阅读说明：本技术 具有光导部的销售或测试用展示装置 (Display device with light guide part for sale or test ) 是由 卢瓦克·沃苏 史蒂芬·卢瓦克·查瑞特 文森特·菲利普·帕斯卡尔·克洛斯维尔 于 2020-10-12 设计创作，主要内容包括：本申请涉及一种具有光导部的销售或测试用展示装置,所述展示装置包括用于在组装状态下容纳产品的下层(14)、发光系统(16)以及固定所述发光系统的上层,所述发光系统包括：基座(24),印刷电路板(22)以及引导件(26),所述印刷电路板包括适于发射光(L1)的发光二极管,所述引导件由半透明材料制成沿着路线(L)延伸,并且定位成与所述发光二极管相对以传导所述光,所述引导件(26)包括：上表面,所述上表面将所述光(L1)的至少一部分向下反射并形成反射光,以及下表面,所述下表面允许所述反射光的至少一部分通过并形成散射光(L3),所述引导件被构造成在所述下层形成照亮区域(20)。(The present application relates to a display device for sale or testing having a light guide, comprising a lower layer (14) for accommodating a product in an assembled state, a lighting system (16) and an upper layer fixing the lighting system, the lighting system comprising: -a base (24), -a printed circuit board (22) comprising a light emitting diode adapted to emit light (L1), and-a guide (26) made of a translucent material extending along a path (L) and positioned opposite said light emitting diode to conduct said light, said guide (26) comprising: an upper surface that reflects at least a portion of the light (L1) downward and forms reflected light, and a lower surface that allows at least a portion of the reflected light to pass through and form scattered light (L3), the guide being configured to form an illuminated area (20) at the lower layer.)

1. A sales or testing display device assembled or in kit form, the display device comprising a lower layer for containing a product in assembled state, a lighting system adapted to illuminate the product from above and an upper layer for fixing the lighting system, the lighting system comprising:

-at least one base for receiving a substrate,

-at least one printed circuit board fixed on said base and comprising at least one light emitting diode adapted to emit light, and

-a guide made of a translucent material and extending from the base along a path, the guide being positioned opposite the light emitting diodes along the path to collect and conduct the light,

the guide includes:

-an upper surface adapted to reflect at least a part of the light inside the guide downwards and form reflected light, an

-a lower surface adapted to allow at least a portion of the reflected light to pass through and form scattered light, the guide being configured to form an illuminated area at the lower layer.

2. The display device of claim 1, wherein the guide is configured such that the illuminated area is free of visually separated spots and halos from each other.

3. The display of claim 1, wherein the guide comprises polycarbonate, polymethylmethacrylate, or glass.

4. The display device of claim 1, wherein the upper surface defines protrusions or grooves forming a plurality of flat mirrors.

5. A display device as claimed in claim 1, in which the upper surface comprises white reflective paint or white reflective serigraphy.

6. The display device of claim 1, wherein the printed circuit board is movable relative to the base between a disassembled position in which the printed circuit board is separated from the base and an assembled position in which the printed circuit board is secured to the base.

7. A display device as claimed in claim 6, wherein:

-the printed circuit board comprises a first plate on which the light emitting diodes are fixed, an

-the base comprises a second plate extending in a plane perpendicular to the path and parallel to the first plate in the assembled position, and a first pin and a second pin projecting from the first plate along the path and located on the other side of the second plate with respect to the guide along the path, the first pin and the second pin being adapted to be received in a first notch and a second notch, respectively, defined by the peripheral edge of the first plate in the assembled position.

8. The display of claim 1, wherein the guide comprises a reflective surface located at an end opposite the base along the path, the reflective surface adapted to reflect at least a portion of the light located inside the guide and form a second reflected light that propagates along the path in an opposite direction relative to the light.

9. A display device as claimed in claim 1, in which the path is straight.

10. Display device according to claim 1, wherein, in the assembled state, the lighting system (16) comprises:

-a second printed circuit board having a second light emitting diode, an

-a second base from which the guide extends along the path, the second printed circuit board being fixed on the second base, and the guide being positioned opposite the second light emitting diode along the path.

