Patent Publication Number: US-2023156907-A1

Title: Circuit board

Description:
RELATED APPLICATION DATA 
     This application claims priority to, and the benefit of, Danish Patent Application No. PA 2021 70567 filed on Nov. 17, 2021. The entire disclosure of the above application is expressly incorporated by reference herein. 
     FIELD 
     The present disclosure relates to a method of manufacturing a circuit board, a circuit board and a hearing device comprising a circuit board. 
     BACKGROUND 
     Circuit boards for advanced audio devices such as hearing devices, mobile phones, etc. undergo intense development and are made to have an increasing number of functions in a smaller area, i.e. miniaturization is in high demand. This, however, also increases the need for electromagnetic shielding of those electronic components on the circuit boards, which produce electromagnetic noise that can affect other components of the audio device as the electronic components are mounted ever closer to each other. It is therefore desirable to shield Electro-Magnetic Interference (EMI) generating electronic components on circuit boards. 
     One option that has been utilised is to shield the EMI-generating electronic components inside a conductive casing, such as folded sheets of metal or encapsulations. While functional, such conductive casing require space, which is in short supply in many devices. 
     Another option has been to construct dams around the components that were to be shielded and add a conductive shielding layer onto the electronic components within the dammed area. This process is also functional but has some drawbacks. 
     There is thus a need for an improved method of producing a circuit board with shielded electronic components. 
     It is an object to provide an improved method of manufacturing a circuit board. 
     It is a further object to provide an improved circuit board. 
     It is a further object to provide a hearing device comprising the improved circuit board. 
     SUMMARY 
     In a first aspect is provided a method of manufacturing a circuit board, in a second aspect is provided a circuit board, and in a third aspect is provided a hearing device comprising the circuit board. In the aspects, the terms and features relate to the terms and features having the same name in the other aspects and therefore the descriptions and explanations of terms and features given in one aspect apply to the other aspects. 
     In the first aspect, a method of manufacturing a circuit board is disclosed, the method comprises providing a circuit board comprising a first surface and an opposing second surface, the circuit board further comprising a ground connection; defining a shielding zone and a non-shielding zone on the first surface, one or more shielding-zone electronic components being comprised within the shielding zone; providing a groove in the circuit board, the groove extending along at least part of the shielding zone and being provided in-between the shielding zone and the non-shielding zone; applying an insulating encapsulation layer so as to cover the shielding zone, whereby the one or more shielding-zone electronic components are encapsulated; applying an electrically conductive shielding layer on top of at least part of the encapsulation layer and to the ground connection so as to electrically couple the shielding layer to the ground connection, whereby the one or more shielding-zone electronic components are electromagnetically shielded. 
     A groove is provided in the circuit board extending along at least part of the shielding zone and in-between the shielding zone and the non-shielding zone. The groove is configured so as to allow for insulating material applied during the step of applying an insulating encapsulation layer to flow into the groove, thereby reducing the risk of insulating material overflowing into the non-shielding zone, where it may e.g. cover a ground connection with which the shielding layer needs to electrically couple. 
     The circuit board may e.g. be a printed circuit board, PCB, the circuit board may e.g. be configured to mechanically support and electrically connect the one or more shielding-zone electronic components using e.g. conductive tracks or pads. The circuit board may comprise one or more sheet layers of a conductive layer, laminate, or film such as of copper e.g. laminated onto and/or between sheet layers of a non-conductive substrate, i.e. be a unitarily formed multilayer board with a plurality of layers, where the plurality of layers are interleaved conductive and non-conductive layers. By unitarily formed is meant that the multilayer circuit board is manufactured so as to constitute a unit. That is, it may be constructed from individual parts, but after manufacture the individual parts form a new whole, which cannot be disassembled into the individual parts from which it was constructed. By interleaved conductive and non-conductive layers is meant the alternating layers of conductive material, usually copper, and non-conductive material, usually a dielectric substrate, which are laminated together to form part of a multilayer circuit board. The circuit board may part of a system in package electronic circuit. 
     A shielding zone and a non-shielding zone are defined on the circuit board, and one or more shielding-zone electronic components are comprised within the shielding zone, where the shielding-zone electronic component(s) are the electronic component(s) that are to be electromagnetically shielded. The non-shielding zone is the part of the first surface, which is not included in the shielding zone, and the non-shielding zone may comprise non-shielding zone electronic components. Thus, the shielding zone will at least partly be defined on the surface of the circuit board on which the shielding-zone electronic components are mounted. The shielding zone is a largely continuous area. In some embodiments, the shielding zone is close to one or more edges of the circuit board such as the shielding zone extends to an edge of the circuit board, i.e. the defined shielding zone goes to an edge of the circuit board. 
     By electronic components is meant any of a multitude of possible electronic components attachable to a circuit board. The one or more shielding-zone electronic components may be mounted on the circuit board, e.g. by being soldered on, or bonded, e.g. wire bonded or adhesive bonded, to the circuit board. 
     The one or more shielding-zone electronic components may comprise a power supply unit such as switch-mode power supply, e.g. comprising a switch capacitor and/or an inductor, or a processing unit, or a chip, or a receiver such as a speaker, a microphone, a filter, an antenna e.g. a magnetic radio, a battery, a transceiver, and/or an interface. 
     The non-shielding zone may comprise one or more non-shielding-zone electronic components, such as a speaker, a microphone, a filter, one or more antennas e.g. a magnetic induction antenna configured for emission and reception below 100 MHZ, preferably between 9 MHZ and 15 MHZ, and/or an electric antenna configured for emission and reception above 800 MHz, preferably a wavelength between 900 MHz and 6 GHz. The first frequency may be 902 MHz to 928 MHz. The first frequency may be 2.4 to 2.5 GHz. The first frequency may be 5.725 GHz to 5.875 GHz, a battery, a transceiver, and/or an interface. Any component, which cannot function satisfactorily, when shielded by an electrically conducting shielding layer, should be positioned outside the shielding zone at a safe distance. 
     One or more of the shielding-zone components may generate electromagnetic fields of different magnitudes and at different frequencies, thereby creating electromagnetic interference between the components, the electromagnetic interference being more or less disturbing for other components e.g. depending on the operating frequencies of the components and the magnitude of the electromagnetic fields. One or more of the shielding-zone components may generate electromagnetic fields such as electrically and/or magnetically noise. One or more of the shielding-zone components may generate electromagnetic fields such as electrical fields and/or magnetic fields. 
