Patent Description:
A tight housing, which has an insert with assembled components inside, can be manufactured by an over-molding process. The over-molded housing (which is also referred to as molded housing or housing), seals the insert against media such as fluids or particles. A fluid may be a liquid or a gas. A particle may be for example dust. A liquid may comprise for example water and/or oil As generally known, liquid proof and in particular waterproof can provide protection against dripping liquid, spraying liquid, splashing liquid, jetting liquid (nozzle), or against temporary submersion. The kind of protection is, for example, defined by the Ingress Protection Code (IPC). In particular, for water IP classes are defined. For other liquids, such as oil, corresponding IPCs may be defined. For gases, a leakage rate may be defined. For particles, a particle rate may be defined.

The insert according to the present description is preferably a part for holding an electrical component. Known over-molding process do not lead to a tight, i.e. waterproof, housing. In particular, the problem is that the insert must be positioned in the over-molding tool by means such as a contact element. Thus, the contact element is touching at one or various areas the tool. In those regions, which are referred to as touchpoint, an over-molding of the insert is not possible.

Further, the insert delaminates from the over-molded housing. Delamination is a mode of failure where a material fractures into layers. A variety of materials including laminate composites can fail by delamination. For example, over-molding processes create layers that can delaminate.

As discussed above, the insert is held by the contact element. The touchpoint of the contact element is not over-molded. Thus, the over-molding processes do not lead to a tight housing. For example, liquids such as water and/or particle can enter between the delaminated layers.

It is known to use primer technics on the insert, special surface structures on a surface of the insert, special contact elements, such as retractable pins in a molding tool, coating of the housing, melting rips at the insert, or the like.

However, the above discussed existing technologies are not offering an appropriate solution for more tight housing. In particular, the electrical component may require protection according to a specific IPC. An object of the invention is to provide a solution for an improved sealing against media such as fluids, e.g. water, or particles, e.g. dust.

Further, the electronic component may be used in harsh environments, e.g. must withstand high temperature changes or mechanical loads. For example, the wheel of a vehicle may be provided with a rotation sensor for determining based on rotational speed the pressure level of the wheel. An electrical component installed close to a wheel may experience a plurality of thermal cycles, and thus, the above discussed known technics may not sufficiently seal the insert over the lifetime of the sensor. A further object of the invention is to provide a solution for an improved sealing that can be used under harsh environmental conditions.

Further, sensors for vehicles are mass products, and thus, need to be fabricated economically. It is therefore advantageous to use known process technologies that are readily available. A further object of the invention is to provide a solution for an improved sealing that can be used fabricated economically.

<CIT> relates to a method for producing a printed conductor grid.

<CIT> relates to a conductor track lead frame which is designed to conduct electrical currents, wherein the conductor track lead frame has a core element which has at least one first region coated with a plurality of plastic layers and at least one second region which serves to contact an additional component.

At least one of objects is solved by the independent claims. Advantageous embodiments are solved by the dependent claims.

In particular, the present disclosure proposes welding an insert to an over-molded housing to form a fusion zone for joining the insert and the over-molded housing. In other words, after the insert has been over molded, the layered structure is welded to seal the insert from the touchpoint.

As used in the present disclosure, welding is a fabrication process that joins materials, usually metals or thermoplastics, by using high heat to melt the parts together and allowing them to cool, causing fusion. Welding is distinct from lower temperature techniques such as brazing and soldering, which do not melt the base metal. The fusion zone allows waterproof sealing of the insert in the over-molded housing. In particular, the fusion zone is stable even under harsh environmental conditions.

As used herein, waterproof defines a certain tightness as for example defined by the Ingress Protection Code (IPC).

Further, the present discloses proposes using a radiation source for welding. This allows for laser or electron beam welding. Laser welding is a welding technique used to join pieces of metal or thermoplastics by the use of a laser. The beam provides a concentrated radian energy source, allowing for narrow, deep welds and high welding rates. The process is frequently used in high volume applications using automation, as in the automotive industry.

