EP2025049B1 - Over-current protection device with additional mechanical trip, preferably implemented as a trip bolt, for use in over-voltage protection devices - Google Patents

Description

The invention relates to an overcurrent protection device for use in surge protection devices with additional mechanical release, preferably designed as a firing pin, according to the preamble of patent claim 1.

Overvoltage protection devices are used in electrical and information technology networks to protect equipment, consumers and end devices.

Such overvoltage protection devices limit especially in transient overvoltage events, e.g. Lightning events, the voltage to uncritical values.

The limitation occurs in case of overvoltage events by the derivation of pulse currents in the transverse path and thus generally parallel to the load terminals.

As overvoltage protection elements inter alia spark gaps, varistors, suppressor diodes, gas arresters, capacitors and non-linear resistors and their combinations are used.

The above-mentioned elements generally have a nonlinear response or a non-linear characteristic.

With frequent response of these elements or overload due to excessively high or too long overvoltages or currents may lead to gradual aging or destruction of the surge protective devices.

In the usually staggered arrangement of surge arresters with different performance and / or different levels of surge protection, the risk of overload can increase even with originally correct dimensioning and coordination of the surge arrester due to aging or due to changes in the system.

An overload of such coordinated devices, often with different principles of action, can lead to unwanted and sometimes the entire plant hazardous damage.

The causes of overload are manifold and specific to the respective protection device.

In a varistor mentioned by way of example, destruction may occur during gradual aging due to very small leakage currents over a longer period of time. When Protection against such loads are therefore used in many cases thermal separation devices.

By means of thermal cut-off devices, sufficient protection can usually be achieved within their switching capacity at small leakage currents in the range of mA to several A and in the low-voltage range of the varistor.

If the varistor is loaded with pulse currents above its capacity or with extremely high current and voltage gradients, the varistor can be blown over or over.
When exposed to long-lasting transient or power-frequency overvoltages, however, thermal breakdown or breakdown of the varistor may occur after a time course of a few tens of ms.

The latter errors can not be controlled by known thermal separation devices, since their response time is usually several seconds.

For the above reason, it is therefore common practice to operate varistors in series with a conventional electrical fuse or switching devices.

The manufacturers of varistor discs often give the maximum rated current value of such back-up fuses for sufficient protection. Conventional fuses generally respond well below their theoretical adiabatic melting integral value at momentum load.

At short but high pulse currents, with which the varistors are loaded, however, the load limit of the varistors is already well above the theoretical value of the fuses and thus far beyond the practical maximum values of these.

This means that pulse values which the varistors divert several times without problems can lead to the destruction of the fuse even at a single load, which is the maximum permissible for the protection of the varistor disk according to its manufacturer's instructions.

In order to make the most possible use of the performance of the varistor disc, manufacturers of surge protective devices therefore often recommend larger fuses. However, this can lead to significant damage to the equipment in the event of a fault due to the higher I ² t load that occurs as a result of too late tripping.

In addition to the protective function of the overvoltage protection element, the response the fuse often used as a display criterion for the overload and the separation of the overvoltage protection element.

For this purpose, the power interruption or the increased voltage drop across the fuse is evaluated.
In addition to the optical display, the electrical signal is also used for acoustic displays or the opening and closing of switches for remote signaling. However, the use of electrical energy for signal delivery has several disadvantages. Many displays require energy and cause unwanted leakage currents. Shutdown on surge current loads of fuses is often undefined and unwanted.
The fusible link of fuses can have a variety of damage after the pulse load, which can lead from the separation of individual parallel bottlenecks to the total destruction of the fusible conductor, without a desired high-impedance interruption occurs.

Due to the above explanations, currents in the mA or also in the A range are still possible without the display function indicating the defect of the device. This can lead to considerable damage in the event of a renewed overvoltage event despite the control of the system.

The cause of the described behavior lies in the different functioning of the fuse in the case of mains-frequency fault currents in the longitudinal branch and in the case of pulse currents in the shunt branch.

In the case of a mains-frequency current increase in the longitudinal branch, which leads to the activation of the fuse, the fuse interruption represents the single most point of interruption and the dielectric strength of the tripped fuse must be higher than the mains voltage.
This leads to a high-impedance and quite long separation distance within the fuse.

