EP1867066A1

EP1867066A1 - Electrical appliance, plug-on part and method for switching a plug socket

Info

Publication number: EP1867066A1
Application number: EP06830719A
Authority: EP
Inventors: Roland Huttner
Original assignee: Siemens AG
Current assignee: Siemens AG
Priority date: 2006-03-29
Filing date: 2006-12-19
Publication date: 2007-12-19
Also published as: CN101194436A; BRPI0610939A2; DE102006014621A1; WO2007112793A1

Abstract

According to the invention, a transmitter is provided in or on an electrical appliance and can emit signals, by means of capacitive injection in the electrical near field, via plug pins (20) of a plug (18) to a plug socket (22) or lines (26, 44) connected downstream from the plug socket (22). In particular, the signals are emitted when the plug socket is switched off. The transmitter is independent of the current through the plug socket, and is battery-powered. The use of capacitive signal injection avoids interference effects such as those when using radio controllers for plug sockets. In addition, the fitting of the transmitter in or to the electrical appliance means that there is no need to use an additional remote controller.

Description

description

Electrical device, plug-on part and method for switching a socket

The invention relates to an electrical device to be powered via a socket. For this purpose, the electrical ^¬ cal device comprises a connecting cable with a plug at the end of the connecting line, which has (at least) two plug-in pins.

The invention also relates to a plug-on part for attachment to a connecting lead of an electrical device.

Furthermore, the invention provides a method for switching a socket.

Switchable sockets are known as such from the prior Tech ^¬ nik. In the simplest versions, a socket is switched off and on with the aid of a manual switch. This is particularly useful for outdoor sockets, which should not ^{always be} energized.

It is also known to turn off the electrical sockets via a bus system or even turn on.

Finally, it is also known to use a radio system: A handset radio signals are sent to an actuator that switches the socket. The actuator can be located directly at the socket or can also be located in a distribution box or a so-called sub-distribution, where several sockets are switched at once. An ^alternative to radio is the use of infrared.

Both with radio and with infrared the range is ^limited . Infrared signals are shielded by walls or objects. If the actuator is to be located in a distribution box, this means that the signals are in poor quality. arrive at the actuator. In this regard, there are also problems with radio, because metal structures in the walls can shield radio. In particular distribution cabinets have so sheet metal housing.

It is an object of the invention to show a simple way ^¬ how sockets can be switched.

The object is achieved by an electrical device according to claim 1, by a plug-on part according to claim 11 and a method according to claim 12.

The electrical device according to the invention has a transmitter which is designed, when the transmitter is plugged into a switchable socket, when the socket is switched off,

Signals at least via a plug pin to the socket from ^{¬ give} to cause a switching operation in one of the socket o- in a socket electrically connected to the distributor actuator with which the socket is turned on.

The invention has the advantage that the transmitter belongs to the electrical device. By integrating the transmitter into the electrical device, in contrast to the use of radio or infrared, no separate operating device must be used. The fact that the signals are delivered via the plug pin to the socket, it can not interfere with the wireless or infrared path, but those lines that are intended to conduct electricity, are also useful for the transmission of switching signals used.

In a preferred embodiment, the transmitter is battery powered. The battery allows the generation of Signa ^¬ le even if the socket is turned off, ie, if no power can be supplied through the socket.

In a preferred embodiment, a transmitter is used, as it is known from WO2004 / 036784 Al. Such a Transmitter capacitively couples its signals into electrical lines via a near field. The use of the near field has the consequence that no electrical waves are emitted. At the same time, however, there is no need for an electrically conductive connection between the transmitter and the electrical conductor into which the signals are coupled. Thus, the electrical transmitter does not have to be integrated into a circuit in the electrical device, so that it can not interfere with the Be ^{¬ operation of} the electrical device. As long as the transmitter does not emit signals, it is independent of the electrical conductor, and power can be conducted to the electrical appliance via the electrical conductor.

In a preferred embodiment, the transmitter capacitively couples the signals via a near field in the connecting line. The transmitter can then be arranged on the device-side end of the connecting line, in particular in a housing of the electrical device to which the connecting line leads, be located. The transmitter can also be plugged onto the connection cable. Like experiences with in the

WO2004 / 036784 Al described technology, an electric near field can be strong enough to overcome the insulation ^¬ tion of a connecting line of an electrical device in the interior of which are then conductive elements. The transmitter can thus capacitively via the isolation of a near field signals in the Anschlußlei ^¬ lines, in particular in the conductive elements there, couple.

