EA042832B1 - ELECTRIC CRIMP CONNECTOR WITH PROTECTIVE ELEMENT - Google Patents

Description

The field of technology to which the present invention relates

The present invention relates to a glazing panel that contains an electrical connector. More specifically, the present invention relates to a vehicle glazing that includes an electrically conductive connector connected to an electrically conductive structure, such as a heated coating or an antenna.

Prerequisites for the creation of the invention

Nowadays, more and more glazing panels are functional units with functions such as lighting, privacy, video, sound, heating, antenna functions and many other functions.

These functional elements are applied to the glazing panel as an electrically conductive structure. Thus, for work, for communication, for food, etc. these electrically conductive structures must be connected to the outside of the glazing by means of a cable crimped with an electrical crimp connector soldered to the electrically conductive structure.

The cable is usually made of metal surrounded by a plastic film. For correct and efficient crimping, the plastic film of the cable is removed only in the crimped area. The plastic film allows you to protect the cable and insulate it. The metal part is made of at least one metal fiber. Depending on the current flowing through the cable and the quality of the cable, the metal part can be made from a variety of fibers. This plurality of fibers may be twisted. The plastic part of the cable keeps the fibers together.

An electrical crimp connector is an element capable of crimping at least a cable. The electrical crimp connector can be implemented as an open or closed crimp. In the case of an open crimp, the electrical crimp connector is provided as a small plate with pre-bent or unbent lugs. These petals are folded or bent around the cable using crimping pliers. In the case of a closed crimping point, the electrical crimp connector is made in the form of a tube or sleeve. The electrical crimp connector is crimped around the previously inserted cable. In both cases, the electrical crimp connector deforms around the cable to secure it.

The electrically conductive structure may be applied to the substrate on only a portion of the panel or on the entire surface by a coating process such as magnetron sputtering, printing, adhesive bonding, or any other means suitable for applying the electrically conductive structure to a glazing panel. The electrically conductive structure may be an antenna for television (TV), digital television (DTV), private modulation (FM) broadcast, amplitude modulation (AM) broadcast, and so on. and can be made, for example, in the form of a wire or a plate on a substrate. The electrically conductive structure may be a coating layer stack with conductive and insulating layers, or may be made of Ag, Cu, or any other suitable metal material or mixture, which may be conductive and printed, glued, etc. on the substrate.

Soldering an electrical crimp connector to an electrically conductive structure requires a certain amount of soldering material. If there is not enough soldering material, the electrical crimp connector is not properly secured and may come off. Even if the correct amount is used, when an electrical crimp connector is soldered to an electrically conductive structure, the soldering material may rise up the cable due to capillarity, also called solder wicking. Due to this effect, the cable is directly soldered to the electrically conductive structure. In case of operations on the glazing panel after the soldering step, operators must coil the cable on the glazing panel in order to be able to operate on this panel without damaging the cable and the entire system.

During the cable folding step, the operator manipulates the cable, and when the cable is soldered directly to the electrically conductive structure, mechanical stresses are applied to the electrically conductive structure and to the substrate, with the risk of breakage, damage, separation of fragments, etc. The plastic part of the cable or the cable itself can also be damaged by soldering material and the heat used to solder.

The soldering material is any known soldering material and may be a lead-free soldering material in accordance with the end-of-life vehicle directive 2000/53/EC. The soldering method may be any known soldering method for this soldering, depending on the material used for the substrate and any part to be soldered.

The following description relates to an automotive glazing panel, but it will be understood that the invention may be applicable to other areas, such as architectural glazing, which may include an electrical functional component or an electrical functional layer.

The present invention provides a solution to overcome these problems.

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The essence of the invention

The invention relates to an improved glazing panel comprising at least a substrate with an electrically conductive structure; a protective element soldered with a soldering material to an electrically conductive structure; an electrical crimp connector attached to said protective element, and an electrical cable crimped with an electrical crimp connector. The invention also relates to the use of a protective element to prevent the wicking effect of the solder contained between the soldering material and the cable crimped by an electrical crimp connector. The invention also relates to a protective element for preventing the effect of capillary flow of solder contained between the soldering material and a cable crimped by an electrical crimp connector containing a protective element.

The invention also relates to the use of a protective element to prevent the effect of capillary flow of solder, located between the soldering material and the cable crimped by an electrical crimp connector; wherein said protective element is soldered to the electrically conductive structure of the substrate.

The invention also relates to a protective element for preventing the effect of capillary flow of solder, located between the soldering material and the cable crimped by an electrical crimp connector containing a protective element.

The protective element protrudes from the specified electrical crimp connector at least in the area of the exit of the specified cable from the specified electrical crimp connector to prevent the effect of capillary flow of solder between the soldering material and the cable.

