FR3113497A1 - Breathable 3D Spacer Fabric Shade Device - Google Patents

Abstract

The invention relates to the field of shading devices such as shade sails, awnings, parasols and umbrellas. The shading device comprises a three-dimensional 3D spacer fabric whose pressure drop coefficient of the three-dimensional 3D spacer fabric is less than 5. For good mechanical resistance, the 3D spacer fabric is run-proof Preferably to facilitate installation, the Three-dimensional 3D spacer fabric is stretchy so it can be put under tension. The three-dimensional 3D spacer fabric (T) is a succession of parallel and oblique knitted stitches (M) interconnected by a multitude of longitudinal filaments (F). Figure to be published with abstract: Fig. 5.

Description

Breathable 3D Spacer Fabric Shade Device

FIELD OF THE INVENTION TO WHICH THE INVENTION RELATES

The invention relates to the field of shading devices such as shade sails, awnings, parasols and umbrellas.

PRIOR ART

Shading devices such as shade sails, awnings, parasols and parasols are often made of waterproof fabric.

For some models of shade cloth, there are variants whose fabrics are not waterproof but permeable so as not to store water in the event of rain.

In fact, these permeable models, if they let water through, let little air through.

As a result, despite everything, they remain less pleasant than the shade of a tree whose upper leaves protect the lower leaves from the sun, which remain cool, unlike the underside of a shade sail or an awning which emit infra-red because of their high temperature towards users although they are in the shade.

In addition, these fabrics, being insufficiently permeable to air, take the wind which can make them unstable or even dangerous, for example in the case of a parasol.

BRIEF DESCRIPTION OF THE INVENTION

The shading device according to the invention comprises a three-dimensional 3D spacer fabric.

Preferably, the pressure drop coefficient of the three-dimensional 3D spacer fabric is less than 5, if possible less than 1.

For good mechanical resistance, the 3D spacer fabric is run-proof

Preferably to facilitate the placement of the shade device, the three-dimensional 3D spacer fabric is stretchy

For the placement of the shading device, it is advantageous that the three-dimensional 3D spacer fabric is put under tension.

According to a first embodiment, the stitches of the three-dimensional 3D spacer fabric are staggered.

Preferably, the surface of the knitted part represents more than 50% of the surface of the fabric. This increases the probability that the sun's rays will be intercepted regardless of the position of the sun.

According to a second embodiment, the filaments of the three-dimensional 3D spacer fabric are longitudinal.

In terms of the manufacturing process, the manufacturing process of the shade device uses three-dimensional 3D spacer fabric knitting machines.

In the case of the second embodiment with longitudinal filaments, it is possible to produce them for small series by assembling superimposed three-dimensional spacer fabrics then laser cut in slices.

For larger series, it is possible to industrialize a process to produce them directly on knitting machines for three-dimensional 3D spacer fabrics.

Other characteristics and advantages of the invention will appear on reading the detailed description which follows for the understanding of which reference will be made to the appended drawings.

illustrates a first example of a three-dimensional spacer fabric with fine mesh and thickness of 7.5 mm.

illustrates a second example of a three-dimensional spacer fabric with wide meshes and a double thickness of approximately 1.5 centimeters.

shows a third example of a three-dimensional, wide-knit, 3D spacer fabric in which the area of the knitted part represents more than 50% of the area of the fabric on each side.

shows in section a 3D spacer fabric with longitudinal filaments whose meshes are parallel to each other and perpendicular to the fabric.

shows in section a three-dimensional spacer fabric with longitudinal filaments whose meshes are parallel to each other and oblique to the fabric.

shows a machine for knitting three-dimensional 3D spacer fabrics.

DETAILED DESCRIPTION OF THE INVENTION

The shading device according to the invention comprises a three-dimensional 3D spacer fabric (T).

These are fabrics (T) composed of at least two knitted sides (M1) and (M2) with stitches (M), the two sides are connected by a multitude of nylon filaments (F). These fabrics are used in particular in mattresses.

There illustrates a first example of a three-dimensional spacer fabric (T) with a fine mesh and a thickness of 7.5 mm. Note that in this example the stitches (M) of the two knitted sides (M1) and (M2) overlap.

There illustrates a second example of a three-dimensional spacer fabric (T) with a wide mesh (M) and a double thickness of approximately 1.5 centimeters. Note that in this example the stitches (M) of the two knitted faces (M1) and (M2) are staggered.

There illustrates a third example of a three-dimensional spacer fabric (T) with a wide mesh (M) and a thickness of about 2 centimeters. It should be noted that in this example the stitches (M) of the two knitted faces (M1) and (M2) are staggered and that the surface of the knitted part represents more than 50% of the surface of the fabric. This makes it possible to increase the probability that the sun's rays are intercepted whatever the position of the sun.

More generally, the sum of the surface of the knitted face (M1) and the surface of the knitted face (M2) must be greater than the surface of the fabric (T) to block the rays of the sun. by at least one of the two knitted faces (M1) or (M2).

These three spacer fabrics offer shade due to the presence of knitted meshes (M1, M2), the multiplicity of filaments (F) allowing air to circulate.

