EP2650980B1 - Extension cable - Google Patents

Description

field of invention

The invention relates to an extension cord, in particular an extension cord for socket outlets with earthing contact.

Background of the Invention

Extension cords, such as those used in the home and in the commercial sector, are known. These are in particular extension cords for socket systems with earthing contact plugs, in particular plugs of type F or CEE 7/4.

The basic structure of such protective contact socket systems is known to those skilled in the art.

Extension cords typically include a plug that is connected to an outlet or power strip by a flexible cord. With such extension cords, a socket outlet can be provided at a desired location. If a power strip is used, it can also be used to increase the number of sockets in order to be able to connect multiple devices.

The disadvantage is that the socket on the wall is blocked by the plug of the extension cable and no more devices can be plugged in at this point.

In order to provide a number of connections at a socket, adapters are also known which can be inserted into a socket and have a number of connection sockets. If an extension is now required at the same time, it is now conceivable to plug an extension cable into the adapter. However, such a cascading of adapters and extension cords is not permissible and can lead to dangers, in particular due to the fact that a large number of current consumers with high current consumption can be connected to one socket.

The document DE 20 2010 012 018 U1 shows an extension cord with a plug which has a socket on the back. The document GB 2 456 793 A shows a power supply with a power supply unit that has a socket on the back. The document

U.S. 2002/0127917 A1 shows a connector with an overload protection, which includes a bimetallic contact. document U.S. 5,844,765 shows a plug with a protection circuit.

object of the invention

In contrast, the invention is based on the object of at least reducing the aforementioned disadvantages of the prior art.

It is a particular object of the invention to provide an extension cord of simple construction and safety in which the outlet into which the extension cord is plugged does not become blocked.

Summary of the Invention

The invention is already solved by an extension cable according to claim 1.

Preferred embodiments and developments of the invention are the subject matter of the dependent claims.

The invention relates to an extension cable which is designed as an extension cable for a socket outlet with earthing contact, in particular of the F-type plug.

The extension cord includes a plug. In the case of socket outlets with earthing contact, this plug usually has two connection contacts, namely phase and neutral, and a grounded protective conductor.

The plug includes a housing which is formed from a dielectric material such as a plastic and in which the current-carrying contacts and the protective conductor are held.

A flexible cable is inserted into this housing, with which the contacts of the plug are connected.

In order to be able to use this as an extension cable, a socket is also provided on the other side of the cable. This usually also has a dielectric housing into which the cable is inserted.

The two housings are preferably connected directly to one another via the cable, such that the connection cannot be separated without opening one of the two housings.

According to the invention, a further socket is arranged in the housing of the plug.

The socket of the extension cable is therefore designed as a through socket and includes a socket that allows other devices to be plugged in at the point of the wall socket into which the extension cable is inserted.

The further socket is preferably arranged on a side opposite the plug, the plug-in position is therefore the same.

The integration of the socket in the housing of the plug prevents unwanted cascading of an adapter with an extension cable.

According to the invention, the first socket, ie the socket which sits at the outer end of the extension cord, is part of a power strip. Consequently, the extension cable is not only used for an extension while at the same time preserving the space of the wall socket, but as a multiple socket to plug in several devices.

In a further development of the invention, overload protection is arranged in the housing of the plug.

The overload protection can be designed as a fuse or circuit breaker.

In an embodiment which is not part of the invention, the overload protection is designed as a fuse, in particular as a glass tube fuse.

Such a fuse has a compact design and can be integrated in the housing of the connector without the size of the housing changing significantly.

The overload protection ensures, particularly in the case of impermissible cascading of the extension cable, that there is no risk of overheating of the extension cable itself or the house-side lines and/or contacts due to excessive current flow.

On the current side, the overload protection is arranged both in front of the socket at the end of the extension cable and in front of the other socket, which is integrated in the housing of the plug.

The overload protection is preferably accessible via a side of the housing on which the plug is arranged.

If the plug is now inserted into the wall socket, the overload protection, in particular the fuse, is no longer accessible. Manipulation of the overload protection is thus prevented as long as the extension cable is plugged in.

An overload protection designed as a safety fuse can be arranged in particular behind a cover made of a dielectric material. The cover can contain a window, which in particular enables a view of the transparent part of a glass tube fuse. Since the fuse is made of a dielectric material in this area, the window can be designed as a simple opening.

In a further development, the cover has a holder for the fuse, so that the fuse is removed together with the cover when the cover is removed. This prevents the cover from being removed individually, i.e. without the fuse, which could lead to live areas of the fuse, such as the contacts, becoming accessible.

