WO2010094548A1

WO2010094548A1 - Electrical protection device and control method of the electrical protection device

Info

Publication number: WO2010094548A1
Application number: PCT/EP2010/051137
Authority: WO
Inventors: Thomas Rothmayer; Harald Schweigert
Original assignee: Siemens Aktiengesellschaft
Priority date: 2009-02-18
Filing date: 2010-02-01
Publication date: 2010-08-26
Also published as: AT507083B1; CN102326309B; CN102326309A; EP2399327A1; AT507083A4

Abstract

The invention relates to an electrical protection device (SCH) for arrangement between at least one load (V1, V2) and a power supply, wherein said protection device (SCH) comprises a current limiting function and a switch-off function. The protection device (SCH) is composed of several current-limiting or switching-off protection elements (E1... En), the outputs of which are connected in parallel. The invention further relates to a control method of the electrical protection device (SCH).

Description

Electrical protective device and control method of the electrical protective device

description

The invention relates to an electrical protective device for the arrangement between at least one consumer and a power supply, wherein this protective device has a Strombegrezungs- and a shutdown function. Furthermore, the invention relates to a control method of the electrical protective device.

Electrical protective devices are used wherever accidents within an electrical system can endanger people and / or machines. In particular, in the supply of a consumer or more consumers by means of a power supply, it requires an electrical protection device. This is arranged between the power supply and the consumer (s) to reduce the current through the consumer (s) in the event of a fault and to shut it off if the fault persists.

Especially with power supplies to supply multiple load branches, it makes sense to secure each load branch with an electrical protective device. If a fault occurs in a load branch, it is current-limited or switched off, without jeopardizing the supply of the remaining load branches. Without such a protective device, a faulty load branch loads the power supply beyond the intended load current. The power supply, in particular a switched-mode power supply, then optionally transitions itself into a current-limiting mode and switches off when the fault persists. All load branches are then de-energized. The same thing happens when the loads at the output of the

Power supply are each protected by means of an upstream, mechanical circuit breaker, as a such a significant overcurrent needed to trigger. This overcurrent can often no longer supply the power supply in addition to the supply of the remaining loads.

The type of application of the generic electrical protective devices entails that they must be present with different current limit values specified as tripping limits. In particular, in industrial plants, it is the rule that several load branches of different power are supplied by means of a power supply. Each load branch thus comprises an electrical protection device with a respective different current limit value. It also happens in industrial plants that there is only one load branch which, as a result of changed production conditions, comprises once more and once fewer consumers. Even in such a case, electrical protective devices with different current limits must be used.

From WO 01/41277 A2 and EP 0933849 Al is known, for example, an electrical protective device for power supplies with multiple load branches. It is for each load branch in the connecting line between the power supply and the load, a semiconductor switch with adjustment, a current measuring element and a Auswertebzw. Control electronics switched in the form of operational amplifiers. The performance of each semiconductor switch is designed for a defined nominal current. When smaller consumers are connected, the tripping limit is set to a lower value than this rated current. This often leads to the undesirable case that the performance of the respective semiconductor switch and the respective drive circuit is not utilized. Such a solution thus usually leads to an oversizing of the electrical

Guard with a poor cost-benefit ratio. Therefore, according to the prior art, electrical protective devices are known which are provided for individual load branches. This overdimensioning is prevented by product lines are offered with fine rated current gradations. In each load branch thus the corresponding electrical protection device is switched with the required rated current. The disadvantage here is a required high storage costs.

Another known electrical protection provides that in each load branch a step-down converter is arranged, which switches through in normal operation and only in case of failure in a current limiting mode. AT 504 528 A describes such a solution.

The invention has for its object to provide an improvement over the prior art for an electrical protective device of the type mentioned.

According to the invention, this object is achieved by the independent claims 1 and 9 and by advantageous developments according to the subclaims.

In this case, the protective device is formed from a plurality of current-limiting or disconnecting protective elements, the outputs of which are connected in parallel. In this way, a simple measure is specified to secure a load branch or multiple load branches with the respective required current limit. The respective current limit results from the sum of the partial current limits of the protective elements connected in parallel on the output side.

