RU2808517C1 - Antenna equipment and electronic device - Google Patents

Abstract

FIELD: antennas.

SUBSTANCE: invention is related in particular to antenna equipment and electronic devices. An electronic communication device is proposed, which includes a frame, a screen and a printed circuit board assembly. The screen is mounted on one side of the frame. The frame section forms the antenna emitter, or the antenna emitter is fixed on the inside of the frame. The printed circuit board assembly is located on the inside of the frame. The printed circuit board assembly includes a first conductive member and a first board, a riser board, and a second board stacked in series. The first board is located on one side of the second board away from the screen and includes a first main body portion and a first extension portion connected to the first main body portion. The first part of the main body is fixedly connected to the lifting plate. The first extension part projects relative to the riser plate and the second plate and is located close to the emitter. The first conductive element is attached to the first extension part and is in elastic contact with the emitter.

EFFECT: increase the lumen area of the antenna of an electronic device and improve the performance of the antenna.

20 cl, 40 dwg

Description

[0001] This application claims priority to Chinese Patent Application No. 202010292512.5, filed with the National Intellectual Property Office of China on April 14, 2020, entitled “ANTENNA APPARATUS AND ELECTRONIC DEVICE,” which is incorporated herein by reference in its entirety.

TECHNICAL FIELD

[0002] The present invention relates to the technical field of antennas and, in particular, to antenna equipment and electronic devices.

BACKGROUND OF THE ART

[0003] As electronic device technology advances, users hope that more electronic components (such as cameras and various types of sensors) can be integrated into a mobile phone to realize more diverse functions of the mobile phone. However, as more and more electronic components are packaged inside a mobile phone, there is less and less space available for antenna layout. In addition, with the rapid development of 5G mobile phones, more and more 5G frequency bands and more and more antennas are available. Thus, in a cramped environment in which there is little space for antenna arrangement and the number of antennas is large, the antenna clearance area of a traditional mobile phone is small, and the antenna has poor ability to transmit and receive electromagnetic waves.

SUMMARY OF THE INVENTION

[0004] The clearance area of the electronic device provided by the technical solutions of this application is larger, and the antenna performance of the electronic device is better.

[0005] According to a first aspect, an electronic device is provided. The electronic device may be a cell phone, watch, or other device capable of transmitting and receiving electromagnetic wave signals. The electronic device includes a frame, a screen, and a printed circuit board assembly.

[0006] The screen is mounted on one side of the frame. In some implementation, the screen includes a protective cover plate and a display screen. The protective cover plate is placed on the display screen. The display screen is located close to the PCB assembly relative to the protective cover plate. The protective cover plate can be mainly configured to protect the display screen and prevent dust from entering.

[0007] Some portion of the frame forms an antenna emitter, or the antenna emitter is fixed to the inside of the frame.

[0008] The printed circuit board assembly is located on the inside of the frame. The printed circuit board assembly includes a first conductive member and a first board, a riser board, and a second board stacked in series. In other words, the lifting board is located between the first board and the second board. The first board is located on one side of the second board from the screen. In other words, the first board is located at a distance from the screen relative to the second board. The first board includes a first main body portion and a first extension portion connected to the first main body portion. The first part of the main body is fixedly connected to the lifting plate. The first extension portion projects relative to the riser plate and the second board and is located close to the emitter. The first conductive element is attached to the first extension part. The first conductive element is in elastic contact with the emitter.

[0009] It should be noted that the first conductive element may be an elastic member having electrical conductivity, or alternatively may be a spring having electrical conductivity, which is not limited to this application. In each of the solutions that can be implemented below, the first conductive element is described using the example of a first elastic part.

[0010] In this implementation, by placing a first extension portion that projects relative to the riser board and the second board, and rigidly connecting the first elastic portion to the first extension portion, the first elastic portion is positioned away from the display screen of said screen, that is, in the thickness direction electronic device, the distance between the first elastic part and the display screen becomes larger. Thus, the clearance area of the antenna between the first elastic member and the display screen can be increased to a greater extent, and the performance of the antenna is improved.

[0011] In addition, when the first elastic member is located away from the display screen, the contact point at which the first elastic member is in contact with the emitter may also be arranged away from the display screen. Thus, the display screen has less influence on the contact point (feed point) between the first elastic part and the emitter.

[0012] In addition, compared to the solution of fixing the first elastic part on the second board, in this implementation, by fixing the first elastic part on the first extension part, there are no more components or wiring associated with the antenna (for example, antenna switches, inductors, capacitors or resistors) located on the riser board and the second board. Thus, on the one hand, the design of the PCB assembly is simplified, that is, the assembly complexity of said PCB assembly is reduced, and the cost of PCB assembly is lower; and on the other hand, more space can be freed up on the second board to accommodate more electronic components.

[0013] In addition, by bringing the first elastic member into elastic contact with the emitter, more stable transmission of radio frequency signals between the first elastic member and the emitter is provided. Specifically, since the first elastic member has an elastic force, the first elastic member can always be in contact with the emitter when the first elastic member is in elastic contact with the emitter, so that the connection stability between the first elastic member and the emitter is improved.

[0014] In addition, by sequentially stacking the first board, the riser board, and the second board, it is possible to significantly increase the board area of the circuit board assembly, thereby increasing the number of electronic components arranged on the circuit board assembly. In particular, when the first board and the second board are lifted by the lifting board, on the circuit board assembly, electronic components (such as a CPU, a battery management chip, etc.) can be arranged not only on the surface of the first board facing the rear cover, and the surface of the second board facing the display screen, but may also be arranged in the space between the first board and the second board (on the surface of the first board facing the second board and the surface of the second board facing the first board). In other words, more electronic components can be arranged on the PCB assembly of this implementation. Thus, on the one hand, the electronic device has more and more functions and a better user experience; and on the other hand, in the case where the internal environment of the electronic device is cramped, by arranging a large number of electronic components of the electronic device on a printed circuit board assembly, more space inside the electronic device can be freed up. When this area of space is used for the antenna clearance area, the antenna clearance area can be significantly increased, thereby greatly improving the antenna performance.

[0015] In an exemplary implementation according to the first aspect, the electronic device further includes a radio frequency path. The radio frequency path may be configured to transmit radio frequency signals to an antenna radiator such that the antenna radiator transmits electromagnetic wave signals in accordance with the radio frequency signals. In addition, when the antenna radiator converts the received electromagnetic wave signals into radio frequency signals, the radio frequency path may be further configured to receive the radio frequency signals transmitted by the antenna radiator. In this case, the first elastic part is electrically connected between the radio frequency path and the emitter.

[0016] In another possible implementation, the first resilient member is electrically connected between the emitter and the ground plane of the first extension portion.

[0017] In another possible implementation, the first elastic member is electrically connected to the ground plane of the first extension part through a matching network.

[0018] In accordance with the first aspect, or any of the implementations of the first aspect described above, the first elastic member is attached to one side of the first extension portion facing the screen. In this case, the first elastic member, the lifting plate and the second board are located on the same side of the first board. In the thickness direction of the electronic device, there is an overlap region between the first elastic member and the lifting plate. The first elastic part uses the space of the riser plate facing the side of the emitter. Thus, in the thickness direction of the electronic device, the circuit board assembly is not thickened due to the configuration of the first elastic member.

[0019] In addition, the space between the surface of the first extension portion facing the screen and the emitter is generally small. Conventional chips or electronic components are not easily placed in this area. In this case, the space is not used, which easily leads to wastage of space. In this implementation, by attaching a small-sized first elastic piece to one side of the first extension portion facing the display screen, on the one hand, the space of this portion can be effectively used to improve the utilization of the internal space of the electronic device; and on the other hand, compared with the case in which the first elastic member is located on one side of the first board facing the rear cover, in this embodiment, the space occupied by the at least one first elastic member can be saved due to the space between the first board and the back cover, in which case the saved space can be used to arrange more electronic components, thereby improving the utilization of PCB assembly space to a greater extent.

[0020] In accordance with the first aspect, or any of the implementations of the first aspect described above,

[0021] Additionally, the distance L from the contact point between the first elastic member and the emitter to the display screen is greater than or equal to 2 mm. For example, L is equal to 2 mm, 2.5 mm, 3 mm, 3.5 mm or 4 mm.

[0022] It is understood that when the distance L from the contact point between the first elastic member and the emitter to the display screen is greater than or equal to 2 mm, the first elastic member can be further removed from the display screen. Thus, the clearance area of the antenna between the first elastic member and the display screen can be increased to a greater extent, and the performance of the antenna is improved.

[0023] According to the first aspect or any of the implementations of the first aspect described above, the distance L from the point of contact between the first elastic member and the emitter to the display screen is less than or equal to 4.7 mm.

[0024] It is understood that when the distance L from the contact point between the first elastic part and the emitter to the display screen is less than or equal to 4.7 mm, on the one hand, it can be ensured that the first elastic part is removed from the display screen; and on the other hand, it can be ensured that the thickness of the electronic device in the Z direction is small, which is conducive to thinning the configuration.

[0025] According to the first aspect or any of the implementations of the first aspect described above, the distance between the first elastic member and the lifting plate is from 0.15 mm to 30 mm.

[0026] It is understood that when the distance between the first elastic member and the lifting plate is from 0.15 mm to 30 mm, the size of the first extension portion located between the first elastic member and the lifting plate is relatively moderate. Thus, when the first elastic member is in elastic contact with the emitter, the first elastic member receives the counter force of the emitter. The first elastic part transmits a counter force to the first extension part. In this case, the first extension portion located between the first elastic member and the lifting plate is not easily broken or cracked. In other words, the counter force received by the first extension part can be quickly transmitted to the lifting plate, thereby counteracting the counter force by the internal tension of the lifting plate.

[0027] In accordance with the first aspect, or any of the implementations of the first aspect described above, the printed circuit board assembly further includes a first reinforcement board. The first reinforcing board is located on one side of the first elastic part and is fixedly connected to the surface of the board of the first extension part facing the screen.

[0028] It can be understood that by laying the first reinforcing board on one side of the first elastic member and on the first extension portion, the thickness of the portions of the first extension portion is significantly increased, which further significantly improves the structural strength of the first board. Thus, when the first elastic member is in elastic contact with the emitter, the first elastic member receives the counter force of the antenna emitter. The first elastic part transmits a counter force to the first extension part of the first board. In this case, by interacting with the first amplification board, the first extension portion can effectively resist said force, thereby avoiding damage or cracking of the first extension portion due to the external force, and thus avoiding disconnection of the antenna circuit.

[0029] In accordance with the first aspect, or any of the implementations of the first aspect described above, the first amplification board includes a first part and a second part connected to the first part. The first part is fixedly connected to the board surface of the first extension part facing the screen, and the first part is fixedly connected to the lifting board. The second part is fixedly connected to the second board. In the thickness direction of the electronic device, the thickness of the first amplification board is greater than the thickness of the lifting board.

[0030] It can be understood that the first part and the second part are sequentially laid on the first extension part, the first part is fixedly connected to the lifting plate, and the second part is fixedly connected to the second board, thereby greatly improving the structural strength of the first board. Thus, when the first elastic member is in elastic contact with the antenna radiator, the first elastic member receives a counterforce of the antenna radiator. The first elastic part transmits a counter force to the first extension part of the first board. In this case, by interacting the first amplification board, the lifting board and the second board, the first extension portion can effectively resist said force, thereby preventing the first extension portion from being damaged or cracked due to the external force, and thereby avoiding disconnection of the antenna circuit.

[0031] In another possible implementation, the first reinforcing board is fixedly connected to the lifting board. In the thickness direction of the electronic device, the thickness of the first reinforcing board is less than or equal to the thickness of the lifting board.

[0032] It can be understood that the first reinforcing board is laid on the first extension portion, and the first reinforcing board is fixedly connected to the lifting board, thereby greatly increasing the structural strength of the first board. Thus, when the first elastic member is in elastic contact with the antenna radiator, the first elastic member receives a counterforce of the antenna radiator. The first elastic part transmits a counter force to the first extension part of the first board. In this case, by interacting the first reinforcing board and the lifting board, the first extension portion can effectively resist said force, thereby preventing the first extension portion from being damaged or cracked by the external force.

[0033] In accordance with the first aspect or any of the implementations of the first aspect described above, the first part and the lifting plate are of a single structure, and the second part and the second board are of a single structure. In other words, the first part and the lifting plate are a single board. In this case, the connection between the first part and the lifting plate is stronger. In this way, the first part and the lifting plate cannot be easily broken or cracked when exposed to external force. In addition, the second part and the second board are a single board. In this case, the connection between the second part and the second board is stronger. In this way, the second part and the second board cannot be easily broken or cracked when exposed to external force.

[0034] In another possible implementation, the first part may be permanently connected to the riser plate using a soldering process. Alternatively, the second part may be permanently connected to the second board using a soldering process.

[0035] In accordance with the first aspect, or any of the implementations of the first aspect described above, the first part is provided with a first solder reinforcement pad. The first extension part is provided with a second reinforcing solder pad. The first solder reinforcement pad is soldered to the second solder reinforcement pad.

[0036] It can be understood that when the first part and the first extension part are soldered to each other through the first solder reinforcement pad and the second solder reinforcement pad, the connection between the first part and the first extension part becomes stronger and the overall strength of the printed circuit board assembly better. In addition, after soldering the first solder enhancement pad and the second solder enhancement pad, the first solder enhancement pad and the second solder enhancement pad can effectively protect the solder pad (the solder pad of this portion is mainly configured for electrical connection between the wiring of the first board and riser board wiring) between the first part of the first board main body and the riser board. That is, the solder pad between the first body part and the riser plate is prevented from being easily destroyed by external force.

[0037] According to the first aspect or any of the implementations of the first aspect described above, the distance between the first elastic member and the first part is in the range of 0.15 mm to 30 mm. In this case, the size of the first extension portion located between the first elastic member and the first portion is relatively moderate. Thus, when the first elastic member is in elastic contact with the antenna emitter, the first elastic member receives the counter force of the emitter. The first elastic part transmits a counter force to the first extension part. In this case, the first extension portion located between the first elastic member and the first portion is not easily broken or cracked. In other words, the reaction force received by the first extension part can be quickly transmitted to the first part, thereby counteracting the reaction force due to the internal tension of the first part.

[0038] In accordance with the first aspect, or any of the implementations of the first aspect described above, the printed circuit board assembly further includes a second reinforcement board. The second reinforcing board is located on one side of the first elastic part at a distance from the first reinforcing board and is fixedly connected to the board surface of the first extension part facing the screen.

[0039] It can be understood that by laying the first reinforcing board on one side of the first elastic part and on the first extension part and laying the second reinforcing board on the other side of the first elastic part and on the first extension part, the thickness of the portion of the first extension part is significantly increased, which further significantly increases the structural strength of the first board. Thus, when the first elastic member is in elastic contact with the emitter, the first elastic member receives the counter force of the antenna emitter. The first elastic part transmits a counter force to the first extension part of the first board. In this case, by interacting the first amplification board and the second amplification board, the first extension portion can effectively resist said force, thereby avoiding damage or cracking of the first extension portion due to the external force, and thus avoiding disconnection of the antenna circuit.

[0040] In accordance with the first aspect or any of the implementations of the first aspect described above, the second amplification board includes a third part and a fourth part connected to the third part. The third part is fixedly connected to the board surface of the first extension part facing the screen, and the third part is fixedly connected to the lifting board. The fourth part is fixedly connected to the second board. In the thickness direction of the electronic device, the thickness of the second amplification board is greater than the thickness of the lifting board.

[0041] It can be understood that the third part and the fourth part connected to the third part are sequentially laid on the first extension part, the third part is fixedly connected to the lifting board, and the fourth part is fixedly connected to the second board, thereby greatly increasing the structural strength of the first board . Thus, when the first elastic member is in elastic contact with the antenna radiator, the first elastic member receives a counterforce of the antenna radiator. The first elastic part transmits a counter force to the first extension part of the first board. In this case, by interacting the first amplification board, the second amplification board, the lifting board and the second board, the first extension portion can effectively resist said force, thereby preventing the first extension portion from being damaged or cracked due to external force, and thus avoiding disconnection of the antenna circuit .

[0042] In another possible embodiment, the second reinforcing board is fixedly connected to the lifting board. In the thickness direction of the electronic device, the thickness of the second reinforcing board is less than or equal to the thickness of the lifting board.

[0043] In accordance with the first aspect, or any of the implementations of the first aspect described above, the third part and the riser plate are a single structure. The fourth part and the second board have a single design. In other words, the third part and the lifting board are a single board. In this case, the connection between the third part and the lifting plate is stronger. Therefore, the third part and the lifting plate are not easy to break or crack when exposed to external force. In addition, the fourth part and the second board are a single board. In this case, the connection between the fourth part and the second board is stronger. Therefore, the fourth part and the second board are not easy to break or crack when exposed to external force.

[0044] In another possible implementation, the third part may alternatively be fixedly connected to the riser plate using a soldering process. Alternatively, the fourth part can be permanently connected to the second board using a soldering process.

[0045] According to the first aspect or any of the implementations of the first aspect described above, the distance d3 between the first elastic member and the third part is in the range of 0.15 mm to 30 mm.

[0046] In this case, the size of the first extension portion located between the first elastic member and the third portion is relatively moderate. Thus, when the first elastic member is in elastic contact with the antenna emitter, the first elastic member receives the counter force of the emitter. The first elastic part transmits a counter force to the first extension part. In this case, the first extension portion located between the first elastic member and the third portion is not easily broken or cracked. In other words, the reaction force received by the first extension part can be quickly transmitted to the third part, thereby counteracting the reaction force by the internal tension of the third part.

[0047] In accordance with the first aspect or any of the implementations of the first aspect described above, the first extension portion is provided with a groove. The groove is located between the first amplification board and the second amplification board, and the opening of the groove is located on a surface of the first extension portion facing the screen. Some portion of the first elastic part is mounted in the groove.

[0048] It can be understood that when the first elastic piece portion is mounted in the groove in the thickness direction of the electronic device, there is an overlap region between the first elastic piece and the first extension portion. In this case, the first elastic member can be located further from the display screen, that is, in the thickness direction of the electronic device, the distance between the first elastic member and the display screen can be significantly increased. In this case, the distance from the point of contact between the first elastic part and the emitter to the display screen increases significantly. Thus, in the thickness direction of the electronic device, the antenna clearance area between the first elastic member and the display screen can be increased, and the performance of the antenna is improved.

[0049] In addition, when the first extension part is provided with a first reinforcement board and a second reinforcement board, the first reinforcement board and the second reinforcement board are located at the periphery of the groove. In this case, the first reinforcing board and the second reinforcing board can increase the strength of the first extension portion, thereby preventing the strength of the first extension portion from being reduced due to the groove opening.

[0050] According to the first aspect, or any of the implementations of the first aspect described above, the conductive member is located on a surface of the emitter facing the first resilient member. The first elastic part is in elastic contact with the conductive part.

[0051] It can be understood that when the conductive part is located on the emitter, the conductive part can improve the flatness of the surface of the emitter. Thus, when the first elastic member is in elastic contact with the emitter through the conductive member, the elastic contact between the first elastic member and the emitter is more stable. Thus, the RF signals are also more stable during transmission between the emitter and the first resilient member, resulting in better performance of the antenna of the electronic device.

[0052] According to the first aspect, or any of the implementations of the first aspect described above, the oxidation resistance of the conductive part is better than that of the emitter. It can be understood that in an environment with the same temperature and humidity, the conductive part is not as easy to oxidize compared to the emitter. Thus, compared with the solution in which the first elastic part directly comes into elastic contact with the emitter, the contact resistance between the first elastic part and the conductive part is smaller, that is, the contact resistance between the first elastic part and the conductive part is more stable, and the transmission loss There are fewer radio frequency signals. In this case, the antenna performance of the electronic device is better.

[0053] In accordance with the first aspect, or any of the implementations of the first aspect described above, the electronic device includes a mount. The emitter is equipped with a blind hole. The mount is fixed in a blind hole. The first elastic part is in elastic contact with the fastener.

[0054] It can be understood that, compared to the solution of soldering the conductive part to the emitter, this implementation saves on the process of soldering the conductive part to the emitter by placing the fastener in the blind hole of the emitter and electrically connecting the first elastic part to the antenna emitter through the fastener. Therefore, on the one hand, the cost of the electronic device is reduced, and there is no need to further increase the cost of the soldering process; and on the other hand, the case is excluded when the characteristics of the emitter when transmitting and receiving electromagnetic waves are affected by the formation of gas holes, slag inclusions, solder joints or cracks during the soldering process in the emitter.

[0055] In accordance with the first aspect, or any of the implementations of the first aspect described above, the emitter has an inner side surface facing the printed circuit board assembly. The first elastic part is in elastic contact with the inner side surface. In this way, the first elastic member can be further spaced from the display screen. In the thickness direction of the electronic device, the distance between the first elastic member and the display screen can be significantly increased. Thus, in the thickness direction of the electronic device, the clearance area of the antenna between the first elastic member and the display screen can be increased, and the performance of the antenna is improved.

[0056] In addition, the distance from the contact point between the first resilient member and the emitter to the display screen is significantly increased, in which case the interference of the display screen signal with the contact point of the first elastic member and the emitter is reduced.

[0057] In addition, the emitter may not have a protrusion for contacting the first elastic member, in which case, in the thickness direction of the electronic device, the protrusion-free space can also be used for the antenna clearance area. Thus, the antenna clearance area is larger and the antenna performance is better.

[0058] In accordance with the first aspect, or any of the implementations of the first aspect described above, the first elastic member is attached to one side of the first extension portion of the first board facing the rear cover. In addition, the first elastic part is in elastic contact with the emitter protrusion.

[0059] It is understood that by securing the first resilient member to one side of the first extension portion facing the rear cover and bringing the first resilient member into resilient contact with the emitter protrusion, the first resilient member may be positioned close to the rear cover to a greater extent, that is, the first elastic member may be positioned further away from the display screen, that is, in the thickness direction of the electronic device, the distance between the first elastic member and the screen display may be significantly increased. Thus, in the thickness direction of the electronic device, the protrusion configured to contact the first elastic member can be further removed from the display screen. The antenna clearance area between the bottom of the protrusion and the display screen can be increased and the antenna performance will be improved.

[0060] In addition, the distance from the contact point between the first resilient member and the emitter to the display screen is significantly increased, and in this case, the interference of the display screen signal with the contact point between the first elastic member and the emitter is reduced.

[0061] According to the first aspect, or any of the implementations of the first aspect described above, the first resilient member includes a first stationary member, an elastic member, and a second stationary member. The elastic element is connected between the first fixed part and the second fixed part. It will be understood that the elastic element may be, among other things, an elastic member or a spring. Additionally, the first stationary piece may be, among other things, a copper piece, an aluminum piece, or a gold piece. The second stationary piece may be, among other things, a copper piece, an aluminum piece, or a gold piece.

[0062] In addition, the first stationary piece is fixedly connected to the emitter. The second fixed part is fixedly connected to the first extension part of the first board.

[0063] It is understood that the first elastic part has a simple structure and is easy to assemble, which can reduce the complexity of assembling the electronic device.

[0064] In accordance with the first aspect or any of the implementations of the first aspect described above, the electronic device further includes a middle plate. The middle plate is located on the inside of the frame. The middle plate is grounded. The frame further includes a connecting segment. One end of the connecting segment is connected to the emitter, and the other end is connected to the middle plate.

[0065] It can be understood that the emitter is grounded in a relatively simple manner and has a simple design and relatively low capital investment.

[0066] In accordance with the first aspect, or any of the implementations of the first aspect described above, the printed circuit board assembly further includes a second conductive element. The second conductive element may be, but is not limited to, an elastic member or a spring. The second conductive element is located on the first extension portion of the first board. The second conductive element is electrically connected between the ground plane of the first board and the emitter. In other words, the second conductive element is designed to ground the emitter.

[0067] It can be understood that the emitter is grounded in a relatively simple manner and has a simple design and relatively low capital investment.

[0068] In accordance with the first aspect, or any of the implementations of the first aspect described above, the first board is provided with a second matching network. The second matching network includes an inductor, capacitor, resistor, or antenna switch. The second resilient member is electrically coupled to the second matching network and is electrically coupled to the ground plane of the first board through the second matching network. The second matching circuit is configured to adjust the antenna frequency bands for receiving and transmitting electromagnetic waves and matching the antenna impedance. Thus, the antenna is more widely used for transmitting and receiving electromagnetic waves and has better performance.

[0069] In accordance with the first aspect or any of the implementations of the first aspect described above, the electronic device further includes a middle plate. The middle plate is grounded. The middle plate is located on the inside of the frame. The printed circuit board assembly further includes a second conductive element and a third conductive element. The second conductive element is attached to the first extension portion of the first board. The second conductive element is in elastic contact with the emitter. The third conductive element is attached to the second board. The third conductive element is in elastic contact with the middle plate and is electrically connected to the second conductive element.

[0070] It can be understood that by placing a second conductive element on the first extension portion, placing a third conductive element on the second conductive element, and using the third conductive element for grounding, the grounding path of the emitter is enlarged. In this case, a matching circuit can be placed in the ground path of the emitter on the printed circuit board assembly to adjust the frequency bands of the antenna for receiving and transmitting electromagnetic waves, so that the frequency bands of the antenna for receiving and transmitting are wider.

[0071] In accordance with the first aspect, or any of the implementations of the first aspect described above, the emitter includes a projection facing the interior of the electronic device. The first conductive element is attached to one side of the first extension portion facing the screen. The first conductive element is in elastic contact with the protrusion, and the first conductive element is electrically coupled between the radiator and the radio frequency path of the antenna. The radio frequency path is mounted on a printed circuit board assembly;

[0072] The printed circuit board assembly further includes a first amplification board and a second amplification board. The first amplification board and the second amplification board are respectively located on two sides of the first conductive element. In the thickness direction of the electronic device, the thickness of the first enhancement board and the thickness of the second enhancement board are greater than the thickness of the lifting board.

[0073] The first amplification board includes a first part and a second part connected to the first part. The first part is fixedly connected to the board surface of the first extension part facing the screen. The first part is fixedly connected to the lifting plate. The second part is fixedly connected to the second board.

[0074] The second amplification board includes a third part and a fourth part connected to the third part. The third part is fixedly connected to the board surface of the first extension part facing the screen. The third part is fixedly connected to the lifting plate, and the fourth part is fixedly connected to the second board.

[0075] The first part, the third part and the lifting plate are of one-piece (single) structure. The second part, the fourth part and the second panel are of one-piece construction.

[0076] It can be understood that by sequentially laying the first part and the second part on one side of the first elastic part and on the first extension part, and sequentially laying the third part and the fourth part on the other side of the first elastic part and on the first extension part, the thickness of some portion of the first the extension part is significantly enlarged, thereby significantly increasing the structural strength of the first board. Thus, when the first elastic member is in elastic contact with the emitter, the first elastic member receives the counter force of the antenna emitter. The first elastic part transmits a counter force to the first extension part of the first board. In this case, by interacting the first part, the second part, the third part and the fourth part, the first extension part can effectively resist said force, thereby preventing the first extension part from being damaged or cracked due to the external force, and thus avoiding disconnection of the antenna circuit.

[0077] In addition, the first elastic part is attached to one side of the first extension part facing the display screen. In this case, the first elastic member, the lifting plate and the second board are located on the same side of the first board. In the thickness direction of the electronic device, there is an overlap region between the first elastic member and the lifting plate. The first elastic part uses the space of the lift plate facing the side of the emitter. Thus, in the thickness direction of the electronic device, the circuit board assembly is not thickened due to the configuration of the first elastic member.

