DE102016208782A1 - Method of encasing an electrical unit and electrical component - Google Patents

Abstract

The invention relates to a method for sheathing an electrical unit, wherein the electrical unit is connected to a leadframe and sheathed twice. The invention further relates to an associated electrical component.

Description

The invention relates to a method for sheathing an electrical unit and to an electrical component which has been produced by means of such a method.

Components can be used, for example, in the form of sensors for measuring accelerations or yaw rates, or also for other measured variables, such as magnetic rotating fields or currents, and for forwarding the pre-processed measurement signals to a higher-level evaluation electronics or control system. Such components may for example have a populated printed circuit board on which various electrical or electronic components are present.

In known manufacturing process, a populated printed circuit board is pressed for example in a thermoplastic housing, wherein subsequently a lid is poured and cured or is lasered. Different designs and manufacturing concepts are known in this regard for different types of components, in particular for different types of sensors.

A disadvantage of the known embodiments is in particular that the respective circuit board is located in a cavity. Diffusing moisture can lead to migration, corrosion and short circuits. It has been shown that customer-specified requirements with regard to the installation space can not always be fulfilled. In addition, a shield is displayed only with great effort. Highest tightness classes typically can not be achieved. A wide variety of designs and manufacturing processes or systems is required. In addition, with the known manufacturing processes, a great design, qualification and support effort goes hand in hand.

It is therefore an object of the invention to provide a method for covering an electrical unit, which in particular avoids at least one or more of the disadvantages mentioned. It is a further object of the invention to provide an electrical component which has been produced by a method according to the invention.

This is inventively achieved by a method according to claim 1 and an electrical component according to claim 15. Advantageous embodiments can be taken, for example, the respective subclaims. The content of the claims is made by express reference to the content of the description.

• – Verbinden der elektrischen Einheit mit einem Leadframe,
• – Anbringen eines der elektrischen Einheit zugeordneten Abschirmblechs, dann
• – Ummanteln der elektrischen Einheit und des Abschirmblechs mit einem ersten Kunststoffmaterial zur Ausbildung eines inneren Moldkörpers, so dass eine Mehrzahl von Kontakten der elektrischen Einheit aus dem inneren Moldkörper herausstehen,
• – Ausstanzen des inneren Moldkörpers aus dem Leadframe,
• – zumindest teilweises Ummanteln des inneren Moldkörpers mit einem zweiten Kunststoffmaterial zur Ausbildung eines äußeren Moldkörpers.

The invention relates to a method for covering an electrical unit, the method comprising the following steps:

• Connecting the electrical unit to a leadframe,
• - Attaching one of the electrical unit associated shielding plate, then
• Sheathing the electrical unit and the shielding plate with a first plastic material to form an inner mold body so that a plurality of contacts of the electrical unit protrude from the inner mold body,
• Punching out the inner mold body from the leadframe,
• - At least partially sheathing the inner mold body with a second plastic material to form an outer mold body.

In carrying out the method according to the invention, the electrical unit is completely enclosed by a typically chemically and mechanically stable plastic material. No corrosion, migration and short-circuiting are to be expected. In addition, ultrasonic welding of additional components can be used. Compared to process guides, which are known from the prior art, fewer processes are required overall, which speeds up and simplifies the process.

Furthermore, the integration of a shielding plate is particularly easy in the process control according to the invention. In process guides known from the prior art, a considerably greater effort was required for this in order to enable a reliable attachment of such a shielding plate. In particular, a shielding plate can improve the interference immunity of electronics and / or sensors.

The joining can be understood in particular to include pressing in, soldering such as hard or soft soldering, gluing, welding such as ultrasonic welding, laser welding or resistance welding, or also sintering. In the bonding step, the electrical unit is typically reliably connected to the leadframe for the remainder of the process to be held in the leadframe. The leadframe may include, for example, plug or crimp terminals. More generally, metal strips for external contacting may already be part of the leadframe.

The leadframe may have index holes and thus additionally serve as a transport and adjustment aid.

The electrical unit may for example be any electrical component which is suitable for performing any electrical functions.

Furthermore, a shunt resistor can also be attached, which in particular can have a section which is formed from manganin. This is a typically used and proven resistance material, which allows a reliable measurement of the current flowing through tapping the voltage drop across it. Instead of manganin, for example, another resistance material, in particular another copper-nickel-manganese alloy, can be used. The shunt resistor can be contacted, for example, at two points or at more points, for example at four points. The latter allows in particular a four-point measurement, which may be advantageous, for example, in the case that a non-temperature-stable material is used.

It should also be mentioned that the electrical unit or a printed circuit board can be fully enclosed by means of the method according to the invention, namely by a chemically and mechanically stable thermoset material. No corrosion, migration and short-circuiting are to be expected. This meets the highest requirements for mechanical and chemical resistance. A shield is displayed without significant additional effort.