According to the above-mentioned aspect of the invention, the invention therefore also includes a plug-on part for plugging onto a connecting lead of an electrical device with a battery-powered transmitter which is capable of coupling signals into a conductive element of the connecting lead via a (capacitive) electric near field ,

The sender does not have to inject line signals into the connection ^¬. Instead, the transmitter can receive the signals capacitively coupled via a near field in the at least one plug-in pin. It is therefore not necessary for the signals to pass through the connecting cable. The transmitter is then preferably arranged directly in the plug itself. The plug has a plug body from which protrude the two plug-in pin, wherein the transmitter is arranged in the interior of the plug body and optionally switched on and off via a switch on the outside of the plug body.

Instead of such a switch, a contact pin may be provided which turns on the transmitter in the plug with plugged plug. As a result, the battery of the transmitter is spared, because only when plugged in the transmitter sends. In this case, the transmitter can be designed so that it transmits directly after insertion and then switches itself off automatically. In the plug, a monitoring ^{scarf ¬} tion can be provided, through which a constant check of the insertion takes place, wherein the contact pin can play the role of a switch here. When unplugging, which takes place in the time frame of tenths of a second, then a delivery of signals by the transmitter to turn off the socket can be done, which then "just" on the pulled out in the state of he ^¬ pulled out two pin to the actuator be designed to switch as early as possible, that is, when the plug is pulled out just a little so that the contact delivery can still be done quickly enough This embodiment automates the switching off the power outlet, otherwise it would be necessary to induce the transmitter, even at If a user of the electrical device would then have to learn to trigger a transmission signal at the same time as unplugging or switching off the electrical device, for example by pressing it a push-button.

In a preferred embodiment, the signals include (or "use") device-specific coding, wherein the signals can either be self-coded or transmit the code as a corresponding signal sequence, for example in the form of a code number. This preferred embodiment makes it possible to distinguish different electrical devices from each other. Also the sockets can have a code, so that certain electrical devices ^¬ be voted outlets are associated with or specific groups of electrical equipment associated with certain groups of sockets are.

Using the code in the signals will then prevent the "wrong" electrical device from mistakenly turning on the power and pulling power.

In a further preferred embodiment, the transmitter is switched on simultaneously with the electrical device. This has the consequence that the socket is only switched on ^¬ tet when the electrical device actually requires power ^¬ tigt.

The preferred embodiment of the invention also makes it possible to provide a method according to claim 12.

The inventive method comprises providing egg nes electrical apparatus according to the last-mentioned Favor ^¬ th embodiment and the provision of a socket with a socket connector, the socket being ^¬ tor switchable via a Pc, and wherein in the off state to the actuator via the socket connector signals can be fed, which cause him to switch. It is then turned on the electrical device and the plug plugged into the socket. The order of the two steps mentioned here is irrelevant. Both partial steps together made it ^¬ union that the actuator receives a signal from the transmitter of the see electrical device and thus the socket Power On ^¬ tet. The method according to the invention also includes targeted switching off of the socket. For this purpose, it is constantly monitored whether a switched-on electrical device via the socket connected. The monitoring is carried out by means of a current or voltage criterion by the actuator zugeord ^¬ designated monitoring unit, which control signals can be sent to the actuator. The voltage criterion may include that when the electrical equipment is connected, the voltage at the socket falls (slightly) from the rated voltage. The current criterion may include pulling a non-zero current. Both current and voltage criteria do not have to include the acquisition of absolute values of the corresponding magnitude, but it is sufficient to be able to distinguish between the two states whether a switched on electrical device is connected or not.

In the subsequent step, switching off the electrical device and / or unplugging the electrical device, ie pulling out the plug from the socket outlet. Both steps have the same effect that no turned stale ^¬ tetes electrical appliance is more connected to the outlet. The following step is then possible, namely the switching off of the socket by the actuator on the basis of a control signal of the monitoring unit generated in response to step f).

Hereinafter, preferred embodiments of the invention will be described with reference to the drawings, in which

1 is a basic diagram of a first embodiment of the

Invention is illustrated, FIG 2 according ei illustrating a plug for an electrical appliance ^¬ ner second embodiment of the invention,

3 illustrates a connecting line with a plug for an electrical device according to a third embodiment of the invention.

A shown in FIG 1, denoted overall by 10 elec ^¬ cal device (electrical load) 10 includes a housing 12, in which typically a motor 14 is located. The engine can be of any type. Instead of the motor 14, another electrical consumption unit may be provided, for example heating wires, when the electrical appliance 10 is a heater.