[0078] In addition, the space between the surface of the first extension portion facing the screen and the emitter is generally small. Conventional chips or electronic components are not easily positioned in this area. In this case, the space is not used, which easily leads to wastage of space. In this implementation, on the one hand, by attaching the first elastic part of a relatively small size on the side of the first extension part facing the display screen, the space of this portion can be effectively used to improve the utilization of the internal space of the device, and, on the other hand, compared with the case in which the first elastic member is located on one side of the first board facing the rear cover, in this implementation, the space between the first board and the rear cover can save the space occupied by the at least one first elastic member. In this case, the saved space can be used to package more electronic components, thereby greatly improving the utilization of PCB assembly space.

[0079] In addition, the first part and the lifting board are a single board. In this case, the connection between the first part and the lifting plate is stronger. In this way, the first part and the lifting plate cannot be easily broken or cracked when exposed to external force. In addition, the second part and the second board are a single board. In this case, the connection between the second part and the second board is stronger. In this way, the second part and the second board cannot be easily broken or cracked when exposed to external force.

[0080] According to a second aspect, an electronic device is provided. The electronic device may be a mobile phone, watch, or other type of device capable of transmitting and receiving electromagnetic wave signals. The electronic device includes a frame, a screen, and a printed circuit board assembly.

[0081] The screen is mounted on one side of the frame. In some implementation, the screen includes a protective cover plate and a display screen. The protective cover plate is placed on the display screen. The display screen is located close to the PCB assembly relative to the protective cover plate. The protective cover plate can be mainly configured to protect the display screen and prevent dust from entering.

[0082] The frame portion forms an antenna emitter, or the antenna emitter is fixed to the inner side of the frame.

[0083] The printed circuit board assembly is located on the inside of the frame. The printed circuit board assembly includes a first board, a riser board, a second board, and a first conductive element. The first board and the riser board are both located on one side of the second board away from the screen. In other words, the first board and the riser board are located at a distance from the screen relative to the second board. The first board includes a first main body portion and a first extension portion connected to the first main body portion. The lifting plate includes a second main body portion and a second extension portion connected to the second main body portion. The first main body part, the second main body part and the second board are stacked sequentially. In other words, the second main body part is located between the first main body part and the second board. The first extension part and the second extension part are stacked on top of each other, and the first extension part and the second extension part protrude relative to the second board and are located close to the emitter. The first conductive element is attached to the second extension part and is in elastic contact with the emitter.

[0084] It should be noted that the first conductive element may be an elastic member having electrical conductivity, or alternatively may be a spring having electrical conductivity, which is not limited to this application. In each of the solutions that can be implemented below, the first conductive element is described using the example of a first elastic part.

[0085] In this implementation, by positioning the second extension portion that projects relative to the second board and the fixed connection of the first elastic portion to the second extension portion, the first elastic portion is positioned away from the display screen, that is, in the thickness direction of the electronic device, the distance between the first elastic portion the detail and display screen becomes larger. Thus, the clearance area of the antenna between the first elastic member and the display screen can be increased to a greater extent, and the performance of the antenna is improved.

[0086] In addition, when the first resilient member is located away from the display screen, the contact point between the first resilient member and the emitter may also be arranged away from the display screen. Thus, the contact point (feed point) at which the first elastic part contacts the emitter is less affected by the display screen.

[0087] In addition, by stacking the second extension portion on the first extension portion and, in this case, by interacting the second extension portion and the first extension portion, the overall strength of that portion can be increased. Thus, when the first elastic member is in elastic contact with the antenna emitter, the first elastic member receives the counter force of the emitter. The first elastic part transmits the counter force to the second extension part. In this case, by interacting the first extension portion, the second extension portion can effectively resist said force, thereby avoiding damage or cracking of the second extension portion due to the external force, and thus avoiding disconnection of the antenna circuit.

[0088] In addition, by bringing the first elastic member into elastic contact with the emitter, more stable transmission of radio frequency signals between the first elastic member and the emitter is provided. In particular, since the first elastic member has an elastic force, the first elastic member can always be in contact with the emitter when the first elastic member is in elastic contact with the emitter, so that the connection stability between the first elastic member and the emitter is better.

[0089] In an exemplary implementation according to the second aspect, the electronic device further includes a radio frequency path. The radio frequency path may be configured to transmit radio frequency signals to an antenna radiator such that the antenna radiator transmits electromagnetic wave signals in accordance with the radio frequency signals. In addition, when the antenna radiator converts the received electromagnetic wave signals into radio frequency signals, the radio frequency path may be further configured to receive the radio frequency signals transmitted by the antenna radiator. In this case, the first elastic part is electrically connected between the radio frequency path and the emitter.

[0090] In another possible implementation, the first resilient member is electrically connected between the emitter and the ground plane of the second extension portion.

[0091] In another possible embodiment, the first elastic member is electrically connected to the ground plane of the second extension part through a matching circuit.

[0092] According to the second aspect or any of the implementations of the second aspect described above, the first elastic member is attached to one side of the second extension portion facing the display screen. In this case, the first elastic member and the second plate are located on the same side of the lifting plate. In the thickness direction of the electronic device, there is an overlap region between the first elastic member and the second board. The first elastic part uses the space of the second board facing one side of the emitter. Thus, in the thickness direction of the electronic device, the circuit board assembly is not thickened due to the configuration of the first elastic member.

[0093] In addition, the space between the screen-facing surface of the second extension portion and the emitter is generally small. Conventional chips or electronic components are not easily placed in this area. In this case, the space is not used, which easily leads to wastage of space. In this implementation, on the one hand, by fixing the first elastic part of a small size on one side of the second extension part facing the display screen, the space of this part can be effectively used to improve the utilization of the internal space of the electronic device; and, on the other hand, compared to the case in which the first elastic part is located on one side of the first board facing the rear cover, in this embodiment, the space occupied by the at least one first elastic part can be saved due to the space between the first board and back cover, in which case the saved space can be used to package more electronic components, thereby improving the utilization of PCB assembly space to a greater extent.

[0094] According to the second aspect or any of the implementations of the second aspect described above, the distance L from the point of contact between the first elastic member and the emitter to the display screen is greater than or equal to 2 mm. For example, L is equal to 2 mm, 2.5 mm, 3 mm, 3.5 mm or 4 mm.

[0095] It is understood that when the distance L from the point of contact between the first elastic part and the emitter to the display screen is greater than or equal to 2 mm, the first elastic part can be located further away from the display screen. Thus, the clearance area of the antenna between the first elastic member and the display screen can be increased to a greater extent, and the performance of the antenna is improved.

[0096] According to the second aspect or any of the implementations of the second aspect described above, the distance L from the point of contact between the first elastic member and the emitter to the display screen is less than or equal to 4.7 mm.

[0097] It is understood that when the distance L from the contact point between the first elastic part and the emitter to the display screen is less than or equal to 4.7 mm, on the one hand, it can be ensured that the first elastic part is located away from the display screen; and on the other hand, it can be ensured that the thickness of the electronic device in the Z direction is small, which is conducive to thinning the configuration.

[0098] According to the second aspect or any of the implementations of the second aspect described above, the distance between the first elastic member and the second board is from 0.15 mm to 30 mm.

[0099] It can be understood that when the distance between the first elastic piece and the second board is from 0.15 mm to 30 mm, the size of the second extension portion located between the first elastic piece and the second board is relatively moderate. Thus, when the first elastic member is in elastic contact with the emitter, the first elastic member receives the counter force of the emitter. The first elastic part transmits the counter force to the second extension part. In this case, the second extension portion located between the first elastic member and the second board is not easily broken or cracked. In other words, the reaction force received by the second extension portion can be quickly transmitted to the second board, thereby counteracting the reaction force by the internal voltage of the second board.

[00100] In accordance with the second aspect, or any of the implementations of the second aspect described above, the printed circuit board assembly further includes a third reinforcement board. The third reinforcing board is located on one side of the first elastic part and is fixedly connected to the surface of the board of the second extension part facing the screen.

[00101] It can be understood that by laying the third reinforcing board on one side of the first elastic member and on the second extension portion, the thickness of the portion of the second extension portion is greatly increased, which further greatly improves the structural strength of the riser board. Thus, when the first elastic member is in elastic contact with the emitter, the first elastic member receives the counter force of the antenna emitter. The first elastic part transmits the counter force to the second extension part of the lifting plate. In this case, by interacting with the third reinforcing plate, the second extension portion can effectively resist said force, thereby avoiding damage or cracking of the second extension portion due to the external force and thus avoiding the antenna circuit being opened.

[00102] In accordance with the second aspect, or any of the implementations of the second aspect described above, the third amplification board and the second board are of a single structure. In other words, the third amplification board and the second board are a single board. In this case, the strength of the single structure of the third reinforcing board and the second board is better. Thus, the third reinforcing board and the second board cannot be easily broken or cracked when receiving external force.

[00103] In another possible implementation, the third amplification board may be connected to the second board using a soldering process, or the third amplification board may be located separately from the second board.

[00104] According to the second aspect or any of the implementations of the second aspect described above, the distance between the first elastic member and the third reinforcing board is from 0.15 mm to 30 mm. In this case, the size of the second extension portion located between the first elastic member and the third reinforcing board is relatively moderate. Thus, when the first elastic member is in elastic contact with the antenna emitter, the first elastic member receives the counter force of the emitter. The first elastic part transmits the counter force to the second extension part. In this case, the second extension portion located between the first elastic member and the third reinforcing board is not easily broken or cracked. In other words, the reaction force received by the first extension portion can be quickly transmitted to the third enhancement board, thereby counteracting the reaction force by the internal voltage of the third enhancement board.

[00105] In accordance with the second aspect, or any of the implementations of the second aspect described above, the printed circuit board assembly further includes a fourth reinforcement board. The fourth reinforcing board is located on one side of the first elastic part at a distance from the third reinforcing board and is fixedly connected to the surface of the board of the second extension part facing the screen.

[00106] It can be understood that by laying the fourth reinforcing board on one side of the first elastic piece and on the second extension portion, the thickness of the portion of the second extension portion is significantly increased, which further greatly improves the structural strength of the riser board. Thus, when the first elastic member is in elastic contact with the emitter, the first elastic member receives the counter force of the antenna emitter. The first elastic part transmits the counter force to the second extension part of the lifting plate. In this case, by interacting with the fourth amplification board, the second extension portion can effectively resist said force, thereby avoiding the second extension portion being damaged or cracked due to external force and thus preventing the antenna circuit from being disconnected.

[00107] In accordance with the second aspect, or any of the implementations of the second aspect described above, the fourth amplification board and the second board are a single structure. In other words, the fourth amplification board and the second board are a single board. In this case, the strength of the single structure of the fourth reinforcing board and the second board is better. Thus, the fourth reinforcing board and the second board cannot be easily broken or cracked when receiving external force.

[00108] In another possible implementation, the fourth enhancement board may be connected to the second board through a soldering process, or the fourth enhancement board may be located separately from the second board.

[00109] According to the second aspect or any of the implementations of the second aspect described above, the distance between the first elastic member and the fourth reinforcing board is from 0.15 mm to 30 mm. In this case, the size of the second extension portion located between the first elastic member and the fourth reinforcing board is relatively moderate. Thus, when the first elastic member is in elastic contact with the antenna emitter, the first elastic member receives the counter force of the emitter. The first elastic part transmits the counter force to the second extension part. In this case, the second extension portion located between the first elastic member and the fourth reinforcing board is not easily broken or cracked. In other words, the reaction force received by the first extension portion can be quickly transmitted to the fourth enhancement board, thereby counteracting the reaction force by the internal voltage of the fourth enhancement board.

[00110] According to the second aspect or any of the implementations of the second aspect described above, the second extension portion is provided with a groove, the groove is located between the third reinforcing board and the fourth reinforcing board, the opening of the groove is located on the screen-facing surface of the second extension portion, and a portion of the first elastic member mounted in a groove.

[00111] It can be understood that when the first elastic member portion is mounted in the groove in the thickness direction of the electronic device, there is an overlap region between the first elastic member and the second extension portion. In this case, the first elastic member can be located at a distance from the display screen, that is, in the thickness direction of the electronic device, the distance between the first elastic member and the display screen can be significantly increased. In this case, the distance from the point of contact of the first elastic part with the emitter to the display screen increases significantly. Thus, in the thickness direction of the electronic device, the antenna clearance area between the first elastic member and the display screen can be increased, and the performance of the antenna is improved.

[00112] In addition, when the second extension portion is provided with a first reinforcing board and a second reinforcing board, the first reinforcing board and the second reinforcing board can increase the strength of the second extension portion, thereby preventing the strength of the second extension portion from being reduced due to the groove hole.

[00113] According to the second aspect, or any of the implementations of the second aspect described above, the conductive member is located on a surface of the emitter facing the first resilient member. The first elastic part is in elastic contact with the conductive part.

[00114] It can be understood that when the conductive part is located on the emitter, the conductive part can improve the flatness of the surface of the emitter. Thus, when the first elastic member is in elastic contact with the emitter through the conductive member, the elastic contact between the first elastic member and the emitter is more stable. Thus, the RF signals are also more stable during transmission between the emitter and the first resilient member, resulting in better performance of the antenna of the electronic device.

[00115] According to the second aspect, or any of the implementations of the second aspect described above, the oxidation resistance of the conductive part is better than that of the emitter. It can be understood that in an environment with the same temperature and humidity, the conductive part is not as easily oxidized compared to the emitter. Thus, compared with the solution in which the first elastic part directly comes into elastic contact with the emitter, the contact resistance between the first elastic part and the conductive part is smaller, that is, the contact resistance between the first elastic part and the conductive part is more stable, and the transmission loss There are fewer radio frequency signals. In this case, the antenna performance of the electronic device is better.

[00116] According to the second aspect, or any of the implementations of the second aspect described above, the electronic device includes a mount. The emitter is equipped with a blind hole. The mount is fixed in a blind hole. The first elastic part is in elastic contact with the fastener.

[00117] It can be understood that, compared to the solution of soldering the conductive part to the emitter, this implementation saves the process of soldering the conductive part to the emitter by placing the fastener in the blind hole of the emitter and electrically connecting the first elastic part to the antenna emitter through the fastener. Therefore, on the one hand, the cost of the electronic device is reduced, and there is no need to further increase the cost of the soldering process; and on the other hand, the case is excluded when the characteristics of the emitter when transmitting and receiving electromagnetic waves are affected by the formation of gas holes, slag inclusions, solder joints or cracks during the soldering process in the emitter.

[00118] According to the second aspect, or any of the implementations of the second aspect described above, the emitter has an inner side surface facing the printed circuit board assembly. The first elastic part is in elastic contact with the inner side surface. In this way, the first elastic member can be further spaced from the display screen. In the thickness direction of the electronic device, the distance between the first elastic member and the display screen can be significantly increased. Thus, in the thickness direction of the electronic device, the antenna clearance area between the first elastic member and the display screen can be increased, and the performance of the antenna is improved.

[00119] In addition, the distance from the contact point of the first elastic part with the emitter to the display screen is significantly increased, and in this case, the interference of the display screen signal with the contact point between the first elastic part and the emitter is less.

[00120] In addition, the emitter may not have a protrusion for contacting the first elastic member, in which case, in the thickness direction of the electronic device, the protrusion-free space can also be used for the antenna clearance area. Thus, the antenna clearance area is larger and the antenna performance is better.

[00121] According to the second aspect, or any of the implementations of the second aspect described above, the first resilient member includes a first stationary member, an elastic member, and a second stationary member. The elastic element is connected between the first fixed part and the second fixed part. It will be understood that the elastic element may be, among other things, an elastic element or a spring. Additionally, the first stationary piece may be, among other things, a copper piece, an aluminum piece, or a gold piece. The second stationary part may be, among other things, a copper part, an aluminum part, or a gold part.

[00122] In addition, the first stationary piece is fixedly connected to the emitter. The second fixed part is fixedly connected to the second extension part of the lifting plate.

[00123] It is understood that the first elastic part has a simple structure and is easy to assemble, which can reduce the complexity of assembling the electronic device.

[00124] In accordance with the second aspect, or any of the implementations of the second aspect described above, the electronic device further includes a middle plate. The middle plate is located on the inside of the frame. The middle plate is grounded. The frame further includes a connecting segment. One end of the connecting segment is connected to the emitter, and the other end is connected to the middle plate.

[00125] It can be understood that the emitter is grounded in a relatively simple manner and has a simple design and relatively low capital investment.

[00126] In accordance with the second aspect, or any of the implementations of the second aspect described above, the printed circuit board assembly further includes a second conductive element. The second conductive element may be, but is not limited to, an elastic member or a spring. The second conductive element is located on the second extension portion of the lifting plate. The second conductive element is electrically connected between the ground plane of the riser plate and the emitter. In other words, the second conductive element is designed to ground the emitter.

[00127] It can be understood that the emitter is grounded in a relatively simple manner and has a simple design and relatively low capital investment.

[00128] According to the second aspect, or any of the implementations of the second aspect described above, the first board is provided with a second matching network. The second matching network includes an inductor, capacitor, resistor, or antenna switch. The second elastic element is electrically connected to the second matching circuit and is electrically connected to the ground plane of the riser plate through the second matching circuit. The second matching circuit is configured to adjust the antenna frequency bands for receiving and transmitting electromagnetic waves and matching the antenna impedance. Thus, the antenna is more widely used for transmitting and receiving electromagnetic waves and has better performance.

[00129] In accordance with the second aspect, or any of the implementations of the second aspect described above, the electronic device further includes a middle plate. The middle plate is grounded. The middle plate is located on the inside of the frame. The printed circuit board assembly further includes a second conductive element and a third conductive element. The second conductive element is attached to the second extension portion of the lifting plate. The second conductive element is in elastic contact with the emitter. The third conductive element is attached to the second board. The third conductive element is in elastic contact with the middle board and is electrically connected to the second conductive element.

[00130] It can be understood that by placing a second conductive element on the second extension portion, placing a third conductive element on the second conductive element, and using the third conductive element for grounding, the grounding path of the emitter is enlarged. In this case, a matching circuit can be placed in the ground path of the emitter on the printed circuit board to adjust the frequency bands of the antenna for receiving and transmitting electromagnetic waves, so that the frequency bands of the antenna for receiving and transmitting are wider.

[00131] In accordance with a third aspect, an electronic device is provided. The electronic device may be a mobile phone, watch, or other type of device capable of transmitting and receiving electromagnetic wave signals. The electronic device includes a frame, a screen, and a printed circuit board assembly.

[00132] The screen is mounted on a frame and located around the frame. In an implementation, the screen includes a protective cover plate and a display screen. The protective cover plate is placed on the display screen. The display screen is located close to the PCB assembly relative to the protective cover plate. The protective cover plate can be mainly configured to protect the display screen and prevent dust from entering.

[00133] In addition, the screen includes a first screen area and a second screen area located opposite each other.

[00134] The frame portion forms an antenna emitter, or the antenna emitter is fixed to the inner side of the frame.

[00135] The printed circuit board assembly is located on the inside of the frame. The printed circuit board assembly includes a first conductive member and a first board, a riser board, and a second board stacked in series. In other words, the lifting board is located between the first board and the second board. The first board is located at a distance from the first screen area relative to the second board. In other words, the first board is located at a distance from the first screen area relative to the second board. The first board includes a first main body portion and a first extension portion connected to the first main body portion. The first part of the main body is fixedly connected to the lifting plate. The first extension part projects relative to the riser plate and the second plate and is located close to the emitter. The first conductive element is attached to the first extension part and is in elastic contact with the emitter.

[00136] The distance from the point of contact between the first conductive element and the emitter to the first screen area is the first distance. The distance from the point of contact between the first conductive element and the emitter to the second screen area is the second distance. The ratio of the first distance to the second distance is in the range from 0.5 to 2.

[00137] It should be noted that the first conductive element may be an elastic member having electrical conductivity, or alternatively may be a spring having electrical conductivity, which is not limited to this application. In each of the solutions that can be implemented below, the first conductive element is described using the example of a first elastic part.

[00138] It is understood that when the first elastic member is attached to the second board in the thickness direction of the electronic device, the distance between the first elastic member and the first screen area is relatively small, that is, the first elastic member is located close to the first shield area. In this embodiment, by fixedly connecting the first elastic part to the first extension part, and when the ratio of the first distance to the second distance is in the range of 0.5 to 2, in the thickness direction of the electronic device, the distance between the first elastic part and the first screen area is increased more degrees. Thus, in the thickness direction of the electronic device, the antenna clearance area between the first elastic member and the first screen area can be increased to a greater extent, and the performance of the antenna can be further improved. In addition, when the ratio of the first distance to the second distance is from 0.5 to 2, the distance from the contact point between the first conductive element and the emitter to the second shield area is relatively small, and in this case, the second shield area has less influence on the antenna's performance. reception and transmission of electromagnetic waves.

[00139] In addition, by bringing the first elastic member into elastic contact with the emitter, more stable transmission of radio frequency signals between the first elastic member and the emitter is provided. In particular, since the first elastic member has an elastic force, the first elastic member can always be in contact with the emitter when the first elastic member is in elastic contact with the emitter, so that the connection stability between the first elastic member and the emitter is better.

[00140] In an exemplary implementation according to the third aspect, the electronic device further includes a radio frequency path. The radio frequency path may be configured to transmit radio frequency signals to an antenna radiator such that the antenna radiator transmits electromagnetic wave signals in accordance with the radio frequency signals. In addition, when the antenna radiator converts the received electromagnetic wave signals into radio frequency signals, the radio frequency path may be further configured to receive the radio frequency signals transmitted by the antenna radiator. In this case, the first elastic part is electrically connected between the radio frequency path and the emitter.

[00141] In another possible implementation, the first resilient member is electrically connected between the emitter and the ground plane of the first extension portion.

[00142] In another possible implementation, the first elastic member is electrically connected to the ground plane of the first extension part through a matching network.

[00143] In accordance with the third aspect or any of the implementations of the third aspect described above, the first elastic member is attached to one side of the first extension portion facing the first screen area. In this case, the first elastic member, the lifting plate and the second board are located on the same side of the first board. In the thickness direction of the electronic device, there is an overlap region between the first elastic member and the lifting plate. The first elastic part uses the space of the lift plate facing the side of the emitter. Thus, in the thickness direction of the electronic device, the circuit board assembly is not thickened due to the configuration of the first elastic member.

[00144] In addition, the space between the surface of the first extension portion facing the first screen area and the emitter is generally small. Conventional chips or electronic components are not easily placed in this area. In this case, the space is not used, which easily leads to wastage of space. In this implementation, on the one hand, by attaching a small-sized first elastic part to one side of the first extension part facing the first screen area, the space of this area can be effectively used to improve the utilization of the internal space of the electronic device; and, on the other hand, compared to the case in which the first elastic part is located on one side of the first board facing the rear cover, in this embodiment, the space occupied by the at least one first elastic part can be saved due to the space between the first board and back cover, in which case the saved space can be used to package more electronic components, thereby improving the utilization of PCB assembly space to a greater extent.

[00145] According to the third aspect or any of the implementations of the third aspect described above, the first distance from the point of contact between the first elastic member and the emitter to the first screen area is greater than or equal to 2 mm. For example, L1 is 2 mm, 2.5 mm, 3 mm, 3.5 mm or 4 mm.

[00146] It is understood that when the first distance L1 from the point of contact between the first elastic part and the emitter to the first screen area is greater than or equal to 2 mm, the first elastic part can be located further away from the first screen area. In this case, in the thickness direction of the electronic device, the antenna clearance area between the first elastic member and the first screen area can be increased to a greater extent, and the antenna performance is also improved.

[00147] In addition, the first distance L1 from the contact point between the first elastic member and the emitter to the first screen area is less than or equal to 4.7 mm.

[00148] It is understood that when the first distance L1 from the contact point between the first elastic part and the emitter to the first screen area is less than or equal to 4.7 mm, on the one hand, it can be ensured that the first elastic part is located at a distance from the first screen area; and on the other hand, it can be ensured that the thickness of the electronic device is small, which is conducive to thinning the configuration of the electronic device.

[00149] According to the third aspect, or any of the implementations of the third aspect described above, the distance between the first elastic member and the riser plate is from 0.15 mm to 30 mm.

[00150] It can be understood that when the distance between the first elastic member and the lifting plate is from 0.15 mm to 30 mm, the size of the first extension portion located between the first elastic member and the lifting plate is relatively moderate. Thus, when the first elastic member is in elastic contact with the emitter, the first elastic member receives the counter force of the emitter. The first elastic part transmits a counter force to the first extension part. In this case, the first extension portion located between the first elastic member and the lifting plate is not easily broken or cracked. In other words, the counter force received by the first extension part can be quickly transmitted to the lifting plate, thereby counteracting the counter force by the internal tension of the lifting plate.

[00151] In accordance with the third aspect, or any of the implementations of the third aspect described above, the printed circuit board assembly further includes a first reinforcement board. The first reinforcing board is located on one side of the first elastic part and is fixedly connected to the board surface of the first extension part facing the first screen area.

[00152] It can be understood that by laying the first reinforcing board on one side of the first elastic member and on the first extension portion, the thickness of the portion of the first extension portion is significantly increased, which further greatly improves the structural strength of the first board. Thus, when the first elastic member is in elastic contact with the emitter, the first elastic member receives the counter force of the antenna emitter. The first elastic part transmits a counter force to the first extension part of the first board. In this case, by interacting with the first amplification board, the first extension portion can effectively resist said force, thereby avoiding damage or cracking of the first extension portion due to the external force, and thus avoiding disconnection of the antenna circuit.

[00153] In accordance with the third aspect, or any of the implementations of the third aspect described above, the first amplification board includes a first part and a second part connected to the first part. The first part is fixedly connected to the board surface of the first extension part facing the first screen area, and the first part is fixedly connected to the lifting board. The second part is fixedly connected to the second board. In the thickness direction of the electronic device, the thickness of the first amplification board is greater than the thickness of the lifting board.

[00154] It can be understood that the first part and the second part are sequentially laid on the first extension part, the first part is fixedly connected to the lifting plate, and the second part is fixedly connected to the second board, thereby greatly improving the structural strength of the first board. Thus, when the first elastic member is in elastic contact with the antenna radiator, the first elastic member receives a counterforce of the antenna radiator. The first elastic part transmits a counter force to the first extension part of the first board. In this case, by interacting the first amplification board, the lifting board and the second board, the first extension portion can effectively resist said force, thereby preventing the first extension portion from being damaged or cracked due to the external force, and thereby avoiding disconnection of the antenna circuit.

[00155] In another possible implementation, the first reinforcing board is fixedly connected to the lifting board. In the thickness direction of the electronic device, the thickness of the first reinforcing board is less than or equal to the thickness of the lifting board.

[00156] It can be understood that the first reinforcing board is laid on the first extension portion, and the first reinforcing board is fixedly connected to the lifting board, thereby greatly increasing the structural strength of the first board. Thus, when the first elastic member is in elastic contact with the antenna radiator, the first elastic member receives a counterforce of the antenna radiator. The first elastic part transmits a counter force to the first extension part of the first board. In this case, by interacting the first reinforcing board and the lifting board, the first extension portion can effectively resist said force, thereby preventing the first extension portion from being damaged or cracked by the external force.

[00157] In accordance with the third aspect, or any of the implementations of the third aspect described above, the first part and the riser plate are of a single structure, and the second part and the second plate are of a single structure. In other words, the first part and the lifting board are a single board. In this case, the connection between the first part and the lifting plate is stronger. In this way, the first part and the lifting plate cannot be easily broken or cracked when exposed to external force. In addition, the second part and the second board are a single board. In this case, the connection between the second part and the second board is stronger. In this way, the second part and the second board cannot be easily broken or cracked when exposed to external force.

[00158] In another possible implementation, the first part may alternatively be fixedly connected to the riser board by a soldering process, the second part may alternatively be fixedly connected to the second board by a soldering process.

[00159] In accordance with the third aspect, or any of the implementations of the third aspect described above, the first portion is provided with a first solder reinforcement pad. The first extension part is provided with a second reinforcing solder pad. The first solder reinforcement pad is soldered to the second solder reinforcement pad.

