DE3343270A1 - Switchable single-phase AC voltage plug socket - Google Patents

Abstract

A switchable single-phase AC voltage plug socket is described, having a conductor and neutral conductor plug socket arranged in a plug socket base, it being possible to connect the mains voltage to the conductor plug socket via a switching contact. However, according to the invention, the mains voltage is applied only when an electronic control unit has confirmed that no unauthorised human operation has taken place on the plug socket, but that an electrical load has been correctly connected.

Description

Switchable single-phase alternating voltage socket

The invention relates to a switchable single-phase AC voltage socket according to the preamble of claim 1.

With the sockets generally used in installation technology in walls, the sockets provided in the sockets are usually permanent put on tension. There is therefore the risk that such sockets in particular Children can get into these sockets with wires or nails, whereby they may be exposed to considerable dangers under certain circumstances.

There are already a number of sockets to avoid these dangers created. So many sockets are known where they are live standing sockets through provided with holes for inserting the plug pins Protective parts are covered when the sockets are not in use. Should the socket then be used the plug is inserted into the holes in the protective parts and with the protective parts twisted until the holes above the previously through the Protective parts come to lie covered sockets and then the plug pins can be plugged into the latter.

These known sockets have the disadvantage that their susceptibility to damage is relatively large and thereby or by forgetting to attach the Protective part lose their protective function.

There are also known sockets, in which in the sockets an insulating button is provided, which when inserting the connector pins in the direction the socket axis is movable and thereby on a standing under spring action Switching element acts so that when the plug is inserted, the switching element touches the sockets puts on tension, while when the plug is pulled out due to the spring action the Switching element is fed back so that the sockets are no longer live.

These sockets can also be inserted in a simple manner a foreign body put the socket in an unintentional manner on voltage, so that So here too no adequate security is guaranteed.

Furthermore, a socket is arranged in a socket base Sockets and with one centrally in the socket base in the direction of the socket axis movably guided slide-like organ made of insulating material known (DE-PS 1 115 335), which occurs when inserting or removing a plug from or into the Sockets is displaceable on a displacement path and an electrical one Connection between the connection terminals attached to the socket base and the sockets only produces when the plug is inserted, but interrupts when the plug is pulled out and wherein a lock for the organ is provided, which only when inserted Plug allows the organ to be moved. This version also has the disadvantage that the lock can be outwitted and you then live with the live Sockets can come into contact.

What all known solutions have in common is that they use mechanical protective parts is to be prevented that a person with the live sockets in Contact can come. This protective function can also be achieved with proper handling however, these protective measures do not offer any in the event of improper handling Security more, as these protective measures, for example, of children, albeit unintentionally, can be outwitted.

The object of the invention is to design a generic socket in such a way that that the dangerous mains voltage is only then applied to their sockets, if it was "recognized" by the socket that an electrical consumer is working properly is connected, but no mains voltage is applied when from the socket an inadmissible interference by a person is recognized.

According to the invention, this object is achieved with the characterizing features of claim 1 solved.

The invention is based on the knowledge gained in experiments from the fact that the human electrical resistance is greater than or equal to the internal electrical resistance of most electrical consumers that can be connected to sockets.

The human electrical resistance is greater than or equal to 3,200 Ohm, while the electrical resistance of a consumer with a power of 2000 watts 25 ohms and a consumer with a power of 15 watts 3,230 ohms amounts to. Electrical consumers of low power therefore have roughly the same effect Internal resistance like the human body in the most unfavorable I.lll. limit one now, for example, the connection value of the socket to a minimum consumer power from 17 watts, corresponding to 2,850 ohms, can be achieved by the Resistance value as a criterion for distinguishing recognition - whether it is a People or an electrical consumer - be used.

According to the invention, this distinction is recognized by an electronic one Control unit carried out, the load detection assembly of which between the conductor and neutral conductor socket or only the resistor located on the conductor socket recorded. For this purpose, there is a harmless one at the sockets - also none The smallest measuring voltage causing the startle reaction, which is from a supply voltage is derived, which at the same time supplies the entire electronic control unit. The load detection module is followed by a Schmitt trigger and a driver and relay assembly, the relay of which when there is an output signal from the load detection assembly a switching contact is actuated, which supplies the mains voltage to the conductor socket applies.

The relay and its switch contact be held in an active position.

An embodiment of the invention is shown in the drawing and is described in more detail below.

A switchable single-phase alternating voltage marked with a total of 1 -Socket has a conductor socket in its socket base, not shown in detail 2 and a neutral citer socket 3. Preferably there is one in the socket electronic control unit 4 integrated, which is built on modules and the following Assemblies includes: a load detection assembly 5, a Schmitt trigger assembly 6 with an input voltage divider 6.1, a driver and relay assembly 7, a self-holding assembly 8 and a voltage supply assembly 9. This voltage supply assembly 9 supplies the control unit 4 on the one hand with energy, for example 12 V direct current, and it is on the other hand via a Voltage divider 5.1, 5.2 at the input of the load identification module 5 a very small measuring voltage applied to the sockets 2, 3, including the conductor socket 2 via a switching contact 7.3.1 is connected to the input of the load detection module 5.

If a consumer resistor 11 is now connected to the sockets 2, 3, For example, an electrical device with a resistance of less than or equal to 3,200 ohms, so the total resistance becomes through its parallel connection to the voltage divider resistor 5.2 and thus the voltage drop across both resistors is also smaller. The accompanying Lowering the base-emitter voltage - for example to less than 0.7 volts - at the transistor 5.3 of the load detection assembly 5, whose operating point by means of a variable resistance 5.1.1 of the voltage divider 5.1 is adjustable, has result that the transistor 5.3 blocks.