It should also be mentioned that in the method according to the invention, a design for a neutral part can be set and only needs custom Umspritzungsvarianten needs to be varied. This means a significantly lower investment, fewer core processes and high volumes for the neutral part. Subassemblies with a lower number of pieces can be cost-effectively co-produced. The qualification, design and support effort is reduced.

According to an embodiment, the shielding plate is attached by a step of punching out the shielding plate from the leadframe prior to the step of connecting the electrical unit to the leadframe. This allows a particularly simple provision of the shielding plate, which can be produced for example as part of the leadframe.

The shielding plate may be formed as a molded part and be attached by pressing into the electrical unit. This allows a separate production of the shielding and a greater freedom of design.

The shielding plate can in particular be mounted parallel to the electrical unit. This may relate in particular to respective extensions of the shielding plate or an electrical unit, which may be designed in particular as a plate. Thus, a particularly advantageous shielding effect can be achieved.

The shielding plate may be formed according to an advantageous embodiment as a trough, which receives the electrical unit. Thus, a multi-sided enclosure of the electrical unit can be achieved. The tub can preferably be covered by means of a tub cover. This can be achieved particularly advantageous all-round enclosure of the electrical unit. This allows a particularly advantageous protection against electromagnetic radiation and other comparable influences.

As an electrical unit, a populated printed circuit board is preferably used. This may in particular be a circuit for measuring currents. For such printed circuit boards, the method has proven to be particularly advantageous. For example, an integrated circuit (IC) may also be used. In particular, this can be designed for a sensor.

The circuit board may for example be rigid, flexible or made of ceramic.

As a first plastic material, in particular a thermoset material can be used. This is in particular chemically and mechanically stable.

As a second plastic material, in particular a thermoplastic material can be used. This is easy to apply and has proven itself as an external protection.

If contacts are to be connected during the process, these can in particular be connected to another element, in particular a shunt resistor, by welding, brazing, ultrasonic welding, laser welding, gluing, soldering, sintering and / or resistance welding. Such methods have been proven for typical applications.

The step of connecting the contacts to the shunt resistor is performed according to an embodiment after the step of covering with the first plastic material. Alternatively, the step of connecting the contacts to the shunt resistor may be performed prior to the step of wrapping with the first plastic material.

• – Abdecken des Sensors mit einem Schutzmaterial, insbesondere mit einem niedrigviskosen Material, bevorzugt mit einem Glob-Top-Material.

According to a development, at least one sensor is applied to the electrical unit, and the method comprises the following step before the step of covering the electrical unit and the shielding plate with a first plastic material:

• - Covering the sensor with a protective material, in particular with a low-viscosity material, preferably with a glob-top material.

Such an embodiment leads to a particularly advantageous further protection of the sensor, which thus can be protected against chemical and / or mechanical damage.

The step of wrapping with the first plastic material and / or the step of wrapping with the second plastic material according to respective embodiments each completely encased, optionally with the exception of protruding contacts. This has proved particularly useful because in this way a particularly good chemical and mechanical protection is achieved.

The inner mold body is preferably connected after the step of wrapping with the first plastic material with a number of inserted or anchored support webs with the leadframe. This facilitates the process control and ensures a defined position of the inner mold body.

In this case, for example, solid support webs, retractable support webs and versions without support webs can be used. This will be discussed further below.

An inserted support web can in particular be understood as a support web which can be completely removed from the mold body during punching. Under an anchored support web can be understood in particular a support web, which is anchored in the mold body such that a part of the support web in each case remains in the mold body.

In the inner mold body, a number of convex and / or concave contours are formed according to an embodiment. These can be used for adjusting other components or even during Moldens for fixing the first mold body in a second Moldtool, so a Moldtool for forming the outer mold body.

The contacts may advantageously each have a number of beads. This facilitates handling and leads to a better grip in surrounding structures. In addition, a creepage distance for any penetrating liquid is extended.

The electrical unit may have a number of holes for anchoring in the first plastic material. This improves the hold of the electrical unit in the first plastic material, which prevents production errors.

In the step of wrapping with the second plastic material, a plug is preferably formed, which allows easy provision of a connection component. Inserts can also be embedded so that prefabricated elements can be used and easily co-processed.

In the step of wrapping with the second plastic material preferably a rivet is gemoldet, in particular for connection with an additional component. This allows easy attachment and alignment of the additional component.

According to a development, an additional surface activation of the inner mold body can take place, in particular before the step of wrapping with the second plastic material.

This leads to an improved adhesion of the outer mold body on the inner mold body.

