Acoustic device for estimating tripping intensity, associated electrical protection assembly and electrical installation

An acoustic device estimates tripping current in circuit breakers by measuring noise, addressing the cost and intrusion issues of traditional methods, providing accurate and cost-effective tripping intensity estimation.

FR3162281B1Active Publication Date: 2026-06-05SCHNEIDER ELECTRIC IND SAS

Patent Information

Authority / Receiving Office
FR · FR
Patent Type
Patents
Current Assignee / Owner
SCHNEIDER ELECTRIC IND SAS
Filing Date
2024-05-17
Publication Date
2026-06-05

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Abstract

Acoustic device for estimating tripping intensity, associated electrical protection assembly and electrical installation. The present invention relates to an acoustic device for estimating the tripping intensity of a tripping current flowing in a circuit breaker, the device comprising: an enclosure (22); a plate (32); a support (40); a tab (42) connecting the support and the plate; a microphone (70);an attenuator (44), the support extending between the microphone and the attenuator, the attenuator comprising a housing (46) including a housing opening (48) and an attenuating membrane (50), and an electronic control unit (38) connected to the microphone, the attenuator being configured to attenuate noise generated by the circuit breaker, the noise being representative of the tripping intensity, the microphone being configured to measure the noise attenuated by the attenuator, and to output a signal, and the electronic control unit being configured to receive the output signal and to estimate the tripping intensity. Figure for the abstract: Figure 2;
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Description

Title of the invention: Acoustic device for estimating tripping intensity, associated electrical protection assembly and electrical installation

[0001] The present invention relates to an acoustic device for estimating a tripping intensity, an associated electrical protection assembly and electrical installation.

[0002] In order to monitor the operation of a circuit breaker and to plan predictive maintenance, it is known to measure the current flowing through the circuit breaker at the moment the circuit breaker switches to the tripped configuration, that is, becomes electrically insulating. The current flowing through the circuit breaker at the moment the circuit breaker switches to the tripped configuration is called the tripping current, and has a value called the tripping current.

[0003] However, measuring the tripping intensity is costly and intrusive, since it requires adding an intensity sensor inside the circuit breaker, more precisely on one of the circuit breaker conductors, this sensor having to be able to withstand tripping intensities whose values ​​can be high.

[0004] The aim of the invention is then to propose a device allowing the triggering intensity to be estimated in a simple, non-intrusive and low-cost manner.

[0005] To this end, the invention relates to an acoustic device for estimating the tripping intensity of a tripping current flowing in a circuit breaker, the device comprising: - an enclosure configured to be attached to the circuit breaker; - a plate, integrated inside the envelope, the plate extending along a main plane; - a support, integrated inside the envelope, the support extending parallel to the main plane, a tab connecting the support and the plate, the support being connected to the plate only via the tab; - a microphone, attached to the stand; - an attenuator, attached to the support, the support extending between the microphone and the attenuator, the attenuator comprising: • a dwelling comprising a housing opening, passing through and extending along a housing axis, and • a damping membrane, received in the housing and covering the housing opening; and - an electronic control unit, connected to the microphone,

[0006] the attenuator being configured to attenuate noise generated by the circuit breaker, the noise being representative of the tripping intensity, the microphone being configured to measure the noise attenuated by the attenuator, and to emit an output signal representative of the attenuated noise, and the electronic control unit being configured to receive the output signal emitted by the microphone and to estimate the tripping intensity of the tripping current of the circuit breaker, from the output signal.

[0007] Thanks to the invention, estimating the tripping current using the noise emitted by the circuit breaker is simple, non-intrusive, and inexpensive. Indeed, since the noise emitted by the circuit breaker is representative of the tripping current, estimating the tripping current from the noise measured by the microphone is a simple and inexpensive solution. Furthermore, the microphone does not need to be integrated into the circuit breaker to function. The attenuator, particularly through its attenuating membrane, reduces the noise emitted by the circuit breaker to sound levels that can be measured by the microphone, while providing constant attenuation across the frequency range of the noise.This helps to limit the risk of microphone saturation and damage while allowing the microphone to record attenuated noise that is representative of the trigger intensity, so that the electronic unit can estimate the trigger intensity with the best possible accuracy.

