DE4019211A1 - POWER CONTROLLER WITH TOUCH SWITCH - Google Patents

Description

Background of the Invention 1. Field of the Invention

The invention relates to a power control system with touch switches.

2. Description of the prior art

Dimming light sources is desirable to provide energy to save, to extend the life of the lamps and to aesthetically improve the environment. Known circuit methods, for example Leading edge controls are widely used to adjust the performance resulting from a AC voltage source supplied to a lighting source becomes.

Different dimming circuits, for example those according to the US-PS 37 46 923, are designed so that they in one fit electrical over or flush-mounted box that are common to the usual rocker switch accommodate. Other circuits generally used for Controlling larger powers are required  Chambers in an electrical cabinet or the like can be accommodated. In any case, a Dimmer actuator manipulated so that the Brightness of the light sources is set. Some Dimmer circuits are located across several remotely located Actuators controllable, with each actuator in the Is able to "command" the dimmer circuit from one to take over another actuator (cf. for example, US Pat. No. 4,689,547).

Numerous types of actuators are used to To operate dimmer switches. The earliest Actuators were rotary actuators. These point generally a round button around a central one Axis is rotatable. A rotary potentiometer behind the Button is mounted, it is operated to generate a signal for example a variable voltage or a Resistance to deliver to control the performance that is transmitted to the load by the dimmer circuit. A disadvantage of the rotating actuators is that that they are not simply the light level (e.g. a light source in an adjacent one Space) from the orientation of the button to let. Generally, a cover plate fits between the knob and the potentiometer to turn the potentiometer to protect against dust and dirt and around a to achieve an aesthetically pleasing appearance. In the The present description and the claims are intended to a "cover plate" means a plate that has a front and a rear surface. The front surface is prominent and common aesthetically pleasing. The back surface is  generally out of sight.

Linear slide actuators, as in the US-PS 37 46 923 are described in the Dimmer industry largely introduced. You point generally a slide that extends along one predetermined path moves. There is a behind the glider linear potentiometer arranged, which is a variable Voltage or a variable resistance of the Dimmer circuit delivers. Generally, such Slider dimmer the light level in a simple way Detect slider position.

Recently there are dimmers with a touch actuator has been developed. A touch dimmer generally includes a device operated by touch or pressure, which controls a conventional dimmer circuit. This one Devices are typically small and thin, can make touch dimmers flat, compact and less are strikingly manufactured as mechanically operated Dimmer. The rough construction of touch actuated Devices makes these dimmers permanent and reliable.

With a type of touch dimmer like this from "Home Automation" is manufactured, they have one conductive cover plate electrically with a Control circuit is connected. By touching the conductive plate with your finger or the like the electrical capacitance value increases, which is indicated by a Control circuit is determined. This control circuit delivers signals to a dimmer circuit around which one  To control load supplied power. The system works as follows: When a finger comes into contact with the plate is held, then the brightness of one changes Light source over a range of selectable Light levels. If the finger is removed, then the circuit remains at a certain light level stand, which is then maintained. One only instant contact with the conductive plate switches alternatively the lighting now and then on the last set light level. One disadvantage of this Touch dimmer is that the setting of the Light crossing a range of light levels required before the desired light level is reached. Since there is also a certain delay in the response of the Eye on the changing light level, it can be difficult to stop at a light level that is after Eye adjustment appears correct.

The "Touch-A-Levele" lamp dimmer, manufactured by Westek, San Diego, California, is manufactured in one Power plugs can be plugged in up to 200 W power to steer after a table lamp. He is touched actuated to immediately from a range of light levels to choose the power supplied to the lamp. The dimmer has an elongated flexible plastic strip on the multiple electrical contacts along the length owns and one on the front surface Plastic cover plate is attached. By touching the flexible strip anywhere along the length is caused that one or the other contact closes, so that a signal is delivered that one corresponds to certain light levels. The contacts are like this  arranged to have a discrete area of about 25 deliver selectable light levels. Two drawbacks to this Westek dimmers are that not one continuous range of selectable light levels can be brushed and that the flexible Stripe that adheres to the cover plate for a long time Can peel off use.

Essence of the invention

The present invention provides one in a wall box accommodatable power controller, one by one Touch operated device, the rear a flexible area of a removable cover plate is arranged. A control circuit is arranged that they receive signals - preferably instantaneous voltages - from the touch operated device to control a conventional dimmer circuit. In this Description and in the claims is intended under one Signal of any measurable size, and an electrical or other size, through which information from one place to another can be transferred. The operated by touch The device is preferably a thin membrane is supported against the back of the cover plate. Electrical connections after the device end in a connector socket that receives a plug electrical connection with the device and the Manufacture dimmer circuit. Plug and socket are separable to be able to remove the cover plate.  

