DE102021108607A1 - SYSTEM FOR DETACHABLE CONNECTION OF ELECTRIC CONDUCTORS - Google Patents

Abstract

A system for the detachable connection of electrical conductors is shown. The system includes a first device in which a first and a second electrical conductor are arranged, a second device in which a third and a fourth electrical conductor are arranged, a sensor designed to detect a current flow between the first electrical conductor and the third electrical conductor, and a device which is activated when an actuating element attached to the first device is actuated and the sensed current flow is above a first threshold value and/or is deactivated when the actuating element attached to the first device is actuated and the sensed Current flow is below a second threshold.

Description

AREA

The present invention relates to a system for detachably connecting electrical conductors. In particular, the present invention relates to a system for the detachable connection of electrical conductors with a first device and a second device, which are designed as a plug or socket or as a socket or plug.

BACKGROUND

If electrical conductors are disconnected under load, an arc can form which can cause severe wear and tear on the electrical conductors and/or pose a danger to people or other components.

SUMMARY

An inventive system for the detachable connection of electrical conductors comprises a first device in which a first and a second electrical conductor are arranged, a second device in which a third and a fourth electrical conductor are arranged, a sensor configured to detect a current flow between the first electrical conductor and the third electrical conductor, and means which are activated when an actuator attached to the first device is actuated and the sensed current flow is above a first threshold and/or deactivated when the actuator attached to the first device Actuating element is actuated and the detected current flow is below a second threshold value.

In this context, the term "electrical conductor" as used in the context of the present description and the claims, in particular means a component made of a metal (e.g. aluminum, copper or iron) or a metal alloy (which, for example, aluminum, copper or has iron) to understand. Furthermore, the wording “for a detachable connection” as used in the context of the present description and the claims is to be understood in particular as a connection that can be released without damaging the electrical conductors and thus (repeated) disconnection and reconnection of the electrical conductor allows. Furthermore, the term “actuating element” as used in the context of the present description and the claims is to be understood in particular as a component that is set up to be actuated manually.

The first device and the second device can be designed as a plug or socket or as a socket or plug.

The actuating element can be set up to cancel a mechanical locking between the plug and the socket.

The actuating element can be set up to convert actuating energy applied when the actuating element is actuated into electrical energy, with which the sensor is fed.

By actuating the actuating element, a circuit can be closed, which feeds the sensor with energy.

The circuit can include a memory for storing electrical energy.

The device can be supplied with energy by a current flow from the first electrical conductor to the second electrical conductor.

The device can generate an optical signal upon activation of the device.

The second device may comprise a magnetic material and the activated device may generate a magnetic field that resists separation of the second device from the first device.

The device may include a locking mechanism that blocks separation of the second device from the first device when the device is activated.

The locking mechanism may include a locking element made of a shape memory material.

The shape memory material may be a shape memory plastic or a shape memory alloy.

It goes without saying that the processes described with reference to the system can be steps of a corresponding method.

character list

• 1 Elemente eines erfindungsgemäßen Systems in einem Zustand, in dem die erste Vorrichtung und die zweite Vorrichtung voneinander getrennt sind, illustriert;
• 2 das in 1 gezeigte System in einem Zustand, in dem die erste Vorrichtung und die zweite Vorrichtung miteinander mechanisch lösbar verbunden sind, illustriert;
• 3 das in 1 und 2 gezeigte System gemäß einer ersten Ausführungsform in einem Zustand, in dem das Betätigungselement nicht betätigt wird, illustriert;
• 4 das in 3 gezeigte System in einem Zustand, in dem das Betätigungselement betätigt wird, illustriert;
• 5 das in 1 und 2 gezeigte System gemäß einer zweiten Ausführungsform in einem Zustand, in dem das Betätigungselement nicht betätigt wird, illustriert;
• 6 das in 5 gezeigte System in einem Zustand, in dem das Betätigungselement betätigt wird, illustriert;
• 7 eine erste Abwandlung der in 1 bis 6 gezeigten Systeme illustriert;
• 8 eine zweite Abwandlung der in 1 bis 6 gezeigten Systeme illustriert;
• 9 eine dritte Abwandlung der in 1 bis 6 gezeigten Systeme illustriert;
• 10 eine vierte Abwandlung der in 1 bis 6 gezeigten Systeme illustriert;
• 11 und 12 eine erste beispielhafte Ausgestaltung der Einrichtung illustrieren; und
• 13 und 14 eine zweite beispielhafte Ausgestaltung der Einrichtung illustrieren.

