DE202009018023U1 - Active glazing with integrated display - Google Patents

Abstract

Active glazing (I) with integrated display device, comprising
- on a disc (5) an electrically conductive coating (1),
On the electrically conductive coating (1) an active layer structure (15),
On the active layer structure (15) a further electrically conductive layer (14),
- At least one electrode (2a) (3a) formed by insulating regions (6) in the electrically conductive coating (1) and
A display surface (16) formed by at least one electrode (2a) (3a),
wherein the sum of the display areas (16) is at most 1/10 of the area of the active glazing (I).

Description

The The present invention relates to a glazing with integrated Display device.

It It is known that an arrangement of two electrodes is an electrical Field generated by dielectric material therethrough. approaches an object becomes the dielectric material becomes the charge distribution and affects the resulting electric field. By a suitable Transmitter can change the electric field be detected and a switching operation and / or display process to be triggered.

For example, the US 6,452,514 B1 a device and method with capacitive sensors or fields of capacitive sensors to trigger a switching operation.

From the DE 1 129 270 For example, there is known a power-on state indicator of electric hotplates behind the actuator of the switch to provide an impact-resistant and cost-effective indicator over the on-state.

From the DD 148 424 For example, a contact switch with integrated light emitter drive is known, which contains a carrier strip with light emitting diode, drive circuit and contact surfaces.

there However, it is necessary that the switching devices and / or Display devices consuming on the dielectric materials attached or applied and must be adjusted.

Of the The present invention is based on the object, an improved to provide active glazing, which is a simple and inexpensive integrated display device contains.

The Tasks are characterized by those in the independent claim 1 listed features solved. Preferred embodiments The invention are given by the features of the dependent claims.

The active glazing according to the invention with integrated Display device comprises on a disc an electrically conductive Coating, on the electrically conductive coating an active layer structure, on the active layer structure another electrically conductive layer, at least one electrode formed by isolation regions in the electrically conductive Coating and a display area formed by at least an electrode, where the sum of the display areas maximum 1/10 of the area of active glazing.

Of the Advantage of the glazing invention exists in that display surfaces regardless of the State of active glazing can be switched and thereby prematurely about the state of the active glazing can inform. The display area is based on the active layer structure of the active glazing.

In a preferred embodiment of the invention active glazing is the sum of the ad slots maximum 1/20 of the area of active glazing.

In a further preferred embodiment of the invention active glazing, the display area has a maximum of 1/100 the surface of the active glazing.

According to the Invention, it is particularly advantageous if the isolation areas a width of a width of 5 microns to 5 mm and preferred from 10 μm to 2 mm Removal of the coating or the insulation area completely circulating electrical dividing lines are formed. The isolation area can be electrically conductive and must be aware of the potential of Electrodes and a ground potential to be electrically isolated. With These isolation areas become good properties of the display device achieved.

The electrically conductive coating according to the invention is preferred a layer thickness of 10 nm to 1 μm, and particularly preferred a layer thickness of 30 nm to 300 nm. With these layer thicknesses especially good results are achieved.

In a further preferred embodiment of the invention the electrically conductive coating conductor tracks with a width of 1 .mu.m to 5 mm, and preferably of 10 .mu.m up to 2 mm.

According to the Invention, it is particularly advantageous if the interconnects of Electrodes have a width of 5 microns to 5 mm and preferred from 10 μm to 2 mm. With these electrodes will be good Achieved properties for controlling the display area.

In a further preferred embodiment of the invention, the Electrodes spiral-like, comb-like or meandering Shapes up.

The Shapes are transmitted through the preferably linear isolation regions Laser ablation or mechanical abrasion produced.

Likewise, it is advantageous according to the invention if the electrodes are connected to cable guides and contact areas with a flat conductor in order to guide the contacts out of the active glazing on a simple and hardly visible to the user.

Prefers is in addition to the further electrically conductive layer an adhesive layer and cover disc applied and the active glazing designed as a laminated glass.

