Abstract: A mold die includes: a mold die body that is configured to hold an object to be molded, the object including a substrate and a chip mounted in a central area of the substrate, and that has a cavity which is rectangular in a plan view and which is configured to receive a resin material, the mold die body including: a pot for containing the resin material; a gate disposed at one side of the cavity and configured to allow the resin material to flow into the cavity; and a flow-path restricting mechanism that is disposed on both lateral sides of the cavity that are perpendicular to the one side and that is configured to narrow lateral flow paths, the lateral flow paths being flow paths for the resin material flowing through the cavity in which the chip is not disposed.

Abstract: In a first step, a circuit sheet is set such that a first region of a second main surface of the circuit sheet is in contact with a plateau portion of a first mold and a second region is not in contact with the first mold. In the first step, a first fixed portion of the circuit sheet is arranged on a first portion of the first mold, and a second fixed portion is arranged on a second portion of the first mold. The first portion is a portion that is higher than the plateau portion and runs along at least one of a first protruding portion and a second protruding portion provided along the plateau portion. The second portion is a portion where the first protruding portion or the second protruding portion is not provided along the plateau portion.

Abstract: A semiconductor device includes a semiconductor element, first and second leads, and a sealing resin. The semiconductor element includes first and second electrodes. The first lead includes a mounting base having a main face to which the first electrode is bonded and a back face, and includes a first terminal connected to the first electrode. The second lead includes a second terminal connected to the second electrode. The sealing resin includes a main face and a back face opposite to each other, and includes an end face oriented in the protruding direction of the terminals. The back face of the mounting base is exposed from the back face of the resin. The sealing resin includes a groove formed in its back face and disposed between the back face of the mounting base and a boundary between the second terminal and the end face of the resin.

Abstract: A method for producing an injection-moulded plastic component made of a plastic having at least one recess for accommodating sensors, having the following steps: producing the injection-moulded plastic component in a mould having top and bottom mould halves; raising the top mould half and introducing a thermoregulatable ram which is guided in a sleeve; placing the sleeve with integrated annular space on the surface of the injection-moulded component, to form an annular bead in the annular space; pressing the thermoregulated ram into the surface of the injection-moulded component; and cooling the ram and raising it from the surface.

Abstract: Provided is an apparatus for attaching semiconductor parts. The apparatus includes a substrate loading unit, at least one semiconductor part loader, a first vision examination unit, at least one semiconductor part picker, at least one adhesive hardening unit, and a substrate unloading unit, wherein the substrate loading unit supplies a substrate on which semiconductor units are arranged, the at least one semiconductor part loader supplies semiconductor parts, the first vision examination unit examines arrangement states of the semiconductor units, the at least one semiconductor part picker mounts semiconductor parts in the semiconductor units, the at least one adhesive hardening unit hardens and attaches adhesives interposed between the semiconductor units and the semiconductor parts, and the substrate unloading unit releases the substrate on which semiconductor parts are mounted.

Abstract: A game token by which a plurality of RFID tags embedded in a plurality of the game tokens stacked each other can be read in a relatively stable manner is provided. A game token is provided with a security part and a receiving part that receives the security part. The security part has a shape with a diameter smaller than the diameter of the receiving part, a structure with a plurality of plastic layers laminated together, an RFID tag, and a visible print layer indicating a type or ID of the game token. The receiving part has a surface. The surface of the receiving part has a recessed portion for receiving the security part, and the depth of the recessed portion is 25% or more of the thickness of the game token.

Abstract: Described embodiments provide a flat conductive fluid sensor cable capable of manufacture in long lengths comprising a flexible substrate, two or more flat conductors, and a fluid-permeable cover material arranged to allow a conductive fluid to form an electrically conductive path between the two or more conductors when conductive fluid contacts the conductive fluid sensor cable.

Abstract: A system and method for forming plastic sheet into a three-dimensional shape. The plastic sheet may include one or more sheet-mounted components, such as electronics, that must be shielded from excessive heat, pressure, and/or crushing when the formation of the sheet occurs. A recess will be formed to protect against directly contacting sheet-mounted component. The recess may be aligned along the heating plate and/or the form core and/or along a protective blanket which may be set over (and under) sheet prior to heating/forming. The sheet is registered (with or without a blanket) onto a base plate, and preferably over a form core. The sheet is then raised to contact with a heating plate, and then placed downward over the (optionally heated) form core. Recess(es) align in locations corresponding to mounted component to protect same.