A control circuit according to the invention controls one conventional dimmer circuit according to the Instantaneous voltage signals through a through Touch operated device can be supplied. The Circuit has an electronically adjustable Voltage divider (EAVD) based on a continuous Delivers voltage that comes from a range of voltages is selectable, and a comparator is provided which - the EAVD so that there is a continuous voltage is delivered which corresponds to the instantaneous voltage. The continuous voltage is applied to the dimmer circuit applied to the power supplied to the load Taxes. In this description and in the claims is meant by "load" any device that uses electrical power. A burden can be a light source, for example a Filament lamp or a gas discharge lamp, or them can also be a motor etc.

The present invention also provides one non-volatile memory for storing Power levels. After a power cut, the Store the power back to a level before the Interruption was set. Instead, the Power to any preset level or to Turn off be saved depending on whether the load was on or off before the interruption took place.

There can be several actuators of the type described an area to be distributed to control a conventional dimmer switch from many places  enable. In this case, everyone is touched actuated facility will be able to To deliver instantaneous voltage signal that one corresponds to certain desired light levels. The Characteristics of the circuit are such that the Power levels correspond to the signal emitted by the last actuated switch was delivered.

According to one embodiment of the invention, a System for controlling the power from one source a combination of the following characteristics:

• a) a cover plate that a front surface and a Has an area that is flexible
• b) means operable by touch behind the flexible area to receive a signal according to the pressure deliver who exercised on the flexible area was, and
• c) a circuit to determine the power delivered by the source after the load delivered according to the signal becomes.

According to a further embodiment of the invention a system to control the power from a source after a load in combination the following characteristics:

• a) a voltage divider that can be actuated by touch, that provides an instantaneous tension that comes from one Range of voltages can be selected,  
• b) an electronically adjustable voltage divider to to deliver a continuous tension that out a range of voltages can be selected,
• c) means to the instantaneous voltage and the to compare continuous tension and the electronically adjustable voltage divider so set that a predetermined relationship between the tensions is obtained, and
• d) a circuit to control the performance of the source after the load according to the continuous Voltage is supplied.

According to a further embodiment of the invention is a system that can be operated from many positions provided to post the power from a voltage source to control a load, which in combination includes:

• a) several devices which can be actuated by touch, which can be arranged in many places and each of which provides an instantaneous tension that selectable from a range of voltages is
• b) means for storing the information that is representative of the instantaneous voltage, and um a continuous corresponding tension deliver,
• c) a circuit that measures the power from the source after the load according to the continuous voltage  certainly.

According to a further embodiment of the invention is a system to control the performance of one Source provided after a load, which in combination includes the following features:

• a) means operable by touch to provide a signal to deliver according to an applied pressure,
• b) Means that do not require performance in order to Store information relevant to the signal is representative, and
• c) a circuit to determine the power delivered by the source after the load delivered according to the signal becomes.

Brief description of the drawings

Fig. 1 is a cross-sectional view of a membrane switch of known type,

Fig. 2 is a cross sectional view of a membrane voltage divider known type,

Fig. 3 is a cross section of a touch activated actuator according to the invention,

Fig. 4 is an isometric view of a touch activated control element according to the invention,

Fig. 5 is a block diagram of the control circuit according to the invention,

Fig. 6 is a circuit diagram of the control circuit of FIG. 5,

Fig. 7 is a circuit diagram of a control circuit operable from several positions according to the invention.

Individual description of the exemplary embodiments

The one used in the description and in the claims The term "touch device" is intended to refer to all devices which are capable of generating a signal according to a to generate applied pressure, for example by a finger is exercised. Such a device can a capacitive touch plate, a load cell, a pressure sensor or preferably one by touch actuated membrane arrangement, which can be used as a switch or acts as a voltage divider.

Fig. 1 is a cross section of a touch-operated membrane switch of a known type. The switch consists of two conductors 1 and 3 , which are supported by flexible insulating substrates 5 and 7 , between which spacers 9 are glued. When pressure is applied to the membrane switch by a finger or the like, the substrate 5 and 7 bends and the conductors 1 and 3 come into contact. When the pressure is removed from the membrane switch, the substrate takes on its original shape and conductors 1 and 3 are separated.

