KR20220098690A - Electrical assembly for transporting electrical energy subjected to high temperature - Google Patents

Abstract

The present invention relates to an electric assembly (1) for transmitting electric energy to a component (10) exposed to high temperature. The electric assembly (1) comprises: a conductive cable connected to a connection terminal of the component (10); a connector integrated with an end part of the conductive cable and connecting the conductive cable to the terminal; an exterior (4) surrounding the conductive cable; and a cover (5) connecting the exterior (4) to the component (10) while surrounding the connector and the terminal. Herein, the conductive cable comprises a protection material (6) electrically insulated and enduring high temperature. For protecting the conductive cable (2) and the protection material thereof, the exterior (4), the cover (5), and an interface between the exterior (4) and the cover (5) form a continuous envelope which is sealed against ejection and dripping of liquid.

Description

ELECTRICAL ASSEMBLY FOR TRANSPORTING ELECTRICAL ENERGY SUBJECTED TO HIGH TEMPERATURE

The present invention relates to an electrical assembly for transferring electrical energy to or from a component that is exposed to high temperatures, such as at least 400°C. Use in automobiles for parts of exhaust lines in general also requires protection against splashes and spills of liquids.

In this thermal environment, most electrical cables used in the automotive sector, such as those specified by standard ISO 19642, have assemblies or insulating sheaths made of polymers, since these types of materials cannot withstand these temperatures. Inappropriate.

In general, solutions based on PTFE are known. However, this solution is limited to a temperature of about 300° C. and is not sufficient.

Cables that withstand such high temperatures are known outside the automotive industry. These cables are usually insulated by a mineral protective material. However, these mineral protective materials, usually composed of porous ceramics, no longer ensure their primary function of electrical insulation when exposed to jets and drips of liquids.

Thus, the present invention relates to an electrical assembly for the transfer of electrical energy having a component exposed to high temperatures, said electrical assembly connectable to a connecting terminal of the component, said conductive cable being integral with the end of said conductive cable and said conductive a connector capable of connecting a cable to the terminal, a sheath surrounding the conductive cable, and a cover surrounding the connector and terminal and capable of connecting the sheath to the component, wherein the conductive cable is electrically insulated and a protective material that withstands high temperatures, and for protecting the conductive cable and its protective material, the sheath, the sheath, and the interface between the sheath and the sheath form a continuous envelope that is hermetic against escaping and dripping of liquid. .

Certain embodiments or features that can be used alone or in combination are as follows:

- Conductive cables include multi-stranded cables, each strand comprising an optional copper core surrounded by nickel or nickel alloy.

- The protective material preferably comprises at least one mineral layer composed of glass fibers, mica fibers or aramid fibers.

- the sheath is made of metal and consists of aluminum or preferably stainless steel;

- The exterior is formed in the form of interlocking rings.

- the sealing at the interface between the sheath and the lid is achieved by at least one baffle;

- the sheath has, at the interface with the sheath, an axial profile that is substantially complementary to the axial profile of the sheath;

- the sheath contains two half shells separated by a plane through which the axis of the conductive cable and the axis of the connector pass;

- the sealing at the interface between the two half shells is achieved by means of obstructions;

- The cover includes a single block body and a cover that fits straight to the connector and terminal.

In a second aspect of the invention, the exhaust gas heater comprises at least one, preferably two, such electrical assemblies ensuring a power supply.

BRIEF DESCRIPTION OF THE DRAWINGS The present invention will be better understood by reading the following detailed description, provided by way of example only, with reference to the accompanying drawings.
1 shows a perspective view of an EHC with connection terminals;
FIG. 2 is a perspective view of a conductive cable, connector and sheath disposed on the EHC of FIG. 1 ;
Fig. 3 is a perspective view of the device of Fig. 2 in which a cover is supplementally provided to form a complete electrical assembly;
4 is a longitudinal cross-sectional view illustrating a conductive cable, its protective material and its sheath.