Abstract: A method of preparing an overmolded optical fiber assembly comprising: (a) placing at least one flexible optical circuit in a bottom mold, said bottom mold defining a bottom overmold cavity having a bottom surface, said at least one flexible optical circuit having a substrate and a plurality of fibers adhered to said substrate, said substrate being disposed within said bottom overmold cavity to define a first space between said substrate and said bottom surface; (b) flowing a polymer in at least said first space; (c) placing a top mold over said substrate, said top mold defining a top overmold cavity and a top surface and a port defined in said top surface to access said top overmold cavity, said substrate defining a second space between said top surface and said substrate; (d) flowing a polymer in at least a portion of said second space; and (e) removing said bottom and top molds to release said overmolded optical circuit.

Abstract: A method of manufacturing a package unit, comprising: preparing a circuit board having a first region, a second region surrounding the first region, and a third region between the first and the second region; preparing a mold having a frame-shaped protruding portion surrounding a first cavity, the frame-shaped protruding portion partitioning the first cavity and a second cavity surrounding the first cavity; arranging the circuit board and the mold such that the first region of the circuit board faces the first cavity, the second region of the circuit board faces the second cavity, and a gap which communicates the first cavity and the second cavity with each other is formed between the frame-shaped protruding portion and the third region of the circuit board; and forming a frame-shaped resin member on top of the second region of the circuit board by pouring a resin into the second cavity.

Abstract: Provided is a silicone composition having components (A) to (E):100 parts by mass of (A) a linear, branched, or network organopolysiloxane having a vinyl value of 0.01 mol/100 g or more and 0.04 mol/100 g or less and a viscosity of 100 mm2/sec or more and 500 mm2/sec or less at 25° C., wherein each of terminals of the organopolysiloxane has one or more alkenyl groups; 0.01 to 3 parts by mass of (B) a linear, branched, or network organopolysiloxane having a vinyl value of 0.2 mol/100 g or more and 1.2 mol/100 g or less and a viscosity of 2 mm2/sec or more and 60 mm2/sec or less at 25° C., wherein each of terminals of the organopolysiloxane has one or more alkenyl groups; (C) an organohydrogenpolysiloxane having an amount of 1 mol/100 g or more and 2 mol/100 g or less of an SiH group, wherein a ratio of the number of the SiH group in component (C) to a total number of the alkenyl groups in components (A) and (B) is 1 to 5; 0.

Abstract: Provided are an imaging device that enables formation of a film over the entirety of a film formation region, a method of producing the imaging device, an imaging apparatus, and an electronic apparatus. The imaging device includes a sensor and a glass sheet bonded to a front surface of the sensor. The glass sheet includes a recess in a peripheral portion that is outside a film formation region over which an inorganic film is to be formed. The recess corresponds to a claw on a periphery of an opening of a tray for a vapor deposition process for the inorganic film. This allows the entirety of the film formation region of the glass sheet to be exposed from the opening when the imaging device is set in the opening, and thus enables formation of the inorganic film over the entirety of the film formation region.

Abstract: A process includes forming one or more apertures on a component backside, creating a vacuum in a mold chase, and engaging the component backside with a mold compound in the mold chase. The one or more apertures form an aperture structure. The aperture structure may include multiple apertures parallel or orthogonal to each other. The apertures have an aperture width, aperture depth, and aperture pitch. These characteristics may be altered to minimize the likelihood of trapped air remaining after creating the vacuum in the mold chase.

Abstract: An embedded-bridge substrate connector apparatus includes a patterned reference layer to which a first module and a subsequent module are aligned and the two modules are mated at the patterned reference layer. At least one module includes a silicon bridge connector that bridges to two devices, through the patterned reference layer, to the mated module.

Abstract: A die face monitoring system may include an upper die having an upper die face and an upper die opening extending towards the upper die face. Similarly, a lower die may include a lower die face and a lower die opening extending towards the lower die face. The lower die face is arranged to confront the upper die face and form a concavity therebetween. Furthermore, a plurality of sensors are mounted on a press, with each sensor corresponding to each one of the upper and lower die openings. Each sensor emits a beam of light towards and receives a reflection from a target surface within the upper and lower die openings in order to calculate a distance thereto.