The voltage divider 6.1 of the Schmitt trigger assembly 6 is then applied but a positive voltage, being the voltage value that is across the resistor 6.2 reaches the base of the transistor 6.3, can be set precisely. this is with regard to a tolerance reduction with regard to the consumer resistance to be detected 11 beneficial.

Due to the voltage reaching the base of transistor 6.3 controls this through and as a result of the direct coupling with the transistor 6.4 this blocked. There is now a high positive at the collector of transistor 6.4 Tension, which via the diode 7.1 of the driver and relay assembly 7 to the base of their Transistor 7.2 arrives, whereupon it becomes conductive and a relay 7.3 is activated.

The relay 7.3 now switches the switching contact 7.3.1 and possibly another contact 7.3.2, so that the socket 2 is directly connected to the mains voltage 10 is applied, but is separated from the smallest measuring voltage.

In order to prevent that after switching over the switch contact 7.3.1 the relay 7.3 does not drop out again, the following measures are provided. In the Neutral conductors 12 are within the self-holding assembly 8 between its mains connection side and the neutral conductor socket 3 has two anti-parallel connected diodes 8.1 and 8.2 built in. A capacitor 8.3 is used as soon as the electronic control unit 4 is supplied with voltage, charged and a transistor 8.4 assigned to it controls then through. There is then only a very small positive voltage on its collector, which is not sufficient to make the diode 7.4 of the driver and relay assembly 7 conductive to be let. There is therefore no positive voltage at the base of transistor 7.2 on and he does not steer through.

But has now - as described - switched the switch contact 7.3.1 and the conductor socket 2 is applied to the mains voltage 10, so flows due the connected consumer resistor 11 via the diodes 8.1 and 8.2 a current, which has the consequence that a voltage drop occurs at these, for example from 0.7 volts. The voltage drop of the negative half-wave discharges the capacitor 8.3 and as a result there is no longer any positive voltage at the base of transistor 8.4 so that it locks. On the other hand, there is now one at the collector of transistor 8.4 positive voltage, which the diode 7.4 overcomes and and thus also applied to the transistor 7.2, so that it remains conductive and the relay 7.3 still activated. The mains voltage is still present at socket 2 10 at. To prevent the relay 7.3 from fluttering during the switchover process, another capacitor 6.5 is connected to the base of transistor 6.3, which, due to its charge, causes a dropout delay during switching.

If the consumer resistance 11 is now derived from the sockets 2, 3 unplugged again, the capacitor 8.3 charges up again and the transistor 8.4 becomes conductive. There is now only a very small positive on his collector Voltage, which in turn is no longer sufficient to overcome the diode 7.4 and to control the transistor 7.2. The result is that the relay 7.3 drops out, the Switching contact 7.3.1 switches over and the non-hazardous to socket 2 again Lowest voltage applied.

On the other hand, it is connected to sockets 2, 3 or only to the socket 2 a resistance greater than 3,200 ohms is applied, for example by a child who would like to examine the socket with a nail, it causes its parallel connection to the resistor 5.2 a voltage drop, which is not enough, however, to the Lock transistor 5.3. The transistor 5.3 thus continues to conduct and as a result there is also no positive voltage applied to its collector, which is necessary for activation of the relay 7.3 would be required. The mains voltage remains switched off and protection at the sockets is guaranteed.

The switchable socket according to the invention has a wide field of application given. So it is to protect people in the household, in workshops, in classrooms, in laboratories etc. ideally suited. Even in selected areas of application, for example on construction sites, the socket is very suitable because it is through here a targeted setting of the threshold value, the switch-on threshold can be lowered could, since very low-resistance loads are usually operated there.

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Claims (10)

Claims Switchable single-phase alternating voltage. Socket in one Socket base arranged conductor L) and neutral conductor (N) socket, whereby The mains voltage can be applied to the L socket via a closable switch contact is, characterized in that the switching contact (7.3.1) of an activatable Component (7.3) of an electronic control unit (4) can be actuated, the component (7.3) with one lying below a threshold value, which is a harmless one L-socket (2) and the N-socket (3) connected to the lowest measuring voltage Consumer resistor (11) is activated and the switching contact (7.3.1) closes, on the other hand, if it is above the threshold value, at least to the L socket (2) connected resistor remains inactive. 2. Switchable socket according to claim 1, characterized in that the component (7.3) becomes inactive again when the consumer resistor (11) is removed and the switching contact (7.3.1) opens. 3. Switchable socket according to claim 1, characterized in that the component (7.3) is a relay, which is designed as a changeover contact Has switching contact (7.3.1). 4. Switchable socket according to claim 1 and 3, characterized in that that the switching contact (7.3.1) between the mains voltage (10) and the smallest measuring voltage switches. 5. Switchable socket according to claim 1, d a d u r c h g e k e n n z e.i c h n e t that the electronic control unit (4) is integrated into the socket (1) is. 6. Switchable socket according to claim 1 and 5, characterized in that that the electronic control unit (4) consists of assemblies, in particular one Self-holding assembly (8), a load detection assembly (5), a Schmitt trigger assembly (6) with an input voltage divider (6.1), a driver and relay assembly (7) and a power supply module (9). 7. Switchable socket according to claim 6, characterized in that the modules (5 to 9) are interconnected in the order mentioned and also an output of the self-holding assembly (8) with an input of the driver and relay assembly (7) is connected. 8. Switchable socket according to claim 1, characterized in that that the minimum measuring voltage is <3 V- (direct voltage). 9. Switchable socket according to claim 1, characterized in that that the threshold value for activating the component 7.3) is adjustable. 10. Switchable socket according to claim 1 and 9, characterized in that that the threshold value is preferably less than or equal to 3,200 ohms.