FR2598556A1 - Self-destruct electrical protection device - Google Patents

Abstract

Electrical protection device characterised in that it comprises, on the one hand, an electrically insulating substrate 2 which breaks under the effect of a controlled pre-set thermal overload and, on the other hand, two electrical circuits 3, 4 formed on the two opposite faces respectively of this substrate, one being an electrical conduction or power circuit 3 intended for continuous passage of an electric current to be monitored, and the other being an electrical protection control circuit 4 intended to create, through an electric control current, this pre-set thermal overload.

Description

SELF-DESTROYING ELECTRICAL PROTECTION DEVICE
The present invention relates to a self-destructive electrical protection device.

 There are many known devices for electrical protection of electrical circuits, instruments or apparatus by cutting off their supply current. Some are in the form of a fuse which automatically cuts off an electric current to be monitored through it by self-destruction by melting one of its sections under the effect of an excess of heat released by the Joule effect following an increase in this current. to be monitored beyond a predetermined maximum value. The others are in the form of bimetal contacts which cut an electric current to be monitored passing through them, by a separation of these contacts under the effect of a change in the geometric shape of their bimetallic strip DO to an unequal expansion of the two faces of the body of this bimetallic strip under the effect of an excess of heat released by the Joule effect consecutive to an increase in this current to be monitored beyond a predetermined maximum value. The third are in the form of an electromagnetic relay switch or a differential circuit breaker which cuts an electric current to be monitored passing through them, by a separation of their contacts using their mechanical system actuated by their electromagnetic relay in which is injected an electric control current.The devices in the form of a fuse do not work with a protective control current separate from the electric current to be monitored. In addition, these devices are either long to set up or not very visible when they are thin and / or protected by an envelope. Bimetallic devices have the drawback of automatically re-establishing a current after it has been cut off.

Electromagnetic relay devices are expensive and bulky devices.

 The aim of the present invention is to avoid these drawbacks, and makes it possible to produce an economical self-destructive electrical protection device, with controlled protection operation, efficient fast, with reduced dimensions, easy to assemble, and applicable as well in electrical circuits of costly industrial instruments or apparatus than those of mass-market and low-cost apparatus for the general public sector.

 According to the invention, an electrical protection device is characterized in that it comprises on the one hand an electrically insulating substrate, breaking under the effect of a controlled preset thermal overload, and on the other hand two electrical circuits, formed respectively on the two opposite faces of this substrate, one being an electrical conduction or power circuit, intended for a continuous passage of an electrical current to be monitored, and the other being an electrical protection control circuit intended to create by a control electric current this preset thermal overload.

To better understand the invention, a number of embodiments are described below, illustrated by the attached drawings,
- Figure 1 shows a schematic perspective view of a self-destructive electrical protection device, produced according to the invention;
- Figure 2 shows a schematic perspective view of a first alternative embodiment of the device of Figure 1
FIG. 3 represents, on another scale, a schematic view of the device of FIG. 1, and
- Figure 4 shows on another scale, a schematic side view of a spring of the device of Figure 3.

 A self-destructive electrical protection device with controlled protection operation 1 comprises, according to an exemplary embodiment illustrated in FIG. 1, on the one hand an electrically insulating substrate 2 constituted by a plate of an electrically insulating material of a known type such as a ceramic which breaks under the effect of a controlled, pre-established thermal overload, and on the other hand two electrical film circuits 3, 4 formed respectively on the two opposite faces of this substrate 2, namely an electrical film conduction circuit or of power 3 having a reduced electrical resistivity and intended for a continuous passage of an electrical current to be monitored, and a protective electrical control film circuit 4 with high electrical resistivity forming an electrical heating resistance intended to create by a current of control, this preset thermal overload which causes a break or a rupture of the substrate 2.

 The ceramic substrate 2 has the shape of a plate and can comprise, in the central zone of its faces which carry electrical conduction 3 and control 4 circuits, one or more recesses 5 creating in this plate a thinned transverse zone 6 which facilitates a breakage of this plate under the effect of a preset thermal overload. The recesses 5 can be formed on one of the faces or on the two opposite faces of the substrate 2. For a given characteristic of the material constituting the substrate 2, the values of the thermal overloads determined by the values of the protective control currents sent in the protection control circuit 4 to cause breakage of the assembly "substrate 2 and electrical film conduction circuits 3 and control 4" are a function of the dimensions of the thinned transverse area 6 of the substrate 2. The electric film conduction circuit or power, with low electrical resistivity 3 and the electrical film control circuit with high electrical resistivity 4 are formed, deposited or plated using a known technique such as, screen printing with a conductive or resistive ink, electroplating, plating, etc. Because of their small thickness, the conductive film circuit 3 and the resistive film circuit 4 oppose the breakage of the substrate 2 only with negligible or insensitive mechanical resistance. The electrical conduction or power film circuit 3 and the electrical control film circuit comprise at their two ends rapid electrical connection members in the form of pins 7, 8 and 9, 10 the dimensions and spacings of which are standardized or comply with standards. existing.

 In an example of application, the electrical film conduction or power circuit 3 of an electrical protection device 1 supports a continuous passage of an alternating electric current to be monitored of the order of fifteen effective amps, - the circuit electric control film 4 of this device creates, with a protective control current of the order of 400 effective milliamps, a thermal overload which causes the substrate 2 to break or break, this electric control current being produced under an alternating voltage between 187 volts and 247 volts approximately, and a random and non-repetitive passage of a half-wave of a supply current does not trigger a rupture of this substrate 2, - and the substrate 2 supports without failure this passage in continuous of this electric current to be monitored through its film conduction or power circuit 3, and breaks with its film circuits 3 and 4 in a shorter time eur to a second after a passage of this electric control current through its film control circuit 4, without driving a formation between broken parts of this substrate, electric arcs under an alternating electric voltage of the order of 247 volts . The passage of the current to be monitored causes very low heating of the substrate 2 without causing it to break. However, the passage of a protective control current creates a thermal overload which causes this substrate 2 to break.