     In some embodiments, the shielding zone comprises a plurality of shielding-zone electronic components. A distance, or gap, between two neighbouring shielding-zone electronic components may preferably be such one or more of the applied layers, such as the insulating encapsulation layer and/or the electrically conductive shielding layer, may penetrate between those shielding-zone components. The gap between two neighbouring shielding-zone electronic components may e.g. be in the range from 1 μm to 1 cm, in the range from 5 μm to 5 mm, in the range from 10 μm to 1 mm, in the range from 20 μm to 500 μm, in the range from 20 μm to 200 μm, in the range from 20 μm to 100 μm, in the range from 500 μm to 1 cm, or in the range from 1 mm to 5 mm. In one or more preferred embodiments, the gap between two neighbouring components may be in the range from 20 μm to 20 mm. 
     Applying the insulating encapsulation layer comprises applying the insulating encapsulation layer around the one or more shielding-zone electronic components, i.e. on the surface of the circuit board and possibly other surfaces, and onto the one or more shielding-zone electronic components, so as to cover and encapsulate the one or more shielding-zone electronic components and likely an area around them, thereby protecting them from the surrounding environment in such a way that all metallic terminals/soldering of the components are covered. After application of the insulating encapsulation layer, the shielding-zone components will be positioned between the circuit board and the insulating encapsulation layer. 
     If applying the insulating encapsulation layer on a plurality of electronic components, applying the insulating encapsulation layer may comprise applying a portion of the insulating encapsulation layer on each electronic component individually, or applying the insulating encapsulation layer on the plurality of components such that the insulating encapsulation layer is substantially continuous on the plurality of electronic components. Applying the insulating encapsulation layer may comprise conformal coating of the insulating encapsulation layer. Conformal coating may provide a uniform insulating encapsulation layer on the one or more shielding-zone electronic components and minimize the thickness of the insulating encapsulation layer that is needed to cover the shielding-zone electronic components. 
     In some embodiments, applying the insulating encapsulation layer comprises applying one or more liquid encapsulation materials. 
     In some embodiments, applying the insulating encapsulation layer comprises applying a plurality of insulating layers, e.g. applying a first insulating layer and then a second insulating layer on at least part of first insulating layer. The insulating materials used for the plurality of layers may have different viscosities. The first insulating layer may be cured before applying the second insulating layer. Likewise, the second insulating layer may be cured before applying a third insulating layer, etc. 
     The insulating encapsulation layer, or one or more of the insulating layers, is an electrically non-conductive layer such that no electrical or galvanic contact can be established to the one or more shielding-zone electronic components, e.g. from the electrically conductive shielding layer. The insulating encapsulation layer, or one or more of the insulating layers, may be made of an insulating material comprising one or more polymers. The plurality of insulating layers may be of the same material. 
     In some embodiments, the insulating encapsulation layer or one or more of the insulating layers are made of a material with a viscosity prior to curing in the range of 0.001 Pa·s to 300 Pa·s, such as in the range of 0.01 Pa·s to 200 Pa·s., such as in the range of 0.5 Pa·s to 175 Pa·s, such as in the range of 1 to 30 Pa·s, such as in the range of 1 Pa·s-20 Pa·s, or such as in the range of 3 Pa·s to 10 Pa·s, when measured at a temperature of 20-25° C. 
     One or more of the materials used for the insulating encapsulation layer may be a material that cures by polymerization induced by UV light source. One or more of the materials used for the insulating encapsulation layer may be a material that cures through solvent removal induced by heating. Examples of insulating materials may be acrylated polyurethane (e.g. Electrolube® UVCL, HumiSeal® UV 40 , HumiSeal® UV40-250, HumiSeal® UV40 Gel, and/or HumiSeal® UV40HV), acrylate, epoxy resin (e.g. Namics® U8443, Elpeguard® SL 1367, and/or Humiseal® 1R32A-2). 
     One or more of the materials used for the insulating encapsulation layer may comprise and/or function as an underfill material having low viscosity, i.e. lower than 15 Pas, such as lower than 1 Pa·s, so as to allow the insulating material to penetrate around and below the one or more shielding-zone electronic components. 
     The electrically conductive shielding layer is applied so as to electrically couple to a ground connection (GND), such as to one or more ground pad elements, e.g. of a ground pad ring. In some embodiments, the ground connection is provided on the first surface of the circuit board. The ground connection may e.g. be a ground connection of the circuit board, a ground connection through an electronic component being connected to a ground connection of the circuit board, a ground pad ring e.g. at least partly encircling an electronic component. The ground connection may comprise one or more ground pad elements. 
     The ground pad ring may be an unbroken continuous ring. The ground pad ring may be formed by a number of ground pad elements arranged along a closed curve, e.g. encircling one or more electronic components. A ground pad ring having a continuous ring may provide greater flexibility for the grounding of the shielding layer. A continuous ring of the ground pad ring or a ground pad element may have a width in the range from 1 μm to 500 μm, 100 μm to 500 μm, 200 μm to 500 μm, 1 μm to 100 μm, preferably between 5-50 μm, more preferably between 10-50 μm. In some embodiments, the ground connection is provided on a surface inside the groove in the circuit board, for example the ground connection may be provided by at least a part of a conductive layer of a multilayer circuit board. 
     The electrically conductive shielding layer may be applied on the insulating encapsulation layer, e.g. on a first insulating layer, a second insulating layer, etc., and/or on the circuit board, i.e. the shielding layer may be applied on different surfaces as long as it electrically couples to the ground connection and electromagnetically shields the one or more shielding-zone electronic components. 
     In some embodiments, applying the electrically conductive shielding layer comprises applying a liquid shielding material. 
     In some embodiments applying the electrically conductive shielding layer comprises applying a plurality of shielding layers, e.g. applying a first shielding layer and then a second shielding layer on at least part of first shielding layer. The plurality of shielding layers may have different viscosities. The first shielding layer may be cured before applying the shielding insulating layer. Likewise, the second shielding layer may be cured before applying a third shielding layer, etc. 
     The electrically conductive shielding layer is an electrically conducting layer. Thus, the electrically conductive shielding layer, or one or more of the shielding layers, is made of an electrically conductive shielding material. The conductivity of the electrically conductive shielding layer may be in the range of 1 μΩ·cm to 1000 μΩ·cm, i.e. 1 μΩ·cm to 1 mΩ·cm. 
