evaporates through them without heat buildup on the temperature control element 12.1. obtain.

The temperature control element 12.1 extends to the knitted fabric structure 11.1 in two main directions, specifically, a body that extends essentially perpendicular to the wearer in an upright position and corresponds to the airflow direction. The axis X and the lateral direction extending at an obtuse angle or perpendicular to the body axis are arranged so as to be established. In the lateral direction, the individual temperature control elements 12.1 are separated from each other by a peripheral region 17.1 and an inner air channel 13.1 is formed between them. The web 14.1 of the adjacent temperature control elements 12.1 are further separated on their extension in the lateral direction by the separation region 16.1.

The outer air channels 18.1 formed in the channels of the shirred knitted fabric are interrupted in the separation region 16.1 while the individual inner air channels 13.1 are placed in the temperature control region 10.1. There is a lateral connection that joins each other on the inside and below the separation region 16.1. Therefore, the separation region 16.1 and the inner air channel 13.1 are part of an air channel network formed inside the fabric structure 11.1 so as to face the wearer's body side.

The effects thus obtained will be described below with reference to the top views of different exemplary embodiments of the temperature control regions 10.2, ..., 10.6 designed by the present invention, shown in FIGS. 2-6.

FIG. 2 is a cutaway view of the temperature control region 10.2 according to another embodiment of the present invention. It can be formed directly on the knitted fabric structure 11.2, where adjacent areas of sportswear are also formed. It is also possible to manufacture the temperature control region 10.2 separately and connect it to the remaining region of the sportswear.

FIG. 2 is a diagram showing the inside of the temperature control region 10.2 that faces the skin. When clothing with a temperature control area 10.2 is worn, dark areas are provided in contact with the skin and the light areas between them remain distanced from the skin surface.

Several rows of individual Y-shaped temperature control elements 12.2 are in the temperature control region 10.2, and one of the legs of the Y-shaped temperature control element 12.2 is in the vertical direction, i.e. , Arranged in such a manner that they are aligned parallel to the body axis X. Further, the row of the temperature control element 12.2 is arranged so as to shift from the row of the adjacent temperature control element 12.2 in the horizontal direction. As a result, wherever the separation point 16.2 between the temperature control elements 12.2 is in the upper row, there is always a collection area 19.2 for sweat droplets, thereby providing an inner air channel. 13.2 is formed in between. In the embodiment according to FIG. 2, the collection area 19.2 is formed by the beveled legs of the Y-order temperature control element 12.2. The thin dotted line with an upward arrow indicates the so-called airflow direction, that is, the path followed by the warmed air A on the skin inside the knitted fabric structure 11.2 facing the skin. Upon contact with the skin, the temperature control element 12.2, which is shown as a dark area, acts as an obstacle and diverts the air flow. As a result of the chimney effect, warm air is eliminated as it moves upwards over obstacles.

At the same time, sweat drips from above to below, as shown by the thick solid line on the left side of FIG. Sweat droplets generated directly in the area between the adjacent temperature control elements 12.2 flow directly to the temperature control element 12.2 located below. According to the exemplary embodiment of FIG. 2, this is the temperature control elements in the second and fourth columns arranged laterally offset with respect to the temperature control elements in the first, third and fifth columns. Achieved by 12.2. The effects of capturing the flowing sweat S and the rising warm air A overlap everywhere. However, the pathways of sweat S and air A are shown in separate areas for illustrative purposes only.

