EP2850362A1

EP2850362A1 - Indicator lamp

Info

Publication number: EP2850362A1
Application number: EP12809627.8A
Authority: EP
Inventors: Jindrich HALAMA; Jiri VARAK; Vit Ledl; Radek Melich
Original assignee: Siemens AG
Current assignee: Siemens AG
Priority date: 2012-11-20
Filing date: 2012-11-20
Publication date: 2015-03-25
Anticipated expiration: 2032-11-20
Also published as: CN104641169A; WO2014079481A1; CN104641169B; US9336966B2; US20150255230A1; EP2850362B1

Abstract

The invention relates to an indicator lamp, in particular for an electromechanical command device. The indicator lamp comprises a housing (1) and a light source (2), which is arranged in said housing (1) and emits light when supplied with energy. Furthermore, a lens arrangement (5) is provided, comprising a first lens unit (6), which is arranged in the propagation direction of the light emitted by the light source (2) and is built such that light beams emitted by the light source (2) exit substantially parallel from a side of the first lens unit (6) that faces away from the light source (2). According to the invention, the lens arrangement (5) comprises a second lens (7), which is arranged on the side of the first lens unit (6) that faces away from the light source (2) and is built such that some of the light beams exiting from the first lens unit (6) are directed with respect to the propagation direction towards a transparent side surface of the housing (1).

Description

description

The invention relates to a warning light, which is in particular part of a elektromechanisehen command device.

Indicator lights are used to visually signal a condition of a device in which the warning lights are installed. For operator-easily detectable signaling, the beacons must provide uniform and bright illumination from the front to a defined viewing angle, e.g. 60 ° with respect to a longitudinal axis of the indicator.

Indicator lights are for this purpose e.g. realized with a diffuser, with which over the (entire) surface of the indicator light a uniform illumination can be achieved. However, the provision of a diffuser disposed between a light source and a transparent, frequently colored cover usually entails a loss of brightness. The absence of the diffuser provides for a higher brightness, but brings a non-uniform illumination of the cover with it.

In order to allow a uniform brightness over the viewing area with simultaneous high luminosity, US Pat. No. 4,758,701 proposes the use of two matched Fresnel lenses between the light source and a cover. Due to the lens arrangement, the light emitted by the light source can emerge from the cover substantially parallel.

It is an object of the present invention to provide a control lamp, which may be in particular part of an electromechanical control device, which is structurally and / or functionally improved further. This object is achieved by a control lamp according to the features of claim 1 and an electromechanical command device according to the features of claim 9. Advantageous embodiments will be apparent from the dependent claims.

A warning light is proposed, in particular for an electromechanical command device. The control lamp comprises a housing and arranged in the housing

Light source which emits light when energized. Furthermore, a lens arrangement with a first lens unit is provided, which is arranged in the direction of propagation of the light emitted by the light source and arranged such that light rays emitted by the light source exit substantially parallel from a side facing away from the light source side of the first lens unit. The side facing away from the light source side of the first lens unit is an exit surface of the first lens unit. In essence, this exit surface extends perpendicular to a

Longitudinal axis of the indicator light. The exit surface of the first lens unit may have a continuous or a non-continuous profile in cross section. In particular, the exit surface can consist of a multiplicity of non-continuous partial surfaces.

According to the invention, the lens arrangement comprises a second lens, which is arranged on the side facing away from the light source side of the first lens unit and arranged such that a part of the emerging from the first lens unit light beams are directed with respect to the parallel propagation direction to a transparent side surface of the housing. The proposed warning light not only allows a uniform brightness over the viewing area with high luminosity, but also a lighting on their side surfaces, so that the visibility of the illumination of the indicator light is given even from a large viewing angle. If the indicator light is used especially in safety-relevant systems, this contributes to a higher level of safety. In addition, the visibility of the illuminated indicator light by a user is perceived as better. The advantages described can be achieved using a conventional light bulb or a light emitting diode (LED).

The transparent side surface of the housing, through which a part of the light rays is directed, can be formed by a cup-shaped, for example colored, cap. In this case, the light rays deflected by the second lens pass through the side walls of the covering cap. The undeflected light rays, however, pass through the bottom or lid of the cap. The bottom or cover forms a viewing surface of the indicator light, which, as usual, lies substantially in a plane perpendicular to the longitudinal propagation direction of the light beams.

