EP1636881A1

EP1636881A1 - Plug-in connection for a mobile terminal

Info

Publication number: EP1636881A1
Application number: EP04740330A
Authority: EP
Inventors: Frank Homann; Michael Bothe
Original assignee: Friwo Geraetebau GmbH
Current assignee: Friwo Geraetebau GmbH
Priority date: 2003-06-25
Filing date: 2004-06-25
Publication date: 2006-03-22
Also published as: JP2005050795A; US20050020133A1; CN100524968C; WO2004114472A1; DE20309812U1; US7121899B2; CN1591998A

Abstract

The invention relates to a plug-in connection for electrically connecting network equipment that is to be supplied with a mains voltage and that is located in a mobile terminal, to the mains voltage, by means of a cable that conducts a mains voltage or by means of a coupling piece that can be coupled to a conventional mains cable. In particular, the flexible mains cable can be coupled to the network equipment by means of a plug system, which comprises a plug and a socket and which is proportioned in such a way that it is smaller than plug systems according to IEC 320, but conforms to the valid norms in terms of contact and handling safety.

Description

CONNECTOR FOR A MOBILE DEVICE

The invention relates to a connector for a mobile terminal.

Today, mobile devices are mostly supplied by external power supplies. As a rule, plug-in power supplies or desktop devices are used. Both types of device generate a safety extra-low voltage, which is connected to the end device via an output line and a plug system. The tabletop unit also has a mostly removable mains cable for supplying mains voltage. Furthermore, a device for voltage conversion is known from WO 99-43074 A1, in which the unit for supplying power to the terminal has been integrated into the (output) connector on the device. This eliminates the voltage drop on the output power and the efficiency is significantly improved.

Due to the increased power requirements of mobile devices (e.g. UMTS mobile phones) as well as the desire for shorter charging times and the use of battery systems with low cell voltages, e.g. B. lithium polymer batteries, increased demands are placed on the tolerances of the charging voltage. Voltage fluctuations of more than 1% mean that the battery is either not sufficiently charged and thus only part of the available operating time is available, or that the batteries are overcharged and the service life is significantly shortened. A commercially available coaxial connector has a contact resistance of typically 30 mΩ according to the manufacturer's data sheet. With a charging current of 1.5 A, approximately 45 mV of the output voltage drop. At a charging voltage of typically 4.1 V, this is more than the permissible 1%.

Furthermore, for reasons of user-friendliness, there is often a desire to integrate the power supply into the end device, similar to a razor, in order not to have to transport additional supply devices when traveling. The connection is made via a plug system in accordance with IEC 320 C7 / C8, the so-called razor plug. This connector system is approved for 2.5 A and is therefore very common in small power supplies up to approx. 70 W.

For particularly compact applications with a power requirement below 10 W, such as Mobile phones, M P3 players, PDAs, portable CD / DVD players or the like, however, this connector system requires too much space.

It is therefore the object of the invention to provide a connector system which avoids the disadvantages shown.

The solution to the problem is that a plug connection is proposed for a mobile terminal, in particular also for a mobile telephone, preferably with an integrated battery system for an energy supply with low current (or low battery cell voltage), the energy supply for the terminal device being integrated Power supply unit takes place, which receives mains voltage, in particular 240 VAC, via a mains cable, the, in particular, flexibly designed mains cable being able to be coupled to the mains unit via a plug system which is dimensioned in such a way that it is smaller than plug systems in accordance with IEC 320 and yet by the Touch and handling safety corresponds to the applicable standards.

For the purposes of the invention, the term “power supply unit” should be understood in the following to mean both the voltage converter of the terminal, for example a transformer or piezoelectric voltage converter, for the direct supply of the electronic components of the terminal, and the voltage converter for supplying the battery charging station of the terminal.

The end devices can be equipped with an integrated battery system for energy supply with low-wattage current (or with low battery cell voltage), or with a power supply unit (without a battery system) for the direct supply of the electrical components in the end device.

Any common mobile end devices can be provided as end devices, for example dictation devices, notebook computers, shavers, mobile telephones, cordless telephones, etc.

The essence of the invention is to propose a miniaturized plug connection consisting of a plug and socket (socket) which is suitable for a nominal voltage of 240 VAC and for nominal currents up to 0.5 A. In particular, a preferred training a device socket can be integrated into mobile devices to save space. This enables integrated power supplies to be implemented, which can be connected directly to the charging station of the battery in the device. They have no voltage drop at low voltage connectors or output lines. The safety distances and the requirements for contact protection are observed. Furthermore, the overall efficiency of the arrangement improves.

A handy coupling piece is proposed for the transition from known IEC 320 power lines to the plug connection according to the invention. This coupling piece can also be used if a power line with the solution according to the invention is to be connected to a desktop power supply, for example with a known IEC socket. An additional power cable can then be omitted. Users of the mobile device then only need the coupling piece.

