| Class / Patent application number | Description | Number of patent applications / Date published |
|---|
| 228180100 | Simultaneous bonding of multiple joints (e.g., dip soldering of printed circuit boards) | 70 |
| 20080217383 | MANUFACTURING METHOD OF PRINTED CIRCUIT BOARD - A screen plate having a plurality of openings is placed on a suspension substrate in which a plurality of conductive pads are formed. Conductive paste is moved in one direction on an upper surface of the screen plate, so that the conductive paste is applied onto the conductive pads through the openings. A recess that is inwardly bent is formed in each of the openings of the screen plate. | 09-11-2008 |
| 20080272180 | METHOD OF MANUFACTURING HEAT SPREADER MODULE - A heat spreader module has a pedestal, a heat spreader member joined to the pedestal by a first active hard brazing material, an intermediate layer joined to the heat spreader member by a second active hard brazing material, an insulating board joined to the intermediate layer by a third active hard brazing material, and a circuit board joined to the insulating board by a fourth active hard brazing material. The first through fourth active hard brazing materials are supplied such that the active hard brazing materials have a thickness ranging from 3 to 20 μm when the components of the heat spreader module are joined together under pressure, and contain an active element in an amount ranging from 400 to 1000 μg/cm | 11-06-2008 |
| 20090108052 | Selective soldering using fiber optic device - A fiber optic device for enabling soldering is described. The fiber optic device includes an entry portion comprising an optical fiber bundle for receiving a single light beam wherein the optical fiber bundle splits the light beam into a plurality of separate portions, each of the separate portions for enabling soldering. The fiber optic device further includes an exit portion for emitting each of the plurality of separate portions of the light beam in a pattern to enable soldering at a plurality of locations simultaneously utilizing the single light beam. | 04-30-2009 |
| 20090179067 | SELECTIVE SOLDERING SYSTEM - A solder machine includes a top flat carrier that holds PWBs just above a solder bath. Opposed edges of the carrier are coupled to a frame and each edge can be independently raised or lowered by a respective piston. Also, the base of the frame can pivot along one of its edges to provide a second degree of freedom of motion to the top flat carrier in dipping the PWBs relative to the solder bath, thereby providing a solder machine with a relatively small footprint that nonetheless can achieve precise soldering of PWBs. | 07-16-2009 |
| 20110049222 | QUICK-LOADING SOLDERING APPARATUS - A quick-loading soldering apparatus for soldering PCBs comprises a rotatable deck which has a plurality of angularly spaced PCB work sites. While a first PCB work site is angularly positioned for pre-loading and pre-heating PCB components at a pre-loading station, a second PCB work site is angularly positioned for soldering pre-loaded PCB components at a soldering station. Correct rotation of the deck is ensured by a sensor mounted on the deck. If the rotation angle is correct, locator pins provided externally of the deck become actionable by an operator to register the deck prior to the PCB being soldered. | 03-03-2011 |
| 20110089224 | LEAD-FREE SOLDER - An inexpensive lead-free solder which prevents the occurrence of tin pest at extremely low temperatures and which has good wettability and impact resistance has a composition consisting essentially of, in mass %, Cu: 0.5-0.8%, Bi: at least 0.1% and less than 1%, Ni: 0.02-0.04%, and a remainder of Sn. | 04-21-2011 |
| 20120097734 | System and Method for Packaging Electronic Devices - In accordance with particular embodiments, a method for packaging electronic devices includes melting solder for a solder jet. The method additionally includes depositing the melted solder from the solder jet in a pattern on a first substrate of a first component of an electronic device. The pattern comprises a plurality of individual dots of melted solder. The method also includes aligning a second substrate of a second component of the electronic device with the pattern deposited on the first substrate of the electronic device. The method further includes re-melting the solder deposited in the pattern on the first substrate. The method additionally includes, while the solder is re-melting, compressing the first and second substrates. | 04-26-2012 |
| 20130082092 | Curable Amine, Carboxylic Acid Flux Composition And Method Of Soldering - A curable flux composition is provided, comprising, as initial components: a resin component having at least two oxirane groups per molecule; a carboxylic acid; and, an amine fluxing agent represented by formula I: | 04-04-2013 |
| 20130126591 | Thermal Compress Bonding - A method includes providing a substrate carrier including work piece holders, and placing a first plurality of work pieces into the work piece holders. A second plurality of work pieces is picked up and placed, with each of the second plurality of work pieces being placed on one of the first plurality of work pieces. Solder bumps between the first and the second plurality of work pieces are then reflowed to simultaneously bond the first and the second plurality of work pieces together. | 05-23-2013 |