Fig. 2 is a cross-sectional view of a membrane voltage divider as described in US Pat. No. 3,968,467. A conductive element 11 and a resistance element 13 are carried in the same area extent close to each other by a spacer frame 15 . A voltage V _in is applied to the resistance element 13 to produce a voltage gradient across the surface. The pressure exerted at a location along the conductive member 11 causes the member to deflect downward and come into electrical contact with a corresponding point on the surface of the resistive member 13 , thereby producing a voltage V _out , the value of which is between V _in and earth lies. When the pressure subsides, the conductivity element 11 returns to its original shape and is electrically isolated from the resistance element 13 . In the description and in the claims, the terms "conductive" and "resistance" refer to electrical terms. Thus, the essential feature of the resistance element 13 is the electrical resistance and the essential feature of the conductivity element 11 is the electrical conductivity.

Fig. 3 is a sectional view of a touch activated actuator, according to the invention. The actuator 19 actuated by touch preferably has, as shown, a membrane voltage divider of the type shown in FIG. 2. Instead, a membrane switch as shown in FIG. 1 or any other touch actuatable device could be provided in place of the voltage divider 19 . The cover plate 21 is preferably a wall-mountable cover plate, as described in US-PS 48 03 380. Instead, the lid can be part of a housing that can be hand-held and effect wireless remote control, or it can be any other cover plate. The front surface of the cover plate 21 is preferably flat and smooth; however, education can largely be determined by aesthetic considerations. The cover plate 21 is preferably formed from ABS plastic material and has a flexible surface 23 , the front surface of which is preferably flush with the rest of the front surface of the cover plate 21 . The flexible surface 23 is preferably formed from a strip of material which is between 0.2 mm and 0.5 mm thick and has grooves along the circumference in order to reduce the tension. Behind the flexible area 23 there is a pocket in which the voltage divider 19 fits. The carrier plate 25 forms a rigid support for the pocket and preferably forms a watertight seal against the shoulder 26 . A socket 27 is electrically connected to the elements 11 and 13 and cooperates with a plug 29 to electrically connect the voltage divider 19 to a conventional phase gating dimmer circuit (not shown). Pressure applied to the front of the flexible portion 23 causes the conductive element 11 to contact the resistance element 13 at a preselected point 17 along its length. A corresponding instantaneous voltage, which is selected from a continuous range, is applied to the dimmer circuit, which controls the power accordingly according to the load.

Instead, if a membrane switch is used in place of the membrane voltage divider 19 , the power after the load can be alternately turned off or set to a predetermined level according to the pressure applied to the front surface of the flexible portion 23 .

Fig. 4 is a perspective view of a touch activated actuator according to the invention. The front surface 31 of the cover plate 21 can be completely smooth or, depending on the aesthetic point of view or for reasons of expediency, have optical markings, for example 33 , 35 and 37 . These markings each show the position of the flexible area 23 or the position of the switch-off point or the lowest power level. A conventional leading edge dimmer circuit within the switch housing 38 controls the power from a voltage source after a load in accordance with the pressure applied at a preselected point of the flexible region 23 .

Optional light emitting diode arrangements 39 provide a visual indication of the power level. US Pat. No. 3,968,467 describes a circuit for exciting a light-emitting diode arrangement, the number of light-emitting diodes which are successively illuminated from one end corresponding to the voltage output of a membrane voltage divider. When the load is a light source, there is preferably a linear relationship between the number of light emitting diodes illuminated and the corresponding light level. The flexible surface 23 can optionally have a translucent surface through which the light-emitting diode arrangement 39 is visible.

Fig. 5 is a block diagram of a preferred control circuit according to the invention for controlling a conventional phase control dimmer circuit according to an instantaneous voltage from a voltage divider membrane. Pressure is initially applied to a selected point along the membrane voltage divider 41 to produce an instantaneous voltage V _m that corresponds to a desired power level. The voltage sensor 43 detects this voltage and switches on the clock generator 45 . The clock 45 provides periodic control pulses to the wiper movement control pin of IC 47 , preferably an electronic adjustable voltage divider (EAVD), which increasingly moves the wiper 48 along the resistance element 49 . The wiper 48 divides a voltage across the resistance element 49 according to its location and supplies a corresponding continuous voltage V _c . A comparator 50 compares the instantaneous voltage V _m to the continuous voltage V _c and provides an output to the forward / backward pin of the EAVD 47 which, on the next actuating pulse, causes the wiper to move upward if V _{m is} greater than V _c , and moves down if the opposite is the case. In this way, V _c quickly approaches V _m . When the pressure on the voltage divider 41 decreases, the voltage is removed from the voltage sensor 43 and the clock generator 45 is switched off. Clock 45 stops providing actuating pulses to the slider motion control pin of EAVD 47 and slider 48 stops moving. V _c is applied to the dimmer circuit 51 , which determines the power that is applied to the load. The dimmer circuit 51 may be a conventional leading edge control or any other suitable power control circuit. as described above, wiper 48 moves up or down along resistance element 49 to provide a changing voltage V _c . The same function is preferably achieved by selectively controlling a series of electronic switches or the like.

