The present invention generally relates to a microphone assembly for a motor vehicle, and in particular to a microphone assembly having shielding function.
One or more microphones are typically mounted inside the cabin of vehicle to pick up passengers' voice signals to enable various intelligent applications such as hands-free telephone, voice recognition, and/or emergency calls. Prior arts have provided microphone assemblies that integrate microphones (e.g., MEMS microphones) into existing interior control modules of vehicle (e.g., instrument panels, central console, overhead console, etc.). The microphone integrated are in communication with a plurality of electronic devices arranged on the interior control modules.
Typically, a microphone communicates with a transceiver in differential signal, such as by means of an A2B audio bus. In this case, the transceiver responds to the electrical difference between two signals received from the microphone. Since there is no ground line in the differential signal bus, the ground of the microphone is floating, rather than electrically connecting to the vehicle chassis ground. Moreover, in order to ensure the acoustic performance, a microphone needs to be arranged as close as possible to the outer cover (less than 5 mm apart). This arrangement causes that the microphone typically becomes a weak point of electrostatic discharge (ESD). In motor vehicles, the accumulation and release of electrostatic charge due to electrostatic on human body, friction, induction, and etc. are unavoidable. Once subjected to electrostatic discharge, the ungrounded microphone may be affected. For example, the signal quality may be temporarily affected, or even the microphone may be permanently damaged. In current design of microphone assemblies for vehicles, ESD robustness is typically only a few kV, being below the automotive ESD standard of at least 15 kV.
Hence, the present invention intends to improve the ESD robustness of a microphone assembly for a motor vehicle.
The present invention provides a microphone assembly having shielding function for a motor vehicle, comprising: a microphone circuit board having a microphone, which is supplied by a differential audio bus such that the ground potential of the microphone is floating; a cover which is located outside the microphone circuit board; a foamy part which is located between the cover and the microphone circuit board; and a shielding film which is suitable for shielding the microphone against electrostatic discharge, wherein the shielding film is located between the cover and the foamy part and covers the outer surface of the foamy part, and wherein the shielding film is electrically conductive and grounded to a vehicle chassis ground potential. In this situation, the shielding film can collect electrostatic charges and guide them to the chassis ground of the vehicle, so that the electronic components on the microphone circuit board under the shielding film, especially the microphones having the floating ground, can be shielded from electrostatic discharge damage, such that the ESD robust performance of the microphone assembly is significantly improved. In addition, the shielding film can also shield the microphone from electromagnetic fields.
In some embodiments, the shielding film is electrically connected to a chassis ground terminal provided on the microphone circuit board. In this situation, the shielding film can be grounded by electrically connecting to the microphone circuit board.
In some embodiments, the assembly further comprises another circuit board, and the shielding film is electrically connected to a chassis ground terminal provided on said another circuit board. In this situation, the shielding film can be grounded by electrically connecting to the said another circuit board. One example for the said another circuit board is main application circuit board, which provides power to and/or communicates with the microphone circuit board.
The present invention provides various embodiments for grounding the shielding film.
According to the first embodiment, the inner surface of the cover has an electrically conductive portion, which is electrically connected to the chassis ground terminal through a connecting member; and the outer surface of the shielding film electrically contacts the electrically conductive portion of inner surface of the cover in order to ground the shielding film. This approach eliminates the need of specifically designing the structure of the shield film or foamy part and is therefore easy to use.
Optionally, the connecting member may be an electrically conductive spring contact, which is compressively located between the cover and the microphone circuit board or said another circuit board. In addition, the inner surface of the cover may also be connected to the corresponding chassis ground terminal by bolt or the like.
According to the second embodiment, the shielding film has an extruding portion which extends beyond the foamy part and electrically connects to the chassis ground terminal provided on the microphone circuit board or said another circuit board.
Optionally, the extruding portion extends downward and backward to the inner surface of the microphone circuit board, and the end of the extruding portion is attached to a chassis ground terminal provided on the inner surface of the microphone circuit board.