In the shunt branch, on the other hand, the mains voltage resistance is generally taken over by the surge protection device, even with moderate overloads. That is, the fuse is not necessarily burdened with the mains voltage even after their response. This sometimes leads to an undefined separation distance within the fuse.

On the other hand, pulse currents often lead to a considerable mechanical stress on the fusible conductor and to a very different current distribution in the usually parallel bottlenecks of the fusible conductor. This is what happens often for the partial destruction of the fusible conductor. If the energy content of the pulse is just barely enough to melt the fusible conductor continuously in all bottleneck areas, this does not necessarily lead to a high-impedance separation point. The melted melt remnants and the surrounding filler often lead to a still conductive connection with a resistance of a few kOhms. This may well lead to a false display of a conventional electrical energy based device. In addition to a false indication of the arrester state, this can lead to the destruction of the surge arrester and / or the fuse at renewed impulse load. In addition, the consumer is at risk because of a defective overvoltage protection. The endangerment of the consumer is greatly increased, in particular in those cases in which so-called combination arresters are used. In these devices, the overvoltage protection is often implemented in only one device, ie the usual staggering of different performance surge arresters with different levels of protection and simultaneously redundant effect deleted.

The DE 199 14 313 A1 shows the protection of a so-called starting aid of a spark gap. In this case, fuses or reversible fuses are used. The melting of the fuse is used with the aid of electronic circuits for optical, acoustic and / or electronic display. After the fuse has responded, the spark gap should be able to exert a redundant protective function with an increased protection level without an ignition aid. Derivation of a display function from the shutdown behavior of fuses is beyond the EP 1 345247 , of the DE 38 31 935 , of the DE 197 51 470 or for example the DE 32 28 471 previously known.

The U.S. Patent 6,157,529 discloses the interruption of a circuit by means of the disconnection of a fuse and a holding coil of a switch.

Ignition aids, as in the DE 199 14 313 A1 described, are also used in combination arresters. With these arresters, the starting aid itself can be designed as an independent overvoltage protection device, which activates the short-circuit element, generally a spark gap, only at the risk of its own overload via a trigger function. A combination arrester is for example in the DE 198 38 776 C2 disclosed.

From the foregoing, it is therefore an object of the invention to provide an advanced overcurrent protection device for use in surge protection devices with additional mechanical release, preferably designed as a firing pin, indicate which has a high age-stable momentum current carrying capacity, a mechanical display function or support such a display and signal function and a high switching capacity.

In addition, the specified overcurrent protection device should have a small size, easy to install and have a high peak current stability and a high switching voltage.

The object of the invention is achieved by an overcurrent protection device according to the combination of features according to claim 1, wherein the dependent claims represent at least expedient refinements and developments.

According to the invention therefore a combination of functional units is provided. This combination includes a fuse suitable for pulse currents with parallel indicator fuse, which takes over a firing pin function. The firing pin can serve for the mechanical triggering of an optical and / or electrical display. The firing pin and the signal function can be carried out floating or floating.

The pulse current carrying capacity of the actual fuse is brought close to the theoretical, ie the material-specific melt integral value (I ² t value) of the fuse conductor. As a result, an otherwise usual over-dimensioning of the fuse can be avoided. This is necessary in the prior art, since the usual fusible conductors are already overloaded significantly below the theoretical I ² t value due to the dynamic current forces, the asymmetrical current distribution and the aging at pulse currents. The reason for this is the geometry of the fusible conductor, the type of contacting of the fusible conductor, the current conduction to and in the fusible conductor, the fusible conductor fixation and additives which cause aging or premature overloading.

The small design created by the invention is in the range of conventional device protection measures of substantially 5x20 mm. Such small devices can be mounted in a particularly simple manner on a circuit board, as an SMD component.

According to the invention, it is possible to use the presented overcurrent protection device for the trigger circuit of combination arresters

The overcurrent protection device comprises a first functional unit containing the mechanical release. This first functional unit has a first Melting on.

A second functional unit is designed as actual overload protection and has a second melting element.