As a material for the outer Moldkörper, so as a second plastic material, in particular PA (polyamide), PBT (polybutylene terephthalate), hotmelt or PU (polyurethane) can be used. The sheathing with the second plastic material can be done in particular by injection Molden or RIM Molden.

It should be noted that, in particular, a step of connecting at least a first contact and a second contact to a shunt resistor may be performed. This can be done in particular before wrapping with the second plastic material to form an outer mold body. Thus, for example, a battery sensor can be advantageously formed.

The second mold body is formed according to an advantageous embodiment, at least partially in the form of a cage structure surrounding the inner mold body.

Due to the design as a cage structure is advantageously achieved that a decoupling takes place between the outer mold body and inner mold body. This can help avoid distortion of the inner Moldkörper by the outer Moldkörper. For example, it is possible to form protectors against static and dynamic forces which protect the entire unit. In contrast to a full deformation with thermoplastic or more generally the second plastic material is given here the advantage of decoupling the two sheaths through a gap. Thermomechanical forces, for example, a thermoplastic on a thermoset and from there to a sensor element are largely prevented.

Preferably, the outer mold body lies only partially on the inner mold body and is partially spaced from the inner mold body. This allows an advantageous decoupling to avoid the emergence of voltages which can falsify, for example, measurement results of a sensor.

According to an advantageous embodiment, the outer mold body has a cage region with a number of struts or brackets spaced apart from one another, which are each spaced from the inner mold body. This allows protection of the inner mold body similar to a surrounding bicycle helmet. If, for example, impacts on the outer moldings occur, they are not forwarded directly to the inner mold body, which likewise helps to avoid tension and associated measuring errors.

According to a preferred embodiment, a part of the inner mold body adjacent to the outer mold body is at least partially surface-treated before application of the outer mold body, in particular by means of plasma treatment or laser treatment, in order to achieve a seal against the ingress of liquid. By means of such a surface treatment, a leak possibly resulting from the embodiment with an outer mold body which is only partly formed, which could lead to the ingress of liquid, is closed. A failure of the installed electrical or electronic components by diffusing moisture is effectively prevented in this way.

The invention further relates to an electrical component which has been produced by means of a method according to the invention. Regarding the method can be used on all embodiments and variants described herein.

The outer mold body is typically, optionally with protruding contacts, the device.

Further features and advantages will be apparent to those skilled in the embodiments described below with reference to the accompanying drawings. Showing:

1 to 9 : possible states in a method according to the invention,

10 a modification with pins that are transverse to a printed circuit board,

11 a variant with only a partial envelope,

12 : a modification with additionally protected sensor,

13 : the modification of 12 in a later process step,

14a . 14b a modification with only partial wrapping and trained protectors,

15 a modification with a cover tray,

16 : the modification of 15 in a side view,

17 : the modification of the 15 and 16 at a later stage of the procedure,

18 : the state of 17 in a side view,

19 a modification with additional support bars,

20 : the state of 19 in a side view,

21 a modification with embedded measuring resistor,

22 : the modification of 21 in a top view.

1 shows an arrangement, as typically occurs at the beginning of a method according to the invention.

Outboard is a leadframe 10 arranged in which index holes 11 are formed. The leadframe 10 serves for stabilization and transport, by means of the index holes 11 can be easily grasped and moved. The index holes 11 serve in particular for transporting the leadframe 10 and for fine fixing in a Moldtool. The index holes are used to mechanically adjust the leadframe 10 and thus the already assembled component or a sensor in the various devices and / or Moldtools, which are used in the context of the method.

The leadframe 10 has dambars 12 on which the leadframe 10 stabilize and as well are designed for attaching other components. In the dambars 12 are fixation holes 13 formed, which for fixing the leadframe 10 or other components can serve. The fixation holes 13 are used in particular for fixing the punched-out part in the Overmoldtool.

The leadframe 10 further includes a number of presently three terminals in the form of connector terminals 14 which serve as electrical contacts after completion of the manufacturing process. Furthermore, the leadframe points 10 two shunt connection terminals 15 on, which serve to connect a shunt resistor. In addition, the leadframe points 10 an anchored support bar 16 and an inserted support bar 18 on. Their function will be discussed later. It is understood that from the supporting webs 16 . 18 each one or a plurality may be present.

With the leadframe 10 is an electrical unit in the form of a printed circuit board 20 connected. The circuit board 20 is at the connector terminals 14 and the shunt connection terminals 15 attached, in the present case soldered. However, in principle, the other connection techniques described above can also be used here, for example press-fitting. This ensures a firm connection between the circuit board 20 and the leadframe 10 ,

To protect the circuit board 20 against electromagnetic influences is a shielding plate 45 appropriate. This is parallel and above the PCB 20 arranged.