From the electrical device 10 leads a connection line 16 away to a plug 18. The plug 18 has two Steckzap ^¬ fen 20.

The plug 18 is plugged into a socket 22. The ei ^¬ genliche socket socket comprises two socket holes 24, de ^¬ ren shape complementary to the two plug-in pin 20 is. In the socket receptacle holes 24, the electrical con- tacting of plug pin 20 on the one hand and electrical system of the house on the other hand. From the socket holes 24 lines 26 are routed via switch actuators 28 to the power grid 29.

The present invention is concerned with how the switch actuators 28 can be made to close from the open state shown.

The switch actuators 28 are housed in a distribution box 30 ("subdivision") in which each one is also housed

Switch actuator 28 associated receiver 32 are located. The receivers 32 are now not controlled for example by radio, but via signals that arrive via the lines 26. When the socket 20 is switched off, the signals are coupled in via at least one of the two plug-in pins 20. The signals are generated by a transmitter 34 in the device housing 12, which is powered by a battery (in particular a battery) 36. The transmitter 34 now operates according to a principle which is described in WO2004 / 036784 A1: The transmitter 34 has an (asymmetrical) capacity, for example a single capacitive plate. He is a near field from that time ^¬ is Lich changeable without the energy sufficient laundri ^¬ re radiate electromagnetic waves. By capacitive Coupling time-varying signals are coupled into conductive elements 38, ie in the actual conductor 38 in the connecting line 16. In the present case, it is provided that the transmitter 34 is turned on via a button, the same time a switch 42 for closing the circuit in the electrical device 10th actuated. The electrical device 10 is thus turned on simultaneously to the transmitter, but it does not work immediately because of the lack of power. Rather, the transmitter 34 sends by means of the capacitive coupling into the conductive elements 38 signals via the plug pins 20 in the lines 26 to the receivers 32. The receiver 32 are not connected to one end 44 of the lines 26, but also the receiving end of WO2004 / 036784 Al known principle used. In other words, the conductive element 44 is capacitively coupled to the receiver 32, wherein the near field is used and no far field, so that it does not come to the emission of electromagnetic ^¬ tical waves.

On the device side, there are two other variants, which are explained below with reference to FIG 2 and FIG 3, wherein the Emp ^¬ start page, which is shown in FIG 1, each unchanged. While Figure 1 of the Sen ^¬ of 34 is arranged in the device 10 according to the embodiment, carried out te at a Varian which is illustrated in FIG 2, an accommodation ei ^¬ nes transmitter 34 ', which by a battery 36' is stored in a plug 18 '. Although it would also be possible here, the transmitter 34 'via a button on the type of button 40 on and off. However, this is preferably done automatically by the use of a contact pin 46 which is arranged between the two plug-in pin 20 of the plug 18 '. Upon insertion of the plug 18 'in a socket 22, the contact pin 46 moves against the force of a spring 48 to a switch element 50 and closes a switch 52. Thus, the transmitter 34' immediately after the insertion of the

Plug 18 'into a socket 22 signals via the Steckzap ^¬ fen 20 and causes when the socket 22 is turned off that it is turned on by the actuators 28. In a refinement, not shown in FIG. 2, a monitoring circuit is arranged inside the transmitter 34 ', which causes the transmitter 34' to emit signals again immediately after opening the switch 52, this time to switch off the socket 22. The spring 48 causes that the plug-in pin 20 must first be pulled out a small distance, so that the contact pin 46 is no longer acting on the switch element 50, so that the switch 52 opens when pulling relatively early. If the transmitter 34 is sufficiently fast, an off signal for the socket can still during the Herauszie ^¬ hens be issued via the plug pin 20 fast.

In a further alternative, which will be ^{¬ written} with reference to FIG 3, a conventional electrical device 10 'with connecting cable 16 and plug 18 is only retrofitted to cause it is provided with a transmitter according to the invention. For this purpose, a plug-in part 54 is plugged or otherwise attached to the connecting line 16, in which a transmitter 34 '', which is powered by a battery 36 '', is arranged. The transmitter can be switched on and off via a button 40 '. The embodiment according to FIG. 3 with the plug-on part 54 makes use of the fact that the principle used (from WO2004 / 036784 A1) uses a capacitive coupling via the near field. The near field usually extends over a range of 1.50 m and can in particular penetrate insulating layers. Thus, the near field can also penetrate an outer insulation 56 of the connection line 16 and capacitively couple signals into the conductive elements 38 of the connection line 16. Thus, signals are again sent to the two plug-in pins 20 and finally into the socket into the lines 26 and thus to the receivers 32, so that the switch actuators 28 are actuated.

