DE102011004570A1 - Component carrier for e.g. microelectromechanical system component, has carrier film formed with coating, where mounting surface is formed on inner wall of film for mounting microelectromechanical system components - Google Patents

Abstract

The carrier (130) has a three-dimensional carrier film (131) formed with a coating (32), where the carrier film is formed such that the carrier film is arranged on an inner wall of the component carrier. A mounting surface is formed on an inner wall of the carrier film for mounting microelectromechanical system (MEMS) components such as microphone element (10) and application specific integrated circuit (ASIC) (51). The carrier film is provided with contact surfaces and insulated strip conductors for electrical contact with one of the components. An independent claim is also included for a method for manufacturing a component carrier.

Description

State of the art

The invention generally relates to the packaging of MEMS components with a sensitive structure or the construction of components with such a MEMS component and a housing. In particular, the invention relates to a component carrier for MEMS devices which are to be mounted in the cavity of a housing and to be contacted electrically.

The prior art and the invention are discussed below using the example of the packaging of a MEMS microphone component, without the invention being restricted to this specific application.

It is known to use substrate-based packages for the packaging of MEMS microphone components. In this packaging variant, the microphone chip is mounted by means of chip-on-board (COB) technology on a planar, designated as a substrate component carrier, electrically contacted and housed with a lid. If the sound inlet opening is located in the cover of the housing, then the backside volume is usually limited to the chip cavity, whereby the microphone performance is limited. Alternatively, the sound inlet opening may be formed below the microphone chip in the component carrier. In this case, the entire cavity in the housing is available as a backside volume, which can be used to increase performance.

Regardless of application-specific requirements, the known packaging concept proves to be problematic in two respects.

Thus, in practice, mechanical stresses often occur in the sensitive structure of the MEMS component, which are due to installation and can be attributed to different coefficients of thermal expansion on the one hand of the MEMS component and, on the other hand, of the component carrier. Such mechanical stresses affect in each case the functionality of a MEMS device.

Since the known packaging concept provides for a "side by side" assembly of the components on the planar component carrier, the "footprint" of the component with the number of components within the housing also increases. However, an increase in the component area always leads to an increase in the production costs.

Disclosure of the invention

With the present invention, a component carrier is proposed, which allows a cost-effective, space-saving and low-stress packaging of MEMS components with a sensitive structure.

The component carrier according to the invention is realized as a composite part in the form of a hollow body open on one side and consists essentially of a flexible in their shape, three-dimensionally shaped carrier film and a wrapping compound which is integrally formed on the carrier film, so that the carrier film is disposed on the inner wall of the component carrier , There, at least one mounting surface is formed for at least one component. In addition, the carrier film is provided with contact surfaces and with insulated conductor tracks for electrical contacting of the at least one component.

Accordingly, the component carrier according to the invention consists essentially of two functionally different components, namely a flexible film in their shape, which is intended as a carrier of contact surfaces and insulated interconnects for the electrical contacting of the components, and a Umhüllmasse, realized with a dimensionally stable three-dimensional housing part becomes. According to the invention, these two components, which can be prepared easily and independently of one another, are combined in one composite part. In this case, the carrier film is formed in three dimensions, wherein the Umhüllmasse comes into contact only with the back of the carrier film and not with their front, on or in which are the sensitive traces and electrical contacts. Only in the adhesive bond created with the cured wrapping material mechanically stable and electrically contactable chip mounting areas on the carrier film.

The component carrier according to the invention can be very easily produced with standard tools and standard methods and thus also very cost-effective in multiple benefits.

In a particularly advantageous variant of the method, the three-dimensional shaping of the carrier film and the production of the composite of carrier film and encasing compound take place in a molding process step. For this purpose, a first mold part is used, whose shape corresponds to the desired three-dimensional shape of the inner wall of the component carrier, and at least one second Moldwerkzeugteil which determines the shape of the outside of the component carrier. The carrier film is here simply before pressing the liquid molding compound into the first mold part inserted. In the simplest case, it is then created by the inflowing mold flow to the mold. However, the carrier film can also be applied to the tool surface even before the molding compound is pressed in by suction or by blowing or by area-wise clamping. When the molding compound is cured, a bond between the molding compound and the carrier film, which at least partially covers the inner wall of the component carrier, thus results. The adhesion between carrier film and molding compound can additionally be improved by adhesive layers on the carrier film.