| 20130146646 | SEMICONDUCTOR LIGHT-EMITTING APPARATUS AND METHOD OF FABRICATING THE SAME - A light-emitting apparatus has a light-emitting device and a supporting board. The light-emitting device has a pair of n-electrodes with a p-electrode therebetween, on the same plane. The supporting board includes an insulating substrate on which positive and negative electrodes are formed, opposing to the p- and n-electrodes of the light-emitting device, respectively. Bonding members bond the p- and n-electrodes with the positive and negative electrodes, respectively. The positive electrode on the supporting board is formed within the width region of the p-electrode and narrower in width than the width of the p-electrode, in a cross-section along a line extending through the pair of n-electrodes. The negative electrodes oppose to the n-electrodes, respectively, with the same widths, or with that side face of each of the negative electrodes which faces the positive electrode being retracted outwardly from that side face of each of the n-electrodes which faces the p-electrode. | 06-13-2013 |
| 20130161376 | METHOD FOR ALIGNING PLATE-LIKE MEMBERS AND METHOD FOR MANUFACTURING ELECTRICAL CONNECTING APPARATUS - One plate-like member and the other plate-like member to be aligned with each other are provided with guide holes and guide portions to be received in the guide holes, respectively. The plate-like members are aligned appropriately, and in a state in which this alignment is held, the guide portions are formed on land portions provided on the other plate-like member so as to be aligned with the guide holes. Accordingly, regardless of presence/absence or size of a process error in the guide holes, the guide portions appropriate to the respective guide holes can be formed. Consequently, by aligning the guide portions with the guide holes, the plate-like members can be aligned appropriately without relative fine adjustment between the members. | 06-27-2013 |
| 20130186943 | ELECTRONIC DEVICE, CONDUCTIVE COMPOSITION, METAL FILLING APPARATUS, AND ELECTRONIC DEVICE MANUFACTURING METHOD - A method includes applying, between connection conductors of adjacent substrates, a junction material containing the first metal or alloy component and the second metal or alloy component having a higher melting point than said first metal or alloy component. The method further includes melting the junction material by a heat treatment. | 07-25-2013 |
| 20130186944 | MICROELECTRONIC SUBSTRATE OR ELEMENT HAVING CONDUCTIVE PADS AND METAL POSTS JOINED THERETO USING BOND LAYER - An interconnection element can include a substrate, e.g., a connection substrate, element of a package, circuit panel or microelectronic substrate, e.g., semiconductor chip, the substrate having a plurality of metal conductive elements such as conductive pads, contacts, bond pads, traces, or the like exposed at the surface. A plurality of solid metal posts may overlie and project away from respective ones of the conductive elements. An intermetallic layer can be disposed between the posts and the conductive elements, such layer providing electrically conductive interconnection between the posts and the conductive elements. Bases of the posts adjacent to the intermetallic layer can be aligned with the intermetallic layer. | 07-25-2013 |
| 20130206820 | SOLDER IN CAVITY INTERCONNECTION TECHNOLOGY - An interconnection technology may use molded solder to define solder balls. A mask layer may be patterned to form cavities and solder paste deposited in the cavities. Upon heating, solder balls are formed. The cavity is defined by spaced walls to keep the solder ball from bridging during a bonding process. In some embodiments, the solder bumps connected to the solder balls may have facing surfaces which are larger than the facing surfaces of the solder ball. | 08-15-2013 |
| 20130306712 | HOT PRESS DEVICE AND HOT PRESSING METHOD - A hot press device includes a spacing strip, a winding roller, a feeding roller and a hot press head. The spacing strip includes a metal layer and a resin layer stacked on the metal layer. The resin layer has a glass transition temperature of greater than | 11-21-2013 |
| 20140091131 | ASSEMBLY JIG FOR A SEMICONDUCTOR DEVICE AND ASSEMBLY METHOD FOR A SEMICONDUCTOR DEVICE - In aspects of the assembly jig and method of the invention, when a packaging substrate is curved concaving upward at temperatures of melting solder, the gap between the assembly jig and the packaging substrate can be made smaller than the dimension of the sum of the thickness of the semiconductor chip and the thickness of the melted solder by allowing a part of the bottom surface of the chip positioning piece to become always, or substantially always, in contact with the upper surface of the packaging substrate owing to the weight of the chip positioning jig itself. As a consequence, the semiconductor chip does not slip aside out of the opening of the chip positioning piece. Therefore, the semiconductor chip can be positioned accurately on the packaging substrate. | 04-03-2014 |
| 20140209666 | 3D ASSEMBLY FOR INTERPOSER BOW - A method for packaging a semiconductor device includes attaching a first array of solder material to a first surface of an interposer; bringing the first array of solder material into physical contact with a laminate; and initially bonding the interposer to the laminate by applying a first temperature and pressure gradient to the first array of solder material such that a melting temperature of the first array of solder material is not exceeded. | 07-31-2014 |
| 20140263583 | Two-Step Direct Bonding Processes and Tools for Performing the Same - A method includes placing a plurality of first package components over second package components, which are included in a third package component. First metal connectors in the first package components are aligned to respective second metal connectors of the second package components. After the plurality of first package components is placed, a metal-to-metal bonding is performed to bond the first metal connectors to the second metal connectors. | 09-18-2014 |