Furthermore, in the circuit board 20 a number of holes 24 formed, which serve the fixation in a mold body described below.

In 1 is the printed circuit board 20 shown in the leadframe network. The circuit board 20 serves here in particular as a wiring carrier for sensors and additional circuitry. As sensors, for example, acceleration sensors and yaw rate sensors in any combination are possible. Similarly, magnetic field sensors and current sensors can be used or manufactured. The circuit board 20 can through the extra holes 24 be better anchored in the thermoset mold body described below.

In the lead frame 10 are preferred the connector terminals 14 already pre-punched. It is also possible to use the leadframe 10 in a separate connection process with the connector terminals 14 connect to.

The shielding plate 45 can directly from the leadframe 10 be punched or as a molded part in the circuit board 20 be pressed.

The circuit board 20 will be in the leadframe 10 preferably pressed. But there are also other connection techniques, such as soldering and gluing, conceivable.

For non-straight connector terminals 14 can be molded connector terminals 14 be attached. The connection of the leadframe 10 with the molded connector terminals 14 can be produced by welding, soldering, gluing or splicing.

In addition to one regarding the connector terminals 14 parallel position of the circuit board 20 like this in 1 shown, a vertical position is also displayed. This will be further down in 10 shown.

2 shows the arrangement of 1 in a side view after pressing. It can also be seen that on the circuit board 20 a sensor 6 and also a number of electrical components 9 are arranged. These are present in SMD technology on the circuit board 20 applied.

In 3 is a state after the application of a first Moldkörper 30 shown. The circuit board 20 is from the first mold body 30 surrounded, which consists of a thermoset material. The first mold body 30 can also be referred to as an inner mold body. The first mold body 30 was by sheathing the circuit board 20 produced by means of a thermoset material.

As in 3 can be seen, both the anchored support bridge protrude 16 as well as the inserted support bar 18 in the first mold body 30 into it. The anchored support bridge 16 is designed so that it has a barb in the first mold body 20 Has. That is why he is also called "anchored". The inserted support bar 18 however, has no barbs, so that it is easy and complete from the first mold body 30 can be pulled out. The anchored support bridge 16 In any case, it remains partly in the first mold body 30 , being with his outside of the first mold body 30 lying part can be canceled.

The first mold body 30 ensures in particular by its thermoset material for a chemical and mechanical protection of the circuit board 20 , where only the connector terminals 14 and the shunt connection terminals 15 from the first mold body 30 stand out.

As will be shown below, the two shunt connection terminals 15 U-shaped, leaving a connection from the circuit board 20 to an area next to the circuit board 20 is trained. As will also be shown below, this serves to connect a shunt resistor.

The assembled circuit board 20 has no contact with the outside world in the state shown. It is completely surrounded by a thermoset material. This increases the risk of moisture or corrosive media on the circuit board 20 or the sensor, low. Mechanical stresses on the assembled components of the printed circuit board are low or negligible, since the coefficient of expansion of the thermoset material is approximately equal to that of the printed circuit board 20 and the components on it. In addition, the adhesion of the materials to each other is very good.

The support bars 16 . 18 can be designed to be embeddable or anchored. They serve to support the Moldkörper, which is held only on one side of Dambarseite, in addition to gravity-induced bending. These webs have no connection to the circuit board 20 ,

4 shows the arrangement of 3 in a side view.

It can also be seen that only the terminals 14 . 15 over the first mold body 30 protrude. Basically, it should be mentioned that the shunt connection terminals 15 also under the first mold bodies 30 can protrude.

5 shows the in 4 illustrated arrangement in a modification. It was in the mold body 30 in the present case two concave fixations 32 and two convex fixations 34 educated. The fixations 32 . 34 serve to the Moldkörper 30 to anchor or fix in a parent structure or other components to the mold body 30 to install. In particular, they provide the possibility of forming form-fitting connections with other components or superordinate structures, for example with a mold tool for a further jacket. For example, they serve to position and lock the thermoset molding 30 in the thermoplastic overmold tool. The fixations 32 . 34 can also be referred to as contours. It should be noted that the fixations 32 . 34 or corresponding elements, for example, laterally, ie transversely to the paper plane of 5 can be trained.

6 shows the arrangement of 3 after punching out the first mold body 30 from the leadframe 10 , Here are the circuit board 20 with the surrounding first Moldkörper 30 to recognize, with the terminals connected 14 . 15 from the first mold body 30 stand out, which was originally part of the leadframe 10 were. As can also be seen, remains a small part of the anchored support web 16 in the first mold body 30 , The rest of the leadframe 10 is still visible outside.

