Disclosed is a drilling method for PCBs with high hole position precision, comprising: step 1 of fixing a PCB on a workbench; step 2 of pre-drilling a to-be-drilled portion of the PCB by using a short-blade drilling tool; and step 3 of deeply drilling the to-be-drilled portion which has been machined in step 2 by using along-blade drilling tool. The PCB is fixed in step 1 to prevent the PCB from moving during drilling which otherwise would affect the drilling precision; the to-be-drilled portion of the PCB is pre-drilled by using a short-blade drilling tool in step 2, and the short-blade drilling tool has a higher rigidity than along-blade drilling tool and thus will not easily slide at the moment of contacting the surface of the PCB; and the to-be-drilled portion which has been machined in step 2 is deep drilled by using the long-blade drilling tool in step 3, and the long-blade drilling tool has reduced sliding upon entry, thus guaranteeing the entry alignment of the long-blade drilling tool in the case of deep drilling, so that the drilled hole meets the requirement of high hole position precision for PCBs.

The present disclosure discloses a PCB processing method and a PCB. The method includes: respectively carrying out laminating processing on a plurality of PCB daughter boards constituting a PCB, and drilling and electroplating the top-most PCB daughter board to form a via hole; and laminating the plurality of PCB daughter boards together to form the PCB, and drilling and electroplating the formed PCB to form a through hole for mounting a connector, wherein a blind hole for mounting a connector is formed by the via hole, and a depth of the blind hole is greater than or equal to the length of a signal pin of the connector. By virtue of the technical scheme of the present disclosure, a space between wafers of the lower layer of PCBs may be doubled, and the space for layout between wafers may be doubled.

A bendable printed circuit board is provided. The bendable circuit board may include a circuit board having first and second sections and at least one plated wire that electrically connects and mechanically joins the first and second sections together. The first section may be pivotable with respect to the second section through the at least one plated wire.

Embodiments provide a multilayer printed circuit board intended to connect electronic components, the board comprising a stack of a plurality of conductive layers, the conductive layers comprising two surface layers and one or more internal layers, the board comprising one or more counterbored holes, each counterbored hole comprising a portion with metallization opening onto one of the two surface layers and a portion without metallization opening onto the other surface layer; the multilayer printed circuit board may advantageously comprise one or more metal pads, each metal pad being joined to one of the two surface layers so as to occult the portion without metallization of a corresponding counterbored hole.

An approach for through-hole component soldering for a PCB, and a resulting PCB assembly, that eliminates protruding solder joints, is provided. The approach comprises back-drilling, from a bottom surface of a PCB, one or more through-holes, wherein each back-drilled through-hole is back-drilled to a depth partially through the PCB and at a diameter that is larger than the diameter of the through hole. Solder paste is applied to the PCB. The components are placed on the PCB, inserting each pin into a corresponding through-hole. The PCB is passed through a solder process, whereby, within each through-hole having a component pin inserted therein, the solder paste is wicked into the through-hole, and forms a solder joint with the respective pin. Each solder joint of a back-drilled through-hole is situated within the through-hole in a manner whereby the solder joint does not protrude beyond the bottom surface of the PCB.

According to an embodiment, a printed circuit board and an electronic device is disclosed. The printed circuit board includes a first pattern configured to be formed in a first layer. The printed circuit board also includes a second pattern configured to be formed in at least one second layer under the first layer. The printed circuit board also includes a via configured to electrically connect the first pattern to the second pattern. The printed circuit board further includes a recess configured to be formed by removing at least a portion of an area in which the via is formed and to electrically separate the first pattern from the second pattern.

Methods and mechanisms for mitigating attenuation in a printed circuit board connection may include selecting the relative permittivities of resin layers proximate to the connection to control connection frequency resonances such that the attenuation of signals in the connection due to frequency resonance is mitigated.

A device has a base with a mounting surface with a length and a stack, the stack having a diameter smaller than the length and fastened to the mounting surface. The stack may have a plurality of stack conductive layers in addition to a plurality of insulating layers that separate each of the plurality of stack conductive layers. The stack conductive layers may be separated in a manner that aligns them with corresponding printed circuit board conductive layers when the stack portion of the device is inserted into an aperture in a printed circuit board.

An approach for through-hole component soldering for a PCB, and a resulting PCB assembly, that eliminates protruding solder joints, is provided. The approach comprises back-drilling, from a bottom surface of a PCB, one or more through-holes, wherein each back-drilled through-hole is back-drilled to a depth partially through the PCB and at a diameter that is larger than the diameter of the through hole. Solder paste is applied to the PCB. The components are placed on the PCB, inserting each pin into a corresponding through-hole. The PCB is passed through a solder process, whereby, within each through-hole having a component pin inserted therein, the solder paste is wicked into the through-hole, and forms a solder joint with the respective pin. Each solder joint of a back-drilled through-hole is situated within the through-hole in a manner whereby the solder joint does not protrude beyond the bottom surface of the PCB.

Methods for integrating copper-graphene laminate (CGL) in a multilayer PCB fabrication process and the resulting lamination stacks are disclosed. The methods include providing a core and applying a first graphene layer to the surface of the core. The methods further include applying a metal layer to the first graphene layer and applying a second graphene layer to the metal layer. Further, the methods include applying a photoresist layer to the second graphene layer and applying a protective layer to the photoresist layer. In some embodiments, the methods include applying a metallic plating to lamination stack. The methods further include drilling through the protective layer and at least one of a photoresist layer, the second graphene layer, the metal layer, the first graphene layer, and/or the core.