In a further preferred embodiment of the invention the electrically conductive coating conductive, preferably transparent and conductive materials and especially preferably silver, zinc oxide, indium tin oxide, gallium, tin oxide, gold, Copper, tungsten and / or mixtures thereof. Silver can be considered more conductive Component of a screen printing paste but preferably as at least one transparent Silver layer with layer thicknesses of 5 nm to 30 nm by sputtering be deposited.

In A preferred embodiment of the invention has the active layer structure a switchable electrochromic, light-scattering and / or light-emitting, prefers an electrochromic function. By applying a voltage to the electrically conductive layers the properties the active layer structure with respect to light transmission, light scattering or light emission be controlled discretely or continuously.

In a particularly preferred embodiment of the invention changes the active layer structure in the display area faster their state than on the remaining area of active glazing. The State change of the active layer structures is on active glazings through the specific sheet resistance and the low electrical transverse conductivity of the electric limited conductive coatings. The faster change of state the display surfaces of the glazing invention in particular due to the small electrode area of the display area.

The active glazings according to the invention can have areas of 100 cm ² to 18 m ² . Preferably, the glazings surfaces of 400 cm ² to 4 m ² , as are customary for glazing of motor vehicles and of architectural and architectural glazings.

Especially preferred according to the invention is a signal circuit connected to contact areas of the electrodes. Likewise is a Leistungsstromkeis with at least the electrically conductive layer and the connected further electrically conductive layer.

The Signal circuits and power circuits preferably contain at least a switch and at least one supply and evaluation electronics with the switches, the different electrodes and electrical conductive layers are connected. Likewise, it is according to the Invention preferably at least one capacitive sensor and / or an inductive sensor, a mechanical and / or an electromechanical To integrate switches in the interconnection of the active glazing. The switches can be directly or indirectly over the Supply and transmitter the display area and Switch the remaining area of the active glazing. The switch can be integrated in the active glazing, or be mounted in the vicinity of the disc.

If the switch is integrated as a capacitive switch in the active glazing is, it is particularly advantageous that the switch in whole or in part is formed with electrodes of the display surface.

to Display of information is according to the invention particularly advantageous at least two display areas to integrate a display panel.

Embodiments of the invention are in the 1 to 10 shown schematically.

It demonstrate:

1 a top view of an embodiment of a glazing (I) according to the invention,

2 a cross section through an embodiment of a glazing (I) according to the invention according to the section AA 'of 1 .

3 a longitudinal section through an embodiment of a glazing (I) according to the invention according to the section B'-B of 1 .

4 a cross section with a schematic interconnection of an active glazing (I) according to the invention according to the section AA 'of 1 .

5 a cross section of an active glazing (I) according to the invention according to the section AA 'of 1 .

6 a top view of an embodiment of a glazing (I) according to the invention with schematic interconnection,

7 a top view of a further embodiment of a glazing (I) according to the invention with schematic interconnection,

8th a schematic of a plan view of a further embodiment of an inventive glazing (I) with schematic wiring of the glazing,

9 a flowchart of a method according to the invention for displaying a state of active glazing (I) and a plan view of embodiments of the state display and

10 a plan view of an inventive embodiment of a display panel of an active glazing (I).

It follows the explanation of the invention with reference to the figures according to structure and possibly also after the mode of action of the illustrated Invention.