According to an expedient embodiment, it is provided that the first lens unit comprises at least one, in particular aspherical, Fresnel lens. The use of a Fresnel lens as a first lens unit allows space-saving manner that light rays emitted by the light source substantially parallel out of the side facing away from the light source side of the Fresnel lens exit. In particular, this makes it possible to arrange the light source at a short distance from the first lens unit. If the space conditions in the indicator light play a minor role, the first lens unit can also be formed by a conventional lens with a convex surface on the side facing away from the light source side. The aspherical shape can reduce the aberrations caused by spherical lenses. According to a further expedient embodiment, the second lens is a prismatic ring whose entrance surface overlaps at least partially with the exit surface of the light beams of the first lens unit. An overlap of the entry surface of the prismatic ring with the exit surface of the first lens unit may be expedient for mechanical reasons. If as many rays of light emerging from the exit surface of the first lens unit are to be deflected to the side by the prismatic ring, then the entrance surface may also completely overlap with the exit surface of the first lens unit.

In a further embodiment, the second lens completely reflects and deflects the light beams entering it. In particular, according to this embodiment, the second lens need not be designed to reflect the light beams entering it. In cross-section, the prismatic ring has the shape of a triangle, in particular an equilateral triangle, so that the light rays entering the entry surface of the prismatic ring are reflected approximately at a right angle.

It is also expedient if the entrance surface of the second lens and the exit surface of the first lens unit are parallel to each other. In particular, the

Adjacent entrance surface of the second lens and the exit surface of the first lens unit. This ensures that the deflection of the light rays entering the prismatic ring takes place in the desired manner. By adjoining the entrance surface of the second

Lens and the exit surface of the first lens unit can create a compact indicator light.

A further embodiment of the proposed control light provides that an exit surface of the second lens is arranged parallel to a transparent surface section of a transparent cover cap and in particular to this borders. Optionally, the cap can be colored. The purpose of the cap is to provide mechanical protection of the lens assembly. If the cap is colored, a certain signal effect can be caused by the choice of color. As already explained above, the cap can have a cup-shaped shape. At this time, the light beams deflected by the second lens pass through the side walls while the undeflected light beams pass through the bottom.

According to a further embodiment, the housing between the light source and the first lens unit comprises a light reflection body, which reflects light emitted by the light source and / or reflects light reflected by the first lens unit. The light reflecting body allows a more uniform and uniform illumination of the warning light when a viewer looks at the warning light at an angle with respect to the longitudinal axis of the warning light.

It is particularly useful if, for this purpose, the light reflection body is formed from a light and diffusive material. It is particularly preferred if the light reflection body is formed from a white material. For example, the light reflecting body may consist of a colored plastic. Due to the light color and the resulting reflection properties, the light reflection body assumes the function of a "secondary" light source with respect to an oblique viewing angle.

According to a further expedient embodiment, the light reflection body extends from the light source to the first lens unit in a cone shape. As a result, the light emitted by the light source and the optionally reflected light at the lens arrangement in the desired

Be reflected by the light reflecting body to form the secondary light source. The invention further provides an electro-mechanical control device comprising a push-button or switch with a control lamp of the type described above. In contrast to a passive indicator light, an electromechanical command device makes it possible to actively give a switching command by actuating it. For example, the command device can be used to switch a machine on or off or to activate or deactivate a specific function. The structure of an electromechanical control device can be realized in many different ways and is of minor importance to the present invention. An exemplary structure of a command device can be taken, for example, from the document US Pat. No. 4,758,701 mentioned in the introduction.

The invention will be explained in more detail below with reference to an embodiment in the drawing. 1 is a cross-sectional view of a control lamp according to the invention,

Fig. 2 is an enlarged cross-sectional view of an off

Section of the Kontrollleuch te shown in Figure 1 to illustrate the led out of the indicator light beams, and

Fig. 3 is a principle known projection of a

Light source outgoing light rays through a lens assembly through which the light rays are projected into the infinite.

In the figures, the same elements are provided with the same reference numerals.

