WO2017121886A1 - Film control device for a liquid crystal film - Google Patents

Abstract

The invention relates to a film control device (200) for a liquid crystal film and to a method for controlling the liquid crystal film by means of the film control device (200), using at least one supply voltage. The film control device (200) has at least one adjustable voltage supply (201), at least one first voltage output (203) and at least one second voltage output (203) for supplying the liquid crystal film with a supply voltage in the form of an alternating voltage, the adjustable voltage supply (201) being connected to the first and the second voltage output (203) and the adjustable voltage supply (201) providing the supply voltage. The invention also provides a potentiometer which is connected to the adjustable voltage supply (201) in order to control the supply voltage.

Description

 Film control device for a Flüssigkristatlfolie

description

The invention relates to a film control device for a liquid crystal film and to a method for controlling a liquid crystal film having at least one supply voltage with the film control device.

The use of liquid ^' igkr ^' istallen has meanwhile also made its way into glass element technology. Thus, a glass element is known from the prior art, which is provided with a liquid crystal film. For example, the liquid crystal film is arranged between a first glass pane and a second glass pane. By applying a voltage to the liquid crystal film, poles of liquid crystals align with the liquid crystal film, so that the liquid crystal film becomes transparent. In other words, the liquid crystal film becomes clear when the voltage is applied. When the voltage is not applied, the liquid crystals are randomly oriented. In the liquid crystal film incident light is therefore strongly scattered. It is thus opaque, ie not transparent It is thus possible to make a glass element provided with the liquid crystal film (for example a glass window or a glass door) transparent by applying a voltage or by switching off the voltage close.

It may happen that a liquid crystal film of a glass element has to be examined and maintained. For this purpose, it has usually been necessary to completely remove the glass element from its holder. Only then can the liquid crystal film be examined. This is time consuming and costly.

It is currently known from the prior art that the liquid crystal film can only be switched in two operating modes. In the first operating mode, the liquid-crystal film is milky (ie opaque). In the second mode of operation, the liquid crystal film is transparent. It is desirable to be able to variably choose the degree of transparency. In other words, it is desirable to be able to control the liquid crystal film in such a way that further operating modes can be set between the opaque state and the transparent state, for example a state with 20% or 50% transparency (transparency).

The invention has for its object to be able to choose the degree of transparency of the liquid crystal film freely. According to the invention this object is achieved with a film control device for a liquid crystal film with the features of claim 1. A method according to the invention is given by the features of claim 11. A system comprising a transparent disk, a liquid crystal film and a film control device is given by the features of claim 13. A further film control device according to the invention is given by the features of claim 17. Further features of the invention will become apparent from the following description, the appended claims and / or the accompanying drawings. The film control device according to the invention is provided for a liquid crystal film which is arranged on a transparent pane. For example, the transparent pane is designed as a glass element. The glass element is designed, for example, as a glass window or as a glass door. However, it is explicitly pointed out that the invention is not restricted to use in glass elements. Rather, the invention is suitable for any element in which a liquid crystal film is used, for example, a transparent plastic element, in particular a Plexiglas element.

The film control device according to the invention has at least one adjustable voltage supply which is connected to at least one first voltage output and at least one second voltage output. The first voltage output and the second voltage output are used to supply the Flüssigkrisfallfolie with a trained as AC voltage supply voltage. The adjustable voltage supply provides the supply voltage. In addition, the film control device according to the invention has at least one potentiometer which can be connected to the adjustable voltage supply. supply for regulating the supply voltage is connected. In this case, a potentiometer is understood to mean any actuating unit which is suitable for regulating the supply voltage. These include, but are not limited to, analog potentiometers and / or digital actuators.

The invention has the advantage that due to the potentiometer, the degree of transparency of the liquid crystal film can be chosen freely.

In one embodiment of the film control device according to the invention, it is provided that the adjustable voltage supply is designed as a phase section control. Additionally or alternatively, it is provided that the adjustable voltage supply is designed as a phase control. Again in addition or alternatively, it is provided that the film control device has a control unit for adjusting the frequency of the supply voltage. As mentioned above, the supply voltage is an AC voltage having a frequency. The frequency is adjusted by means of the control unit. In this embodiment, it is possible to influence and adjust the degree of transparency of the liquid crystal film by means of the frequency of the power supply voltage.