[0008] The fact that the support is connected to the plate only via the tab helps to dampen the mechanical vibrations generated by the circuit breaker and transmitted to the device, in order to limit that their measurement by the microphone masks the attenuated noise and prevents a correct estimation of the tripping intensity.

[0009] According to other advantageous aspects of the invention, the acoustic device comprises one or more of the following features, taken individually or in all technically possible combinations:

[0010] - The attenuator further comprises a washer, including a washer orifice, the washer orifice being through and extending along a washer axis, the washer being received in the housing so that the housing and washer axes coincide, the washer being in contact with the attenuation membrane, and the attenuation membrane covering the washer orifice.

[0011] - The device further comprises a mechanical shock absorber, fixed to the casing, surrounding the support and the attenuator, and leaving the microphone and housing opening free, the mechanical damper being configured to dampen mechanical vibrations of the device.

[0012] - The envelope includes a wedge, the tab being in contact with the wedge in order to Position the support at a distance from the plate along an axis perpendicular to the main plane.

[0013] - The support includes a support hole, the support hole being through along a support axis; - the microphone is fixed to the bracket so as to cover the bracket opening; and - the attenuator is fixed to the support so that the axes of the housing, washer and support coincide.

[0014] - The enclosure includes an acoustic port, comprising at least one opening, the The support is positioned opposite the acoustic port and the attenuator is placed between the support and the acoustic port.

[0015] - The attenuator is fixed to the support by an adhesive film, the adhesive film comprising at at least two adhesive layers and at least one membrane, interposed between two of the at least two adhesive layers, one of the at least two adhesive layers being glued to the attenuator and another of the at least two adhesive layers being glued to the support.

[0016] - The membrane or each membrane comprises woven fibers.

[0017] - The membrane or each membrane comprises non-woven fibers.

[0018] The invention also relates to an electrical protection assembly comprising a circuit breaker, the circuit breaker being configured to be connected between a source and a load, and being configured to switch from an armed configuration, in which the circuit breaker conducts a current flowing between the source and the load, to a tripped configuration, in which the circuit breaker electrically isolates the load from the source, when a tripping current of intensity the tripping intensity flows in the circuit breaker, the switching of the circuit breaker from the armed configuration to the tripped configuration generating a noise, representative of the tripping intensity, the circuit breaker comprising a housing, the electrical protection assembly further comprising a device as described above, the enclosure of the device being fixed to the housing.

[0019] The invention also relates to an electrical installation comprising a source, a load connected to the source and an electrical protection assembly, connected between the source and the load.

[0020] The invention will become clearer upon reading the following description, given solely by way of non-limiting example, and made with reference to the drawings in which: - [Fig.1] [Fig.1] is a view of an electrical installation according to the invention; - [Fig.2] [Fig.2] is a cross-section of a protective device according to the invention; - [Fig.3] [Fig.3] is an exploded view of elements of the protection device; - [Fig.4] [Fig.4] is a detailed view of the protective device according to the plan IV-IV.

[0021] Figure 1 represents an electrical installation 1, comprising a source 3 and a load 5. The source 3 supplies electricity and is, for example, an electric generator, a transformer, or an electrical network such as a mains power grid. The load 5 is a device consuming electricity, for example, industrial equipment such as an electric motor, a server, or a household appliance.

[0022] In the example of [Fig. 1], the source 3 and the load 5 are connected by a phase conductor 7, but alternatively, the source and the load are connected by more than one phase conductor, for example, three phase conductors. An electric current, also simply called current, supplied by the source 3, flows between the source 3 and the load 5 through the phase conductor 7. The electric current is advantageously a low-voltage electric current, that is, with a nominal voltage less than or equal to 1500 V. The current is advantageously an alternating current. Alternatively, the current is a direct current.

[0023] Advantageously, and in a manner not shown, the source 3 and the load 5 are further connected to each other by a neutral conductor.

[0024] The electrical installation 1 includes an electrical protection unit 10, connected between the source 3 and the load 5. The electrical protection unit 10 includes a circuit breaker 12, which is connected between the source 3 and the load 5. Thus, the current flowing from the source 3 to the load 5 through the phase conductor 7 also flows through the circuit breaker 12. The circuit breaker 12 is, for example, as shown in [Fig. 1], a molded case circuit breaker, or MCCB.

[0025] The circuit breaker 12 includes a housing 14, which is made of an electrically insulating material. The housing 14 contains most of the other components of the circuit breaker 12, including circuit breaker contacts, which are not shown.