Further developments can be found in the subclaims, the features of which are explicitly referred to here.

Embodiments of the invention are shown in detail in the figures. These show in detail:

FIG. 1 connector according to the invention and IEC device connector;

FIG. 2 connectors and socket in section;

FIG. 3 Coupling piece for IEC 320 mains cable socket type C7 and miniaturized plug connection;

FIG. 4 Miniaturized connector on an output connector;

FIG. 5 front-end AC / DC module with the miniaturized connector and

FIG. 6 State of the art; a) plug-in power supply, b) desktop power supply and c) output plug-in power supply. The prior art is shown in FIG. 6a shows a plug-in power supply unit with transformer part T1, flexible power line NL and the low-voltage coaxial output plug KS. FIG. 6b shows a desktop power supply unit T2 which is detachably coupled on the network side via the mains cable NL via an IEC 320 plug system (C7 corresponds to plug, C8 corresponds to socket; in each case two-pole). On the output side, the low voltage is again available at the coaxial output connector KS. A further known variant is shown in FIG. 6c. It is a so-called output plug-in power supply, in which the power supply or transformer part T3 is arranged at the end of the power line NL, and the output voltage can be removed directly from the housing of the transformer part T3 via the coaxial plug KS.

The quality of the voltage applied to the coaxial connector KS has the above-mentioned limitation, which consists in the fact that a voltage drop is associated with the contact resistance of the connector, which drop is usually intolerable, or at least disadvantageous.

A device plug according to the invention is shown in FIG. 1A compared to a C7 connector according to IEC 320 (for a C8 socket). The dimensions are significantly smaller, but with the same electrical handling safety. In the slot 21 of the connector 20, which can be produced from known insulating materials, the guide ridge 23 is visible for inserting a socket 10 according to the invention in the correct position and polarity. Such is shown in FIG. To see 1C. The slot 21 is rectangular. This is to be taken as an example, oval-rounded or differently shaped shaft openings, similar to the different IEC 320 types (for example C5 / C6 three-pole or C7 / C8 two-pole) can be provided according to the invention.

The contact pins 22 of the connector 20 are angular, whereas round designs are also within the scope of the invention. On the lower part of the connector 20, mounting pins 26 and contact wires 24 can be seen, which in turn are intended to indicate an embodiment, namely one that is suitable for mounting on a printed circuit board (in the form of soldering feet). It goes without saying that the contact guidance from the contact pins 22 of the device connector via the contact wires 24 (also compare the cutting representation in FIG. 2A) for the next electrical assembly (power supply or battery part) of the terminal can also be formed in any other known manner. Both the contact guidance and the type of fastening of the device plug in the terminal can be carried out according to known patterns, for example snap-in fixings, one-part integration into the terminal housing (in the injection molding tool), screw fastenings and other known types of mounting. The connector 20 has a rectangular, transverse collar 25, which can be integrated in the housing wall, but can also rest on the edge of a housing opening.

In this regard, the possible designs are identical to the known types of mounting IEC device plugs or sockets, of which comparatively left in FIG. 1A a device plug S is shown. This connector is designed for a double-groove power line; therefore shows two guide ridges 23 'for the double groove and two contact pins 22' for the two-wire connection to the power line. A snap hook 26 'serving for fastening is still visible cut.

The device plug 20 in FIG. 1 B is suitable for the socket 10 according to FIG. 1C, an illustration being indicated as mounting on a printed circuit board 150.

Figures 1C and the sub-figures FIG. 2 essentially show the socket 10. This is characterized by the relatively long socket body 11. The socket body 11, which is made of relatively rigid or hard insulating material, is seated in the end closure EA of the flexible network line NL, which (in the figures) is designed as an insulated two-wire line.

FIG. 2A to C show, in each case cut open, also the socket 10, wherein in FIG. 2A (corresponding to FIG. 1B) the connector 20 is also drawn in section. No further explanations have to be made for the person skilled in the art regarding the materials of the plug and the socket, since a customary and known selection can be made here. It is essential that the socket 10 is introduced with a strain relief 19 in the end section EA of the power line NL. The electrical contacts of the socket are designed as knife contacts 14. The knife contacts are located relatively deep in the channels of the pin Recordings 12. The channels of the recordings 12 are either round or angular in cross section corresponding to the contact pins 22 of the connector. The contacts 14 in the socket can of course also be designed in a round shape as contact sleeves or in another known manner (see for example the differences according to IEC 320 between C11 / C12 and C7 / C8) for receiving the contact pins 22 of a plug. The knife contacts are connected inside the socket to the conductors 14 'of the mains cable. One can see in the sectional drawings an insulating material body designed as a strain relief 19, in which the conductors 14 'of the power line and their insulation are embedded in a tensile manner.