In yet another embodiment of the film control device according to the invention, it is provided that the film control device has a control unit for setting an amount of current, wherein the set amount of current for controlling the liquid crystal film is provided. This embodiment is based on the fact that a control of the liquid crystal film can also be done on the amount of electricity.

In one embodiment of the film control device according to the invention, it is provided that the potentiometer for regulating the supply voltage to a voltage value in the range of 0 V to 65 V AC voltage is designed. This range is particularly advantageous since liquid crystal films which are supplied with such a supply voltage are particularly easy to control. The desired degree of transparency achieved with these voltage values is particularly easy to achieve. For example, at a supply voltage of 65 V AC, the liquid crystal film is almost transparent. Further, for example, at a supply voltage of 0 V, the liquid crystal film In a further embodiment, the degree of transparency may additionally depend on the supply voltage also on the area of the liquid-crystal film as well as on the temperature of the liquid-crystal film According to the invention, the potentiometer is designed to regulate the supply voltage to a voltage value in the range from 0 V to 120 V AC voltage a voltage value in

Range from 0 V to 230 V AC voltage is designed. The supply voltage ^"is not limited to the aforementioned ranges. Rather, the supply voltage may take any suitable value, which is suitable for the invention.

In yet another embodiment of the film control device according to the invention, it is additionally or alternatively provided that the first voltage output and the second voltage output can be switched to a first operating mode and to a second operating mode. In the first operating mode, the supply voltage can be supplied to the liquid crystal film. In a second operating mode, a reset supply voltage designed as an alternating voltage is supplied to the liquid crystal foil. In one embodiment of the film control device according to the invention, it is additionally or alternatively provided that the reset supply voltage is greater than the supply voltage. For example, the reset supply voltage is in the range of 90 V to 230 V AC (AC), or in the range of 100 V to 190 V AC or in the range of 120 V to 170 V AC. In another embodiment, the reset supply voltage is 130 V AC. This embodiment is based on the following idea. When contacts are made on the liquid crystal film, micro-shorts may occur between the contacts of the liquid crystal film, increasing in size as the liquid crystal film is operated. It can then happen that, at a certain point in time, the current through these micro-shorts is so great that the voltage between the contacts is no longer sufficient to switch the liquid-crystal foil into a transparent state. Accordingly, it may happen that the liquid crystal film in a milky state remains, even if the film control device the

Actuates liquid crystal film such that the liquid crystal Ifolie would have to be transparent. Since this condition is undesirable, it is necessary to maintain the liquid crystal sheet. In general, it was previously necessary that the transparent

Slice, such as a glass sheet of a window or a door, is completely removed from a holder and the liquid crystal film is examined thereafter. This is time consuming and costly. It has now been found that when the reset supply voltage is applied, which is, for example, significantly above the normal supply voltage, the liquid-crystal film can be restored to such a state that the film control device can control any degree of transparency again. This takes place here in the second operating mode, which is taken in a short time. For example, a few seconds are enough. In the second operating mode, the current in the micro-short circuits is increased in such a way that their electrical conductivity is interrupted. The reset

Supply voltage is, for example, greater than 100 V AC, or greater than 130 V AC or greater than 200 V AC. In yet another embodiment of the film control device according to the invention, it is additionally or alternatively provided that the film control device has a component supply output to which a component supply voltage from the range of 10 V to 15 V DC voltage is applied. For example, the component supply voltage is 12 V DC. The component is, for example, a relay with which the supply voltage for the liquid crystal film is switched off or switched on depending on a detected switching state. The switching state is detected, for example, by a contact, in particular a reed contact, for example on a door. For example, a first switching state is detected with a locked door. Then, for example, the supply voltage is switched off, that is set to 0 V AC voltage, so that the liquid crystal film is almost opaque. Furthermore, a second switching state is detected when the door is unlocked and opened, for example. Then, for example, the supply voltage is switched on, for example, set to 65 V AC voltage, so that the liquid crystal film assumes a switching state corresponding degree of transparency. For example, the liquid crystal film becomes almost transparent or semi-transparent.