Equipment for e.g. thermoplastic Laser-welding using e.g. red or infrared light, which covers wavelength larger equal <NUM> and less equal <NUM>, e.g. λ = <NUM> wave length. Such lasers are well established in the market and thus is a readily available technology that is globally available.

Further, as used in the present description, the fusion zone comprises a reversible material. The reversible material is to be melt when heated by the radiation source. Then, the reversible material is cured to seal the insert from the contact element, for example by cooling.

For example, the reversible material can be provided by the insert, and/ the over-molded housing, and/or a part provided in addition to the insert and the over-molded housing.

In more detail, the reversible material is a material that changes a property reversible by temperature. In particular, the reversible material may be melting upon heating with a radiation source. When cooling, the reversible material freezes. Further, the reversible material may expand upon heating and contract upon cooling.

As used in the present description, heat is generated by using the radiation source for welding. Radiation beam welding enables that a predetermined region can be heated while the remaining part of the tool is not heated. This enables reducing process time, costs and protect heat sensitive parts mounted on the insert to be heated.

Upon heating, the reversible material changes its property to melt. The molten material enables to cohesively or adhesively attach to the insert and to the over-molded material. Adhesion is the tendency of dissimilar particles or surfaces to cling to one another. Cohesion refers to the tendency of similar or identical particles/surfaces to cling to one another. Thus, the reversible molten material, which is heated with the radiation source, allows connecting the insert to the over-molding by using the reversible material.

Further, the processes comprise a curing step. As used in the present description, the curing occurs by freezing, i.e. hardening, the liquified molten material, e.g. by cooling. Thus, the curing of the reversible material allows to make the connection permanent.

Additionally, curing may use chemical processes employed in polymer chemistry and process engineering that produces the toughening or hardening of a polymer material by cross-linking of polymer chains. Heat, radiation, electron beams, or chemical additives can for example initiate curing.

Examples of a reversible material are a metal or a thermoplastic. A thermoplastic, or thermosoft plastic, is a plastic polymer material that becomes pliable or moldable at a certain elevated temperature and solidifies upon cooling. The polymer chains associate by intermolecular forces, which weaken rapidly with increased temperature, yielding a viscous liquid. In this state, thermoplastics may be reshaped and are typically used to produce parts by various polymer processing techniques such as injection molding, compression molding, calendaring, and extrusion.

An example of an irreversible material is a thermoset, which forms irreversible chemical bonds during a curing process. In particular, thermosets do not melt when heated, but typically decompose and do not reform upon cooling.

Further, before welding the insert in the over-molded housing, the insert is over-molded.

As used in the description, molding is the process of manufacturing by shaping liquid or pliable raw material using a rigid frame called a mold or matrix. The raw material is for example, a thermoplastic. Over-molding means that a part, here the insert, is covered in the molding process by the raw material. In particular, the part to be over-molded comprises an insert and a contact element. The insert is adapted to carry components to be layered by the raw molding material used during the over-molding. A touchpoint of the contact element is used for holding the part at a molding tool, e.g. a molding cavity. Thus, over-molding allows the insert to be enclosed by the raw material.

Holding the insert with the touchpoint means that the insert is, for example, clamped or fixed or the like to position the insert in the molding tool, e.g. a molding cavity.

As discussed above, the touchpoint of the contact element cannot be over-molded. By the welding step, the fusion zone is created after the over-molding process. The fusion zone joins the insert to the over-molded housing. Further, the fusion zone enables to seal the insert from the touchpoint of the contact element.

According to an aspect, the insert comprises or consists of a first reversible material. Such a configuration enables that the first reversible material can be provided by the insert. Additionally or alternatively, the over-molded housing comprises or consists of a second reversible material. Such a configuration enables that the second reversible material can be provided by the molded housing. In particular, using first and second reversible material enables that both materials can be melting and thus the fusion zone can comprise both materials, which enables a particular strong connection.