Technical Field

The present invention relates to a sales or test display device, assembled or in kit form, comprising a lower layer for containing a product in assembled condition, a lighting system adapted to illuminate the product from above and an upper layer to which the lighting system is fixed. Such a display device makes it possible to display a product to be sold or tested.

Background

One type of light emitting system currently in common use comprises a plurality of light emitting diodes (or LEDs) arranged in series, each diode being adapted to emit intense white light (mainly at the physical angle forming a cone).

This type of lighting system is suitable for well illuminating the product from the point of view of the light intensity reaching the product. However, the illuminated area has a spot or halo that is produced by each of the diodes and can be clearly found by the user. These spots or halos detract from the aesthetics of the display device for the product.

It is therefore an object of the present invention to provide a display device of the above-mentioned type having technical features that make it possible to improve the display of the product.

Disclosure of Invention

To this end, the invention relates to a sales or test display device, assembled or in kit form, comprising a lower layer for containing a product in assembled condition, a lighting system adapted to illuminate said product from above and an upper layer to which said lighting system is fixed, said lighting system comprising:

-at least one base for receiving a substrate,

-at least one printed circuit board fixed on said base and comprising at least one light emitting diode adapted to emit light, and

-a guide made of a translucent material and extending from the base along a path, the guide being positioned opposite the light emitting diodes along the path to collect and conduct the light,

the guide includes:

-an upper surface adapted to reflect at least a part of the light inside the guide downwards and form reflected light, an

-a lower surface adapted to allow at least a portion of the reflected light to pass through and form scattered light, the guide being configured to form an illuminated area at the lower layer.

According to a particular embodiment, the display device comprises one or more of the following features, considered individually or according to all technically possible combinations:

-the guide is configured such that the illuminated area is free of macroscopic spots and halos separated from each other;

-the guide comprises polycarbonate, polymethylmethacrylate or glass;

-said upper surface defines a protrusion or a recess forming a plurality of flat mirrors;

-the upper surface comprises a white reflective paint or a white reflective serigraphy;

-the printed circuit board is movable with respect to the base between a disassembled position, in which the printed circuit board is separated from the base, and an assembled position, in which the printed circuit board is fixed on the base;

-the base comprises a second plate extending in a plane perpendicular to the path and parallel to the first plate in the assembled position, and a first pin and a second pin projecting from the first plate along the path and located on the other side of the second plate with respect to the guide along the path, the first pin and the second pin being adapted to be received in a first notch and a second notch, respectively, defined by the peripheral edge of the first plate in the assembled position;

-the guide comprises a reflective surface located at an end opposite the base along the path, the reflective surface being adapted to reflect at least a portion of the light located inside the guide and form a second reflected light propagating along the path in an opposite direction with respect to the light;

-the course is straight;

-in an assembled state, the lighting system comprises: a second printed circuit board having a second light emitting diode and a second base, the guide extending from the second base along the path, the second printed circuit board being fixed to the second base, and the guide being positioned opposite the second light emitting diode along the path;

the lighting system comprises one or two light emitting diodes located at the end of the guide along the route,

-the base or the printed circuit board comprises a post adapted to position the base relative to the printed circuit board in an assembled state of the display device,

-the printed circuit board comprises a heat sink,

the guide has a substantially circular cross section perpendicular to the path, with or without flats, or an elliptical, rectangular, square or trapezoidal cross section,

the largest dimension of said cross-section is between 2mm and 16mm, for example between 6mm and 8mm,

the guide is further fixed on the second layer by means of a clamp or clamping ring, for example made of metal or plastic,

-the guide is rigid and the guide is rigid,

-the guide is flexible, and

-the course is curved or defines one or more angles.