Abstract: A semiconductor package includes a second leadframe assembly stacked above a first leadframe assembly, each leadframe assembly including a die pad, a plurality of leads and a semiconductor die attached to the die pad and electrically connected to the leads. A spacer separates the leadframe assemblies from one another. A single mold compound embeds part of the first leadframe assembly, part of the second leadframe assembly and the spacer. A portion of the leads of both leadframe assemblies are uncovered by the mold compound to form terminals of the semiconductor package. A side of both die pads is uncovered by the mold compound.

Abstract: A press machine includes a drive mechanism that moves at least one of an upper tool and a lower tool and machines a workpiece placed between the upper and lower tools. The drive mechanism includes a first drive source that rotates a screw shaft serving as an advance-retract component and a second drive source that rotates a nut connected to the screw shaft. A structure including the upper tool and lower tools includes a casing supporting the screw shaft such that the screw shaft is rotatable, a movable member that is movably formed in the casing and can contact an end of the screw shaft or retract therefrom, and a drive unit that moves the movable member.

Abstract: Embodiments of the present disclosure are directed to package assemblies and methods for fabricating package assemblies. In one embodiment, a package assembly includes a die at least partially embedded in a mold compound; and a through mold via (TMV). The TMV may have vertical sides or may include two different portions with varying shapes. In some instances, prefabricated via bars may be used during fabrication. Package assemblies of the present disclosure may include package-on-package (POP) interconnects having a pitch of less than 0.3 mm. Other embodiments may be described and/or claimed.

Abstract: A system for performing a direct transfer of a plurality of semiconductor die from a first substrate to a second substrate based on map data of the location of the semiconductor die. A first conveyance mechanism conveys the first substrate. A second conveyance mechanism conveys the second substrate. A transfer mechanism is disposed adjacent to the first conveyance mechanism to effectuate the direct transfer. A controller causes one or more processors to perform operations including: determining positions of the plurality of semiconductor die based at least in part on map data, conveying at least one of the first substrate or the second substrate such that the first substrate, the second substrate, and the transfer mechanism are in a direct transfer position, and activating the transfer mechanism to perform the direct transfer of the plurality of semiconductor die.

Abstract: An injection molding system is provided with inspection means for inspecting an insert part before a resin is injected into a mold, inspection data output means for outputting inspection data on the insert part obtained by the inspection means, and inspection data recording means for recording the inspection data on the insert part and physical quantities related to the injection of the resin into the mold in association with the cycle number of the molded article from the injection molding machine. Thus, the cause of bad molded articles, as well as that for a finished product, can be investigated in consideration of the inspection data on the insert part inserted into the mold.

Abstract: The reliability of a semiconductor device is improved. During resin injection in a molding step, in a plan view, a plurality of gates of a molding die are arranged at positions different from those over extended lines of a plurality of dicing regions and a resin is injected from the gates. In this way, it becomes possible to reduce entrainment of air in the dicing regions and to lower an occurrence rate of voids. As a consequence, it becomes possible to suppress an occurrence of poor appearance such as formation of voids in a sealing body and to suppress formation of a starting point of a crack which may occur during a reflow process. Thus, the reliability of the semiconductor device can be improved.

Abstract: The inventive concepts provide an apparatus for manufacturing a semiconductor package and a method for manufacturing a semiconductor package using the same. The apparatus includes a mold unit with a cavity formed by an inner space of the mold unit. The mold unit includes a first mold, a second mold coupled to the first mold, a supply part supplying a molding resin into the cavity, and a vent part disposed to be opposite to the supply part. The vent part includes a first vent part fixed in the mold unit, and a second vent part movable with respect to the first vent part.

Abstract: A semiconductor device manufacturing apparatus for encapsulating with a resin a semiconductor chip includes upper and lower molds configured to receive therebetween a lead frame on which the semiconductor chip is mounted. A positioning pin provided to the lower mold is configured to be received by a positioning hole provided in the lead frame. Ejector pins provided in proximity to the positioning pin are arranged so as to be symmetrical with respect to the positioning pin.

Abstract: A thermosetting resin composition for an underfilling of a semiconductor comprising, as essential components, a thermosetting resin, a curing agent, a flux agent and two or more inorganic fillers with different mean particle sizes, wherein the inorganic fillers include an inorganic filler with a mean particle size of no greater than 100 nm and an inorganic filler with a mean particle size of greater than 100 nm.