In other words, a first faying surface of the insert is liquified and a second faying surface of the over-molded housing is liquefied. As used herein, a faying surface is one of the surfaces that are in contact at a joint.

The first reversible and the second reversible material may be identical or different. At least one of the first reversible and the second reversible material may be a thermoplastic. In particular, the insert may comprise a thermoplastic as the reversible material.

In general, reversible material, and in particular thermoplastics, can be reshaped and are typically used to produce parts by various polymer processing techniques such as injection molding, compression molding, calendaring, and extrusion. Such processes may be used to fabricate the over-molded housing.

According to one aspect, the over-molding step further comprises a step of injecting the molding material in a molding cavity of the molding tool for enclosing the insert, the insert being hold, during the injecting step, in the molding cavity at the touchpoint and curing the molding material to form the over-molded housing.

Injection molding can be performed with a host of materials mainly including metals, glasses, elastomers, confections, and most commonly thermoplastic and thermosetting polymers. Further, a plurality of forms can be used.

Additionally, the material of the over-molding housing can be heated before curing, for example in the molding cavity. Additionally or alternatively, the molding material can be heated before injecting in the material in the molding cavity. In particular, such a process step is optimized for reversible materials such as thermoplastics for fabricating the over-molding housing.

In more detail, thermoplastics are prevalent for injection molding due to characteristics such as ease of recycling, versatility for a wide variety of applications, and ability to soften and flow on heating. Thermoplastics also have an element of safety over thermosets; if a thermosetting polymer is not ejected from the injection barrel in a timely manner, chemical crosslinking may occur causing the screw and check valves to seize and potentially damaging the injection molding machine.

Additionally or alternatively, the insert is fabricated by a molding process. Such a configuration allows a particular economic fabrication for the insert, in particular providing an insert comprising a reversible material comprising or consisting of a thermoplastic, which may be subject of the welding process.

According to the present invention, the welding step further comprises guiding radiation emitted by the radiation source through a transparent layer and absorbing the radiation emitted by the radiation source in an opaque layer. Such an arrangement allows that the fusion zone is protected by the transparent layer, and thus, allows for a particular robust connection.

In particular, the over-molded housing comprises the transparent layer for guiding the light to the opaque layer comprised in the insert. Thus, the insert may be directly heated, and thus, cause the reversible material to melt. Such a configuration allows for an improved quality assurance. In particular, the connection quality of the fusion zone can be determined via the transparent layer by optical devices.

According to a further aspect, the reversible material is opaque for radiation emitted by the radiation source so that the reversible material is directly heated by absorbing the radiation of the radiation source. This may increase the processing speed, namely by directly melting the reversible material. Advantageously, the insert comprises the opaque reversible material.

Additionally, the radiation source emits light with a wavelength larger equal <NUM> and less equal <NUM>. This arrangement allows the use of commercially available laser devices as radiation sources.

In order to provide a particularly strong connection, the method may comprise the step of pressing, during the welding step, the over-molding housing to the insert to reduce a gap between the molding housing and the insert in a welding region.

Additionally, the method may comprise the step of providing a transparent element, during pressing the molded housing to the insert, and guiding radiation emitted by the radiation source through the transparent element. Such an arrangement allows a compact set-up for using the welding step in combination with the pressing step.

According to an aspect, a molded part for waterproof sealing an electrical component solves the above discussed objects. In particular, the molded part comprises an insert for holding the electrical component. Further, the molded part comprises a contact element for positioning the insert in a molding cavity during an over-molding process. Further, the molded part comprises an over-molded molded housing enclosing the insert for protecting the electrical component.

Further, the molded part comprises a fusion zone comprising a reversible material. The fusion zone joins the insert to the molded housing to seal the insert from the contact element. Such an arrangement allows to seal the electrical components.

In particular, the electrical component is for example a lead frame or a magnet. The electrical component may be used for generating a wheel seed sensor for an anti-lock braking system (ABS).