Each of the functional units is arranged in a housing, wherein on the respective housing lateral, opposite end caps are befindlich and the fusible elements are each arranged inside the housing and are electrically connected to the end caps.

The first and the second functional unit are electrically connected in parallel. This parallel circuit is in series with the surge protection device.

The functional units form a common mechanical composite, each housing being surrounded by a separate or both housing by a common elastic jacket.

The end caps of each side of the respective functional unit are connected electrically and mechanically connected in a connection extension, which allows or facilitates the already mentioned PCB assembly of the overall direction.

On a closing cap of the first functional unit, a chamber for receiving a spring-biased firing pin is arranged, wherein the firing pin is held by the first melting element in its rest position. With the melting of the first melting element, the spring biasing force comes into effect and the firing pin moves to its maximum achievable end position.

The first fusible element consists of a wire which has a high tensile strength and an I ² t value, which is significantly lower than that of the material of the second fusible element.

The housing of the first functional unit forms an arc switching chamber, which consists of a tubular body, which laterally adjoins a cavity which forms the chamber for receiving the firing pin.

Between the arc switching chamber and the cavity, one or more insulating plates are arranged, through which or which the first melting element is passed.

The arc switch room is filled with an extinguishing agent.

The cavity with the firing pin is limited by a Stülpkappe, wherein the side facing away from the arc combustion chamber side of the Stülpkappe forms a stop for the striking plate of the firing pin and thus a route limitation.

The impact plate itself can be surrounded by an insulating cap.

The striking plate is designed as a punch or striker, the Displacement can be limited by a stop and a recess within a hood cap.

The first fusible element may be composed of a composite material and have at least one constriction and / or a portion of different impedance or resistance.

The second functional unit has a hollow cylindrical housing with lateral end caps, wherein the second melting element is guided as a band, wire or in a hollow cylindrical shape from cap to cap.

It should be noted at this point that also the housing of the first functional unit may have the form of a pipe or a hollow cylinder.

The wire or hollow cylindrical melting element of the second functional unit is connected by force and / or positive connection with the inner sides or with corresponding openings in or on the caps.

The hollow cylinder of the second melting element may have defined bottlenecks and / or tapers.

Also, the housing of the second functional unit has a filling. This filling can consist of a high-density bulk material or contain compressible materials.

In the embodiment of the second fusible element as a band, this band consists of flat wire with a width to thickness ratio less than 4: 1.

The second fusible element can be held by guide bars, guide rings or the like located in the housing.

Both the first and the second functional unit may be surrounded by a common outer housing or arranged in such a housing.

The invention will be explained below with reference to an embodiment and with the aid of figures.

Hereby show:

Fig. 1 a schematic representation of the electrical arrangement of the overcurrent protection device;

Fig. 2 a side view of a variant of the overcurrent protection device in electrical and geometric parallel connection;

Fig. 3 a sectional view through a preferred embodiment of the first functional unit;

Fig. 4a to 4c Further embodiments of the functional unit with variants of Firing pin design;

Fig. 5 Variants for changing the fuse impedance of the first functional unit;

Fig. 6 the arrangement of a resistance material in the arc switching room of the first functional unit;

Fig. 7 the basic structure of the second functional unit with security tape or security wire;

Fig. 8 a sectional view of the embodiment similar to the Fig. 7 , but with guide bars;

Fig. 9 a sectional view of a combination of the two functional units with recognizable internal structure;

Fig. 10 a further variant of the combination of the functional units with a changed internal power supply between the first and second functional unit;

Fig. 11 and 12 alternative arrangements for attachment of the functional units and

Fig. 13 Section view of the possibility of execution of the first functional unit, which is separate from the second functional unit such as after Fig. 11 or 12 can be arranged on a printed circuit board in electrical parallel connection, but not in the geometric composite.

Fig. 1 shows a schematic representation of the invention. The device A according to the invention consists of two functional units. A functional unit A1 assumes the overload protection for the overvoltage element B and forms the actual overcurrent protection device. A further functional unit A2 realizes, after the functional unit A1 has responded, the mechanical display and signal function with the aid of a firing pin which is preferably used.

