WO1996041407A1 - Power supply for mobile electrical appliances - Google Patents

Abstract

The invention concerns an electric circuit (5) for an electrical direct voltage source (4) accommodated in a housing (3), the live pole (6) being brought out of the housing (3) via a switching device (23) which can be controlled from outside the housing (3). The switching device (23) can be controlled, for example, by being connected to the on-off switch (21, 22) of an electrical appliance (2). If the on-off switch (21, 22) is closed, for example, by the user, the electrical switching device (23) likewise changes to its closed state such that the voltage emitted by the direct voltage source (4) can be picked up externally at the housing (3). In contrast, if the on-off switch (21, 22) is in its open state, no voltage can be picked up at the connection points (8, 12) on the outside of the housing (3). The advantage of the invention is that no short-circuits can occur between these connection points (8, 12).

Description

 DESCRIPTION

POWER SUPPLY FOR MOBILE ELECTRICAL DEVICES

The invention relates to an electrical circuit for an electrical direct voltage source accommodated in a housing, in particular a battery, an accumulator or the like.

Mobile electrical devices usually have a mains-independent voltage supply. This is usually a DC voltage source, for example a battery or an accumulator. Such a DC voltage source is often discharged relatively quickly through the operation of the electrical device. For this reason, the DC voltage source is usually designed in such a way that the user can quickly replace it with a fully charged DC voltage source. It has now been found that despite all circuit-related safety measures, short-circuits or other defects occur repeatedly in the electrical device, which ultimately lead to a short-circuit between the poles of the DC voltage source and thus to a high current flow through the electrical device. This can not only result in the destruction of components of the electrical device, but also the risk of scorching or the like. Similar dangers exist in particular in the case of fully charged DC voltage sources which have not yet been plugged into the electrical device, but which are often carried by the user without any protective measures. Here, too, there is often a direct short circuit between the poles of the DC voltage source, which often results in the destruction of the DC voltage source due to the extremely high current flowing through it. Based on this, it is the object of the invention to provide an electrical circuit for such a DC voltage source, which offers effective protection against the dangers described.

This object is achieved according to the invention in that one of the poles of the DC voltage source is led out of the housing via a switching device, the switching device being controllable from outside the housing. It can be the live pole as well as the ground pole of the DC voltage source. It is particularly expedient to lead the live pole of the DC voltage source out of the housing via the switching device.

The DC voltage source can be “switched off” with the aid of the switching device. When the DC voltage source is switched off, there is no longer any voltage at the poles that can be tapped from the outside of the housing. A short circuit between these poles is therefore not possible. Any damage that can result from such a short circuit is therefore excluded. When the DC voltage source is switched on, the full voltage of the DC voltage source is present between the poles that can be tapped off on the outside of the housing. The electrical device can then be operated with this voltage.

The user of the electrical device can thus switch the entire electrical device including the DC voltage source into an operationally safe state by switching off the DC voltage source, in which a short circuit within the device or at the poles of the DC voltage source that can be tapped off on the outside of the housing is not possible. Theoretically, a short circuit is only conceivable within the housing; the probability of one Such a short circuit is extremely small, however, since the endangered poles are not accessible from the outside due to the encapsulation of the electrical circuit inside the housing.

The switching device can be controlled from outside the housing in various ways. So it is possible that a mechanical switch is provided which can be operated by the user. Another possibility is that the switching device can be electrically controlled via further connection points which can be tapped off on the housing. Furthermore, wireless controls of the switching device are also theoretically conceivable.

Overall, the electrical circuit according to the invention has the advantage that no voltage is applied to the poles of the DC voltage source that can be tapped off on the outside of the housing by the interposed switching device.

In an advantageous development of the invention, in order to control the switching device, on the one hand the live pole of the DC voltage source is led out of the housing via a resistor and on the other hand a control line connected to the switching device. In this way, electrical control of the switching device can be implemented. For example, an on / off switch can be connected between the voltage-carrying pole led out via the resistor and the control line, which in the closed state controls the switching device in its likewise switched-on state. The result of this is that when the on / off switch is closed, a voltage is present at the poles of the DC voltage source that can be tapped off on the outside of the housing. In the open state of the on / off switch, however, opens the switching device, so that then to the no voltage is available on the outside of the housing. Said on / off switch can be arranged within the electrical device, in particular it can be the on / off switch of the electrical device.