| 20150008254 | BOND HEADS FOR THERMOCOMPRESSION BONDERS, THERMOCOMPRESSION BONDERS, AND METHODS OF OPERATING THE SAME - A bond head for a thermocompression bonder is provided. The bond head includes a tool configured to hold a workpiece to be bonded, a heater configured to heat the workpiece to be bonded, and a chamber proximate the heater. The chamber is configured to receive a cooling fluid for cooling the heater. | 01-08-2015 |
| 20150048148 | Electromagnetic Field Assisted Self-Assembly With Formation Of Electrical Contacts - A method and apparatus for self-assembling a part on a substrate are disclosed herein. In some embodiments, a method includes placing a substrate having a first binding site capable of generating a first magnetic field and having a first shaped surface with a first droplet conformably disposed thereon into a first fluid; placing a part having a second binding site capable of generating a second magnetic field and having a second shaped surface with a second droplet conformably disposed on the second shaped surface into the first fluid; and attracting the part towards the first binding site such that an equilibrium is formed between an attractive force and a repulsive force such that the part is free to rotate about the first binding site to minimize the repulsive force when the first and second shaped surfaces rotate into an alignment causing the part to aligned with the first binding site. | 02-19-2015 |
| 20150298232 | METHOD FOR PRE-SOLDERING METAL SURFACES ONTO METALIZED SUBSTRATES USING A METALLIC GAUZE, METALIZED SUBSTRATES WITH A SOLDER LAYER WHICH HAS A SUPERFICIAL STRUCTURE OF A GAUZE - A method for pre-soldering metal surfaces onto metallized substrates (1 | 10-22-2015 |
| 20150313024 | SURFACE MOUNT DEVICE AND METHOD OF MANUFACTURING THE SAME - Disclosed is a surface mount device to be mounted on a base member, including plural lead units, each of the plural lead units including, a lead including a body portion and a foot formed at an end of the lead; a solder portion formed at the foot of the lead to protrude toward the direction of the base member to have a summit portion, and a diffusion prevention portion provided on the lead for preventing a diffusion of a solder along the body portion of the lead. | 10-29-2015 |
| 20150373856 | METHOD FOR FORMING BUMPS AND SUBSTRATE INCLUDING THE BUMPS - A method for forming bumps and a substrate including the bumps. The method includes: coating a solder resist on a substrate and electrodes formed on the substrate: performing laser etching treatment on the solder resist to form openings for forming bumps; printing a composition for forming bumps in the openings for forming bumps; and performing a reflowing process. Accordingly, the method can decrease the number of processes and realize a fine bump pitch of 90 μm or less at the time of forming bumps. Further, the method can also decrease the number of times that alignment is performed, due to the decrease in the number of processes. | 12-24-2015 |
| 20150382480 | THERMOCOMPRESSION BONDERS, METHODS OF OPERATING THERMOCOMPRESSION BONDERS, AND INTERCONNECT METHODS FOR FINE PITCH FLIP CHIP ASSEMBLY - A thermocompression bonder is provided. The thermocompression bonder includes: a bond head including a heated bonding tool for bonding a semiconductor element to a substrate; and a flux application tool for applying a flux material to conductive contacts of the substrate prior to bonding of the semiconductor element to the substrate. | 12-31-2015 |
| 20160044796 | METHOD FOR PRODUCING A MODULE - A method includes applying solder pastes separately to first and second portions of the first member; bringing the solder paste applied to the first portion of the first member and a first portion of the second member into contact with each other, and bringing the solder paste applied to the second portion of the first member and a second portion of the second member into contact with other; and causing the solder paste brought into contact with the first portion of the second member and the solder paste brought into contact with the second portion of the second member to melt. In the melting, molten solder formed by melting the solder paste brought into contact with the first portion of the second member and molten solder formed by melting the solder paste brought into contact with the second portion of the second member are joined to each other. | 02-11-2016 |
| 20160254245 | BOND HEAD ASSEMBLIES, THERMOCOMPRESSION BONDING SYSTEMS AND METHODS OF ASSEMBLING AND OPERATING THE SAME | 09-01-2016 |
| 228180210 | Component terminal to substrate surface (i.e., nonpenetrating terminal) | 44 |
| 20080217384 | ELLIPTIC C4 WITH OPTIMAL ORIENTATION FOR ENHANCED RELIABILITY IN ELECTRONIC PACKAGES - An arrangement for the equipping of electronic packages with elliptical C4 connects possessing optimal orientation for enhanced reliability. Furthermore, disclosed is a method providing elliptical C4 connects which possesses optimal orientation for enhanced reliability, as implemented in connection with their installation in electronic packages. Employed are essentially elliptical solder pads or elliptical C4 pad configurations at various preferably corner locations on a semiconductor chip. | 09-11-2008 |