In this process variant can be dispensed with a polymer film in the first mold for tolerance compensation or to prevent tool contamination, since the carrier film performs this function. This simplifies the molding process.

Likewise, plastic molded parts having the shape of the hollow body open at one end can first be produced, for example in a standard molding process, for producing component carriers according to the invention. The carrier film is then applied in a separate process step on the inner wall of such a plastic part. In particular, methods such as lamination or embossing are suitable for this purpose. In this case, the carrier film may extend over the entire inner wall of the plastic molding or even only over individual areas of the inner wall.

It should be noted at this point that the thermal material properties of the component carrier according to the invention can be adapted very well to those of the MEMS component, as a result of which mechanical and thermo-mechanical stresses in the MEMS component can be largely reduced. In the case of the component carrier according to the invention, namely, the wrapping compound, as the dominant composite partner, determines the material behavior of the composite part, while the influence of the carrier film can be neglected. However, the encapsulants commonly used are already much better adapted to the semiconductor material of MEMS components than rigid printed circuit boards, based on the thermal expansion coefficient.

In principle, there are various possibilities for realizing a component carrier according to the invention, in particular as regards the shape of the hollow body open on one side and the design of the carrier foil with the electrical connections. In the first place, the function and number of components to be included but also the location and the required 2nd-level mounting of the MEMS package have to be considered.

The inner wall of the component carrier according to the invention, which is lined with the carrier foil, can simply be shaped as a trough with a mounting surface for components in the bottom region. Since most components in addition to the MEMS device still other components such. As an ASIC for processing the sensor or microphone signal, are on the inner wall of the device carrier according to the invention in addition to the mounting surface for the MEMS device usually more chip mounting areas or areas for the assembly of passive components with connection pads and conductors for electrical contact. In a particularly advantageous embodiment of the component carrier according to the invention, the trough-like shaped inner wall comprises at least one step on which a mounting surface for components is formed. Such a gradation may extend circumferentially over the entire inner wall or only over a portion of the inner wall, which is then shaped like a staircase and extending at two opposite portions of the inner wall. In this way chip placement areas are provided at different height levels of the component carrier. As a result, for example, differences in thickness between components on the component carrier can be compensated in order to simplify the electrical contacting of these components. The arrangement of the chip placement areas at different height levels also opens up the possibility of positioning several components overlapping or even one above the other without the component surfaces being in touching contact. This is particularly important for MEMS devices with a sensitive structure, since this is usually free to ensure the functionality of the MEMS device. By such a stacking of components on the component carrier according to the invention, the lateral size of a MEMS package compared to the classic "side by side" assembly can be significantly reduced.

Due to its three-dimensional configuration in the form of a hollow body open on one side, the component carrier according to the invention can be advantageously used as part of a housing with a cavity for a MEMS component. At the end of the housing then only a lid part is required, which is connected to the open side of the component carrier. As a cover part, for example, simply a flat housing part can be used. In an advantageous variant of the component carrier according to the invention, at least one preferably circumferential graduation is formed as a receptacle for such a cover part in the upper edge region of the trough-like inner wall. This simplifies the Positioning of the lid part during assembly on the populated component carrier. In addition, the connection area between the component carrier and the cover part can thereby be increased, which has a favorable effect on the reliability or tightness of this connection.

MEMS devices, such as pressure sensors, microphone and speaker components, require media access. Accordingly, the housing of such devices are equipped with at least one access opening. This can be located in the lid part. But also the component carrier according to the invention may be provided with a passage opening.

The packaging or the housing of a MEMS component specifies the framework conditions for the 2nd-level assembly at the place of use of the MEMS package. In particular, the arrangement and design of the electrical connections for external contacting play an essential role.

If the open side of the component carrier is closed with a flat lid part and this side of the housing acts as a mounting side for the 2nd level mounting, then it proves to be advantageous if the carrier film with the conductor tracks not only on the trough-like inner wall of the component carrier but also extends over a surface area of the component carrier on the mounting side of the housing. In this case, in addition to the conductor tracks and contact surfaces for the components, the carrier foil can also be provided with connection surfaces for external electrical contacting, so that the entire rewiring between the components of the component and the external contact is guided via the three-dimensionally formed component carrier. In this variant, a lid part can be used, which has no electrical functionality but only serves to close the housing. Since the two housing parts only need to be mechanically interconnected here, the assembly and connection technology (AVT) is particularly simple here.