Abstract: A substrate having a plurality of protrusion members on its surface is molded by a molding system comprising first and second molds cooperating to apply a clamping force onto the substrate for molding, and a middle plate located between the first and second molds such that the substrate is clamped between the middle plate and the first mold during molding. A plurality of molding cavities is located on the second mold and through-holes formed in the middle plate correspond to positions of the molding cavities, such that each through-hole is sized and configured for inserting a protrusion member of the substrate to enable each protrusion member to be in communication with a molding cavity of the second mold. Molding compound is molded onto the protrusion members by the molding cavities during molding.

Abstract: Inductive devices are disclosed. Multiple partial windings may be created relative to a core, where each of the partial windings is initially discontinuous. Multiple printed conductors may be created on a substrate, where the multiple printed conductors are arranged to electrically connect the multiple partial windings. The multiple partial windings may be electrically connected to the multiple printed conductors to create a complete winding around the core.

Abstract: A semiconductor device manufacturing apparatus for encapsulating with a resin a semiconductor chip. A lead frame on which the semiconductor chip is mounted is provided between an upper mold and a lower mold. A tapered positioning pin is provided to the lower mold and includes a columnar portion having an outer diameter larger than an inner diameter of a positioning hole provided at an upper surface of the lead frame and configured to receive the columnar portion of the tapered positioning pin. Ejector pins are disposed in proximity to the tapered positioning pin at a distance determined by a thickness of the lead frame. The ejector pins are arranged so as to be symmetrical with respect to the tapered positioning pin.

Abstract: An integrated circuit (IC) module with a lead frame micro-needle for a medical device, and methods of forming the IC module are described. The methods include forming a lead frame blank including a micro-needle integrally formed therein. The micro-needle may be bent beyond an initial lower side of the lead frame blank. The initial lower side may be joined with a protection layer such that the bent micro-needle is embedded in the protection layer, which may be removably attached to the initial lower side and the bent micro-needle. An IC component may be affixed to an upper side of the lead frame blank. The IC component and an upper surface of a core of the lead frame blank may be encapsulated with a molding compound forming a packaging of the IC module. Removal of the protection layer may expose the bent micro-needle projecting away from the packaging.

Abstract: A semiconductor package has a semiconductor chip, a lead frame in which a semiconductor chip is mounted on a die pad, and a resin sealing the semiconductor chip and the die pad from an upper surface and a lower surface, the resin has a concave portion disposed at the surface and a concave portion situated inside the concave portion in a plan view.

Abstract: An apparatus for fabricating a semiconductor package may include a mold and a molding plate. The mold may define a mold cavity with the mold being configured to receive a circuit board in the mold cavity, and the circuit board may include a semiconductor chip mounted thereon. A molding plate may be moveable in the mold cavity with the molding plate being configured to adjust a volume of the mold cavity. Related methods are also discussed.

Abstract: A system and method for a semiconductor molding chamber is disclosed. An embodiment comprises a top molding portion and a bottom molding portion that form a cavity between them into which a semiconductor wafer is placed. The semiconductor molding chamber has a first set of vacuum tubes which hold and fix the position of the semiconductor wafer and a second set of vacuum tubes which evacuate the cavity of extraneous ambient gasses. The encapsulant may then be placed over the semiconductor wafer in order to encapsulate the semiconductor wafer.

Abstract: Provided is a heat sink for a chip mounting substrate in which a heat dissipation material is embedded. The heat sink includes: an accommodation portion configured to accommodate a substrate whereon a chip is mounted or to be mounted, and support or fix the accommodated substrate; and a heat dissipation portion configured to insulate the accommodated substrate, and dissipate heat generated from the substrate or the chip mounted on the substrate to an outside through a heat dissipation material contained in the heat dissipation portion. Accordingly, since the heat sink for a chip mounting substrate in which a heat dissipation material is embedded is manufactured by injection molding, a manufacturing process can be simplified.

Abstract: A cured product exhibits good heat resistance and flame retardancy as well as low dielectric constant and low loss tangent. A phosphorus-containing compound (i) obtained by a reaction between an aromatic aldehyde (a1) having an alkoxy group as a substituent on a nucleus and an organic phosphorus compound (a2) having a P—H group or a P—OH group in a molecular structure is reacted with a phenolic substance (a3) to obtain a phosphorus-containing phenolic substance (A1). Then the phosphorus-containing phenolic substance (A1) is reacted with an aromatic dicarboxylic acid or an anhydride or dihalide of an aromatic dicarboxylic acid or a C2-6 saturated dicarboxylic acid or an anhydride or dihalide of a C2-6 saturated dicarboxylic acid (A2) so that all or some of hydroxyl groups of the phenolic substance (A1) form ester bonds.