1 to 3 show a plan view of a cross section and a longitudinal section through an embodiment of a glazing (I) according to the invention. On a windshield ( 5 ) of a vehicle was an electrically conductive transparent heat-reflecting coating ( 1 ) has been applied with a transparent conductive silver layer. The glazing (I) had a g-value of 70%. The total layer thickness of the coating ( 1 was 200 nm. The area of the glazing (I) with the electrically conductive coating ( 1 ) was 5000 cm ² . In the electrically conductive coating ( 1 ) were spiral isolation areas ( 6 ) with a width of 0.1 mm available. The isolation areas ( 6 ) separated two nested helical electrodes ( 2a () 3a ) electrically from each other. The conductor tracks of the electrodes ( 2a () 3a ) had a width of 1 mm. Through further isolation areas ( 6 ) were cable routes ( 2 B () 3b ) and contact areas ( 2c () 3c ) of the electrically conductive layer structure ( 1 ) electrically isolated. At the edge ( 4 ) of the glass pane ( 1 ) were the contact areas ( 2c () 3c ) with flat conductors ( 10 ) connected. The electrodes ( 2a () 3a ), Cable guides ( 2 B () 3b ) and contact areas ( 2c () 3c ) were transparent and not or hardly visible to the viewer. The electrodes ( 2a () 3a ) were excited with an AC voltage of 2 MHz and an alternating electric field was generated. Depending on the width of the isolation areas ( 6 ), the shape of the electrodes ( 2a () 3a ), the layer thickness of the electrodes ( 2a () 3a ), the glass pane ( 5 ) and the materials used, an impedance between the electrodes was measured. When a body, such as a human finger, approaches the electrodes ( 2a () 3a ) and / or the glass pane ( 5 ), the electric field changed and subsequently the impedance between the electrodes ( 2a () 3a ). The change in impedance was measured. The alternating electric field penetrated the glass pane ( 5 ). On the side facing away from the electrically conductive layer structure of the glass sheet ( 5 ) was in the range of electrodes ( 2a () 3a ) through the alternating field a button ( 16 ) produced with an area of 9 cm ² . To avoid unwanted detections of bodies outside the button ( 16 ) was the electrically conductive coating ( 1 ) outside the electrode area ( 2a () 3a ) via another contact area ( 3c ) at ground potential. To increase the sensitivity of the arrangement, further isolation regions ( 6 ) Intermediate areas ( 7 ) between the electrically conductive coating ( 1 ) and the electrodes ( 2a () 2 B ) of the electrically conductive coating ( 1 ) electrically isolated. The disc ( 5 ) with the electrically conductive coating ( 1 ), the isolation areas ( 6 ) and parts of the flat conductor ( 10 ) were over an adhesive layer ( 9 ) with polyvinyl butyral and luminescent particles with a cover disc ( 8th ) connected. The cover disc ( 8th ) was outboard in the vehicle. The button ( 16 ) was aligned to the passenger compartment. The button ( 16 ) could be operated from the interior of the vehicle. The button ( 16 ) was dynamically marked via luminescence in the polyvinyl butyral via a dynamic projection (head-up display, not shown) in the vehicle.

It was unpredictable for a person skilled in the art that a transparent button ( 16 ) from areas of a heat-reflecting and heatable layer ( 1 ) of a windshield could be formed, which can be used to control functions of the vehicle.

4 shows an alternative cross section with schematic interconnection of an active glazing according to the invention (I) according to the section AA 'of 1 , The glazing (I) contained between the electrode structures ( 2a () 3a ) and an additional further electrically conductive layer ( 14 ) an electrochromic layer structure ( 15 ). When applying a direct electrical voltage via a signal circuit between the electrode structures ( 2a () 3a ) and the further electrically conductive layer ( 14 ), the light transmittance of the electrochromic layer structure ( 15 ) in the display area ( 16 ) are set in an area of 9 cm ² . To control the display area ( 16 ) the signal circuit contained a switch ( 19 ) with the supply and evaluation electronics ( 13 ) was connected. By applying a direct electrical voltage across a power circuit between the electrically conductive layer structure ( 1 ) and the further electrically conductive coating ( 14 ), the transmittance of the active glazing (I) could be adjusted to an area of about 4990 cm ² . The power circuit ( 12 ) also contained at least one switch ( 19 ), which is also connected to the supply and evaluation electronics ( 13 ) was connected. Due to the independent switching possibility of the display area ( 16 ) and the remaining area of the active glazing (I), the fast-reacting display area ( 16 ge and then the remaining area of the active glazing (I). The electrodes ( 2a () 3a ) were further developed to form the alternating electric field of a button ( 16 ), so that a combined switching and display area ( 16 ) was present. In addition, the electrodes ( 2a () 3a ) with an AC voltage of 2 MHz to generate an alternating electric field for the button ( 16 ). For measuring the impedance between the electrode structures ( 2a () 2 B ), the contact areas ( 2c () 3c ) via a signal circuit ( 11 ) with the supply and evaluation electronics ( 13 ) connected. A high pass in the signal circuit ( 11 ) separated the alternating voltages and the DC voltages.