The presented overcurrent protection device for overvoltage protection devices preferably consists of an electrically as well as geometrically, i. spatially arranged in parallel fixed composite of two functional units 1 and 2.

The electrical contacting is preferably carried out together via PCB contactable terminals 6, which can serve at the same time for the mechanical joining of the parallel functional units 1 and 2.

The in the Fig. 2 shown terminals 6 may have a taper, whereby the position of the firing pin relative to the board (not shown) is clearly definable.

By the connection of the two functional units 1; 2 becomes one created easy to install solution while supporting the claim of a small size. Like from the Fig. 2 can be seen, the functional units 1 and 2 are superimposed.

With a corresponding bending of the terminals 6, the two connected functional units can also occupy a parallel to the printed circuit board, not shown, or any angular position.

Each functional unit 1; 2 is enveloped or surrounded by an elastic jacket 4 on the circumference and by common lateral connection caps 3 and is thereby mechanically stabilized and fixed.

The elastic sheath 4 can in a simple form as a tube or shrink tube with or without tissue elements, but also as a second tube, e.g. be made of an elastic plastic material.

The above measures and the fixation on the circuit board lead to an increase in the switching capacity of the functional units.

The first functional unit 1 realizes the desired mechanical display function by means of a firing pin or a firing pin plate 5 and the generation of a high switching voltage.

The second functional unit 2 takes over the other tasks already mentioned.

Due to the appropriate separation into functional units, a high switching capacity and a functionally reliable firing pin release can be realized despite small dimensions with a high I ² t value of the unit.

The first functional unit 1 includes a mechanism for triggering the firing pin.

By the firing pin can be exercised at a distance to a maximum of half the total length of the functional unit, a defined force on a triggering system or a display device.

The height of the transmittable force can be variably adjusted and specified from approximately 1 N to several 10 N at a defined distance.

In a preferred embodiment, prestressed compression springs are used for this purpose. Of course, the firing pin itself can be used as a visual display in an analogous manner to a simple conventional indicator.

As an alternative to the above-mentioned spring, gas generators or priming charges for the firing pin function can also be provided.

When using a spring, the necessary high and aging stable Preload realized with wire, which has a high tensile strength. The I ² t value of the wire is adjusted so that it is significantly smaller than the I ² t value of the second functional unit. A value of less than 1% is preferred. The meter resistance of the wire, however, is significantly higher than that in the second functional unit. Preferably, larger ratios than 1: 100 are used. In addition, the wire may be wound on a carrier to provide additional impedance.

By the above vote is achieved that the wire of the first functional unit remains almost unloaded under pulse load. In the event of a fault, ie the interruption of the current conduction in the second functional unit, the fusible conductor is also almost distortion-free interrupted by a current which is a multiple of its current carrying capacity. This is also the case with errors due to line frequency currents. Overload factors of approximately 20 to 1000 are preferred. These factors guarantee adiabatic heating of the wire and a so-called strip decay of the fusible conductor.
This strip decay leads to a high switching voltage. The height of this tension can be influenced by the geometric design and the choice of material of the wire. The level of the switching voltage is also determined by the error case and the impedance ratios of the feeder circuit.
In trigger aids, which often include a pulse transformer, the generated arc voltage can be increased due to the increase in the inductance of the circuit.

With suitable tuning, switching voltages of a few 100 V up to several kV can be generated even with small dimensions of the functional units. These voltages are generally sufficient to ignite in particular spark gaps with Gleitentladungsstrecken.

Fig. 3 shows a preferred construction of the first functional unit.

In this illustration, not the elastic sheath 4 and not the formation of the common caps 3 is shown. The functional unit 1 consists of an arc switching chamber 17 and a cavity 16, which serves to receive the firing pin 5. The arc switch chamber 17 and the cavity 16 are adjacent to each other on a common axis.

The arc switch chamber 17 is bounded by a fixed tube 7, for example made of ceramic, and the caps 8 and 9. The fuse element 11 arranged in the interior is led through the arc switching chamber 17 and the cavity 16 to the firing pin 5.
For this purpose, a hole is provided in the cap 9.
For better foreclosure of the arc switching chamber 17, one or two insulating plates 10 are provided. The platelets 10 are preferably made of an elastic and arc-resistant insulating material. This allows easy piercing of the material and close nestling against the fusible conductor 11, whereby an undesirable gap between platelets and fusible conductor can be avoided.