In a further embodiment of the film control device, it is additionally or alternatively provided that the film control device has at least one power supply, with which the component supply voltage is provided. In addition, it is additionally or alternatively provided that the film control device has a programmable switching unit for determining switching states of the component, wherein in a first switching state, the component has a first operating mode and wherein in a second switching state, the component has a second operating mode. This embodiment provides, for example, that can be freely programmed by means of the programmable Schalteretnhelt whether the supply voltage is switched off or switched on in a detected switching state. The invention also relates to a method for driving a liquid crystal film, which is arranged on a transparent pane, with a supply voltage using a film control device which has at least one of the above-mentioned features or a combination of at least two of those above or below has mentioned features. The method according to the invention comprises the step of

Supply voltage to the liquid crystal sheet for a period of time from 1 second to 10 seconds. In particular, it is provided to supply the reset supply voltage for a period of time from the range of 2 seconds to 5 seconds. As a result, the advantages already mentioned above are achieved.

The invention also relates to a system with at least one transparent one

 Washer, for example a glass element and / or a glass pane of a window or a glass door. Furthermore, the system has at least one liquid crystal film arranged on the transparent pane. In addition, a film control device for controlling the Flüssigkristalifolie is provided, wherein the film control device has at least one of the above or below mentioned features or a combination of at least two of the above or below mentioned features.

In a further embodiment of the system according to the invention it is additionally or alternatively provided that at least one light source is arranged on the Flüssigkristailfolie. For example, the light source is designed as an LED. The invention is not limited to an LED. Rather, any light source suitable for the invention can be used. In a still further embodiment of the system according to the invention, it is additionally or alternatively provided that the system has a light source control unit for controlling the light source. The abovementioned embodiments of the system according to the invention are suitable for illuminating the liquid-crystal film in any adjustable degree of transparency as desired. For example, the liquid crystal film is illuminated in a lightly or strongly scattering state. A slightly scattering state can be achieved, for example, at a supply voltage of approximately 20 V to 50 V AC. A strongly scattering state can be achieved, for example, with a supply voltage of approximately 0 V to 5 V AC. In the slightly or strongly scattering state, when the light source of the light source is irradiated into the liquid crystal film, the liquid crystal film can be used as a luminaire, which can be used, for example, to illuminate a room. Because of this, for example, the number of lights in a room can be reduced, so that the cost of installations in the room is reduced. Furthermore, this embodiment can be used in the artistic field.

The invention will be described in more detail below with reference to exemplary embodiments. 1 shows a schematic representation of a first embodiment of a

 Glass element in the form of a window with a Flüssigkristailfolie;

Figure 2 is a schematic representation of a film control device; FIG. 3 shows a further schematic representation of the film control device according to FIG. 2; such as

Figure 4 is a schematic representation of a second embodiment of a

 Glass element in the form of a window with a liquid crystal foil.

FIG. 1 shows a schematic representation of a system 100, which has a first transparent disk 101 and a second transparent disk 102. Between the first transparent disk 101 and the second transparent disk 102, a liquid crystal film 103 is disposed. The

Liquid crystal film 103 is laminated on the first transparent plate 101, for example. The first transparent pane 101 is formed for example of glass or Plexiglas. Furthermore, it is for example also intended to form the second transparent pane 102 made of glass or Plexiglas.

For example, the system 100 is attached to a house wall with at least one fitting (not shown). In particular, it is envisaged that the system 100 be formed as a movable or immovable glass window or as a glass door. By applying a supply voltage to the liquid crystal film 103, poles of liquid crystals align with the liquid crystal film 103, so that the liquid crystal film 103 becomes transparent. In other words, the liquid crystal sheet 103 becomes clear upon application of the supply voltage. When the supply voltage is not applied, the liquid crystals are randomly oriented. Light incident on the liquid crystal film 103 is therefore largely scattered. The liquid crystal film 103 becomes opaque (ie "milky ^* ). It is therefore opaque, not transparent. It is thus possible to make the system 100 (for example, a glass window or a glass door) provided with the liquid crystal film 103 opaque by applying the supply voltage or by turning off the supply voltage opaque. The supply voltage is provided by a foil control device 200, which is connected via lines 104 to the liquid crystal foil 103.