Drawings

The invention will be better understood on reading the following description, provided purely by way of example and with reference to the accompanying drawings, in which:

figure 1 is a schematic vertical cross-section of a display device according to the invention in an assembled state,

figure 2 is a schematic perspective view of the lighting system and underlying illuminated area of the display device shown in figure 1,

figure 3 is a top view of the lighting system shown in figures 1 and 2,

fig. 4 is a side view of one end of the lighting system shown in fig. 1-3, the end including a base mounted on a printed circuit board,

fig. 5 is a perspective view of the end shown in fig. 4, the base separated from the printed circuit board,

fig. 6 is a perspective view of the printed circuit board shown in fig. 2 to 5, viewed from the side including the light emitting diodes,

fig 7 is a plan view of a light emitting system constituting a first modification of the light emitting system shown in fig 1 to 5,

fig 8 is a plan view of a light emitting system constituting a second modification of the light emitting system shown in fig 1 to 5,

FIG. 9 is a plan view of a light emitting system constituting a third modification of the light emitting system shown in FIGS. 1 to 5, an

Fig. 10 is a schematic view of a different variant of the guide, shown in a section perpendicular to the path.

Detailed Description

A display 10 according to the present invention is described with reference to fig. 1. In this figure, the device 10 is shown in an assembled state. Display 10 is used to display a product 12 for sale or testing to a user (not shown).

In a variant not shown, the display device 10 is in the kit state, that is to say in the unassembled state, the detachable components being advantageously housed in a package (not shown).

In this example, the display 10 includes a lower layer 14 containing the products 12, a lighting system 16 adapted to illuminate the products from above, and an upper layer 18 to which the lighting system is secured.

According to a variant not shown, display 10 may comprise more than two layers. According to one of these variants, the upper layer 18 also comprises products illuminated by a third layer located above the upper layer 18.

Within the meaning of the present invention, "upper" means that upper layer 16 is positioned above lower layer 14 when display 10 is in the normal use position.

Advantageously, the lower layer 14 forms a shelf or drawer for containing the products 12.

Advantageously, the upper layer 18 is similar to the first layer 14, but it also serves as a support for the light-emitting system 16.

As can be seen in fig. 2, the lighting system 16 is adapted to form an illuminated area 20 at the lower layer 14.

As can be seen in fig. 2 to 4, the lighting system 16 comprises a printed circuit board 22, a base 24 and a guide 26, which is made of a translucent material and extends from the base along a path L.

In this example, the path L is straight and advantageously horizontal in the normal use position of the display device 10.

The printed circuit board 22 is fixed to the base 24. The printed circuit board 22 includes a first board 28 serving as a support portion, light emitting diodes 30 fixed on the first board, and a connector 32.

Advantageously, the printed circuit board 22 further comprises a heat sink 33.

The first plate 28 includes, for example, two apertures 34 so that two screws, two rivets or two clamps (not shown) may be used to secure the printed circuit board 22 to the base 24.

Advantageously, the first plate 28 includes a peripheral edge 36, the peripheral edge 36 defining a first notch 38, for example on a major side 40 of the first plate, and a second notch 42, for example on a minor side 44 of the first plate.

The light emitting diode 30 is, for example, a surface-mounted component (SMC) type.

Advantageously, the printed circuit board 22 is movable relative to the base 24 between a disassembled position (shown in fig. 6) in which the printed circuit board is separated from the base, and an assembled position (shown in fig. 3 and 4) in which the printed circuit board is secured to the base.

The base 24 comprises, for example, a second plate 46 extending on a plane P perpendicular to the path L and parallel to the first plate 28 in the assembled position. Advantageously, the base 24 comprises a first pin 48 and a second pin 50, which protrude from the second plate along the path L and are located on the other side of the plate with respect to the guide 26 along the path L, the first and second pins being adapted to be housed in the first 38 and second 42 notches, respectively, in the assembled position.

The base 24 is made of, for example, the same material as the guide 26. Advantageously, the base 24 is integral with the guide 26.

Advantageously, the base portion 24 includes a plurality of posts 54 on which the printed circuit board 22 is seated in the assembled position to ensure a predetermined position of the base relative to the printed circuit board in the assembled position.