1 to 3 , a component 10 is shown, for example an EHC (Electrically Heated Catalyst) or an electric heater for exhaust gases. This component 10 is designed to guide the exhaust gas which can reach a temperature of 980°C in a certain direction. In addition, the component 10 may be exposed to high temperatures during operation. This component 10 is an electrical component and therefore requires an electrical supply. This electrical supply is provided to the component via the terminal 11 . The interior of the component 10 may reach 980°C. The outer surface of the terminal 11 and the component 10 can reach a temperature of 350° C. to 400° C. by thermal conduction. The ambient temperature around the component 10 is on the order of 200°C.

The present invention aims to provide an electrical assembly ( 1 ) for transmitting electrical energy, power or measurement results to or from a component ( 10 ). The electrical assembly 1 is located in the outer region of the component 10 . In addition, the electrical assembly 1 is exposed to high temperatures that may reach and/or exceed 400°C. Moreover, it is located in the area exposed to the jet of liquid. The electrical assembly 1 must withstand these high temperatures and the jets and flows of liquids.

For transmitting electrical energy, the electrical assembly 1 comprises a conductive cable 2 . In order to be electrically connected to the connecting terminal 11 of the component 10 , the conductive cable 2 is extended by a connector 3 fixed to one end of the conductive cable 2 . This connector can electrically connect the conductive cable 2 to the terminal 11 . This may be a connector crimped to the conductive cable 2 as shown and comprising connecting means such as an eyelet. Any other means for connecting the connector to the conductive cable 2 are alternatively possible, namely welding, generally ultrasonic welding, screwing, etc.

In order to remain electrically insulated, the conductive cable 2 includes an electrically insulating protective material 6 capable of withstanding high temperatures exceeding 350°C and reaching 1000°C. FIG. 4 shows a conductive cable 2 surrounded by a protective material 6 and surrounded entirely by a sheath 4 in a longitudinal section.

To protect the conductive cable 2 , its protective material 6 and the terminals 11 , so as to be able to withstand splashes and spills of liquids, the electrical assembly 1 also includes a sheath 4 and a cover 5 . do. The sheath 4 surrounds the conductive cable over substantially its entire length, including its protective material 6 . The cover 5 connects the sheath 4 to the component 10 while enclosing the connector 3 and the terminal 11 to which the connector 3 is connected to form a continuous envelope.

The sheath 4 is continuous to provide an immersion seal.

The lid (5) and the interface between the sheath (4) and the lid (5) are sealed against ejection and dripping of liquid.

According to another feature, the conductive cable 2 comprises a multi-stranded cable. Multiple strands can maintain a certain flexibility in the conductive cable 2 . Considering that high current strength is transmitted, the cross-sectional area of the conductive cable 2 is 16 to 50 mm 2 . To withstand high temperatures, each strand of the cable is surrounded by nickel and/or a nickel alloy. The nickel or nickel alloy sheath protects against high temperature corrosion of cores made of other materials such as copper. Each strand may include a copper core. This core can be reduced to zero, so that the entire strand can be made of nickel and/or nickel alloy. Taking into account the size of the cross-sectional area of the conductive cable, the conductive cable 2 comprises one and only one conductor.

According to another characteristic, the protective material 6 surrounds the conductive cable 2 substantially over its entire length. The protective material 6 preferably comprises at least one mineral layer composed of glass fibers, mica fibers, basalt fibers or aramid fibers such as Kevlar®. This technique of protecting conductors with a mineral protective material 6 is known outside the automotive field. This protective material 6 electrically insulates the conductive cable 2 and withstands high temperatures. A disadvantage of these protective materials is that they typically contain ceramics in the form of fibers or sheets that are permeable to water or other liquids. Therefore, it is appropriate to provide an outer envelope that protects the conductive cable 2 and its protective material 6 from any jetting and dripping of liquid. This outer envelope comprises the sheath 4 , the sheath 5 and their interfaces.

According to another feature, the sheath 4 is made of metal to withstand high temperatures while providing sealability against liquids. The metal may be aluminum. Preferably, the metal may be stainless steel.