FIG. 6 is a circuit diagram of the control circuit according to FIG. 5. The resistance element R 1 of the membrane voltage divider 41 is connected in series with the resistors R 2 and R 3 . A DC voltage of preferably 5 V is applied to the series circuit, whereby a predetermined voltage gradient is formed along the surface of the resistance element R 1 . The resistors R 2 and R 3 are selected such that the high and the low end values of the voltage are limited to R1.

The circuit operates as follows: The pressure impressed on the membrane voltage divider 41 causes electrical contact at a location along the resistance element R 1 to selectively deliver an instantaneous voltage V _m which can be selected from a continuous range of voltages. The current flow through the resistor R 4 and the base-emitter connection of the transistor T 1 turns it on. The collector voltage of the transistor T 1 drops, so that a current can flow through the resistor R 5 , so that the inputs of the NAND gate N 1 switched by a Schmidt trigger become logic zero. The NAND gate N 1 provides a logic one value after one input of the NAND gate N 2 and the other input is provided by an oscillator circuit which includes the NAND gates N 3 and N 4 , the resistor R 6 and the capacitor C 1 includes. The resistor R 6 and the capacitor C 1 are preferably selected so that an oscillation frequency of approximately 1000 Hz is achieved. The output of NAND gate N 2 inversely follows the output of NAND gate N 4 , and an oscillating input is provided to wiper motion control pin 1 of EAVD IC1, and this is preferably a digitally controlled potentiometer of the type Xicor E ² POT model no. X9103P (see for example Xicor Data Book, Section 4).

The E ² POT has a resistor arrangement R 7 which has 99 resistor elements which are located between pins 3 and 6 . Tap points are accessible between the elements and at each end, which can be electrically connected to the grinder pin 5 . An oscillating input after the wiper movement control pin 1 has the effect of moving the wiper pin 5 up or down along the resistor arrangement R 7 according to a logic-on or a logic-zero input signal at the up / down pin 2 . A continuous DC voltage, which is applied to the resistor arrangement R 7 , is divided between the resistance elements on both sides of the grinder pin 5 , and a corresponding continuous voltage output V _{c is} generated, which can be selected from a substantially continuous range of voltages. The resistors R 8 and R 9 determine the voltage range that can be selected along the resistor arrangement R 7 . The voltage range along R 7 is preferably, but not necessarily, equal to the voltage range along R 1 .

The comparator IC2 receives an instantaneous voltage V _m and a continuous voltage V _c and provides a digital output with a single bit after the up / down pin 2 corresponding to the difference. Preferably IC2 is an output device with an open collector, R 10 is the pull-up resistor. The characteristics of the circuit are such that the continuous voltage V _c converges quickly (ie in less than 100 ms) after the instantaneous voltage V _m . Instead, V _c may converge towards a value that is proportional to V _m or otherwise functionally dependent on it. The resistor R 11 and the capacitor C 2 filter the output voltage V _{c of} the pin 5 ; in the same way, resistor R 12 and capacitor C 3 filter the output voltage V _{m of} the voltage divider 41 in order to avoid an unstable operation of the comparator IC2.

When the pressure from the voltage divider 41 drops, V _m becomes zero. The resistor R 13 pulls the base of the transistor T 1 to ground and switches it off. Diode D 1 prevents the voltage stored in capacitor C 3 from turning transistor T 1 on again. Resistor R 14 forms a discharge path for capacitor C 3 to ground. The collector voltage of transistor T 1 switches the inputs of NAND gate N 1 to logic one. The output of NAND gate N 1 , which is supplied to an input of NAND gate N 2 , is switched to logic zero, so that the output of NAND gate N 2 is kept at logic one, regardless of its second input. A continuous logic one value is supplied to the wiper motion control pin 1 , thereby preventing any change in the wiper position, so that V _{c is kept} at a constant value. V _c is supplied to a conventional phase gating dimmer circuit, as described, for example, in US Pat. No. 4,575,660, whereby the power is controlled accordingly after the load.