[00160] It can be understood that when the first part and the first extension part are soldered to each other through the first solder reinforcement pad and the second solder reinforcement pad, the connection between the first part and the first extension part becomes stronger, and the overall strength of the printed circuit board assembly better. In addition, after the first strengthening solder pad and the second strengthening solder pad are soldered together, the first strengthening solder pad and the second strengthening solder pad can effectively protect the solder pad (the solder pad of this section is mainly intended for electrical connection between the wiring of the first board and the wiring of the riser board) between the first part of the main body of the first board and the riser board. That is, the solder pad between the first body body and the riser plate is prevented from being easily destroyed by external force.

[00161] According to the third aspect or any of the implementations of the third aspect described above, the distance between the first elastic member and the first part is from 0.15 mm to 30 mm. In this case, the size of the first extension portion located between the first elastic member and the first portion is relatively moderate. Thus, when the first elastic member is in elastic contact with the antenna emitter, the first elastic member receives the counter force of the emitter. The first elastic part transmits a counter force to the first extension part. In this case, the first extension portion located between the first elastic member and the first portion is not easily broken or cracked. In other words, the reaction force received by the first extension part can be quickly transmitted to the first part, thereby counteracting the reaction force due to the internal tension of the first part.

[00162] In accordance with the third aspect, or any of the implementations of the third aspect described above, the printed circuit board assembly further includes a second reinforcement board. The second reinforcing board is located on one side of the first elastic part at a distance from the first reinforcing board and is fixedly connected to the board surface of the first extension part facing the first screen area.

[00163] It can be understood that by laying the first reinforcing board on one side of the first elastic part and on the first extension part and laying the second reinforcing board on the other side of the first elastic part and on the first extension part, the thickness of the portion of the first extension part is significantly increased, which further significantly increases the structural strength of the first board. Thus, when the first elastic member is in elastic contact with the emitter, the first elastic member receives the counter force of the antenna emitter. The first elastic part transmits a counter force to the first extension part of the first board. In this case, by interacting the first amplification board and the second amplification board, the first extension portion can effectively resist said force, thereby avoiding damage or cracking of the first extension portion due to the external force, and thus avoiding disconnection of the antenna circuit.

[00164] According to the third aspect, or any of the implementations of the third aspect described above, the second amplification board includes a third portion and a fourth portion coupled to the third portion. The third part is fixedly connected to the board surface of the first extension part facing the first screen area, and the third part is fixedly connected to the lifting board. The fourth part is fixedly connected to the second board. In the thickness direction of the electronic device, the thickness of the second amplification board is greater than the thickness of the lifting board.

[00165] It can be understood that the third part and the fourth part connected to the third part are sequentially laid on the first extension part, the third part is fixedly connected to the lifting plate, and the fourth part is fixedly connected to the second board, thereby greatly increasing the structural strength of the first board . Thus, when the first elastic member is in elastic contact with the antenna radiator, the first elastic member receives a counterforce of the antenna radiator. The first elastic part transmits a counter force to the first extension part of the first board. In this case, by interacting the first amplification board, the second amplification board, the lifting board and the second board, the first extension portion can effectively resist said force, thereby preventing the first extension portion from being damaged or cracked due to external force, and thus avoiding disconnection of the antenna circuit .

[00166] In another possible implementation, the second reinforcing board is fixedly connected to the lifting board. In the thickness direction of the electronic device, the thickness of the second reinforcing board is less than or equal to the thickness of the lifting board.

[00167] According to the third aspect, or any of the implementations of the third aspect described above, the third part and the riser plate are a single structure. The fourth part and the second board have a single design. In other words, the third part and the lifting board are a single board. In this case, the connection between the third part and the lifting plate is stronger. Therefore, the third part and the lifting plate are not easy to break or crack when exposed to external force. In addition, the fourth part and the second board are a single board. In this case, the connection between the fourth part and the second board is stronger. Therefore, the fourth part and the second board are not easy to break or crack when exposed to external force.

[00168] In another possible implementation, the third part may alternatively be fixedly connected to the riser plate using a soldering process. Alternatively, the fourth part can be permanently connected to the second board using a soldering process.

[00169] According to the third aspect or any of the implementations of the third aspect described above, the distance d3 between the first elastic member and the third part is in the range of 0.15 mm to 30 mm.

[00170] In this case, the size of the first extension portion located between the first elastic member and the third portion is relatively moderate. Thus, when the first elastic member is in elastic contact with the antenna emitter, the first elastic member receives the counter force of the emitter. The first elastic part transmits a counter force to the first extension part. In this case, the first extension portion located between the first elastic member and the third portion is not easily broken or cracked. In other words, the reaction force received by the first extension part can be quickly transmitted to the third part, thereby counteracting the reaction force by the internal tension of the third part.

[00171] According to the third aspect, or any of the implementations of the third aspect described above, the conductive member is located on a surface of the emitter facing the first resilient member. The first elastic part is in elastic contact with the conductive part.

[00172] It can be understood that when the conductive piece is located on the emitter, the conductive piece can improve the flatness of the surface of the emitter. Thus, when the first elastic member is in elastic contact with the emitter through the conductive member, the elastic contact between the first elastic member and the emitter is more stable. Thus, the RF signals are also more stable during transmission between the emitter and the first resilient member, resulting in better performance of the antenna of the electronic device.

[00173] According to the third aspect, or any of the implementations of the third aspect described above, the oxidation resistance of the conductive part is better than that of the emitter. It can be understood that in an environment with the same temperature and humidity, the conductive part is not as easily oxidized compared to the emitter. Thus, compared with the solution in which the first elastic part directly comes into elastic contact with the emitter, the contact resistance between the first elastic part and the conductive part is smaller, that is, the contact resistance between the first elastic part and the conductive part is more stable, and the transmission loss There are fewer radio frequency signals. In this case, the antenna performance of the electronic device is better.

[00174] In accordance with the third aspect, or any of the implementations of the third aspect described above, the electronic device includes a mount. The emitter is equipped with a blind hole. The mount is attached in a blind hole. The first elastic part is in elastic contact with the fastener.

[00175] It can be understood that, compared to the solution of soldering the conductive part to the emitter, this implementation saves on the process of soldering the conductive part to the emitter by placing the fastener in the blind hole of the emitter and electrically connecting the first elastic part to the antenna emitter through the fastener. Therefore, on the one hand, the cost of the electronic device is reduced, and there is no need to further increase the cost of the soldering process; and, on the other hand, the case is excluded when the characteristics of the emitter when transmitting and receiving electromagnetic waves are affected by the formation of gas holes, slag inclusions, solder joints or cracks during the soldering process in the emitter.

[00176] In accordance with the third aspect, or any of the implementations of the third aspect described above, the emitter has an inner side surface facing the printed circuit board assembly. The first elastic part is in elastic contact with the inner side surface. Thus, the emitter may not have a protrusion for contacting the first elastic member, in which case, in the thickness direction of the electronic device, the protrusion-free space can also be used for the antenna clearance area. Thus, the antenna clearance area is larger and the antenna performance is better.

[00177] According to the third aspect, or any of the implementations of the third aspect described above, the first resilient member includes a first stationary member, an elastic member, and a second stationary member. The elastic element is connected between the first fixed part and the second fixed part. It will be understood that the elastic element may be, among other things, an elastic member or a spring. Additionally, the first stationary piece may be, among other things, a copper piece, an aluminum piece, or a gold piece. The second stationary part may be, among other things, a copper part, an aluminum part, or a gold part.

[00178] In addition, the first stationary piece is fixedly connected to the emitter. The second fixed part is fixedly connected to the first extension part of the first board.

[00179] It is understood that the first elastic part has a simple structure and is easy to assemble, which can reduce the complexity of assembling the electronic device.

[00180] In accordance with the third aspect, or any of the implementations of the third aspect described above, the electronic device further includes a middle plate. The middle plate is located on the inside of the frame. The middle plate is grounded. The frame further includes a connecting segment. One end of the connecting segment is connected to the emitter, and the other end is connected to the middle plate.

[00181] It can be understood that the emitter is grounded in a relatively simple manner and has a simple design and relatively low capital investment.

[00182] In accordance with the third aspect, or any of the implementations of the third aspect described above, the printed circuit board assembly further includes a second conductive element. The second conductive element may be, but is not limited to, an elastic member or a spring. The second conductive element is located on the first extension portion of the first board. The second conductive element is electrically connected between the ground plane of the first board and the emitter. In other words, the second conductive element is designed to ground the emitter.

[00183] It can be understood that the emitter is grounded in a relatively simple manner and has a simple design and relatively low capital investment.

[00184] In accordance with the third aspect, or any of the implementations of the third aspect described above, the first board is provided with a second matching network. The second matching network includes an inductor, capacitor, resistor, or antenna switch. The second elastic element is electrically connected to the second matching network and is electrically connected to the ground plane of the first board through the second matching network. The second matching circuit is configured to adjust the antenna frequency bands for receiving and transmitting electromagnetic waves and matching the antenna impedance. Thus, the antenna is more widely used for transmitting and receiving electromagnetic waves and has better performance.

[00185] In accordance with the third aspect, or any of the implementations of the third aspect described above, the electronic device further includes a middle plate. The middle plate is grounded. The middle plate is located on the inside of the frame. The printed circuit board assembly further includes a second conductive element and a third conductive element. The second conductive element is attached to the first extension portion of the first board. The second conductive element is in elastic contact with the emitter. The third conductive element is attached to the second board. The third conductive element is in elastic contact with the middle plate and is electrically connected to the second conductive element.

[00186] It can be understood that by placing a second conductive element on the first extension portion, placing a third conductive element on the second conductive element, and using the third conductive element for grounding, the grounding path of the emitter is enlarged. In this case, a matching circuit can be placed in the ground path of the emitter on the printed circuit board assembly to adjust the antenna frequency bands for receiving and transmitting electromagnetic waves so that the antenna frequency bands for receiving and transmitting are wider.

[00187] In accordance with the fourth aspect, an electronic device is provided. The electronic device may be a cell phone, watch, or other type of device capable of transmitting and receiving electromagnetic wave signals. The electronic device includes a frame, a screen, and a printed circuit board assembly.

[00188] The screen is mounted on the frame and is located around the frame. In an implementation, the screen includes a protective cover plate and a display screen. The protective cover plate is placed on the display screen. The display screen is located close to the PCB assembly relative to the protective cover plate. The protective cover plate can be mainly configured to protect the display screen and prevent dust from entering.

[00189] In addition, the screen includes a first screen area and a second screen area located opposite each other.

[00190] The frame portion forms an antenna emitter, or the antenna emitter is fixed to the inner side of the frame.

[00191] The printed circuit board assembly is located on the inside of the frame. The printed circuit board assembly includes a first board, a riser board, a second board, and a first conductive element. The first board and the riser board are located on one side of the second board away from the first screen area. In other words, the first board and the riser board are located at a distance from the first screen area relative to the second board. The first board includes a first main body portion and a first extension portion connected to the first main body portion. The lifting plate includes a second main body portion and a second extension portion connected to the second main body portion. The first main body part, the second main body part and the second board are stacked sequentially. In other words, the second main body part is located between the first main body part and the second board. The first extension part and the second extension part are stacked on top of each other, and the first extension part and the second extension part protrude relative to the second board and are located close to the emitter. The first conductive element is attached to the second extension part and is in elastic contact with the emitter.

[00192] The distance from the point of contact between the first conductive element and the emitter to the first screen area is the first distance. The distance from the point of contact between the first conductive element and the emitter to the second screen area is the second distance. The ratio of the first distance to the second distance is in the range from 0.5 to 2.

[00193] It should be noted that the first conductive element may be an elastic member having electrical conductivity, or alternatively may be a spring having electrical conductivity, which is not limited to this application. In each of the solutions that can be implemented below, the first conductive element is described using the example of a first elastic part.

[00194] It is understood that when the first elastic member is attached to the second board in the thickness direction of the electronic device, the distance between the first elastic member and the first screen area is relatively small, that is, the first elastic member is located close to the first shield area. In this implementation, by fixedly connecting the first elastic part to the second extension part, and when the ratio of the first distance to the second distance is in the range of 0.5 to 2, in the thickness direction of the electronic device, the distance between the first elastic part and the first screen area is increased more degrees. Thus, in the thickness direction of the electronic device, the antenna clearance area between the first elastic member and the first screen area can be increased to a greater extent, and the performance of the antenna can be further improved. In addition, when the ratio of the first distance to the second distance is from 0.5 to 2, the distance from the contact point between the first conductive element and the emitter to the second shield area is relatively small, and in this case, the second shield area has less influence on the antenna's performance. reception and transmission of electromagnetic waves.

[00195] In addition, by bringing the first elastic member into elastic contact with the emitter, more stable transmission of radio frequency signals between the first elastic member and the emitter is provided. In particular, since the first elastic member has an elastic force, the first elastic member can always be in contact with the emitter when the first elastic member is in elastic contact with the emitter, so that the connection stability between the first elastic member and the emitter is better.

[00196] In an exemplary implementation according to the fourth aspect, the electronic device further includes a radio frequency path. The radio frequency path may be configured to transmit radio frequency signals to an antenna radiator such that the antenna radiator transmits electromagnetic wave signals in accordance with the radio frequency signals. In addition, when the antenna radiator converts the received electromagnetic wave signals into radio frequency signals, the radio frequency path may be further configured to receive the radio frequency signals transmitted by the antenna radiator. In this case, the first elastic part is electrically connected between the radio frequency path and the emitter.

[00197] In another possible implementation, the first resilient member is electrically connected between the emitter and the ground plane of the second extension portion.

[00198] In another possible embodiment, the first elastic member is electrically connected to the ground plane of the second extension part through a matching circuit.

[00199] In accordance with the fourth aspect or any implementation of the fourth aspect described above, the first elastic member is attached to one side of the second extension portion facing the first screen area. In this case, the first elastic member and the second plate are located on the same side of the lifting plate. In the thickness direction of the electronic device, there is an overlap region between the first elastic member and the second board. The first elastic part uses the space of the second board facing one side of the emitter. Thus, in the thickness direction of the electronic device, the circuit board assembly is not thickened due to the configuration of the first elastic member.

[00200] In addition, the space between the surface of the second extension portion facing the first screen area and the emitter is generally small. Conventional chips or electronic components are not easily placed in this area. In this case, the space is not used, which easily leads to wastage of space. In this embodiment, a first elastic member of relatively small size is secured to the side of the second extension portion facing the first screen area. On the one hand, the space of this part can be effectively used to improve the utilization of the internal space of an electronic device. On the other hand, compared with the case in which the first elastic member is located on one side of the first board facing the rear cover, in this embodiment, the space between the first board and the rear cover can save the space occupied by the at least one first elastic member. In this case, the saved space can be used to package more electronic components, thereby greatly improving the utilization of PCB assembly space.

[00201] According to the fourth aspect or any implementation of the fourth aspect described above, the distance L from the point of contact between the first elastic member and the emitter to the first screen area is greater than or equal to 2 mm. For example, L is equal to 2 mm, 2.5 mm, 3 mm, 3.5 mm or 4 mm.

[00202] It is understood that when the distance L from the point of contact between the first elastic member and the emitter to the first screen region is greater than or equal to 2 mm, the first elastic member may be located further away from the first screen region. In this way, the antenna clearance area between the first elastic member and the first shield area can be significantly increased, and the antenna performance can also be improved.

[00203] According to the fourth aspect or any implementation of the fourth aspect described above, the distance L from the point of contact between the first elastic member and the emitter to the first screen area is less than or equal to 4.7 mm.

[00204] It is understood that when the distance L from the contact point between the first elastic part and the emitter to the first screen area is less than or equal to 4.7 mm, on the one hand, it can be ensured that the first elastic part is located at a distance from the first screen area; and on the other hand, it can be ensured that the thickness of the electronic device in the Z direction is small, which is conducive to thinning the configuration.

[00205] According to the fourth aspect or any implementation of the fourth aspect described above, the distance between the first elastic member and the second board is from 0.15 mm to 30 mm.

[00206] It can be understood that when the distance between the first elastic piece and the second board is from 0.15 mm to 30 mm, the size of the second extension portion located between the first elastic piece and the second board is relatively moderate. Thus, when the first elastic member is in elastic contact with the emitter, the first elastic member receives the counter force of the emitter. The first elastic part transmits the counter force to the second extension part. In this case, the second extension portion located between the first elastic member and the second board is not easily broken or cracked. In other words, the reaction force received by the second extension portion can be quickly transmitted to the second board, thereby counteracting the reaction force by the internal voltage of the second board.

[00207] In accordance with the fourth aspect, or any implementation of the fourth aspect described above, the printed circuit board assembly further includes a third reinforcement board. The third reinforcing board is located on one side of the first elastic part and is fixedly connected to the surface of the board of the second extension part facing the first screen area.

[00208] It can be understood that by laying the third reinforcing board on one side of the first elastic member and on the second extension portion, the thickness of the portion of the second extension portion is greatly increased, which further greatly improves the structural strength of the riser board. Thus, when the first elastic member is in elastic contact with the emitter, the first elastic member receives the counter force of the antenna emitter. The first elastic part transmits the counter force to the second extension part of the lifting plate. In this case, by interacting with the third amplification board, the second extension portion can effectively resist said force, thereby avoiding damage or cracking of the second extension portion due to external force and thus avoiding disconnection of the antenna circuit.

[00209] In accordance with the fourth aspect or any implementation of the fourth aspect described above, the third amplification board and the second board are of one piece construction. In other words, the third amplification board and the second board are a single board. In this case, the strength of the single structure of the third reinforcing board and the second board is higher. In this way, the third reinforcing board and the second board cannot be easily broken or cracked when subjected to external force.

[00210] In another possible implementation, the third amplification board may be connected to the second board using a soldering process, or the third amplification board may be located separately from the second board.

[00211] According to the fourth aspect or any implementation of the fourth aspect described above, the distance between the first elastic member and the third reinforcing board is from 0.15 mm to 30 mm. In this case, the size of the second extension portion located between the first elastic member and the third reinforcing board is relatively moderate. Thus, when the first elastic member is in elastic contact with the antenna emitter, the first elastic member receives the counter force of the emitter. The first elastic part transmits the counter force to the second extension part. In this case, the second extension portion located between the first elastic member and the third reinforcing board is not easily broken or cracked. In other words, the reaction force received by the first extension portion can be quickly transmitted to the third enhancement board, thereby counteracting the reaction force by the internal tension of the third enhancement board.

[00212] In accordance with the fourth aspect, or any implementation of the fourth aspect described above, the printed circuit board assembly further includes a fourth reinforcement board. The fourth reinforcing board is located on one side of the first elastic part at a distance from the third reinforcing board and is fixedly connected to the surface of the second extension part facing the first area of the flat screen.

[00213] It can be understood that by laying the fourth reinforcing board on one side of the first elastic part and on the second extension part, the thickness of the part of the second extension part is significantly increased, which further greatly improves the structural strength of the lifting board. Thus, when the first elastic member is in elastic contact with the emitter, the first elastic member receives the counter force of the antenna emitter. The first elastic part transmits the counter force to the second extension part of the lifting plate. In this case, by interacting with the fourth amplification board, the second extension portion can effectively resist the force, thereby avoiding the second extension portion being damaged or cracked due to external force and thus preventing the antenna circuit from being disconnected.

[00214] In accordance with the fourth aspect or any implementation of the fourth aspect described above, the fourth amplification board and the second board are of one piece construction. In other words, the fourth amplification board and the second board are a solid board. In this case, the integral structural strength of the fourth reinforcing board and the second board is higher. In this way, the fourth reinforcing board and the second board cannot be easily broken or cracked when subjected to external force.

[00215] In another possible implementation, the fourth enhancement board may be connected to the second board through a soldering process, or the fourth enhancement board may be located separately from the second board.

[00216] According to the fourth aspect or any implementation of the fourth aspect described above, the distance between the first elastic member and the fourth reinforcing board is from 0.15 mm to 30 mm. In this case, the size of the second extension portion located between the first elastic member and the fourth reinforcing board is relatively moderate. Thus, when the first elastic member is in elastic contact with the antenna emitter, the first elastic member receives the counter force of the emitter. The first elastic part transmits the counter force to the second extension part. In this case, the second extension portion located between the first elastic member and the fourth reinforcing board is not easily broken or cracked. In other words, the reaction force received by the second extension portion can be quickly transmitted to the fourth enhancement board. Therefore, the reaction force counteracts the internal voltage of the fourth amplification board.

[00217] According to the fourth aspect, or any implementation of the fourth aspect described above, the surface of the emitter facing the first resilient member is provided with a conductive member. The first elastic part is in elastic contact with the conductive part.

[00218] It can be understood that when the conductive part is located on the emitter, the conductive part can improve the flatness of the surface of the emitter. Thus, when the first elastic member is in elastic contact with the emitter through the conductive member, the elastic contact between the first elastic member and the emitter is more stable. Thus, the RF signals are also more stable during transmission between the emitter and the first resilient member, resulting in better performance of the antenna of the electronic device.

[00219] According to the fourth aspect, or any implementation of the fourth aspect described above, the oxidation resistance of the conductive part is higher than that of the emitter. It can be understood that in an environment with the same temperature and humidity, the conductive part is not as easily oxidized compared to the emitter. Thus, compared with the solution in which the first elastic part directly comes into elastic contact with the emitter, the contact resistance between the first elastic part and the conductive part is smaller, that is, the contact resistance between the first elastic part and the conductive part is more stable, and the transmission loss There are fewer radio frequency signals. In this case, the antenna performance of the electronic device is better.

[00220] In accordance with the fourth aspect, or any implementation of the fourth aspect described above, the electronic device includes a mount. The emitter is equipped with a blind hole. The mount is fixed in a blind hole. The first elastic part is in elastic contact with the fastener.

[00221] It can be understood that, compared to the solution of soldering the conductive part to the emitter, this implementation saves on the process of soldering the conductive part to the emitter by placing the fastener in the blind hole of the emitter and electrically connecting the first elastic part to the antenna emitter through the fastener. Therefore, on the one hand, the cost of the electronic device is reduced, and there is no need to further increase the cost of the soldering process; and, on the other hand, the case is excluded when the characteristics of the emitter when transmitting and receiving electromagnetic waves are affected by the formation of gas holes, slag inclusions, solder joints or cracks during the soldering process in the emitter.

[00222] In accordance with the fourth aspect, or any implementation of the fourth aspect described above, the emitter includes an inner side surface facing a printed circuit board assembly. The first elastic part is in elastic contact with the inner side surface. Thus, the emitter may not have a protrusion for contacting the first elastic member, in which case, in the thickness direction of the electronic device, the protrusion-free space can also be used for the antenna clearance area. Thus, the antenna clearance area is larger and the antenna performance is better.

[00223] According to the fourth aspect, or any implementation of the fourth aspect described above, the first resilient member includes a first stationary member, an elastic member, and a second stationary member. The elastic element is connected between the first fixed part and the second fixed part. It will be understood that the elastic element may be, among other things, an elastic member or a spring. Additionally, the first stationary piece may be, among other things, a copper piece, an aluminum piece, or a gold piece. The second stationary part may be, among other things, a copper part, an aluminum part, or a gold part.

[00224] In addition, the first stationary piece is fixedly connected to the emitter. The second fixed part is fixedly connected to the second extension part of the lifting plate.

[00225] It is understood that the first elastic part has a simple structure and is easy to assemble, which can reduce the complexity of assembling the electronic device.

[00226] In accordance with the fourth aspect or any implementation of the fourth aspect described above, the electronic device further includes a middle plate. The middle plate is located on the inside of the frame. The middle plate is grounded. The frame further includes a connecting segment. One end of the connecting segment is connected to the emitter, and the other end is connected to the middle plate.

[00227] It can be understood that the emitter is grounded in a relatively simple manner and has a simple design and relatively low capital investment.

[00228] In accordance with the fourth aspect, or any implementation of the fourth aspect described above, the printed circuit board assembly further includes a second conductive element. The second conductive element may be, but is not limited to, an elastic member or a spring. The second conductive element is located on the second extension portion of the lifting plate. The second conductive element is electrically connected between the ground plane of the riser plate and the emitter. In other words, the second conductive element is configured to ground the emitter.

[00229] It can be understood that the emitter is grounded in a relatively simple manner and has a simple design and relatively low capital investment.

[00230] In accordance with the fourth aspect, or any implementation of the fourth aspect described above, the first board is provided with a second matching network. The second matching network includes an inductor, capacitor, resistor, or antenna switch. The second resilient member is electrically coupled to the second matching circuit and is electrically coupled to the riser board ground plane via the second matching circuit. The second matching circuit is configured to adjust the antenna frequency bands for receiving and transmitting electromagnetic waves and matching the antenna impedance. Thus, the antenna is more widely used for transmitting and receiving electromagnetic waves and has better performance.

[00231] In accordance with the fourth aspect or any implementation of the fourth aspect described above, the electronic device further includes a middle plate. The middle plate is grounded. The middle plate is located on the inside of the frame. The printed circuit board assembly further includes a second conductive element and a third conductive element. The second conductive element is attached to the second extension portion of the lifting plate. The second conductive element is in elastic contact with the emitter. The third conductive element is attached to the second board. The third conductive element is in elastic contact with the middle plate and is electrically connected to the second conductive element.

[00232] It can be understood that by placing a second conductive element on the second extension portion, placing a third conductive element on the second conductive element, and using the third conductive element for grounding, the grounding path of the emitter is enlarged. In this case, a matching circuit can be placed in the radiator ground path on the printed circuit board to adjust the antenna frequency bands for receiving and transmitting electromagnetic waves so that the antenna frequency bands for receiving and transmitting are wider.

[00233] In a fifth aspect, antenna equipment is provided. Antenna equipment can transmit and receive electromagnetic wave signals. The antenna equipment includes a radiator and a printed circuit board assembly.

[00234] The printed circuit board assembly is located on the inside of the frame. The printed circuit board assembly includes a first conductive member and a first board, a riser board, and a second board stacked in series. In other words, the lifting board is located between the first board and the second board. The first board includes a first main body portion and a first extension portion connected to the first main body portion. The first part of the main body is fixedly connected to the lifting plate. The first extension portion projects relative to the riser plate and the second board and is located close to the emitter. The first conductive element is attached to the first extension part, and the first conductive element, the lifting panel and the second board are located on one side of the first board. The first conductive element is in elastic contact with the emitter.

[00235] It should be noted that the first conductive element may be an elastic member having electrical conductivity, or alternatively may be a spring having electrical conductivity, which is not limited to this application. In each of the solutions that can be implemented below, the first conductive element is described using the example of a first elastic part.

[00236] In this implementation, by placing a first extension portion that projects relative to the lifting plate and the second plate, and immovably connecting the first elastic member to the first extension portion and the first elastic member, the lifting plate and the second charger are located on the same side of the first board, in in the thickness direction of the printed circuit board assembly, there is an overlap region between the first elastic member and the lifting board. The first elastic part uses the space of the lift plate facing the side of the emitter. Thus, in the thickness direction of the antenna device, the circuit board assembly is not thickened due to the configuration of the first elastic member.

[00237] In addition, compared to the solution of attaching the first resilient member to the second board, in this embodiment, by attaching the first resilient member to the first extension portion, there are no longer antenna-related components or wiring (e.g., antennas, switches, inductors, capacitors or resistors) located on the riser board and the second board. Thus, on the one hand, the design of PCB assembly is simplified, that is, the complexity of PCB assembly is reduced, and the cost of PCB assembly is lower; on the other hand, more space can be freed up on the second board to accommodate more electronic components.

[00238] In addition, by bringing the first resilient member into elastic contact with the emitter, more stable transmission of RF signals is provided between the first resilient member and the emitter. In particular, since the first elastic member has an elastic force, the first elastic member can always be in contact with the emitter when the first elastic member is in elastic contact with the emitter, so that the connection stability between the first elastic member and the emitter is better.