The film control device 200 is shown schematically in FIGS. 2 and 3. The film control device 200 has a phase section controller 201. The phase section controller 201 is a power divider operated with AC voltage. The AC voltage is an input voltage of the foil controller 200. Any voltage can be used as the input voltage. For example, the input voltage is 110 V AC, 220 V AC or 230 V AC. In the embodiment shown here, the input voltage is 230 V AC. The AC voltage is applied to terminals 1 and 2 of a connection terminal 203 of the film control device 200. From the terminals 1 and 2 of the terminal 203, the input voltage is applied to a terminal unit 204 of the phase section controller 201. The phase section controller 201 now provides the supply voltage for the liquid crystal foil 103. In the exemplary embodiment shown here, it is provided that the phase section controller 201 provides a supply voltage in the amount of 65 V ± 5 V in the form of an AC voltage. The invention is not limited to the aforementioned values of the supply voltage. Rather, any value of the supply voltage is suitable, which is suitable for the invention. For example, in another embodiment, the phase section controller 201 provides a supply voltage of 120V ± 5V in the form of an AC voltage. In yet another embodiment of the invention, it is provided that the phase section controller 201 provides a supply voltage in the amount of 230 V ± 5 V in the form of an AC voltage.

The film control device 200 also has a potentiometer 202, which is shown schematically in FIG. The potentiometer 202 is connected to the terminals 10 to 12 of the terminal 203. The potentiometer 202 is arranged, for example, on a wall of a room. The potentiometer 202 is connected to the clamping unit 204 of the phase section controller 201, by means of which the supply voltage of the liquid crystal film 103 is switched on or off in dependence on a detected switching state (for example a locked or unlocked door). The potentiometer 202 cooperates with a first series resistor 205. The first series resistor 205 is, for example, a resistance of 120 kQ. By means of the potentiometer 202 and the first series resistor 205, it is now possible to set the supply voltage to a value between 0 V to 65 V AC voltage at the phase section controller 201. The supply voltage is then applied to the terminals 5 and 6 of the terminal 203. At the terminal 203, the lines 104 are arranged {not shown in Figures 2 and 3). In this way, the supply voltage of the liquid crystal film 103 is provided. Due to the potentiometer 202, the degree of transparency of the liquid crystal film 103 can be freely selected. The achieved with the aforementioned voltage values desired degree of transparency is particularly easy to reach. For example, at a supply voltage of 65 V AC, the liquid crystal film 103 is almost transparent. Further, for example, at a supply voltage of 0 V AC, the liquid crystal foil 103 is almost opaque, since it is highly scattering (ie, basically "milky.") At a supply voltage between OV and 65V AC, a degree of transparency is achieved between the almost opaque and almost transparent state of the Flussigkristallfolie 103 is located.

The film control device 200 also has a second series resistor 206. The second series resistor 206 is, for example, a resistor of 47 kö. The second series resistor 206 is connected to a button 207. If the button 207 is pressed and thereby the second resistor 206 is connected in parallel to the first resistor 205, then the liquid crystal film 103 is not the supply voltage in the range of 0 V to 65 V AC voltage provided, but a reset supply voltage. This reset supply voltage is significantly larger than the supply saving, from the range of 0 V to 65 V AC. The reset supply voltage is for example in the range of 90 V to 230 V AC, or from 100 V to 190 V AC, or from 120 V to 170 V AC. For example, the reset supply voltage is 130 V AC. As explained briefly above, it may happen that the liquid crystal film 103 remains in a milky state even if the film control device 200 drives the liquid crystal film 103 such that the liquid crystal film 103 would have to be transparent. Since this is an undesirable state, it is necessary to maintain the liquid crystal sheet 103. When the reset supply voltage is supplied, the liquid crystal film 103 can be restored to such a state that the film control device 200 can control each degree of transparency again. The reset supply voltage is provided to the terminal 4 of the terminal 203. Also at the terminal 4, the lines 104 are arranged so that the reset supply voltage of the liquid crystal film 103 can be supplied. The reset supply voltage is supplied to the liquid crystal film 103, for example, for a period of time from the range of 1 second to 10 seconds, especially up to 5 seconds.