As an alternative to the variant described above, however, the closed side of the component carrier according to the invention can also function as a mounting side for the 2nd level mounting. For this case, the composite part of the component carrier according to the invention is advantageously provided with electrical contacts, which emanate from the contact surfaces or conductor tracks of the carrier film and are guided by the Umhüllmasse to the outside of the composite part.

With regard to the production of the component carrier according to the invention in a molding process, the carrier film should be as heat-resistant as possible and can be coated well with a conductive material. As a carrier film component therefore particularly suitable polyimide films.

In certain applications, it makes sense to shield the components electromagnetically. In this context, it proves to be advantageous to use a multilayer carrier film whose layer structure comprises at least one metallic layer as an electromagnetic shield.

The encapsulation compound used is preferably a molding compound whose thermal expansion coefficient is matched to that of the semiconductor material of the components. The risk of contamination of the conductor tracks or contact surfaces on the carrier film does not exist here, since the molding compound also does not come into contact with the front side of the carrier film during the production of the composite part, on or in which the sensitive conductor tracks and contact surfaces are formed.

As already mentioned, the component carrier according to the invention is preferably used in conjunction with at least one further housing part in order to provide a MEMS component with a closed housing. The further housing part may simply be a flat cover part made of a plastic material. However, the cover part can also be made of a metal-coated plastic material, a metal, a semiconductor material or a metal-coated semiconductor material, if an electromagnetic shielding of the MEMS component is required. In many applications, it is advisable to connect the lid part media-tight with the component carrier. Such a connection between the component carrier and a cover part can be produced, for example, simply with the aid of a suitable adhesive or with a welded connection. As an alternative to a cover part, however, it is also possible to use a film to close off the cavity.

The component carrier according to the invention can be used particularly advantageously in the packaging of MEMS microphone components. The microphone component can be mounted in the component carrier, for example, via a passage opening acting as a sound opening. The front side volume is very small in this case, which improves the sound absorption of the membrane structure, while the entire cavity within the housing is available as a backside volume. Both contribute to a good microphone performance.

Brief description of the drawings

As already discussed above, there are various possibilities for embodying and developing the teaching of the present invention in an advantageous manner. For this purpose, reference is made on the one hand to the claims subordinate to the independent claims and on the other hand to the following description of several embodiments of the invention with reference to FIGS. Although all embodiments relate to microphone components, the invention is not limited to this application.

The 1 to 4 each show a sectional view of a microphone component 100 . 200 . 300 respectively. 400 whose housing comprises a component carrier according to the invention.

Embodiments of the invention

This in 1 shown microphone component 100 includes a MEMS microphone device 10 in whose front a membrane structure 11 is formed, which is a cavern 12 spans in the component back. The MEMS microphone component 10 is in a housing 120 arranged, which comprises two housing parts, namely a component carrier 130 for the first level AVT, which has the shape of a hollow body open on one side, and a flat housing cover 40 to the conclusion of the housing 120 Standing on the mounting side of the microphone component 100 located. In the component carrier 130 It is a composite part, which consists essentially of a flexible in their shape, three-dimensionally shaped carrier film 131 and a wrapping mass 132 exists, the one-sided to the carrier film 131 is molded, so that the carrier sheet 131 on the inner wall of the component carrier 130 is arranged. The bottom region of the trough-shaped inner wall serves as a mounting surface for the MEMS microphone component 10 and another semiconductor device, here an ASIC 51 for processing the microphone signal. The electrical contacting of these components 10 and 51 via wire bonds 61 and via contact surfaces and insulated conductor tracks on or in the carrier film 131 ,

In the component carrier 130 is a passage opening 133 formed, which acts as a sound opening. The MEMS microphone component 10 is with its back pressure-tight over the sound opening 133 mounted so that the membrane structure 11 over the back cavern 12 is acted upon by the sound pressure. The connection between the back of the component and the component carrier 130 was made here by gluing, but could also be produced by surface soldering. Also a flip-chip mounting of the MEMS microphone component 10 with the membrane structure 11 above the sound opening 133 is conceivable.