[00239] In addition, the space between the emitter and the surface of the first extension portion facing the emitter is generally small. Conventional chips or electronic components are not easily placed in this area. In this case, the space is not used, which easily leads to wastage of space. In this embodiment, by securing a first elastic member of a relatively small size to one side of the first extension portion facing the radiator, the space of that portion can be effectively utilized to improve the utilization of the internal space of the antenna equipment.

[00240] In addition, by stacking the first board, the riser board, and the second board in series, the board area of the circuit board assembly can be significantly increased, thereby increasing the number of electronic components placed on the circuit board assembly. In particular, when the first board and the second board are lifted by the lifting board, on the circuit board assembly, electronic components (such as a CPU, a battery management chip, etc.) can be arranged not only on the surface of the first board facing away from the second board, and surfaces of the second board facing away from the first board, but may also be arranged in the space between the first board and the second board (on the surface of the first board facing the second board and the surface of the second board facing the first board). In other words, more electronic components can be arranged on the PCB assembly of this implementation.

[00241] In an exemplary implementation according to the fifth aspect, the antenna apparatus further includes a radio frequency path. The radio frequency path may be configured to transmit radio frequency signals to an antenna radiator such that the antenna radiator transmits electromagnetic wave signals in accordance with the radio frequency signals. In addition, when the antenna radiator converts the received electromagnetic wave signals into radio frequency signals, the radio frequency path may be further configured to receive the radio frequency signals transmitted by the antenna radiator. In this case, the first elastic part is electrically connected between the radio frequency path and the emitter.

[00242] In another possible implementation, the first resilient member is electrically coupled between the emitter and the ground plane of the first extension portion.

[00243] In another possible implementation, the first elastic member is electrically connected to the ground plane of the first extension part through a matching network.

[00244] According to the fifth aspect or any implementation of the fifth aspect described above, the distance between the first elastic member and the lifting plate is from 0.15 mm to 30 mm.

[00245] It can be understood that when the distance between the first elastic member and the lifting plate is from 0.15 mm to 30 mm, the size of the first extension portion located between the first elastic member and the lifting plate is relatively moderate. Thus, when the first elastic member is in elastic contact with the emitter, the first elastic member receives the counter force of the emitter. The first elastic part transmits a counter force to the first extension part. In this case, the first extension portion located between the first elastic member and the lifting plate is not easily broken or cracked. In other words, the counter force received by the first extension part can be quickly transmitted to the lifting plate, thereby counteracting the counter force by the internal tension of the lifting plate.

[00246] In accordance with the fifth aspect or any implementation of the fifth aspect described above, the printed circuit board assembly further includes a first reinforcement board. The first reinforcing board is located on one side of the first elastic part and is fixedly connected to the board surface of the first extension part facing the second board.

[00247] It can be understood that by laying the first reinforcing board on one side of the first elastic member and on the first extension portion, the thickness of the portions of the first extension portion is significantly increased, which further significantly improves the structural strength of the first board. Thus, when the first elastic member is in elastic contact with the emitter, the first elastic member receives the counter force of the antenna emitter. The first elastic part transmits a counter force to the first extension part of the first board. In this case, when interacting with the first amplification board, the first extension portion can effectively resist the force, thereby avoiding damage or cracking of the first extension portion due to external force and thus avoiding disconnection of the antenna circuit.

[00248] According to the fifth aspect or any implementation of the fifth aspect described above, the first amplification board includes a first portion and a second portion coupled to the first portion. The first part is fixedly connected to the board surface of the first extension part facing the second board, and the first part is fixedly connected to the lifting board. The second part is fixedly connected to the second board. In the thickness direction of the antenna equipment, the thickness of the first gain board is greater than the thickness of the lifting board.

[00249] It can be understood that the first part and the second part are sequentially laid on the first extension part, the first part is fixedly connected to the lifting plate, and the second part is fixedly connected to the second board, thereby greatly improving the structural strength of the first board. Thus, when the first elastic member is in elastic contact with the antenna radiator, the first elastic member receives a counterforce of the antenna radiator. The first elastic part transmits a counter force to the first extension part of the first board. In this case, by interacting the first amplification board, the lifting board and the second board, the first extension portion can effectively resist the force, thereby preventing the first extension portion from being damaged or cracked due to external force, and thereby avoiding disconnection of the antenna circuit.

[00250] In another possible embodiment, the first reinforcing board is fixedly connected to the lifting board. In the direction of the thickness of the antenna equipment, the thickness of the first amplification board is less than or equal to the thickness of the lifting board.

[00251] It can be understood that the first reinforcing board is laid on the first extension portion, and the first reinforcing board is fixedly connected to the lifting board, thereby greatly increasing the structural strength of the first board. Thus, when the first elastic member is in elastic contact with the antenna radiator, the first elastic member receives a counterforce of the antenna radiator. The first elastic part transmits a counter force to the first extension part of the first board. In this case, by interacting the first reinforcing board and the lifting board, the first extension portion can effectively resist said force, thereby preventing the first extension portion from being damaged or cracked by the external force.

[00252] According to the fifth aspect or any implementation of the fifth aspect described above, the first part and the riser board are of a single structure, and the second part and the second board are of a single structure. In other words, the first part and the lifting plate are a single board. In this case, the connection between the first part and the lifting plate is stronger. In this way, the first part and the lifting plate cannot be easily broken or cracked when exposed to external force. In addition, the second part and the second board are a single board. In this case, the connection between the second part and the second board is stronger. In this way, the second part and the second board cannot be easily broken or cracked when exposed to external force.

[00253] In another possible embodiment, the first part can be fixedly connected to the riser plate using a soldering process. alternatively, the second part can be permanently connected to the second board using a soldering process.

[00254] In accordance with the fifth aspect or any implementation of the fifth aspect described above, the first part is provided with a first solder reinforcement pad. The first extension part is provided with a second reinforcing solder pad. The first solder reinforcement pad is soldered to the second solder reinforcement pad.

[00255] It can be understood that when the first part and the first extension part are soldered to each other through the first solder reinforcement pad and the second solder reinforcement pad, the connection between the first part and the first extension part becomes stronger, and the strength of the circuit board assembly structure better. In addition, after the first strengthening solder pad and the second strengthening solder pad are soldered together, the first strengthening solder pad and the second strengthening solder pad can effectively protect the solder pad (the solder pad of this section is mainly intended for electrical connection between the wiring of the first board and the wiring of the riser board) between the first part of the main body of the first board and the riser board. That is, the solder pad between the first body body and the riser plate is prevented from being easily destroyed by external force.

[00256] According to the fifth aspect or any implementation of the fifth aspect described above, the distance between the first elastic member and the first part is in the range of 0.15 mm to 30 mm. In this case, the size of the first extension portion located between the first elastic member and the first portion is relatively moderate. Thus, when the first elastic member is in elastic contact with the antenna emitter, the first elastic member receives the counter force of the emitter. The first elastic part transmits a counter force to the first extension part. In this case, the first extension portion located between the first elastic member and the first portion is not easily broken or cracked. In other words, the reaction force received by the first extension part can be quickly transmitted to the first part, thereby counteracting the reaction force due to the internal tension of the first part.

[00257] In accordance with the fifth aspect or any implementation of the fifth aspect described above, the printed circuit board assembly further includes a second reinforcement board. The second reinforcing board is located on one side of the first elastic part at a distance from the first reinforcing board and is fixedly connected to the board surface of the first extension part facing the second board.

[00258] It can be understood that by laying the first reinforcing board on one side of the first elastic part and on the first extension part and laying the second reinforcing board on the other side of the first elastic part and on the first extension part, the thickness of the portion of the first extension part is significantly increased, which further significantly increases the structural strength of the first board. Thus, when the first elastic member is in elastic contact with the emitter, the first elastic member receives the counter force of the antenna emitter. The first elastic part transmits a counter force to the first extension part of the first board. In this case, by interacting the first amplification board and the second amplification board, the first extension portion can effectively resist said force, thereby avoiding damage or cracking of the first extension portion due to the external force and thus avoiding disconnection of the antenna circuit.

[00259] According to the fifth aspect or any implementation of the fifth aspect described above, the second amplification board includes a third portion and a fourth portion coupled to the third portion. The third part is fixedly connected to the board surface of the first extension part facing the second board, and the third part is fixedly connected to the lifting board. The fourth part is fixedly connected to the second board. In the direction of the thickness of the antenna equipment, the thickness of the second amplification board is greater than the thickness of the lifting board.

[00260] It can be understood that the third part and the fourth part connected to the third part are sequentially laid on the first extension part, the third part is fixedly connected to the lifting plate, and the fourth part is fixedly connected to the second board, thereby greatly increasing the structural strength of the first board . Thus, when the first elastic member is in elastic contact with the antenna radiator, the first elastic member receives a counterforce of the antenna radiator. The first elastic part transmits a counter force to the first extension part of the first board. In this case, by interacting the first amplification board, the second amplification board, the lifting board and the second board, the first extension portion can effectively resist said force, thereby preventing the first extension portion from being damaged or cracked due to external force, and thus avoiding disconnection of the antenna circuit .

[00261] In another possible embodiment, the second reinforcing board is fixedly connected to the lifting board. In the direction of the thickness of the antenna equipment, the thickness of the second amplification board is less than or equal to the thickness of the lifting board.

[00262] According to the fifth aspect or any implementation of the fifth aspect described above, the third part and the riser plate are a single structure. The fourth part and the second board are one-piece. In other words, the third part and the lifting board are a single board. In this case, the connection between the third part and the lifting plate is stronger. Therefore, the third part and the lifting plate are not easy to break or crack when exposed to external force. In addition, the fourth part and the second board are a single board. In this case, the connection between the fourth part and the second board is stronger. Therefore, the fourth part and the second board are not easy to break or crack when exposed to external force.

[00263] In another possible embodiment, the third part can be fixedly connected to the riser plate using a soldering process. Alternatively, the fourth part can be permanently connected to the second board using a soldering process.

[00264] According to the fifth aspect or any implementation of the fifth aspect described above, the distance d3 between the first elastic member and the third part is in the range of 0.15 mm to 30 mm.

[00265] In this case, the size of the first extension portion located between the first elastic member and the third portion is relatively moderate. Thus, when the first elastic member is in elastic contact with the antenna emitter, the first elastic member receives the counter force of the emitter. The first elastic part transmits a counter force to the first extension part. In this case, the first extension portion located between the first elastic member and the third portion is not easily broken or cracked. In other words, the reaction force received by the first extension part can be quickly transmitted to the third part, thereby counteracting the reaction force by the internal tension of the third part.

[00266] According to the fifth aspect or any implementation of the fifth aspect described above, the first extension portion is provided with a groove. The groove is located between the first amplification board and the second amplification board, and the opening of the groove is located on a surface of the first extension portion facing the emitter. Part of the first elastic part is mounted in the groove.

[00267] It can be understood that when the first elastic piece portion is mounted in the groove in the thickness direction of the printed circuit board assembly, there is an overlap region between the first elastic piece and the first extension portion. In this case there is also an overlap region between the first elastic part and the first board. Thus, in the direction of the thickness of the antenna equipment, the circuit board assembly is not thickened due to the configuration of the first elastic part.

[00268] In addition, when the first extension portion is provided with a first reinforcing board and a second reinforcing board, the first reinforcing board and the second reinforcing board can increase the strength of the first extension portion, thereby avoiding a decrease in the strength of the first extension portion due to the groove hole.

[00269] According to the fifth aspect or any implementation of the fifth aspect described above, the surface of the emitter facing the first elastic member is provided with a conductive member. The first elastic part is in elastic contact with the conductive part.

[00270] It can be understood that when the conductive part is located on the emitter, the conductive part can improve the flatness of the surface of the emitter. Thus, when the first elastic member is in elastic contact with the emitter through the conductive member, the elastic contact between the first elastic member and the emitter is more stable. In this way, RF signals are also transmitted relatively stably between the emitter and the first resilient member, thereby ensuring that the antenna equipment has better antenna performance.

[00271] According to the fifth aspect or any implementation of the fifth aspect described above, the oxidation resistance of the conductive part is higher than that of the emitter. It can be understood that in an environment with the same temperature and humidity, the conductive part is not as easily oxidized compared to the emitter. Thus, compared with the solution in which the first elastic part directly comes into elastic contact with the emitter, the contact resistance between the first elastic part and the conductive part is smaller, that is, the contact resistance between the first elastic part and the conductive part is more stable, and the transmission loss There are fewer radio frequency signals. In this case, the antenna characteristics of the antenna equipment are better.

[00272] In accordance with the fifth aspect, or any implementation of the fifth aspect described above, the antenna apparatus includes a mount. The emitter is equipped with a blind hole. The mount is attached in a blind hole. The first elastic part is in elastic contact with the fastener.

[00273] It can be understood that, compared to the solution of soldering the conductive part to the emitter, this embodiment saves the process of soldering the conductive part to the emitter by placing the fastener in the blind hole of the emitter and electrically connecting the first elastic part. piece to the antenna emitter through the mount. Consequently, on the one hand, the costs of antenna equipment are reduced, and there is no need to increase the costs of the soldering process. and on the other hand, the case is excluded when the characteristics of the emitter when transmitting and receiving electromagnetic waves are affected by the formation of gas holes, slag inclusions, solder joints or cracks during the soldering process in the emitter.

[00274] In accordance with the fifth aspect, or any implementation of the fifth aspect described above, the emitter includes an inner side surface facing a printed circuit board assembly. The first elastic part is in elastic contact with the inner side surface. Thus, the emitter can be in contact with the first elastic member without a protrusion. In this case, in the direction of the thickness of the antenna equipment, the space without the protrusion can be used as the antenna clearance area. Thus, the antenna clearance area is larger and the antenna performance is better. In addition, the antenna radiator also has a relatively simple structure and is easy to mass produce.

[00275] According to the fifth aspect or any implementation of the fifth aspect described above, the first resilient member includes a first stationary member, an elastic member, and a second stationary member. The elastic element is connected between the first fixed part and the second fixed part. It will be understood that the elastic element may be, but is not limited to, an elastic member or a spring. Additionally, the first stationary piece may be, but is not limited to, a copper piece, an aluminum piece, or a gold piece. The second stationary piece may be, but is not limited to, a copper piece, an aluminum piece, or a gold piece.

[00276] In addition, the first stationary piece is fixedly connected to the emitter. The second fixed part is fixedly connected to the first extension part of the first board.

[00277] It is understood that the first elastic part has a simple structure and is easy to assemble, which can reduce the complexity of assembling the antenna equipment.

[00278] In accordance with the fifth aspect or any implementation of the fifth aspect described above, the printed circuit board assembly further includes a second conductive element. The second conductive element may be, but is not limited to, an elastic member or a spring. The second conductive element is located on the first extension portion of the first board. The second conductive element is electrically connected between the ground plane of the first board and the emitter. In other words, the second conductive element is designed to ground the emitter.

[00279] It can be understood that the emitter in this implementation is grounded in a relatively simple manner and has a simple structure and low capital investment.

[00280] In accordance with the fifth aspect or any implementation of the fifth aspect described above, the first board is provided with a second matching network. The second matching network includes an inductor, capacitor, resistor, or antenna switch. The second resilient member is electrically coupled to the second matching network and is electrically coupled to the ground plane of the first board through the second matching network. The second matching circuit is configured to adjust the antenna frequency bands for receiving and transmitting electromagnetic waves and matching the antenna impedance. Thus, the antenna is more widely used for transmitting and receiving electromagnetic waves and has better performance.

[00281] In a sixth aspect, antenna apparatus is provided. Antenna equipment can transmit and receive electromagnetic wave signals. The antenna equipment includes a radiator and a printed circuit board assembly.

[00282] The printed circuit board assembly is located on the inside of the frame. The printed circuit board assembly includes a first board, a riser board, a second board, and a first conductive element. The first board includes a first main body portion and a first extension portion connected to the first main body portion. The lifting plate includes a second main body portion and a second extension portion connected to the second main body portion. The first main body part, the second main body part and the second board are stacked sequentially. In other words, the second main body part is located between the first main body part and the second board. The first extension part and the second extension part are stacked on top of each other, and the first extension part and the second extension part protrude relative to the second board and are located close to the emitter. The first conductive element is attached to the second elongated portion, and the first conductive element and the second board are located on one side of the lifting board. The second conductive element is in elastic contact with the emitter.

[00283] It should be noted that the first conductive element may be an elastic member having electrical conductivity, or alternatively may be a spring having electrical conductivity, which is not limited to this in this application. In each of the solutions that can be implemented below, the first conductive element is described using the example of a first elastic part.

[00284] In this implementation, by arranging a second extension portion that projects relative to the second board, and statically connecting the first elastic portion to the second extension portion, and placing the first conductive member and the second board on one side of the riser board in the thickness direction of the printed circuit board assembly , there is an overlap region between the first elastic member and the second board. The first elastic part uses the space of the second board facing one side of the emitter. Thus, in the direction of the thickness of the antenna equipment, the circuit board assembly is not thickened due to the configuration of the first elastic part.

[00285] In addition, by stacking the second extension portion on the first extension portion and, in this case, by interacting the second extension portion and the first extension portion, the overall strength of that portion can be increased. Thus, when the first elastic member is in elastic contact with the antenna emitter, the first elastic member receives the counter force of the emitter. The first elastic part transmits the counter force to the second extension part. In this case, by interacting the first extension portion, the second extension portion can effectively counteract said force, thereby avoiding damage or cracking of the second extension portion due to the external force, and thus avoiding disconnection of the antenna circuit.

[00286] In addition, by bringing the first resilient member into elastic contact with the emitter, more stable transmission of RF signals is provided between the first resilient member and the emitter. In particular, since the first elastic member has an elastic force, the first elastic member can always be in contact with the emitter when the first elastic member is in elastic contact with the emitter, so that the connection stability between the first elastic member and the emitter is better.

[00287] In addition, the space between the surface of the second extension portion facing the emitter and the emitter is generally small. Conventional chips or electronic components are not easily placed in this area. In this case, the space is not used, which easily leads to wastage of space. In this embodiment, by securing a first elastic member of relatively small size to one side of the second extension portion facing the radiator, the space of that portion can be effectively utilized to improve the utilization of the internal space of the antenna equipment.

[00288] In an exemplary implementation according to the sixth aspect, the antenna apparatus further includes a radio frequency path. The radio frequency path may be configured to transmit radio frequency signals to an antenna radiator such that the antenna radiator transmits electromagnetic wave signals in accordance with the radio frequency signals. In addition, when the antenna radiator converts the received electromagnetic wave signals into radio frequency signals, the radio frequency path may be further configured to receive the radio frequency signals transmitted by the antenna radiator. In this case, the first elastic part is electrically connected between the radio frequency path and the emitter.

[00289] In another possible implementation, the first resilient member is electrically connected between the emitter and the ground plane of the second extension portion.

[00290] In another possible embodiment, the first elastic member is electrically connected to the ground plane of the second extension part through a matching circuit.

[00291] According to the sixth aspect or any implementation of the sixth aspect described above, the distance between the first elastic member and the second board is from 0.15 mm to 30 mm.

[00292] It can be understood that when the distance between the first elastic piece and the second plate is from 0.15 mm to 30 mm, the size of the second extension portion located between the first elastic piece and the second plate is relatively moderate. Thus, when the first elastic member is in elastic contact with the emitter, the first elastic member receives the counter force of the emitter. The first elastic part transmits the counter force to the second extension part. In this case, the second extension portion located between the first elastic member and the second board is not easily broken or cracked. In other words, the reaction force received by the second extension portion can be quickly transmitted to the second board, thereby counteracting the reaction force by the internal voltage of the second board.

[00293] In accordance with the sixth aspect or any implementation of the sixth aspect described above, the printed circuit board assembly further includes a third reinforcing board. The third reinforcing board is located on one side of the first elastic part and is fixedly connected to the surface of the second extension part facing the second board.

[00294] It can be understood that by laying the third reinforcing board on one side of the first elastic member and on the second extension portion, the thickness of the portion of the second extension portion is greatly increased, which further greatly improves the structural strength of the riser board. Thus, when the first elastic member is in elastic contact with the emitter, the first elastic member receives the counter force of the antenna emitter. The first elastic part transmits the counter force to the second extension part of the lifting plate. In this case, by interacting with the third reinforcing plate, the second extension portion can effectively resist the force, thereby avoiding damage or cracking of the second extension portion due to external force and thus avoiding the antenna circuit being opened.

[00295] In accordance with the sixth aspect or any implementation of the sixth aspect described above, the third amplification board and the second board are of one piece construction. In other words, the third amplification board and the second board are a single board. In this case, the strength of the integral structure of the third reinforcing board and the second board is higher. In this way, the third reinforcing board and the second board cannot be easily broken or cracked when subjected to external force.

[00296] In another possible implementation, the third amplification board may be connected to the second board using a soldering process, or the third amplification board may be located separately from the second board.

[00297] According to the sixth aspect or any implementation of the sixth aspect described above, the distance between the first elastic member and the third reinforcing board is from 0.15 mm to 30 mm. In this case, the size of the second extension portion located between the first elastic member and the third reinforcing board is relatively moderate. Thus, when the first elastic member is in elastic contact with the antenna emitter, the first elastic member receives the counter force of the emitter. The first elastic part transmits the counter force to the second extension part. In this case, the second extension portion located between the first elastic member and the third reinforcing board is not easily broken or cracked. In other words, the reaction force received by the first extension portion can be quickly transmitted to the third enhancement board, thereby counteracting the reaction force by the internal voltage of the third enhancement board.

[00298] In accordance with the sixth aspect or any implementation of the sixth aspect described above, the printed circuit board assembly further includes a fourth reinforcement board. The fourth reinforcing board is located on one side of the first elastic part at a distance from the third reinforcing board and is fixedly connected to the surface of the second extension part facing the second board.

[00299] It can be understood that by laying the fourth reinforcing board on one side of the first elastic piece and on the second extension portion, the thickness of the portion of the second extension portion is significantly increased, which further greatly improves the structural strength of the riser board. Thus, when the first elastic member is in elastic contact with the emitter, the first elastic member receives the counter force of the antenna emitter. The first elastic part transmits the counter force to the second extension part of the lifting plate. In this case, by interacting with the fourth amplification board, the second extension portion can effectively resist said force, thereby avoiding the second extension portion being damaged or cracked due to external force and thus preventing the antenna circuit from being disconnected.

[00300] In accordance with the sixth aspect or any implementation of the sixth aspect described above, the fourth amplification board and the second board are of one piece construction. In other words, the fourth amplification board and the second board are a solid board. In this case, the strength of the integral structure of the fourth reinforcing board and the second board is higher. In this way, the fourth reinforcing board and the second board cannot be easily broken or cracked when subjected to external force.

[00301] In another possible implementation, the fourth amplification board may be connected to the second board using a soldering process, or the fourth amplification board may be located separately from the second board.

[00302] According to the sixth aspect or any implementation of the sixth aspect described above, the distance between the first elastic member and the fourth reinforcing board is from 0.15 mm to 30 mm. In this case, the size of the second extension portion located between the first elastic member and the fourth reinforcing board is relatively moderate. Thus, when the first elastic member is in elastic contact with the antenna emitter, the first elastic member receives the counter force of the emitter. The first elastic part transmits the counter force to the second extension part. In this case, the second extension portion located between the first elastic member and the fourth reinforcing board is not easily broken or cracked. In other words, the reaction force received by the second extension portion can be quickly transmitted to the fourth enhancement board. Therefore, the reaction force counteracts the internal voltage of the fourth amplification board.

[00303] According to the sixth aspect or any implementation of the sixth aspect described above, the second extension portion is provided with a groove, the groove is located between the third enhancement board and the fourth enhancement board, the opening of the groove is located on a surface of the second extension portion facing the emitter, and a portion of the first elastic part is mounted in the groove.

[00304] It can be understood that when the first elastic piece portion is mounted in the groove, in the thickness direction of the printed circuit board assembly, there is an overlap region between the first elastic piece and the second extension portion. In this case there is also an overlap region between the first elastic part and the first board. Thus, in the direction of the thickness of the antenna equipment, the circuit board assembly is not thickened due to the configuration of the first elastic part.

[00305] In addition, when the second extension portion is provided with a first reinforcing board and a second reinforcing board, the first reinforcing board and the second reinforcing board can increase the strength of the second extension portion, thereby preventing the strength of the second extension portion from being reduced due to the groove hole.

[00306] According to the sixth aspect or any implementation of the sixth aspect described above, the surface of the emitter facing the first resilient member is provided with a conductive member. The first elastic part is in elastic contact with the conductive part.

[00307] It can be understood that when the conductive part is located on the emitter, the conductive part can improve the flatness of the surface of the emitter. Thus, when the first elastic member is in elastic contact with the emitter through the conductive member, the elastic contact between the first elastic member and the emitter is more stable. In this way, RF signals are also transmitted relatively stably between the emitter and the first resilient member, thereby ensuring that the antenna equipment has better antenna performance.

[00308] According to the sixth aspect or any implementation of the sixth aspect described above, the oxidation resistance of the conductive part is higher than that of the emitter. It can be understood that in an environment with the same temperature and humidity, the conductive part is not as easily oxidized compared to the emitter. Thus, compared with the solution in which the first elastic part directly comes into elastic contact with the emitter, the contact resistance between the first elastic part and the conductive part is smaller, that is, the contact resistance between the first elastic part and the conductive part is more stable, and the transmission loss There are fewer radio frequency signals. In this case, the antenna characteristics of the antenna equipment are better.

[00309] In accordance with the sixth aspect, or any implementation of the sixth aspect described above, the antenna apparatus includes a mount. The emitter is equipped with a blind hole. The mount is attached in a blind hole. The first elastic part is in elastic contact with the fastener.

[00310] It can be understood that, compared to the solution of soldering the conductive part to the emitter, this embodiment saves on the process of soldering the conductive part to the emitter by placing a fastener in the blind hole of the emitter and electrically connecting the first elastic part to the antenna emitter through the fastener . Consequently, on the one hand, the costs of antenna equipment are reduced, and there is no need to increase the costs of the soldering process, and on the other hand, the case is excluded when the characteristics of the emitter when transmitting and receiving electromagnetic waves are affected by the formation of gas holes, slag inclusions, solder joints or cracks during soldering in the emitter.

[00311] According to the sixth aspect, or any implementation of the sixth aspect described above, the emitter includes an inner side surface facing a printed circuit board assembly. The first elastic part is in elastic contact with the inner side surface. Thus, the emitter can be in contact with the first elastic member without a protrusion. In this case, in the thickness direction of the printed circuit board assembly, the space not having a protrusion can also be used as an antenna clearance area. Thus, the antenna clearance area is larger and the antenna performance is better.

[00312] According to the sixth aspect or any implementation of the sixth aspect described above, the first resilient member includes a first stationary member, an elastic member, and a second stationary member. The elastic element is connected between the first fixed part and the second fixed part. It will be understood that the elastic element may be, without limitation, an elastic member or a spring. Moreover, the first stationary piece may be, without limitation, a copper piece, an aluminum piece, or a gold piece. The second stationary piece may be, among other things, a copper piece, an aluminum piece, or a gold piece.

[00313] In addition, the first stationary piece is fixedly connected to the emitter. The second fixed part is fixedly connected to the second extension part of the lifting plate.

[00314] It is understood that the first elastic part has a simple structure and is easy to assemble, which can reduce the complexity of assembling the antenna equipment.

[00315] In accordance with the sixth aspect or any implementation of the sixth aspect described above, the printed circuit board assembly further includes a second conductive element. The second conductive element may be, but is not limited to, an elastic member or a spring. The second conductive element is located on the second extension portion of the lifting plate. The second conductive element is electrically connected between the ground plane of the riser plate and the emitter. In other words, the second conductive element is designed to ground the emitter.

[00316] It can be understood that the emitter in this implementation is grounded in a relatively simple manner and has a simple structure and low capital investment.