Further, the over-molded housing comprises a transparent layer for guiding light of a radiation source to an opaque layer comprised in the insert for absorbing radiation of the radiation source. Such a configuration allows it to protect the fusion zone by the transparent layer.

In particular, the transparent layer transmits light with a wavelength larger equal <NUM> and less equal <NUM> and the opaque layer absorbs light with a wavelength larger equal <NUM> and less equal <NUM>. Such an arrangement is optimized for using readily available lasers. Further, such an arrangement improves the quality of the connection, for example, by allowing control by quality assurances measuring devices operated in the optical wavelength regime. In other words, it can be optically determined if the fusion zone is joining the insert and the over-molded housing.

According to a further aspect, the fusion zone comprises material of the insert. Additionally or alternatively, the fusion zone comprises material of the over-molded housing. This enables a particular strong connection between the reversible material and at least one of the over-molded housing and the insert.

According to a further aspect, the fusion zone abuts and/or surrounds the contact element. As discussed above, the contact element comprising the touchpoint is not covered by the over-molded housing. Such a configuration is particularly efficient, in particular if the contact element is a pin extending from a surface of the insert and the fusion zone forms a closed path on the surface of the insert around the pin.

The invention will now be described in greater detail and in an exemplary manner using advantageous embodiments and with reference to the drawings. The described embodiments are only possible configurations in which, however, the individual features as described above can be provided independently of one another or can be omitted.

The accompanying drawings are incorporated into the specification and form a part of the specification to illustrate several embodiments of the present invention. These drawings, together with the description serve to explain the principles of the invention. The drawings are merely for the purpose of illustrating the preferred and alternative examples of how the invention can be made and used and are not to be construed as limiting the invention to only the illustrated and described embodiments. Furthermore, several aspects of the embodiments may form-individually or in different combinations-solutions according to the present invention. The following described embodiments thus can be considered either alone or in an arbitrary combination thereof. The described embodiments are merely possible configurations and it must be borne in mind that the individual features as described above can be provided independently of one another or can be omitted altogether while implementing this invention. Further features and advantages will become apparent from the following more particular description of the various embodiments of the invention, as illustrated in the accompanying drawings, in which like references refer to like elements, and wherein:.

The present invention will now be explained in more detail with reference to the Figures. Referring to <FIG>, a flow diagram of a method according to an aspect is described.

The method starts for example with method step S1: providing an insert. The insert being for example fabricated by a molding process, such as injection molding. In particular, the insert can comprise a reversible material such as a thermoplastic. The insert can be an isolating part for isolating electronic components. The insert can hold an electronic component such as a lead frame or a magnet. The electronic components may be used for a wheel speed sensor.

The method can comprise method step S3: holding the insert with a contact element to place the insert in a molding tool. In particular, <FIG> shows the insert <NUM> that is hold by the contact element <NUM> in a molding tool <NUM>. For example, the molding tool <NUM> being a molding cavity used for injection molding.

Further, the contact element <NUM> has a touchpoint <NUM> that is in contact with the molding tool <NUM>, e.g. the molding cavity. This touchpoint <NUM> will appear later as non-over-molded area. In other words, the insert <NUM> can be over-molded except for the touchpoint <NUM> of the contact element.

As for example shown in <FIG>, the contact element <NUM> can be an integral pin of the insert <NUM>. In more detail, the contact element <NUM> is a pin extending from a surface of the insert.

According to an alternative, not shown in the Figures, the contact element can be a pin extending form the molding tool. Thus, a touchpoint located is on a surface of the insert.

Further, as shown in <FIG>, the method can comprise method step S5: over-molding the insert with a molding material to enclose to the insert with the over-molded housing. In particular, as shown in <FIG>, the insert <NUM>, which is hold by the contact element <NUM> at the molding element <NUM>, is over-molded with the over-molded housing <NUM>.