Optionally, the extruding portion extends downward and forward to the outer surface of the microphone circuit board, and the end of the extruding portion is attached to a chassis ground terminal provided on the outer surface of the microphone circuit board.
Optionally, the extruding portion of the shielding film may be attached to the chassis ground terminal through an electrically conductive adhesive. In addition, the extruding portion may also be connected to the corresponding chassis ground terminal by bolt or the like.
According to the third embodiment, the assembly further comprises a rubber connector which is compressively assembled between the microphone circuit board and said another circuit board; and the extruding portion of the shielding film extends downward and backward in order to be at least partially interposed between the rubber connector and the microphone circuit board, such that the extruding portion is electrically connected to the chassis ground terminal of said another circuit board through the rubber connector. In this way, it is not necessary to make significant adjustment to the structure of the existing microphone circuit board, and thus the operation is convenient.
According to the fourth embodiment, the inner surface of the shielding film is electrically connected to the chassis ground terminal provided on the microphone circuit board through a connecting member.
Optionally, the connecting member may be an electrically conductive spring contact, which is located within a through-hole of the foamy part covered by the shielding film, and the spring contact is compressively located between the inner surface of shielding film and the microphone circuit board.
In the embodiments of the present invention, optionally, the inner surface of the cover is provided with an electrically conductive layer, which electrically connects to the outer surface of the shielding film.
Optionally, the shielding film has a mesh film structure.
Optionally, the shielding film may be glued or stuck onto the outer surface of the foamy part.
Optionally, the foamy part is provided with an acoustic hole for the microphone, and the acoustic hole is covered by the shielding film.
The present invention further provides an interior module for a motor vehicle, which comprises the microphone assembly as disclosed above.
The present invention further provides a motor vehicle comprising the interior module as disclosed above.
The above features and advantages and other features and advantages of the present invention are apparent from the following detailed description of the best embodiments by referring the accompanying drawings.
In the drawings and the following detailed description, the same or similar components are denoted by the same reference numerals. The drawings are intended to be illustrative of the present invention but not to limit the invention in any way. For example, the dimensions and proportions shown in the drawings do not limit the invention. Also, various features that are well known in the art are not described in detail in order to avoid obscuring the understanding of the invention.
The cover 2 is located outside the microphone circuit board 1 for protecting the microphone circuit board 1 and other components from the external environment. The cover 2 may be a molded plastic piece. The cover 2 may be the outer housing of the vehicle interior control module (as shown in FIG.1) incorporating this microphone assembly, or the cover 2 may be a separate housing dedicated to this microphone assembly (as best shown in
The foamy part 3 is disposed between the cover 2 and the microphone circuit board 1. The foamy part 3 is usually made of a foamy material having a porous structure. The upper and lower sides of the foamy part 3 abut against the inner surface of the cover 2 and the outer surface of the microphone circuit board 1, respectively. The foamy part 3 functions as a vibration absorbing layer to prevent the mechanical vibration in the cover 2 from propagating to the microphone circuit board 1 below, thereby ensuring the acoustic performance of the microphone M. As shown in
The shielding film 4 is disposed outside the foamy part 3. As shown in
In order to enable grounding, the shielding film 4 may be electrically connected to the chassis ground terminal 1G provided on the microphone circuit board 1. Additionally or alternatively, the shielding film 4 may be electrically connected to a chassis ground terminal 5G disposed on another circuit board 5. Said another circuit board 5 may be a main application circuit board 5 carrying other functions of the vehicle module. The main application circuit board 5 may be electrically coupled to the microphone circuit board 1 for power transmission and/or signal communication. It will be understood by those skilled in the art that the chassis ground terminal 1G or 5G can be disposed at any suitable position, for example, on either side of the corresponding microphone circuit board 1 or said another circuit board 5.
As shown in
As shown, a support member may be provided on the outer surface of the end 42 of the extruding portion 41. The support member may be a metal sheet having a rigidity greater than that of the shielding film 4, so that the end 42 can be easily displaced, attached, or the like.