[0026] The circuit breaker 12 is configured to switch between an armed configuration, in which the contacts are closed and in which it conducts the current flowing between the source 3 and the load 5, and a tripped configuration, in which the contacts are open and in which it electrically isolates the source 3 from the load 5. The circuit breaker 12 is configured to switch to the tripped configuration in the event of a short circuit or overload of the electrical installation 1, in order to prevent excessive current from flowing in the electrical installation 1. The circuit breaker 12 is also configured to switch to tripped mode following a user command, for example, manually switching it to tripped mode by operating a lever 16 on circuit breaker 12. When circuit breaker 12 switches to tripped mode, the current flowing through circuit breaker 12 is called the tripping current and is characterized by a tripping current Id. The tripping current Id varies depending on the reason for switching circuit breaker 12 to tripped mode and can range from virtually zero, for example, when the user commands the switching of circuit breaker 12 to tripped mode, to greater than 2500 A, for example, in the case of short circuits.

[0027] In the example of [Fig. 1], the handle 16 protrudes from a front face 18 of the housing 14. The front face 18 is perpendicular to a depth axis X, linked to the circuit breaker 12. A width axis Y and a height axis Z are associated with the depth axis X, the three axes forming a right-handed trihedron. The front face 18 thus extends along the width axis Y and the height axis Z.

[0028] The electrical assembly 10 also includes an acoustic device 20 for estimating the tripping current Id. The device 20 includes an enclosure 22, attached to the circuit breaker 12. More specifically, the enclosure 22 is attached to the housing 14, for example by being glued or screwed to the housing 14. In the example of [Fig. 1], the enclosure 22 includes a face referred to as the rear face 24, partially visible in [Fig. 4], which is in contact with the front face 18. Alternatively, the rear face 24 of the enclosure 22 is at a distance of a few millimeters from the front face 18 of the housing 14, measured along the depth axis X. The enclosure 22 includes an opening 26, which passes through it completely to allow free movement of the handle 16, which can thus move when the circuit breaker 12 trips, when it is reset by the user, or when The user operates lever 16 to manually trigger circuit breaker 12.

[0029] Advantageously, the enclosure 22 includes an acoustic port 28, visible in [Fig. 4]. In the example of Figures 1 and 4, the acoustic port 28 is located on the rear face 24, so as to be in contact with the front face 22, or at least as close as possible to the circuit breaker 12. The acoustic port 28 includes at least one opening 29, in the example of [Fig. 4], a plurality of openings 29, connecting the inside of the enclosure 22 to the outside. Air can thus circulate from the outside to the inside of the enclosure 22 through the openings 29 and vice versa.

[0030] The device 20 further includes a plate 32, visible in figures 2 and 4, integrated inside the casing 22. The plate 32 extends along a principal plane P, which, in the example of figures 2 and 4, is perpendicular to the depth axis X.

[0031] The plate 32 is, for example, a printed circuit board, on which electronic components 34 are connected, such as programmable logic components, such than FPGAs (from the English Field Programmable Gate Array), or even integrated circuits, such as ASICs (from the English Application Specified Integrated Circuit) the printed circuit and the electronic components 34 forming an electronic control unit 38, represented in dotted lines on the [Fig.1], and partially on figures 2 and 3 whose function is described in detail later.

[0032] The device 20 includes a support 40, integrated inside the housing 22 and visible in [Fig. 2]. In the example of [Fig. 2], the support 40 is circular and extends parallel to the principal plane P. The support 40 is, for example, a printed circuit board. Advantageously, the support 40 includes a support hole 41, passing through and extending along a support axis R40.

[0033] Advantageously, the support 40 is at a distance from the plate 32 along an axis X32, perpendicular to the main plane P.

[0034] The support 40 is connected to the plate 32 by means of a tab 42. The support 40 is connected to the plate 32 only by means of this tab 42. The tab 42 is advantageously made of flexible polymer, for example polyimide, or alternatively, the tab 42 is itself a flexible printed circuit board.

[0035] Advantageously, in order to position the support 40 at a distance from the plate 32 along the X32 axis, the housing 22 includes a wedge 43, visible in [Fig. 2]. The tab 42 bears against the wedge 43 and is constrained by the wedge 43 to position the support 40 while limiting the stresses applied to the latter.