FIG. 3 shows another embodiment of the temperature control region 10.3 designed according to the present invention. Again, the sweat path is indicated by a thick downward arrow on the left side, and the air A path is indicated by a thin dotted arrow on the right side. Again, the body axis extends vertically. Each of the rod-shaped temperature control elements 12.3 is located in the left and right areas of the temperature control region 10.3. Similarly, air A can rise through the separation region between the inner air channel 13.3 and the temperature control elements 12.3 and 12.3'. In this example, the temperature control region 12.3 is arranged in the central region so as to form a V shape with each other. A sweat collection area 19.3 is formed inside a temperature control area 12.3 having a downward facing tip. With respect to the lateral rod-shaped temperature control element 12.3', the offset resulting in the formation of the sweat collection region 19.3' is not caused by the laterally offset temperature control elements 12.3, 12, 3'. The inclination and spacing of the rod-shaped temperature control element 12.3'are adjusted so that the sweat droplets flowing by each upper end of the temperature control element 12.2'are adjacent to the lower end of the temperature control element 12.3'. The arrangement is such that it is captured by the part.

In principle, the illustrated example of FIG. 4 corresponds to the illustrated example described above with respect to the path of sweat X and air A and the positioning of the temperature control region 10.4 with respect to the vertical body axis.

According to the embodiment according to FIG. 4, the individual rod-shaped temperature control elements 12.4 are aligned along their longitudinal extension lines and separated from each other by a separation region 16.4 on the narrow side. doing. Several rows of temperature control elements 12.4 are arranged so as to cover each other, and a peripheral region 17. 4 exists. There is a half-width offset of the horizon between the rows of temperature control elements 12.4 in the lateral direction, which traps sweat droplets flowing down through the separation area 16.4 in the collection area 19.4. Will be done. The collection area 19.4 is formed by each temperature control element 12.4 arranged like a cross girder located in the lower row thereof.

FIG. 5 shows another embodiment of the temperature control region 10.5. In this example, sweat and air pathways are not shown. This is because they extend as in the embodiments described above. As illustrated by the exemplary embodiment of the temperature control region 10.5 of FIG. 5, the temperature control element 12.5 can be arranged without a uniform horizontal line (raster). Each temperature control element 12.5 in FIG. 5 has a different length for each row, and the offset between the rows of the temperature control elements 12.5 is coupled to the length of the temperature control element 12.5. It has a size that is not similar. It is only essential that a sweat collection area 19.5 be provided below the separation region forming the inner air channel 13.5.

FIG. 6 shows another top view of the temperature control region 10.6 arranged in the knitted fabric structure 11.6 designed as the knitted fabric. The stepped structure shown in FIG. 6 serves to represent the individual meshes. The webs 14.6 and the outer air channels 18.6 formed on their rear surfaces consist of, for example, 10 mesh rows, and the spanning tensile regions 15.6 over the outer air channels 18.6 have three. Has only the width of the mesh row of. The width of the outer air channel 18.6 can be increased by the same ratio by providing up to 25 mesh rows forming the outer air channel 18.6, but the tensile region 15.6 over these areas is Since there are only about 10 mesh rows, a shirring effect can be obtained. Seen from the longitudinal extension of the outer air channel, the tensile region 15.6 has a length of 2 to 7 meshes and is separated from each other by 5 to 12 meshes, thereby causing the outer air. It has a width of 5 to 12 meshes for channel 18.6, producing a non-interlaced chamber. Each part of the temperature control element 12.6, which is arranged so as to cover each other and has an outer air channel 18.6, is separated from each other by an inner air channel 13.6 having a width of 4 to 40 mesh rows.

FIG. 7 shows the single temperature control element 12.1 in the knitted fabric structure 11.1 in the squint three-dimensional structure outside the garment. As is clearly shown, the sportswear according to the invention does not have the sharp, raised boundary edges that are graphically shown only in the schematics of FIGS. 2-6. The shirring of the woven or knitted fabric by the tension region 15.1 and the channel-shaped structure forming the so-called outer air channel 18.1 extending below it is obvious.