In other embodiments, the extruding portion 41 can also be attached to the circuit board in a manner other than conductive adhesive, such as a screw, a bolt or the like. In addition, the extruding portion 41 may also possible to extend to electrically connect the ground terminal 5G on the main application circuit board 5 below the microphone circuit board 1. The person skilled in the art can adjust the shape, size, attachment manner, and the like of the extruding portion 41 according to the specific structure and size of the microphone assembly.
Specifically, as shown in
The spring contact 7 is located in the through hole 32 of the foamy part 3, and the lower end thereof is mounted on the microphone circuit board 1 and electrically connected to the ground terminal 1G. The upper end of the spring contact 7 abuts against the inner surface of the shielding film 4. The spring contact 7 is elastically compressively arranged between the shielding film 4 and the microphone circuit board 1 to achieve a stable electrical connection. In the microphone assembly, the inner surface of the cover 2 is pressed against the shielding film 4 from the upper side, which in turn ensures that the spring contact 7 below the shielding film 4 is stably placed in position.
Although the illustrated example shows that the connecting member 7 is a spring contact 7, the present invention is not limited thereto, and other structures may be employed, such as an elastic rubber electrical connector separate or integral with the foamy part 3, or a bolt assembly simultaneously connected to the shielding film 4 and the microphone circuit board 1, and the like.
This kind of rubber electrical connector used in a microphone assembly has been disclosed in Chinese patent application CN201710266229.3, which is entirely incorporated herein by reference. Such rubber connector comprises staggered conductive strips and insulating strips. The pitch of the conductive strips is arranged to effectively electrically connect corresponding terminals on two opposite circuit boards, thereby implementing interconnection between two circuit boards face-to-face. The rubber connector is typically elastically compressively disposed between two circuit boards to achieve a stable electrical connection, and isolate mechanical vibrations from propagating between the boards at same time.
As shown in FIG.6A, the end 42 of the extruding portion 41 has a projection 43. When the extruding portion 41 is placed in position, the projection 43 and the exposed terminals 12 on the microphone circuit board 1 are arranged side by side so as to form an array for mating with the conductive strips in the rubber connector 8. In other words, the pitch in the array including the projection 43 is consistent with the pitch of conductive strips in the rubber connector 8. In addition, the end 42 can also be provided with a support such as a metal sheet for supporting the relatively soft extruding portion 41. In this case, a recess matching with the shape of the end 42 may be provided inside the microphone circuit board 1, as best shown in
In the first embodiment described above, it is disclosed that the cover 2 has an electrically conductive inner surface portion. However, in the second, third and fourth embodiments described above, it is also possible to provide the cover 2 with same conductive inner surface portion being in electrical contact with the outer surface of the shielding film 4. In this case, the conductive inner surface portion of the cover 2 can also serve as a current collector for electrostatic charge and conduct electrostatic charge to the shielding film 4, thereby enhancing the ESD shielding effect of the microphone assembly. Additionally or alternatively, another electrically conductive layer may also be disposed between the shielding film 4 and the cover 2 to further enhance the shielding effect.
In another aspect of the invention, a vehicle interior module including the aforementioned microphone assembly is provided. The vehicle interior module is, for example, an overhead console, a central console, a rear view mirror, a dashboard, and the like. This interior module integrates a microphone function so as to capture passengers' voice. By virtue of the shielding film as disclosed above grounding to the vehicle chassis ground, the microphone unit in the interior module exhibits a high ESD robustness, and is capable of withstanding higher voltage electrostatic discharge.
In yet another aspect of the present invention, a motor vehicle including the aforementioned vehicle interior module is provided. This motor vehicle can implement a microphone function inside the cabin, which microphone function can withstand a higher voltage of electrostatic discharge.
Although the invention has been described with reference to a limited number of embodiments, it is understood that some other embodiments of the invention may be devised by those skilled under the teaching of the present disclosure without departing from the scope of the invention disclosed herein. Therefore, the scope of the invention is limited merely by the appended claims.
Number | Date | Country | Kind |
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201710605417.4 | Jul 2017 | CN | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2018/070057 | 7/24/2018 | WO | 00 |