The arc switch room can be equipped with an extinguishing agent 15, e.g. be filled from quartz sand material.

The cavity 16 is enclosed by a special terminal cap 9. The firing pin 5 has an outer shield, which has a larger dimension than the cavity 16. The firing pin 5 also has a bore through which the fusible conductor 11 is guided and fastened. In the cavity 16 is a prestressed spring 12, which serves to carry out the firing pin function.

The Fig. 4a to 4c show alternative design variants of the firing pin design.

According to Fig. 4a is the complete firing pin in the cavity of the cap. 9

According to Fig. 4b For example, an electrically conductive firing pin is covered by an additional cap 13 made of insulating material. As a result, the contact of the firing pin is carried out floating and the cap 13 serves as additional protection against leaking gases or dirt.

The execution of the firing pin after Fig. 4c is captive even without external stop.

The stroke and the end force of the firing pin are defined by the stop on the edge of the hood cap 21.

In this embodiment, it is very easy to use in addition to the spring force and the resulting pressure in the control room supportive. For this purpose, the plate 10 in front of the cavity of the cap 9 can be dispensed with. The seal to prevent the blowing out of plasma is determined by the design of the firing pin according to Fig. 4c self-realized. Such a design variant is also suitable for the realization of a pyrotechnic firing pin.

Particular importance is assigned to the insulating platelets 10. These plates 10 serve to seal the switching space, whereby leakage of ionized plasma is prevented. This plasma would not be in contrast to that are discharging behavior of the arrester and mean in the tight space conditions a hazard.

The insulated plate 10 also prevents a stable footing of the switching arc on the opposite terminal cap, whereby the switching capacity and thus the load of the first unit is reduced.

Instead of the platelets 10 also massive insulating materials can be used. Likewise, the entire implementation may consist of an insulating material. In this case, the power supply via the front hollow cylinder cap and the firing pin to the wire.

If only the inner area of the leadthrough is made of an insulating material, the current can be conducted via the spring to the wire, if the spring diameter is greater than the insulated area.

Other variants of the wire feedthrough can also be used for fastening the firing pin. Likewise, wire wire composite materials may be used for the wire.

Fig. 5 shows an embodiment with a multiple composite fusible conductor. This design variant has the advantage that the melt conductor evaporates only in the region of the bottleneck. This allows the arc region to be optimally positioned within the arc quenching chamber and reduces the risk of plasma spewing out.

As shown Fig. 5 In addition to the fuse impedance another impedance is connected, for example in the form of a resistor 22. This design variant has the advantage that the current can be limited until and after the melting of the fusible conductor. This results in a positive switching capacity.

As shown Fig. 6 a resistance material 20 is introduced into the arc switching space, at which the actual fusible conductor is contacted. As an alternative to introducing resistors or resistance materials, other impedances can also be used.

However, impedances can also already be arranged outside the functional unit, which is easily possible with separate functional units. But also in a composite according to Fig. 2 Such an arrangement of impedances can take place without effort. For this purpose, the cap material 8, 9 of the functional unit 1 consist of a resistance material. A common connection cap 3 can be above the current transition to the functional unit 2 of resistance material There may be measures or measures to increase the impedance, such as bottlenecks or meanders, in the connection area between the functional units 1 and 2 are arranged.

The reduction of the bias and the centering of the wire can be done by a Lötbefestigung in Durchfühmngsbereich. The feedthrough and the solder (e.g., low melting temperature, low volume) are selected so that the resulting arc detaches the attachment of the wire.

The wire can also be wound several times to distribute the force around the spring. The bolt can be made loose or captive. Likewise, electrically conductive versions of the bolt, but also isolated variants are possible.

Electrically conductive versions can be used in addition to the basic functions in addition to the transmission of electrical signals. In contrast, the isolated versions ensure a desired potential freedom of possible display means.

Fig. 7 shows an example of an embodiment variant of the second functional unit. This second functional unit implements the basic functions of the protection device.