The substrate may be any substrate on which an electrically conductive structure can be placed. Preferably the substrate is a glass substrate. The glass substrate can be processed, i.e. annealed, hardened, etc.

The electrically conductive structure is applied to at least one part of one surface of the substrate.

The electrically conductive structure may be a heated structure, an antenna, or any other electrically conductive structure that is to be powered by or connected to a cable. The glazing panel may comprise more than one electrically conductive structure.

The main property of the cable, i.e. section, allows you to receive power. The dimensions of the electrical crimp connector may vary depending on the size of the cable.

The electrically conductive structure can be deposited by sputtering, chemical vapor deposition (CVD), plasma chemical vapor deposition (PECVD), etc. for coating layers, for example, or by printing for antenna structures. The material may be any conductive material that can be applied to the glass surface; such as silver, copper or aluminum printed element, metal plating structure, silver, copper or aluminum foil, etc.

An electrical crimp connector is an element that connects an electrical cable to an electrically conductive structure. The electrical crimp connector can be made from copper or brass, aluminium, steel and stainless steel, iron-nickel alloys, titanium, or any conductive metal. In the case of stainless steel, steel, titanium or FeNi alloys. Preferably, the surface may be coated with solderable materials (such as nickel, copper, or silver, or a combination thereof).

The electrical crimp connector is attached directly to the protective element.

In one embodiment of the invention, the electrical crimp connector is soldered to the security element. In another embodiment, the electrical crimp connector is welded to the security element. The crimp connector is spot welded to the protective element. In another embodiment, the electrical crimp connector is ultrasonic welded to the security element. In another embodiment, the electrical crimp connector is riveted to the security element with at least one rivet.

In another embodiment, the cable is directly attached to the protective element. In this embodiment, the electrical crimp connector is a fastener. The cable can be welded or soldered to the protective element. Thus, in this embodiment, the material to be welded or soldered refers to an electrical crimp connector.

It will be understood that the electrical crimp connector may also be a male/female connector or any electrical connector capable of connecting a cable to an electrically conductive structure with a solder material and a protective element.

The cable as a whole is a metal core with a plastic protective layer. The metal core may be a single wire or a plurality of wires and is typically made of copper or aluminum.

The protective element is located between the electrical crimp connector and the electrical conductor

- 2 042832 common design. The protective element is soldered with soldering material to the electrically conductive structure. The protective element prevents the soldering material from rising along the electrical crimp connector and/or the electrical cable. The protective element can be made of copper or brass, aluminum, steel and stainless steel, iron-nickel alloys, titanium or any conductive metal. In the case of stainless steel, steel, titanium or FeNi alloys. Preferably, the surface may be coated with solderable materials (such as nickel, copper, or silver, or a combination thereof).

In another embodiment of the invention, the security element and the electrical crimp connector are made from the same material. The security element and the electrical crimp connector can be made as one piece to facilitate handling, reduce cost, etc.

The soldering material solders the protective element to the electrically conductive structure. Soldering material can be made from lead alloys or lead-free alloys depending on legislation and/or thermal expansion required between the protective element and the electrically conductive structure. In another embodiment, the soldering material may be replaced with a conductive adhesive or adhesive.

According to the present invention, the security element is at least as large as the largest dimension of the electrical crimp connector. The dimensions of the security element are measured on a surface slightly parallel to the surface of said substrate on which the electrically conductive structure is located. Preferably, the protective element is larger than the largest dimension of the electrical crimp connector in order to protect the cable attached to the electrical crimp connector from solder material between the protective element and the electrically conductive structure.

The shape of the protective element has the shape of a surface slightly parallel to the surface of said substrate on which the electrically conductive structure is located.

More preferably, for manufacturing reasons, the shape of the security element is oval. In the case of an oval shape, the size, which must be at least as large as the largest size of the electrical crimp connector, is the largest diameter of the oval shape. In the case of the smallest oval shape, the electrical crimp connector must be fixed in the direction of the largest diameter in order to protect the cable.

In a specific embodiment, the shape is a round shape. The round shape is particularly easy to manufacture and allows the electrical crimp connector to be fixed in any direction.

In another embodiment, the security element has a rectangular shape. Preferably the rectangular shape has corner edges like a polygon. Preferably, in order to facilitate soldering of the protective element to the electrically conductive structure, the rectangular shape has rounded edges.

In one embodiment, the protective element protrudes from said electrical crimp connector at least in the area where the cable exits the electrical crimp connector by at least a diameter of the cable.

figures

The present invention will now be described in more detail with reference to the drawings and exemplary embodiments, which are presented by way of illustration and not limitation. The graphics are schematic representations and are not drawn to scale. The drawings do not limit the present invention in any way. Additional benefits will be described using examples.