In addition, they are mechanically strong and will withstand strong winds. They support forces of several tens of kilos per m².

For good mechanical resistance, the three-dimensional 3D spacer fabric (T) is run-proof.

Preferably, to allow air to pass through better, the pressure drop coefficient of the three-dimensional 3D spacer fabric is less than 5, or even if possible less than 1. This coefficient represents the opposition to the passage of air through the fabric of the shading device. This is the ratio between the pressure drop measured in Pascal between the upstream and downstream pressure when the fabric is crossed by an air flow at a speed V given in meters per second and the equivalent of the kinetic energy of air ½ ρV², ρ being the density of air.

A pressure loss coefficient of less than 5 makes it more permeable than the permeable shade cloths usually marketed.

A loss coefficient of less than 1 makes it possible to limit the consequences of the force of the wind and to prevent a parasol from blowing away with all the risks that this entails.

Preferably to facilitate placement of the shading device, the three-dimensional 3D spacer fabric is stretchable.

For this, to keep a form of elasticity so that the three-dimensional 3D spacer fabric (T) remains extensible, it is not necessary to perform the operation of geometric stabilization by thermal process used in the case of 3D spacer fabrics integrated into the mattresses for guarantee the dimensional conformity expected for use in a mattress.

Unlike the three-dimensional 3D spacer fabrics integrated into the mattresses, it is not necessary to implement the thermal stabilization process which would make the fabric (T) not very stretchy. For example, the heat treatment may consist of bringing the three-dimensional 3D spacer fabric (T) to 200°C for 30 seconds to ensure dimensional conformity.

By not doing this, the 3D spacer fabric can remain stretchy for values greater than 30% or even 50% depending on their design.

For placement of the device, it is advantageous for the three-dimensional 3D spacer tissue to be put under tension. This is particularly interesting in the case of a shade sail, an awning, a parasol or a parasol on its ribs.

According to a first embodiment, the stitches of the three-dimensional 3D spacer fabric are staggered so that each of the two levels of knitted stitches obstructs the rays of the sun.

According to a second embodiment shown And , the filaments (F) of the three-dimensional 3D spacer fabric are longitudinal. The fabric is then a succession of knitted stitches (M) parallel to each other, interconnected by a multitude of filaments (F).

Preferably, in this configuration, the knitted faces of the three-dimensional 3D spacer fabric do not let the sun through at all and the knitted surface of the stitches (M) represents 100% of the surface of the knitted face.

Depending on the case depending on the respective position of the shading device and the sun, the meshes (M) are perpendicular as shown or oblique as shown ,

Thus, depending on the inclination of the fabric, the meshes provide protection from the sun while letting the air pass in a different direction.

This is particularly the case of parasols and umbrellas where the inclination of the fabric varies according to its position while the wind is most often horizontal regardless of the position of the sun.

Then the angle of inclination of the mesh (M) can vary continuously depending on its distance from the center of the parasol or parasol, which leads to a specific product.

In terms of the manufacturing process, the manufacturing process of the shading device uses three-dimensional 3D spacer fabric knitting (MT) machines like the one shown .

In the case of the second embodiment with longitudinal filaments (F), it is possible to produce them for small series by assembling superposed three-dimensional 3D spacer fabrics (T) then laser cut in slices to the desired thickness.

For larger series, it is possible to industrialize a process to produce them directly on machines (MT) to knit the three-dimensional 3D spacer fabrics like the one illustrated .

In terms of industrial application, the invention applies to shading devices such as shade sails, awnings, parasols and umbrellas.

The present invention is in no way limited to the embodiments described and represented, but a person skilled in the art will know how to make any variant in accordance with his spirit for a range of products in different fields.

Claims (10)

Shading device characterized in that the device comprises a three-dimensional 3D spacer fabric in the form of a 3D knit composed of knitted meshes (M) connected by a multitude of filaments (F). Device according to Claim 1, characterized in that the pressure drop coefficient is less than 5. Device according to any one of Claims 1 to 2, characterized in that the 3D spacer fabric is run-proof. Device according to any one of Claims 1 to 3, characterized in that the three-dimensional 3D spacer fabric is extensible. Device according to any one of Claims 1 to 4, characterized in that the three-dimensional 3D spacer fabric is put under tension. Device according to any one of Claims 1 to 5, characterized in that the stitches (M1, M2) of the three-dimensional 3D spacer fabric are staggered. Device according to any one of Claims 1 to 7, characterized in that the knitted surface of the stitches (M) represents more than 50% of the surface of the fabric. Device according to any one of Claims 1 to 5, characterized in that the 3D knit is composed of a succession of knitted stitches (M) perpendicular or oblique with respect to the longitudinal direction of the 3D knit, interconnected by a multitude of filaments (F). Process for manufacturing the shading device according to any one of Claims 1 to 9, characterized in that it uses three-dimensional 3D spacer fabric knitting machines. Method according to claim 9 consisting of assembling three-dimensional 3D spacer fabrics and then cutting them by laser in slices.