The invention is explained below in the detailed description using exemplary embodiments, reference being made to drawings in which:

• 1 Elements of a system according to the invention in a state in which the first device device and the second device are separated from each other, illustrated;
• 2 this in 1 illustrated system in a state in which the first device and the second device are mechanically detachably connected to each other;
• 3 this in 1 and 2 Figure 1 illustrates the system according to a first embodiment in a state in which the actuating element is not actuated;
• 4 this in 3 illustrated system in a condition in which the actuator is actuated;
• 5 this in 1 and 2 Figure 12 illustrates the system according to a second embodiment in a state in which the actuating element is not actuated;
• 6 this in 5 illustrated system in a condition in which the actuator is actuated;
• 7 a first modification of the in 1 until 6 illustrated systems shown;
• 8th a second modification of the 1 until 6 illustrated systems shown;
• 9 a third modification of the 1 until 6 illustrated systems shown;
• 10 a fourth modification of the 1 until 6 illustrated systems shown;
• 11 and 12 illustrate a first exemplary embodiment of the device; and
• 13 and 14 illustrate a second exemplary embodiment of the device.

The same or functionally similar elements are identified by the same reference symbols in the drawings.

DETAILED DESCRIPTION

1 and 2 12 show a side view and a top view, respectively, of system 100 consisting of device 200 and device 300, with some elements arranged in device 200 and device 300 being represented schematically by broken lines. Device 200 includes conductor 210 and conductor 220. Device 300 includes conductor 310, conductor 320, actuator 330, and current sensor 340 (e.g., a magnetic field sensor based on Hall effect, TMR, AMR, GMR, etc.).

Device 300 and device 200 are configured as sockets and plugs, respectively, with conductor 210 being inserted into conductor 310 and conductor 220 being inserted into conductor 320 when device 200 is inserted into device 300 . When device 200 is fully inserted into device 300, the plug connection is secured by latching hooks 230, which can be released again by actuating actuating element 330. For example, the housing of device 300 can have a plurality of projections 350 (or a peripheral projection) on the inside, through which the latching hooks 230 are deflected inwards when pushed in and which engage behind the latching hooks 230 in a form-fitting manner after they have snapped in (which causes a mechanical locking ).

Device 200 further includes cage clamp springs 240 which are electrically connected to conductor 210 and conductor 220, respectively. Cage clamps 240 have terminal points to which solid or stranded conductors 410 or 420 can be connected. Device 300 includes cage clamps 360 which are electrically connected to conductor 310 and conductor 320, respectively. Cage clamps 360 have terminal points to which solid or stranded conductors 510 or 520 can be connected. The terminal points can be opened to facilitate insertion/extraction of the conductors 410, 420, 510 and 520 by operating a lever (not shown) or by means of an operating tool. The terminal points can also be set up to enable direct plugging of the solid or stranded conductors 410, 420, 510 and 520. If necessary, the conductors 410, 420, 510 and 520 can also be released without tools, for example by pulling out and rotating the conductors 410, 420, 510 and 520 at the same time.

3 illustrates system 100 (here without the optional latching hooks 230), which is designed according to a first embodiment, in a state in which current flows between electrical conductor 310 and electrical conductor 210 and actuating element 330 is not actuated. In this state, locking device 610 and locking device 620 are deactivated. Will, as in 4 illustrated, actuating element 330 is actuated while a current I is flowing between electrical conductor 310 and electrical conductor 210, the magnitude of which is above threshold value S1 (which may be zero), controller 600 causes locking device 610 and locking device 620 to be activated, thereby disconnecting Device 200 and device 300 (from each other) is prevented or at least made more difficult.

5 illustrates system 100 (without the optional latching hooks 230), which is designed according to a second embodiment, in a state in which current flows between electrical conductor 310 and electrical conductor 210 and actuating element 330 is not actuated. In this state, latch 610 and latches are in place development device 620 activated. Will, as in 6 illustrated, actuating element 330 is actuated while a current I flows between electrical conductor 310 and electrical conductor 210, the magnitude of which is below threshold value S2, causing control device 600 that locking device 610 and locking device 620 are deactivated.

As in 7 illustrated, actuating element 330 can comprise a piezo element 370 (or a plurality of piezo elements 370 connected in series), as a result of which actuating energy applied when actuating element 330 is actuated can be converted into electrical energy. The electrical energy may be stored in storage (e.g., a capacitor) and used to power sensor 340 .

Locking device 610 and locking device 620 can each be formed from two cooperating locking elements 610a and 610b or 620a and 620b, one of the locking elements 610a and 610b or 620a and 620b being part of device 200 and one of the locking elements 610a and 610b or 620a and 620b is part of device 300.

