1. Field of the Invention
This invention relates to the field of surface mounted component handling, and particularly to methods and systems for holding, thermally attaching and detaching surface-mount components (SMCs) to and from substrates.
2. Description of the Related Art
Parts are often attached to other parts of equal or larger size using thermal processes. The parts of equal or larger size may be referred to as substrates. Thermal processes which may cause a part to attach to a substrate include gluing, soldering, bonding, brazing and welding.
The electronics industry, in particular, interconnects electrical device and integrated circuit chips called surface mounted components (SMCs) by thermally attaching their electrical input/output (I/O) leads to electrically conducting circuits on and within polymer and ceramic substrates.
One of the two most common interconnect structures is called a hybrid-circuit. This is usually comprised of SMCs interconnected by bonding their electrical I/O leads or electrodes to an electrically conducting circuit on a ceramic substrate. The metal of the I/O leads is caused to attach to the electrically conducting circuit by ultrasonic and thermal means.
The most common interconnect structure—and the one used to illustrate the methods and systems described herein—is comprised of surface-mount devices (SMDs) (any SMC with electrical I/O leads) interconnected by soldering their I/O leads to electrical circuits on a polymeric substrate called a printed circuit board (PCB). Soldering is an attachment process wherein a metal or metal mixture (called solder), when heated to an appropriate temperature, fuses with the SMD's electrical I/O leads and the electrical circuit contact points on the PCB, thus holding them together.
SMCs include hybrid-circuits, integrated circuits, discrete devices (inductors, capacitors, diodes, transistors, etc.), metal heat sinks and metal shields. Hybrid- and integrated-circuit SMDs are usually packaged within a polymer and their electrical I/O leads are extended to pins or balls located on at the edges and or on the bottom of the package.
The density of SMCs, such as SMDs, mounted on a substrate such as a printed circuit board (PCB) is increasing, as is the complexity of the circuitry within the SMDs. Higher SMC densities on PCBs have increased the demands on the methods used to hold, solder and desolder SMCs to and from PCBs, with the precision and selectivity of the handling methods being more important than ever to avoid heat spillover which could cause damage to nearby SMCs.
In addition, the replacement of lead-based solders with melting temperatures in the 183-200° C. range with higher melting temperature lead-free solders requiring process temperatures as high as 250-260° C. further reduces the margin of error. This is particularly true for Multi-Chip Modules (MCMs), which use higher melting temperature solder or epoxy processes for assembly and can be irreversibly damaged by subsequent exposure to temperatures approaching those at which the original MCM was assembled.
If an individual SMC on a PCB fails, there are two options: discard the whole PCB, or replace the SMC. In the past, the cost of individual PCBs may have been low enough to make discarding the PCB the preferred choice. However, this is no longer true in many cases.
Heating methods currently employed to attach and remove SMCs to and from PCBs in SMC fabrication and rework include: (1) hot air or nitrogen, (2) soldering irons, and (3) infrared heating. Each of these methods has a number of drawbacks, as noted below.
Hot air or nitrogen gas (400-900° C.) is emitted under pressure, after passing along a heated path wherein heat is transferred to the gas, typically by means of a resistively heated coil. This method has several disadvantages:
Since the gas is not a very efficient heat transfer mechanism, it must be well above the melting temperature of the solder to actually melt the solder. The high temperature of the gas stream is a risk to the SMC itself as well as to adjacent SMCs and the PCB.
The temperature of an exiting gas stream as it impinges on the component cannot be very accurately controlled since there is no means for measurement at the SMC/heater interface. Thus, it is not possible to accurately control desolder, solder and resolder processes or to accurately replicate the original reflow oven attachment sequence.
It is difficult to confine the heating to only the area of the target SMC. Complex nozzles and baffles have been designed to shield adjacent SMCs from damage. However, these require customization of the rework tooling for each SMC size, and hence add to the overall rework cost.