The described development of the invention thus has the advantage that the switching device can be electrically controlled in its switched-on state. This electrical control can take place from the electrical device. If the DC voltage source is uncoupled from the electrical device, the switching device automatically changes to its open state, so that a short circuit at the poles of the DC voltage source that can be tapped off from the housing is not possible.

In one embodiment of the invention, a relay, a thyristor or the like is provided as the switching device. An electrical or electromechanical component is thus provided as the switching device. These components ensure high reliability, high switching reliability and a long service life. A defect in these components is extremely unlikely, so that a short circuit within the housing due to such a defect is also very unlikely.

In a further advantageous embodiment of the invention, a transistor is provided to control the switching device. This has the advantage that the current required to control the switching device is independent of the current required to actuate the switching device. If, for example, a relay is provided as the switching device, the current required for actuating the relay can be higher than that for controlling the relay required electricity. As a result, on the one hand, the current consumption when the switching device is switched off can be limited to a minimum, while on the other hand, the switching reliability of the relay can be increased to a maximum by a relatively high current when it is actuated.

It is particularly useful if the base of the transistor is connected to the control line led out of the housing, if the emitter of the transistor is connected to the ground pole of the DC voltage source, if the coil of the relay on the one hand with the collector of the transistor and on the other hand with the voltage-carrying pole of the DC voltage source is connected, and if a switch connected to the voltage-carrying pole of the DC voltage source can be switched on and off by means of the coil. This circuit arrangement has proven to be particularly advantageous in practice. In particular, it has been found that this circuit has particularly expedient electrical properties with regard to power consumption, switching reliability, etc. when the switching device is switched on and also when it is switched off.

It is particularly advantageous if the electrical circuit according to the invention is used in a voltage supply unit of an electrical device. The voltage supply unit has an electrical DC voltage source accommodated in a housing and the electrical circuit likewise housed in the housing. The voltage supply unit can usually be coupled to the electrical device. In the case of in particular mobile electrical devices, such as, for example, portable radio devices or the like, the voltage supply unit is usually in the form of a package can be plugged into the device. This voltage supply unit according to the invention also has the advantages already described in connection with the electrical circuit according to the invention. In particular, a short circuit between the poles of the DC voltage source that can be tapped on the outside of the housing when the voltage supply unit is not plugged in is not possible.

Furthermore, it is particularly advantageous if the voltage supply unit according to the invention is used in an electrical device, preferably in a portable computer. The voltage supply unit can be coupled to the electrical device and is therefore easy to replace. With the aid of the switching device in the voltage supply unit according to the invention, the electrical device is reliably protected against short circuits and their consequences when the operating state is switched off.

In an advantageous embodiment of the electrical device according to the invention, an on / off switch which can be operated by the user is provided to control the switching device. It can expediently be the on / off switch of the electrical device. Thus, when the user switches the electrical device on or off at the on / off switch, not only is the circuit interrupted at some point within the device, but the DC voltage source is switched on or off via the switching device in the voltage supply unit. This has the advantages already explained. In particular, no voltage is present at the poles of the DC voltage source that can be tapped off from the outside of the housing of the voltage supply unit, so that no short circuits can occur. In a further advantageous embodiment of the device according to the invention, an on / off switch controllable by the device is provided for controlling the switching device. This on / off switch can be, for example, an electrical component that the switching device in the

The voltage supply unit is switched to the switched-on state as soon as, for example, the DC voltage source in the voltage supply unit is to be recharged via a mains connection and a corresponding charger. Such a mains connection with an associated charger is provided in most mobile electrical devices. With the help of the on / off switch which can be controlled by the device itself, the DC voltage source can be charged without the circuit according to the invention having to be changed in the voltage supply unit.

In a further advantageous embodiment of the device according to the invention, means are provided for measuring the current actually flowing into the device, for comparing the current with a desired value and for controlling the switching device as a function thereof. With the aid of these means, it is possible to limit the current flowing when the electrical device is switched on to a maximum value. If this maximum value is exceeded, the switching device in the voltage supply unit is switched off. As a result, no more current flows. The electrical device is thus protected against excessive current flow. The maximum permissible current flow can be changeable. It is thus possible, for example in the case of a portable computer, to set this maximum current flow as a function of the actually operated components of the computer. The means by which According to the invention, the current limitation can be carried out expediently in the electrical device itself, but it is also possible for the means, at least in part, to be accommodated in the voltage supply unit, in particular as additional components of the circuit according to the invention.