In this case, a protective device according to the invention comprises, for example, a selectable number of protective elements which, in total, necessitate the load required for a connected load Provide protection without being over-dimensioned. It is also possible to subdivide the protective device into several protective device blocks in order to create a number of separate, parallel safety channels for different loads or load branches in this way. Different levels of protection elements are connected together on the output side for different loads. The respective interconnected protective elements form a block with the required protection protection for each connected load.

The corresponding control method provides that a protective element, upon reaching an assigned predetermined partial current limit value, limits the current through the protective element until a critical parameter of the protective element exceeds a predetermined maximum value and shuts off the protective element. The load current through the protective elements connected in parallel thus always divides in normal operation so that none of the protective elements flows a current greater than the partial current limit value. Upon reaching a partial current limit of a protective element, the current is reduced by this protective element. To the same extent, the current increases through the other protective elements connected in parallel with this protective element. In this way, tolerances of the individual protection elements are compensated.

An advantageous embodiment of the invention provides that each protective element has a fixed partial current limit, so that the protective elements are simple in construction and therefore inexpensive to manufacture.

It is advantageous if a current limit value of the protective device or of a protective device block is formed as the sum of equally large partial current limit values of the parallel-connected protective elements. Thus, by means of identical protective elements different protective devices or protective device blocks can be selected graded current limits. With only one protective element design, load branches with a wide variety of powers can be protected without overdimensioning the protective device.

A simple embodiment is carried out in such a way that the protective elements of the protective device are connected on the output side by means of a connecting comb. A complex wiring in a control box is thus eliminated.

Advantageously, the connecting comb is soldered to the outputs of the protective elements, so that a secure and predictable contact between the individual outputs of the protective elements is given.

Furthermore, it is advantageous if the connecting comb between the protective elements has at least one manually separable separation point, in particular a predetermined breaking point. The protective device comprises a preselectable number of protective elements, which are already connected on the output side. As part of an installation, the protective device is divided into several as needed

Splits guard blocks by breaking one or more connections between any two protection elements. Each of the resulting protector blocks comprises the number of protective elements required to protect a connected load branch.

In a favorable variant of the connecting comb between the protective elements in each case a bulky shaped separator, which is manually herausschennbar from the comb. The separator is released to separate the comb, the bulky shape causing the separator to not accidentally fall through vents in a nearby device housing. In addition, it is favorable to provide below a separation point or a separating piece a mark indicating a comb separation by the mark is visible after a separation process.

Another embodiment provides that the protective device is installed in the power supply. This simplifies the installation, especially in a control box.

In one embodiment of the invention, each protective element comprises a drive unit and a current limiting element with a variable volume resistance. In this case, the volume resistance is determined by means of the drive unit as a function of the current flowing through the current limiting element current. The control then takes place, for example, in the form that the passage channel of a protection element that has arrived at the partial flow limit value becomes slightly higher impedance. In this case, the abregelde protective element builds only so much more resistance that the tolerances of the protective elements are compensated.

In a further development of the control method it is provided that the voltage is detected at each output of a protection element and that upon reaching a predetermined voltage drop value, the protection element concerned limits the current through the protection element for a predetermined limitation period and that the protection element switches off after a lapse of the limitation period. A timer is thus started only after a clear drop in the voltage at the output of all parallel-connected protection elements, so that minor disturbances or an uneven distribution of the load current does not lead to shutdown.

It is also advantageous if after a shutdown all protection elements are reset as soon as possible a predetermined switch-off period has elapsed and / or a critical parameter of the respective protective element falls below a predetermined switch-on value. For example, all timers are reset, so that all protection elements, regardless of the current switching state again assume the same initial state. As a result, any protective element outputs can be interconnected and reactivated via a common reset.

As a critical parameter is conveniently a

Chip temperature of the respective protective element detected. In this way, it is ensured that the protective device or a relevant protector block only turns off when the thermal load due to a Abregelvorgangs is too large.

The invention will now be described by way of example with reference to the accompanying drawings. In a schematic representation:

Fig. 1 circuit construction of a protective device with two consumer branches

Fig. 2 connecting comb with separation points

In Fig. 1 is a protective device SCH with several

Protective elements El ... En shown. In this case, the first three protective elements El, E2, E3 to a first

Protective device block BIl and the remaining protective elements E4 ... En combined to form a second protective device block B12. A first consumer or consumer branch V1 is connected to the first protective device block BI1 and a second consumer or consumer branch V2 is connected via the second protective device block B12 to a supply voltage U of a power supply.

