The invention relates to a heating and cooling device for a vehicle seat with separating material that forms at least a portion of an air-distribution chamber, an upper-side layer covering the separating material on its upper side and a lower-side layer of separating material on the underside opposite from the upper-side layer essentially airtight, whereby the upper-side layer and the lower-side layer are connected together about the outer circumference of the separating material. An air-inlet aperture is provided for the air-distribution chamber and air-outlet apertures are provided in the upper-side layer to remove air from the air-distribution chamber.
Such heating and cooling devices are generally known.
For example, EP 2 423 040 A2 describes an insert to ventilate a seat with a non-airtight separating part that is encased within, an airtight shell whereby this covering part is formed like a pouch. The upper side and the lower side of this pouch are bound flatly together at their edges with, one on the other. Air pass-through apertures are located about the circumference.
DE 203 21 141 U1 describes an insert to ventilate a vehicle seat that is located below the seat cover of a seat cushion or seat back. The insert possesses separating material that is covered on its lower side by a barrier layer whereby this barrier layer is attached to the separating material by means of an adhesive layer. On the upper side, the separating material is covered by an additional barrier layer, which in turn is attached to the separating material by means of adhesive layer. A heating layer, which is covered by a buffer layer, is in turn attached by means of art adhesive layer to the barrier layer. Pass-through apertures are located in the layers above the separating material. The separating part with, its layers located on it possesses an extension that serves to guide air from a ventilator located remotely from the seat-base surface or seat-back surface.
DE 10 2005 014 333 A1 relates to a heated and cooled seat and a beating and cooling device. The heating and cooling device comprises a hearing and cooling mat located below the surface of the seat-base surface or below the surface of the seat back and connected with, an air-supply device, e.g., a ventilator. The heating and cooling mat is formed as a sack, of essentially airtight material whereby the upper side of the bag includes air pass-through apertures.
DE 10 2006 004 465 A1 describes an inlaid component for a heated and cooled vehicle seat. The inlaid component comprises at least one non-airtight top layer, a three-dimensional air-distribution layer under it, and at least one lower top layer that comprises at least one air inlet. The upper top layer and the lower top layer are connected together along a lateral edge of the air-distribution layer.
It is the objective of this invention to provide a beating and cooling device for a vehicle seat that possesses a simple design, that is simple to manufacture, and that meets the requirements placed on such a heating and cooling device during use in a vehicle.
This objective, as well as other objectives which will become apparent from the discussion that follows, are achieved, according to the present invention, by connecting the upper side layer and the lower side layer, at least about their outer circumference, by a box-shaped insert.
According to a particular feature of the invention, the box-shaped insert surrounds the separating material, which advantageously involves a knitted separator that limits an air-distribution chamber between the upper-side layer and the lower-side layer. This box-shaped insert should be of such a material, and should possess such, properties, that it is essentially airtight so that the insert limits flow from the air-distribution chamber outward.
A heating and cooling device based on the invention may be integrated into a vehicle seat directly onto the upholstery core of the seat. It is particularly suited, however, to insertion into an indentation or recess within an upholstery core that is of foamed material, for example. In such case, such an indentation or recess could be sized such that a free space remains between the circumference of the box-shaped insert of the heating and cooling device and the circumference of the indentation or recess that forms a channel through which air may be supplied or exhausted, and water vapor may also be diverted as necessary. For this, the box-shaped insert is of a material that is partially permeable for air and/or for water vapor.