In the circuit board 20 are as already described above, a number of now no longer seen anchor holes 24 formed, which better fixation of the circuit board 20 in the first mold body 30 serve. Furthermore, to the right of the first mold body 30 be formed a decoupling zone, not shown, in which a certain mobility between the terminals 14 . 15 and the circuit board 20 or the first mold body 30 is provided. The decoupling zone has become particularly effective in ultrasonic welding of the shunt connection terminals 15 to a shunt resistor found to be advantageous because possibly leading to delamination Schwingungseinkopplungen in the first Moldkörper 30 be prevented.

In the free punched part are now the terminals 14 . 15 designed as single pins. If necessary, a programming pin can be provided, which is no longer accessible after the final mold.

All terminals 14 . 15 can be beaded to extend the creepage distance for moisture and provide better anchoring in the overmold.

According to one possible embodiment, an in 6 not shown bead may be provided, which extends a creepage distance for moisture and allows better anchoring in a subsequently formed second mold body.

Starting from the in 6 shown state can be in 6 not shown shunt resistor, which is below as shunt resistor 40 is shown. The shunt resistor 40 can be present by ultrasonic welding welding at the shunt connection terminals 15 be attached. In principle, other connection techniques as described above can also be used. By the arrangement shown, a voltage can be measured, which corresponds approximately to a width of the first mold body 30 at the shunt resistor 40 drops. This allows a conclusion on the current flowing through.

7 shows a state of the arrangement of 6 after applying a second Moldkörpers 50 , The second mold body 50 can also be referred to as an outer mold body. The second mold body 50 in the present case consists of a thermoplastic material and surrounds the printed circuit board 20 and the first mold body 30 as well as mostly the shunt connection terminals 15 , the connector terminals 14 and, if present, the shunt resistor, not shown here 40 , A shunt connection terminal 15 , which is shown in the picture above, is slightly modified in terms of its contacting to the outside, in particular in comparison to in 6 illustrated state.

The connector terminals 14 stand over the second mold body 50 protruding, so that an electrical contact of the circuit board 20 is possible. Furthermore, if available, there are a first contacting surface and a second contacting surface of the shunt resistor 40 over the second mold body 50 to allow external components to be connected. For example, other electrical units or an external circuit can be connected to these contacting surfaces, one by the shunt resistor 40 flowing current from the circuit board 20 can be measured. Corresponding signals indicative of such a current may be provided via the connector terminals 14 be given to other units.

The final envelope of the thermoset molded circuit board 20 is particularly preferably carried out with a thermoplastic material.

In this operation is present also a plug 56 formed. If necessary, other inserts, such as sleeves, pivot bearings, shunts, etc. are embedded in the thermoplastic body.

It should be noted that it can further be seen here that in the second mold body 50 an insert in the form of a fastening part 53 located. This allows, for example, attachment to other components.

8th shows the arrangement of 7 in a side view. With regard to the individual features, reference is made to the above description.

At the bottom of the second mold body 50 is furthermore a rivet 52 designed for hot caulking. Besides, right is the plug 56 formed, which a simple contacting of the connector terminals 14 and / or the shunt connection terminals 15 allowed.

It can also be provided a molded Fixierungsnippel or Befestigungsdom.

The in the 7 and 8th shown finished arrangement after completion of a possible embodiment of the method according to the invention can be used as an electrical component 5 be designated. This can be used in a higher-level component or in a unit such as a motor vehicle, in particular to measure a current.

For the fixation of the thermoset body or first mold body 30 in the Overmold tool different Pinkonfigurationen are possible, which are schematically in 9 are shown. In 9 is a modification to the execution 8th shown.

On the one hand, a retractable support pin or support bar can be used. After closing the tool, it will be withdrawn accordingly. One possible result is in 9 with reference number 32a shown.

A fixed support pin or support bar can also be used. The support pin forms the contour in the overmold. One possible result is in 9 with reference number 32b shown.

It is also possible to use a version without a support pin or support bar. The raised contour of the thermoset body serves, for example, as a spacer in the Overmoldtool. One possible result is in 9 with reference number 32c shown.

Likewise, the already mentioned Fixierungsnippel 52 be used.

In 10 a modified embodiment is shown, in which the circuit board 20 perpendicular to the connector terminals 14 is pressed. As a result, other sensing directions, for example, can be realized in the case of sensors with sensing axes that are orthogonal to the measuring direction.

In 11 a modification is shown in which the thermoplastic casing or the second Moldkörper 50 is designed by partial shaping so that the thermo-mechanical stress is minimized on the sensor element. The second mold body encloses the first mold body as shown 30 not completely, but only partially.

In 12 is a modification of a state before the application of the first mold body 30 shown in which above the sensor 6 a serving 7 from a low-viscosity material, in particular Globtop was applied. This serves in particular to protect the sensor against thermo-mechanical stress in a special way.