     One or more of the materials used for the electrically conductive shielding layer may be a shielding material that is a conductive material, e.g. an electrically conductive polymer material. One or more of the shielding material used for the electrically conductive shielding layer may be conductive polymer material, e.g. a conductive coating, e.g. based on inorganic or organic material, a conductive ink, a conductive micro-ink comprising micrometer-sized particles, or a conductive nano-ink comprising nanometer-sized particles. Examples of shielding materials may be Genes&#39;ink® Smart spray S-CS11101, Genes&#39;ink® Smart&#39;ink S-CS21303, Genes&#39;ink® Smart&#39;ink S-CS01520, Tatsuta® AE1244, Tatsuta® AE5000A5, Tatsuta® AE5000L, Tatsuta® AE5000ST, or Tatsuta® SF-PC5600. 
     In some embodiments, the liquid encapsulation material and/or the liquid shielding material is applied using the jetting method, and/or the spray method, and/or the aerosol method. In some preferred embodiments, the liquid insulating encapsulation material, or one or more of the liquid encapsulation materials if a plurality of insulating layers are applied, is applied by jetting. In some embodiments, jetting an insulating material on the one or more shielding-zone electronic components may be combined with masking prior to jetting, e.g. by arranging a masking element. Jetting an insulating material may allow for a more automatized and accurate application of an insulating layer, e.g. by removing human steps in the manufacturing of the electronic circuit. This may provide a higher uniformity of an applied layer, e.g. the thickness of the layers, and in turn provide more reliable layers. Further, introduction of potential human/operator-related contamination on the boards-to-be-coated can be reduced and/or prevented. 
     The insulating encapsulation layer is applied so as to cover at least the shielding zone, and thereby cover the one or more shielding-zone electronic components. 
     In some embodiments, applying the liquid encapsulation layer further comprises curing the liquid encapsulation material so as to solidify it and/or applying the liquid shielding layer further comprises curing the liquid shielding material so as to solidify it. In some preferred embodiments, the liquid encapsulation material is cured before the liquid shielding material is applied. In some embodiments, the method further comprises the step of curing the encapsulation layer and the shielding layer at the same time. Curing may comprise e.g. low-temperature curing, heat-curing, moisture-curing, UV-curing, infrared light curing, near infrared light curing, or photonic curing. The UV-curing may be performed at a wavelength in the range of 100 nm to 400 nm. 
     Both the application of the insulating material(s) and of the shielding material(s) may be achieved by jetting, which allows the use of the same machine for all steps. By using the same machine, the number of fabrication steps of the electronic circuit may be reduced, whereby an easier and faster fabrication process may be achieved. 
     A groove is provided in the circuit board, extending along at least part of the shielding zone and in-between the shielding zone and the non-shielding zone. The groove is configured so as to allow for insulating material applied during the step of applying an insulating encapsulation layer to flow into the groove, thereby reducing the risk of insulating material overflowing into the non-shielding zone, where it may a ground connection with which the shielding layer need to electrically couple. 
     By extending along is meant that the groove extends along at least part of the border of the shielding zone, i.e. that it extends parallel to at least part of the border of the defined shielding zone. The border of the shielding zone is where the shielding zone ends and the non-shielding zone begins. By “in-between” is not meant that the shielding zone and non- shielding zone are separated by a third zone in which the groove extends. The groove will have a physical extent, which may extend into one or both of the two defined zones, i.e. of the shielding zone and/or the non-shielding zone. 
     In some embodiments, the provided groove encircles the shielding zone. In some embodiments, a plurality of provided grooves encircle the shielding zone. In some embodiments, the shielding zone is close to one or more edges of the circuit board such as the shielding zone extends to an edge of the circuit board, i.e. the defined shielding zone goes to an edge of the circuit board. 
     In some embodiments, the maximum depth of the groove provided in the circuit board is between 5 and 200 micrometres, such as between 20 and 150 micrometres, such as between 40 and 100 micrometres, such as between 50 and 80 micrometres. 
     In some embodiments, the maximum width of the groove provided in the circuit board is between 100 and 500 micrometres, such as between 150 and 400 micrometres, such as between 200 and 300 micrometres. 
     In some embodiments, the circuit board is a multilayer circuit board comprising a plurality of layers, the plurality of layers comprising interleaved conductive and non-conductive layers, and the groove is provided in one or more of the plurality of layers. In some embodiments, providing the groove in the circuit board comprises making a through-hole in one or more layers of the plurality of layers before assembly of the multilayer circuit board. In some embodiments, the groove extends through 1-5 layers of the plurality of layers, such as through 1-4 layers of the plurality of layers, such as 1-3 layers of the plurality of layers, or wherein the groove extends through less than or equal to half of the layers of the plurality of layers, such as less than or equal to a third of the layers of the plurality of layers, such as less than or equal to a quarter of the layers of the plurality of layers. 
     The groove may be provided by any known method to carve, cut, punch, etc. in the materials used for circuit boards. In some embodiments, the groove is provided by performing laser cutting, or punching. 
     The shape of the groove may be any suitable shape. In some embodiments, the groove is a square, rectangular, or a trapezoidal groove, and/or an undercut. In some embodiments, when the groove is viewed in a cross-sectional cut that is perpendicular to the surface of the circuit board and perpendicular to the top edges of the groove, the sides of the groove, which extend into the circuit board, make a first and a fourth angle with respect to the surface of the circuit board, the first angle being the angle closer to the shielding zone and the fourth angle being the angle closer to the ground connection, the sides of the groove, which extend into the circuit board, further make a second and a third angle with respect to the bottom of the groove, the second angle being closer to the first angle, and the first angle is greater than 45 degrees, such as greater than 60 degrees, such as greater than 75 degrees, such as greater than 90 degrees. 
     In some embodiments, the fourth angle is less than 135 degrees, such as less than 120 degrees, such as less than 105 degrees, such as less than 90 degrees. 
     In the second aspect, a circuit board is disclosed, where the circuit board comprises a ground connection, a first surface and an opposing second surface, the first surface comprises a shielding zone and a non-shielding zone, one or more shielding-zone electronic components ( 7 ) being comprised within the shielding zone ( 11 ). The circuit board further comprises a groove that extends along at least part of the shielding zone and in-between the shielding zone and the non-shielding zone. The circuit board further comprises an insulating encapsulation layer on the shielding zone, whereby the one or more shielding-zone electronic components are encapsulated, and an electrically conductive shielding layer on top of at least part of the encapsulation layer, the shielding layer being coupled electrically to the ground connection, whereby the one or more shielding-zone electronic components are electromagnetically shielded. 