The film control device 200 further has a component supply unit 208 on. The component supply unit 208 is provided with a power supply 209 having an integrated circuit 210. The power supply 209 serves to provide a component with a component supply voltage. The integrated circuit 210 transforms the input voltage of 230 V AC to the component supply voltage, for example to 12 V DC. In other embodiments, other input voltages are provided, for example, 110 V AC.

The component supply voltage in the amount of 12 V DC voltage is applied to the terminal 7 of the terminal 203 and serves to supply a

 Bolt contact 212, which is arranged for example on an actuatable locking unit of a door or a window (not shown). For example, as soon as a window or door of the system 100 is locked to the actuatable latch unit, contact is initiated in one embodiment. This is the first switching state. If the window or door of the system 100 is unlocked with the actuatable latch unit, in one embodiment the contact is released. This is the second one

 Switching state. The first switching state and the second switching state serve to generate control signals for the liquid crystal film 103. In the first switching state, the supply voltage is switched off, for example, by means of the relay 214. Accordingly, the liquid crystal film 103 is supplied with a supply voltage of 0 V such that the liquid crystal film 103 is completely opaque. In the second switching state, the supply voltage is switched on by means of the relay 214. For example, the liquid crystal film 103 is supplied with a supply voltage such that the liquid crystal film 103 is transparent depending on the setting of the potentiometer 202. For example, when 65 V AC is supplied to the liquid crystal film 103, the liquid crystal keto 103 is almost transparent. If the potentiometer 202 is set to supply the liquid crystal foil 103 with a supply voltage between 0 V AC and 65 V AC, then a degree of transparency is achieved which is between the near-opaque state and the almost transparent state.

The latch contact 212 is arranged on the connection 8 and on the connection 9 of the connection terminal 203. -

In addition, the component supply unit 208 has a latch contact controller 211. The latch contact controller 211 also includes the latch contact 212. Further, the latch contact controller 211 includes a programmable switching unit 213 in the form of a jumper. By means of the programmable switching unit 213, it is determined what is caused by the first switching state and what by the second switching state. For example, in the first switching state, the liquid crystal film 103 is supplied with the supply voltage in such a way that the liquid crystal film 103 is completely transparent. Alternatively, the programmable switching unit 213 can be set to apply the supply voltage in the first switching state to the liquid crystal film 103 in such a way that the liquid crystal film 103 becomes transparent depending on the setting of the potentiometer 202. The same applies to the second

Switching state.

FIG. 4 shows, in a schematic representation, a further exemplary embodiment of the system 100. The exemplary embodiment of FIG. 4 is based on the embodiment of FIG. 1. Identical components are identified by the same reference numeral. In contrast to the embodiment of Figure 1, the Ausführungsebelspiel of Figure 4, a light source 215 on. The light source 216 is formed, for example, as an LED. The system 100 also includes a light source control unit 216 for driving the light source. The embodiment of the system 100 is suitable for illuminating the FIQssigkristallfolie 103 in any adjustable degree of transparency as desired. For example, the liquid crystal film 103 is illuminated in a lightly or strongly scattering state. A slightly scattering state can be achieved, for example, at a supply voltage of approximately 20 V to 50 V AC. A strongly scattering state can be achieved, for example, at a supply voltage of approximately 0 V to 5 V. In the slightly or strongly scattering state, when the light source 215 is irradiated into the liquid crystal film 103, the liquid crystal film 103 can be used as a luminaire, which can be used, for example, to illuminate a room. Because of this, for example, the number of lights in a room can be reduced, so that the cost of installations in the room is reduced.

The features of the invention disclosed in the present description, in the drawings as well as in the claims can be applied individually as well as in Any combination for the realization of the invention in its various forms of execution essential.

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Bezugszefchenliste

100 system

 101 first transparent pane

102 second transparent pane

 103 Liquid crystal sheet

 104 lines

200 slide control device

201 phase section control

 202 potentiometers

 203 Anechiussklemme with 12 clamping units

204 more clamping unit

 205 first series resistor

206 second series resistor

 207 buttons

 208 component supply unit

 209 power supply

 210 integrated circuit

 211 latch contact control

 212 bar contact

 213 programmable switching unit

 214 relays

 215 light source

 216 light source control unit

Claims

-Patentaneprüche

1. film control device (200) for controlling a liquid crystal film (103) which is arranged on a transparent plate (101, 102), with

at least one adjustable voltage supply (201),

 - With at least a first voltage output (203) and at least one second voltage output (203) for supplying the liquid crystal film (103) with a formed as AC voltage supply voltage, wherein the adjustable voltage supply (201) with the first voltage output (203) and with the second voltage output (203) is connected and wherein the adjustable voltage supply (201) provides the supply voltage, and with

 - At least one potentiometer (202) which is connected to the adjustable power supply (201) for controlling the supply voltage.