The box-shaped insert of the heating and cooling device limiting the separating material along its circumference has the advantage that the heating and cooling device may possess an essentially exact right-angle shape even in the edge area since the upper-side layer and the lower-side layer may end directly at the edge of the box-shaped insert to which these layers are adhered. A further advantage of the box-shaped insert consists in the fact that, the material of the insert may be matched to the material of the separating materials, particularly with respect to wear hardening, which can ensure that a person seated on the seat does not perceive transitional areas between materials. The heating and cooling device based on the invention is particularly suited to being directly foamed into a seat-base cushion when it is manufactured. In such case, the material of the box-shaped insert should be selected such that the foam does not penetrate through the insert material into the air-distribution chamber. In this case, the material for the box-shaped insert is preferably essentially closed-cell foam, fleece, felt, or synthetic plastic polymers such as silicone, for example. Additional advantages of the box-shaped insert include a firm connection with the upholstery or foam core. If the heating and cooling device is foamed into a foam core, the box-shaped insert prevents penetration of the foam. The box-shaped insert forms a flat surface that is important during the foaming process: the surface prevents folding and/or over-foaming of the heating and cooling device. Any potential folding in the seat covering that may form on the side of a seat on which a person sits is thus avoided.
While on the one hand a foamed material, which is advantageous from a cost perspective, is a preferred material for the box-shaped insert, closed-cell rubber may be used. Such a closed-cell rubber should be as airtight as possible, and thus provides an advantage when a narrow frame is required. Another material may be closed-cell sponge. Sponge has the advantage of a high, degree of wear hardening, which allows a comfortable and/or stable bridging of interstitial spaces larger than 30 mm.
If the box-shaped insert is adhered to the upper-side layer and/or the lower-side layer, a temperature-activated adhesive should be applied, to the top-side and/or the lower-side layer. A two-sided adhesive tape should preferably be used as the adhesive since it allows quicker bonding between the upper-side layer and/or the lower-side layer with box-shaped insert.
The box-shaped insert is preferably sized such that it possesses a width seen along the direction of the plane of the upper-side layer or of the lower-side layer of 5 mm to 30 mm, preferably of 5 mm to 20 mm, or from 10 mm to 15 mm. Depending on the material used, the box-shaped, insert may be manufactured with a very narrow width, e.g., with a width between 5 mm and 10 mm, so that a very large surface of the heating and cooling device may be used as an air-distribution chamber. A particular advantage of the box-shaped insert also to be emphasized is the fact that it may be manufactured with varying widths along the circumference of the separating material so that the circumferential shape of the air-distribution chamber may be simply matched to the peculiarities of the seat-base surface of a seat that is to be heated and/or cooled.
The box-shaped insert should possess a thickness in a direction perpendicular to the plane of the upper-side layer or the lower-side layer that roughly corresponds to the thickness of the separating materials along this direction.
In another particularly advantageous embodiment the separating material possesses at least one punched-out area that is filled with an inlay of an essentially airtight material. Such inlays allow the air-distribution chamber to be divided into different flow areas and thus structured. For this, it is also provided that such inlays are connected by at least one spar of the box-shaped insert to form a single piece. In such case, the box-shaped insert with the inlay and/or the inlays is manufactured as a single, interconnected, textured structure into which suitably-shaped separating material forming the air-distribution chamber is then inserted.
The same material used for the box-shaped insert may be used as material for lire inlays. It is also possible, however, to manufacture the inlays of a different material, but the material must not alter the properties of the separating materials, particularly with respect to wear hardening of the entire surface of the separating materials so that a person seated on the seat perceives no texture within the heating and cooling device and/or the surface of the separating materials. A foamed material, closed-cell foam rubber, closed-cell sponge, or a silicone-type material should be chosen as material for the inlays.
Like the box-shaped insert, the inlays may be adhered to the upper-side layer and/or the lower-side layer.
The minimum of one inlay may also be adhered to the separating material. The inlay may be attached to the separating material by means of overlapping thermal adhesive, adhesive tape, or suitable adhesive.