The great depth of the channels of the pin receptacles 12 until the knife contacts are reached is an essential feature for the contact protection and the safety distances to be maintained for the intended voltage level. The insertion shafts 21 of the plugs 20 are also formed correspondingly deep.

The FIG. 3A and 3B show a two-pin coupling piece 30 (adapter plug) between an IEC 320 power line and the miniaturized plug connection in two views. The plug part 11 is identical to that from FIG. 1C trained. The plug S for the power line is designed for a two-core double-groove line. It goes without saying from the illustration of the invention that the coupling piece 30 can also be designed for three-pole power lines with a corresponding IEC type version and a correspondingly suitable version of the plug-in part. In this respect, the representation in FIG. 3 is not to be understood as restrictive for a special design of a coupling piece.

In FIG. 4, the miniaturized plug system is designed and shown as a connection between a two-wire mains cable NL and an output plug device T3 '. The power cord closes on the device side with a socket 10 in the configuration according to FIG. 1 C. The device plug 20 on the device T3 'is suitably designed and corresponds to the representation from FIG. 1A. The device T3 'is provided with a coaxial plug KS, this type of plug-in also to be understood only as an example, since this figure is about the illustration of a plug system designed on a power line.

A front-end AC / DC module 130 '(right) with the miniaturized connector system 20 is shown in FIG. 5 shown. The two plugs shown (IEC device connector S according to IEC 320 and Rätestecker 20) correspond in shape and design to the representation from FIG. 1A. The reference numerals are the same as in FIG. 1A, so that the description need not be repeated here.

The smaller space requirement of the connector 20 in the component 130 'is particularly clear from this illustration. It is clear that miniaturization of the electronic components cannot continue unless the electrical leads and connector systems are also miniaturized.

REFERENCE NUMBERS

100 end devices

130, 130 'power supply (power supply or battery part in the end device)

150 pcb

T1.T2, transformer part

T3.T3 '

S lEC connector for 2-slot socket C8

C7, C8 two-pole two-slot version IEC-320 connector,

NL flexible two-wire power cord (round or flat)

EA final degree

KS conventional coaxial connector

10 socket (female socket)

11 socket body

12 pin holder

13 guide groove

14 contact knife, contact sleeve

14 'Head of the power line

19 Strain relief 0 Male connector 1 connector slot 2 contact pin 3 guide burr 4 contact wires 5 collar 6 mounting pin 7 solder pin 0 coupling piece

Claims

EXPECTATIONS

1. Plug connection for the electrical connection of a power supply unit (130) to be supplied with line voltage and arranged in a mobile terminal (100) via line (NL) carrying line voltage or via a coupling piece (30) that can be coupled to a conventional line line (NL) with the line voltage The mains line (NL), which is designed to be particularly flexible, can be coupled to the power unit (130) via a plug system comprising a plug (20) and a socket (10), which is dimensioned such that it is smaller than plug systems according to IEC 320 and yet meets the applicable standards with regard to safety in handling and handling.

2. Plug connection according to claim 1, characterized in that the socket (10) consists of a socket body (11) and an end termination (EA) of a power line (NL) or a socket body of a coupling piece (30), the length of the socket body (11) and the depth of the channels of the pin receptacle (12) until the contacts (14) in the socket (10) are reached in such a way that they comply with the requirements regarding safety of contact and dielectric strength.

3. Plug connection according to claim 2, characterized in that the plug (20) is formed with a plug shaft (21) which corresponds to the length of the socket body (11).

4. Plug connection according to at least one of the preceding claims, characterized in that the plug (20) is arranged directly as a device plug for the electrical input to the battery system of the terminal (100).

5. Plug connection according to at least one of the preceding claims, characterized in that the attachment of the plug (20) in the terminal (1OO) is designed as a snap-in fixation.

6. Plug connection according to at least one of claims 1 to 4, characterized in that the attachment of the plug (20) in the terminal (100) as a built-in Device connector for mounting on a printed circuit board (150) is executed.

7. Plug connection according to at least one of the preceding claims, characterized in that the socket (10) is designed as a built-in socket.

8. Plug connection according to at least one of claims 1 to 6, characterized in that the socket (10) is designed as the termination of a power line (NL).

9. Plug connection according to the preceding claim, characterized in that the socket (10) is provided with a strain relief (19) integrated in the end termination (EA) of a power line (NL).

10. Plug connection according to at least one of the preceding claims, characterized in that the coupling piece (30) is provided for the connection between a socket according to IEC 320 and a socket according to the invention (10).

11. A plug connection according to the preceding claim, characterized in that the coupling piece (30) is provided for the connection between a socket according to IEC 320 of type C8 and a socket (10) according to the invention.

12. Plug connection according to at least one of the preceding claims, characterized in that the terminal (100) is designed as a telephone, in particular as a mobile phone.