[0036] The device 20 further comprises an attenuator 44, fixed to the support 40. The attenuator 44 comprises a housing 46, which includes a housing opening 48. The housing opening 48 is through-hole and extends along a housing axis R46. The housing 46 is advantageously circular and made of metal, for example, aluminum. Advantageously, the housing opening 48 is aligned with the support opening 41, such that the support axes R40 and the housing axis R46 coincide.

[0037] The attenuator 44 also includes an attenuation membrane 50, received in the housing 46 and covering the housing opening 48. The attenuation membrane 50 is advantageously made of an airtight material, for example, polyimide. Advantageously, a thickness of the attenuation membrane 50, measured along the X32 axis, is less than 100 µm, for example, equal to 75 µm.

[0038] Advantageously, the attenuator 44 also includes a washer 52. The washer 52 includes a washer orifice 54, passing through and extending along a washer axis R52. Advantageously, the washer orifice 54 has a diameter d54 less than 4 mm, for example, equal to 3.5 mm and equal to a diameter d48 of the housing orifice 48. The washer 52 is advantageously made of metal, for example, aluminum. The washer 54 is received in the housing 46, for example, by being crimped into the housing 46, so that the housing 46 and the washer 52 are each in contact with the membrane attenuation membrane 50. The attenuation membrane 50 thus covers both the housing orifice 48 and the washer orifice 54. The membrane 50 is thus exposed to the air through the housing orifice 40 and through the washer orifice 54, while being airtight, as described previously.

[0039] Advantageously, the washer 54 is received in the housing 46 such that the axes of the housing R46 and the washer R52 coincide. Thus, the axes of the support R40, the support R46, and the washer R52 coincide.

[0040] Advantageously, the attenuator 44 is attached to the support 40 by means of an adhesive film 60. The adhesive film 60 comprises at least two adhesive layers 62 and at least one membrane 64, interposed between two of the at least two adhesive layers 62. The adhesive film 60 is visible in Figures 2 and 3, and in the example of Figures 2 and 3, comprises three double-sided adhesive layers 62 and two membranes 64, each membrane 64 being interposed between two adhesive layers 62. The adhesive layers 62 and the membranes 64 are thus bonded to one another. In order to attach the attenuator 44 to the support 40, one of the adhesive layers 62 is bonded to the attenuator 44 and another of the adhesive layers 62 is bonded to the support 40.

[0041] Advantageously, the adhesive layers 62 each comprise a through orifice 66, each orifice 66 being along a film axis R60. Advantageously, the diameter of the orifices 66 is variable, as can be seen in [Fig. 2]. Alternatively, the orifices 66 of the adhesive layers 62 all have the same diameter. The membranes 64 do not comprise any orifices and therefore cover the orifices 66.

[0042] Advantageously, the membranes 64 comprise woven fibers, or alternatively, non-woven fibers.

[0043] Advantageously, the membranes 64 are airtight, and the adhesive film 60 seals the attenuator 44 and the support orifice 41 against air.

[0044] The device 20 also includes a microphone 70, fixed to the support 40, the support 40 extending between the microphone 70 and the attenuator 44. Advantageously, the microphone 70 covers the support opening 4L. The microphone 70 is advantageously a micro-electromechanical system (MEMS) microphone. The microphone 70 is connected to the electronic control unit 38, for example, by being connected to one of the electronic components 34. The microphone 70 is configured to measure ambient noise, i.e., the mechanical vibrations of the surrounding air. If the microphone 70 is a MEMS microphone, it is configured to measure noise levels up to approximately 135 dB, beyond which it saturates.

[0045] Advantageously, the device 20 further comprises a mechanical damper 74. The mechanical damper 74 is fixed to the casing 22 and, advantageously, bears against the plate 32. The mechanical damper 74 surrounds the support 40 and the attenuator 44. In particular, the mechanical damper 74 includes a central opening 76, through, and extending along a damper axis R74, into which the support 40 is inserted, closing the central opening 76.

[0046] Advantageously, the mechanical damper 74 is made of an elastomeric material, such as silicone. The mechanical damper 74 is advantageously mounted tightly around the support 40, the support 40 being inserted into the central opening 76, for example, by elastic or plastic deformation of the mechanical damper 74.