In the upper edge region of the trough-shaped inner wall of the component carrier 130 is a circumferential gradation as a recording 134 for the flat housing cover 40 formed. The housing cover 40 is pressure-tight with the component carrier 130 connected so that the cavity within the housing 120 the backside volume 70 for the MEMS microphone component 10 forms. The connection of the two housing parts 130 and 40 can be made for example by gluing or laser welding.

The carrier foil 131 not only extends over the trough-shaped inner wall with the gradation 134 in the upper edge area but also up to the surface area of the component carrier 130 , which together with the flat housing cover 40 the mounting surface for the 2nd level assembly of the component 100 forms. The insulated conductor tracks on or in the carrier film 131 are led up to this surface area, where on the carrier foil 131 also connection contacts 135 for external electrical contacting of the component 10 are located. Depending on the 2nd-level mounting process, the connection contacts 135 be executed as LGA (Land Grid Array) country or be prepared for a BGA (Ball Grid Array) -AVT.

The carrier foil 131 of the component carrier 130 should initially be flexible and thermally stable in shape. These requirements are fulfilled, for example, by polyimide films. If the components are to be shielded electromagnetically, it is advisable to use multilayer films with mutually insulated metallic layers for the electromechanical shielding and the electrical conductors or contact surfaces. As wrapping compound is preferably a molding compound, such as. As an epoxy material with SiO2 fillers used. As materials for the housing cover are plastic, a metal-coated plastic or metal in question. A housing cover made of or with metal contributes to the electromagnetic shielding of the microphone component, when it is connected by means of a Leitklebung or a Lötkontakts to the microphone circuit.

At the in 1 shown microphone component 100 is the sensitive structure of the MEMS device 10 despite media access 133 in the component carrier 130 good against the ingress of foreign matter during the 2nd-level assembly of the component 100 protected because the sound opening 133 on the mounting side of the housing 120 is arranged opposite side. Vapors or precipitation, which arise during reflow soldering, so can not directly to the sensitive micromechanical structure of the MEMS device 10 reach.

With the same housing shape and component arrangement, as in 1 illustrated, the sound opening could alternatively be formed in the flat housing cover on the mounting side of the microphone component. In this case, the sound would be transmitted to the microphone diaphragm via the cavity within the housing. The backside volume of the MEMS microphone component would be confined to the cavern between the diaphragm structure and the closed inner wall of the component carrier.

This in 2 shown microphone component 200 includes - like that in 1 shown microphone component 100 A MEMS microphone component 10 in a housing 220 , consisting of a three-dimensionally shaped composite part of carrier film 231 and enveloping mass 232 as a component carrier 230 and a flat housing cover 40 , The MEMS microphone component 10 is pressure tight over a sound opening 233 in the bottom region of the trough-shaped inner wall of the component carrier 230 mounted so that the cavern 12 under the membrane structure 11 directly to the sound opening 233 in the component carrier 230 connected. The flat housing cover 40 was flush in the upper edge region of the trough-shaped inner wall of the component carrier 230 inserted and pressure-tightly connected to this to the housing 220 and thus the backside volume for the MEMS microphone device 10 complete.

In the trough-shaped inner wall of the component carrier 230 is a gradation 236 formed, which - in contrast to the microphone component 100 - Not as a receptacle for the housing cover 40 but as a mounting surface for an ASIC 52 serves. The ASIC 52 is on one opposite the MEMS device 10 offset height level within the housing 220 arranged. This allows differences in thickness between the components 10 and 52 be compensated, which is the preparation of the bond 62 between the components 10 and 52 simplified. Incidentally, the electrical contacting of the two components takes place 10 and 52 via contact surfaces and insulated conductor tracks on the carrier foil 231 of the component carrier 230 , As in the case of the microphone component 100 the carrier film extends 231 not only via the chip mounting areas on the trough-shaped inner wall of the component carrier 230 but also down to the surface area of the component carrier 230 , which together with the flat housing cover 40 the mounting surface for the 2nd level assembly of the component 200 forms. Again, the rewiring between the components takes place 10 . 52 and the external electrical contact on the mounting side of the microphone component 200 exclusively via the component carrier 230 or the corresponding conductor tracks and connection contacts 235 provided carrier film 231 of the component carrier 230 , The flat housing cover 40 does not matter.