According to a variant not shown, the post 54 is formed by the printed circuit board 22 and cooperates with the base 24.

The second plate 46 comprises, for example, two apertures 56 which, in the assembled position, are aligned with the apertures 34 of the first plate 28 to enable the printed circuit board 22 to be fixed on the base 24.

In the assembled position, the guide 26 opposes the light emitting diode 30 along the path L to collect and conduct light L1 emitted by the light emitting diode.

The guide 26 is configured to form an illuminated area 20 at the lower layer 14 via light L1.

The guide 26 is configured such that the illuminated area 20 is free of visually separated spots and halos. Such spots or halos may form if the lower layer 14 is directly illuminated by a plurality of light emitting diodes.

The guides 26 comprise one or more optical grade materials, advantageously capable of achieving a light transmission greater than or equal to 80%, preferably greater than or equal to 90%, determined according to standard ISO 13468-2 in 2006. The light transmission allowed by the guidance 26 is advantageously at least equal to the light transmission of the window glass.

For example, the guide 26 includes polycarbonate, polymethyl methacrylate, or glass. According to a particular embodiment, the guide 26 is made of one of these materials, the base 24 forming, for example, an end piece integral with the guide.

In this example, the guide 26 is rigid.

As can be seen in fig. 4, the guide 26 comprises an upper surface 56 adapted to reflect at least a part of the light L1 located inside the guide downwards and form reflected light L2 in the normal use position. The guide 26 includes a lower surface 58 adapted to allow at least a portion of the reflected light L2 to pass through and form the scattered light L3, thereby forming the illuminated area 20.

Advantageously, guide 26 comprises a reflective surface 60 (fig. 3) located at an end opposite to base 24, this reflective surface 60 being adapted to reflect at least part of light L1 located inside the guide and forming a second reflected light L4 that propagates in the opposite direction along path L.

For example, the guide 26 has a substantially circular cross section 62 perpendicular to the path L, which forms a flat portion 64 (right side in fig. 4 and 10).

Advantageously, the guide 26 is fixed to the upper deck 18 by means of one or more clamps 65 (fig. 1) or clamping rings, for example made of metal or plastic.

The maximum dimension D of the section 62 is for example between 2mm and 16mm, preferably between 6mm and 8 mm.

According to a particular embodiment, the upper surface 56 defines a protrusion 66 (fig. 4) or a groove forming a plurality of flat mirrors 68, each having a plurality of inclinations α with respect to the path L, advantageously varying with respect to each other along the path L. This makes it possible to adjust the amounts of reflected light L2 and scattered light L3 along the route L.

According to a particular embodiment, the upper surface 56 is provided with a white reflective paint or white reflective silk (serigraph).

The projection 66 or the groove is oriented, for example, perpendicular to the path L.

Advantageously, the illuminated area 20 is uniform. In the illuminated area 20, a strongly illuminated oval central portion 70 is shown, which is surrounded by a slightly less illuminated first peripheral portion 72 and an even less illuminated second peripheral portion 74. The central portion 70 is the only spot illuminating the area 20. The other spots are not noticeable to the observer with the naked eye. The observer cannot perceive multiple halos. The illuminated area 20 is not caused by the projected light cone generated by the plurality of diodes, but is a result of the continuous diffusion of the light along the path L by the guide 26.

To assemble display 10, lower layer 14 and upper layer 18 are assembled in a manner known per se (FIG. 1).

The printed circuit board 22 is then moved from the disassembled position (fig. 6) to the assembled position (fig. 3 and 4). The first pin 48 is engaged in the first recess 38 (fig. 4) and the second pin 50 enters the second recess 42. First plate 28 is in contact with post portion 54. Advantageously, the posts 54 fix the relative position of the base 24 with respect to the printed circuit board 22, and in particular with respect to the light emitting diodes 30, very precisely, so that the guides 26 are perfectly opposite the light emitting diodes.