13 shows the execution of 13 after ummolden with the two Moldkörpern 30 . 50 , ie in particular as a finished component 5 ,

14a shows a modification of a finished device 5 in which the second mold body 50 the first mold body 30 not completely encloses, but only partially. 14a shows a plan view. 14b shows the state of 14a in a side view.

In the respective right part of the 14a . 14b are the two mold bodies 30 . 50 executed immediately adjacent to each other. It is between the two Moldkörpern 30 . 50 an interface 59 formed, which is to be protected in a special way against ingress of moisture. This will be discussed further below.

In the respective left part of the 14a . 14b is the second mold body 50 in the form of protectors 58 educated. These enclose the first mold body 30 only partially, leaving the first mold body 30 can still be seen.

The protectors 58 are similar in terms of their effect designed a bicycle helmet, ie they hold shocks from the first mold body 30 remote and ensure a mechanical decoupling between the two Moldkörpern 30 . 50 , As a result, the occurrence of mechanical tension in the first mold body 30 , which can lead to falsified measurement results, for example, in sensors, can be effectively prevented. In particular, for example, the occurrence of thermal stresses can be prevented with temperature changes.

Generally, it should be noted that thermoset material is typically hard and brittle. To protect this against mechanical damage, it can by the protectors 58 protected against static and dynamic forces. These protectors 58 are in this case bow-shaped, for example, similar to a bicycle helmet, and hold external forces from the epoxy mold or from the first mold body 30 remote.

In contrast to a full enclosure with thermoplastic, which, for example, in 7 is shown in the execution of 14a . 14b the advantage of decoupling the thermoset from the thermoplastic enclosure given by a gap. Thermomechanical forces of the thermoplastic on the thermoset and from there to a sensor element are largely prevented.

A gap formation between protectors and thermoset housing is produced, for example, by a special adjustment of the overmold process or tool-bound.

In addition, the exposed surfaces of the thermoset may serve to support the thermoset preform in the thermoplastic overmold tool.

In an adhesion zone or the interface 59 , which is achieved by special surface treatment of the thermoset body, there is an increased adhesion of the thermoplastic to the thermoset. This ensures that no corrosive or conductive materials or liquids penetrate into the contact area of the Duroplastkörpers and there damage or short circuit the electrical contact. The surface treatment or surface treatment of a thermoset body or more generally of the first mold body 30 can be done in particular by plasma treatment or by laser treatment. This has proven itself for producing the desired permanent tightness.

It is advantageous if, as shown here, the circuit board 20 mechanically and chemically protected in two molding steps.

In special applications, additional adhesion of the overmold to the thermoset mold can be achieved by additional surface activation of the thermoset body.

It is advantageous if the fully calibrated and tested sensors can be used as BGA or QFN (with and without internal additional circuitry). On the circuit board 20 This makes a customer-specific wiring possible without increased effort. The connection technique is preferably in soldering, as was provided in the design of the sensor. In particular, but not only, in BGA versions, the Duroplastmold can also be used as Underfiller.

Also advantageous is the production of a neutral part made of duroplastic, which can then be custom molded with a thermoplastic or thermoset or elastomer.

In a special form, the plug can be replaced by a cable.

It is advantageous if the dimension of the printed circuit board is standardized, since then the production facilities can be optimized to this / this format (s). This corresponds to the strategy of the IC manufacturers by the determination of the housing form.

It is advantageous in this context, when the leadframe acts as a holder, adjustment and electrical contact with the circuit board. Thereby needs the PCB 20 even no direct connection to the outside. It is completely enveloped by the thermoset material, which lies very close to the printed circuit board material in the coefficient of expansion. The only access point for contaminants is in the area of the terminals. However, these channels are advantageously sealed because the thermoset material enters into a connection with the leadframe materials.

In a further embodiment, the circuit board 20 be replaced by one or more integrated circuits (IC), which are connected by means of suitable techniques such as soldering, gluing or welding to the leadframe. Additional circuits such as capacitors can be fitted directly to the lead frame terminals within the thermoset.

As final encapsulation materials, generally referred to in the text as thermoplastic, are typically PA, PBT, hotmelt or PU into consideration. The final coating can typically be done by injection mint or RIM mellow.

It should be noted in general that in this description is often spoken of a thermoset, a thermoset material or a thermoset material for the inner mold body and also of a thermoplastic, a thermoplastic material or a thermoplastic material for the outer mold body.

This refers only to the currently considered most suitable execution. It should be understood that these terms can in principle be generalized, in particular to more general plastic materials or in general materials or moldings. The disclosure of this application fully encompasses a corresponding modification or generalization.

The 15 shows an alternative embodiment in a process stage before applying the first mold body 30 , wherein instead of a mere shielding a shielding tray 45 is used. The shielding tray 45 can, as in 15 represented, in particular with the leadframe 10 be formed, wherein the circuit board 20 in the trained shielding tub 45 inserted or otherwise introduced.

