FR3113503A1 - Breathable Three-Dimensional 3D Spacer Fabric Mosquito Net - Google Patents

Abstract

The invention relates to the field of mosquito nets. The mosquito net comprises a three-dimensional 3D spacer fabric whose pressure drop coefficient of the three-dimensional 3D spacer fabric is less than 1. For good mechanical resistance, the 3D spacer fabric is run-proof Preferably to facilitate the installation of the mosquito net, 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 perpendicular or oblique knitted stitches (M) interconnected by a multitude of longitudinal filaments (F). Figure to be published with abstract: Fig. 4.

Description

Breathable Three-Dimensional 3D Spacer Fabric Mosquito Net

FIELD OF THE INVENTION TO WHICH THE INVENTION RELATES

The invention relates to the field of mosquito nets.

PRIOR ART

Mosquito nets are usually made in the form of a fine grid whose hole size of a few millimeters is sufficiently fine not to let mosquitoes pass while letting a little air pass through. They are, for example, made of tulle for a stroller mosquito net or of a more rigid material for a window mosquito net.

Although the mosquito net allows air to pass, it opposes the passage of air with two consequences.

The first consequence is that in the presence of wind, the action of the air translates into a force which is applied to the surface of the mosquito net and that in the event of strong wind, the mosquito net cannot resist the pressure. wind and either tears or shifts losing its functionality.

The second consequence is that it opposes the passage of air, preventing you from benefiting from a current of air which would in some cases be welcome, especially in the event of high temperatures.

BRIEF DESCRIPTION OF THE INVENTION

The mosquito net features a three-dimensional 3D spacer fabric.

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

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

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

For the placement of the mosquito net, 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.

To ensure visibility through the mosquito net, it is possible to combine strips of tulle and strips of vertical three-dimensional 3D spacer fabric spaced apart from the average distance between the eyes.

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

In terms of the manufacturing process, the mosquito net manufacturing process 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 in section a 3D spacer fabric with wide staggered mesh and low thickness.

shows in section a three-dimensional spacer fabric with longitudinal filaments.

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

DETAILED DESCRIPTION OF THE INVENTION

The mosquito net has 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). In particular, they are used integrated into mattresses.

There illustrates a first example of a three-dimensional 3D 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.

These two spacer fabrics (3D) offer the same functionality as a classic fabric, the multiplicity of filaments (F) obstructing the passage of mosquitoes while allowing air to pass through. In addition, they are mechanically much stronger 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 better, the pressure drop coefficient of the three-dimensional 3D spacer fabric is less than 1. This coefficient represents the opposition to the passage of air through the fabric of the mosquito net. 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.

There represents a fabric (T) optimized in this sense with wide meshes, staggered, spaced a few millimeters apart and therefore with fewer filaments in order to limit the pressure drop.

Preferably to facilitate the placement of the mosquito net, the three-dimensional 3D spacer fabric is extensible.

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 the placement of the mosquito net, 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.

To ensure visibility through the mosquito net, it is possible to combine strips of tulle and strips of vertical three-dimensional 3D spacer fabric spaced apart from the average distance between the eyes. Typically, these would be vertical bands 3 centimeters wide alternating in tulle and fabric 3D spacers spaced about 6 centimeters apart.

According to a second embodiment shown , the filaments (F) of the three-dimensional 3D spacer fabric are longitudinal. The fabric is then a succession of perpendicular or oblique knitted stitches (M) interconnected by a multitude of filaments (F). Thus the knitted meshes (M) are preferably oriented perpendicular with little obstacle to the passage of air, the main obstacle becoming the filaments whose density and thickness must be adjusted.

In terms of the manufacturing process, the mosquito net manufacturing process uses three-dimensional 3D spacer fabric knitting machines like the one pictured .

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 knitting machines for three-dimensional 3D spacer fabrics like the one illustrated .

In terms of industrial application, the invention applies to mosquito nets.

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)

Mosquito net characterized in that the mosquito net 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). Mosquito net according to Claim 1, characterized in that the pressure drop coefficient is less than 1. Mosquito net according to any one of Claims 1 to 2, characterized in that the 3D spacer fabric is run-proof Mosquito net according to any one of Claims 1 to 3, characterized in that the three-dimensional 3D spacer fabric is extensible. Mosquito net according to any one of Claims 1 to 4, characterized in that the three-dimensional 3D spacer fabric is put under tension. Mosquito net according to any one of Claims 1 to 5, characterized in that the meshes (M1, M2) of the three-dimensional 3D spacer fabric (T) are staggered. Mosquito net according to any one of Claims 1 to 6, characterized in that the mosquito net comprises strips of tulle and strips of vertical three-dimensional 3D spacer fabric at distances from the average distance between the eyes. Mosquito net 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). Method of manufacturing the mosquito net according to any one of Claims 1 to 8, characterized in that it uses machines (MT) for knitting three-dimensional 3D spacer fabrics. Method according to claim 9 consisting of assembling three-dimensional 3D spacer fabrics (T) then cutting them by laser in slices