[0047] The mechanical damper 74 leaves the microphone 70 and the housing orifice 48 free, that is to say that the mechanical damper 74 is not in contact with the latter, for example does not cover the housing orifice 48.

[0048] Advantageously, the wedge 43 and the tongue 42 allow the support 40 to be positioned in such a way as to limit the stresses exerted by the support 40 on the mechanical damper 74.

[0049] One operation of the device is now explained.

[0050] When the circuit breaker 12 switches to the tripped configuration following an overload or short-circuit fault, or following a user command, the circuit breaker 12 generates noise, representative of the tripping current Id, as well as mechanical vibrations in the solid parts forming the circuit breaker 12. In particular, the noise generated is caused by detonations and by so-called acoustic pressure variations, which are representative of the tripping current. The detonations can cause pressure variations of up to several hundred thousand pascals, which can damage the microphone 70. The acoustic pressure variations are, for example, on the order of a thousand pascals, and the maximum acoustic pressure variations are, for example, on the order of 6000 Pa, or on the order of 169.5 dB.

[0051] The attenuator 44, particularly through the attenuating membrane 50, reduces the noise generated by the circuit breaker 12 when it switches to the triggered configuration. More specifically, the attenuator 44 attenuates both the detonations, thus protecting the microphone 70, and the acoustic pressure variations. Advantageously, the attenuator 44 attenuates the acoustic pressure variations so as to obtain attenuated noise at the microphone 70 input, generated by maximum pressure variation values ​​on the order of 135 dB, which limits the risk of saturation of the microphone 70. Thus, when the microphone 70 receives the noise attenuated by the attenuator 44, it is able to measure it.

[0052] Furthermore, the attenuator 44 attenuates acoustic pressure variations in a constant manner, regardless of their frequency. In practice, the attenuator 44 attenuates pressure variations in a constant manner for a spectrum of predefined frequency. For example, the frequency spectrum is between 20 Hz and 15 kHz, preferably between 30 Hz and 10 kHz. In other words, the attenuated noise is not distorted over the frequency spectrum between 30 Hz and 10 kHz. Thus, the attenuated noise is representative of the noise generated by circuit breaker 12, and therefore, of the tripping current Id.

[0053] The microphone 70 measures the ambient noise, which, in the case of the device 20, is the noise attenuated by the attenuator 44, and generates an output signal representative of the attenuated noise. The electronic control unit 38 receives the output signal emitted by the microphone 70 and estimates the tripping intensity Id of the tripping current of the circuit breaker 12 from the output signal. Advantageously, the output signal is taken into account by the electronic control unit 38 only when the electronic control unit 38 receives an acquisition command, emitted, for example, by a microswitch. The microswitch is configured to detect the tripping of the circuit breaker 12 and then emits the acquisition command.

[0054] The mechanical vibrations generated by the circuit breaker 12 are transmitted to the device 20, notably via the housing 22, which then transmits them to the plate 32. To prevent their transmission to the microphone 70, the mechanical vibrations are dampened by the assembly formed by the support 40 and the tab 42 and, advantageously, by the mechanical damper 74. The assembly formed by the support 40 and the tab 42 allows the support 40 to be decoupled from the plate 32, and thus limits the transmission of mechanical vibrations from the circuit breaker 12 to the support 40, and therefore to the microphone 70 fixed to the support 40. The mechanical damper 74 reduces the mechanical vibrations nevertheless transmitted to the tab 42 and the support 40. Thus, the mechanical vibrations transmitted to the microphone 70 from the support 40 are limited, preventing them from masking the attenuated noise obtained from the noise produced by the circuit breaker 12.

[0055] The noise and mechanical vibrations generated by the circuit breaker 12 cause resonance phenomena, generating additional noise, the frequency of which is, for example, between 20 kHz and 35 kHz. Advantageously, the diaphragms 64 attenuate noises with frequencies above 20 kHz, without attenuating other noises, thus limiting the risk of saturation of the microphone 70 caused by resonance phenomena. The diaphragms 64 thus function as acoustic impedances.

[0056] The attenuator 44, the assembly formed by the support 40 and the tab 42, and advantageously, the mechanical damper 74 and the membranes 64 limit the presence of interference in the output signal, and thus allow the most accurate possible estimation of the trigger intensity Id by the electronic control unit 38.

Claims

1.