The film control device (200) of claim 1, wherein the film control device (200) has at least one of the following features

(I) the adjustable voltage supply (201) is designed as a phase section control;

 (il) the adjustable voltage supply (201) is designed as a phase control;

 (iii) a control unit for adjusting the frequency of the supply voltage.

The film control device (200) of claim 1 or 2, wherein the film control device (200) has one of the following features: (i) the potentiometer (202) ^" is designed to control the supply voltage to a voltage value in the range of 0 V to 65 V AC voltage;

 (ii) the potentiometer (202) is designed to regulate the supply voltage to a voltage value in the range of 0 V to 120 V AC voltage;

 (iii) the potentiometer (202) is designed to regulate the supply voltage to a voltage value in the range of 0 V to 230 V AC.

4. film control device (200) according to one of the preceding claims, wherein

the first voltage output and the second voltage output are switchable into a first operating mode and into a second operating mode,

- In the first operating mode, the supply voltage of the liquid crystal film (103) can be fed, and wherein

 - In the second mode of operation designed as an AC voltage reset supply voltage of the liquid crystal film (103) can be fed.

5. film control device (200) according to claim 4, wherein the reset supply voltage is greater than the supply voltage.

The film control device (200) of claim 5, wherein the film control device (200) has at least one of the following features:

 - The reset supply voltage is in the range of 90 V to 230 V.

 AC voltage;

 - The reset supply voltage is in the range of 100 V to 190 V.

 AC voltage;

 - The reset supply voltage is in the range of 120 V to 170 V.

 AC voltage; or

- The reset supply voltage is 130 V AC. -

7. The film control device (200) according to one of the preceding claims, wherein the film control device (200) has a component supply output (203) against which a component supply voltage is applied, wherein the component supply voltage is a DC voltage in the range of 10 V to 15 V is.

8. The film control device (200) according to claim 7, wherein the component supply voltage is 12 V.

9. The film control device (200) according to claim 7 or 8, wherein the film control device (200) has at least one power supply unit (209) for providing the component supply voltage.

10. Foam damper (200) according to claim 9, wöbet the foil control device (200) has a programmable switching unit for determining switching states of the component (212), wherein in a first switching state, the component (212) has a first operating mode and wherein in a second switching state the component (212) has a second operating mode.

11. A method for driving a liquid crystal film (103), which on a

 transparent disc (101, 102) is arranged, with at least one supply voltage using a foil control device (200) according to one of the preceding claims, wherein the method comprises the following step:

the reset supply voltage is supplied to the liquid crystal film (103) for driving the liquid crystal film (103) for a period of time from the range of 1 second to 10 seconds.

12. The method of 11, wherein the reset supply voltage for a period of time from the range of 2 seconds to 5 seconds is supplied.

13. System (100) with

 at least one transparent pane (101, 102),

 - At least one on the transparent plate (101, 102) arranged liquid crystal film (103), and with

 - At least one film control device (200) for controlling the liquid crystal film (103) according to at least one of claims 1 to 10.

14. System (100) according to claim 13, wherein the transparent pane (101, 102) is a glass pane.

15. System (100) according to claim 13 or 14, wherein at least one light source (215) is arranged on the liquid crystal film (10).

The system 100 of claim 15, wherein the system (100) comprises a light source control unit (216) for driving the light source (215).

17. Film control device (200) for controlling a liquid crystal film (103) which is arranged on a transparent pane (101, 102), with

at least one adjustable power supply,

 - At least one current output for supplying the liquid crystal film (103) with a predetermined amount of power, wherein the adjustable power supply is connected to the power output and wherein the adjustable power supply provides the predetermined amount of power, and with

 - At least one potentiometer, which is connected to the adjustable power supply for controlling the predetermined amount of power.