Abstract: Device for identifying articles such as animals, comprising a male part and a female part, which male part comprises an arrow-shaped element and which female part is provided with a passage with a front end and a rear end, wherein the arrow-shaped element can be inserted into the passage along the front end, wherein the passage is provided close to the front end with at least one protruding element, and wherein the passage is partly closed close to the rear end by a closing part, wherein the partly closed passage, including the protruding element, are manufactured integrally from a hard material; method for manufacturing such a device.

Abstract: A method for fabricating an electronic assembly which enables the assembly and interconnection of surface mount components and/or other electrical, electronic, electro-optical, electro-mechanical and user interface devices with external I/O contacts on a planar surface without the use of solder or otherwise exposing the components to temperatures substantially above ambient.

Abstract: An article including a microelectronic substrate is provided as an article usable during the processing of the microelectronic substrate. Such article includes a microelectronic substrate having a front surface, a rear surface opposite the front surface and a peripheral edge at boundaries of the front and rear surfaces. The front surface is a major surface of the article. A removable annular edge extension element having a front surface, a rear surface and an inner edge extending between the front and rear surfaces has the inner edge joined to the peripheral edge of the microelectronic substrate. In such way, a continuous surface is formed which includes the front surface of the edge extension element extending laterally from the peripheral edge of the microelectronic substrate and the front surface of the microelectronic substrate, the continuous surface being substantially co-planar and flat where the peripheral edge is joined to the inner edge.

Abstract: A circuit board that is to be mounted in a connector socket includes a plurality of electrical connectors located along a side edge of the circuit board. Retention bosses are formed on first and second opposite sides of the circuit board, each of the retention bosses protruding from a surface of the circuit board and extending parallel to and adjacent to the first edge of the circuit board. When the first edge of the circuit board is inserted into a slot of a connector socket, contact surfaces of the first and second retention bosses contact top surfaces of the connector socket to help immobilize the circuit board with respect to the connector socket. Adhesive layers on the contact surfaces of the first and second retention bosses may adhere to the top surfaces of the connector socket to help hold the circuit board immobile with respect to the connector socket.

Abstract: An object of one embodiment of the present invention is to provide a more convenient highly reliable light-emitting device which can be used for a variety of applications. Another object of one embodiment of the present invention is to manufacture, without complicating the process, a highly reliable light-emitting device having a shape suitable for its intended purpose. In a manufacturing process of a light-emitting device, a light-emitting panel is manufactured which is at least partly curved by processing the shape to be molded after the manufacture of an electrode layer and/or an element layer, and a protective film covering a surface of the light-emitting panel which is at least partly curved is formed, so that a light-emitting device using the light-emitting panel has a more useful function and higher reliability.

Abstract: An electronic component includes a flexible printed circuit board which has a main body, a fixing portion and a connecting portion, and an insulating portion integrally molded to the fixing portion. In the process of the insulating portion being molded to the fixing portion, a filling mold fixture is sleeved around and spaced from outsides of the fixing portion. A method of manufacturing the electronic component is described hereinafter. Sleeve the filling mold fixture around the fixing portion and apart from the outsides of the fixing portion. Place the flexible printed circuit board together with the filling mold fixture in a mold. Inject liquid rubber into the filling mold fixture. Close the mold. Cool the electronic component and the filling mold fixture. Open the mold to take out the electronic component and the filling mold fixture, and then separate the filling mold fixture from the electronic component smoothly.

Abstract: Methods, apparatuses, and computer program products for forming an overmolded dual in-line memory module (DIMM) cooling structure are provided. Embodiments include identifying, by a tagging module, contextual information indicating circumstances in which the photograph was taken; based on the contextual information, selecting, by the tagging module, candidate profiles from a plurality of friend profiles associated with a profile of a user; and suggesting, by the tagging module to the user, the selected candidate profiles as potential friends to tag in the photograph.

Abstract: A semiconductor chip which is mounted on a wiring substrate and which is electrically connected to the wiring substrate is disposed in a sealing apparatus. A sealing resin material made of a thermosetting resin composition is supplied into the sealing apparatus. The sealing resin material contains a solid foreign matter having a cured product of a thermosetting resin, and includes particulates of the thermosetting resin composition pulverized with the solid foreign matter, a granulation powder of the particulates, or a preform of the particulates. The semiconductor chip is resin sealed by using the sealing resin material.