 In a first alternative embodiment illustrated in FIG. 2, the substrate 2 comprises on the one hand a spacer spring made of wound elastic wire, the two spaced ends 12, 13 of which constantly tend to move away from one of the other, and on the other hand in its thickness two holes 14, 15 located on the two sides of its thinned transverse zone 6 intended to receive the two ends 12 and 13 of the spring in the banded state 11. During a rupture or a break in the assembly "substrate 2 and film conduction circuits 3 and control 4" the banded spring 11 spreads out and separates from one another the broken parts of this assembly by its ends 12, 13, which contributes to eliminating any risk of arcing between these broken parts. When the assembly "substrate 2 and film conduction circuits 3 and control 4" is broken, the electric current to be monitored passing through the film conduction circuit 3 is interrupted until replaces ment of the device 1 destroyed by another protection device 1 which is in good working order. The electrical protection device I is therefore self-destructive but its protection operation is, unlike a protection device in the form of a fuse, subject to control by sending through its film control circuit 4, a electric control current separate from the electric current to be monitored passing through its film conduction circuit 3. The electric protection device 1 is also distinguished from an electric protection circuit breaker with electromagnetic relay by an absence of resetting possibility for reuse.

 In a second alternative embodiment illustrated in FIG. 3, the substrate 2 comprises a spacer spring 16 in the form of a U-shaped blade folded with a wide bottom and with two branches 17, 18 flared outwards (FIG. 4) . The spacer spring 16 is bandaged by elastic approximation of its two branches 17, 18 towards one another, then fixed by these two branches to the two ends of the substrate 2 by a known technique, such as bonding, fixing by screws , fixing by stapling, etc. In this alternative embodiment, during a break or a rupture of the substrate 2 caused by a sending of an electric control current through the film control circuit 4, the banded spring 16 is released and spreads the parts broken by its two branches 17, 18 which move away from each other to return to their rest position. The risk of arcing maintained between these broken parts is thus eliminated.

 In a third embodiment not shown, the substrate 2 comprises spacing springs constituted by spiral springs, the central end of which is fixed to a support and the banded external end is engaged in one of the corresponding holes formed in this substrate 2 and located on both sides of the thinned transverse area 6 of this substrate 2. When the substrate 2 breaks or breaks, caused by an electric control current being sent through the film control circuit 4, the spiral springs separate the broken parts of this substrate 2 from one another and make it possible to avoid any risk of the formation of electric arcs between these broken parts.

Claims (12)

 1. Electrical protection device, characterized in that it comprises on the one hand an electrically insulating substrate (2) which breaks under the effect of a controlled preset thermal overload, and on the other hand two electrical circuits (3, 4) formed respectively on the two opposite faces of this substrate, one being an electric conduction or power circuit (3), intended for a continuous passage of an electric current to be monitored, and the other being a circuit electrical protection control (4) intended to create, by an electric control current, this preset thermal overload.  2. Device according to claim 1, characterized in that the substrate (2) has the shape of a wafer.  3. Device according to one of claims 1 and 2, characterized in that the substrate (2) comprises in its central zone of its faces which carry the electrical conduction (3) and control (4) circuits, one or more hollow (5), creating a thinned transverse zone (6) there.  4. Device according to claim 1, characterized in that the electrical conduction (3) and control (4) circuits are respectively electrical circuits in film form.  5. Device according to claim 4, characterized in that the electrical film conduction (3) and control (4) circuits are formed, deposited or plated on the two opposite faces of the substrate (2) according to a technique chosen from screen printing , electroplating, plating.  6. Device according to one of claims 1, 4 and 5, characterized in that the electrical film conduction (3) and control (4) circuits are provided at their two ends with electrical connection members in the form of pins (7, 8, 9, 10) with standardized or standardized dimensions and spacings.  7. Device according to one of claims 1 to 3, characterized in that the substrate (2) consists of a ceramic.  8. Device according to one of claims 1 to 8, characterized in that the assembly "substrate (2) and electrical circuits (3, 4P supports without failure a continuous passage through its film conduction circuit (3), an electric current to be monitored of the order of 15 effective amps.  9. Device according to one of claims 1 to 9, characterized in that the assembly "substrate (2) and electrical circuits (4)" breaks within less than a second after being sent through its electrical film circuit control (4), an electric control current of the order of four hundred milliamps.  10. Device according to one of claims 1 to 9, characterized in that the substrate (2) comprises on the one hand a spacer spring (I1) of elastic wire whose spaced ends (12, 13) tend continuously to move away from each other, and on the other hand in its thickness, two holes (14, 15) located on the two sides of its thinned transverse zone (6) and intended to receive the two ends (12 , 13) of this spring in a bandaged state (11).  11. Device according to one of claims 1 to 9, characterized in that the substrate (2) comprises, on the one hand, spiral spacing springs, made of elastic wire, the central end of which is fixed to a support, and on the other hand in its thickness of the holes located on the two sides of its thinned transverse zone (6) and intended to receive the corresponding external ends of these spiral springs in a banded state.  12. Device according to one of claims 1 to 9, characterized in that the substrate (2) comprises a spacer spring (16) in the form of a blade folded in a broadband U and with branches (17, 18 ) flared outwards, these two branches (17, 18) being resiliently brought together to be fixed at the two ends of this substrate (2) and to put this spring (16) in a banded state.