Further features, advantages and possible uses of the invention result from the following description of exemplary embodiments, which are shown in more detail in the drawing. All of the described and / or illustrated features, individually or in any combination, form the subject matter of the invention, regardless of their summary in the patent claims and / or their relationship.

Show it:

1 is a schematic block diagram of an electrical circuit for an electrical DC voltage source housed in a housing, and

Fig. 2 is a schematic block diagram of a

Extension of the electrical circuit of FIG. 1.

1 shows a voltage supply unit 1 which can be coupled to an electrical device 2. The electrical device 2 is, for example, a portable computer. The voltage supply unit 1 can be coupled to the electrical device 2, for example, with the aid of pins which can be inserted into assigned sockets. Usually is furthermore, a cavity or the like is provided in the electrical device 2, in which the voltage supply unit 1 is accommodated. The insertion or insertion of the voltage supply unit 1 into this cavity then mostly simultaneously causes the electrical connection between the voltage supply unit 1 and the electrical device 2, for example by inserting the pins into the assigned sockets.

The voltage supply unit 1 has a housing 3, in which a DC voltage source 4 and an electrical circuit 5 are accommodated. In the

DC voltage source 4 can be a battery or an accumulator. The DC voltage source 4 has a voltage-carrying pole 6 and a ground pole 7. The ground pole 7 is connected to a minus connection point 8 which can be tapped off the outside of the housing 3.

The electrical circuit 5 has a relay 9 which contains a switch 10 and a coil 11 which controls the switch. The switch 10 is connected on the one hand to the voltage-carrying pole 6 of the DC voltage source 4 and on the other hand to a positive connection point 12 which can be tapped from the outside of the housing. The coil 11 is connected on the one hand to the live pole 6 of the DC voltage source 4 and on the other hand to the collector of an NPN transistor 13, whose emitter is connected to the ground pole 7 of the DC voltage source 4.

The base of the transistor 13 is connected to a first control connection point 14 which can be tapped on the outside of the housing 3 of the voltage supply unit 1. Furthermore, the voltage-carrying pole 6 is connected via a resistor 15 to a second control connection point 16, which can also be tapped on the outside of the housing 3. The electrical device 2 has on its outside two connection points 17, 18, the minus connection point 8 and the plus connection point 12 of the

Power supply unit 1 are assigned. The electrical device 2 can be supplied with the voltage required for operation via these connection points 17, 18. Furthermore, the electrical device 2 has control connection points 19, 20 which are the control connection points 14, 16

Power supply unit 1 are assigned. Between the control connection points 19, 20 of the electrical device 2, an on / off switch 21 is connected, which can be operated by the user of the electrical device 2, and on the other hand, an on / off switch 22, which is controlled by the electrical device 2 itself can. The on / off switch 21 which can be actuated by the user can be directly the on / off switch of the electrical device. The on / off switch 22, which can itself be controlled by the electrical device 2, can be connected, for example, to a mains-dependent charging device for the DC voltage source 4.

If the voltage supply unit 1 is not coupled to the electrical device 2, that is, if there is no electrical connection between the

Power supply unit 1 and the electrical device 2, the transistor 13 is in its blocked, switched-off state. The result of this is that the relay 9 does not pick up and the switch 10 is thus open. There is thus no connection from the voltage-carrying pole 6 of the DC voltage source 4 to the positive connection point 12 on the outside of the housing 3 of the voltage supply unit 1. Between the positive connection point 12 and the negative connection point 8 Voltage supply unit 1 thus has no voltage.

However, due to the connection of the live pole 6 to the control connection point 16 on the outside of the housing 3 of the voltage supply unit 1, there is a voltage to the negative connection point 8. With the help of the resistor 15, the maximum flowing current between the control connection point 16 and the minus connection point 8 can be set to an extremely low value. As a result, the possible consequences of a short circuit can be safely avoided.