Upon detection of a body in the alternating electric field of the switching range ( 16 ), for example, a switch ( 19 ) for the display area and the active layer structure ( 15 ) first changed in the display area ( 16 ) her condition. Due to the small area of 9 cm ² , the layer structure ( 15 ) in the display area ( 16 ) within 10 ms to 10 s the transmittance. The operator was informed about the detection within a short time. The change in the switching state of the active glazing with an area of 4990 cm ² was then carried out within a period of 20 s to 3600 s.

It was not foreseeable for a person skilled in the art that a switching and / or fast-reacting display area ( 16 ) in existing electrically conductive coatings ( 1 ) could be integrated and thus an electrochromic glazing (I) could be provided, which indicated an operator within a short time the switching state of the electrochromic glazing (I).

5 shows a further embodiment of the active glazing according to the invention according to the embodiment of 4 , The difference to the glazing after 4 lies in the fact that isolation areas ( 6 ) additionally in the active layer structure ( 15 ) were introduced. By this embodiment according to the invention, the sensitivity of the switching range ( 16 ) and / or the reaction time of the display area ( 16 ) are further increased.

6 shows embodiments of the inventive heat protection glazing (I) with a button ( 16 ) or an embodiment as active electrochromic glazing with switching and display surface ( 16 ). The electrically conductive layer structure ( 1 ) was in the border area ( 4 ) of the disc ( 5 ) bordered by a frame and was at ground potential. The active glazing (I) was via switchable power circuits ( 12 ) and switchable signal circuits ( 11 ) with the supply and evaluation electronics ( 13 ) connected.

7 and 8th show in continuation of the embodiment according to the 6 an inventive heat protection glazing with a field of buttons ( 16.1 () 16.2 ) or in an alternative embodiment, an active electrochromic glazing with a field of switching and / or display surfaces ( 16.1 () 16.2 ). The electrodes ( 2a () 3a ), the cable guides ( 2 B () 3b ) of the electrodes ( 2a () 3a ) were arranged so that an overlap outside the display area ( 16 ) was avoided. In particular, this was an activation of the active layer structure ( 15 ) in the area of the line feeds ( 2 B () 3b ) avoided.

9 shows in detail an embodiment of a method according to the invention for activating or deactivating an electrochromic glazing (I) as well as the state change from opaque to transparent within the display area ( 16 ) and on the remaining active glazing (I) with the electrically conductive coating ( 1 ).

10 shows a field of display areas ( 16.1 ) ( 16.2 ) ( 16.3 ) ( 16.4 ) for indicating intermediate states in the transmittance of an electrochromic glazing (I) for the information of an operator. In the exemplary embodiment, the active glazing (I) could be switched from completely transparent to opaque via three intermediate states, and the selected state could be displayed. By repeatedly detecting a body on at least one button ( 16.1 ) 16.1 ) ( 16.2 ) ( 16.3 ) ( 16.4 ), the switching state of the active glazing (I) and the display area ( 16.1 ) 16.1 ) ( 16.2 ) ( 16.3 ) ( 16.4 ) in segments. The operator was thus immediately and clearly informed about the selected switching state of the electrochromic glazing (I) before the electrochromic glazing assumed the selected state.

It was not foreseeable for the person skilled in the art that existing electrically conductive layer structures ( 1 ) or electrode layers ( 1 () 14 ) to a button and / or display area ( 16 ) for switching states of an active glazing (I), without affecting the existing function of the glazing / active glazing (I).