According to the invention, a thermal fuse is arranged in the housing of the through socket as overload protection.

The thermal fuse can preferably be reset using a reset mechanism. In particular, a reset pin is provided. The resetting mechanism is preferably arranged on the plug-side side of the through-type socket. This reduces the risk of manipulation to prevent or delay triggering of the thermal fuse.

Thermal fuses as such are known. As a rule, these have a bimetallic strip which, in the case of resettable thermal fuses, is used to initiate a switching operation is triggered, which can only be reversed by the user after the bimetallic strip has cooled, so that an electrical connection can be established again.

Compared to the fuse mentioned above, the thermal switch has the advantage that the user does not need a spare part. Rather, the function of the extension cord can be restored by resetting the thermal fuse.

In a further development of the invention, a mains filter is integrated in the housing of the connector in order to block unwanted frequencies.

It is also conceivable to integrate overvoltage protection in the housing of the plug.

According to the invention, at least the socket in the housing of the plug is surrounded by a plug-in protection that blocks the insertion of a housing with larger dimensions than a plug itself.

In the simplest case, sections of the socket are surrounded by a web.

If you try to plug a slightly larger case, such as the case mentioned above with an overload protection or a timer or a multi-socket adapter into the case, this is not possible due to the larger case dimensions as the case hits the bridge.

In many cases, this can prevent impermissible cascading, especially of several extension cables.

Description of the drawings

The invention shall in the following be referred to the drawings Figures 1 to 8 are explained in more detail with reference to exemplary embodiments shown schematically.

1 shows a perspective view of an embodiment of an extension cord 1, as it is not the subject of the invention.

The extension cord includes a line 2 and a socket 3, which is designed as a safety socket.

By means of a plug 5, the extension cord is connected to an existing socket in a wall, for example.

The socket is designed as a pass-through socket 4 and includes on the opposite side of the plug 5 another socket 6, which is connected to the socket 3 in parallel.

Due to the additional socket 6, a socket is still available on the wall side.

The pass-through socket 4 includes overload protection, as will be explained in more detail below.

2 Figure 12 shows another perspective view of an embodiment of the invention.

The housing 9 of the pass-through socket 4 can be seen.

This is connected to a socket strip 7 via a cable 2 .

In this embodiment, the power strip 7 includes three sockets 3a, 3b, 3c. However, it is also understood that the power strip can include a higher or lower number of sockets.

The power strip 7 also includes a power switch 8 with which the devices plugged into the power strip 7 can be switched off.

The housing of the power strip 7 and the housing 9 of the through-socket 4 are inseparably connected to each other via the line 2, so they cannot be separated from one another without opening or breaking open one of the two housings with a tool.

3 shows a perspective view of the in 1 and 2 shown pass-through socket 4, which is connected via line 2.

In this view, the plug-side end of the through socket 4 with the plug 5 is shown.

The housing consists of a lower housing part 13 and an upper housing part 10. These two components can be screwed. However, it is also conceivable to weld or glue the housing parts to one another.

A cover 11 is arranged adjacent to the plug 5 and has a viewing window 13 which provides a view of a safety fuse.

The safety fuse located behind the cover 11 serves as overload protection and can be designed for a maximum continuous load of 16 A, for example.

If the plug 5 is now plugged into the wall, the cover 11 is no longer accessible. It is thus ensured that the cover 11 can only be manipulated in the de-energized state.

4 shows another perspective view of the pass-through socket, in which the housing is hidden.

The contact pin 17 is connected to the contact 18 via the fuse 14 .

The fuse 14 sits in a fuse holder 15, which is arranged below the components of the safety socket and via the in 3 cover shown is accessible.

The fuse holder 15 sits between the contact pins of the plug and a strain relief 16.

In this embodiment, a child safety device 23 is integrated into the housing, via which the

Passage openings for the contacts of the plug to be used are closed and only released when a contact pin is inserted on both sides at the same time. The basic structure of such a child safety device 23 is known to those skilled in the art.

figure 5 shows a further detailed view of the overload protection.

A base plate 19 made of metal can be seen.

The base plate 19 has contact terminals 21 and 22 via which it is connected on one side via a line 20 to the contact pin and on the other side to the contact of the socket.

Fig. 6 shows a further perspective detailed view of the pass-through socket, in which now only the housing but not the cover is hidden.

The two contacts 26, 27 of the fuse holder designed as spring contacts can be seen.