1 shows a cross-sectional view of a warning light 100 according to the invention. The warning light 100 comprises a cylindrical housing 1, in which a light source 2 is arranged. The light source 2 may be, for example, a light bulb or a light emitting diode. A longitudinal axis of the cylindrical housing 1 is marked with the reference numeral 3. The light source 2 is located on the longitudinal axis 3. Light emitted by the light source 2 extends in a substantially longitudinal direction of propagation in the direction of an outer end 4 of the housing 1. At the outer end 4 of the housing 1, a lens assembly 5 is mounted. On the side facing away from the light source 2 side of the lens assembly 5, a cap 13 is arranged. The cap 13 has a pot-shaped shape and surrounds the lens assembly 5. The cap 13 is with its lateral flanks or its side surface 12 with the outer end 4 of the housing 1, optionally releasably latched. About the locking the lens assembly 5 may be fixed in the indicator 100. The cap 13 is made of a transparent and optionally colored material. Optionally, a colored plate can also be located between the lens arrangement 5 and a viewing surface 14 of the then preferably non-colored cover cap 13 in order to achieve a signal effect which is desired in accordance with the color.

The lens assembly 5 comprises a first lens unit 6 and a second lens 7. The lens unit 6 may be formed by a single lens or a plurality of lenses. An entrance surface of the light beams of the lens unit 6 is designated by the reference numeral 8. The light beams exit via a light exit surface 9 on the side of the lens unit 6 facing away from the light source 2. The lens unit 6 is such that light beams emitted by the light source 2 exit the exit surface 9 substantially parallel. This is done a projection of the point of light emanating from the light source 2 light rays into the infinite.

This is shown schematically in FIG. Starting from the light source not shown in detail (compare reference numeral 2 in FIG. 1), the light beams 18 emitted by the punctiform light source extend in the direction of the lens unit 6 and enter the lens unit 6 through the entrance surface 8. At this time, the light rays 18 are deflected at the entrance surface (i.e., a first optical surface). A further deflection of the light beams 18 takes place after passing through the interior of the lens 6 at a light exit surface 9 (second optical surface). The shape of the lens unit 6 (which may be a single lens or a plurality of lenses) deflects the light rays 18 into the infinite in the desired manner. This means that the light rays 18 emerging from the light exit surface 9 extend approximately parallel. This results in a uniform illumination in a plane perpendicular to the longitudinal axis 3.

The same effect is achieved when the lens unit 6 is formed by a single Fresnel lens. The use of a Fresnel lens makes it possible in particular to make the distance between the light source 2 and the lens unit 6 very small. Another advantage of the Fresnel lens is that it builds very flat in contrast to the lens unit 6 shown in FIG. 3, whereby compact control lamps 100 can be realized. In the control lamp according to the invention shown in Fig. 1, therefore, a Fresnel lens is preferably used as a lens unit 6.

This ensures that the viewing surface 14 of the cap 13 is uniformly illuminated. The uniform illumination results in the indicator light 100 shown in FIG. 1 not only when the observer is on the longitudinal axis 3. Rather, the uniform illumination of the viewing surface 14 is also given when the viewing surface 14 is viewed from an angle.

The uniform illumination is supported by a arranged between the light source 2 and the lens unit 6 light reflection body 15, which has the shape of a cone in cross section. As can be seen from FIG. 1, the cone widens out from the light source 2 towards the lens unit 6. The light reflection body 15 reflects light emitted by the light source 2 and / or reflected by the lens unit 6. Preferably, the light reflecting body 15 is made of a light and diffusive material. Particularly good reflection properties arise when the light reflection body is white. For example, the light reflecting body 15 is made of a white plastic. The oblique viewing angle is understood to mean a viewing of the indicator light 100 which takes place from outside the longitudinal axis 3. It has been found that the uniform illumination effect of the viewing surface 14 to is maintained at a viewing angle 17 of 60 ° with respect to the longitudinal axis 3 or a parallel thereto The light reflection body 15 could also be formed in a parabolic shape, but for manufacturing reasons the shape of a cone is to be preferred.

By means of the second lens 7 of the lens arrangement 5, part of the light beams emerging from the first lens unit 6 can be directed with respect to the longitudinal propagation direction, ie the longitudinal axis, to the transparent side surface 12 of the cover cap 13. For this purpose, the second lens 7 is formed as a prismatic ring, while a tread 10 overlaps at least partially with the exit surface 9 of the light rays of the lens unit 6. Such a partial overlap is shown in FIG. In this case, the prismatic ring lies partly on an end face of the outer edge 4 of the housing 1.

In a modification of this embodiment, the prismatic ring 7 could also be arranged on the lens unit 6 such that the entrance surface 10 of the lens 7 completely overlaps with the exit surface 9 of the lens unit 6.