If inlays are provided within the separating materials, a pass-through aperture from the upper-side layer to the lower-side layer may be formed within the area of such inlays, said aperture extending through the upper-side layer, and through the lower-side layer as necessary. Such pass-through apertures may be used as suspension apertures for the seat covering. As necessary, such pass-through apertures may serve for air supply or exhaust from, the seat-base surface. Since these pass-through apertures are provided in the inlays, the pass-through apertures are sealed with respect to the air-distribution chamber by the material of the inlays. Simultaneously, the separating material is stabilized by the inlays, and/or the separating material is not weakened and its strain behavior is not altered because of the pass-through apertures.
Using the inlays, the air flow may be guided within the air-distribution chamber and distributed or channeled into the various areas of the air-distribution chamber without additional design expense. This means that such inlays form a flow-guide body. In their function as flow-guide bodies, the inlays preferably possess a teardrop-shaped cross section whereby the broad side faces the approach direction for the air stream.
In addition to the air-outlet apertures, it is also provided that the upper-side layer be at least partially non-airtight. For this, the number of air-outlet apertures per unit of area of the air-distribution chamber seen in projection onto the upper-side layer increases as the separation from the air-inlet aperture increases.
The box-shaped insert offers a simple design opportunity to implement the air-inlet aperture to the air-distribution chamber as an interruption of the box-shaped insert. Moreover, additional air-inlet apertures to the air-distribution chamber and/or air-outlet apertures from the air-distribution chamber may be formed by interruptions or free spaces in the box-shaped insert.
In an additional embodiment example, the upper-side layer comprises an area, or at least a partial area, on the side facing toward a person that comprises a ferromagnetic and/or magnetic layer. During an additional processing step, this layer allows affixation of the heating and cooling device, e.g., during encasing the heating and cooling device in a foam core. This ferromagnetic and/or magnetic layer prevents intrusion of foreign bodies and/or foreign material during additional processing steps.
In an additional embodiment example, the upper-side layer comprises an additional airtight layer, so that the upper-side layer may possess a multi-layer structure. In a multi-layer structure, it is particularly significant that at least one air pass-through aperture be present in the additional airtight layer and in the upper-side layer.
In an additional embodiment example, the upper-side layer includes apertures only in the area in which the box-shaped insert is mounted. For this, the apertures in the upper-side layer also pass through the box-shaped insert. For this, box-shaped insert may include laterally-mounted notches in the edge toward the air-distribution chamber so that air may flow from the air-distribution chamber through the box-shaped insert and the upper-side layer.
For a full understanding of the present invention, reference should now be made to the following detailed description of the preferred embodiments of the invention as illustrated in the accompanying drawings.
The preferred embodiments of the present invention will now be described with reference to
To the extent that components are represented in individual Figures with identical reference indices, then the implementation of these components in one Figure may analogously be transferred to the implementation of these analogous components in other Figures without describing these components for the other Figures again.
The heating and cooling devices in the various embodiment examples shown in
The heating and cooling device based on the invention also offers the option that the upper-side layer 4 be manufactured to possess greater surface area than the surface limited by the outer shape of the box-shaped insert 3 so that a narrow surface section projects above the upper-side layer 4 about the circumference of the box-shaped insert 3. If inserted into an indentation in the upholstery core, for example, the heating and cooling device may be secured to the upper side of the upholstery core by means of this projecting surface section, which is not shown in
An air-Inlet aperture 6 to the air-distribution chamber 1, which may also be used as an air-outlet aperture is present in the lower-side layer 5 by means of which the air-distribution chamber 1 may be connected to a fan unit (not shown) for air flow. The air-inlet aperture 6, or the air-outlet aperture as necessary, is shown in
The box-shaped insert 3 possesses a constant width about the greatest portion of the circumference of the heating and cooling device in a direction seen in parallel to the plane of the upper-side layer or the lower-side layer of 5 mm to 30 mm, preferably from 5 mm to 20 mm, or from 10 mm to 15 mm. The width should be as small as possible so that, in relation to the surfaces under tension by the outer circumference of the heating and cooling device, a large surface remains for the air-distribution chamber 1. Resultantly, the width of the box-shaped insert 3, at least in specific areas of the heating and cooling device, is 5 mm and less, which means from 3 mm through 5 mm. The box-shaped insert 3 makes it possible to alter the shape of the air-distribution chamber 1 simply in that parts of the box-shaped insert 3 fill out larger surfaces of the space between the upper-side layer 4 and the lower-side layer 5, as is shown, for example, in corner areas 7 in
In the illustrated embodiment examples, punched-out areas 8 within the separating materials 2 are present that are filled with inlays 9. The material for these inlays 9 is preferably the same material used for the box-shaped insert 3. The preferred material for the box-shaped insert 3 and/or the inlays 9 is a foamed material that moreover is essentially closed-cell construction and therefore airtight, or a closed-cell foam rubber. Other materials for the box-shaped insert 3 and/or the inlays 9 are closed-cell sponge, film, reversible stressable plastic polymer, fleece, felt, or a silicone-type material.