As in 8th As illustrated, actuator 330 may be coupled to switch 330a such that the circuit energizing sensor 340 is completed by actuator 330 being actuated. Furthermore, the circuit that is closed by actuating element 330 can comprise an energy store 600a (e.g. an accumulator such as a button cell) by which sensor 340 can be supplied with energy when actuating element 330 is actuated. As in 9 As illustrated, the circuit can also be powered via electrical conductors 310 and electrical conductors 320 . For example, conductor 310 and conductor 320 may be intended to be connected (in use) to a 12V or 24V power supply. Furthermore, two circuits can be provided. A first circuit, which is closed by actuating the actuating element 330 and supplies sensor 340 with energy, and a second circuit, which is closed as a function of the measured sensor value and supplies locking device 610 and locking device 620 (and, if applicable, control device 600) with energy.

As in 10 As illustrated, device 300 may be provided with an audible or visual signal generator 700 (e.g., an LED) that generates a specific visual signal when the device is activated or deactivated. For example, beacon 700 may emit a green signal when actuator 330 is actuated and the device is deactivated, and emit a red signal when actuator 330 is actuated and the device is activated. If no signal is output, the user knows that there is an error. Furthermore, it is also possible to dispense with the locking device 610 and 620, so that only a (warning) signal is output when the actuating element 330 is actuated.

As in 11 and 12 illustrated, the two interacting locking elements 610a and 610b or 620a and 620b can be designed as a coil or element made of (ferro)magnetic material, with current flowing through the coils 610a and 620a when the device is activated, so that a magnetic field is generated which counteracts a (manual) separation of device 300 from device 200 or, with a corresponding strength of the magnetic field, completely blocks a manual separation of device 300 from device 200.

As in 13 and 14 As illustrated, the locking elements 610a and 620a can comprise a shape memory material (e.g. a shape memory plastic or a shape memory alloy), wherein when the device is activated an electromagnetic field is generated which causes the locking elements 610a and 620a to enter into a positive connection with the locking elements 610b and 620b , which blocks manual disconnection of device 300 from device 200.

Reference List

100

system

200

contraption

210

director

220

director

230

latch hook

240

cage clamp

300

contraption

310

director

320

director

330

actuator

330a

Switch

340

sensor

350

head Start

360

cage clamp

370

piezo element

600

control device

600a

Storage

610

locking device

610a

locking element

610b

locking element

620

locking device

620a

locking element

620b

locking element

700

signaller

S1

threshold

S2

threshold

Claims (12)

System (100) for detachably connecting electrical conductors (210, 220, 310, 320), comprising: a first device (300) in which a first and a second electrical conductor (310, 320) are arranged; a second device (200) in which a third and a fourth electrical conductor (210, 220) are arranged; a sensor (340) set up to detect a current flow (I) between the first electrical conductor (310) and the third electrical conductor (210); and a device (600, 610, 620) which is activated when an actuating element (330) attached to the first device (300) is actuated and the detected current flow (I) is above a first threshold value (S1) and/or is deactivated when the actuating element (340) attached to the first device (300) is actuated and the detected current flow (I) is below a second threshold value (S2). system (100) after claim 1 , wherein the first device (300) and the second device (200) are designed as a plug or socket or as a socket or plug. system (100) after claim 2 , wherein the actuating element (330) is set up to release a mechanical locking between the plug and the socket. System (100) according to one of Claims 1 until 3 , wherein the actuating element (330) is set up to convert an actuating energy applied when the actuating element (330) is actuated into electrical energy, with which the sensor (340) is fed. System (100) according to one of Claims 1 until 3 , wherein when the actuating element (330) is actuated, a circuit is closed which feeds the sensor (340) with energy. system (100) after claim 5 , wherein the circuit comprises a memory (600a) for storing electrical energy. System (100) according to one of Claims 1 until 6 , wherein the device is powered by a current flow from the first electrical conductor (310) to the second electrical conductor (320). System (100) according to one of Claims 1 until 7 , the device generating an optical signal upon activation of the device. System (100) according to one of Claims 1 until 8th , wherein the second device (200) comprises a magnetic material and the activated device generates a magnetic field which counteracts a separation of the second device (200) from the first device (300). System (100) according to one of Claims 1 until 9 , wherein the device has a locking mechanism which blocks a separation of the second device (200) from the first device (300) when the device is activated. system (100) after claim 10 , wherein the locking mechanism comprises a locking element made of a shape memory material. system (100) after claim 11 , wherein the shape memory material is a shape memory plastic or a shape memory alloy.

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