     The shielding and non-shielding zones of the circuit board are zones that are defined, where the shielding zone comprises the electronic components that are to be shielded. Ideally, the insulating encapsulation layer covers only the shielding-zone electronic components. However, often the material(s) used in the insulating encapsulation layer have a low viscosity, which is good for ensuring that the material flows well around the electronic components, and possibly under, but also means that the material can easily flow out of the intended shielding zone such that it covers at least part of the intended non-shielding zone. The groove provided in the circuit board extends along at least part of the shielding zone and in-between the shielding zone and the non-shielding zone. The groove is configured so as to allow for insulating material applied during the step of applying an insulating encapsulation layer to flow into the groove, thereby reducing the risk of insulating material overflowing into the non-shielding zone, where it may cover a ground connection with which the shielding layer needs to electrically couple. 
     In some embodiments, the encapsulation layer extends into the groove. In some embodiments, the encapsulation layer does not extend beyond the groove. 
     In some embodiments, the ground connection is provided on the first surface of the circuit board. In some embodiments the ground connection is provided on a surface inside the groove. 
     In some embodiments, the maximum depth of the groove in the circuit board is between 5 and 200 micrometres, such as between 20 and 150 micrometres, such as between 40 and 100 micrometres, such as between 50 and 80 micrometres. 
     In some embodiments, the maximum width of the groove in the circuit board is between 100 and 500 micrometres, such as between 150 and 400 micrometres, such as between 200 and 300 micrometres. 
     In some embodiments, the encapsulation layer comprises one or more of: an epoxy-based material, acrylated (poly)urethane, a urethane-acrylate, an acrylic, a urethane, or other polymer matrixes. 
     In some embodiments, the circuit board is a multilayer circuit board comprising a plurality of layers, the plurality of layers comprising interleaved conductive and non-conductive layers, and wherein the groove is provided in one or more of the plurality of layers. In some embodiments, the groove in the circuit board comprises a through-hole in one or more layers of the plurality of layers. In some embodiments, the groove extends through 1-5 layers of the plurality of layers, such as through 1-4 layers of the plurality of layers, such as 1-3 layers of the plurality of layers, or wherein the groove extends through less than or equal to half of the layers of the plurality of layers, such as less than or equal to a third of the layers of the plurality of layers, such as less than or equal to a quarter of the layers of the plurality of layers. 
     In some embodiments, the groove encircles the shielding zone or wherein a plurality of grooves encircle the shielding zone. 
     In some embodiments, the groove is a square groove, or a trapezoidal groove. 
     In some embodiments, when the groove is viewed in a cross-sectional cut that is perpendicular to the surface of the circuit board and perpendicular to the top edges of the groove, the sides of the groove, which extend into the circuit board, make a first and a fourth angle with respect to the surface of the circuit board, the first angle being the angle closer to the shielding zone and the fourth angle being the angle closer to the ground connection, the sides of the groove, which extend into the circuit board, further make a second and a third angle with respect to the bottom of the groove, the second angle being closer to the first angle, and wherein the first angle is greater than 45 degrees, such as greater than 60 degrees, such as greater than 75 degrees, such as greater than 90 degrees. 
     In some embodiments, the fourth angle is less than 135 degrees, such as less than 120 degrees, such as less than 105 degrees, such as less than 90 degrees. 
     In some embodiments, the shielding zone is close to one or more edges of the circuit board. 
     In the third aspect, is disclosed a hearing device comprising a circuit board according to the second aspect. 
     The hearing device is configured to be worn by a user. The hearing device may be arranged at the user&#39;s ear, on the user&#39;s ear, over the user&#39;s ear, in the user&#39;s ear, in the user&#39;s ear canal, behind the user&#39;s ear, and/or in the user&#39;s concha, i.e., the hearing device is configured to be worn in, on, and/or over the user&#39;s ear. The user may wear two hearing devices, one hearing device at each ear. The two hearing devices may be connected, such as wirelessly connected and/or connected by wires, such as a binaural hearing aid system. 
     The hearing device (or pair of hearing devices) may be a hearable such as a headset, headphones, earphones, ear bud, hearing aids, a personal sound amplification product (PSAP), an over-the-counter (OTC) hearing device, a hearing protection device, a one-size-fits-all hearing device, a custom hearing device or another head-wearable hearing device. Hearing devices can include both prescription devices and non-prescription devices. 
     The hearing device may be embodied in various housing styles or form factors. Some of these form factors are Behind-the-Ear (BTE) hearing device, Receiver-in-Canal (RIC) hearing device, Receiver-in-Ear (RIE) hearing device, or Microphone-and-Receiver-in-Ear (MaRIE) hearing device. These devices have in common that they comprise a BTE component configured to be worn behind the ear of the user and an in the ear (ITE) component configured to be inserted partly or fully into the user&#39;s ear canal. Generally, the BTE component comprises at least one input transducer, a power source, and a processing unit. The term BTE hearing device refers to a hearing device where the receiver, i.e. the output transducer, is comprised in the BTE component and sound is guided to the ITE component via a sound tube connecting the BTE and ITE components, whereas the terms RIE, RIC, and MaRIE devices refers to hearing devices where the receiver is comprised in the ITE component, which is coupled to the BTE component via a connector cable configured for transferring electric signals between the BTE and ITE components. 
     Some of these form factors are In-the-Ear (ITE) hearing device, Completely-in-Canal (CIC) hearing device, or Invisible-in-Canal (IIC) hearing device. These hearing devices comprise an ITE component, wherein the ITE component comprises at least one input transducer, a power source, a processing unit, and an output transducer. These form factors may be custom devices, meaning that the ITE component comprises a housing having a shell made from a hard material, such as a hard polymer or metal, moulded to have an outer shape conforming to the shape of the specific user&#39;s ear canal. 
     Some of these form factors are earbuds, on the ear headphones, or over the ear headphones. Some of these form factors are cochlear implant comprising a BTE component an implant component. In some embodiments, the one or more electronic components in the shielding zone comprise hearing device components, which generate electrical or/and magnetic noise (EMI). 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       In the following, exemplary embodiments are described in more detail with reference to the appended drawings, wherein: 
         FIG.  1    shows a flow diagram illustrating some embodiments of the method of manufacturing a circuit board, 
         FIG.  2    shows a flow diagram illustrating some embodiments of the method of manufacturing a circuit board, 
         FIG.  3    shows a flow diagram illustrating some embodiments of the method of manufacturing a circuit board, 
         FIGS.  4 - 5    schematically illustrate a circuit board from a view looking at the first surface, 
         FIGS.  6 - 7    schematically illustrate overflow of the encapsulation layer, 
         FIGS.  8 - 14    schematically illustrate a circuit board viewed from a side according to some embodiments, 
         FIGS.  15 A,  15 B, and  15 C  schematically illustrate the geometry of the groove according to some embodiments, and 
         FIGS.  16 - 17    schematically illustrate hearing devices, which comprise a circuit board according to some embodiments. 