As can be readily seen from the cross-sectional illustration of FIG. 1, the prismatic ring 7 has the shape of an approximately isosceles triangle in cross-section. As a result, the lens 7 completely reflects the light beams entering it and deflects them in the direction of the side surfaces 12 of the cap 13. At the same time, a light emission in the region of the viewing surface 14 is prevented in the region of the prismatic lens 7. This results in a dark ring, which enhances the perception of the side emerging from the cap 13 light.

As a result, the illumination of the control lamp 100 can be perceived not only from the direction of the longitudinal axis and within the above-described viewing angle, but also from a complete lateral view of the indicator lamp 100.

2 shows an enlarged illustration of the illumination concept of the indicator light 100 in the region of the covering cap 13. As can readily be seen, in the region of the viewing surface 14, a clearly delimited, circularly illuminated region results. The transition from an illuminated area 19 of the viewing area 14 to an unilluminated area, which is perceivable as a dark ring 16, is identified by the reference numeral 20. The dark ring 16, which illuminates the circular illuminated surface 14, is caused by the presence of the prismatic lens 7. In contrast, the flanks or side surfaces 12 of the cover cap 13 are illuminated again due to the presence of the prismatic ring 7. This is indicated by the reference numeral 19.

In Fig. 3, the already mentioned viewing angle 17 is shown with respect to a parallel lines 3 ^λ to the longitudinal axis 3 beyond. If the parallel passes 3 ^λ through the boundary 20, then the viewing angle 17 to the outside marks the transition between the illuminated area 19 and the non-illuminated area 16.

LIST OF REFERENCE NUMBERS

1 housing

2 light source

3 longitudinal axis

3 ¹ Parallel to the longitudinal axis

4 outer end of the housing

5 lens arrangement

6 lens unit

7 second (prismatic) lens

8 light entrance surface of the lens unit 6

9 light exit surface of the lens unit 6

10 light entrance surface of the prismatic lens. 7

11 light exit surface of the prismatic lens 7

12 lateral flanks of the cap

13 cap

14 viewing area

15 light reflection body

16 dark ring

17 viewing angles

18 light beam

19 lighted area

20 border between illuminated and non-illuminated

Area

100 indicator light

Claims

claims

1. Indicator light, in particular for an electromechanical command device, comprising

- A housing (1);

a light source (2) arranged in the housing (1) which emits light when energized;

a lens arrangement (5) having a first lens unit (6) which is arranged in the propagation direction of the light emitted by the light source (2) and is such that light beams emitted by the light source (2) are substantially parallel from one of the light source (2 ) side facing away from the first lens unit (6) emerge;

characterized in that

- The lens assembly (5) comprises a second lens (7) disposed on the side facing away from the light source (2) side of the first lens unit (6) and is such that a part of the first lens unit (6) exiting light beams be directed with respect to the parallel spreading direction to a transparent side surface of the housing (1).

2. Control lamp according to claim 1, characterized in that the first lens unit (6) comprises at least one, in particular aspherical, Fresnel lens.

3. Control lamp according to claim 1 or 2, characterized in that the second lens (7) is a prismatic ring whose entrance surface (10) at least partially overlaps with an exit surface (9) of the light rays of the first lens unit (6).

4. Control lamp according to claim 3, characterized in that the second lens (7) completely reflects and deflects the light rays entering it.

5. Control lamp according to claim 3 or 4, characterized in that the entry surface (10) of the second lens (7) and the exit surface (9) of the first lens unit (6) parallel to each other and in particular border.

6. Control lamp according to one of the preceding claims, characterized in that an exit surface (11) of the second lens (7) is arranged parallel to a transparent surface portion of a transparent and optionally colored cap (15) and in particular adjacent to this.

7. Control lamp according to one of the preceding claims, characterized in that the housing (1) between the light source (2) and the first lens unit (6) comprises a light reflection body (15) which emitted from the light source (2) and / or the first lens unit (6) reflects reflected light.

8. Control lamp according to claim 7, characterized in that the light reflection body (15) is formed of a light, in particular white, and diffusive material.

9. Indicator lamp according to claim 7 or 8, characterized in that the light reflection body (15) differs from the

Light source (2) to the first lens unit (6) cone-shaped extended.

10. Electromechanical control device, comprising a push-button (10) comprising a control lamp (100) according to one of the preceding claims.