To achieve a high momentum current carrying capacity, the following measures are used.
The attachment of the fusible conductor 30 is carried out only with a minimal use or waiving media that can cause aging of the fusible conductor, eg by oxidation or by diffusion in the normal state or when heated. Such negative media are solders, solders and other materials that tend to diffuse or react with the fusible link. This also applies to the filling medium.
Instead of a solder joint, large-area clamping connections are preferably used while avoiding constrictions or even welded joints.

The fusible conductor 30 is integrally formed in wire form or as a hollow cylinder to achieve maximum pulse current carrying capacity.

With high fusible conductor cross sections, the hollow cylindrical shape is preferable to a conventional division of parallel fusible conductors, since, despite similarly high switching capacity, it offers fewer disadvantages in terms of aging and possibly uneven current distribution.

In order to realize separate bottlenecks for increasing the switching capacity, gradual melt conductor tapers can be introduced on the cylinder. The tapers are to be designed in such a way that even at high current gradients a nearly uniform current density distribution in each axial section of the Fusible conductor and in particular the bottleneck area is achieved.

The rejuvenations can be done both in the extent and in the layer thickness. Alternatively, webs can be applied electrically conductive or non-conductive, whereby the arc can be divided or partially extremely constricted.

In this case, the waveguide can be designed as a hollow cylinder, but also as a conductive coating of a cylinder.

When choosing a hollow cylinder this can be filled with the same extinguishing medium or with a different extinguishing medium than the rest of the arc furnace. When coating a cylinder, this can consist of insulating material or semiconducting material. By suitable choice of material of the cylinder, the arc quenching can be supported. The material may e.g. be gas. In this embodiment, a high mechanical strength, a sufficient switching capacity and a high pulse current carrying capacity is given. If the spatial dimensions of the entire spark gap are limited, an embodiment may be useful as a hollow cylinder with internal coating. Such a design also causes a uniform distribution of the pressure wave to the outer wall or to the outer housing. With very large construction volume of the overcurrent protection device, the waveguide can also offer the possibility of integration of the firing pin despite separate arc switch room.

The material used for the fusible conductor is preferably copper, silver or their alloys. When using copper, it is expedient to apply a protective layer against oxidation. The guide of the fusible conductor is centrally through the housing 31. The power supply to the caps 32 is made without or with little current loops.

The filling medium 33 is chosen so that it does not allow dynamic movements of the fusible conductor 30.

If quartz sand is selected as filling medium, an optimal particle size distribution and optimized compaction may be sufficient.

In addition, guide webs 34 correspondingly Fig. 8 be provided. The guide webs 34 can be made insulating or else as metal plates for subdividing the arc.

The webs 34 may be connected to each other for mechanical guidance or be supported in a further variant parallel spaced on the inner wall of the housing 31.

In one variant of the filling material, so-called stone sand is used. Alternatively, high-density bulk materials are suitable for filling. In addition to bulk materials, filling media based on epoxy or silicone with or without curing are applicable. These materials can be added high levels of admixtures of extinguishing media, such as sand, ceramics, glass or gas-emitting substances.

If simple extinguishing hoses are pulled over the fusible link, a sand filling can additionally be used or the use of stabilizing webs or stabilizing liquids for damping movement is advantageous.

When using solid, non-compressible fillings and also when using clay sand, it has to be taken into consideration that these materials transmit the pressure waves during arcing to the housing 31 relatively undamped. Therefore, very high dynamic housing strength is required. Alternatively, compressible filling media can be provided or possibilities for damping the pressure wave can be realized. On the one hand, this can be measures for equal distribution of the pressure. For this purpose, additional elastic, but also rigid cylinder between the fusible conductor and the housing wall can be realized. In the filling medium but also breaking walls and compensation chambers can be created. The filling media may also contain implosive ingredients. Hollow spheres made of glass or ceramic can be used here.

Instead of filling media, the fusible conductor can also be guided in solids. These solids can be designed to support the extinguishing capacity gas-emitting. As gas donating substances are e.g. Polymers such as POM, hard gas or ceramics or substances with such admixtures for use.