| 20090134205 | Soldering Method, Method for Manufacturing Semiconductor Module, and Soldering Apparatus - A soldering method for soldering an electronic component to a circuit board is disclosed. The soldering method includes placing the electronic component on the bonding portion of the circuit board with solder arranged between the electronic component and the bonding portion, placing a weight on the electronic component, and heating and melting the solder while pressing the electronic component toward the circuit board with the weight. The weight is spaced from the electronic component while the temperature of the solder is still high after the melted solder wets the bonding portion and the bonding surface of the electronic component and spreads out therebetween. | 05-28-2009 |
| 20110121059 | ELECTRICAL BOND CONNECTION SYSTEM - An electrical bond connection system between a first electrical contact surface and a second electrical contact surface having at least one first electrical conductor, which is bonded to at least one of the contact surfaces via at least one first bond connection. At least one additional second electrical conductor ( | 05-26-2011 |
| 20110272452 | SYSTEM FOR DISPENSING SOFT SOLDER FOR MOUNTING SEMICONDUCTOR CHIPS USING MULTIPLE SOLDER WIRES - An apparatus for dispensing solder onto a substrate for mounting a semiconductor chip on the substrate comprises a dispensing body and first and second dispensing channels extending through the dispensing body. Each dispensing channel is operative to receive a separate solder wire to feed the solder wire to an end of the dispensing body facing the substrate. The dispensing channels are further operative to introduce the solder wires in a solid state simultaneously from the end of the dispensing body to be melted upon contact with the substrate which is heated. | 11-10-2011 |
| 20120305632 | LOW VOID SOLDER JOINT FOR MULTIPLE REFLOW APPLICATIONS - A method is provided for the forming of a metallic solder joint without a liquid flux to create a solder joint that has minimal voids and can be reflowed multiple times without void propagation. This process can be done for any solder alloy, and is most specifically used in the application of first level thermal interface in a IC or micro processor or BGA microprocessor. | 12-06-2012 |
| 20120318852 | METHOD OF PREVENTING EMI FOR A FASTENING HOLE IN A CIRCUIT BOARD AND A FIXTURE THEREFOR - A method of preventing EMI for a fastening hole in a circuit board includes the steps of providing a circuit board which includes a plurality of fastening holes extending through opposite first and second surfaces thereof and a plurality of solder pads disposed on the second surface, each fastening hole being surrounded by the solder pads; disposing an electronic component on the first surface; positioning the circuit board on a fixture such that the solder pads are not covered by the fixture; and wave soldering the circuit board so that the electronic component is fixed to the circuit board and the solder pads are attached with solder materials. | 12-20-2012 |
| 20130240610 | SOLDER PASTE TRANSFER PROCESS - A solder paste transfer process is provided and includes defining multiple arrangements of solder pad locations on a surface, applying solder paste onto multiple transfer tools coupled to a fixture in a pre-defined configuration reflective of the multiple arrangements, disposing the fixture such that the multiple transfer tools are disposed in an inverted orientation proximate to the surface and reflowing the solder paste to flow from the multiple transfer tools to the solder pad locations. | 09-19-2013 |
| 20140124566 | FLIP CHIP ASSEMBLY APPARATUS EMPLOYING A WARPAGE-SUPPRESSOR ASSEMBLY - A flip chip assembly apparatus includes at least one warpage-suppressor assembly. Each warpage-suppressor assembly can include a side heater, a deformable material pad, and an actuator assembly for moving the side heater and the deformable material pad. Each side heater provides additional heat to peripheral solder balls during bonding of two substrates, thereby facilitating the reflow of the peripheral solder balls. Each deformable material pad contacts, and presses down on, a surface of one of the two substrates under bonding. The deformable material pad(s) can prevent or minimize warpage of the contacted substrate. | 05-08-2014 |
| 20140217156 | JOINING METHOD AND SEMICONDUCTOR DEVICE MANUFACTURING METHOD - A joining method that allows joining processing to be carried out simultaneously at a plurality of portions without being influenced by a supply time restriction on a joining material, and a semiconductor device manufacturing method using the joining method are provided. A chip and a lead frame are tentatively assembled having a solid solder block interposed therebetween. The solder block is provided with protruding parts that protrude in one direction. The protruding parts are inserted into solder supply ports of the lead frame, whereby the chip and the lead frame are tentatively assembled. Subsequently, the chip and the lead frame are fed into a reflow oven, and the solder block is melted and thereafter solidified. Thus, the chip and the lead frame are joined to each other. | 08-07-2014 |
| 20160008904 | DEVICE FOR THERMAL MANAGEMENT OF SURFACE MOUNT DEVICES DURING REFLOW SOLDERING | 01-14-2016 |
| 20160027933 | Soldering System - This disclosure relates to a soldering system containing a soldering apparatus and a heating apparatus. The soldering apparatus includes a heating plate having a body defining a plurality of first air exits, each first air exit extending through the body of the heating plate and the heating plate being configured to supply hot air through the first air exits; a cover disposed on the heating plate, the cover and the heating plate defining a hot air chamber; a plurality of axially movable positioning shafts extending though the body of the heating plate, in which each shaft has a first end and a second end, the first end is in the hot air chamber, and the second end is outside the hot air chamber; and a conduit attached to the cover, the conduit being configured to supply hot air to the hot air chamber. | 01-28-2016 |