2. Demands Acoustic device (20) for estimating the tripping intensity (Id) of a tripping current flowing in a circuit breaker (12), the device (20) comprising: - an enclosure (22) configured to be attached to the circuit breaker (12); - a plate (32), integrated inside the envelope (22), the plate (32) extending along a principal plane (P); - a support (40), integrated inside the envelope (22), the support (40) extending parallel to the main plane (P), a tab (42) connecting the support (40) and the plate (32), the support (40) being connected to the plate (32) only via the tab (42); - a microphone (70), attached to the support (40); - an attenuator (44), fixed to the support (40), the support (40) extending between the microphone (70) and the attenuator (44), the attenuator (44) comprising: • a housing (46) comprising a housing opening (48), passing through and extending along a housing axis (R46), and • a damping membrane (50), received in the housing (46) and covering the housing opening (48); and - an electronic control unit (38), connected to the microphone (70), the attenuator (44) being configured to attenuate noise generated by the circuit breaker (12), the noise being representative of the tripping intensity (Id), the microphone (70) being configured to measure the noise attenuated by the attenuator (44), and to emit an output signal representative of the attenuated noise, and the electronic control unit (38) being configured to receive the output signal emitted by the microphone (70) and to estimate the tripping intensity (Id) of the tripping current of the circuit breaker (12), from the output signal. Device (20) according to claim 1, wherein the attenuator (44) further comprises a washer (52), comprising an orifice of washer (54), the washer orifice (54) being through and extending along a washer axis (R52), the washer (52) being received in the housing (46) so that the housing (R46) and washer (R52) axes coincide, the washer (52) being in contact with the attenuation membrane (50), and the attenuation membrane (50) covering the washer orifice (54).

3. Device according to any one of the preceding claims, further comprising a mechanical damper (74), fixed to the housing (22), surrounding the support (40) and the attenuator (44), and leaving the microphone (70) and the housing opening (48) free, the mechanical damper (74) being configured to dampen mechanical vibrations of the device (20).

4. Device (20) according to any one of the preceding claims, wherein the envelope (22) includes a wedge (43), the tab (42) being in contact with the wedge (43) in order to position the support (40) at a distance from the plate (32) along an axis perpendicular (X32) to the principal plane (P).

5. Device (20) according to claim 2, wherein: - the support (40) includes a support hole (41), the support hole (41) being through along a support axis (R40); - the microphone (70) is fixed on the support (40) so as to cover the support hole (41); and - the attenuator (44) is fixed to the support (40) so that the axes of housing (R46), washer (R52) and support (R40) coincide.

6. Device (20) according to any one of the preceding claims, wherein the enclosure (22) includes an acoustic port (28), comprising at least one opening, the support (40) is opposite the acoustic port (28) and the attenuator (44) is disposed between the support (40) and the acoustic port (28).

7. A device (20) according to any one of the preceding claims, wherein the attenuator (44) is fixed to the support (40) by an adhesive film (60), the adhesive film (60) comprising at least two adhesive layers (62) and at least one membrane (64) interposed between two of the at least two adhesive layers (62), one of the at least two adhesive layers (62) being bonded to the attenuator (44) and another of the at least two adhesive layers (62) being glued to the support (40).

8. Device (20) according to claim 7, wherein the or each membrane (64) comprises woven fibers.

9. Device (20) according to claim 7, wherein the or each membrane (64) comprises non-woven fibers.

10. Electrical protection assembly (10) comprising a circuit breaker (12), the circuit breaker being configured to be connected between a source (3) and a load (5), and being configured to switch from an armed configuration, in which the circuit breaker (12) conducts a current flowing between the source (3) and the load (5), to a tripped configuration, in which the circuit breaker (12) electrically isolates the load (5) from the source (3), when a tripping current of intensity the tripping current (Id) flows in the circuit breaker (12), the switching of the circuit breaker (12) from the armed configuration to the tripped configuration generating a noise, representative of the tripping current (Id), the circuit breaker (12) comprising a housing (14), the electrical protection assembly further comprising a device (20) according to any one of claims 1 to 9, the enclosure (22) of the device (20) being fixed to the housing (14).

11. Electrical installation (1) comprising a source (3), a load (5) connected to the source (3) and an electrical protection assembly (10) according to claim 10, connected between the source (3) and the load (5).