As shown in <FIG>, the insert <NUM> and the over-molded housing <NUM> are delaminated. The space between the insert <NUM> and the over-molded housing <NUM> is typically in the range of <NUM> to <NUM>. Through this space, media such as fluids and/or particles may enter.

<FIG> describes by way of example a process for over-molding the insert. In particular, <FIG> describes an injection molding process. The molding material is inserted in step S53 in a molding cavity of the molding tool <NUM> for enclosing the insert <NUM>. The molding material can be in solid state, e.g. particles such as a granulate, or in liquid state. During injecting the molding material, the insert <NUM> is hold in the molding cavity by the contact element.

According to one example, in a first optional step, the molding material is heated in step S51 to become liquid before injecting. Then, the heated molding material is inserted in step S53 in a molding cavity of the molding tool <NUM> for enclosing the insert <NUM>.

Alternatively, for example if the molding material is a granulated, the molding material is first inserted in step S53 and then heated in step S55 in the molding cavity.

Further, the molding material is cured in step S57 to form the over-molded housing. For example, in case the molding material has been heated in one of steps S51 and S55, the molding material can be cured by cooling down. Additionally or alternatively, the molding material may be cured by a chemical process or by radiation, e.g. ultra violet radiation.

<FIG> shows a schematic of a molded part <NUM>, which is fabricated in line with steps S1, S3, and S5. In particular, the over-molded housing <NUM> encloses the insert <NUM> except for the touchpoint <NUM> of the contact element <NUM>. Further, an outer surface <NUM> of the insert <NUM> is delaminated from an inner surface <NUM> of the over-molded housing <NUM> facing the outer surface <NUM>. Thus, media such as fluids or particles can enter between the insert <NUM> and the over-molded part <NUM>. In particular, water can enter via the opening <NUM> abutting to the not over-molded touchpoint <NUM> of the contact element <NUM>.

As further shown in <FIG>, the method comprises the step of welding S7. Within the welding step, a radiation source <NUM> is used to weld the insert to the over-molded housing to form a fusion zone <NUM>. The fusion zone <NUM> joins the insert <NUM> and the over-molded housing <NUM>.

In particular, <FIG> shows a molded part <NUM> during the welding step. In particular, the radiation source <NUM> emits radiation <NUM>. For example, the radiation source emits light with a wavelength larger equal <NUM> and less equal <NUM>.

Further, according to the example shown in <FIG>, the over-molded housing has a transparent layer <NUM> for guiding the radiation <NUM> to an opaque layer <NUM> formed in the insert <NUM>. In particular, the transparent layer <NUM> comprises material allowing radiation emitted by the radiation source to pass through the material without appreciable scattering of the radiation. Thus, the radiation <NUM> is not substantially absorbed by the transparent layer <NUM>. In other words, the transparent layer <NUM> guides the majority of the radiation <NUM> to the opaque layer <NUM>. Notably, a minor part of the radiation may be scattered or absorbed even in the transparent layer. However, the absorbed radiation is not sufficient to melt the transparent layer <NUM>.

In other words, transparent means that a part of the radiation emitted by the radiation source is guided through the layer. For example, down to <NUM> % of the radiation emitted by radiation source <NUM> may be guided through the layer <NUM>, which thus is transparent. The material and the thickness of the layer <NUM> may be chosen so that the layer <NUM> becomes transparent for a radiation source having for example a wavelength larger equal <NUM> and less equal <NUM>.

Further, according to the example shown in <FIG>, the opaque layer <NUM> comprises material for absorbing the radiation of the radiation source <NUM>. The absorption process transfers the radiation energy in thermal energy heating the opaque layer <NUM>.

Further, according to an example shown in <FIG>, the insert <NUM> comprises the region <NUM>, which comprises reversible material. The region <NUM> is close to or comprises the opaque layer. Thus, by heating the opaque layer <NUM>, heat is conducted to the region <NUM>, thereby heating the reversible material. Further, the thermal energy is sufficient to melt the reversible material, and thus, a fusion zone is formed.