[00317] In accordance with the sixth aspect or any implementation of the sixth aspect described above, the first board is provided with a second matching network. The second matching network includes an inductor, capacitor, resistor, or antenna switch. The second resilient member is electrically coupled to the second matching circuit and is electrically coupled to the riser board ground plane via the second matching circuit. The second matching circuit is configured to adjust the antenna frequency bands for receiving and transmitting electromagnetic waves and matching the antenna impedance. Thus, the antenna is more widely used for transmitting and receiving electromagnetic waves and has better performance.

BRIEF DESCRIPTION OF THE DRAWINGS

[00318] FIG. 1 is a schematic structural view of an electronic device optionally provided by an embodiment of this application;

[00319] FIG. 2 is a schematic exploded view of the electronic device shown in FIG. 1;

[00320] FIG. 3 is a partial sectional view of the electronic device shown in FIG. 1, optionally along line A-A;

[00321] FIG. 4 is a partial section through the electronic device shown in FIG. 1 in another optional way along the line A-A;

[00322] FIG. 5 is a partial sectional view of the electronic device shown in FIG. 1, optionally along the B-B line;

[00323] FIG. 6 is a partial schematic structural view of a printed circuit board assembly of the electronic device shown in FIG. 1 optional;

[00324] FIG. 7 is a schematic exploded view of the printed circuit board assembly shown in FIG. 6;

[00325] FIG. 8a is a partial schematic structural view of the circuit board assembly of the electronic device shown in FIG. 1 in another optional way;

[00326] FIG. 8b is a partial section through the electronic device shown in FIG. 1 in another optional way along the B-B line;

[00327] FIG. 9 is a partial schematic structural view of a printed circuit board assembly of the electronic device shown in FIG. 1, in another optional way;

[00328] FIG. 10 is a schematic sectional view of the printed circuit board assembly shown in FIG. 6, along the line C-C;

[00329] FIG. 11 is a partial schematic structural view of the printed circuit board assembly shown in FIG. 6, from another angle;

[00330] FIG. 12 is a partial sectional view of the electronic device shown in FIG. 1, in another optional way, taken along the line B-B;

[00331] FIG. 13a is a partial schematic structural view of the circuit board assembly of the electronic device shown in FIG. 1, in another optional way;

[00332] FIG. 13b is a partial schematic structural view of the circuit board assembly of the electronic device shown in FIG. 1, in another optional way;

[00333] FIG. 14 is a partial schematic structural view of the circuit board assembly of the electronic device shown in FIG. 1, in another optional way;

[00334] FIG. 15 is a partial schematic structural view of the circuit board assembly of the electronic device shown in FIG. 1, in another optional way;

[00335] FIG. 16 is a partial schematic structural view of the circuit board assembly of the electronic device shown in FIG. 1, in another optional way;

[00336] FIG. 17 is a partial schematic structural view of the circuit board assembly of the electronic device shown in FIG. 1, in another optional way;

[00337] FIG. 18 is a partial sectional view of the electronic device shown in FIG. 1, in another optional way, taken along the line B-B;

[00338] FIG. 19 is a partial sectional view of the electronic device shown in FIG. 1, in another optional way, taken along the line B-B;

[00339] FIG. 20a is a partial section through the electronic device shown in FIG. 1, in another optional way, taken along the line B-B;

[00340] FIG. 20b is a partial sectional view of the electronic device shown in FIG. 1, in another optional way, taken along the line B-B;

[00341] FIG. 21 is a partial sectional view of the electronic device shown in FIG. 1, in another optional way, taken along the line BB;

[00342] FIG. 22 is a partial sectional view of the electronic device shown in FIG. 1, in another optional manner along line A-A;

[00343] FIG. 23 is a partial sectional view of the electronic device shown in FIG. 22, along line D-D;

[00344] FIG. 24 is a partial schematic structural view of the circuit board assembly of the electronic device shown in FIG. 1, in another optional manner;

[00345] FIG. 25 is a partial sectional view of the electronic device shown in FIG. 1, optionally along line E-E;

[00346] FIG. 26 is a partial sectional view of the electronic device shown in FIG. 1, in another optional manner along line E-E;

[00347] FIG. 27 is a partial sectional view of the electronic device shown in FIG. 1, made in another optional manner along the line AA;

[00348] FIG. 28 is a partial sectional view of the electronic device shown in FIG. 1, in another optional way, taken along the line A-A;

[00349] FIG. 29 is a partial sectional view of the electronic device shown in FIG. 1, in another optional way, taken along the line BB;

[00350] FIG. 30 is a partial schematic structural view of the circuit board assembly of the electronic device shown in FIG. 1, in another optional manner;

[00351] FIG. 31 is a schematic exploded view of the printed circuit board assembly shown in FIG. thirty;

[00352] FIG. 32 is a partial sectional view of the electronic device shown in FIG. 1, in another optional way, taken along the line B-B;

[00353] FIG. 33 is a partial schematic structural view of the printed circuit board assembly shown in FIG. 30 from a different angle;

[00354] FIG. 34 is a partial sectional view of the electronic device shown in FIG. 1, in another optional manner along line B-B;

[00355] FIG. 35 is a partial schematic structural view of the circuit board assembly of the electronic device shown in FIG. 1, in another optional manner;

[00356] FIG. 36 is a partial schematic structural view of the circuit board assembly of the electronic device shown in FIG. 1, in another optional manner;

[00357] FIG. 37 is a schematic structural view of an electronic device in another optional manner provided by an embodiment of this application;

[00358] FIG. 38 is a partial cross-section of the electronic device shown in FIG. 37, optionally along line F-F;

[00359] FIG. 39 is a schematic structural view of an electronic device in another optional manner provided by an embodiment of this application; And

[00360] FIG. 40 is a partial sectional view of the electronic device shown in FIG. 39, optionally along the line G-G;

Description of Embodiments

[00361] FIG. 1 is a schematic structural view of an optional electronic device provided by an embodiment of this application. The electronic device 100 may be a mobile phone, a watch, a tablet personal computer, a laptop computer, a personal digital assistant (PDA), a personal computer, a laptop, an in-vehicle device, a wearable device, or an AR glasses. augmented reality (AR), AR helmet, virtual reality (VR) glasses, VR headset, or other device capable of transmitting and receiving electromagnetic wave signals in other forms. The electronic device 100 of some embodiment shown in FIG. 1 is described using a mobile phone as an example. For convenience of description, the width direction of the electronic device 100 is defined as the X-axis. The length direction of the electronic device 100 is the Y-axis. The thickness direction of the electronic device 100 is the Z-axis.

[00362] This application below mainly describes the structures of three electronic devices 100. One of them is the electronic device 100 in which the screen is a flat screen. The other is an electronic device 100 in which the screen is a curved screen. Another example is an electronic device in which the screen is a 360° curved screen. First, the electronic device 100 in which the screen is a flat screen according to the first embodiment will be described in detail below with reference to the corresponding accompanying drawings.

[00363] First Embodiment: With reference to FIG. 1, fig. 2 is a schematic exploded view of the electronic device shown in FIG. 1. The electronic device 100 includes a screen 10, a housing 20, and a circuit board assembly 30. It can be understood that in FIG. 1 and fig. 2 merely schematically illustrates some of the components included in the electronic device 100, and the actual shapes, actual dimensions, and actual construction of these components are not limited to FIG. 1 and fig. 2.

[00364] Screen 10 may be configured to display images, text, or the like. The screen 10 is a flat screen. In addition, the screen 10 includes a protective cover plate 11 and a display screen 12. The protective cover plate 11 is placed on the display screen 12. The protective cover plate 11 may be positioned close to the display screen 12 and may be generally configured to protect the display screen 12 and prevent dust from entering. The material of the protective cover plate 11 may be, but is not limited to, glass. The display screen 12 may be an organic light-emitting diode (OLED) display screen, an active-matrix organic light-emitting diode (AMOLED) display screen, a quantum dot light-emitting diode (QD) display screen ( quantum dot light emitting diodes, QLED), etc.

[00365] The housing 20 may be configured to support a screen 10. The housing 20 includes a frame 21 and a back cover 22. The back cover 22 is positioned opposite the screen 10. The back cover 22 and the screen 10 are mounted on opposite sides of the frame 21, respectively. In this case, the back cover 22, frame 21, and screen 10 together form the interior of the electronic device 100. The interior of the electronic device 100 may be used to house components of the electronic device 100 such as a battery, a receiver, a microphone, and the like.

[00366] Optionally, the back cover 22 is fixedly connected to the frame 21 using adhesive. In another optional embodiment, the back cover 22 and the frame 21 form a one-piece structure, that is, the back cover 22 and the frame 21 are of one piece construction.

[00367] In addition, housing 20 may further be used as part of an antenna radiator, or the interior of housing 20 may be used to attach an antenna radiator.

[00368] It will be appreciated that electronic device 100 may use an antenna and communicate with a network or other device through one or more of the following communication technologies. Communication technologies include Bluetooth (BT) communication technology, Global Positioning System (GPS) communication technology, Wireless Fidelity (Wi-Fi) communication technology, global system for mobile communication technology communications, GSM), wideband code division multiple access (WCDMA), long term evolution (LTE), 5G communications technology, SUB-6G communications technology, another future communications technology or the like.

[00369] Additionally, electronic device 100 may share mobile data traffic or a wireless network shared with other devices (eg, cell phones, watches, tablet computers, or other devices capable of transmitting and receiving electromagnetic wave signals) via an antenna. For example, when other devices operate a data sharing network, the electronic device 100 can access the other devices' data sharing network by receiving antenna signals from the other devices. Thus, the electronic device 100 does not affect the user experience of the electronic device 100 because its traffic is insufficient or has ceased to be used.

[00370] The antenna emitter is configured to transmit and receive electromagnetic wave signals. There are many methods for configuring an antenna's radiator. Two optional methods are described in detail below with reference to the corresponding accompanying drawings.

[00371] First optional method: FIG. 3 is a partial cross-sectional view of the electronic device shown in FIG. 1 optionally along line AA. It can be understood that the cross-sectional view shown in FIG. 3 is a cross-sectional view of the electronic device of FIG. 1 taken along line AA and viewed in the negative Z-axis direction. The frame 21 of the housing 20 is made of a metallic material, for example steel. In this case, a metal segment is isolated on the frame 21, which forms the antenna radiator 41. Specifically, the frame 21 includes a first short frame 212 and a first long frame 213 connected to the first short frame 212. The first short frame 212 includes a first gap 214. The first long frame 213 includes a second gap 215. Thus, an independent metal segment is isolated on the frame 21 by a first gap 214 and a second gap 215, forming an antenna radiator 41.

[00372] In this implementation, the housing 20 further includes a middle plate 24. The middle plate 24 is made of a metallic material, such as steel. The middle plate 24 is connected to the inner surface of the frame 21. Between a portion of the middle plate 24, the first short frame 212 and the first long frame 213, there is a third gap 216. The third gap 216 communicates with the first gap 214 and the second gap 215. Thus, the first gap 214, the second gap 215 and the third gap 216 may define an antenna clearance area. In another optional method, housing 20 may alternatively not include a middle plate 24.

[00373] Additionally, first gap 214, second gap 215, and third gap 216 may alternatively be filled with insulating materials. For example, insulating materials can be polymers, glass, ceramics, etc. or a combination of these materials. In another optional method, the first gap 214, second gap 215, and third gap 216 may be hollow, that is, the first gap 214, second gap 215, and third gap 216 are not filled with other materials.

[00374] It can be understood that the position of the antenna radiator 41 is not limited to the position shown in FIG. 3. For example, an independent metal segment is isolated on the first short frame 212 to form an antenna radiator 41. Alternatively, an independent metal segment is isolated on the first long frame 213 to form the antenna radiator 41. Of course, the antenna emitter 41 may alternatively be provided in another portion of the frame 21. The details are not limited to this embodiment.

[00375] Second optional method: FIG. 4 is a partial cross-sectional view of the electronic device shown in FIG. 1 in another optional way along the line A-A. It can be understood that the cross-sectional view shown in FIG. 4 is a cross-sectional view of the electronic device of FIG. 1 taken along the line AA and viewed in the negative direction of the Z axis. The frame 21 of the housing 20 is made of an insulating material. For example, the insulating material may be polymer, glass, or a combination of these materials. In this case, a conductive conductor is formed on the inner surface of the frame 21 by laser directstructuring (LDS) or direct printing technique. The conductive conductor may be made of, but is not limited to, copper, gold, or graphene. The conductive conductor forms the radiator 41 of the antenna. It will be understood that the position of the emitter 41 is not limited to the inner surfaces of the first short frame 212 and the first long frame 213 shown in FIG. 4. For example, the emitter 41 may be located on the inner surface of the first short frame 212. Alternatively, the emitter 41 may be located on the inner surface of the first long frame 213 or on the inner surface of another portion of the frame 21.

[00376] In addition, the housing 20 further includes a middle plate 24. The middle plate 24 is made of a metallic material, such as steel. The middle plate 24 is connected to the inner surface of the frame 21. There is a fourth gap 217 between a portion of the middle plate 24, the first short frame 212 and the first long frame 213. Thus, the fourth gap 217 can form an antenna gap. In another optional method, housing 20 may alternatively not include a middle plate 24.

[00377] It is understood that the antenna radiator 41 may alternatively be implemented by another method. For example, a flexible printed circuit board is fixedly connected to the inner surface of the frame 21. The flexible printed circuit board forms an antenna radiator 41. The configuration method of the antenna radiator 41 will not be described again here. In the following embodiments, the design of the antenna radiator 41 is described using the first optional method as an example.

[00378] FIG. 5 is a partial cross-sectional view of the electronic device shown in FIG. 1, optionally along the B-B line; It can be understood that the cross-sectional view shown in FIG. 5 is a cross-sectional view formed by taking a cross-section of the electronic device shown in FIG. 1 along line B-B, and viewing along the positive Y-axis direction, and then rotating the resulting cross-section 180° with the Y-axis as the axis of rotation. The circuit board assembly 30 is located within the electronic device 100. The circuit board assembly 30 may be secured to the middle plate 24 with screws, pins, or rivets for stability. The printed circuit board assembly 30 may be configured to accommodate an RF antenna path 42 . The radio frequency path 42 may be configured to transmit radio frequency signals to the antenna radiator 41, such that the antenna radiator 41 transmits electromagnetic wave signals in accordance with the radio frequency signals. In addition, when the antenna radiator 41 converts the received electromagnetic wave signals into radio frequency signals, the radio frequency path 42 may be further configured to receive the radio frequency signals transmitted by the antenna radiator 41.

[00379] The RF path 42 includes an RF transceiver chip 421 and a first matching network 422. It can be understood that in FIG. 3 according to FIG. 5 schematically shows the RF transceiver chip 421 and the first matching network 422. However, the actual shapes, actual dimensions, and actual structures of the RF transceiver chip 421 and the first matching network 422 are not limited to FIG. 3 - fig. 5.

[00380] The RF transceiver chip 421 is configured to transmit RF signals to the antenna emitter 41 and is further configured to receive RF signals transmitted by the antenna emitter 41 . It can be understood that when the functions of transmitting and receiving RF signals are integrated into an independent module (RF transceiver chip 421), the RF transceiver chip 421 can operate independently to transmit and receive RF signals. In this case, the transmission efficiency and processing efficiency of RF signals are greatly improved.

[00381] In another optional method, the RF signal transmitting and receiving functions may alternatively be integrated into a central processing unit (CPU) of the electronic device 100 or another chip in the electronic device 100, such as a battery control chip. In this case, since the CPU or other chip of the electronic device 100 also has functions of transmitting and receiving RF signals, the space occupied by one chip (RF transceiver chip 421) can be saved inside the electronic device 100, thereby improving the utilization of the internal space of the electronic device 100 .

[00382] The first matching network 422 is electrically connected between the RF transceiver chip 421 and the emitter 41. In other words, RF signals transmitted by the RF transceiver chip 421 can be transmitted to the emitter 41 through the first matching network 422. In addition, after the emitter 41 converts received electromagnetic wave signals into RF signals, the RF signals may be further transmitted to the RF transceiver chip 421 via a first matching circuit 422. The first matching network 422 may be electrically coupled to the RF transceiver chip 421 via wiring in the circuit board assembly 30. The first matching network 422 may be configured to perform signal processing such as signal amplification, filtering, and the like. radio frequency signals. The first matching network 422 may include electronic components such as antenna switches, capacitors, inductors, or resistors.

[00383] It can be understood that the general structure of the electronic device 100 and the general structure of the antenna in the electronic device 100 have been described in detail above with reference to the corresponding accompanying drawings. To provide the user with a more convenient visual experience, the electronic device 100 may adopt a full-screen industry design (industry design, ID). Full screen means a huge screen-to-body ratio (usually above 90%). In this case, the width of the frame 21 of the electronic device 100 is significantly reduced, and internal components such as a battery, receiver, microphone, antenna, and the like. electronic device 100 must be re-arranged. In particular, for the antenna design, when the width of the frame 21 of the electronic device 100 is greatly reduced, the antenna clearance area is also greatly reduced. Antenna size, bandwidth, and efficiency are interrelated and influence each other. In addition, if the size (space) of the antenna is reduced, the product of the antenna's efficiency and bandwidth will necessarily decrease. However, in this embodiment, under dense antenna packaging conditions, the circuit board assembly structure 30 is laid out and the corresponding antenna components are rearranged so that the antenna has a wider clearance area, thereby significantly improving the antenna performance of the electronic device 100.

[00384] FIG. 6 is a partial schematic structural view of the circuit board assembly of the electronic device shown in FIG. 1 optional. Fig. 7 is a schematic exploded view of the printed circuit board assembly shown in FIG. 6. The circuit board assembly 30 includes a first board 31, a riser board 32, a second board 33, and a first conductive member 34. It can be understood that in order to be able to clearly see a portion of the detailed structure of the circuit board assembly 30, FIG. 6 and Fig. 7 simply schematically illustrates a partial structural view of the printed circuit board assembly 30. In the additional techniques below, the accompanying drawings of additional embodiments also schematically illustrate a partial structural view of the printed circuit board assembly 30. The details are not described below. Moreover, the first conductive element 34 may be an electrically conductive elastic member or an electrically conductive spring, which is not limited to in this application. In the following embodiments, the first conductive element 34 is described using the example of the first elastic member 34.

[00385] The first board 31, the lifting board 32 and the second board 33 are stacked on top of each other in series. In other words, the lifting board 32 is fixed between the first board 31 and the second board 33. In FIG. 6 shows that the first board 31, riser board 32, and second board 33 are stacked sequentially along the Z-axis direction. In another optional method, when the electronic device 100 has other shapes, the first board 31, riser board 32, and second board 33 may alternatively be sequentially stacked and positioned along the X-axis, Y-axis, or other direction.

[00386] Optionally, the first board 31 and the riser board 32 may be attached to each other using a soldering process. Optionally, the first board 31 and the riser board 32 may be connected and attached to each other with conductive adhesive.

[00387] If desired, the second board 33 and the riser board 32 can be attached to each other using a soldering process. Optionally, the second board 33 and the riser board 32 may be connected and attached to each other with conductive adhesive.

[00388] In this embodiment, with reference to FIG. 5, by sequentially stacking the first board 31, the riser board 32, and the second board 33 in the Z-axis direction, the surface area of the circuit board 30 can be significantly increased, thereby increasing the number of electronic components placed on the circuit board assembly 30. Particularly when the first board 31 and the second board 33 are lifted in the Z-axis direction by the lifting board 32, on the printed circuit board assembly 30, electronic components (eg, CPU, battery management chip, etc.) can be arranged not only on the surface of the first board 31 facing back cover 22, and on the surface of the second board 33 facing the display screen 12, but may also be arranged in the space between the first board 31 and the second board 33 (on the surface of the first board 31 facing the second board 33, and the surface of the second board 33 , facing the first board 31). In other words, more electronic components can be arranged on the circuit board assembly 30 of this embodiment. Thus, on the one hand, the electronic device 100 has more and more functions, and the user experience is also improved. On the other hand, when the internal environment of the electronic device 100 is cramped, by arranging a large number of electronic components of the electronic device 100 on the circuit board assembly 30, more space inside the electronic device 10 can be freed up. When this space portion is applied to the antenna clearance area, the antenna clearance area can be significantly increased, thereby significantly improving the antenna's performance.

[00389] It can be understood that in FIG. 5 and fig. 6 shows that the lift plate 32 and the second plate 33 are flush with each other. In another optional arrangement, the riser plate 32 and the second plate 33 may alternatively be staggered. In particular, FIG. 8a is a partial schematic structural view of the circuit board assembly of the electronic device shown in FIG. 1 by another optional method. The portion of the riser plate 32 is staggered with the second plate 33, that is, a portion of the riser plate 32 protrudes relative to the second plate 33. In this case, the riser plate 32 and the second plate 33 form a stepped shape. It can be understood that in FIG. 8a shows that a portion of the riser board 32 extends along the X-axis direction relative to the second board 33. In another optional method, a portion of the riser board 32 may alternatively extend along the Y-axis direction relative to the second board 33.

[00390] Additionally, with reference to FIG. 5, the first board 31 is located at a distance from the display screen 12 relative to the second board 33, that is, the first board 31 is located on one side of the second board 33 at a distance from the display screen 12. In this case, the first board 31 is located close to the back cover 22. The second board 33 is located close to the display screen 12.

[00391] The first board 31, the riser board 32, and the second board 33 may be rigid boards, flexible boards, or boards combining soft and rigid characteristics. In addition, the first board 31, the riser board 32, and the second board 33 may be FR-4 dielectric boards, Rogers dielectric boards, mixed Rogers and FR-4 boards, and the like. FR-4 is the code name of the brand of refractory material, and Rogers dielectric board is a high frequency board.

[00392] In addition, the RF transceiver chip 421 and the first matching circuit 422 are located on the first board 31. It can be understood that the first board 31 is located further from the display screen 12 relative to the second board 33. Thus, compared with the placement solution of the RF chip 421 transceiver and first matching circuit 422 on the second board 33, in this embodiment, both the RF transceiver chip 421 and the first matching circuit 422 are located on the first board 31 such that the distance from the RF transceiver chip 421 and the first matching circuit 422 to the display screen 12 more. Thus, the internal circuit of the display screen 12 has less influence on the RF transceiver chip 421 and the first matching circuit 422, that is, the antenna performance is improved.

[00393] In addition, it should be noted that the positions of the RF transceiver chip 421 and the first matching network 422 are not limited to the surface of the first board 31 facing the back cover 22 shown in FIG. 5. For example, the RF transceiver chip 421 and the first matching network 422 may alternatively be located within the first board 31.

[00394] In another optional method, the RF transceiver chip 421 and the first matching network 422 may alternatively be located on the riser board 32 or on the second board 33.

[00395] FIG. 8b is a partial cross-sectional view of the electronic device shown in FIG. 1 in another optional way along the B-B line. It can be understood that the schematic cross-sectional view shown in FIG. 8b is a cross-sectional view along line B-B of the electronic device of FIG. 1, and when viewed in the positive Y-axis direction, and the cross-sectional view is rotated 180° with the Y-axis as the rotation axis to form the cross-sectional view shown in FIG. 8b. The first elastic part 34 is fixed on the surface of the second board 33 facing the screen 10. The first elastic part 34 is in elastic contact with the antenna radiator 41. In this implementation, the emitter 41 includes a protrusion 411 facing the interior of the electronic device 100. In this case, the first elastic member 34 is in elastic contact with the protrusion 411. In addition, the first elastic member 34 is electrically coupled between the first matching circuit 422 and the emitter 41. In this case, the point of contact between the first elastic member 34 and the emitter 41 is the power supply point. Thus, RF signals transmitted by the RF transceiver chip 421 can be transmitted to the emitter 41 through the first matching network 422 and the first elastic member 34. Moreover, after the emitter 41 converts the received electromagnetic wave signals into RF signals, the RF signals can be are further transmitted to the RF transceiver chip 421 via the first elastic member 34 and the first matching circuit 422.

[00396] Disadvantages of the solution shown in FIG. 8b are as follows:

[00397] 1. The first elastic member 34 is located close to the display screen 12, that is, in the Z-axis direction, the distance between the first elastic member 34 and the display screen 12 is relatively close. In this case, in the Z-axis direction, the protrusion 411 configured to contact the first elastic member 34 may alternatively be located closer to the display screen 12 to a greater extent. Thus, the antenna clearance area between the bottom of the protrusion 411 and the display screen 12 is compressed to a large extent. Thus, the display screen 12 can very easily interfere with the emitter 41 for transmitting and receiving electromagnetic wave signals, and the performance of the antenna will be poor.

[00398] 2. When both the first elastic member 34 and the projection 411 are located close to the display screen 12, the contact point of the first elastic member 34 in contact with the projection 411 is also located close to the display screen 12. Thus, the contact point (power supply point) of the first elastic member 34 in contact with the protrusion 411 is extremely easily affected by the display screen 12.

[00399] 3. When the first elastic member 34 is fixed on the surface of the second board 33 facing the screen 10 in the Z-axis direction, the thickness of the printed circuit board assembly 30 includes the thickness of the first elastic member 34. In this case, the thickness of the printed circuit board assembly 30 relative to great. When the circuit board assembly 30 is applied to the electronic device 100, the thickness of the electronic device 100 is also extremely easy to increase, which is not conducive to thinning the structure.

[00400] 4. The RF transceiver chip 421 and the first matching circuit 422 are located on the third board 33. The RF transceiver chip 421 and the first matching circuit 422 are located adjacent to the display screen 12 and are easily affected by the display screen 12.

[00401] In this embodiment, by arranging the structure of the circuit board assembly 30 and rearranging the corresponding antenna components, the antenna has a wider clearance area, thereby greatly improving the antenna performance of the electronic device 100. Details are described as follows:

[00402] Next, with reference to FIG. 5 and fig. 6, the first board 31 includes a first main body portion 311 and a first extension portion 312. The first main body portion 311, the riser board 32, and the second board 33 are sequentially stacked along the Z-axis direction. The first extension portion 312 projects relative to the riser board 32. and the second board 33. In FIG. 5 shows that the first extension portion 312 projects along the X-axis direction relative to the riser plate 32 and the second board 33. The first extension portion 312 is located close to the emitter 41 relative to the first main body portion 311. In another optional method, the first extension portion 312 may alternatively protrude in another direction, such as the Y-axis direction, relative to the riser plate 32 and the second plate 33, which is not limited herein.

[00403] In addition, the first elastic member 34 is attached to the first extension portion 312. Specifically, the first elastic member 34 is attached to one side of the first extension portion 312 facing the display screen 12. In this case, the first elastic piece 34, the lifting plate 32 and the second plate 33 are located on one side of the first board 31. In addition, the first elastic piece 34 is in elastic contact with the antenna radiator 41. In this implementation, the emitter 41 includes a projection 411 facing the interior of the electronic device 100. In this case, the first elastic member 34 is in elastic contact with the projection 411. It can be understood that the thickness of the projection 411 in the Z-axis direction in this optional method can be accordingly reduced according to actual needs, thereby avoiding the reduction of the clearance area between the projection 411 and the display screen 12 due to the relatively large size of the projection 411. In another optional method, the emitter 41 may not have the projection 411. In particular, the details are described below according to the respective the accompanying drawing (Fig. 20a), which are not described again here. Additionally, in another embodiment, the first resilient member 34 may alternatively be located on one side of the first board 31 facing the back cover 22.

[00404] In addition, optionally, by deoxidizing the surface of the protrusion 411 in contact with the first elastic member 34 using laser forming technology, it can be ensured that the position in which the protrusion 411 is in contact with the first elastic member 34 has a better stability of the electrical connection.