Each protective element El ... En comprises a current limiting element Tl ... Tn and a Current detection unit II ... In. The respective current limiting element Tl... Tn is designed, for example, as a transistor and the respective current detection unit II... In is designed as a current transformer. By means of a respective control unit Al ... An, the current flow through the current limiting element Tl ... Tn is controlled as a function of the respectively detected current. Each drive unit Al ... An is a partial current limit specified. The partial current limit values of the protection elements El, E2, E3 and E4... En which are connected on the output side in total produce the current limit value of the respective block BI1 or B12. The control units Al ... An are either constructed analogously or designed as a microcontroller.

Each current limiting element Tl ... Tn is another

Fuse Sl ... Sn upstream for fire protection reasons. This is either a fuse or a circuit breaker.

The functioning of the protective device SCH is explained with reference to the first protective device block BI1. The consumer or consumer branch Vl is connected to an output terminal KIl of the block BIl. The other two output terminals K12, K13 remain free when the output side connection is made by means of a connecting comb Ka. At this time, a first connection comb portion KaI connects the outputs of the first block BI1 and a second connection comb portion Ka2 connects the outputs of the second block B12. Alternatively, an output-side connection via the corresponding terminals KIl, K12, K13 or K14 ... Kln done by wire bridges.

In the case of a connection by means of connection comb Ka, each output terminal KIl ... KIn must be designed for the maximum possible current limit value. In normal operation, the load current drawn by the consumer or load branch V 1 will not reach the current limit value of the block BI 1. The load current then divides according to the volume resistances on the three protective elements El, E2, E3. Tolerances can lead to a protective element El or E2 or E3 reaching its partial current limit value. The respective control unit A1 or A2 or A3 then regulates the current flowing through this protective element E1 or E2 or E3, so that correspondingly more current flows through the other two protective elements E1, E2 or E2, E3 or E1, E3 , In order to use the maximum available performance of the current limiting elements Tl, T2, T3 in such a different power distribution of the individual protection elements El, E2, E3, the chip temperature of the respective current limiting element Tl, T2, T3 is used. If the maximum chip temperature of a protective element El or E2 or E3 is reached, this switches off. As a result, the protective elements El, E2 or E2, E3 or El, E3 connected in parallel must assume the overload. If the maximum permissible chip temperature is exceeded, these also switch off.

As an alternative to chip temperature sensing, overloads are allowed only for a predetermined period of time. In this case, a timer can only be started after a clear drop in the voltage at the output of the parallel-connected protection units El, E2, E3. In this case, a sequential sampling of the individual protective element output voltages is to be carried out by means of a higher-level control unit, since this control unit is not aware of which protective units El ... En are connected in parallel. From the output voltages is closed to the thermal load of the current limiting elements Tl, T2, T3.

Only after that, after expiry of a defined active limitation time, during which the load voltage is already actively reduced, the respective block BI1 is switched off, for example by means of the higher-level control unit to the Control units Al, A2, A3 a shutdown signal is transmitted. During a subsequent switch-on process, cooling-down times to limit the component temperatures must be taken into account. In this case, for example, reset all timers by means of a manually triggered reset. The reset is disabled until either a predetermined switch-off time has expired or a critical parameter falls below a specified switch-on value.

A further embodiment provides that the voltage drop is detected at the respective current limiting element T2, T2, T3.

When specifying certain time periods for a current limitation, the ambient temperature can additionally be detected. At lower ambient temperatures, the permissible load duration is extended. When detecting the respective chip temperature, however, the ambient temperature is already taken into account.

For a secure and calculable connection at the outputs of the protective elements El ... En, it is useful to provide a connecting comb Ka. Such is shown in Fig. 2 and is electrically connected by means of appropriate connections with the outputs of the protective elements (El ... En). Conveniently, this is done by soldering appropriate Lötfahnen in a printed circuit board LP. Each solder tag is connected to a protective element output. With such a connection comb Ka between the individual protective elements El ... En correspondingly large cable cross-sections, so that a large number of protective elements El ... En can be connected in parallel. In addition, the installation effort is reduced significantly, especially when between the protective elements El ... En manually separable separation points Br are provided, preferably designed as predetermined breaking points. According to the consumers or consumer branches Vl, V2, the connecting comb Ka is interrupted at such a separating point Br, so that the connecting comb Ka is divided into a plurality of connecting comb sections KaI, Ka2.