In FIG. 1 is a side view of one embodiment of a glazing panel according to the present invention.

In FIG. 2 is a plan view of one embodiment of a glazing panel according to the present invention.

With reference to FIG. 1 and 2 according to one embodiment of the present invention, the glazing panel (1) comprises a glass substrate (2) with an electrically conductive structure (3), a protective element (7) soldered with a soldering material (5) to the electrically conductive structure (3); electrical crimp connector (4) attached to the specified protective element; electrical cable (6) crimped with an electrical crimp connector. The protective element (7) has a round shape and protrudes from the specified electrical crimp connector (4) at least in the area where the specified cable exits the specified electrical crimp connector to prevent the effect of capillary flow of solder between the soldering material and the cable.

In this embodiment, the electrically conductive structure (3) is an antenna structure. The antenna is a layer of silver deposited on the surface of a glass substrate. In the case of a concealed antenna, the antennas are printed on the border of the glazing panel (1) and hidden by a black stripe. The black stripe can be applied to another surface of the glazing panel or between

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Claims (7)

glass substrate (2) and electrically conductive structure (3). The black stripe may be an enamel frit applied by silk-screen printing. In this embodiment, the electrical crimp connector (4) is a connector that crimps the metal part of the cable made of copper. The electrical crimp connector (4) looks like a cuboid and is made of a conductive material such as copper. The diagonal (D) of the surface slightly parallel to the surface of the glass substrate (2) of the electrical crimp connector (4) is the largest dimension. In this embodiment, the protective element (7) is made of a conductive material such as copper. The surface parallel to the surface of the glass substrate (2) of the protective element (7) has a circular shape with a diameter (Dc) larger than the diagonal (D) of the electrical crimp connector (4). In this embodiment, the protective element (7) protrudes from the electrical crimp connector (4) in all directions and especially in the area where the cable (6) exits the electrical crimp connector (4) to prevent the effect of solder capillary flow between the soldering material (5) and the cable (6). The electrical crimp connector (4) is fixed to the protective element by soldering, for example with a high melting point alloy. The size of the electrically conductive crimp depends on the cable and therefore the current flowing through it. In one embodiment, for a low current application, i. e. below 8 A, the diagonal D is approximately 5 mm and Dc is at least 6 mm. The size of the protective element depends on the electrically conductive crimping point. In one embodiment, for a low current application, i. e. below 8 A, the diagonal D is approximately 5 mm and Dc is at least 6 mm. During the manufacture and operation of the glazing panel (1) the operator manipulates the cable (6) and turns it towards the center of the glazing panel (1). Thanks to the protective element, the soldering material does not come into contact with the cable (6), so that the cable (6) can be manipulated without the risk of breaking it. In another embodiment, the cable (6) is directly soldered to the protective element (7). The second soldering material is considered to be an electrical crimp connector. The protective element (7) is larger than the soldering area of the cable (6). In this embodiment, as in other embodiments, the soldering material between the protective element (7) and the electrically conductive structure (3) cannot come into contact with the cable (6) due to the effect of solder capillary wicking, thus limiting the risk of cracking, glass chips or breakage. CLAIM 1. Panel (1) glazing, containing at least: a substrate (2) with an electrically conductive structure (3); a protective element (7) soldered with a soldering material (5) to an electrically conductive structure (3); electrical crimp connector (4) attached to the specified protective element; electrical cable (6) crimped with an electrical crimp connector; characterized in that the electrical crimp connector (4) is fixed on the specified protective element (7) over the soldering material (5) and the specified protective element (7) protrudes from the specified electrical crimp connector (4) at least in the area of the exit of the specified cable from the specified electrical crimp connector to prevent the effect of solder capillary flow between the soldering material and the cable, and the fact that the protective element has an oval shape. 2. Glazing panel (1) according to claim 1, characterized in that the electrical crimp connector (4) is soldered to the protective element (7). 3. Glazing panel (1) according to claim 1, characterized in that the electrical crimp connector (4) is welded to the protective element (7). 4. Glazing panel (1) according to claim 1, characterized in that the electrical crimp connector is riveted to the protective element with at least one rivet. 5. Glazing panel (1) according to claim 3, characterized in that the electrical crimp connector (4) and the protective element (7) are made of the same material. 6. Glazing panel (1) according to any one of the preceding claims, characterized in that the largest dimension of the protective element is at least 10% smaller than the largest dimension of the electrical crimp connector. 7. Glazing panel (1) according to any of the preceding claims, characterized in that said protective element protrudes from said electrical crimp connector at least in the region where said cable exits said electrical crimp connector at least -