| 20160066435 | FORMING A SOLDER JOINT BETWEEN METAL LAYERS - Forming a solder joint between metal layers by preparing a structure having solder material placed between two metal layers and heating the structure to grow an intermetallic compound in a space between the two metal layers. Growing the intermetallic compound includes setting a first surface, in contact with the solder material between the two metal layers, to a first temperature, thereby enabling growth of the intermetallic compound; setting a second surface, in contact with the solder material between the two metal layers, to a second temperature, wherein the second temperature is higher than the first temperature; and maintaining a temperature gradient (temperature/unit thickness) between the two metal layers at a predetermined value or higher until the intermetallic compound substantially fills the space between the two metal layers. | 03-03-2016 |
| 228180220 | Lead-less (or "bumped") device | 32 |
| 20080197173 | Method for Forming Solder Bump and Method for Mounting Semiconductor Device - [Problem] To provide a method for forming solder bumps for realizing high density mounting and a highly reliable method for mounting a semiconductor device. | 08-21-2008 |
| 20090020591 | CONDUCTIVE BALL MOUNTING METHOD - There is provided a method of mounting one conductive ball on each of a plurality of connection pads on a substrate. The method includes: (a) providing a pre-alignment base including: a support layer formed to allow a flux to pass therethrough; and an alignment layer provided on the support layer and having pockets for containing the conductive ball; (b) applying a paste containing the conductive balls dispersed in the flux onto the alignment layer such that each of the pockets receives one of the conductive balls together with the flux; (c) aligning the pre-alignment base with the substrate such that each of the pockets corresponds to one of the connections pads; and (d) transferring the paste contained in each of the pockets onto the connection pads, thereby mounting the conductive balls along with the flux on the connection pads. | 01-22-2009 |
| 20090026247 | APPARATUS AND METHOD OF MOUNTING CONDUCTIVE BALL - There is provided a conductive ball mounting apparatus for mounting one conductive ball on each of a plurality of connection pads formed on a substrate. The conductive ball mounting apparatus includes: an outer frame; an inner cylinder provided in the outer frame, wherein an upper surface and a lower surface of the inner cylinder are opened; a sieve provided in the inner cylinder, wherein the inner cylinder is partitioned into an upper space and a lower space by the sieve; an inlet port for supplying an air from an outside to the lower space of the inner cylinder; a mask provided to a lower end of the outer frame and having openings, the openings being provided to correspond to conductive ball mounting positions; and an exhaust port for exhausting an air from an upper surface of the mask to the outside and being provided to the lower end of the outer frame, wherein the inner cylinder is adapted to vibrate without being restricted by the outer frame. | 01-29-2009 |
| 20090050678 | METHOD FOR MOUNTING ELECTRONIC PARTS - When a surface-mount electronic part, which includes at least two mounting electrodes on an external underside thereof, is bonded to circuit terminals on a wiring board using solder, a protrusion, which is thicker than the circuit terminal, is provided on a surface of the wiring board facing the outer bottom surface of the electronic part to have the clearance between the mounting electrode and the circuit terminal that is not smaller than a predetermined value, so that the thickness of the solder between the mounting electrode and the circuit terminal is maintained to be large. | 02-26-2009 |
| 20090289101 | METHOD FOR BALL GRID ARRAY (BGA) SOLDER ATTACH FOR SURFACE MOUNT - A method is provided for solder reflow which includes the steps of providing a receptacle having receptacle pads formed on an upper surface and placing a component on the receptacle, the component having a ball grid array of solder balls attached thereto. The component is placed on the receptacle in a manner which aligns the solder balls with the receptacle pads on the receptacle. The method further includes the steps of placing a weight having a predetermined size and a predetermined mass on top of the component to form a stack of the receptacle, the component and the weight, and reflowing the stack to attach the component to the receptacle by exposing the stack to high temperature to reflow the solder balls. | 11-26-2009 |
| 20100147928 | METHOD FOR THE MANUAL PLACEMENT OF BOTTOM TERMINATED LEADLESS DEVICE ELECTRONIC PACKAGES USING A MATED STENCIL PAIR - The present invention relates to a process for the rework of bottom terminated leadless devices as well as a pair of stencils for the manual reattachment of such devices (commonly known as a QFN, LGA or MLF packages). This process is used to remount these devices once they have been removed from the printed circuit board or placing new devices on an already populated PCB. It is also used to add bumps to the bottom side of an electronic device package or pads. | 06-17-2010 |