Next, the printed circuit board 22 is secured to the base 24 by, for example, pushing rivets into engagement in the apertures 34 of the first plate 28 and the apertures 56 of the second plate 46.

The fixation of the lighting system 16 is for example done by fixing the guiding element 26 to the upper layer 18 using a clamp 65.

The operation of display 10, in relation to its structure, will now be briefly described.

Display 10 is in an assembled state. Optionally, the products 12 are placed in the lower layer 14 and illuminated from above by the lighting system 16.

Optionally, other products are placed on the upper layer 18. These products are illuminated, for example, by another layer not shown or by ambient light.

During operation, the light emitting diode 30 emits light L1 (fig. 2, 3, 4, and 6), which light L1 enters the guide 26.

Light L1 propagates in guide 26. The upper surface 56 reflects at least a portion of the light L1 downward and forms reflected light L2 (fig. 4).

The lower surface 58 allows at least a portion of the reflected light L2 to pass through and form scattered light L3.

The scattered light L3 forms the illuminated area 20 by falling on the lower layer 14 or product 12.

Optional reflective surface 60 returns light L1 that does not exit guide 26 in the opposite direction along path L and forms second reflected light L4. The second reflected light L4 is also reflected by the upper surface 56 and scattered by the lower surface 58.

Because of the above-described features, display 10 creates a more pleasing illuminated area for the viewer, unlike what would occur if multiple diodes were mounted in a single path. Display 10 improves the display of product 12 due to the display features of the present application.

Advantageously, display 10 makes it possible to create an illuminated area 20 for the viewer that has a uniform and smooth appearance.

Moreover, display 10, which uses only a single diode in the above example, enables significant energy savings. The environmental impact is also reduced due to the low consumption of individual leds.

The optional feature of the upper surface 56 forming the protrusions 66 allows the scattered light L3 to be modulated and, for example, have a substantially constant intensity along the path L.

Several variations of display 10 will be described below. These variants remain similar to the displays described above with reference to fig. 1 to 6. Similar elements have the same reference numerals and will not be described again. Only the differences are described in detail below.

According to a first variant, shown in fig. 7, display 10 does not comprise a reflecting surface 60. Display 10 includes a second printed circuit 122 and a second base 124 located at an opposite end of guide 26 relative to base 24.

Advantageously, the second printed circuit board 122 and the second base 124 are similar in structure to the printed circuit board 22 and the base 24, and operate similarly. The second printed circuit board 122 is fixed on the second base 124.

The second printed circuit board 122 comprises a second light emitting diode 130 adapted to emit a second light L5, the second light L5 entering the guide 26 and propagating in the opposite direction with respect to the light L1. The second light L5 is reflected by the upper surface 56 and scattered by the lower surface 58 and contributes to the formation of the illuminated area 20.

According to a second variant, shown in fig. 8, the path L is not straight but curved. The route L is for example flat.

According to another example, the course L is warped (warped).

According to a particular embodiment, the guide 26 is not rigid but flexible, which makes it possible to impart the desired shape to the path L and adapt the lighting system 16 to the environment.

According to a third variant shown in fig. 9, the path L is not straight but interrupted, that is to say in the form of a straight segment. In the example, the route L comprises two straight segments LL and LLL, e.g. forming right angles between the segments.

The guide 26 comprises two members 26A and 26B extending along the segments LL and LLL.

Between the parts 26A and 26B, the guide 26 comprises a reflective surface 160 adapted to cause the light L1 arriving from the part 26A to be directed in the part 26B, and advantageously vice versa, to cause the light arriving in the part 26B to be directed in the part 26A.

According to other embodiments, the route L is broken into more than two parts, forming several angles, e.g. any angle, between the segments.

According to the variant shown in fig. 10, the section 62 of the guide 26 does not have a substantially circular shape with a flat 64. The cross-section 62 is, for example, rectangular, circular without flats, oval, trapezoidal or square, from left to right in fig. 10. Other shapes are also possible.