According to another feature, the sheath 4 may also be formed in the form of interleaved rings. Such a ring can impart a certain deformability to the sheath 4 and thus a certain flexibility, thereby facilitating its installation.

Likewise, the lid 5 is made of metal to withstand high temperatures while providing sealability against liquids. The metal may be aluminum. Preferably, the metal may be stainless steel.

The outer envelope extends at several points, such as the proximal end of the sheath 4 at the interface with one end of the sheath 5 , the distal end of the sheath 4 and the other end of the sheath 5 at the interface with the component 10 . must be sealed.

The sealing at the distal end of the sheath 4 may be achieved by any means. This problem is much less severe, since away from the component 10 and its heat, the temperature is greatly reduced, allowing more general methods to be used.

According to another feature, at the proximal end of the sheath 4 , the sealing at the interface between the sheath 4 and the sheath 5 is realized by a baffle.

The lid 5 may be outside or inside the sheath 4 . The choice depends on the direction of flow of the liquid. Therefore, when the exterior 4 is upward, it is preferable that the exterior 4 covers the lid 5 from the outside. If the sheath 4 is downward, it is preferred that the sheath 4 is inside and covered by the sheath 5 .

According to another feature, the sheath 5 has an axial profile that is substantially complementary to the axial profile of the sheath 4 at the interface with the sheath 4 . Accordingly, when the sheath 4 is formed in a looped configuration, the cover 5 may have a complementary axial profile, that is, a profile formed in a looped configuration opposite to the profile of the sheath 4 . Alternatively, the sheath 5 has a substantially complementary axial profile, ie a profile comprising, for example, a circular blade driven into the hollow in a straight line with respect to each hollow between the two rings of the sheath 4 . can have

According to another feature, the interface between the sheath 4 and the lid 5 comprises a clamp clasp.

According to this embodiment with clasps, the lid 5 is preferably on the inside of the sheath 4 . Thus, the clasp clamps the sheath 4 to the corresponding sleeve of the cover 5 .

The sealing at the other end of the lid 5 in contact with the component 10 may be achieved by any suitable means. Accordingly, it is desirable to reproduce one of the embodiments proposed above for the interface between the sheath 4 and the lid 5 , either provided with a baffle or with a clasp.

The component 10 comprises, for example, a sleeve 13 surrounding the terminal 11 .

The sleeve 13 is cylindrical.

The terminal 11 extends along the central axis of the sleeve 13 .

The sleeve 13 is rigidly fixed to the outer surface of the part 10 .

The lid 5 has a free edge 14 , which in cooperation with the sleeve 13 secures the lid 5 to the part 10 in a sealing manner.

A free edge 14 is arranged around the sleeve 13 . In a variant, the free edge 14 engages the interior of the sleeve 13 .

The free edge 14 has a shape complementary to that of the sleeve 13 and/or is secured to the sleeve 13 by clasps, not shown.

According to another feature, the cover 5 comprises two half shells. These half shells are separated, for example, by a plane through which the axis of the conductive cable 2 and the axis of the connector 3 pass or through which the axis of the terminal 11 passes. This embodiment simplifies the assembly of the lid, in that it clamps, between its two half shells, the sheath 4 at one end and the sleeve of the part 10 at the other end.

According to this embodiment with two half shells, the cover 5 is preferably external to the sleeve and sheath 4 of the component 10 . In order to achieve a seal, the assembly of the two half shells is made by enclosing the sleeve and sheath 4 of the part 10 .

According to another feature, the sealing at the interface between the two half shells is achieved by means of a baffle. This baffle ensures a seal against spouting and dripping of liquid. The cover 5 is formed so that, when liquid penetrates therein, the resulting liquid flow through the joint surface between the half shells occurs to the wall side and cannot reach the surface.