     
    
    
     DETAILED DESCRIPTION 
     Various embodiments are described hereinafter with reference to the accompanying drawings. Like reference numerals refer to like elements throughout. Like elements will, thus, not be described in detail with respect to the description of each figure. It should also be noted that the figures are only intended to facilitate the description of the embodiments. They are not intended as an exhaustive description of the claimed invention or as a limitation on the scope of the claimed invention. In addition, an illustrated embodiment needs not have all the aspects or advantages shown. An aspect or an advantage described in conjunction with a particular embodiment is not necessarily limited to that embodiment and can be practiced in any other embodiments even if not so illustrated, or if not so explicitly described. 
     In the following various exemplary embodiments of the disclosed method of manufacturing a circuit board, a circuit board, and a hearing device comprising a circuit board are described with reference to the appended drawings. The skilled person will understand that the accompanying drawings are schematic and simplified for clarity. The elements shown in the drawings are not necessarily drawn to scale, but may primarily be illustrative of relative position, orientation, and function. 
       FIG.  1    shows a flow diagram illustrating some embodiments of the method  100  of manufacturing a circuit board. In step  101 , a circuit board  1  is provided. The circuit board  1  has a first surface  4  and an opposing second surface  6 , and at least one ground connection  9 . In step  103 , a shielding zone  11  and a non-shielding zone  12  are defined on the first surface  4 . One or more shielding-zone electronic components  7  are positioned within the shielding zone  11 , i.e. on the first surface  4  and within the shielding zone  11 . In step  105 , a groove  17  is provided in the circuit board  1 . The groove  17  extends along at least part of the shielding zone  11  and is provided in-between the shielding zone  11  and the non-shielding zone  12 . In step  107 , an insulating encapsulation layer  13  is applied so as to cover the shielding zone  11 , whereby the one or more shielding-zone electronic components  7  are encapsulated and thereby protected from the surrounding environment. 
     An adhesive layer or coating may be applied before applying a first insulating material, e.g. for promoting adhesion of the insulating layer. An adhesive layer or coating may be applied after applying the first insulating material and/or after any later applied layer or material, e.g. for promoting adhesion of a shielding layer. The viscosity of an insulating layer  13  may be chosen based on one or more of the distance or gap between two or more shielding-zone electronic components  7 , the method of applying the insulating layer  13 , and the type of one or more of the shielding-zone electronic components  7 . For example, for a smaller distance between the shielding-zone electronic components  7 , i.e. a smaller gap, the viscosity of one or more of the insulating materials may be lower than for a larger distance between the shielding-zone components  7 , i.e. a larger gap, to allow the insulating material to penetrate the gaps between the electronic components  7 . 
     The insulating encapsulation layer  13  is applied so as to cover the entire shielding zone  11 , and thereby cover the one or more shielding-zone electronic components  7 . Ideally, the insulating encapsulation material in the encapsulation layer  13  covers only the electronic components  7  in a defined circuitry region, i.e. ideally, the insulating encapsulation layer  13  covers only the shielding-zone electronic components  7 . However, often the material(s) used in the insulating encapsulation layer  13  will have a low viscosity, which is good for ensuring that the material flows well around the shielding-zone electronic components  7 , and possibly underneath, but the low viscosity also means that the material can easily flow out of the shielding zone  11  such that it covers at least part of the non-shielding zone  12 . The groove  17  provided in the circuit board  1  extends along at least part of the shielding zone  11  and in-between the shielding zone  11  and the non-shielding zone  12 . The groove  17  is configured so as to allow for insulating material applied during the step of applying  107  an insulating encapsulation layer to flow into the groove  17 , thereby reducing the risk of insulating material overflowing into the non-shielding zone  12 . Thus, ideally, the encapsulation layer  13  stops at or before the ground connection  9 , and does not entirely cover the ground connection  9 . 
     The viscosity of the one or more materials used in the insulating encapsulation layer  13  may be chosen at least in part in accordance with the distance between two or more shielding-zone electronic components  7 . A lower viscosity e.g. in the range from 0.1 to 20 Pa·s may be preferred for smaller gaps e.g. gaps smaller than 500 μm, e.g. to promote the flowing of an insulating material into smaller gaps. A higher viscosity makes the insulating material less likely to flow. In prior art, a higher viscosity might have been chosen to prevent the insulating material from flowing over an edge of the circuit board or from unintentionally and unwanted covering portions of the circuit board  1 , such as ground pad elements  9 , which should not be covered. However, advantageously, a material having a lower viscosity may be used in the method provided and on the circuit board  1  provided as the groove  17  provides at least partly a barrier between the shielding zone  11  and the non-shielding zone  12 . 
     More than one insulating encapsulation layer  13  may be applied, e.g. a first insulating layer may be applied and then a second insulating layer on at least part of first insulating layer, as illustrated by a dashed arrow. The materials used in the plurality of insulating layers may have different viscosities. The first insulating layer may be cured before applying the second insulating layer. Likewise, the second insulating layer may be cured before applying a third insulating layer, etc. 
     In step  109 , an electrically conductive shielding layer  15  is applied on top of at least part of the encapsulation layer  13  and to the ground connection  9  so as to electrically couple the shielding layer  15  to the ground connection  9 , whereby the one or more shielding-zone electronic components  7  are electromagnetically shielded. The shielding layer  15  may act to shield the one or more shielding-zone electronic components  7  from electromagnetic radiation, i.e. act as a Faraday cage, and/or, optionally, from other electronic components of the electronic circuit. In other words, the shielding layer  15  may prevent electromagnetic radiation from disrupting the shielding-zone electronic components  7 . The shielding layer  15  may, additionally or alternatively, shield one or more unshielded electronic component(s)  5  of the circuit board from electromagnetic radiation generated by the one or more shielded electronic components  7 . The shielding provided by the shielding layer  15  may be in the range of 1 dB to 160 dB depending on the frequency or frequency range to shield. 