I

Windows / Active glazing

1

electrical conductive coating

2a

first electrode

2 B

wiring first electrode

2c

contact area first electrode

3a

second electrode

3b

wiring second electrode

3c

contact area second electrode

4

border area

5

disc

6

Quarantine

7

between areas

8th

cover disc

9

adhesive layer

10

flat Head

11

Signal circuit

12

Power circuit

13

supply and evaluation electronics

14

Further electrically conductive layer

15

active layer structure

16

/ Display area button

16.1, 16.2, 16.3, 16.4

segments / Display area button

19

switch

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - US 6452514 B1 [0003]
• - DE 1129270 [0004]
• - DD 148424 [0005]

Claims (15)

Active glazing (I) with integrated display device, comprising - on a pane ( 5 ) an electrically conductive coating ( 1 ), - on the electrically conductive coating ( 1 ) an active layer structure ( 15 ), - on the active layer structure ( 15 ) another electrically conductive layer ( 14 ), - at least one electrode ( 2a () 3a ) formed by isolation areas ( 6 ) in the electrically conductive coating ( 1 ) and - a display area ( 16 ) formed by at least one electrode ( 2a () 3a ), where the sum of the display areas ( 16 ) is 1/10 of the area of the active glazing (I). Active glazing (I) with integrated display device according to claim 1, wherein the sum of the advertising areas ( 16 ) is not more than 1/20 of the area of the active glazing (I). Active glazing (I) with integrated display device according to claim 1 or 2, wherein the display area ( 16 ) is at most 1/100 of the area of the active glazing (I). Active glazing (I) with integrated display device according to one of claims 1 to 3, wherein the isolation areas ( 6 ) have a width of 5 microns to 5 mm and preferably from 10 microns to 2 mm Active glazing (I) with integrated display device according to one of claims 1 to 4, wherein the isolation areas ( 6 ) additionally in the active layer structure and / or the further electrically conductive layer ( 14 ) are introduced. Active glazing (I) with integrated display device according to one of claims 1 to 5, wherein the electrically conductive layer ( 1 ) has a layer thickness of 10 nm to 1 .mu.m, preferably from 30 nm to 300 nm. Active glazing (I) with integrated display device according to one of claims 1 to 6, wherein the electrically conductive coating ( 1 ) Conductor tracks having a width of 1 .mu.m to 5 mm and preferably from 10 .mu.m to 2 mm. Active glazing (I) with integrated display device according to one of claims 1 to 7, wherein at least one of the electrodes ( 2a () 3a ) has a spiral-like, comb-like or meandering shape. Active glazing (I) with integrated display device according to one of claims 1 to 8, wherein electrodes ( 2a () 3a ) with cable guides ( 2 B () 3b ) and contact areas ( 2c () 3c ) with a flat conductor ( 10 ) are connected. Active glazing (I) with integrated display device according to one of claims 1 to 9, wherein the further electrically conductive layer ( 14 ) additionally an adhesive layer ( 9 ) and cover disc ( 8th ) are applied. Active glazing (I) with integrated display device according to one of claims 1 to 10, wherein the electrically conductive coating ( 1 ) Contains silver, zinc oxide, indium tin oxide, gallium, tin oxide, gold, copper, tungsten and / or mixtures thereof. Active glazing (I) with integrated display device according to one of claims 1 to 11, wherein the active layer structure ( 15 ) has a switchable electrochromic, light-scattering and / or light-emitting, preferably an electrochromic function. Active glazing (I) with integrated display device according to one of Claims 1 to 12, having at least one signal circuit ( 11 ), wherein the signal circuit ( 11 ) at least with contact areas of the electrodes ( 2c () 3c ) connected is. Active glazing (I) with integrated display device according to one of claims 1 to 13 with at least one power current ( 12 ), wherein the power circuit with at least the electrically conductive layer ( 1 ) and the further electrically conductive layer ( 14 ) connected is. Active glazing (I) with integrated display device according to one of claims 1 to 14 with at least one switch ( 19 ) and with at least one supply and control electronics ( 13 ), the switch ( 19 ) with the supply and control electronics ( 13 ) and wherein the switch ( 19 ) comprises at least one capacitive touch sensor and / or an inductive touch sensor, a mechanical and / or an electromechanical switch, and wherein the capacitive switch ( 19 ) in whole or in part with electrodes ( 2a () 3a ) of the display areas ( 16 ) is formed.