The embodiments according to FIGS. 1 to 3 have in common that the respective transmitter 34, 34 'or 34''is battery-powered. is fed so that the transmitter can be active without a voltage has to be pulled over the socket. At the same time, however, the transmitter 34, 34 ', 34 "still acts directly on the non-current-carrying socket and capacitively couples signals into conducting elements which are conducted via the plug-in pins 20 to the lines and thus ultimately to the receivers 32. All three embodiments make use of the transceiver arrangement according to WO2004 / 036784 A1.

It is common to FIGS. 1 to 3 that the transmitter is coupled to or located in the electrical device. Unlike the use of radio controls for sockets, where independent HMI devices are used, the sender must be attached to certain electrical consumers. This connection of the transmitter to the electrical device can prevent other elec ^¬ cal devices can draw power from the outlet. This is useful, for example, in the area of computer networks. There are sockets specially designed for use by computer. Typically, a connection of other devices will be prevented by a entspre ^¬ sponding marking or coloring is used in these sockets. By Verwen ^¬ tion of the embodiments according to Figures 1 to 3 in a computer as an electrical device 10 or 10 'would be ensured that the corresponding electrical outlet is turned on only by computer, and not by other consumers ^¬ cher as coffee and vacuum cleaner to be that is not connected to the specific outlet because of to ho ^¬ ^¬ hen electricity consumption included.

Claims

claims

1. Electrical device (10, 10 ') with a connecting line (16) and a plug (18) having at least two plug-in pins (20), characterized by a transmitter (34, 34', 34 '') designed to is, in a switchable plug ^¬ socket (22) plugged plug (18, 18 '), when the socket (22) is turned off to deliver signals via at least one plug ^¬ pin (20) to the socket to a switching operation in an actuator (28) located at the socket (22) or inside a distributor (30) electrically connected to the socket, with which the socket (22) is switched on.

2. Electrical device according to claim 1, characterized in that the transmitter (34, 34 ', 34' ') is battery-powered (36, 36', 36 '') or battery-powered.

3. Electrical device according to claim 1 or 2, characterized in that the transmitter (34, 34 '') capacitively couples the signals via a near field in the connecting line (16).

4. Electrical device (10) according to claim 3, characterized in that the transmitter (34) is arranged at the device-side end of the connecting line (16).

5. Electrical device according to claim 3, characterized in that the transmitter (34 '') is applied directly or in a Aufsteckteil (54) on the connecting line (16).

6. Electrical device according to claim 1 or 2, characterized the transmitter (34 ') is arranged in the plug (18') and capacitively couples the signals via a near field into the at least one plug-in pin (20).

7. Electrical device according to claim 6, characterized in that a contact pin (46) in the plug (18 ') turns on when ^¬ plugged plug the transmitter.

8. Electrical device according to claim 7, characterized in that when plugged in connector (18 ') by a monitoring circuit ^¬ a constant check of the insertion state he follows ^¬ , and that the monitoring circuit when unplugging the delivery of signals for switching off the socket by the transmitter (34 ') causes.

9. Electrical device according to one of the preceding Ansprü ^¬ che, characterized in that the signals use a device-specific coding.

10. Electrical device according to one of the preceding Ansprü ^¬ che, characterized in that the transmitter (34) simultaneously with the electrical device (10) is turned on (40).

11. Aufsteckteil (54) for attachment to a connection line (16) of an electrical device (10 '), with a batte ^¬ riegespeisten (36'') transmitter (34''), which is capable of an electrical Near field signals into a conductive element

(38) to couple the connecting line (16).

12. A method for switching a socket (22) comprising the steps of: a) providing an electrical device (10) according to claim 10, b) providing a socket with a socket, wherein the socket via an actuator (28) is switchable, and wherein in the off state to the actuator via the outlet socket signals are fed, causing him to switch, c) switching on the electrical device ( 10) and inserting the plug (18) into the socket (22), d) receiving a signal from the transmitter (34) of the electrical appliance (10) through the actuator (32, 28) turning on the socket, e) constantly monitoring whether a switched electrical ^¬ sches device is connected via the socket ver ^¬ means of a current or voltage criterion by ei ^¬ ne associated with the actuator monitoring unit, f) switching off the electrical device (10) or unplugging the electrical device (10), g ) Turn off the socket (22) by the actuator (28) due to a generated in response to step f) control signal of the monitoring unit.