| 20100320258 | METHOD FOR MANUFACTURING SEMICONDUCTOR DEVICE - In one embodiment, a first substrate having first solder bumps and a second substrate having second solder bumps are stacked while temporarily tacking the solder bumps to each other, and then a stack is disposed inside a furnace. The gas in the furnace is exhausted to be in a reduced pressure atmosphere, and then a carboxylic acid gas is introduced into the furnace. While increasing a temperature inside the furnace where the carboxylic acid gas is introduced, the gas in the furnace is exhausted to be in a reduced pressure atmosphere at a temperature in a range from a reduction temperature of oxide films by the carboxylic acid gas to lower than a melting temperature of the solder bumps. By increasing the temperature inside the furnace up to a temperature in a range of the melting temperature of the solder bumps and higher, the first solder bumps and the second solder bumps are melted and joined. | 12-23-2010 |
| 20110031300 | CLEANING-FREE ACTIVATED RESINOUS COMPOSITION AND METHOD FOR SURFACE MOUNTING USING THE SAME - Activated resinous composition contains, on the basis of epoxy resin being solid at a room temperature of 100 parts by weight, carboxylic acid compound of 1 to 10 parts by weight, hardening agent of 1 to 30 parts by weight, a hardening reaction initiation temperature of said hardening agent being 150° C. or higher, and solvent of 10 to 300 parts by weight. | 02-10-2011 |
| 20110226841 | ROOM TEMPERATURE DIRECT METAL-METAL BONDING - A method for forming direct metal-metal bond between metallic surfaces is disclosed. The method comprises depositing a first nanostructured organic coating ( | 09-22-2011 |
| 20110240717 | COMPONENT MOUNTING METHOD AND DEVICE MANUFACTURED USING THE SAME - The present invention provides technology for mounting components with simple processing and with comparatively high dimensional precision. Welding sections ( | 10-06-2011 |
| 20120018498 | PRE-SOLDER METHOD AND REWORK METHOD FOR MULTI-ROW QFN CHIP - A pre-solder method for a multi-row quad flat no-lead (QFN) packaged chip is provided. Solder paste is applied on at least one pad of the multi-row QFN packaged chip. The multi-row QFN packaged chip is heated, such that the solder paste on the at least one pad of the multi-row QFN packaged chip becomes solid solder before the multi-row QFN packaged chip is mounted on a substrate. | 01-26-2012 |
| 20120104076 | JOINING METHOD AND DEVICE PRODUCED BY THIS METHOD AND JOINING UNIT - A practical bonding technique is provided for solid-phase room-temperature bonding not requiring a profile irregularity of the order of several nanometers, in which a high-vacuum energy wave treatment and continuous high-vacuum bonding are not required. Since an adhering substance layer is thin immediately after a surface activating treatment using an energy wave, a bonding interface is spread by crushing the adhering substance layer to perform bonding, so that a new surface appears on a bonding surface, and objects to be bonded are bonded together. In order to crush the adhering substance layer more easily, a bonding metal of a bonding portion of the object to be bonded requires a low hardness. According to the results of various experiments conducted by the present inventors, it was found that the hardness of the bonding portion which is a Vickers hardness of 200 Hv or less is particularly effective for room-temperature bonding. | 05-03-2012 |
| 20120118939 | PROCESS AND APPARATUS FOR MANUFACTURING SEMICONDUCTOR DEVICE - The process for manufacturing the semiconductor device and the apparatus, which achieve stable production of semiconductor devices with improved connection reliability, is presented. First terminals of circuit boards | 05-17-2012 |
| 20120318853 | HEATER BLOCK FOR WIRE BONDING SYSTEM - A heater block for a wire bonding system includes a mounting base configured to receive a lead frame and a semiconductor die mounted on the lead frame. A heating structure is removably coupled to a top surface of the mounting base. The heating structure includes a central heating surface and side heating panels surrounding the central heating surface. The heating structure selectively heats wire bonding areas of the lead frame. | 12-20-2012 |
| 20120318854 | THERMALLY DECOMPOSABLE POLYMER COMPOSITIONS INCORPORATING THERMALLY ACTIVATED BASE GENERATORS - Embodiments in accordance with the present invention provide sacrifical polymer compositions and methods for fabricating electronic devices using such sacrifical polymer compositions where such methods include (1) providing a tacky sacrifical polymer composition that holds components in a desired alignment to one another, (2) providing solder fluxing for effecting electrical coupling; and (3) thermal decomposition or depolymerization of the sacrificial polymer composition to provide essentially residue free surfaces. | 12-20-2012 |
| 20130105559 | CONDUCTIVE SIDEWALL FOR MICROBUMPS | 05-02-2013 |
| 20130153645 | Process for Hybrid Integration of Focal Plane Arrays - A method for aligning a first substrate relative to a second substrate by enabling reflow of low-melting-temperature solder bumps is disclosed. Reflow of the solder bumps induces a force that moves one substrate relative to the other to improve alignment accuracy between bond pads located on each substrate. The method further enables reduction of surface oxide on the solder bumps that would otherwise inhibit reliable solder joint formation. | 06-20-2013 |