Three-dimensionally shaped component carriers with chip mounting surfaces at different height levels - as in 2 - offer the possibility to realize an overlapping or even stacked arrangement of several components instead of a "side-by-side" arrangement. As a result, the space requirement of a component with several components can be significantly reduced.

In 3 is a microphone component 300 represented with such a device arrangement. Also the microphone component 300 includes a MEMS microphone device 10 in a housing 320 made of a three-dimensionally shaped composite part as a component carrier 330 and a flat housing cover 40 consists. As in the embodiments described above, the MEMS microphone component is 10 pressure-tight over a sound opening 333 in the bottom region of the trough-shaped inner wall of the component carrier 330 mounted so that the cavern 12 under the membrane structure 11 directly to the sound opening 333 in the component carrier 330 connected.

Above the MEMS microphone device 10 is in the trough-shaped inner wall of the component carrier 330 a gradation 336 designed as a mounting surface for an ASIC 53 serves. The gradation 336 may be circumferential or located only on two opposite portions of the inner wall. In any case, only the outer edge of the ASIC chip lies 53 on the mounting surface (s) 336 of the component carrier 330 on, leaving the ASIC 53 here above the MEMS microphone component 10 and is arranged at a distance to this. The functionality of the MEMS microphone component 10 This is due to this type of stacking without interfacial contact between the two components 10 and 53 so not affected.

If the ASIC chip 53 pressure-tight on a circumferential mounting surface 336 is mounted, then the backside volume of the MEMS microphone component is limited 10 on the space between MEMS microphone component 10 and ASIC chip 53 , Otherwise, ie if the ASIC chip 53 on two opposite steps 336 in the inner wall of the component carrier 330 is mounted, the backside volume - as in the case of the microphone component 200 - Through the flat housing cover 40 completed, the pressure-tight and flush with the upper edge region of the trough-shaped inner wall of the component carrier 330 connected is.

Also in the case of the microphone component 300 the rewiring between the components takes place 10 . 53 and the external electrical contact on the mounting side exclusively via the device carrier 330 , Accordingly, the carrier film 331 both with insulated tracks and contact surfaces for the Firstlevel AVT provided as well as with connection contacts 335 for the 2nd-level AVT. It extends over the chip mounting areas on the trough-shaped inner wall of the component carrier 330 except for the surface area of the component carrier 330 , which together with the flat housing cover 40 the mounting surface for the 2nd level assembly of the component 300 forms In 4 is also a microphone component 400 with a stacked array of MEMS microphone device 10 and ASIC chip 54 shown. The housing 420 this component 400 comprises a composite part as a component carrier 430 , the same trough-like with a circumferential gradation 436 is shaped like the component carrier 330 of the microphone component 300 , In the case of the microphone component 400 became the ASIC chip 54 on the closed bottom region of the trough-shaped inner wall of the component carrier 430 positioned. Above and far from the ASIC chip 54 became the MEMS device 10 on the gradation 436 the inner wall of the component carrier 430 assembled. The component rear side was peripherally pressure-tight with the component carrier 430 connected.

The sound is applied here via an acoustically transparent film 440 , which instead of a housing cover on the open side of the assembled component carrier 430 was applied. It acts as a membrane, helping to improve microphone performance. It also protects the components 10 and 54 on the component carrier 430 against external influences and environmental influences. Such a film may be on the component carrier 430 be laminated, imprinted, welded on or even glued. In this construction, the backside volume is 70 on the space between membrane structure 11 and the closed bottom portion of the inner wall of the component carrier 530 limited.

Because the microphone component 400 over the closed side of the component carrier 430 is installed at its place of use, the carrier film extends 431 with the insulated tracks and electrical contact surfaces for the first level AVT only over the chip mounting areas in the floor area and over the circumferential gradation 435 the inner wall of the component carrier 435 , For the electrical contacting of the microphone component 400 As part of the 2nd-level assembly was the component carrier 430 with electrical contacts 437 provided by the contact surfaces or traces on or in the carrier film 431 go out and by the Umhüllmasse 432 to electrical connection contacts 435 on the outside of the composite part 430 are guided.