Abstract: A mold chase for packaging a semiconductor die includes first and second toothed mold clamps, each having teeth, recesses located between the teeth, and an open cavity located in a center of the first mold clamp. The second mold clamp is in facing arrangement with the first mold clamp and the teeth in the first mold clamp mate with corresponding recesses in the second mold clamp and vice-versa. In an open position a lead frame can be inserted into one of the first or second mold clamps and in a closed position, the teeth and recesses of the first and second mold clamps bend leads of the lead frame into two spaced, planar rows.

Abstract: The invention relates to a method for encapsulating electrical and/or electronic components in a housing, the components being arranged on a printed circuit or a strip conductor in an assembly. Said assembly is positioned in the housing and is encapsulated with a curing, electrically insulating molding compound. The method according to the invention is characterized by encapsulating preferably in a molding chamber at a pressure below atmospheric pressure and by removing the negative pressure after encapsulation and before curing.

Abstract: The method for filling a liquid material, and the apparatus and the program make it possible, without changing a moving speed of an ejection device, to correct a change in ejection amount and to stabilize an application shape. The method fills a liquid material into a gap between a substrate and a work by using the capillary action. The method includes the steps of: generating an application pattern consisting of a plurality of application areas continuous to one another; assigning a plurality of ejection cycles, each obtained by combining the number of ejection pulses and the number of pause pulses at a predetermined ratio therebetween, to each of the application areas; and measuring an ejection amount at correction intervals and calculating a correction amount for the ejection amount.

Abstract: An apparatus for fabricating a semiconductor package may include a mold and a molding plate. The mold may define a mold cavity with the mold being configured to receive a circuit board in the mold cavity, and the circuit board may include a semiconductor chip mounted thereon. A molding plate may be moveable in the mold cavity with the molding plate being configured to adjust a volume of the mold cavity. Related methods are also discussed.

Abstract: An apparatus for molding a semiconductor device includes an upper mold chase and a lower mold chase. The mold chases are capable of being aligned with each other, forming spaced cavities for receiving a lead frame array that includes semiconductor dies for encapsulation. The cavities are aligned in spaced, vertical columns and gates are provided at the opening of each column of cavities. A molding compound is passed through the gates and flows uninterrupted through each cavity and encapsulates the semiconductor dies.

Abstract: An apparatus for fabricating a semiconductor package may include a mold and a molding plate. The mold may define a mold cavity with the mold being configured to receive a circuit board in the mold cavity, and the circuit board may include a semiconductor chip mounted thereon. A molding plate may be moveable in the mold cavity with the molding plate being configured to adjust a volume of the mold cavity. Related methods are also discussed.

Abstract: A method for producing a magnetic field sensor for use in drive train of a motor vehicle includes encapsulating an electrical assembly and an end of a connecting cable via injection molding and integrally extruding a fastening tab. After a first injection step in which the electrical assembly and the connecting cable are encapsulated in a core-type first molded part, a second injection molding step in implemented in which a fastening tab is integrally formed via injection molding on the core-type insertion part in a specifiable longitudinal and/or angular position. The core-like insertion part is held in the injection mold in a longitudinally displaceable and/or rotatable manner.

Abstract: A method of making a semiconductor device comprising a semiconductor element and a support member having a recess for housing the semiconductor element is disclosed. The method includes placing at least two lead electrode portions in the molding die; supplying a molding member to the molding die so that the molding member contacts the portion of at least two lead electrode portions; heating the molding member in the molding die so as to cure the molding member into a package with the portion of at least two lead electrode portions; and removing the package from the molding die by a pushing member such that at least one of a protrusion and a recess are formed in a surface of the package. Using this process, a semiconductor device can be obtained with a high process yield.

Abstract: A device for providing the edge of a starting sheet of an electrode used in the electrolytic refining or recovery of metals with a dielectric part comprises a die space, in which the edge of the starting sheet of the electrode can at least partly be fitted, and a feeding device of the dielectric material for feeding the dielectric material into the die space. The device comprises changing members of the volume of the die space for pressing the dielectric material in the die space to that edge of the starting sheet of the electrode, which is at least partly fitted in the die space.