     The thickness of the shielding layer  15  may depend on a frequency of the generated electromagnetic interference by the one or more shielding-zone electronic components  7  to be shielded. The frequency to be shielded may be determined based on the operating frequency of one or more electronic components of the electronic circuit. More than one shielding layer  15  may be applied, e.g. a first shielding layer may be applied and then a second shielding layer on at least part of first shielding layer, as illustrated by a dashed arrow. The materials used in the plurality of shielding layers may have different viscosities. The first shielding layer may be cured before applying the second shielding layer. Likewise, the second shielding layer may be cured before applying a third shielding layer, etc. 
       FIG.  2    shows a flow diagram illustrating some embodiments of the method  100  of manufacturing a circuit board  1 , wherein steps  101 ,  103 , and  105  may be as described for  FIG.  1   . In step  107 , an insulating encapsulation layer  13  is applied so as to cover the shielding zone  11 , whereby the one or more shielding-zone electronic components  7  are encapsulated and thereby protected from the surrounding environment. In some embodiments, step  107  comprises sub-steps  107 A and  107 B. In step  107 A, a liquid encapsulation material is applied so as to cover the shielding zone  11 , whereby the one or more shielding-zone electronic components  7  are covered. In step  107 B, the liquid encapsulation material is cured so as to solidify it and encapsulate the shielding-zone electronic components  7 . 
     More than one insulating encapsulation layer  13  may be applied, e.g. a first insulating layer may be applied and then a second insulating layer on at least part of first insulating layer, as illustrated by a dashed arrow. The materials used in the plurality of insulating layers may have different viscosities. The first insulating layer may be cured before applying the second insulating layer. Likewise, the second insulating layer may be cured before applying a third insulating layer, etc. 
     In step  109 , an electrically conductive shielding layer  15  is applied on top of at least part of the encapsulation layer  13  and to the ground connection  9  so as to electrically couple the shielding layer  15  to the ground connection  9 , whereby the one or more shielding-zone electronic components  7  are electromagnetically shielded. In some embodiments, step  109  comprises sub-steps  109 A and  109 B. In step  109 A, a liquid shielding material is applied on top of at least part of the encapsulation layer  13  and to the ground connection  9  so as to electrically couple the shielding layer  15  to the ground connection  9 . In step  109 B, the liquid shielding material is cured so as to solidify it. 
     More than one shielding layer  15  may be applied, e.g. a first shielding layer may be applied and then a second shielding layer on at least part of first shielding layer, as illustrated by a dashed arrow. The materials used in the plurality of shielding layers may have different viscosities. The first shielding layer may be cured before applying the second shielding layer. Likewise, the second shielding layer may be cured before applying a third shielding layer, etc. 
       FIG.  3    shows a flow diagram illustrating some embodiments of the method  100  of manufacturing a circuit board, whereby a multilayer circuit board as shown in  FIGS.  10 - 14    may be manufactured. 
     When the circuit board  1  is a unitarily formed multiplayer circuit board, the steps of providing  101  the circuit board and of providing  105  a groove in the circuit board  1  may overlap as the groove  17  may be provided by making a through-hole in one or more layers of the plurality of layers before assembly of the multilayer circuit board  1 . The steps of providing  101  the circuit board and of providing  105  a groove in the circuit board  1  may comprise the sub-steps  102 A,  102 B, and  102 C. In step  102 A, a plurality of circuit board layers is provided. The plurality of circuit board layers comprises conductive  19  and non-conductive layers  21 , which will be interleaved to form the multilayer circuit board. In step  102 B, a through-hole is provided in one or more of the plurality of circuit board layers. The through-hole in the one or more layers is arranged such that it will form the groove  17  after assembly of the multilayer circuit board  1 , i.e. such that the through-holes in the circuit board layers will overlap at least partly. In step  102 C, the plurality of circuit board layers is assembled using standard methods to arrive at a unitarily formed multiplayer circuit board  1  comprising a groove  17 . The groove  17  may extend through  1 - 5  layers of the plurality of circuit board layers, such as through  1 - 4  layers of the plurality of circuit board layers, such as  1 - 3  layers of the plurality of circuit board layers, or wherein the groove extends through less than or equal to half of the layers of the plurality of circuit board layers, such as less than or equal to a third of the layers of the plurality of circuit board layers, such as less than or equal to a quarter of the layers of the plurality of circuit board layers. 
       FIG.  4    schematically illustrates a circuit board  1  from a view looking at the first surface  4 . The circuit board  1  is made of a substrate  3  and comprises electronic components  5 ,  7 . A shielding zone  11  is outlined by a bold, dashed line, which is for illustration only. The shielding zone  11  comprises shielding-zone electronic components  7 , which are positioned within the shielding zone  11 . Likewise, the non-shielding zone  12  comprises non-shielding-zone electronic components  5 , which are positioned within the non-shielding zone  12 . 
     The electronic components  7  within the shielding zone  11  are those that require electromagnetic shielding. For example, to shield the one or more shielding-zone electronic components  7  from electromagnetic radiation, i.e. act as a Faraday cage, and/or, optionally, from other electronic components of the electronic circuit. Additionally, or alternatively, to shield one or more unshielded electronic component(s)  5  of the circuit board from electromagnetic radiation generated by the one or more shielded electronic components  7 . 
       FIG.  5    schematically illustrates a circuit board  1  from a view looking at the first surface  4 . The circuit board  1  may be the circuit board  1  shown in  FIG.  4   . A liquid encapsulation layer  13  has been applied to the shielding zone  11 , as illustrated by the hatched area. The insulating encapsulation layer  13  has been applied perfectly so as to only cover the defined shielding zone  11 , which is the intended area to be covered. However, often the material(s) used in the insulating encapsulation layer  13  have a low viscosity, which is good for ensuring that the material flows well around the electronic components  5 , and possibly under, but which also means that the material can easily flow out of the shielding zone  11  such that it covers at least part of the non-shielding zone  12 , see example in  FIG.  6   . 
       FIG.  6    schematically illustrates a circuit board  1  from a view looking at the first surface  4 . The circuit board  1  may be the circuit board  1  shown in  FIG.  4   . Just as in the illustration in  FIG.  5   , a liquid encapsulation layer  13  has been applied to the shielding zone  11 , as illustrated by the hatched area. However, in this instance, the liquid encapsulation material has not stayed within the shielding zone  11 , but has overflown  16  the shielding zone border into the non-shielding zone  12  in two places. Such overflowing  16  may be detrimental to the functioning of the later applied shielding layer, for example if the insulating encapsulation layer  13  covers the ground connection  9 , which the shielding layer  15  needs to electrically couple to, in such a way that the functionality of the shielding layer  15  is compromised, see example in  FIG.  7   . 