Alternatively, according to another embodiment (not shown), the lid 5 comprises a single block body. In order to be able to proceed with the assembly of the connector 3 and the terminal 11 , an opening in this body is drilled substantially in the axis of the terminal 11 so as to be in line with the connector 3 . This opening can pass through at least one tool for inserting and fixing the connector 3 to the terminal 11 . Thus, as illustrated, when the terminal 11 has a threaded rod provided with a shoulder and the connector 3 includes an eyelet engageable with the threaded rod supported on the shoulder, the fixation is such that the eyelet is attached to the shoulder. A tight fit may be ensured by a nut screwed to the threaded rod. The opening allows passage of the tightening/threading key.

In order to close the opening in a sealing manner, the lid 5 is supplementally provided with a cover, which is advantageously fitted into the opening in a straight line with respect to the connector 3 and the terminals 11 .

According to this second embodiment, in which the lid 5 comprises a single block body, the mounting at the interface between the sheath 4 and the lid 5 is achieved by force. The same is true for mounting at the interface between the lid 5 and the sleeve of the component 10 .

The present invention can be applied to any component 10 that is exposed to high temperatures.

Accordingly, the invention also relates to an exhaust gas heater (10) comprising at least one such electrical assembly (1). To ensure the two-phase electricity supply of this electric heater 10, it is preferable to use two such electrical assemblies 1 to provide two conductive cables 2 .

The invention also relates to a motor vehicle comprising at least one such exhaust gas heater (10).

BRIEF DESCRIPTION OF THE DRAWINGS The invention has been illustrated and described in detail in the drawings and above description. This is to be regarded as illustrative and not to limit the invention to this disclosure alone, but rather by way of example. Numerous implementation variations are possible.

1: Electrical assembly 2: Conductive cable
3: Connector 4: External
5: Cover 6: Protective material
10: part 11: terminal

Claims (11)

An exhaust gas heater (10) comprising a connection terminal (11) and at least one electrical assembly (1) ensuring the supply of electricity to the heater, said electrical assembly (1) being electrically powered by a heater (10) exposed to high temperatures For transmitting energy, the electrical assembly 1 can be connected to a connection terminal 11 , and the electrical assembly 1 is integral with the conductive cable 2 , an end of the conductive cable 2 , and the conductive cable 2 . A connector 3 for connecting the cable 2 to the terminal 11, a sheath 4 surrounding the conductive cable 2, and the sheath 4 surrounding the connector 3 and the terminal 11 In the exhaust gas heater (10) comprising a cover (5) for connecting to the heater (10),
The conductive cable (2) includes a protective material (6) that is electrically insulated and withstands high temperatures, and in order to protect the conductive cable (2) and its protective material (6), the sheath (4), the cover (5) ) and the interface between the sheath (4) and the cover (5) forms a continuous envelope sealingly against ejection and dripping of liquid. The heater (10) of claim 1, wherein the conductive cable (2) comprises a multi-stranded cable, each strand comprising an optional copper core surrounded by nickel or nickel alloy. Heater (10) according to claim 1 or 2, wherein the protective material (6) comprises at least one mineral layer. The heater (10) according to claim 1 or 2, wherein the sheath (4) is made of metal. The heater (10) according to claim 1 or 2, wherein the sheath (4) is formed in a ringed form. The heater (10) according to claim 1 or 2, wherein the sealing at the interface between the sheath (4) and the lid (5) is achieved by at least one baffle. The heater (10) according to claim 6, wherein the sheath (5) has, at the interface with the sheath (4), an axial profile that is substantially complementary to the axial profile of the sheath (4). Heater according to claim 1 or 2, characterized in that the cover (5) comprises two half shells separated by a plane through which the axis of the conductive cable (2) and the axis of the connector (3) pass. (10). The heater (10) according to claim 8, wherein the sealing at the interface between the two half shells is achieved by an obstruction. The heater (10) according to claim 1 or 2, wherein the cover (5) comprises a single block body and a cover that is fitted in a straight line with respect to the connector (3) and the terminal (11). 3. The heater (10) according to claim 1 or 2, wherein the heater (10) comprises a sleeve (13) surrounding the terminal (11), the cover (5) having a free edge (14) cooperating with the sleeve (13) The heater (10) of which the cover (5) is fixed to the heater (10) in a sealing manner.

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