For this purpose, the connecting comb Ka, for example, separators TS, which allow to initiate a torque in the region of the separation points Br. As a result of repeated twisting of the relevant separating piece TS, cold work hardening occurs in the region of these separating points Br and, as a consequence, a desired break occurs on both sides of the separating piece TS. It is also possible to carry out the separators TS only as detachable parts. It must be ensured in every case that the separators TS have an appropriate size, so that they do not accidentally fall through louvers of a device housing. This can be achieved in that the separators TS are formed in comparison to the other line cross-section either as a larger flat parts or as larger curved parts. The connecting comb Ka can also cover a colored mark. This is released when breaking out of a separator TS to clearly indicate which protective elements El ... En connected or separated from each other.

In such an embodiment, it must be ensured that the connecting comb is only accessible when the

Protective device is voltage-free. For this purpose, for example, provide a cover that can only be opened when the protection device is switched off. As an alternative, the connecting comb is made partially insulated.

Claims

claims

1. Electrical protection device (SCH) for the arrangement between at least one consumer (Vl, V2) and a power supply, said protective device (SCH) a

Strombegrezungs- and a shutdown has, characterized in that the protective device (SCH) of a plurality of current-limiting or disconnecting protective elements (El ... En) is formed, whose outputs are connected in parallel.

2. Electrical protective device according to claim 1, characterized in that each protective element (El ... En) has a fixed partial current limit.

3. Electrical protection device according to claim 1 or 2, characterized in that a current limit value of the protective device (SCH) or a protective device block (BIl, B12) is formed as the sum of equal partial flow limits of the parallel-connected protective elements (El ... En).

4. Electrical protection device according to one of claims 1 to 3, characterized in that the protective elements

(El ... En) of the protective device (SCH) are connected on the output side by means of a connecting comb (Ka).

5. Electrical protection device according to claim 4, characterized in that the connecting comb (Ka) with the outputs of the protective elements (El ... En) is soldered.

6. Electrical protection device according to claim 4 or 5, characterized in that the connecting comb (Ka) between the protective elements (El ... En) each having at least one manually separable separation point (Br).

7. Electric scuffing device according to claim 6, characterized in that it is not possible for the connecting comb to intervene Protective elements (El ... En) each having a bulky shaped separator, which is manually herausschennbar from the connecting comb.

8. Electrical protection device according to claim 6 or 7, characterized in that below a separation point or a separator, a mark is attached, indicating a comb separation.

9. Electrical protection device according to one of claims 1 to 8, characterized in that the protective device (SCH) is installed in the power supply.

10. Electrical protective device according to one of claims 1 to 9, characterized in that each protective element

(El ... En) comprises a drive unit (Al ... A2) and a current limiting element (Tl ... Tn) with a variable volume resistance and that the volume resistance by means of the drive unit (Al ... An) depending on the

Current limiting element (Tl ... Tn) flowing current is determined.

11. Control method of an electrical protective device according to one of claims 1 to 10, characterized in that a protective element (El ... En) upon reaching an assigned predetermined partial current limit, the current through the protective element (El ... En) limited to a critical Parameter of the protective element (El ... En) exceeds a predetermined maximum value and the protective element (El ... En) turns off.

12. Control method according to claim 11, characterized in that at each output of a protective element (El ... En) the voltage is detected and that upon reaching a predetermined voltage drop value, the protection element in question (El ... En) the current through the protective element (El ... En) limited for a predetermined limitation period and that the protection element (El ... En) shuts off after a lapse of the limitation period.

13. Control method according to claim 11 or 12, characterized in that after a shutdown all protective elements (El ... En) are reset as soon as a predetermined switch-off has expired and / or a critical parameter of the respective protective element (El ... En) falls below a predetermined switch-on value.

14. Control method according to claim 11 or 13, characterized in that a chip temperature of the respective protective element (El ... En) is detected as a critical parameter.