By the arrangement described above, a very high pulse current carrying capacity is achieved, which is close to the theoretical value of the fusible conductor. The described embodiment is sufficient for the requirement of overcurrent protection devices for numerous overvoltage protection devices.

When using the invention for combination arresters, due to special requirements, other weights of the requirements for the respective protective devices may be useful for their design and embodiment. If very high momentum current carrying capacities are to be achieved, this leads to significant cross sections of the fusible conductor even in the case of copper. Due to the low The size of the functional units for this application is the maximum arc switching power depending on the housing design. Simple round wires or even waveguides lead to larger diameters exceeding the load limit. To achieve a high switching capacity, it is therefore expedient to choose a varying design of the fuse conductor.

If the spatial dimensions are very limited and the desired pulse current resistance is very high, a flat wire can be used as the fusible conductor. Flat wires with a ratio of width to thickness of <4: 1 are preferably used here.

Although the design of the fusible conductor as a flat wire leads with decreasing ratio of thickness to width to a reduction in the maximum impulse load over round wires of the same cross-sectional area, but here the switching capacity can be significantly increased.

The realization of the fusible conductor as a flat wire also allows additional optimization possibilities. Thus, the height of the peak current resistance can be controlled quite easily. This value is particularly important for the protection of varistors in so-called trigger circuits of combination arresters.

The position of the flat wire in the fuse influences, in addition to the geometric design of the connections of the second functional unit, the effect of the dynamic current forces on the fusible conductor. If the flat edge of the fusible conductor is perpendicular to the current force effect and the connecting lengths of the second functional unit are as straight as possible, a very high peak current value can be controlled (see principle arrangement according to FIG Fig. 9 ).

If, on the other hand, the broad side of the fusible conductor is exposed to the current forces, and if the current supply is also loop-shaped, the maximum peak current only insignificantly exceeds the magnitude of the maximum impulse current (see schematic diagram) Fig. 10 ).

In the latter case, the overcurrent protection device responds almost exclusively due to the current forces and not due to adiabatic heating. The thermal load is below the melt integral value.

The length of the power supply can already be achieved by varying the order of the functional units without changing the structural parts with parallel functional units arranged one above the other. When guiding the fusible conductor in solid materials or else in customary fillers, the peak current strength can be further reduced and the extinguishing capacity increased Meander or windings are incorporated.

The functional units 1 and 2 have high-strength housing. As materials for these housings special ceramics, but also wound glass fiber materials can be used.

In addition, each housing or both housings are jointly enclosed by an elastic cylinder. This is used as an extra protection in case of overload of the housing or gas leaks between the caps and the housing. Furthermore, the outer rollover distances are extended and critical field strength increases or endangered sliding distances avoided.

The material of the elastic cylinder can also consist of a gas-emitting substance or be coated with such a material. This results in the outgassing of hot gas or soot from the fuse to the gas delivery, whereby uniform manifestations are avoided and surface discharges can be prevented. In addition, other parts, e.g. be provided in the form of webs, which serve for Wegverlängerung.

The joint fixation of the two functional units with common stable and positive connection caps a high mechanical stabilization of the functional units with each other, but also the individual components of the functional units, in particular the caps on the housing is achieved. By fixing these common connection caps on a printed circuit board, the mechanical strength is further increased.
By these measures, the switching capacity can be further increased compared to a single functional unit. The measures shown lead to a performance that could be significantly increased compared to conventional device protection fuses of the same size. This applies to both the pulse current carrying capacity and the switching capacity.

The Fig. 11 and 12 show alternative arrangements for mounting the second functional unit 2 on a circuit board. These arrangements should lead to the lowest possible current loop formation.

According to Fig. 1 has the outer cap solder connection tabs 40, which are also suitable for SMD mounting. Fig. 12 shows a variant in which the functional unit is soldered directly into the circuit board 41, wherein solderable terminals 42 is used for this purpose.

The attachment of the electrically parallel functional unit 1 can also be appropriate Fig. 13 respectively. Here is between the functional unit 1 and 2 the made electrical connection via printed conductors of a board and realized if necessary via printed or discrete impedances.