The EAVD IC1 preferably has a non-volatile Memory in which the grinder positions are stored can be required without any performance would. In this case, after a power failure the power after the load brought to a value which is equal to the value which is before Power failure was set. Instead, a battery powered RAM or any other device be used that do not have a continuous performance of the source and require the power level information to save. The grinder position can be after everyone  Setting can be saved or preferably only then when a voltage interruption by a Voltage differentiation circuit was found. A similar type of power recovery circuit can be used for any type of touch operated Control systems are used.

Fig. 7 is a circuit diagram of a control circuit to be actuated from several positions according to the invention. In addition to the circuit of FIG. 6, additional voltage dividers 41 'and 41 ''which can be actuated by touch are provided in order to be able to adjust the power according to the load from various points. The circuits operate essentially the same as the circuit of FIG. 6, with the difference that each voltage divider supplies an instantaneous voltage V _m , the last of which determines the magnitude of the wiper voltage V _c . By selectively touching any of the touch-sensitive voltage dividers, the power level is essentially instantaneously adjusted in accordance with the instantaneous voltage thus generated. Each voltage divider preferably produces an equivalent range of instantaneous voltages, but this is not a necessary condition. Each voltage divider is preferably arranged behind a cover plate, as can be seen in FIGS. 3 and 4, and it can be electrically connected to the control circuit, as described above. Instead, one or more voltage dividers can be accommodated in wireless, hand-held remote control devices, such as infrared control devices. LED indicators at any point can optionally provide a visual display of the power level.

Certain changes can be made without the Deviate within the scope of the invention.

Claims (11)

1. System for controlling the power from a voltage source to a load, which in combination has the following features:

• a) a cover plate that has a front surface that is flexible in a certain area,
• b) behind the flexible area touchable means are arranged to provide a signal according to the pressure exerted on the flexible area, and
• c) a circuit is provided to determine the power delivered by the voltage source after the load according to the signal.

2. Control system according to claim 1, characterized characterized that the flexible Area from a thin web made of one material exists, the front surface essentially with the remaining part of the front surface of the cover plate is aligned while the rear surface of the rear surface of the cover plate jumps back. 3. Control system according to claim 1, characterized  characterized in that by Touch actuatable means from a first exist electrically conductive element, which is operable to a voltage gradient along to produce its surface, and that a second electrically conductive element adjacent to this and essentially with the same surface area as the electrically conductive first element is provided is that of the latter through a small gap is separated. 4. Control system according to claim 1, characterized characterized in that by Touch actuatable means behind the flexible Area by an essentially rigid plate are supported on the back of the Cover plate is arranged. 5. Control system according to claim 1, characterized characterized that further visible means are provided to the Power level display that delivered the load becomes. 6. System for controlling the power from a voltage source to a load, which has the following features in combination:

• a) a voltage divider which can be actuated by touch and which supplies an instantaneous voltage which can be selected from a range of voltages,
• b) an electronically adjustable voltage divider to deliver a continuous voltage that can be selected from a range of voltages,
• c) means for comparing the instantaneous voltage with the continuous voltage and for adjusting the electronically adjustable voltage divider so that a predetermined relationship between the voltages is obtained, and
• d) a circuit for determining the power supplied by the voltage source after the load according to the continuous voltage.

7. System for controlling the power from a voltage source after a load from several places, which in combination has the following features:

• a) a plurality of means operable by touch that are attachable at multiple locations and operable to provide an instantaneous voltage that is selectable from a range of voltages,
• b) means to store information corresponding to the instantaneous voltage and to provide a corresponding continuous voltage,
• c) a circuit which determines the power from the voltage source after the load according to the continuous voltage.

8. Control system according to claim 7, characterized characterized that the memory is out an electronically adjustable voltage divider consists. 9. Control system according to claim 7, characterized characterized that optical Display means for the power level provided are fed to the load. 10. System for controlling the power from a voltage source to a load, which in combination has the following features:

• a) a touch-operated device that generates a signal according to an applied pressure,
• b) means that do not require power and store information representative of the signal, and
• c) a circuit that determines the power delivered by the voltage source after the load according to the signal.

11. Control system according to claim 10, characterized characterized that the circuit  has a leading edge control to the Adjust power by the voltage source after the load is delivered.