       FIG.  7    schematically illustrates a circuit board  1  viewed from a side according to some embodiments. The circuit board  1  may be the circuit board  1  shown in  FIG.  6    viewed as a cut along A. The circuit board  1  is illustrated with the first surface  4  towards the top of the page, and the opposite second surface  6  towards the bottom of the page. Two shielding-zone electronic components  7  are covered by an insulating encapsulation layer  13 . An electrically conductive shielding layer  15  has been applied on top of the encapsulation layer  13 . The encapsulation layer  13  has overflown  16  the shielding zone  11  such that it is covering the ground connection  9  shown on the left side of the page. Therefore, the shielding layer  15  cannot, as intended, couple electrically with the covered ground connection  9 , which is now encapsulated in an insulating layer  13 . 
       FIG.  8    schematically illustrates a circuit board  1  viewed from a side according to some embodiments. The circuit board  1  is similar to the circuit boards  1  shown in  FIGS.  6  and  7   , but in the circuit board  1  in  FIG.  8   , one or more grooves  17  have been provided in the circuit board  1 . As in the illustration in  FIG.  7   , two shielding-zone electronic components  7  are covered by an insulating encapsulation layer  13  and an electrically conductive shielding layer  15  has been applied on top of the encapsulation layer  13 . The liquid encapsulation layer  13  applied to the shielding zone  11  has formed a bulge  18  due to surface tension when flowing towards the groove(s)  17 , and if not for the groove(s)  17  the encapsulation layer  13  would likely have flown out of the shielding zone  11  and into the non-shielding zone  12 . Thus, the groove(s)  17  provided in the circuit board  1  solved the issue shown in  FIG.  7   , where the encapsulation layer  13  had flown into the non-shielding zone  12 . A shielding layer  15  has been applied on top of at least part of the encapsulation layer  13  and couples electrically to the ground connection  9  such that the two shielding-zone electronic components  7  are electromagnetically shielded. 
       FIG.  9    schematically illustrates a circuit board viewed from a side according to some embodiments. The circuit board in  FIG.  9    may be the circuit board  1  shown in  FIG.  8   . The shape of the groove(s)  17  may be any suitable shape. For example, the groove may be a square groove, i.e. a groove wherein the angles of its sides are all at 90 degrees, or a trapezoidal groove, and/or an undercut. The groove in  FIG.  9    is shown as a square groove  17  that may be defined by a depth D and a width W. In other shapes, the groove  17  may be characterized by more than one depth and/or more than one width, and the angles of the its sides may be different from 90 degrees. The liquid encapsulation layer  13  applied to the shielding zone  11  has formed a bulge  18  due to surface tension when flowing towards the groove(s)  17 , and if not for the groove(s)  17  the encapsulation layer  13  would likely have flown out of the shielding zone  11  and into the non-shielding zone  12 . Thus, the groove(s)  17  provided in the circuit board  1  solved the issue shown in  FIG.  7   , where the encapsulation layer  13  had flown into the non-shielding zone  12 . A shielding  15  has been applied on top of at least part of the encapsulation layer  13  and couples electrically to the ground connection  9  such that the shielding-zone electronic component  7  is electromagnetically shielded. 
       FIG.  10    schematically illustrates a circuit board  1  viewed from a side according to some embodiments. The circuit board  1  is a unitarily formed multilayer circuit board comprised of interleaved conductive  19  and non-conductive  21  circuit board layers with vias  23  between the conductive layers  19 , and a top  25  and bottom layer  27 . A groove  17  has been provided in the circuit board  1  as an arrangement of aligned through-holes in three of the plurality of circuit board layers as well as in the top layer  25 . The through-holes may have been made before or after assembly of the multilayer circuit board  1 . Thus, the multilayer circuit board comprises cut layers  29  and uncut layers  31 . The liquid encapsulation layer  13  applied to the shielding zone  11  has formed a bulge  18  due to surface tension when flowing towards the groove(s)  17 , and if not for the groove(s)  17  the encapsulation layer  13  would likely have flown out of the shielding zone  11  and into the non-shielding zone  12 . Thus, the groove(s)  17  provided in the circuit board  1  solved the issue shown in  FIG.  7   , where the encapsulation layer  13  had flown into the non-shielding zone  12 . A shielding  15  has been applied on top of at least part of the encapsulation layer  13  and couples electrically to the ground connection  9  such that the shielding-zone electronic component  7  is electromagnetically shielded. 
       FIG.  11    schematically illustrates a circuit board  1  viewed from a side according to some embodiments. The circuit board  1  is a unitarily formed multilayer circuit board similar to the circuit board shown in  FIG.  10   , however, in contrast the groove  17  has been made with a one-sided undercut  32 . The liquid encapsulation layer  13  applied to the shielding zone  11  has flown into the groove  17 , and if not for the groove  17  the encapsulation layer  13  would likely have flown out of the shielding zone  11  and into the non-shielding zone  12 . Thus, the groove  17  provided in the circuit board  1  solved the issue shown in  FIG.  7   , where the encapsulation layer  13  had flown into the non-shielding zone  12 . A shielding  15  has been applied on top of at least part of the encapsulation layer  13  and couples electrically to the ground connection  9  such that the shielding-zone electronic component  7  is electromagnetically shielded. Additionally, it may be arranged that the shielding layer  15  can couple electrically with one or more of the conductive circuit board layers  19  making up the sides of the groove  17 . For example, the shielding layer  15  may be able to couple electrically with the top conductive circuit board layer  19  as shown in  FIG.  11   . This may be utilised to save space on the circuit board  1  as the surface-mounted ground connection  9  may not be needed, see  FIG.  12    for another example. 
       FIG.  12    schematically illustrates a circuit board  1  viewed from a side according to some embodiments. The circuit board  1  is a unitarily formed multilayer circuit board similar to the circuit board shown in  FIG.  10   , however, in contrast the circuit board layer, which forms the bottom of the groove  17  is a conductive circuit board layer  19 , which is grounded. The liquid encapsulation layer  13  applied to the shielding zone  11  has formed a bulge  18  due to surface tension when flowing towards the groove(s)  17 . This has made it possible for the shielding layer  15  to connect to ground  9  in the bottom of the groove  17  thus saving the space taken up by a ground connection  9  on the first surface/top layer  4 ,  25  of the circuit board  1 . The space taken up by a surface-mounted ground connection  9  on the first surface/top layer  4 ,  25  of the circuit board  1  can have a width of e.g. 2-400 μm and, advantageously, that space may be saved. Even if some of the encapsulation layer  13  had flown into the groove  17 , it could be arranged that the shielding layer  15  could connect to one or more of the conductive circuit board layers  19  making up the sides of the groove  17  as discussed also in connection with  FIG.  11   . 