16 shows a side view of the in 15 shown state. Here is the shielding tray 45 to recognize in their tub-like training. Covered is the shielding tub 45 with a lid 46 , This ensures an all-round enclosure of the circuit board 20 and thus for a particularly effective protection against electromagnetic interference.

Furthermore, it can be seen that printed circuit board 20 and shielding tub 45 by means of a fixing pin 47 connected to each other. This creates a stable mechanical and electrical connection between the shielding tray 45 and circuit board 20 reached.

17 shows the execution of 15 and 16 after application of the first mold body 30 ,

18 shows the state of 17 in a side view. It should be noted that while the lid 46 is not shown.

It should generally be noted that in one embodiment of the idea of the molded shielding plate, the shielding plate is designed as a trough or shielding trough.

This variant offers the following advantages.

For the production process it should be mentioned that the leadframe 10 can be punched and formed, so that continuous shielding 45 can be manufactured in Leadframeverbund, in which the ready-equipped and balanced PCB 20 can be inserted and contacted.

This intermediate product can now be punched free or molded in the leadframe composite, which is preferably done with thermoset molding material. Depending on the design and requirement, the shielding tray may 45 For example, they can only be filled with mold material on the inside or they can also be completely ummoldet.

The shielding tray 45 may additionally contain fastening elements.

The trough shape is particularly advantageous in high frequency (RF) assemblies when effective and effective protection against spurious and spurious radiation is required. Conveniently, this module can be used with the shielding tray 45 screwed to the outside of a metal surface, which takes over the shielding of the second half.

19 shows a modification to the state of 3 , with additional support bars 15b are provided, which the first mold body 30 wear. Thus, the stability can be further increased.

20 shows the state of 19 in a side view. It can be seen that vertical parts of the additional support webs 15b denoted by the reference numeral 15b are designated with the shunt connection terminals 15 connected are. If these are connected with a shunt resistor, which will be described in more detail below, so can the vertical parts 15b a connection of the shunt resistor to the circuit board 20 while the shunt resistor is using the shunt connection terminals 15 can also be contacted from the outside.

Furthermore, in the execution of 20 components 22 above the circuit board 20 appropriate.

21 shows a side view of a finished device 5 with separate protectors. It can be seen that in the right part of the first mold body 30 and the second mold body 50 immediately at the interface 59 contiguous, while in the left part of a gap 51 between the first mold body 30 and second mold body 50 is trained. Through the gap 51 the formation or transmission of tension, which can falsify measurement results, is effectively avoided.

Furthermore, according to the embodiment 21 a shunt resistor 40 see which one below the circuit board 20 in the second mold body 50 but not in the first mold body 30 is embedded. This shunt resistor 40 may in particular be a temperature-independent, for example, temperature and / or long-term stable reference resistance, which is used for the measurement of a current, in particular a battery current. It is particularly advantageously mechanically stabilized and protected by the embodiment shown.

22 shows a plan view of the in 21 illustrated state. It can be seen that laterally to the first mold body 30 a first contact area 44 and a second contact area 46 at the shunt 40 are formed. This allows the shunt to be connected to cables or cables that carry a current to be measured.

In the finished component is the shunt 40 especially with the shunt connection terminals 15 connected.

Generally, the shunt resistor 40 Also referred to as insert with electrical function, which with the terminals 15 via the frontal outlet or with the alternative terminals or vertical parts 15b over the side outlet to the circuit board 20 can be tied. This part can also be omitted and there is only one with cage structure realized overmolding or a second Mold body 50 ,

The cage structure of the second mold body 50 is in stress-sensitive components, such. As in sensors, advantageous because a positive connection is prevented locally in the region of the sensor. By shear stress or by the shrinkage, for example, post-crystallization of semi-crystalline thermoplastics, caused shear, tensile or shear stresses are not on the Duroplastmoldkörper 30 transfer. The embedded sensor is not or hardly exposed to external stress.

• – Ohne Käfig und ohne elektrisches Einlegeteil (insbesondere Standardummoldung einer Leiterplatte)
• – Mit Käfig und ohne elektrisches Einlegeteil (insbesondere Ummoldung von Sensoren)
• – Ohne Käfig und mit elektrischem Einlegeteil (insbesondere Stromsensor mit Standardummoldung)
• – Mit Käfig und mit elektrischem Einlegeteil (insbesondere Stromsensor mit stressentkoppelter Ummoldung)

It should be understood that this application generally discloses in particular the following combinations:

• - Without cage and without electrical insert (especially standard gold plating of a printed circuit board)
• - With cage and without electrical insert (in particular recoloring of sensors)
• - Without cage and with electrical insert (especially current sensor with standard gumming)
• - With cage and with electrical insert (especially current sensor with stress-decoupled re-plating)

The formation of cage structures can be carried out by means of slides mounted in the tool or else by targeted surface activation and non-activation.