If the voltage supply unit 1 is coupled to the electrical device 2, then the connection points 8, 12 of the voltage supply unit 1 with the connection points 17, 18 of the electrical device 2 and

If control connection points 14, 16 of the voltage supply unit 1 are connected to the control connection points 19, 20 of the electrical device 2, the electrical circuit 5 in the voltage supply unit 1 can be controlled via the on / off switches 21, 22.

If the on / off switches 21, 22 are in their open state, the transistor 13 is also in its open and thus conductive state and the plus connection point 12 of the voltage supply unit 1 has no voltage.

However, if the on / off switch 21 is closed by the user, a current flows from the voltage-carrying pole 6 via the resistor 15 and the on / off switch 21 to the base of the transistor 13. This causes the transistor 13 to switch to its conductive state, so that a current can flow from the collector to the emitter of transistor 13. This has the result that a current flows from the live pole 6 via the coil 11 to the ground pole 7 of the DC voltage source 4. The coil 11 is excited by this current flow, so that the switch 10 is attracted and thus closed. Now the live pole 6 of the DC voltage source 4 is connected to the positive connection point 12. This means that the positive connection point 12 which can be tapped off on the outside of the housing 3 has a voltage. The one with the plus connection point 12

The voltage supply unit 1 connected connection point 17 of the electrical device 2 is thus acted upon by the aforementioned voltage, so that the electrical device 2 can be operated. When the on / off switch 21 is actuated by the user, the voltage supply unit 1 has thus been “switched on” and thus also the electrical device 2.

If the on / off switch 21 is opened again by the user, this has the consequence that the transistor 13 blocks again and thus the relay 9 drops out. The switch 10 is thereby opened so that the positive connection point 12 is no longer connected to the voltage-carrying pole 6 of the DC voltage source 4. The electrical device 2 is therefore no longer connected to an electrical voltage and is switched off.

If the electrical device 2 is connected to a mains-dependent charging device, this connection or plugging in of the charging device simultaneously causes the on / off switch 22 to be closed. As already explained, this has the consequence that the voltage supplied by the DC voltage source 4 at the connection points 17, 18 of the electrical device 2 is present. Due to the connected charging device, however, the electrical device 2 is now not powered by the DC voltage source 4 supplied, but instead the

DC voltage source 4 charged by the charging device via the electrical device 2. This takes place directly via the described electrical connection of the voltage supply unit 1 and the electrical device 2. If the charging device is removed from the electrical device 2 again, this has the consequence that the on / off switch 22 opens and thereby the connection of the voltage-carrying pole 6 the DC voltage source 4 and the positive connection point 12 is interrupted again.

Furthermore, it is possible that the charging device which can be connected to the electrical device 2 is provided not only for charging the DC voltage source 4 of the voltage supply unit 1, but also for the voltage supply of the electrical device 2 itself. In this case, the user can do this with the charging device plugged in Operate electrical device 2 simultaneously using the on / off switch 21. The functions of the two on / off switches 21, 22 overlap. As long as one of the two on / off switches 21, 22 is in its closed state, the switch 10 is closed and thus the voltage-carrying pole 6 of the DC voltage source 4 is connected to the positive connection point 12 of the voltage supply unit 1. The electrical device can thus be operated and charged at the same time until both on / off switches 21, 22 are open again.

If the relay 9 and the transistor 13 in the voltage supply unit 1 are combined to form an imaginary generalized switching device 23, the result is an electrical circuit 5 which essentially only consists of this between the live pole 6 and the positive connection point 12 Switched switching device 23, a control line 24 connecting the switching device 23 to the control connection point 14 and the described connection of the live pole 6 via the resistor 15 to the control connection point 16. In this generalized electrical circuit 5, the switching device 23 can also consist of a thyristor, a power transistor or the like.

2, the electrical device 2 has an electrical circuit 25, which limits the current flowing into the electrical device 2. The connection point 17 is connected to a current measuring device 26, in particular a shunt or the like, at the output 27 of which a signal is available which represents the current actually flowing into the electrical device 2. This value is compared with a target value 29 using a comparison device 28. The output of the comparison device 28 acts on a switch 30 which is connected between the control connection point 19 and the two on / off switches 21, 22.