<FIG> shows an example of the molded part comprising the fusion zone <NUM>, which joins the insert <NUM> and the over-molded housing <NUM>.

Further, after curing, the fusion zone <NUM> seals the insert <NUM> from the touchpoint <NUM> of the contact element <NUM>. Thus, the method enables sealing of the insert <NUM> against media in the over-molded housing <NUM>. For example, the method enables waterproof sealing of the insert.

Further, according to an example shown in <FIG>, the over-molded housing comprises region <NUM>, which comprises reversible material. By heating the opaque layer <NUM>, heat is transported, e.g. by conduction or radiation, to region <NUM>. Thus, the reversible material melts and forms the fusion zone <NUM>.

Further, according to a further example shown in <FIG>, the reversible material is provided between the insert and the over-molded housing in the region <NUM>. By heating the opaque layer <NUM>, heat is transported, e.g. by conduction, to region <NUM>. Thus, the reversible material melts and forms the fusion zone <NUM>.

Further, according a not shown example, the reversible material can be provided between the insert and the over-molded housing in the region <NUM>, which is opaque. Thus, the reversible material melts directly and forms the fusion zone <NUM>.

As shown in <FIG>, an outer surface <NUM> of the insert <NUM> becomes in the welding process a first faying surface and an inner surface <NUM> of the over-molded housing <NUM> facing the outer surface <NUM> becomes a second faying surface. As used herein, a faying surface is one of the surfaces that are in contact at a joint, i.e. the fusion zone <NUM>.

Notably, the surfaces <NUM> and <NUM> are indicated as flat surface. A person skilled in the art understands that the surface may comprise ribs, i.e. being structured, or having a micro/macro structured surface, i.e. being a rough surface. In particular, the described method enables to connect rough and/or structured surfaces.

As described with reference to <FIG>, at least one of the first faying surface, the second faying surface, and reversible material between the first faying surface and the second faying surface is melting due to the welding process. According to an example, the first and the second faying surface melt during the welding process.

The arrangement of <FIG> may be further modified. For example, as shown in <FIG>, the insert can have a transparent layer <NUM> for guiding the radiation to an opaque layer <NUM> formed in the over-molded housing. Alternatively, a lateral surface <NUM> of the contact element <NUM> facing the over-molded housing, as shown in <FIG>, may be an opaque layer for absorbing the radiation. Notably, in <FIG> the radiation is guided through a transparent layer of the over-molded housing. Using a transparent layer enables to protect the fusion zone from external influences.

According to a not shown example, the contact element may be heated with light not being guided through a transparent layer but entering, for example, through the opening <NUM> between the touchpoint <NUM> and the over-molded housing.

According to a further aspect, the method may comprise a further step of pressing, during the welding step, the over-molded housing to the insert to reduce a gap between the molding housing and the insert in a welding region as shown in <FIG> and <FIG>.

In particular, as shown in <FIG>, the over-molding part can be provided with a transparent element <NUM>. Light emitted by the radiation source is guided through the transparent element <NUM>. Further, as shown in <FIG>, the method comprises the step of pressing, during the welding step, the over-molded housing to the insert. Thus, a gap, e.g. gap caused by delamination, between the molding housing and the insert in a welding region <NUM> is reduced. The welding region comprises at least one of the faying surfaces <NUM> and <NUM>, wherein the distance between the faying surfaces <NUM> and <NUM> is reduced by the additional pressure.

<FIG> shows a molded part <NUM> according to an example. The molded part <NUM> comprises two touchpoints <NUM> that are not over molded. As shown in <FIG>, the insert is partly shining through the transparent over molded housing.