Mentioned steps of the method according to the invention can be carried out in the order given. However, they can also be executed in a different order. In one of its embodiments, for example with a specific set of steps, the method according to the invention can be carried out in such a way that no further steps are carried out. However, in principle also further steps can be carried out, even those which are not mentioned.

The claims belonging to the application do not constitute a waiver of the achievement of further protection.

If, in the course of the procedure, it turns out that a feature or a group of features is not absolutely necessary, it is already desired on the applicant side to formulate at least one independent claim which no longer has the feature or the group of features. This may, for example, be a subcombination of a claim existing on the filing date or a subcombination of a claim existing on the filing date and limited by further features. Such newly formulated claims or feature combinations are to be understood as covered by the disclosure of this application.

It should also be noted that embodiments, features and variants of the invention, which are described in the various embodiments or embodiments and / or shown in the figures, can be combined with each other as desired. Single or multiple features are arbitrarily interchangeable. Resulting combinations of features are to be understood as covered by the disclosure of this application.

Recoveries in dependent claims are not to be understood as a waiver of obtaining independent, objective protection for the features of the dependent claims. These features can also be combined as desired with other features.

Features that are disclosed only in the specification or features that are disclosed in the specification or in a claim only in conjunction with other features may, in principle, be of independent significance to the invention. They can therefore also be included individually in claims to distinguish them from the prior art.

Claims (15)

Method for encasing an electrical unit ( 20 ), the method comprising the steps of: - connecting the electrical unit ( 20 ) with a leadframe ( 10 ), - attaching one of the electrical units ( 20 ) associated shielding plate ( 45 ), then - sheathing the electrical unit ( 20 ) and the shielding plate ( 45 ) with a first plastic material for forming an inner mold body ( 30 ), so that a plurality of contacts ( 14 . 15 ) of the electrical unit ( 20 ) from the inner mold body ( 30 ), - punching out of the inner mold body ( 30 ) from the leadframe ( 10 ), - at least partial sheathing of the inner mold body ( 30 ) with a second plastic material for forming an outer mold body ( 50 ). Method according to claim 1, wherein the shielding plate ( 45 ) by a prior to the step of connecting the electrical unit ( 20 ) with the leadframe ( 10 ) performed step of punching the shielding plate ( 45 ) from the leadframe ( 10 ) is attached. Method according to one of the preceding claims, wherein the shielding plate ( 45 ) is formed as a molded part and by pressing into the electrical unit ( 20 ) is attached. Method according to one of the preceding claims, wherein the shielding plate ( 45 ) parallel to the electrical unit ( 20 ) is attached. Method according to one of the preceding claims, wherein the shielding plate ( 45 ) is formed as a trough which the electrical unit ( 20 ). The method of claim 5, wherein the tub is covered by a tub cover. Method according to one of the preceding claims, wherein the first plastic material used is a duroplastic material; and or wherein a thermo-plastic material is used as the second plastic material. Method according to one of the preceding claims, wherein on the electrical unit at least one sensor ( 6 ), and the method before the step of wrapping the electrical unit ( 20 ) and the shielding plate ( 45 ) comprises with a first plastic material the following step: - covering the sensor ( 6 ) with a protective material ( 7 ), in particular with a low-viscosity material, preferably with a glob-top material. Method according to one of the preceding claims, wherein in the step of wrapping with the first plastic material and / or in the step of wrapping with the second plastic material in each case completely encased, optionally with the exception of protruding contacts ( 14 . 15 ). Method according to one of the preceding claims, wherein the inner mold body ( 30 ) after the step of wrapping with the first plastic material with a number of anchored or inserted support webs ( 16 . 18 ) with the leadframe ( 10 ) connected is. Method according to one of the preceding claims, wherein the contacts ( 14 . 15 ) each have a number of beads. Method according to one of the preceding claims, wherein the electrical unit ( 20 ) a number of holes ( 24 ) for anchoring in the first plastic material. Method according to one of the preceding claims, wherein in the step of wrapping with the second plastic material, a plug ( 56 ) is formed and / or inserts ( 54 ) are embedded. Method according to one of the preceding claims, wherein the second mold body ( 50 ) at least partially in the form of an inner mold body ( 30 ) surrounding cage structure ( 50 ) is formed. Electrical component ( 5 ), which was produced by means of a method according to one of the preceding claims, wherein the outer mold body ( 50 ), possibly with preceding contacts ( 14 . 15 ), the device ( 5 ).

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