If the current actually flowing into the electrical device 2 is smaller than the desired value, the switch 30 remains in its idle state, that is to say in its closed state. This has the consequence that the switch 30 connected between the control connection point 19 and the two on / off switches 21, 22 has no effect, and the mode of operation described with reference to FIG. 1 is therefore given.

However, if the current actually flowing into the electrical device 2 exceeds the predetermined target value, this has the consequence that the switch 30 is opened by the comparison device 28. The current flow over the switch 30 is thereby interrupted, so that the transistor 13 blocks in the voltage supply unit 1. This has the consequence that the relay 9 drops out and thus the live pole 6 is separated from the positive connection point 12 of the voltage supply unit 1. There is therefore no voltage at the electrical device 2 and no more current can flow.

With the help of a timer or the like, the switch 30 can be closed again after the current flow has been interrupted, so that the operation of the electrical device 2 can be continued.

It is also possible to use time switches or the like to interrupt the flow of current via the switch 30 only when the current actually flowing into the electrical device 2 exceeds the predetermined target value for a certain period of time. In this way, current peaks and the like cannot lead to an immediate power cut-off.

Another possibility is that the setpoint can be changed variably. The setpoint can be adapted to the current power requirement of the electrical device. For example, the target value can be increased in a portable computer when, for example, the hard disk is active. Accordingly, it is possible to lower the setpoint if, for example, the screen is switched off. In this way, it is possible to specify a setpoint at any time, which represents the actual current requirement of the electrical device 2, so that exceeding the setpoint is a sure sign of a malfunction in any case and thus an interruption in the flow of electricity is justified.

As described, the electrical circuit 25 shown in FIG. 2 is accommodated in the electrical device 2. In this way it is possible, for example in the case of a portable computer, to have the comparison device 30 and, above all, the variable setpoint specification carried out directly by the processor of the portable computer. Deviating from this, however, it is also possible for the entire electrical circuit 25 or at least components thereof to be accommodated not in the electrical device 2 but in the voltage supply unit 1. This can then make further electrical connection between the voltage supply unit 1 and the electrical device 2 necessary.

Claims

PATENT CLAIMS

1. Electrical circuit (5) for one in a housing

(3) accommodated electrical direct voltage source (4), in particular a battery, an accumulator, or the like,

characterized,

that one of the poles (6, 7) of the DC voltage source

(4) is led out of the housing (3) via a switching device (23), the switching device (23) being controllable from outside the housing (3).

2. Electrical circuit (5) according to claim 1,

characterized,

that to control the switching device (23) on the one hand the live pole (6)

DC voltage source (4) is led out of the housing (3) via a resistor (15) and on the other hand a control line (24) connected to the switching device (23).

3. Electrical circuit (5) according to claim 1 or claim 2,

characterized,

that a relay (9), a thyristor, or the like is provided as the switching device (23).

4. Electrical circuit (5) according to claim 3,

characterized,

that a transistor (13) is provided for driving the switching device (23).

5. Electrical circuit according to claim 4,

characterized,

that the base of the transistor (13) is connected to the control line (24) led out of the housing (3), that the emitter of the transistor (13) is connected to the ground pole (7) of the DC voltage source (4), that the coil ( 11) of the relay (9) is connected on the one hand to the collector of the transistor (13) and on the other hand to the live pole (6) of the direct voltage source (4), and that by means of the coil (11) one with the live pole (6 ) the DC voltage source (4) connected switch (10) can be switched on and off.

6. Power supply unit (1) for an electrical device (2), in particular for a mobile electrical device, with an electrical DC voltage source (4) accommodated in a housing (3),

marked by

an electrical circuit (5) according to one of claims 1-5.

7. Electrical device (2), preferably a portable computer, marked by

a connectable voltage supply unit (1) according to claim 6.

8. Electrical device (2) according to claim 7,

characterized,

that an on / off switch (21) which can be operated by the user is provided for controlling the switching device (23).

9. Electrical device (2) according to claim 7 or claim 8,

characterized,

that an on / off switch (22) controllable by the device (2) is provided for controlling the switching device (23).

10. Electrical device (2) according to one of claims 7-9,

characterized,

that means (26, 28, 30) are provided for measuring the current actually flowing into the device, for comparing the current with a desired value and for controlling the switching device (23) as a function thereof.