The detail XIII of <FIG> is shown as a schematic in <FIG>. In particular, as shown in <FIG>, the molded part <NUM> comprises an insert <NUM> for holding an electrical component. The insert <NUM> is shining through the transparent over molded housing <NUM>. The insert <NUM> comprises a touchpoint <NUM> for position the insert <NUM> in a not shown molding tool during an over-molding process. In particular, the touchpoint <NUM> is arranged at contact element, e.g. a pin extending from a surface of the insert <NUM>. The touchpoint <NUM> is not over molded by the housing <NUM>. Further, between the touchpoint <NUM> and the housing <NUM> is an opening <NUM>. Through this opening <NUM> media can enter.

Further, the over-molded housing <NUM> encloses the insert <NUM> for protecting the electrical component. In particular, the over-molded housing <NUM> is transparent for optical light so that the insert <NUM>, which is opaque for optical light, is optical visible. A person skilled in the art understand that the insert <NUM> does not have to be optically visible. For example, insert may be opaque for the light emitted by the radiation source.

Further, the molded part comprises a fusion zone <NUM>. The fusion zone comprises a reversible material, wherein the fusion zone joins the insert to the molded housing to seal the insert <NUM> from the touchpoint <NUM>. In particular, the fusion zone forms a closed path, e.g. an annular ring or an elliptical ring, on the surface of the insert <NUM> around the pin. Thus, media entering through opening <NUM> are blocked by the fusion zone <NUM>.

<FIG> shows the fusion zone <NUM> in a cross section. In particular, the fusion zone <NUM> is abutting to the insert <NUM> and the over-molded housing <NUM>. According to the present example, the insert <NUM> is made from an opaque material and the over-molded housing <NUM> is made from a transparent material. The fusion zone <NUM> shows a transition region comprising the opaque material and the transparent material.

The arrangement of <FIG> may be further modified. For example, similar to the arrangement of <FIG>, the insert <NUM> may comprise a pin. The over-molded housing <NUM> may surround the pin, i.e. the over-molded housing <NUM> may comprise a cylinder part surrounding the pin. A lateral surface of the pin forming the contact element facing the cylindrical part of the over-molded housing <NUM> may be an opaque layer for absorbing the radiation. Notably, different to the arrangement to <FIG>, the radiation is guided in <FIG> through a transparent layer of the cylindrically shaped over-molded housing that surrounds the pin. Thus, an extending pin arrangement may comprise the fusion region <NUM>.

According to a further modification, shown in <FIG>, the fusion region <NUM> may be formed on two surfaces having an edge, in particular the edge formed by the contact element extending from the insert <NUM>. The radiation source may be arranged inclined relative to the normal of a surface of the insert <NUM> and inclined relative to the normal to a surface of the contact element. Thus, the sealing properties may be increased by welding the edge region. According to an example, the insert <NUM> comprises ZYTEL 77G33L, a registered trademark for a product from DuPont. In particular, the insert comprises long chain polyamide resins. Further, the over-molded housing comprises NC010, in the color: nature, NC010 being a registered trademark for product from DuPont. In particular, the over-molding material is delivered as granulate that can be used for injection molding, profile extrusion, sheet extrusion, other extrusion.

According to a not shown embodiment, at least one of a primer technics on the insert, special surface structures on a surface of the insert, special contact elements, such as retractable pins in a molding tool, coating of the housing, or melting rips at the insert may be used to further seal the insert from the touchpoint.

Claim 1:
Method for sealing of an insert (<NUM>) in an over-molded housing (<NUM>) against media, the method comprises the steps of:
Holding (S3) the insert at a touchpoint (<NUM>) to place the insert in a molding tool (<NUM>);
Over-molding the insert with a molding material to enclose to the insert with the over-molded housing (<NUM>); and
Welding, using a radiation source (<NUM>), the insert to the over-molded housing to form a fusion zone (<NUM>) for joining the insert (<NUM>) and the over-molded housing (<NUM>),
wherein the fusion zone comprises a reversible material, the reversible material to be melt when heated by the radiation source and to seal, when cured, the insert from the contact element,
characterised in that
the welding step further comprises guiding radiation emitted by the radiation source through a transparent layer and absorbing radiation emitted by the radiation source in an opaque layer.