| 20130200135 | COMPOSITION AND METHODS OF FORMING SOLDER BUMP AND FLIP CHIP USING THE SAME - Provided are a composition for an anisotropic conductive adhesive, a method of forming a solder bump and a method of forming a flip chip using the same. The composition for an anisotropic conductive adhesive includes a low melting point solder particle and a thermo-curable polymer resin. The anisotropic conductive adhesive includes forming a mixture by mixing a polymer resin and a curing agent, and mixing a deforming agent, a catalyst or a reductant with the mixture. | 08-08-2013 |
| 20130270329 | 3D Packaging With Low-Force Thermocompression Bonding Of Oxidizable Materials - Methods and systems for low-force, low-temperature thermocompression bonding. The present application teaches new methods and structures for three-dimensional integrated circuits, in which cold thermocompression bonding is used to provide reliable bonding. To achieve this, reduction and passivation steps are preferably both used to reduce native oxide on the contact metals and to prevent reformation of native oxide, preferably using atmospheric plasma treatments. Preferably the physical compression height of the elements is set to be only enough to reliably achieve at least some compression of each bonding element pair, compensating for any lack of flatness. Preferably the thermocompression bonding is performed well below the melting point. This not only avoids the deformation of lower levels which is induced by reflow techniques, but also provides a steep relation of force versus z-axis travel, so that a drastically-increasing resistance to compression helps to regulate the degree of thermocompression. | 10-17-2013 |
| 20140061285 | CONNECTION VERIFICATION TECHNIQUE - Some embodiments of the present invention are generally directed to testing connections of a memory device to a circuit board or other device. In one embodiment, a memory device that is configured to facilitate continuity testing between the device and a printed circuit board or other device is disclosed. The memory device includes a substrate and two connection pads that are electrically coupled to one another via a test path. A system and method for testing the connections between a memory device and a circuit board or other device are also disclosed, as are additional techniques for detecting excess temperature and enabling special functionalities using multi-stage connection pads. | 03-06-2014 |
| 20140069989 | Thin Semiconductor Chip Mounting - The embodiments of the invention provide a semiconductor chip mounting methods to prevent the occurrence of particles created while mounting a thin semiconductor chip onto a substrate. A semiconductor chip having conductive bumps on its main surface is held by its back via an elastic film using a suction tool having a plurality of suction holes, the semiconductor chip is positioned against a substrate provided with connection wires corresponding to said conductive bumps, and the semiconductor chip is mounted onto the substrate in such a manner that the conductive bumps connect to said connection wires, and uniform pressure is applied from the oversized bonding tool suction to the semiconductor chip via said film while said semiconductor chip is being pressed against said substrate by oversized bonding tool to keep constant pressure in order to bond said conductive bumps with said connection wires. The film assisted bonding tool has a film cooling system to assist in making vacuum holes and a through-hole tool movable relative to the bonding head to create a plurality of holes in said assist film with a plurality of needles. | 03-13-2014 |
| 20140231492 | ELECTRONIC COMPONENT MOUNTING METHOD, ELECTRONIC COMPONENT PLACEMENT MACHINE, AND ELECTRONIC COMPONENT MOUNTING SYSTEM - Disclosed is an electronic component mounting method including the steps of: providing a first electronic component having a principal surface provided with a plurality of bumps; providing a substrate having a plurality of first electrodes corresponding to the plurality of bumps; applying flux to the plurality of bumps; placing the first electronic component on the substrate such that the bumps land on the corresponding first electrodes via the flux; dispensing a thermosetting resin to at least one reinforcement position on the substrate with the first electronic component placed thereon, the at least one reinforcement position corresponding to a peripheral edge portion of the first electronic component; and heating the substrate with the first electronic component placed thereon, to melt the bumps and cure the thermosetting resin, followed by cooling, thereby to join the first electronic component to the substrate. | 08-21-2014 |
| 20140246481 | BONDING STRUCTURE MANUFACTURING METHOD, HEATING AND MELTING TREATMENT METHOD, AND SYSTEM THEREFOR - A soldering method capable of alleviating positional displacement between substrates even though a step of removing flux can be omitted is provided. | 09-04-2014 |
| 20140263585 | METHOD FOR FORMING INTERPOSERS AND STACKED MEMORY DEVICES - Methods for forming a stacking interposer are provided that create a more compact and/or reliable interposer cavity. According to one method, a segmentation process that partially cuts a multi-cell, multi-layer PCB panel to a controlled depth along the internal walls/edges of a cavity region with each of the interposer cell sites defined within the PCB panel is used. The material within the cavity region is then removed (by routing) to a controlled depth to form the internal cavity for each interposer cell site. Pillars may then be removed from the PCB panel. As a result of the initial partial cuts of the internal walls of the cavity region, the corners of the cavities may have a square configuration for fitting over the top of a BGA/memory device (which has very square corners). | 09-18-2014 |