[00405] In addition, the first resilient member 34 is electrically coupled between the first matching circuit 422 of the radio frequency path 42 and the emitter 41. In this case, the point of contact between the first elastic member 34 and the emitter 41 is the power supply point. Thus, RF signals transmitted by the RF transceiver chip 421 can be transmitted to the emitter 41 through the first matching network 422 and the first elastic member 34. Moreover, after the emitter 41 converts the received electromagnetic wave signals into RF signals, the RF signals can be further transmitted to the RF transceiver chip 421 via the first resilient member 34 and the first matching network 422. In another optional embodiment, the position at which the first resilient member 34 is in contact with the radiator 41 may alternatively be a tuning point for the antenna on the ground. Details are described below that are not described again here.

[00406] In this embodiment, by positioning the first extension portion 312 that projects relative to the riser plate 32 and the second plate 33, and the first resilient member 34 being fixedly coupled to the first extension portion 312, the first elastic member 34 is positioned away from the display screen 12, that is, in the Z-axis direction, the distance between the first elastic member 34 and the display screen 12 becomes larger. In this case, in the Z-axis direction, the protrusion 411 configured to contact the first elastic member 34 may also be positioned further away from the display screen 12. Thus, the antenna clearance area between the bottom of the protrusion 411 and the display screen 12 is greatly increased, and the antenna performance is also improved.

[00407] In addition, when both the first elastic member 34 and the projection 411 are located away from the display screen 12, the contact point of the first elastic member 34 in contact with the projection 411 may also be located away from the display screen 12. Thus, the contact point (power supply point) of the first elastic member 34 in contact with the protrusion 411 is less affected by the display screen 12.

[00408] In addition, the first elastic member 34 is attached to the first extension portion 312 so that the circuit between the first elastic member 34 and the RF transceiver chip 421 located on the first board 31 becomes shorter. Therefore, the RF signal transmission path is shorter and the RF signal transmission loss is less, meaning the antenna performance is better.

[00409] In addition, compared with the solution of attaching the first resilient member 34 to the second board 33, in this embodiment, the first elastic member 34 is attached to the first extension portion 312. Therefore, components and wiring (e.g., antenna switches, inductors, capacitors) or resistors) related to the antenna are no longer located on the riser board 32 and the second board 33. Thus, on the one hand, the design of the circuit board assembly 30 is more concise, that is, the complexity of the circuit board assembly 30 is reduced and the assembly cost 30 PCB below. On the other hand, more space can be freed up on the second board 33 to accommodate more electronic components.

[00410] In addition, the radio frequency path 42 is electrically coupled to the emitter 41 by the first resilient member 34, which can provide a more stable connection between the radio frequency path 42 and the emitter 41. In particular, since the first elastic member 34 has a resilient force when the first elastic piece 34 is in elastic contact with the emitter 41, the first elastic piece 34 can always be in contact with the emitter 41, thereby providing better stability of the connection between the radio frequency path 42 and the emitter 41.

[00411] In addition, it can be understood that the space between the surface of the first extension portion 312 facing the display screen 12 and the emitter 41 is generally small. Conventional chips or electronic components are not easily placed in this area. In this case, the space is not used, which easily leads to wastage of space. However, in this embodiment, the first elastic piece 34 of a relatively small size is secured to the side of the first extension portion 312 facing the display screen 12. On the one hand, the space of this portion can be effectively used to improve the utilization of the internal space of the electronic device 100. On the other hand, compared with the case in which the first elastic member 34 is located on the surface of the first board 31 facing the back cover 22, in this embodiment implementation, the space between the first board 31 and the back cover 22 can save the space occupied by the at least one first elastic member 34. Thus, the saved space can be used to arrange more electronic components, thereby greatly improving the space utilization of the printed circuit board assembly 30.

[00412] Next, with reference to FIG. 5, the distance L from the point of contact between the first elastic part 34 and the emitter 41 to the display screen 12 is greater than or equal to 2 mm. For example, L is equal to 2 mm, 2.5 mm, 3 mm, 3.5 mm or 4 mm.

[00413] It is understood that when the distance L from the point of contact between the first elastic member 34 and the emitter 41 to the display screen 12 is greater than or equal to 2 mm, the first elastic member 34 can be located further away from the display screen 12. In this case, in the Z-axis direction, the protrusion 411 can also be further removed from the display screen 12. Thus, the antenna clearance area between the bottom of the protrusion 411 and the display screen 12 is greatly increased, and the antenna performance is also improved.

[00414] In addition, the distance L from the contact point between the first elastic member 34 and the emitter 41 to the display screen 12 is less than or equal to 4.7 mm.

[00415] It is understood that when the distance L from the contact point between the first elastic piece 34 and the emitter 41 to the display screen 12 is less than or equal to 4.7 mm, on the one hand, it can be ensured that the first elastic piece 34 is distant from the display screen 12; and on the other hand, it can be ensured that the thickness of the electronic device 100 in the Z-axis direction is not too large, which makes the configuration thin.

[00416] In this embodiment, there are multiple methods for configuring the circuit board assembly 30. Several methods for configuring the circuit board assembly 30 are described in detail below with reference to the corresponding accompanying drawings.

[00417] First optional method: hereinafter referring to FIG. 6 and fig. 7, the printed circuit board assembly 30 further includes a first reinforcement board 35 and a second reinforcement board 36. The first reinforcement board 35 and the second reinforcement board 36 are located on two sides of the first elastic member 34, respectively. In the Z-axis direction, the thickness of the first reinforcement board 35 and the second reinforcement board 36 is greater than the thickness of the lifting board 32.

[00418] The first enhancement board 35 includes a first portion 351 and a second portion 352 connected to the first portion 351. The first portion 351 is fixedly connected to the board surface of the first extension portion 312 facing the screen 10. In this case, the first extension portion 312, the first portion 351 and the second portion 352 of the first board 31 are sequentially stacked along the Z-axis direction. The second enhancement board 36 includes a third portion 361 and a fourth portion 362 connected to the third portion 361. The third portion 361 is fixedly connected to the surface of the first extension board portion 312 facing the screen 10. In this case, the first extension portion 312, the third portion 361, and the fourth portion 362 of the first board 31 are sequentially stacked along the Z-axis direction. In addition, in FIG. 7, the first part 351, the third part 361 and the riser plate 32 are schematically outlined by dotted lines, and the second part 352, the fourth part 362 and the second plate 33 are schematically outlined by dotted lines.

[00419] It can be understood that by sequentially laying the first part 351 and the second part 352 on one side of the first elastic member 34 and the first extension part 312 and sequentially laying the third part 361 and the fourth part 362 on the other side of the first elastic member 34 and on the first extension part 312, the thickness of a portion of the first extension portion 312 in the Z-axis direction is increased, thereby greatly increasing the structural strength of the first plate 31. Thus, when the first elastic member 34 is in elastic contact with the radiator 41, the first elastic member 34 receives the counterforce of the antenna radiator 41 . The first elastic member 34 transmits a counterforce to the first extension portion 312 of the first board 31. In this case, the first extension portion 312 can effectively counteract the force of the interaction of the first portion 351, the second portion 352, the third portion 361, and the fourth portion 362, thereby preventing the first portion from being damaged. extension portion 312 or cracking due to external force, thereby avoiding disconnection of the antenna circuit.

[00420] Additionally, with reference to FIG. 7, the first part 351 and the third part 361 are fixedly connected to the lifting plate 32.

[00421] Optionally, the first portion 351, the third portion 361, and the lift plate 32 are of a single structure. In other words, the first part 351, the third part 361 and the lifting board 32 are a single board. In this case, the overall structural strength of the first part 351, the third part 361 and the lifting plate 32 is higher. Thus, the first part 351, the third part 361 and the lifting plate 32 cannot be easily broken or cracked when subjected to external force. Optionally, the first portion 351 and the third portion 361 may alternatively be permanently connected to the riser plate 32 by a soldering process.

[00422] Additionally, with reference to FIG. 7, the second part 352 and the fourth part 362 are fixedly connected to the second board 33.

[00423] Optionally, the second portion 352, the fourth portion 362, and the second panel 33 are of one-piece construction. In other words, the second part 352, the fourth part 362 and the second board 33 are a single board. In this case, the connection of the second part 352, the fourth part 362 and the second board 33 is stronger. Thus, the second portion 352, the fourth portion 362, and the second board 33 are not easily broken or cracked when subjected to external force. In another optional manner, the second portion 352 and the fourth portion 362 may alternatively be connected to the second board 33 using a soldering process.

[00424] FIG. 9 is a partial schematic structural view of a printed circuit board assembly of the electronic device shown in FIG. 1 in another optional way. The first part 351 of the first reinforcement board 35 and the third part 361 of the second reinforcement board 36 may be located separately from the lifting board 32. That is, the first part 351 and the third part 361 are directly attached to the first extension part 312 of the first board 31, and there is no need for them to be stationary connection with lifting plate 32.

[00425] In addition, the second portion 352 of the first enhancement board 35 and the fourth portion 362 of the second enhancement board 36 may be located separately from the second board 33. That is, the second portion 352 and the fourth portion 362 are directly attached to the first extension portion 312 of the first board 31. and they do not need to be fixedly connected to the second board 33.

[00426] In this implementation, by sequentially laying the first part 351 and the second part 352 on the first extension part 312 and sequentially laying the third part 361 and the fourth part 362 on the first extension part 312, the structural strength of the first board 31 is significantly improved.

[00427] In addition, the first part 351, the third part 361 and the lifting plate 32 are arranged separately. Therefore, the choice of materials of the first part 351 and the third part 361 is not limited to the same material as the lift plate 32. For example, the first part 351 and the third part 361 can be made of inexpensive rigid plastic plates.

[00428] In addition, the second part 352, the fourth part 362 and the second board 33 are located separately. Therefore, the choice of materials for the second portion 352 and the fourth portion 362 is not limited to the same material as the second board 33. For example, the second portion 352 and the fourth portion 362 may be made from lower-cost rigid plastic plates.

[00429] With reference to FIG. 6, fig. 10 is a schematic sectional view of the printed circuit board assembly shown in FIG. 6 along the line C-C. It can be understood that the cross-sectional view shown in FIG. 10 is a cross-sectional view along line C-C of the printed circuit board assembly shown in FIG. 6 and when viewed along the negative X-axis direction. The first portion 351 of the first gain board 35 is provided with a first gain solder pad 353. The first extension portion 312 of the first board 31 is provided with a second reinforcement pad 313 for solder. The first solder reinforcement pad 353 is soldered to the second solder reinforcement pad 313. It can be understood that when the first part 351 and the first extension part 312 are soldered to each other by the first solder reinforcement pad 353 and the second solder reinforcement pad 313, the connection between the first part 351 and the first extension part 312 becomes stronger and the overall strength 30 pcb assembly is better. In addition, after the first solder reinforcement pad 353 and the second solder reinforcement pad 313 are soldered together, the first solder reinforcement pad 353 and the second solder reinforcement pad 313 can effectively protect the solder pad (the solder pad of this portion is mainly configured to electrically connect between the wiring of the first board 31 and the wiring of the riser board 32) between the first main body portion 311 of the first board 31 and the riser board 32. That is, the solder pad between the first main body portion 311 and the riser board 32 is prevented from being easily destroyed by the external strength.

[00430] In addition, the third part 361 of the second reinforcement board 36 is further provided with a third reinforcement pad 363 for solder. The third solder reinforcement pad 363 is soldered to the second solder reinforcement pad 313. It can be understood that when the third part 361 and the first extension part 312 are soldered to each other by the third solder reinforcement pad 363 and the second solder reinforcement pad 313, the connection between the third part 361 and the first extension part 312 becomes stronger, and the overall strength of the assembly 30 PCB is better. In addition, after the third solder reinforcement pad 363 and the second solder reinforcement pad 313 are soldered together, the third solder reinforcement pad 363 and the second solder reinforcement pad 313 can effectively protect the solder pad (the solder pad of this portion is mainly configured to electrically connect between the wiring of the first board 31 and the wiring of the riser board 32) between the first main body portion 311 of the first board 31 and the riser board 32. That is, the solder pad between the first main body portion 311 and the riser board 32 is prevented from being easily destroyed by the external strength.

[00431] Optionally, the first portion 351 and the second portion 352 of the first enhancement board 35 may alternatively be soldered together using a solder pad. In this case, the connection between the first part 351 and the second part 352 is stronger, and the overall strength of the circuit board assembly 30 is higher. In addition, after soldering the first part 351 and the second part 352 by a solder pad, a solder pad (the solder pad of this section is mainly configured for electrical connection between the wiring of the riser board 32 and the wiring of the second board 33) located between the riser board 32 and The second board is 33, not easy to be broken by external force.

[00432] In addition, the third portion 361 and the fourth portion 362 of the second enhancement board 36 may alternatively be soldered together using a solder pad. In this case, the connection between the third portion 361 and the fourth portion 362 is stronger, and the overall strength of the circuit board assembly 30 is higher. In addition, after soldering the third portion 361 and the fourth portion 362 by a solder pad, a solder pad (the solder pad of this portion is mainly configured for electrical connection between the wiring of the riser board 32 and the wiring of the second board 33) located between the riser board 32 and The second board is 33, not easy to be broken by external force.

[00433] FIG. 11 is a partial schematic structural view of the printed circuit board assembly shown in FIG. 6 from a different angle. The distance d1 between the first elastic part 34 and the lifting plate 32 is from 0.15 mm to 30 mm. It can be understood that in FIG. 6, the lifting plate 32 and the second plate 33 are flush with each other. In this case, the lifting plate 32 is simply blocked by the second plate 33 at the angle shown in FIG. 11. In this case, so that the lifting board 32 can be clearly seen, the second board 33 is no longer shown in FIG. eleven.

[00434] In this implementation, when the distance d1 between the first elastic member 34 and the lifting plate 32 is from 0.15 mm to 30 mm, the size of the first extension portion 312 located between the first elastic member 34 and the lifting plate 32 is relatively moderate. Thus, when the first elastic member 34 is in elastic contact with the emitter 41, the first elastic member 34 receives the reaction force of the emitter 41. The first elastic member 34 transmits the reaction force to the first extension portion 312. In this case, the first extension portion 312 located between the first elastic piece 34 and lifting plate 32, not easy to break or crack. In other words, the counter force received by the first extension portion 312 can be quickly transmitted to the lift plate 32 so that the counter force counteracts the internal tension of the lift plate 32.

[00435] Referring to FIG. 11, the distance d2 between the first elastic piece 34 and the first part 351 is from 0.15 mm to 30 mm. It will be appreciated that the second portion 352 is also not shown in FIG. 11. In this case, the size of the first extension portion 312 located between the first elastic member 34 and the first portion 351 is relatively moderate. Thus, when the first elastic member 34 is in elastic contact with the antenna radiator 41, the first elastic member 34 receives the reaction force of the emitter 41. The first elastic member 34 transmits the reaction force to the first extension portion 312. In this case, the first extension portion 312 located between the first elastic part 34 and the first part 351 are not easy to break or crack. In other words, the reaction force received by the first extension part 312 can be quickly transmitted to the first part 351 so that the reaction force counteracts the internal tension of the first part 351.

[00436] Referring to FIG. 11, the distance d3 between the first elastic part 34 and the third part 361 is from 0.15 mm to 30 mm. It will be understood that the fourth portion 362 is also not shown in FIG. 11. In this case, the size of the first extension portion 312 located between the first elastic member 34 and the third portion 361 is relatively moderate. Thus, when the first elastic member 34 is in elastic contact with the antenna radiator 41, the first elastic member 34 receives the reaction force of the emitter 41. The first elastic member 34 transmits the reaction force to the first extension portion 312. In this case, the first extension portion 312 located between the first elastic part 34 and the third part 361, is not easy to break or crack. In other words, the reaction force received by the first extension part 312 can be quickly transmitted to the third part 361, so that the reaction force counteracts the internal tension of the third part 361.

[00437] FIG. 12 is a partial sectional view of the electronic device shown in FIG. 1 in another optional way, taken along the line B-B. It can be understood that the cross-sectional view shown in FIG. 12 is a cross-sectional view formed by taking a cross-section of the electronic device of FIG. 1 along line B-B and viewing along the positive Y-axis direction, and then rotating the resulting cross-section 180° with the Y-axis as the axis of rotation. The first extension portion 312 of the first board 31 is provided with a groove 314. The opening of the groove 314 is located on a surface of the first extension portion 312 facing the display screen 12. A portion of the first elastic member 34 is mounted in the groove 314.

[00438] It can be understood that when a portion of the first elastic member 34 is mounted in the groove 314 in the Z-axis direction, there is an overlap region between the first elastic member 34 and the first extension portion 312. In this case, the first elastic member 34 may be located further from the screen 12 of the display, that is, in the Z-axis direction, the distance between the first elastic member 34 and the display screen 12 can be significantly increased. In this case, the distance from the point of contact between the first elastic part 34 and the emitter 41 to the display screen 12 increases significantly. Thus, in the Z-axis direction, the protrusion 411 of the emitter 41 can also be located in the direction away from the display screen 12, that is, the antenna clearance area between the bottom of the protrusion 411 and the display screen 12 can be made larger, and the performance of the antenna is also better.

[00439] Optionally, when the first extension portion 312 is provided with a first reinforcing board 35 and a second reinforcing board 36, a groove 314 is located between the first reinforcing board 35 and the second reinforcing board 36. In this case, the first reinforcing board 35 and the second reinforcing board 36 can increase strength. the first extension portion 312, thereby preventing the strength of the first extension portion 312 from being reduced due to the opening of the groove 314.

[00440] Second Optional Method: The same technical content of the second optional method as the first optional method is no longer repeated. Fig. 13a is a partial schematic structural view of the circuit board assembly of the electronic device shown in FIG. 1, another optional method. The printed circuit board assembly 30 further includes a first reinforcement board 35 and a second reinforcement board 36. The first reinforcement board 35 and the second reinforcement board 36 are located on two sides of the first elastic member 34, respectively. The thickness of the first reinforcement board 35 is greater than the thickness of the riser board 32 in the Z-axis direction. The thickness of the second reinforcement board 36 is less than or equal to the thickness of the riser board 32.

[00441] The first enhancement board 35 includes a first portion 351 and a second portion 352 connected to the first portion 351. The first portion 351 is fixedly connected to the board surface of the first extension portion 312 facing the screen 10. In this case, the first extension portion 312, the first portion 351 and the second portion 352 of the first board 31 are sequentially stacked along the Z-axis direction. Thus, the thickness of the portion of the first extension portion 312 in the Z-axis direction is increased.

[00442] In addition, unlike the first optional method, the second enhancement board 36 no longer includes the fourth portion 362, that is, the second enhancement board 36 only includes the third portion 361 in the first optional method. The second reinforcing board 36 is fixedly connected to the board surface of the first extension portion 312 facing the screen 10. In this case, the first extension portion 312 of the first board 31 and the second enhancing board 36 are stacked on each other in the Z-axis direction.

[00443] It is understood that by sequentially laying the first portion 351 and the second portion 352 on one side of the first resilient member 34 and on the first extension portion 312 and laying the second reinforcing board 36 on the other side of the first resilient member 34 and on the first extension portion 312, the structural strength the first board 31 increases significantly. Thus, when the first elastic member 34 is in elastic contact with the antenna radiator 41, the first elastic member 34 receives the reaction force of the radiator 41. The first elastic member 34 transmits the reaction force to the first extension portion 312. In this case, when the first amplification board 35 and of the second amplification board 36, the first extension portion 312 can effectively resist said force, thereby preventing the first extension portion 312 from being damaged or cracked due to external force, and thereby avoiding disconnection of the antenna circuit.

[00444] In this implementation in FIG. 13a shows that the riser board 32 and the second board 33 are staggered in the X-axis direction, that is, a portion of the riser board 32 protrudes in the X-axis direction relative to the second board 33. In another optional method, the riser board 32 may be positioned flush with the second board 33.

[00445] In another optional method, a method for configuring the circuit board assembly 30 may refer to a method for configuring the circuit board assembly 30 in a first optional manner. In an example, the connections of the first reinforcement board 35 to the second reinforcement board 36 and the first reinforcement board 35 to the riser board 32 may refer to the connections of the first reinforcement board 35 to the second reinforcement board 36 and to the riser board 32 in a first optional manner. In another example, the relative position of the first elastic member 34, respectively, with the lifting plate 32, the first reinforcing board 35, and the second reinforcing board 36 may also refer to the relative position of the first elastic member 34, respectively, with the lifting plate 32, the first reinforcing board 35, and the second reinforcing board 36 first optional method. The details are not repeated here.

[00446] FIG. 13b is a partial schematic structural view of the circuit board assembly of the electronic device shown in FIG. 1 is another optional method. In this implementation, the printed circuit board assembly 30 further includes a ground conductive element 369. A method for configuring the ground conductive element 369 may refer to a method for configuring the first resilient member 34. The ground conductive element 369 is located on a surface of the second reinforcement board 36 facing away from the first board. 31. The ground conductive element 369 is electrically connected to the grounding point, that is, the ground conductive element 369 is grounded. Of course, in another optional manner, ground conductive element 369 may also be used in other antennas.

[00447] In this implementation, the ground conductive element 369 is located on the second gain board 36, such that the ground conductive element 369 is used to ground the radiator 41 or is used in other antennas. In this way, the functions of the circuit board assembly 30 can be further expanded. In addition, the space on the second amplification board 36 can also be efficiently used, that is, the space utilization of the printed circuit board assembly 30 is improved.

[00448] Optionally, when the second reinforcement board 36 and the riser board 32 are of a single structure, the wiring is arranged in the second reinforcement plate 36, and thus the wiring in the second reinforcement plate 36 is electrically connected to the wiring in the riser board 32 or the wiring in the second reinforcing board 36 is electrically connected to the wiring of the first board 31.

[00449] In another optional embodiment, when the second reinforcement board 36 and the riser board 32 are located separately, the wiring is arranged in the second reinforcement plate 36, and thus the wiring in the second reinforcement plate 36 is electrically connected to the wiring of the first board 31.

[00450] Third Optional Method: The same technical content of the third optional method as in the first optional method and the second optional method is no longer repeated. Fig. 14 is a partial schematic structural view of the circuit board assembly of the electronic device shown in FIG. 1 is another optional method. The printed circuit board assembly 30 includes a first reinforcement board 35. The first reinforcement board 35 is located on one side of the first elastic member 34. In the Z-axis direction, the thickness of the first reinforcement board 35 is greater than that of the riser board 32.

[00451] The first enhancement board 35 includes a first portion 351 and a second portion 352 coupled to the first portion 351. The first portion 351 is fixedly connected to the board surface of the first extension portion 312 facing the screen 10. In this case, the first extension portion 312, the first part 351 and the second part 352 of the first board 31 are sequentially stacked along the Z-axis direction.

[00452] It is understood that the first reinforcing board 35 is laid on one side of the first elastic member 34 and on the first extension portion 312, so that the structural strength of the first board 31 is greatly improved. Thus, when the first elastic member 34 is in elastic contact with the antenna radiator 41, the first elastic member 34 receives the reaction force of the antenna radiator 41. The first elastic member 34 transmits a counterforce to the first extension portion 312 of the first board 31. In this case, when interacting with the first reinforcement board 35, the first extension portion 312 can effectively counteract the force, thereby preventing the first extension portion 312 from being damaged or cracked by the external force. and thus preventing disconnection of the antenna circuit.

[00453] In this implementation, FIG. 14 shows that the riser plate 32 and the second plate 33 are flush with each other. Optionally, alternatively, a portion of the riser board 32 may be offset from the second board 33 in the X-axis direction, that is, a portion of the riser board 32 protrudes in the X-axis direction relative to the second board 33.

[00454] In another optional method for the configuration method of the circuit board assembly 30, reference may be made to the method of configuring the circuit board assembly 30 by the first optional method. In an example, connecting the first reinforcement board 35 to the riser board 32 may refer to connecting the first reinforcement board 35 to the riser board 32 in a first optional manner. In another example, the relationship of the first resilient member 34, respectively, with the lifting plate 32 and the first reinforcing plate 35 may also relate to the relationship of the first elastic member 34, respectively, with the lifting plate 32 and the first reinforcing plate 35 in a first optional manner. The details are not repeated here.

[00455] Fourth Optional Method: The same technical content of the fourth optional method as the first optional method is no longer repeated. Fig. 15 is a partial schematic structural view of the circuit board assembly of the electronic device shown in FIG. 1, another optional method. The printed circuit board assembly 30 includes a first reinforcement board 35. The first reinforcement board 35 is disposed on one side of the first elastic member 34. Moreover, the first extension portion 312 of the first board 31 and the first reinforcement board 35 are stacked on each other in the Z-axis direction. in the Z-axis direction, the thickness of the first reinforcement board 35 is less than or equal to the thickness of the riser board 32. It can be understood that, unlike the above-mentioned additional methods, the first reinforcement board 35 no longer includes the second part 352, that is, the first reinforcement board 35 only includes the first part 351 in the first optional method.

[00456] It can be understood that by laying the first reinforcing board 35 on one side of the first elastic member 34 and on the first extension portion 312, the structural strength of the first board 31 is significantly increased. Thus, when the first elastic member 34 is in elastic contact with the antenna radiator 41, the first elastic member 34 receives the reaction force of the antenna radiator 41. The first elastic member 34 transmits a counterforce to the first extension portion 312 of the first board 31. In this case, when interacting with the first reinforcement board 35, the first extension portion 312 can effectively counteract the force, thereby preventing the first extension portion 312 from being damaged or cracked by the external force. .

[00457] In this implementation, FIG. 15 shows that the lift plate 32 and the second plate 33 are flush with each other. In another optional method, a portion of the riser board 32 and the second board 33 may alternatively be staggered in the X-axis direction, that is, a portion of the riser board 32 protrudes in the X-axis direction relative to the second board 33.

[00458] In another optional method for the configuration method of the circuit board assembly 30, reference may be made to the method of configuring the circuit board assembly 30 by the first optional method. In an example, connecting the first reinforcement board 35 to the riser board 32 may refer to connecting the first reinforcement board 35 to the riser board 32 in a first optional manner. In another example, the relationship of the first elastic member 34 with the lift plate 32 and the first reinforcing plate 35 may also relate to the relationship of the first elastic member 34 with the lift plate 32 and the first reinforcement plate 35 in a first optional manner. The details are not repeated here.

[00459] Fifth optional method: The same technical content of the fifth optional method as in the first optional method is no longer repeated. Fig. 16 is a partial schematic structural view of the circuit board assembly of the electronic device shown in FIG. 1, another optional method. The circuit board assembly 30 no longer includes the first enhancement board 35 and the second enhancement board 36. Thus, the space of the first extension portion 312 becomes wider. In this case, a portion of the first matching circuit 422 can be arranged on the first extension portion 312, so that the first main body portion 311 of the first board 31 can arrange more electronic components, thereby greatly improving the space utilization of the printed circuit board assembly 30.

[00460] In this implementation, FIG. 16 shows that the riser plate 32 and the second plate 33 are flush with each other. In another optional method, alternatively, a portion of the riser board 32 may be staggered from the second board 33 in the X-axis direction, that is, a portion of the riser board 32 protrudes in the X-axis direction relative to the second board 33.

[00461] In another optional method for the configuration method of the circuit board assembly 30, reference may be made to the method of configuring the circuit board assembly 30 by the first optional method. For example, the relationship of the first resilient member 34 to the riser plate 32 may also relate to the relationship of the first resilient member 34 to the riser plate 32 in a first, optional manner. The details are not repeated here.

[00462] Sixth Optional Method: The same technical content of the sixth optional method as the first optional method is no longer repeated. Fig. 17 is a partial schematic structural view of the circuit board assembly of the electronic device shown in FIG. 1, another optional method. In this implementation, the portion of the second board 33 projects relative to the riser board 32. In this case, the protruding portion of the second board 33 relative to the riser board 32 (the area indicated by the dotted line in FIG. 17) is located opposite the first extension portion 312 of the first board 31.