Claims (16)

Component carrier ( 130 ), in particular for MEMS components ( 10 ), which in the cavity of a housing ( 120 ) are mounted and electrically contacted, characterized in that • the component carrier ( 130 ) is realized as a composite part in the form of a hollow body open on one side, 130 ) essentially of a flexible in its shape, three-dimensionally shaped carrier film ( 131 ) and a wrapping compound ( 32 ) is formed, which on one side to the carrier film ( 131 ) is molded so that the carrier film ( 131 ) on the inner wall of the component carrier ( 130 ) is arranged, • that on the inner wall with the carrier film ( 131 ) at least one mounting surface for at least one component ( 10 . 51 ), and • that the carrier film ( 131 ) with contact surfaces and insulated conductor tracks for electrical contacting of the at least one component ( 10 . 51 ) is provided. Component carrier ( 230 ) according to claim 1, characterized in that the inner wall with the carrier film ( 231 ) trough-like with at least one graduation ( 236 ) is formed, so that at different levels of the inner wall mounting surfaces are formed. Component carrier ( 130 ) according to claim 1 or 2, characterized in that the inner wall trough-like with at least one gradation ( 134 ) is formed in the upper edge region, which serves as a receptacle for a cover part ( 40 ) serves. Component carrier ( 130 ) according to one of claims 1 to 3, characterized in that in the composite part ( 130 ) a passage opening ( 133 ) as media access for the MEMS device ( 10 ) is trained. Component carrier ( 430 ) according to one of claims 1 to 4, characterized in that the composite part ( 430 ) with electrical contacts ( 437 ) provided by the contact surfaces or tracks of the carrier film ( 431 ) and by the Umhüllmasse ( 432 ) on the outside of the composite part ( 430 ) are guided. Component carrier ( 130 ) according to one of claims 1 to 5, characterized in that the carrier film ( 131 ) comprises a polyimide film. Component carrier according to one of claims 1 to 6, characterized in that the carrier foil consists of several layers and that the layer structure of the carrier foil comprises at least one metallic layer as an electromagnetic shield for the at least one component. Method for producing a component carrier, in particular a component carrier according to one of Claims 1 to 7, which has the form of a hollow body open on one side, in which at least one first mold part is used, which determines the shape of the inner wall and whose shape corresponds to the desired three-dimensional shape of the inner wall of the component carrier, and in which at least one second mold part is used, which determines the shape of the outside of the component carrier, characterized in that a carrier film is inserted into the first mold part and is applied by the inflow mold flow to the tool mold, so that the carrier film after curing of the molding compound covers the inner wall of the component carrier at least partially. A method for producing a component carrier, in particular a component carrier according to one of claims 1 to 7, which has the form of a hollow body open on one side, characterized in that first a plastic molded part is produced with the shape of the hollow body open at one end and then that a carrier film on the inner wall applied, in particular glued. A method according to claim 9, characterized in that the carrier film is formed on the inner wall by the action of a fluid flow, in particular by blowing or suction. Component ( 100 ), at least comprising • a MEMS device ( 10 ) with at least one sensitive structure ( 11 ) and • a housing ( 120 ) having a cavity in which the MEMS device ( 10 ), characterized by a component carrier ( 130 ) according to one of claims 1 to 7, which acts as a housing part. Component ( 100 ) according to claim 11, characterized in that the carrier film ( 131 ) of the component carrier ( 130 ) down to the mounting side of the housing ( 120 ) and with electrical connections ( 135 ) for external contacting of the component ( 100 ) is provided. Component ( 300 ) according to claim 11 or 12, characterized in that the inner wall of the component carrier ( 330 ) is trough-like and has a plurality of mounting surfaces at different levels, and that at least one further component ( 53 ) above or below the MEMS device ( 10 ) is arranged by being mechanically fixed on at least one corresponding mounting surface and electrically contacted. Component ( 100 ) according to one of claims 11 to 13, characterized in that the housing ( 120 ) a cover part ( 40 ) to the conclusion of the cavity, that the cover part ( 40 ) is made of a plastic material, a metal-coated plastic material, a metal, a semiconductor material or a metal-coated semiconductor material and that the cover part ( 40 ) with the component carrier ( 130 ) media-tightly connected Component ( 400 ) according to one of claims 11 to 14, characterized in that the housing ( 420 ) a film ( 440 ) to close the cavity. Component ( 100 ) according to one of claims 11 to 15 with at least one MEMS microphone component ( 10 ), MEMS speaker component, or MEMS pressure sensor device.

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