| 20140319200 | METHOD OF MOUNTING ELECTRONIC PART, CIRCUIT SUBSTRATE, AND IMAGE FORMING APPARATUS - The circuit substrate includes at least two lands formed on a substrate, wherein one electrode is to be mounted on the at least two lands, an electronic part having electrodes, one of the electrodes is soldered on the at least two lands with solders whose amounts are adjusted by a metal mask having at least two opening parts, positions of the at least two opening parts corresponding to the at least two lands when the solders are applied and melted, areas of the at least two opening parts being different with each other, wherein a height of one of the solders is different from a height of the other of the solders according to the difference of the areas of the at least two opening parts of the metal mask, whereby the electronic part is mounted on the circuit substrate in an inclined state. | 10-30-2014 |
| 20150060527 | NON-UNIFORM HEATER FOR REDUCED TEMPERATURE GRADIENT DURING THERMAL COMPRESSION BONDING - Embodiments of a method for performing a thermal compression bonding process with a non-uniform temperature pattern and a heater having the non-uniform temperature pattern are disclosed. In some embodiments, the heater includes a plurality of heating element segments configured to generate the non-uniform temperature pattern. The configuration comprises a plurality of heating element segment densities or a plurality of heating element segment resistances. | 03-05-2015 |
| 20150108204 | INTEGRATED CIRCUIT PACKAGE WITH SPATIALLY VARIED SOLDER RESIST OPENING DIMENSION - An integrated circuit (IC) package stack with a first and second substrate interconnected by solder further includes solder resist openings (SRO) of mixed lateral dimension are spatially varied across an area of the substrates. In embodiments, SRO dimension is varied between at least two different diameters as a function of an estimated gap between the substrates that is dependent on location within the substrate area. In embodiments where deflection in at least one substrate reduces conformality between the substrates, a varying solder joint height is provided from a fixed volume of solder by reducing the lateral dimensioning of the SRO in regions of larger gap relative to SRO dimensions in regions of smaller gap. In embodiments, the first substrate may be any of an IC chip, package substrate, or interposer while the second substrate may be any of another IC chip, package substrate, interposer, or printed circuit board (PCB). | 04-23-2015 |
| 20150115020 | SOLDER BUMP, METHOD FOR FORMING A SOLDER BUMP, SUBSTRATE PROVIDED WITH SOLDER BUMP, AND METHOD FOR MANUFACTURING SUBSTRATE - Provided is a solder bump forming method capable of forming solder bumps having a desired constant thickness, without any failure such as copper corrosion, on a mounting board such as a printed circuit board having fine copper electrodes. The solder bump forming method includes: a process in which a prepared mask ( | 04-30-2015 |
| 20150357304 | FLIP CHIP ASSEMBLY AND PROCESS WITH SINTERING MATERIAL ON METAL BUMPS - A method is disclosed of fabricating a microelectronic package comprising a substrate overlying the front face of a microelectronic element. A plurality of metal bumps project from conductive elements of the substrate towards the microelectronic element, the metal bumps having first ends extending from the conductive elements, second ends remote from the conductive elements, and lateral surfaces extending between the first and second ends. The metal bumps can be wire bonds having first and second ends attached to a same conductive pad of the substrate. A conductive matrix material contacts at least portions of the lateral surfaces of respective ones of the metal bumps and joins the metal bumps with contacts of the microelectronic element. | 12-10-2015 |
| 20150380381 | FLIP CHIP BONDER AND FLIP CHIP BONDING METHOD - Provided is a flip chip bonder including: a pickup flipping collet configured to flip a chip; and a bonding tool configured to receive the chip flipped with the pickup flipping collet from the pickup flipping collet and to bond the received chip to a circuit board. The pickup flipping collet includes a cooling channel through which cooling air flows to cool the pickup flipping collet. Thus, bonding time can be reduced without lowering bonding quality. | 12-31-2015 |
| 20160005711 | SEMICONDUCTOR CHIP ASSEMBLY AND METHOD FOR MAKING SAME - A microelectronic assembly may include a substrate including a rigid dielectric layer having electrically conductive elements, a microelectronic element having a plurality of contacts exposed at a face thereof, and conductive vias extending through a compliant dielectric layer overlying the rigid dielectric layer. The vias electrically connect the substrate contacts respectively to the conductive elements, and the substrate contacts are joined respectively to the contacts of the microelectronic element. The vias, compliant layer and substrate contacts are adapted to appreciably relieve stress at the substrate contacts associated with differential thermal contact and expansion of the assembly. | 01-07-2016 |
| 20160079200 | APPARATUS AND METHOD FOR MANUFACTURING SEMICONDUCTOR DEVICE - A manufacturing apparatus of a semiconductor device includes a stage, a head unit configured to face the stage, a driving unit configured to move the head unit towards and away from the stage, a heating unit configured to heat the head unit, and a control unit configured to control the driving unit to move the head unit away from the stage when the heating unit heats the head unit. | 03-17-2016 |