[00463] In addition, a portion of the first elastic member 34 extends between the first board 31 and the second board 33, that is, a portion of the first elastic member 34 is located between the second board 33 and the first board 31. A portion of the first elastic member 34 projects relative to the second board 33. It is understood that a portion of the first elastic member 34 with a smaller height in the Z-axis direction can extend between the first plate 31 and the second plate 33. A portion of the first elastic member 34 with a larger height in the Z-axis direction protrudes relative to the second plate 33.

[00464] In this implementation, a portion of the first elastic member 34 extends between the first board 31 and the second board 33 such that the first elastic member 34 is protected by the second board 33, thereby preventing the first elastic member 34 from colliding with other components in the electronic device 100. In addition, when the second board 33 protrudes relative to the riser board 32, the board surface area of the second board 33 increases significantly. In this case, more electronic components can be arranged on the second board 33, that is, more electronic components can be arranged on the circuit board assembly 30, thereby making it easier to realize the multifunctional needs of the electronic device 100.

[00465] Several methods for configuring the circuit board assembly 30 are described in detail above with reference to the corresponding drawings, and additionally several configuration methods for electrically connecting the first resilient member 34 to the emitter 41 are described in detail with reference to the corresponding drawings.

[00466] FIG. 18 is a partial sectional view of the electronic device shown in FIG. 1, another optional method taken along the B-B line. It can be understood that the cross-sectional view shown in FIG. 18 is a cross-sectional view formed by taking a cross-section of the electronic device of FIG. 1 along line B-B and viewing along the positive Y-axis direction, and then rotating the resulting cross-section 180° with the Y-axis as the axis of rotation. A conductive member 43 is located on a surface of the emitter 41 facing the first resilient member 34. The conductive member 43 can be, but is not limited to, gold, silver, or copper. In particular, the conductive piece 43 is located in the projection 411. Optionally, the conductive piece 43 can be connected to the emitter 41 using a soldering process. In this case, the connection between the conductive part 43 and the emitter 41 is stronger. Of course, by other possible methods, the conductive piece 43 can alternatively be fixedly connected to the emitter 41 using a conductive adhesive.

[00467] In addition, the first elastic member 34 is in elastic contact with the conductive member 43. In other words, the first elastic member 34 is electrically coupled to the emitter 41 through the conductive member 43. Thus, when the RF transceiver chip 421 transmits an RF signal, the RF signal is transmitted to the emitter 41 through the first matching circuit 422, the first elastic member 34 and the conductive member 43. In addition, when the emitter 41 receives the electromagnetic wave signal and converts the electromagnetic wave signal into an RF signal, the RF signal is transmitted to the RF transceiver chip 421 through the conductive member 43 , a first elastic member 34 and a first matching circuit 422.

[00468] It can be understood that when the emitter 41 is provided with a conductive member 43, the conductive member 43 can improve the flatness of the surface of the emitter 41. In this case, when the first elastic member 34 is in elastic contact with the emitter 41 through the conductive member 43, the elastic contact of the first the elastic part 34 with the emitter 41 is stable. Thus, the RF signal is also stable during transmission between the emitter 41 and the first elastic member 34, thereby providing better performance of the antenna of the electronic device 100.

[00469] Optionally, the oxidation resistance of the conductive part 43 is higher than that of the emitter 41. It can be understood that in an environment with the same temperature and humidity, the conductive part 43 is not as easily oxidized compared to the emitter 41. Thus, compared with solution in which the first elastic part 34 is in direct elastic contact with the emitter 41, the contact resistance of the first elastic part 34 with the conductive part 43 is less, that is, the contact resistance of the first elastic part 34 with the conductive part 43 is stable, and the loss during transmission of the radio frequency signal is less . In this case, the antenna performance of the electronic device 100 is better.

[00470] In other possible embodiments, alternatively, the oxidation resistance of the conductive member 43 may be equal to or lower than that of the antenna radiator 41.

[00471] FIG. 19 is a partial sectional view of the electronic device shown in FIG. 1 by another optional method taken along the B-B line. It can be understood that the cross-sectional view shown in FIG. 19 is a cross-sectional view formed by taking a cross-section of the electronic device shown in FIG. 1, along line B-B and viewing along the positive Y-axis direction, and then rotating the resulting cross-section 180° with the Y-axis as the axis of rotation. The electronic device 100 includes a fastener 44. The fastener 44 can be, but is not limited to, a screw, rivet, or pin. The mount 44 is made of a conductive material. In addition, the emitter 41 is provided with a blind hole 412. Specifically, the blind hole 412 is located on the projection 411. The fastener 44 is fixed in the blind hole 412. The first elastic member 34 is in elastic contact with the fastener 44. Thus, when the radio frequency transceiver chip 421 emits radio frequency signal, the radio frequency signal is transmitted to the emitter 41 through the first matching circuit 422, the first elastic member 34 and the fastener 44. In addition, when the emitter 41 receives the electromagnetic wave signal and converts the electromagnetic wave signal into an radio frequency signal, the radio frequency signal is transmitted to the radio frequency transceiver chip 421 through the fastening 44, the first elastic part 34 and the first matching circuit 422.

[00472] It can be understood that, compared to the solution in which the conductive piece 43 is soldered to the emitter 41, in this embodiment, the mount 44 is located in the blind hole 412 of the emitter 41, and the first elastic piece 34 is electrically connected to the antenna emitter 41 through the mount 44. thereby eliminating the process of soldering the conductive part 43 to the emitter 41. Therefore, on the one hand, the investment in the electronic device 100 is reduced, and there is no need to increase the investment in the soldering process; and, on the other hand, the case where the performance of the emitter 41 in transmitting and receiving electromagnetic waves deteriorates due to the formation of gas holes, slag inclusions, solder joints or cracks during the soldering process in the emitter 41 is excluded.

[00473] Optionally, the oxidation resistance of the mounting 44 is greater than that of the emitter 41. Thus, compared to a solution in which the first resilient member 34 is in direct elastic contact with the emitter 41, the contact resistance of the first resilient member 34 with the mounting 44 is less. that is, the contact resistance of the first elastic part 34 with the fastening 44 is stable. In this case, the RF signal transmission loss is lower and the antenna performance of the electronic device 100 is better. In other possible embodiments, the oxidation resistance of the mounting 44 may alternatively be equal to or lower than that of the antenna radiator 41.

[00474] Optionally, the resistance of the mount 44 is less than the resistance of the emitter 41. In this case, the conductive characteristic of the mount 44 is better than that of the emitter 41 such that when the first elastic member 34 is in elastic contact with the mount 44, the rate of transmission of the radio frequency signal between the mount 44 and the first elastic part 34 is faster and the losses are smaller, that is, the antenna performance of the electronic device 100 is better.

[00475] FIG. 20a is a partial section through the electronic device shown in FIG. 1, another optional method taken along the B-B line. It can be understood that the cross-sectional view shown in FIG. 20a is a cross-sectional view formed by taking a cross-section of the electronic device in FIG. 1 along line B-B, viewing in the positive Y-axis direction, and then rotating the resulting cross-sectional view 180° with the Y-axis as the axis of rotation. In this implementation, the first elastic member 34 is attached to the side of the first extension portion 312 of the first board 31 facing the display screen 12. The first elastic member 34 is in elastic contact with the inner side surface 413 of the emitter 41. In this case, the protrusion 411 can no longer be located in the emitter 41, that is, the first elastic member 34 may not be in elastic contact with the protrusion 411 of the emitter 41. Thus , the first elastic member 34 may be located relatively close to the back cover 22, that is, the first elastic member 34 may be located relatively far from the display screen 12. Thus, in the Z-axis direction, the distance between the first elastic member 34 and the display screen 12 can be significantly increased. Thus, in the Z-axis direction, the antenna clearance area between the first elastic member 34 and the display screen 12 can be larger, and the antenna performance is also improved.

[00476] In addition, the distance from the contact point between the first elastic member 34 and the emitter 41 to the display screen 12 increases significantly. In this case, the display screen 12 has less signal interference with the point of contact of the first elastic part 34 and the emitter 41.

[00477] In addition, in the Z-axis direction, the space without the projection 411 can also optionally be used for the antenna clearance area. Thus, the antenna clearance area is larger and the antenna performance is better.

[00478] Optionally, a portion of the first elastic member 34 is fixedly connected to the side surface of the first extension portion 312. In this case, the first plate 31 may exert pressure on the first elastic member 34 in the negative X-axis direction, and thus the first elastic member 34 is in more stable contact with the emitter 41.

[00479] Optionally, the inner side surface 413 of the emitter 41 may also be positioned in accordance with the configuration of the protrusion 411 of the emitter 41 described above. For example, a conductive member is located on the inner side surface 413 of the emitter 41, or a hole of the emitter 41 for opening a blind hole is located on the inner side surface 413 of the emitter 41. Details are not repeated here.

[00480] FIG. 20b is a partial sectional view of the electronic device shown in FIG. 1, another optional method taken along the B-B line. It can be understood that the schematic cross-sectional view shown in FIG. 20b is a cross-sectional view formed by taking a cross-section of the electronic device shown in FIG. 1, along line B-B and viewing along the positive Y-axis direction, and then rotating the resulting cross-section 180° with the Y-axis as the axis of rotation. In this implementation, the first elastic member 34 is attached to the side of the first extension portion 312 of the first board 31 facing the back cover 22. In addition, the first elastic member 34 is in elastic contact with the protrusion 411 of the emitter 41.

[00481] In this implementation, the first elastic member 34 is attached to the side of the first extension portion 312 facing the rear cover 22 and is in elastic contact with the protrusion 411 of the emitter 41 by the first elastic member 34, so that the first elastic member 34 can be positioned relatively close to the back cover 22, that is, the first elastic member 34 can be located relatively far from the display screen 12, that is, in the Z-axis direction, the distance between the first elastic member 34 and the display screen 12 can be significantly increased. Thus, in the Z-axis direction, the protrusion 411 for contacting the first elastic member 34 can also be located substantially away from the display screen 12. The antenna clearance area between the bottom of the protrusion 411 and the display screen 12 can be larger in the Z-axis direction, and the antenna performance is also better.

[00482] In addition, the distance from the point of contact between the first elastic member 34 and the emitter 41 to the display screen 12 increases significantly. In this case, the display screen 12 has less signal interference with the point of contact of the first elastic part 34 and the emitter 41.

[00483] In another optional embodiment, the first elastic member 34 may be a ruptured elastic member. Specifically, by opening the through hole or groove in the first extension portion 312 of the first board 31, a portion of the first elastic member 34 is mounted in the through hole or groove, and a portion of the first elastic member 34 is opened relative to the first extension portion 312. Thus, the contact position between the first The elastic member 34 and the protrusion 411 are not limited to the contact position shown in FIG. 20b, which is positioned flush with the surface of the first extension portion 312 facing the rear cover 22. The contact position between the first elastic member 34 and the protrusion 411 can be flexibly positioned in accordance with the position of the first elastic member 34. For example, the contact position between the first elastic member 34 and the projection 411 may be flush with the surface of the first extension portion 312 facing the display screen 12.

[00484] FIG. 21 is a partial sectional view of the electronic device shown in FIG. 1, another optional method taken along the B-B line. It can be understood that the cross-sectional view shown in FIG. 21 is a cross-sectional view formed by taking a cross-section of the electronic device shown in FIG. 1, along line B-B and viewing along the positive Y-axis direction, and then rotating the resulting cross-section 180° with the Y-axis as the axis of rotation. In this implementation, another structure of the first conductive element 34 is described in detail with reference to FIG. 21. Specifically, the first conductive member 34 includes a first locking member 341, an elastic member 342, and a second locking member 343. The elastic member 342 is connected between the first locking member 341 and the second locking member 343. It is understood that the elastic member 342 may be, but not limited to this, an elastic part or a spring. Moreover, the first fixing piece 341 may be a copper piece, an aluminum piece, or a gold piece, among other things. The second fixing piece 343 may be, among other things, a copper piece, an aluminum piece, or a gold piece.

[00485] In addition, the first fixing part 341 is fixedly connected to the emitter 41. Specifically, the first fixing part 341 is attached to the protrusion 411 of the emitter 41. The second fixing part 343 is fixedly connected to the first extension part 312 of the first board 31. In this case, when The RF transceiver chip 421 emits an RF signal, the RF signal is transmitted to the emitter 41 through the first matching circuit 422, the second locking member 343, the elastic member 342 and the first locking member. 341. In addition, when the emitter 41 receives the electromagnetic wave signal and converts the electromagnetic wave signal into an RF signal, the RF signal is transmitted to the RF transceiver chip 421 through the first fixing part 341, the elastic member 342, the second fixing part 343 and the first matching circuit 422.

[00486] In this implementation, the first conductive element 34 has a simple structure and is easy to assemble, which can reduce the complexity of assembling the electronic device 100.

[00487] Several methods for elastically contacting the first elastic member 34 with the emitter 41 are described in detail above with reference to the corresponding drawings. In addition, the above-mentioned emitter 41 uses an ungrounded solution. Several grounding configurations for the emitter 41 are described in detail below with reference to the corresponding drawings.

[00488] First optional method: FIG. 22 is a partial sectional view of the electronic device shown in FIG. 1, in another optional manner along the line A-A. Fig. 23 is a partial sectional view of the electronic device shown in FIG. 22, along the D-D line. The frame 21 further includes a connecting segment 218. It can be understood that the cross-sectional view shown in FIG. 22 is a cross-sectional view of the electronic device of FIG. 1 taken along line AA and viewed in the negative Z-axis direction. Moreover, the cross-sectional view shown in FIG. 23 is a schematic diagram obtained by taking a cross section of the electronic device in FIG. 22 along the line D-D and when viewed along the positive Y-axis direction. The connecting segment 218 is connected between the emitter 41 and the middle plate 24. It can be understood that in the electronic device 100, the middle plate 24 is generally in a grounded state. Thus, the emitter 41 is grounded by connecting to the middle plate 24 through the connecting segment 218. Moreover, as can be seen from FIG. 23, the thickness of the connecting segment 218 in the Z-axis direction is less than the thickness of the emitter 41 in the Z-axis direction. In this case, the third gap 216 between the emitter 41 and the middle plate 24 is not divided by the connecting segment 218.

[00489] It can be understood that the optional method emitter 41 is grounded in a simpler manner, has a simpler structure, and has a lower investment cost.

[00490] Optionally, the connecting segment 218 and the emitter 41 are of a single structure. In this case, compared with the method of connecting the connecting segment 218 to the emitter 41 using a soldering process, in this optional method the soldering process is eliminated, thereby saving the cost of the soldering process. Of course, by other optional methods, the connection segment 218 may alternatively be connected to the emitter 41 by soldering or the like.

[00491] Second optional method: FIG. 24 is a partial schematic structural view of the circuit board assembly of the electronic device shown in FIG. 1, another optional method. Fig. 25 is a partial sectional view of the electronic device shown in FIG. 1, optionally along line E-E. It can be understood that the cross-sectional view shown in FIG. 25 is a cross-sectional view formed by taking a cross-section of the electronic device in FIG. 1 along line B-B, viewing in the positive Y-axis direction, and then rotating the resulting cross-sectional view 180° with the Y-axis as the axis of rotation. The printed circuit board assembly 30 further includes a second conductive element 391. It can be understood that the design and method of configuration of the second conductive element 391 may be related to the design and method of configuration of the first conductive element 34. For example, the second conductive element 391 is located in the first extension portion 312 of the first boards 31. The details are not repeated here. Moreover, in this implementation, the second conductive element 391 is described in terms of the second resilient member 391. Unlike the first resilient member 34, the second resilient member 391 is electrically coupled between the ground plane of the first board 31 and the emitter 41. In other words, the second resilient member 391 is configured for grounding the emitter 41.

[00492] It can be understood that the optional method emitter 41 is grounded in a simpler manner, has a simpler structure, and has a lower investment cost.

[00493] Referring to FIG. 25, the first board 31 is provided with a second matching network 399. The second matching network 399 includes an inductor, a capacitor, a resistor, or an antenna switch. The second elastic member 391 is electrically coupled to the second matching network 399 and is electrically coupled to the ground plane of the first board 31 through the second matching network 399. The second matching network 399 is for tuning the frequency band of the antenna for transmitting and receiving electromagnetic waves and is used to match the impedance of the antenna. Thus, the antenna's performance for transmitting and receiving electromagnetic waves is improved. In another optional method, the first board 31 may alternatively not be provided with a second matching network 399.

[00494] Third optional method: FIG. 26 is a partial sectional view of the electronic device shown in FIG. 1, by another optional method along the E-E line. It can be understood that the cross-sectional view shown in FIG. 26 is a cross-sectional view formed by taking a cross-section of the electronic device in FIG. 1 along line B-B, viewing in the positive Y-axis direction, and then rotating the resulting cross-sectional view 180° with the Y-axis as the axis of rotation. The printed circuit board assembly 30 further includes a second conductive element 391 and a third conductive element 392. It can be understood that the structure and configuration method of the second conductive element 391 may be related to the structure and configuration method of the first conductive element 34, which will not be described again here. Moreover, in this implementation, the second conductive member 391 is described by reference to the second elastic member 391. Moreover, the third conductive member 392 may be an electrically conductive elastic member or an electrically conductive spring, which is not limited to this application. In this implementation, the third conductive element 392 is described in terms of the third elastic member 392.

[00495] Additionally, unlike the first resilient member 34, the second resilient member 391 is electrically coupled between the emitter 41 and the third resilient member 392 secured to the second board 33.

[00496] Optionally, third resilient member 392 is electrically coupled to second resilient member 391 via wiring in circuit board assembly 30. In other optional embodiments, a wire is located on the circuit board assembly 30, in which case the third resilient member 392 is electrically connected to the second resilient member 391 by a wire.

[00497] In addition, the third elastic member 392 is in elastic contact with the middle plate 24. In this case, the emitter 41 is electrically connected to the middle plate 24 through the second elastic member 391 and the third elastic member 392. In other words, the emitter 41 is grounded through the second elastic member part 391 and a third elastic part 392.

[00498] It is understood that the second elastic member 391 is located on the first extension portion 312, and the third elastic member 392 is located on the second board 33 and is used for grounding, and thus the grounding path of the emitter 41 is increased. In this case, a matching circuit may be provided in the grounding path of the emitter 41 on the circuit board assembly 30 to adjust the frequency band of the antenna for transmitting and receiving electromagnetic waves, so that the transmitting and receiving frequency band of the antenna is wider. For example, with reference to FIG. 26, fig. 27 is a partial sectional view of the electronic device shown in FIG. 1, in another optional way, taken along the line A-A. It can be understood that the cross-sectional view shown in FIG. 27 is a cross-sectional view of the electronic device of FIG. 1 taken along line AA and viewed in the negative Z-axis direction. Electronic device 100 includes a first leg 393 and a second leg 394 arranged in parallel, with the first leg 393 and the second leg 394 located between the second elastic member 391 and the third elastic member. part 392. The first branch 393 includes a capacitor. The second leg 394 includes an inductor. When switched to the first branch 393, the electronic device 100 transmits and receives an antenna signal with a first frequency band, for example, the first frequency band is an intermediate frequency band for LTE. When switched to the second branch 394, the electronic device 100 transmits and receives an antenna signal with a second frequency band, for example, the second frequency band is a high frequency band for LTE.

[00499] Optionally, antenna switches for the antenna are located in the first leg 393 and in the second leg 394. The second leg 394 is disabled by the antenna switch for the antenna when the electronic device 100 needs to be switched to the first leg 393. The first leg 393 is disabled by the antenna switch for the antenna when the electronic device 100 must be switched to the second branch 394.

[00500] Several methods for grounding the antenna radiator 41 are described in detail above with reference to the corresponding drawings. Several grounding methods can alternatively be used in combination with each other. Moreover, in each of the above-mentioned additional methods, the first elastic member 34 is generally configured to supply an RF signal emitted by the RF path 42 to the emitter 41 or to transmit an RF signal converted by the emitter 41 to the RF path 42. In other words, a position in which the first elastic part 34 is in elastic contact with the emitter 41, is the power supply point. Another application environment for the first elastic member 34 is described in detail below with reference to the corresponding drawings. Alternatively, the first elastic member 34 may be configured to ground the emitter 41 or to be electrically connected to the matching circuit of the antenna to be grounded via the matching circuit. In this case, the contact position between the first elastic member 34 and the emitter 41 is the antenna tuning point on the ground.

[00501] This implementation does not repeat the same technical content as each of the above optional methods. Fig. 28 is a partial sectional view of the electronic device shown in FIG. 1, in another optional way, taken along the line A-A. Fig. 29 is a partial sectional view of the electronic device shown in FIG. 1, another optional method taken along the B-B line. It can be understood that the cross-sectional view shown in FIG. 28 is a cross-sectional view of the electronic device of FIG. 1 taken along line AA and viewed in the negative Z-axis direction. The cross-sectional view shown in FIG. 29 is a cross-sectional view formed by taking a cross-section of the electronic device shown in FIG. 1, along line B-B and viewing along the positive Y-axis direction, and then rotating the resulting cross-section 180° with the Y-axis as the axis of rotation. The printed circuit board assembly 30 includes a first board 31, a riser board 32, a second board 33, and a first conductive member 34. Methods for configuring the first board 31, riser board 32, second board 33, and first conductive member 34 may be related to methods for configuring the first board 31 , the riser board 32, the second board 33, and the first conductive element 34 by each of the above-mentioned additional methods, which are not described again here.

[00502] In this implementation, the electronic device 100 includes a second matching circuit 395. The second matching circuit 395 is configured to adjust the antenna frequency band for transmitting and receiving electromagnetic waves. Of course, the second matching network 395 can also be used to match the antenna impedance. A second matching network 395 is located on the first board 31. In addition, a second matching network 395 is electrically connected between the first elastic member 34 and the ground plane of the first board 31. In other words, the emitter 41 is grounded through the first elastic member 34 and the second matching network 395. In addition, , the second matching network 395 may include an antenna switch, a capacitor, or an inductor.

[00503] It can be understood that by positioning the first extension portion 312, which projects relative to the riser plate 32 and the second plate 33, and the first elastic member 34 being fixedly coupled to the first extension portion 312, the first elastic member 34 is positioned away from the display screen 12, then is in the Z-axis direction, the distance between the first elastic member 34 and the display screen 12 can be significantly increased. Thus, in the Z-axis direction, the projection 411 of the emitter 41 can also be located in the direction away from the display screen 12, that is, the antenna clearance area between the bottom of the projection 411 and the display screen 12 can be made larger, and the performance of the antenna is also better.

[00504] In addition, when the first elastic member 34 and the projection 411 are located away from the display screen 12, the contact point (antenna ground tuning point) at which the first elastic member 34 contacts the projection 411 may also be located away from display screen 12. Thus, the contact point (antenna-ground alignment point) at which the first elastic member 34 contacts the protrusion 411 is less affected by the display screen 12.

[00505] In addition, by placing the second matching network 395 on the first board 31, the tuning circuit 395 is located at a distance from the display screen 12, that is, the distance between the second matching network 395 and the display screen 12 in the Z-axis direction can be significantly increased. Thus, in the Z-axis direction, the antenna clearance area between the display screen 12 and the second matching network 395 can be larger, and the antenna performance is improved.

[00506] In addition, when the antenna clearance area is significantly increased, by placing the first extension portion 312 protruding relative to the riser plate 32 and the second plate 33, and stationarily connecting the first elastic member 34 to the first extension portion 312, and making the first elastic member elastically contact parts 34 with the emitter 41, the ground path of the emitter 41 is significantly reduced, thereby improving the performance of the antenna.

[00507] In addition, the method of grounding the emitter 41 optionally through the first resilient member 34 and the second matching circuit 395 is simple and convenient to operate.

[00508] In another optional method, the electronic device 100 may alternatively not include a second matching network 395. In this case, the emitter 41 is directly electrically connected to the ground plane of the first board 31, that is, the emitter 41 is directly grounded.

[00509] Several designs of the circuit board assembly 30 and several application scenarios for the first resilient member 34 are described in detail above with reference to the corresponding drawings. In each of the above optional methods, the first elastic member 34 is located on the first extension portion 312 of the first board 31. Several methods for configuring the printed circuit board assembly 30 are described in detail below with reference to the corresponding drawings. It can be understood that the first few elastic parts 34 of the printed circuit board assembly 30 described below are located on the extension portion of the riser board 32. Details may refer to the following description. Additionally, each of the following optional methods does not repeat the same technical content as the previous optional methods.

[00510] FIG. 30 is a partial schematic structural view of the circuit board assembly of the electronic device shown in FIG. 1, another optional method. Fig. 31 is a schematic exploded view of the printed circuit board assembly shown in FIG. 30. The printed circuit board assembly 30 includes a first resilient member 34 and a first board 31, a riser board 32, and a second board 33 stacked in series.

[00511] The first board 31 includes a first main body portion 311 and a first extension portion 312. The first extension portion 312 projects relative to the second board 33. In FIG. 30 and Fig. 31, the first extension portion 312 is shown to protrude in the X-axis direction relative to the second board 33. In another optional method, the first extension portion 312 may alternatively protrude in a different direction relative to the second board 33, such as in the Y-axis direction, which is not limited to in this application. .

[00512] In addition, the lifting board 32 includes a second main body portion 321 and a second extension portion 322. The first main body portion 311, the second main body portion 321, and the second board 33 are sequentially stacked. The second extension portion 322 is stacked on the first extension portion 312, and the second extension portion 322 projects relative to the second board 33. In this implementation, FIG. 30 and fig. 31 shows that the second extension portion 322 and the first extension portion 312 are flush with each other. In another optional method, the second extension portion 322 may alternatively be staggered from the first extension portion 312.

[00513] FIG. 32 is a partial sectional view of the electronic device shown in FIG. 1, another optional method taken along the B-B line. It can be understood that the cross-sectional view shown in FIG. 32 is a cross-sectional view formed by taking a cross-section of the electronic device shown in FIG. 1, along line B-B and viewing along the positive Y-axis direction, and then rotating the resulting cross-section 180° with the Y-axis as the axis of rotation. The first extension portion 312 is located close to the emitter 41 relative to the first main body portion 311. The second extension portion 322 is also located close to the emitter 41 relative to the second main body portion 321.

[00514] In addition, the first elastic member 34 is attached to the second extension portion 322, and the first elastic member 34 is in elastic contact with the antenna radiator 41. In this case, the first resilient member 34 and the second plate 33 are located on one side of the riser plate 32. In this embodiment, the first resilient member 34 is in elastic contact with the projection 411. In another embodiment, the emitter 41 may not have a projection 411. In this case, the first resilient member 34 piece 34 may be in elastic contact with the inner side surface of emitter 41, and details may refer to the optional method shown in FIG. 20a described above, which is not described again here.

[00515] In addition, the first resilient member 34 is electrically coupled between the RF path 42 and the emitter 41. Thus, RF signals transmitted by the RF transceiver chip 421 can be transmitted to the emitter 41 through the first matching circuit 422 and the first resilient member 34. In addition, Moreover, after the emitter 41 converts the received electromagnetic wave signals into radio frequency signals, the radio frequency signals can be further transmitted to the radio frequency transceiver chip 421 through the first elastic member 34 and the first matching network 422.

[00516] In this embodiment, by placing a second extension portion 322 that protrudes relative to the second board 33 and statically connecting the first resilient member 34 to the second extension portion 322, the first resilient member 34 is positioned away from the display screen 12, i.e. . in the Z-axis direction, the distance between the first elastic member 34 and the display screen 12 can be significantly increased. In this case, the distance from the point of contact between the first elastic part 34 and the emitter 41 to the display screen 12 increases significantly. Thus, in the Z-axis direction, the projection 411 of the emitter 41 can also be located in the direction away from the display screen 12, that is, the antenna clearance area between the bottom of the projection 411 and the display screen 12 can be made larger, and the performance of the antenna is also better.

[00517] In addition, when both the first elastic member 34 and the projection 411 are located away from the display screen 12, the contact point of the first elastic member 34 in contact with the projection 411 may also be located away from the display screen 12. Thus, the contact point (power supply point) of the first elastic member 34 in contact with the protrusion 411 is less affected by the display screen 12.