The inlays 9 must consist of an essentially airtight material so that no air is guided over the material 9 of the inlays in the area of the inlays at least toward the upper-side layer 4 although a slight non-airtightness of the inlays 9 does not influence the heating and cooling properties. They must therefore consist of an essentially airtight material. This also applies for the material of the box-shaped insert 3.
The various materials used for the box-shaped insert 3 and/or the inlays 9 should be airtight. Since some materials designated as airtight still permit a certain air flow, designation of the materials of the insert 3 and/or of the inlays 9 as essentially airtight also applies to those materials that are up to 30% non-airtight. However, it is preferred for the non-airtightness to be less than 20%, and more preferably, less than 10% or less than 5%.
It is visible from
In order to channel the air flow within the air-distribution chamber 1, the inlays 9 may be connected to the box-shaped insert 3, as is shown in
Pass-through apertures 12 (see also
In connection with the box-shaped insert 3 and the inlays 9, a woven fabric, a non-woven textile, a plastic film, or a membrane-film material may be used as preferred material for the upper-side layer 4. Such materials are on the one hand moisture-permeable, and on the other hand, are simple to adhere to the upper side of the box-shaped insert 3 and the inlays 9. This upper-side layer 4 should possess a thickness of 0.5 mm to 10 mm, preferably from about 1 mm to 3 mm, especially if they are implemented as a fleece. An airtight material, e.g., a plastic film, felt, compressed fleece, or membrane-film material is used as the material for the lower-side layer 5. In contrast to the material for the upper-side layer 4, the material of the lower-side layer 5 must be airtight.
It is also possible for a heating layer to be mounted on the upper-side layer 4. The upper-side covering layer preferably forms the heating layer.
The material of the box-shaped insert 3 and/or of the inlays 9 should preferably possess wear hardening of 2 kPa through 30 kPa, preferably wear hardening from 2 kPa to 15 kPa, particularly preferably wear hardening from 4 kPa through 10 kPa. This degree of wear hardening, which the separating material 2 should also have, ensures that the heating and cooling device remains stable in shape even when a person sits down in the seat.
The Figures show that the air-distribution chamber 1 is subdivided by the inlays 9 into three flow channels or flow areas, namely seen crosswise to the flow paths between the air-inlet aperture 6 and air-outlet apertures 10. When this heating and cooling device is integrated into a seat-base surface or seat back of a vehicle seat, this cross direction corresponds to the width of the seat-base surface or seat back.
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There has thus been shown and described a novel climatising device for a vehicle seat which fulfills all the objects and advantages sought therefor. Many changes, modifications, variations and other uses and applications of the subject invention will, however, become apparent to those skilled in the art after considering this specification and the accompanying drawings which disclose the preferred embodiments thereof. All such changes, modifications, variations and other uses and applications which do not depart from the spirit and scope of the invention are deemed to be covered by the invention, which is to be limited only by the claims which follow.
Number | Date | Country | Kind |
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20 2013 006 135.9 | Jul 2013 | DE | national |