10.1 ... 10.6 Temperature control area 11.1 ... 11.6 Fabric structure 12.1 ... 12.6 Temperature control element 13.1 ... 13.6 Inner air channel 14.1 ... 14.6 Web 15. 1 ... 15.6 Tension area 16.1 ... 16.6 Separation area 17.1 ... 17.6 Peripheral area 18.1 ... 18.6 Outer air channel 19.1 ... 19.6 Sweat collection area 200 Skin S Sweat A air

Claims (9)

At least one temperature control region comprising a knitted fabric structure (11.1, ..., 11.6) locally shirred over the tension regions (15, 1, ..., 15.6) to form a web. Sportswear having (10.1, ..., 10.6)
The web (14.1, ..., 14.6) is designed to contact the wearer's skin (200) inside the fabric structure (11.1, ..., 11.6).
Adjacent webs (14,1, ..., 14.6) inside the air channel is formed between,
At least one channel is formed on the rear surface of the web (14.1, ..., 14.6) on the shirred fabric structure (11.1, ..., 11.6) to provide outside air. Form channels (18.1, ... 18.6) and
A plurality of webs (14.1, ..., 14.6) are arranged so as to cover each other in the temperature control region (100.1, ..., 100.6).
In sportswear
-Multiple isolated temperature control elements (12.1, ..., 12, 6) are located in the temperature control region (100.1, ..., 100.6) and as part of the inner air channel. lateral side direction of the separation region (16.1, ..., 16.6) of the short web (14.1, ..., 14.6) spaced from each other by include,
-The inner air channel (13.1, ..., 13.6) extending in the adjacent lateral direction inside the fabric structure (11, 1, ..., 11.6) extends in a direction different from the lateral direction. Connected to each other by said separation regions (16.1, ..., 16.6) as part of the inner air channel.
- said temperature control element (12.1, ..., 12, 6) the separation region between the (16,1, ..., 16.6) are arranged laterally offset longitudinal direction to each other, thereby, the The temperature control elements (12.1, ..., 12, 6) overlap at least partially with respect to the longitudinal extension of the vertical body axis (X).
Sportswear that features that. The temperature control elements (12.1, 12.2, 12.3, 12) in at least one temperature control region (10.1, 10.2, 10.3, 10.4, 10.5, 10.6). .4,12.5,12.6), together with at least partially angular attached has the obtuse angle of 120 ° to 150 ° relative to the vertical direction body axis (X),
The sportswear according to claim 1. At least a portion of the temperature control element (12.1) has a tilted Y-shape in at least one temperature control region (10.1).
The sportswear according to claim 2, wherein the sportswear is characterized by the above. At least a portion of the temperature control element (12.2) has an upright Y-shape in at least one temperature control region (10.2).
The sportswear according to claim 2, wherein the sportswear is characterized by the above. At least a portion of the temperature control elements (12.1, 12.3, 12.6) is a tilted or upright V in at least one temperature control region (10.1, 10.3, 10.6). Has a character shape,
The sportswear according to claim 2, wherein the sportswear is characterized by the above. At least a portion of the temperature control elements (12.3, 12.4, 12.5) has a rod shape in at least one temperature control region (10.3, 10.4, 10 and 5) and has a rod shape. Extends laterally or at an angle with respect to the body axis (X).
The sportswear according to claim 1. The web (14.1, ..., 14.6) and pull region (15.1, ..., 15.6) is Bekko produced by said temperature control element (12.1, ..., 12.6) is part of the temperature control element (12.1, ..., 12.6) is connected to the other textile fabric structures,
The sportswear according to claim 1, wherein the sportswear is characterized by the above. The knitted fabric structure (11.1, ..., 11.6) is a woven fabric.
The web (14.1, ..., 14.6) consists of a shirred base woven fabric.
The tension region (15.1, ..., 15.6) has a smaller number of meshes as compared to the base woven fabric.
The sportswear according to claim 1, wherein the sportswear is characterized by the above. Wherein the temperature control region, due to the column offset linearly or alternately knit, Ru extends offset with inclined with respect to the body axis (X),
The sportswear according to any one of claims 1 to 7, wherein the sportswear is characterized by the above.

Images