       FIG.  13    schematically illustrates a circuit board  1  viewed from a side according to some embodiments. A trapezoidal groove  17  has been provided in the circuit board  1 , i.e. it is the cross-sectional shape, which is trapezoidal. The groove may be provided by any known method to carve, cut, punch, etc. in the materials used for circuit boards. For example, the groove is provided by performing laser cutting, and/or punching. The circuit board  1  is a unitarily formed multilayer circuit board, but the trapezoidal groove may be provided in any type of circuit board. A trapezoidal groove is characterised by four angles, as further illustrated in  FIG.  14   . 
       FIG.  14    schematically illustrates a circuit board  1  viewed from a side according to some embodiments. A trapezoidal groove  17  has been provided in a unitarily formed multilayer circuit board  1 . When the groove  17  is viewed in a cross-sectional cut that is perpendicular to the surface of the circuit board and perpendicular to the top edges of the groove, as in  FIG.  14   , the sides of the groove  17 , which extend into the circuit board, make a first  33  and a fourth  39  angle with respect to the first surface  4  of the circuit board  1 . The first angle  33  is the angle closer to the shielding zone  11  and the fourth angle  39  is the angle closer to the non-shielding zone  12 . The sides of the groove  17 , which extend into the circuit board  1 , further make a second  35  and a third  37  angle with respect to the bottom of the groove  17 , the second  35  angle being closer to the first  33  angle. In the example of a groove  17  illustrated in  FIG.  14   , the first  33  and fourth  39  angles are the same and acute, i.e. less than 90 degrees, and the second  35  and third  37  angles are the same and obtuse, i.e. more than 90 degrees. The bottom side is parallel to the surface of the circuit board and the two sides of the groove  17  are not parallel. For the trapezoidal groove the four angles  33 ,  35 ,  37 ,  39  can be optimised so as to achieve the desired technical effect of reducing the risk of the encapsulation layer  13  overflowing out of the shielding zone  11 . 
       FIGS.  15 A,  15 B, and  15 C  schematically illustrates the geometry of the groove  17  according to some embodiments. In  FIG.  15 A  is shown an example of a trapezoidal groove  17 , wherein all the four angles  33 ,  35 ,  37 ,  39  are different. The first  33  and fourth  39  angles are acute, i.e. less than 90 degrees, and the second  35  and third  37  angles are obtuse, i.e. more than 90 degrees. The bottom side is parallel to the surface of the circuit board and the two sides of the groove  17  are not parallel. In  FIG.  15 B  is shown an example of a trapezoidal groove  17 , wherein the first  33  and third  37  angles are obtuse, and the second  35  and fourth  37  angles are acute. All four angles are different from each other. The two sides of the groove  17  are parallel, and the bottom side is not parallel to the surface of the circuit board. In  FIG.  15 C  is shown an example of a trapezoidal groove  17  that is wider at the bottom than at the top. The first  33  and the fourth  39  angles are the same and obtuse, and the second  35  and third  37  angles are the same and acute. 
       FIG.  16    schematically illustrates an in-ear-type hearing device  50 , which comprises a circuit board  1  according to some embodiments. The in-ear-type hearing device  50  is designed to be placed at least partly within the ear canal EC of the user during use. Hearing devices generally, and in particular the in-ear-type, are pressed for space and circuit boards  1  for such devices need to have a small form-factor. Therefore, the electronic components are made ever smaller and positioned closer and closer together. In addition, hearing devices often comprise both electronic components, which produce electromagnetic noise, and electronic components, which are sensitive to electromagnetic noise. Therefore, such devices can advantageously make use of an improved circuit board  1  as disclosed herein. 
       FIG.  17    schematically illustrates a behind-the-ear-type hearing device  60 , which comprises a circuit board  1  according to some embodiments. Hearing devices generally, and in particular the in-ear-type, are pressed for space and circuit boards  1  for such devices need to have a small form-factor. Therefore, the electronic components are made ever smaller and positioned closer and closer together. In addition, hearing devices often comprise both electronic components, which produce electromagnetic noise, and electronic components, which are sensitive to electromagnetic noise. Therefore, such devices can advantageously make use of an improved circuit board  1  as disclosed herein. 
     Although features have been shown and described, it will be understood that they are not intended to limit the claimed invention, and it will be made obvious to those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the claimed invention. The specification and drawings are accordingly to be regarded in an illustrative rather than restrictive sense. The claimed invention is intended to cover all alternatives, modifications, and equivalents. 
     LIST OF REFERENCES 
     
         
           1  Circuit board 
           3  Substrate 
           4  First surface 
           5  Unshielded electronic components/ non-shielding-zone electronic components 
           6  Second surface 
           7  Shielded electronic components/ shielding-zone electronic components 
           9  Ground ring/Shield ring/Ground connection 
           11  Shielding zone 
           12  Non-shielding zone 
           13  Encapsulation layer 
           15  Shielding layer 
           16  Overflow 
           17  Groove 
           18  Bulge 
           19  Conductive layers 
           21  Non-conductive layers 
           23  Via 
           25  Top layer 
           27  Bottom layer 
           29  Cut layers in multilayer board 
           31  Uncut layers in multilayer board 
           32  Undercut 
           33  First angle 
           35  Second angle 
           37  Third angle 
           39  Fourth angle 
           50  In-ear-type hearing device 
           60  Behind-the-ear-type hearing device 
           100  Method of manufacturing an electronic circuit board 
           101  Provide circuit board 
           102 A Provide plurality of circuit board layers 
           102 B Make through-holes in one or more circuit board layers 
           102 C Assemble plurality of circuit board layers 
           103  Define shielding zone 
           105  Provide groove 
           107  Apply encapsulation layer 
           107 A Apply liquid encapsulation layer 
           107 B Cure encapsulation layer 
           109  Apply shielding layer 
           109 A Apply liquid shielding layer 
           109   b  Cure shielding layer 
         A Cross-section line 
         D Depth of groove 
         EC Ear canal 
         W Width of groove