[00518] In addition, the second extension portion 322 is stacked on the first extension portion 312. In this case, the overall strength of this portion can be increased by the interaction of the second extension portion 322 and the first extension portion 312. Thus, when the first elastic member 34 is in elastic contact with the antenna emitter 41, the first elastic member 34 receives the counter force of the emitter 41. The first elastic member 34 transmits the counter force to the second extension part 322. In this case, when the first extension part 312 interacts, the second extension part 322 can effectively counteract the force, thereby preventing the second extension portion 322 from being damaged or cracked due to external force and thus preventing the antenna circuit from being disconnected.

[00519] Referring to FIG. 30 and fig. 31, the printed circuit board assembly 30 further includes a third reinforcement board 37 and a fourth reinforcement board 38. The third reinforcement board 37 and the fourth reinforcement board 38 are also respectively located on both sides of the first elastic member 34. In FIG. 31, the third amplification board 37, the fourth amplification board 38 and the second amplification board 33 are schematically indicated by a dotted line. In addition, the third reinforcing board 37 and the fourth reinforcing board 38 are laid on the board surface of the second extension portion 322 of the lifting board 32 facing the screen 10. Thus, the overall strength of the second extension portion 322 is further enhanced. In this case, when the first elastic member 34 is in elastic contact with the radiator 41, the first elastic member 34 receives the counterforce of the antenna radiator 41. The first elastic member 34 transmits a counter force to the second extension portion 322 of the first board 31. In this case, with the interaction of the third reinforcement board 37 and the fourth reinforcement board 38, the second extension portion 322 can effectively counteract the said force, thereby preventing the second extension portion 322 from being damaged or cracked. under the influence of external force.

[00520] Optionally, the third amplification board 37, the fourth amplification board 38, and the second amplification board 33 are of one-piece construction. In other words, the third amplification board 37, the fourth amplification board 38 and the second amplification board 33 are one-piece boards. In this case, the overall structural strength of the third reinforcement board 37, the fourth reinforcement board 38 and the second reinforcement board 33 is higher. Thus, the third reinforcement board 37, the fourth reinforcement board 38 and the second reinforcement board 33 cannot be easily broken or cracked by external force.

[00521] In another optional method, the third reinforcement board 37 and the fourth reinforcement board 38 may also be connected to the second board 33 using a soldering process.

[00522] In another optional method, the third reinforcement board 37, the fourth reinforcement board 38, and the second reinforcement board 33 can also be located separately, that is, the third reinforcement board 37 and the fourth reinforcement board 38 are directly attached to the second extension portion 322 of the riser board 32 without a fixed connections to the second board 33.

[00523] FIG. 33 is a partial schematic structural view of the printed circuit board assembly shown in FIG. 30 from a different angle. The distance d1 between the first elastic part 34 and the second plate 33 is from 0.15 mm to 30 mm.

[00524] In this implementation, when the distance d1 between the first elastic piece 34 and the second board 33 is from 0.15 mm to 30 mm, the size of the second extension portion 322 located between the first elastic piece 34 and the second board 33 is relatively moderate. Thus, when the first elastic member 34 is in elastic contact with the emitter 41, the first elastic member 34 receives the reaction force of the emitter 41. The first elastic member 34 transmits the reaction force to the second extension part 322. In this case, the second extension part 322 located between the first elastic piece 34 and second plate 33, it is not easy to break or split. In other words, the reaction force received by the second extension portion 322 can be quickly transmitted to the second board 33 so that the reaction force counteracts the internal voltage of the second board 33.

[00525] Referring to FIG. 33, the distance d2 between the first elastic member 34 and the third reinforcing board 37 is from 0.15 mm to 30 mm. In this case, the size of the second extension portion 322 located between the first elastic member 34 and the third reinforcing board 37 is relatively small. Thus, when the first elastic member 34 is in elastic contact with the antenna radiator 41, the first elastic member 34 receives the reaction force of the emitter 41. The first elastic member 34 transmits the reaction force to the second extension portion 322. In this case, the second extension portion 322 located between the first elastic piece 34 and the third reinforcing board 37 are not easy to break or crack. In other words, the reaction force received by the second extension portion 322 can be quickly transmitted to the third enhancement board 37 so that the reaction force counteracts the internal voltage of the third enhancement board 37.

[00526] Referring to FIG. 33, the distance d3 between the first elastic member 34 and the fourth reinforcing board 38 is from 0.15 mm to 30 mm. In this case, the size of the second extension portion 322 located between the first elastic member 34 and the fourth reinforcing board 38 is relatively small. Thus, when the first elastic member 34 is in elastic contact with the antenna radiator 41, the first elastic member 34 receives the reaction force of the emitter 41. The first elastic member 34 transmits the reaction force to the second extension portion 322. In this case, the second extension portion 322 located between the first elastic piece 34 and the fourth reinforcing board 38 are not easy to break or crack. In other words, the reaction force received by the second extension portion 322 can be quickly transmitted to the fourth reinforcement board 38 so that the reaction force counteracts the internal voltage of the fourth reinforcement board 38.

[00527] FIG. 34 is a partial sectional view of the electronic device shown in FIG. 1, by another optional method along the B-B line. It can be understood that the cross-sectional view shown in FIG. 34 is a cross-sectional view formed by taking a cross-section of the electronic device shown in FIG. 1, along line B-B and viewing along the positive Y-axis direction, and then rotating the resulting cross-section 180° with the Y-axis as the axis of rotation. The second extension portion 322 of the riser board 32 is provided with a groove 314. The opening of the groove 314 is located on a surface of the riser board 32 facing the display screen 12. A portion of the first elastic member 34 is mounted in the groove 314.

[00528] It can be understood that when a portion of the first elastic member 34 is mounted in the groove 314 in the Z-axis direction, an overlap region occurs between the first elastic member 34 and the second extension portion 322. In this case, the first elastic member 34 can be located at a distance from the display screen 12, that is, in the Z-axis direction, the distance between the first elastic member 34 and the display screen 12 can be significantly increased. Thus, in the Z-axis direction, the projection 411 of the emitter 41 can also be located in the direction away from the display screen 12, that is, the antenna clearance area between the bottom of the projection 411 and the display screen 12 can be made larger, and the performance of the antenna is also better.

[00529] In addition, when both the first elastic member 34 and the projection 411 are located away from the display screen 12, the contact point of the first elastic member 34 in contact with the projection 411 may also be located away from the display screen 12. Thus, the contact point at which the first elastic member 34 contacts the protrusion 411 is less affected by the display screen 12.

[00530] Optionally, when the third reinforcement board 37 and the fourth reinforcement board 38 are located in the second extension portion 322, the groove 314 is located between the first reinforcement board 35 and the second reinforcement board 36. In this case, the third reinforcement board 37, the fourth reinforcement board 38 and the first extension portion 312 may increase the strength of the second extension portion 322, thereby preventing the strength of the second extension portion 322 from being reduced due to the opening of the groove 314.

[00531] FIG. 35 is a partial schematic structural view of the circuit board assembly of the electronic device shown in FIG. 1, in another optional way. The printed circuit board assembly 30 includes a third reinforcing board 37. The third reinforcing board 37 is located on one side of the first elastic member 34.

[00532] In addition, the third reinforcing board 37 is stacked on the second extension portion 322. Thus, the second extension portion 322, the second chamber 33, and the third reinforcing board 37 enclose the first elastic member 34.

[00533] It can be appreciated that by stacking the third reinforcing board 37 on one side of the first elastic member 34 and the second extension portion 322, the structural strength of the second extension portion 322 is greatly enhanced. Thus, when the first elastic member 34 is in elastic contact with the antenna radiator 41, the first elastic member 34 receives the reaction force of the radiator 41. The first elastic member 34 transmits the reaction force to the second extension portion 322. In this case, when the third amplification board 37 and of the first extension portion 312, the second extension portion 322 can effectively resist said force, thereby preventing the second extension portion 322 from being damaged or cracked by the external force, and thereby avoiding disconnection of the antenna circuit.

[00534] In this implementation of FIG. 35 shows that the second extension portion 322 and the first extension portion 312 are flush with each other. In another optional method, the second extension portion 322 may alternatively be staggered from the first extension portion 312.

[00535] Optionally, a plurality of first elastic members 34 may be located on the second extension portion 322. Different first elastic members 34 may be used in different antennas. Therefore, the PCB assembly 30 has many functions and is widely used.

[00536] FIG. 36 is a partial schematic structural view of the circuit board assembly of the electronic device shown in FIG. 1, another optional method. The circuit board assembly 30 no longer includes the third enhancement board 37 and the fourth enhancement board 38. Thus, the space of the second extension portion 322 becomes wider. In addition, since the second extension portion 322 of the riser board 32 is laid on the first extension portion 312 of the first board 31, the structural strength of the second extension portion 322 is higher. In this case, a plurality of first elastic members 34 may be located on the second extension portion 322. Different first elastic members 34 may be used in different antennas. Therefore, the PCB assembly 30 has many functions and is widely used.

[00537] In this implementation of FIG. 36 shows that the second extension portion 322 and the first extension portion 312 are flush with each other. In another optional manner, the second extension portion 322 may alternatively be staggered from the first extension portion 312.

[00538] The first embodiment of the electronic device 100, in which the screen 10 is flat, is described in detail above with reference to the corresponding drawings. A second embodiment of the electronic device 100, in which the screen 10 is curved, is described in detail below with reference to the corresponding drawings.

[00539] In the second embodiment, the same technical content as in the first embodiment is not described again. Fig. 37 is a schematic structural view of an electronic device by another optional method provided by an embodiment of this application. The screen 10 of the electronic device 100 is a curved screen. The screen 10 may be a 2.5-dimensional (D) curved screen or a three-dimensional curved screen. The details are not limited to this embodiment. Fig. 37 shows that the screen 10 covers most of the housing 20.

[00540] FIG. 38 is a partial cross-section of the electronic device shown in FIG. 37, along the F-F line. It can be understood that the cross-sectional view shown in FIG. 38 is a partial cross-sectional view formed by taking a cross-section of the electronic device in FIG. 37 along the F-F line, viewing in the positive Y-axis direction, and then rotating the resulting cross-sectional view 180° with the Y-axis as the axis of rotation. The screen 10 includes a flat portion 101 and a curved portion 102 connected to the flat portion 101. It can be understood that the flat portion 101 is a flat portion of the screen 10, and the curved portion 102 is a curved portion of the screen 10. Moreover, the flat portion 101 includes a portion of the protective cover plate 11 and a portion of the display screen 12. The curved portion 102 includes a plate portion of the protective cover 11 and a display screen portion 12.

[00541] In this embodiment, the circuit board assembly 30 of the electronic device 100 includes a first board 31, a riser board 32, a second board 33, and a first conductive element 34. Methods for configuring the first board 31, riser board 32, the second board 33, and the first conductor elements 34 may refer to methods for configuring the first board 31, the riser board 32, the second board 33, and the first conductive element 34 in the first embodiment, which are not described again here.

[00542] It can be understood that when the screen 10 is a curved screen, the curved portion 102 of the screen 10 forms a side of the electronic device 100. In this case, when the first elastic member 34 is located on the second board 33, the first elastic member 34 is likely to be surrounded curved portion 102 of the screen 10 in the X-axis direction. In this case, the RF signal of the antenna is more affected by the curved portion 102 of the screen 10. In addition, in the Z-axis direction, the distance between the first elastic member 34 and the flat portion 101 of the screen 10 is small, so that in the direction of Z axis, the antenna clearance area is extremely compressed, and the antenna performance is poor. However, in this embodiment, by placing the first extension portion 312 protruding relative to the riser plate 32 and the second plate 33 on the first plate 31 and fixedly connecting the first elastic member 34 to the first extension portion 312 in the X-axis direction, the first elastic member 34 is larger is not surrounded by the curved portion 102 of the shield 10. Thus, the first elastic member 34 is less affected by the curved portion 102, and the antenna performance is improved. In addition, when the first elastic member 34 is fixedly connected to the first extension portion 312 in the Z-axis direction, the distance between the first elastic member 34 and the flat portion 101 of the screen 10 increases. Thus, in the Z-axis direction, the antenna clearance area between the first elastic member 34 and the flat portion 101 of the screen 10 is larger, and the antenna performance is better.

[00543] In addition, when both the first elastic member 34 and the projection 411 are located away from the display screen 12, the contact point of the first elastic member 34 in contact with the projection 411 may also be located away from the display screen 12. Thus, the contact point at which the first elastic member 34 contacts the protrusion 411 is less affected by the display screen 12.

[00544] Referring to FIG. 38, the distance L from the point of contact between the first elastic part 34 and the emitter 41 to the flat part 101 is greater than or equal to 2 mm. For example, L is equal to 2 mm, 2.5 mm, 3 mm, 3.5 mm or 4 mm.

[00545] It is understood that when the distance L from the point of contact between the first resilient member 34 and the emitter 41 to the flat portion 101 is greater than or equal to 2 mm, the first resilient member 34 may be positioned further away from the flat portion 101. In this case, in the Z-axis direction, the protrusion 411 can also be further removed from the display screen 12. Thus, the antenna clearance area between the bottom of the protrusion 411 and the display screen 12 is greatly increased, and the antenna performance is also improved.

[00546] In addition, the distance L from the contact point between the first elastic member 34 and the emitter 41 to the flat portion 101 is less than or equal to 4.7 mm.

[00547] It can be understood that when the distance L from the contact point between the first elastic part 34 and the emitter 41 to the flat part 101 is less than or equal to 4.7 mm, on the one hand, it can be ensured that the first elastic part 34 is located away from the flat parts 101; on the other hand, it can be ensured that the thickness of the electronic device 100 in the Z-axis direction is not too large, which helps to make the configuration thin.

[00548] It can be understood that in FIG. 38 shows only one design of the printed circuit board assembly 30. Optionally, the curved screen electronic device 100 may also include various designs of the circuit board assembly 30 in the first embodiment.

[00549] An embodiment of the electronic device 100 in which the screen 10 is curved is described in detail above with reference to the corresponding drawings. An embodiment of another electronic device 100 in which the screen 10 is curved is described in detail below with reference to the corresponding drawings.

[00550] In the third embodiment, the same technical content as in the first embodiment and the second embodiment is not described again. Fig. 39 is a schematic structural view of an electronic device by yet another additional method provided by an embodiment of this application. The screen 10 of the electronic device 100 includes a first screen region 101 and a second screen region 102 disposed relative to each other, and a third screen region 103 and a fourth screen region 104 disposed relative to each other. The third screen area 103 and the fourth screen area 104 are connected between the first screen area 101 and the second screen area 102. In this case, the screen 10 of the electronic device 100 is a 360° curved screen.

[00551] In this implementation, the housing 20 no longer includes a back cover 22, that is, the housing 20 includes a frame 21. A first screen area 101, a third screen area 103, a second screen area 102, and a fourth screen area 104 are arranged around the frame 21. Fig. 39 shows that the first screen area 101 and the second screen area 102 are located on the upper and lower sides of the frame 21, and the third screen area 103 and the fourth screen area 104 are located on the left and right sides of the frame 21.

[00552] FIG. 40 is a partial sectional view of the electronic device shown in FIG. 39, along the line G-G. It can be understood that the cross-sectional view shown in FIG. 40 is a cross-sectional view formed by taking a cross-section of the electronic device in FIG. 39 along the G-G line, viewing in the positive Y-axis direction, and then rotating the resulting cross-sectional view 180° with the Y-axis as the axis of rotation. The first screen area 101 and the second screen area 102 include a protective cover plate portion 11 and a display screen portion 12. In addition, the circuit board assembly 30 of the electronic device 100 includes a first board 31, a riser board 32, a second board 33, and a first conductive element 34. Methods for configuring the first board 31, riser board 32, the second board 33, and the first conductive element 34 may include to methods for configuring the first board 31, the riser board 32, the second board 33 and the first conductive element 34 in the first embodiment, which are not described again here. In this embodiment, the first conductive element 34 is described using the first elastic member 34 as an example.

[00553] In addition, the distance from the contact point between the first conductive element 34 and the emitter 41 to the first screen area 101 is the first distance L1. The distance from the contact point between the first conductive element 34 and the emitter 41 to the second screen region 102 is the second distance L2, and the ratio of the first distance L1 to the second distance L2 is from 0.5 to 2. For example, the ratio of the first distance L1 to the second distance L2 is 0.5, 0.8, 1, 1.4, 1.5, 1.8 or 2.

[00554] It is understood that when the first elastic member 34 is attached to the second board 33 in the Z-axis direction, the distance between the first elastic member 34 and the first screen region 101 is small, that is, the first elastic member 34 is located adjacent to the first screen region 101. In this implementation, when the first elastic member 34 is fixedly connected to the first extension portion 312, and the ratio of the first distance L1 to the second distance L2 is from 0.5 to 2, in the Z-axis direction, the distance between the first elastic member 34 and the first screen region 101 is significant increased. Thus, in the Z-axis direction, the antenna clearance area between the first elastic member 34 and the first screen area 101 is greatly increased, and the performance of the antenna is also greatly improved. Moreover, when the ratio of the first distance L1 to the second distance L2 is in the range of 0.5 to 2, the distance from the contact point between the first conductive element 34 and the emitter 41 to the second screen area 102 is relatively moderate. In this case, the second screen area 102 has less influence on the antenna's performance in transmitting and receiving electromagnetic waves.

[00555] Optionally, the first distance L1 from the point of contact between the first conductive element 34 and the emitter 41 to the first screen area 101 is greater than or equal to 2 mm. For example, L1 is 2 mm, 2.5 mm, 3 mm, 3.5 mm or 4 mm.

[00556] It is understood that when the first distance L1 from the point of contact between the first conductive element 34 and the emitter 41 to the first screen area 101 is greater than or equal to 2 mm, the first elastic member 34 can be positioned further away from the first screen area 101 . In this case, in the Z-axis direction, the protrusion 411 can also be moved away from the first screen region 101 to a greater extent, so that the antenna clearance area between the bottom of the protrusion 411 and the first screen region 101 is significantly increased, and the performance of the antenna is also better.

[00557] In addition, the first distance L1 from the contact point between the first conductive element 34 and the emitter 41 to the first screen area 101 is less than or equal to 4.7 mm.

[00558] It can be understood that when the first distance L1 from the contact point between the first conductive element 34 and the emitter 41 to the first screen area 101 is less than or equal to 4.7 mm, on the one hand, it can be ensured that the first elastic member 34 is located at a distance from the first screen area 101; and on the other hand, it can be ensured that the thickness of the electronic device 100 in the Z-axis direction is small, which makes it easier for the electronic device 100 to be thinned.

[00559] It can be understood that in FIG. 40 shows only one structure of the printed circuit board assembly 30. Optionally, the curved screen electronic device 100 may also include various designs of the circuit board assembly 30 in the first embodiment.

[00560] Embodiments of the three electronic devices 100 are described in detail above. Among the three electronic devices 100, each of the electronic devices 100 is provided with a circuit board assembly 30 of each of the above-mentioned additional methods. Thus, in an environment where antennas are crowded, the antenna of the electronic device 100 has a larger clearance area, which significantly improves the antenna performance of the electronic device 100. In another embodiment, the circuit board assembly 30 of each of the above additional methods may also be located in the electronic device with a foldable screen . Thus, in an electronic device with a foldable screen, the electronic device can also have a larger antenna clearance area in an antenna-dense environment, thereby significantly improving the antenna performance of the electronic device 100.

[00561] The above description represents only specific implementations of this application, but it is not intended to limit the scope of protection of this application. Any change or substitution readily detectable by one skilled in the art within the technical scope disclosed in this application shall/shall fall within the scope of protection of this application. Therefore, the scope of protection of the present application should correspond to the scope of protection of the claims.

Claims (35)

1. An electronic communication device containing a frame, a screen and a printed circuit board assembly; and the screen is mounted on one side of the frame, and a section of the frame forms an antenna emitter or the antenna emitter is fixed on the inside of the frame; And a printed circuit board assembly is disposed on an interior side of the frame, the printed circuit board assembly comprising a first conductive member, and a first board, a riser board, and a second board stacked in series, the first board being located on one side of the second board remote from the screen, the first board comprises a first main body part and a first extension part connected to the first main body part, wherein the first main body part is fixedly connected to the lifting plate, wherein the lifting plate is located between the first board and the second board, and the first extension part projects relative to the lifting plate and the second board and is located close to the emitter, and the first conductive element is fixed to the first extension part and is in elastic contact with the emitter; wherein the printed circuit board assembly further comprises a first amplification board, the first amplification board located on one side of the first conductive element and fixedly connected to the board surface of the first extension portion facing the screen; wherein the printed circuit board assembly further comprises a second amplification board, the second amplification board located on one side of the first conductive element remote from the first amplification board, and fixedly connected to the board surface of the first extension portion facing the screen. 2. An electronic device according to claim 1, characterized in that the first amplifying board contains a first part and a second part connected to the first part, the first part being fixedly connected to the surface of the board of the first extension part facing the screen, and the first part being fixedly connected to the lifting part board, the second part is fixedly connected to the second board, and in the thickness direction of the electronic device, the thickness of the first reinforcing board is greater than the thickness of the lifting board. 3. The electronic device of claim 2, wherein the first portion is provided with a first solder enhancement pad, the first extension portion is provided with a second solder enhancement pad, and the first solder enhancement pad is soldered to the second solder enhancement pad. 4. The electronic device according to claim 1, wherein the first extension portion is provided with a groove, the groove is located between the first amplification board and the second amplification board, the opening of the groove is located on a surface of the first extension portion facing the screen, and a portion of the first conductive element is mounted in the groove. 5. Electronic device according to any one of paragraphs. 1-3, characterized in that a conductive part is located on the surface of the emitter facing the first conductive element and the first conductive element is in elastic contact with the conductive part. 6. Electronic device according to any one of paragraphs. 1-3, characterized in that the electronic device contains a mount, the emitter is provided with a blind hole, the mount is fixed in the blind hole, and the first conductive element is in elastic contact with the mount. 7. Electronic device according to any one of paragraphs. 1-3, characterized in that the emitter includes an inner side surface facing the printed circuit board assembly, and the first conductive element is in elastic contact with the inner side surface. 8. Electronic device according to any one of paragraphs. 1-3, characterized in that the electronic device further comprises a middle plate, the middle plate is located on the inner side of the frame, the middle plate is grounded, the frame further includes a connecting segment, one end of the connecting segment is connected to the emitter, and the other end is connected to the middle plate. 9. Electronic device according to any one of paragraphs. 1-3, wherein the electronic device further comprises a middle plate, the middle plate is grounded, the middle plate is located on an inner side of the frame, the printed circuit board assembly further comprises a second conductive element and a third conductive element, the second conductive element being attached to a first extension portion of the first board, wherein the second conductive element is in elastic contact with the emitter, the third conductive element is attached to the second board, and the third conductive element is in elastic contact with the middle plate and is electrically connected to the second conductive element. 10. The electronic device according to claim 1, characterized in that the emitter contains a protrusion facing the inside of the electronic device, the first conductive element is fixed on one side of the first extension part facing the screen, the first conductive element is in elastic contact with the protrusion, the first conductive element electrically connected between the emitter and the radio frequency path of the antenna and the radio frequency path is mounted on the printed circuit board assembly; wherein the printed circuit board assembly further comprises a first amplification board and a second amplification board, wherein the first amplification board and the second amplification board are respectively located on two sides of the first conductive member, and in the thickness direction of the electronic device, the thickness of the first amplification board and the second amplification board are both greater than the thickness of the lifting boards; the first reinforcing board includes a first part and a second part connected to the first part, the first part is fixedly connected to the board surface of the first extension part facing the screen, the first part is fixedly connected to the lifting board and the second part is fixedly connected to the second board; the second reinforcing board includes a third part and a fourth part connected to the third part, the third part being fixedly connected to the board surface of the first extension part facing the screen, the third part being fixedly connected to the lifting board and the fourth part being fixedly connected to the second board; And the first part, the third part and the lifting plate are of one-piece structure, and the second part, the fourth part and the second plate are of one-piece structure. 11. An electronic communication device comprising a frame, a screen and a printed circuit board assembly; and the screen is mounted on the frame and located around the frame and the screen includes a first screen area and a second screen area located opposite each other; a section of the frame forms an antenna emitter or the antenna emitter is fixed on the inside of the frame; a printed circuit board assembly is located on the inside of the frame, the printed circuit board assembly contains a first conductive element and a first board, a riser board, and a second board stacked in series, the first board being spaced from the first screen area relative to the second board, wherein the first board contains a first portion the main body and a first extension portion connected to the first main body portion, the first main body portion being fixedly connected to the riser plate, the riser plate located between the first board and the second board, the first extension portion protruding relative to the riser board and the second board and located close to the emitter, and the first conductive element is fixed to the first extension part and is in elastic contact with the emitter; And the distance from the contact point between the first conductive element and the emitter to the first screen region is the first distance, the distance from the contact point between the first conductive element and the emitter to the second screen region is the second distance, and the ratio of the first distance to the second distance is in the range of 0.5 to 2. 12. The electronic device of claim 11, wherein the printed circuit board assembly further comprises a first amplification board, the first amplification board being located on one side of the first conductive element and fixedly connected to a surface of the first extension portion board facing the first screen area. 13. The electronic device according to claim 12, characterized in that the printed circuit board assembly further comprises a second amplification board, wherein the second amplification board is located on one side of the first conductive element at a distance from the first amplification board and is fixedly connected to the surface of the board of the first extension part facing to the first area of the screen. 14. Electronic device according to any one of paragraphs. 11-13, characterized in that the emitter includes an inner side surface facing the printed circuit board assembly, and the first conductive element is in elastic contact with the inner side surface. 15. Antenna equipment containing an antenna emitter and a printed circuit board assembly; and the printed circuit board assembly comprises a first conductive element and a first board, a riser board and a second board stacked on top of each other in series, the first board comprising a first main body portion and a first extension portion coupled to the first main body portion, wherein the first main body portion is fixedly connected with a riser plate, wherein the riser plate is located between the first board and the second board, wherein the first extension portion projects relative to the riser board and the second board and is located close to the emitter, the first conductive element is secured to the first extension portion, wherein the first conductive element, the riser board and the second the board is located on the same side of the first board, and the first conductive element is in elastic contact with the emitter; wherein the printed circuit board assembly further comprises a first amplification board, the first amplification board located on one side of the first conductive element and fixedly connected to a board surface of the first extension portion facing the second board; wherein the printed circuit board assembly further comprises a second amplification board, the second amplification board located on one side of the first conductive element spaced from the first amplification board and fixedly connected to a board surface of the first extension portion facing the second board. 16. Antenna equipment according to claim 15, characterized in that the first amplifying board contains a first part and a second part connected to the first part, and the first part is fixedly connected to the board surface of the first extension part facing the second board, and the first part is fixedly connected with the lifting board, the second part is fixedly connected to the second board, and in the thickness direction of the printed circuit board assembly, the thickness of the first reinforcing board is greater than the thickness of the lifting board. 17. Antenna equipment according to claim 15, characterized in that the first extension part is provided with a groove, the groove is located between the first amplifying board and the second amplifying board, the opening of the groove is located on the surface of the first extension part facing the emitter, and part of the first conductive element is mounted in the groove . 18. Antenna equipment according to any one of paragraphs. 15 or 16, characterized in that a conductive part is located on the surface of the emitter facing the first conductive element and the first conductive element is in elastic contact with the conductive part. 19. Antenna equipment according to any one of paragraphs. 15 or 16, characterized in that the antenna equipment contains a mount, the emitter is provided with a blind hole, the mount is fixed in the blind hole, and the first conductive element is in elastic contact with the mount. 20. Antenna equipment according to any one of paragraphs. 15 or 16, wherein the emitter includes an inner side surface facing the printed circuit board assembly and the first conductive element is in elastic contact with the inner side surface.

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