The cover 11 has a holder 25 for the fuse 14 .

The holder 25 is essentially provided as a recess adapted to the fuse 14 .

If the cover 11 is now removed from the housing (hidden), the safety fuse 14 is automatically removed as well. So it isn't possible to remove the cover 11 individually without the fuse 14 being removed as well.

Fig. 7 shows another perspective view of the through socket 4.

In this view, the cover (11 in FIG. 6) has been removed together with the safety fuse, so that the fuse holder 15 can now be seen.

Fig. 8 shows a view of the through socket.

In addition to a slightly different shape of the housing 9, a plug-in protection 24 is arranged on the wall side of the socket 6 in the form of a web running approximately halfway around the socket 6.

The plug-in protection prevents components with a larger housing than a normal plug from being plugged in.

In particular, the pass-through socket shown above cannot itself be plugged into another pass-through socket, which further improves security since impermissible cascading is prevented.

Referring to Fig. 9 and Fig. 10, a through socket according to the invention will be explained.

Fig. 9 shows a through-type socket, which in terms of structure is essentially that in Figures 1 to 3 illustrated pass-through socket corresponds.

In contrast to the in Figures 4 to 7 illustrated embodiment, which is not part of the invention, a thermal fuse 28 is integrated into the housing 9 of the through socket 4 instead of a safety fuse. A rear half of the housing is hidden in the view according to FIG. 9 for better visibility.

About the thermal fuse 28, the current of a connection of the socket is performed.

As can be seen in the sectional view according to FIG. 10, the thermal fuse 28 has a reset pin 29 as a reset means, which protrudes on the plug side from the housing 9 of the through socket 4 at least in the tripped state.

Through the thermal fuse 28, both the through socket 4 and the socket arranged on the extension cable (3 in 1 ) or power strip switched off.

After eliminating the overload, the user can push the reset pin 29 back into the housing and thus restore the function of the extension cable.

The use of a thermal fuse makes it possible to design the extension cable more conveniently than the fuse mentioned at the outset.

The invention made it possible to provide a simply and securely constructed safety cable, in which the socket on the wall is not blocked.

Reference List

1

extension cable

2

management

3

socket

4

pass-through socket

5

plug

6

socket

7

power strip

8th

counter

9

casing

10

housing top

11

cover

12

viewing window

13

casing lower time

14

fuse

15

fuse holder

16

strain relief

17

contact pin

18

Contact

19

round plate

20

management

21

contact clamp

22

contact clamp

23

child lock

24

Plug-in protection function

25

holder

26

Contact

27

Contact

28

thermal fuse

29

reset pin

Claims (4)

1. An extension cable (1) for a safety socket, comprising a plug (5), a cable (2), as well as at least one first socket (3), which is connected to the cable and which is part of a socket strip (7), wherein the plug (5) comprises a housing and is connected to the first socket (3) by means of the cable (2) guided into the housing, wherein a further socket (6) is arranged in the housing of the plug (5), and wherein the further socket (6) is arranged on a side located opposite the plug (5), so that the further socket (6) is formed as connector socket (4) and makes it possible that equipment can further be plugged in at the site of a wall socket, into which the extension cable (1) is inserted, characterized in that the socket strip (7) comprises a power switch (8), by means of which equipment plugged into the socket strip can be disconnected from the power supply,

   and that the further socket (6) is surrounded in the housing of the plug (5) with a plug-in protection (24), which blocks the plug-in of a housing with larger dimensions than a plug,

   and wherein the connector socket (4) comprises a housing (9), which consists of a lower housing part (13) and an upper housing part (10), and wherein a thermal fuse (28) is integrated in the housing (9) of the connector socket (4).
2. The extension cable (1) according to claim 1, characterized in that an overload protection formed as the thermal fuse (28) is formed in the plug (5), wherein the overload protection is accessible via a housing side, on which the plug (5) is arranged, and wherein the overload protection is arranged on the side upstream of the socket at the end of the cable (2) as well as upstream of the further socket (6), which is integrated in the housing of the plug (5), so that the first socket (3) as well as the connector socket (4) can be disconnected from the power supply by means of the overload protection formed as thermal fuse (28) .
3. The extension cable according to claim 2, characterized in that the thermal fuse (28) can be reset via a resetting element (29), which sticks out from the housing of a connector socket.
4. The extension cable according to any one of the preceding claims, characterized in that the housing of the plug (5) is connected directly to a housing of the first socket (3) via the cable (2).

Images