If the switching capacity of a simple board fuse is sufficient, the second functional unit 2 can also be designed as such a fuse.

Claims (21)

1. Over-current protection device for use in over-voltage protection devices with an additional mechanical tripping device, preferably configured as a striking bolt, wherein a first functional unit (A2; 1) containing the mechanical tripping device has a first fusible element (11), a second functional unit (A1; 2), configured as an overload protection, has a second fusible element (30),
   characterized in that
   each functional unit is arranged in a housing (7; 31), wherein on the respective housing (7; 31) lateral end caps (3) are located on opposite sides and the fusible conductors or fusible elements are each located in the interior of the housing and are electrically connected to the end caps (3),
   the first and the second functional units are electrically connected in parallel and this parallel circuit is connected in series with the over-voltage protection device and the functional units form a common mechanical grouping.
2. Protection device according to claim 1,
   characterized in that
   the end caps (3) on each side of the respective functional unit extend electrically and mechanically connected into a connection prolongation (6) which permits a printed circuit board assembly of the device.
3. Protection device according to claim 1 or 2,
   characterized in that
   a chamber for receiving a spring-preloaded striking bolt is arranged at an end cap (3) of the first functional unit (1), wherein the striking bolt (5) is held in its unoperated position by the first fusible element (11).
4. Protection device according to claim 3,
   characterized in that
   the first fusible element (11) is formed of a wire having a high tensile strength and a I²t-value which is clearly smaller than that of the material of the second fusible element (30).
5. Protection device according to one of claims 3 or 4,
   characterized in that
   the housing (7) forms an arc switch room (17) which is formed of a tubular body joined, at the side, by a hollow space (16) which forms the chamber for receiving the striking bolt (5).
6. Protection device according to claim 5,
   characterized in that
   an insulating plate (10) is arranged between the arc switch room (17) and the hollow space (16), through which the first fusible element is passed.
7. Protection device according to claim 5 or 6,
   characterized in that
   the arc switch room (17) is filled with an extinguishing medium.
8. Protection device according to one of claims 5, 6 or 7,
   characterized in that
   the hollow space is defined by a slip-on cap (9), wherein the side of the slip-on cap (9) facing away from the arc combustion space (17) forms a stop for a striking plate of the striking bolt (5).
9. Protection device according to claim 8,
   characterized in that
   the striking plate is surrounded by an insulating cap (13).
10. Protection device according to claim 8,
    characterized in that
    the striking plate is configured as a striking mandrel or striking pin, wherein the travel distance is limited by a stop and a recess inside a hood cap (21).
11. Protection device according to one of the preceding claims,
    characterized in that
    the first fusible element (11) is made of a compound material and has at least one constriction and/or a portion with a different impedance or different resistance.
12. Protection device according to one of the preceding claims,
    characterized in that
    the second functional unit comprises a hollow-cylindrical housing (31) with lateral end caps (3), wherein the second fusible element is passed in the form of a tape, wire or in a hollow-cylindrical shape (30) from cap to cap.
13. Protection device according to claim 12,
    characterized in that
    the fusible element (30) in the form of a wire or hollow cylinder is connected to the caps (3) in a non-positive and/or positive manner.
14. Protection device according to claim 12 or 13,
    characterized in that
    the hollow cylinder of the second fusible element comprises constrictions and/or tapers.
15. Protection device according to one of claims 12 to 14,
    characterized in that
    the housing (31) contains a filling (33).
16. Protection device according to claim 15,
    characterized in that
    the filling (33) is made of a highly compressible fill material.
17. Protection device according to claim 15,
    characterized in that
    the filing (33) contains compressible materials.
18. Protection device according to claim 12,
    characterized in that
    the tape is formed as a ribbon wire with a width to height ratio < 4:1.
19. Protection device according to one of claims 12 to 18,
    characterized in that
    the second fusible element is held by guide webs located in the housing (31).
20. Protection device according to one of the preceding claims,
    characterized in that
    a common outer housing surrounding the functional units is provided.
21. Protection device according to claim 1,
    characterized in that
    each housing (7; 31) is surrounded by a separate or both housings by one common elastic jacket (4).

Images