The gas jet method cannot be applied exclusively to the top of the SMC. The high temperature required due to the relatively low heat transfer efficiency of the gas causes the resulting exposure times to be longer than for direct heating of the solder, thus posing a risk to the SMC and its internal components.
There are also drawbacks associated with soldering irons. The temperature to which the SMC is heated is very difficult to control precisely because: (1) the soldering iron tip temperature is often inferred from a temperature measurement taken elsewhere on the soldering iron, and (2) measuring the temperature in this way is subject to further inaccuracy due to changes in the thermal contact between the soldering iron and the thermocouple and to the change of the thermocouple's temperature response over time. The resulting disadvantages include:
Unintentional excessive reflow of solder may occur, possibly damaging the components inside the SMC, or between pads on the PCB.
The large thermal mass of the soldering iron precludes the implementation of temperature ramps during solder/desolder operations. Such ramps are desirable to minimize thermal shock to the PCB and ideally should mimic the temperature ramps used in the original solder reflow oven.
Infrared (IR) radiating elements are activated at high power levels to cause heat energy to radiate from the IR elements to the SMC for desoldering. However:
Complex mechanisms associated with the IR elements must assist in focusing or directing the heat to the desired SMC.
the effectiveness of the IR system is dependent on the IR absorption or IR reflectivity of the SMC. Due to wide variances in the materials used for SMCs and the reflectivity of the surface coatings used on the top surface of SMCs, IR rework tools usually require a bottom-side directed heater as well. Since many current PCB assemblies have components on both sides, the bottom-side heat creates additional risk of component damage.
Monitoring and control of the SMC temperature is accomplished by IR temperature sensing devices connected to a computer-controlled power supply for the IR radiating element. The temperature reported by these devices depends on the emissivity of the SMC surface, which can vary widely with SMC material and surface properties.
It may also be necessary in some applications to heat the PCB board itself prior to attaching or removing a component, to remove moisture from the board and to minimize thermal stresses during SMC attachment and removal. This has conventionally been accomplished using hot air or nitrogen gas, or IR radiating elements. However, as noted above, gases are relatively inefficient heat transfer mediums; as such, the gas temperature must be considerably higher than the target PCB temperature. This inefficiency may also result in the need for an extended exposure time which may risk damage to the PCB and its components. Gas temperatures can also be difficult to control.
Using IR radiating elements to heat a PCB can also be problematic. IR absorption depends on surface emissivity, which depends on material and surface roughness. Due to wide variances in the materials used for PCBs, and the reflectivity of PCB surface coatings, uniform heating of the PCB—and precise control of temperature—can be difficult.
One possible approach to SMC heating is described in co-pending patent application Ser. No. 11/290,942 to Durstan et al., in which a planar-heater generates heat in response to an electrical current. In one embodiment, a vacuum conveyed around the sides of the planar-heater holds the SMC such that its I/O contacts are heated by thermal conduction from the planar-heater, with a “primary” platen affixed to the planar-heater used to convey heat between the heater and the SMC. However, this arrangement limits the minimum SMC size that can be held by vacuum and simultaneously heated to a size larger than the primary platen. In addition, it limits heating to the top surface of the SMC.
A platen for a thermal attach and detach system for use with components to be heated is presented, which enables a component to be held in close proximity to a contact heating source via vacuum suction.
The present platen is employed with a system which includes a contact heating source that conveys heat to a planar surface and which uses vacuum suction to hold components to be heated in close proximity to the planar surface. The platen comprises:
The platen's bottom surface may include a raised rim portion around its perimeter. The portion of the bottom surface within the raised rim is referred to herein as a recessed portion, and the through-hole opening is located within the recessed portion. When so arranged, a component to be heated may be supported by the rim portion and held against the rim by a vacuum conveyed via the grooves and through-hole. Alternatively, a component to be held may be contained within the recessed portion, held against the recessed portion by a vacuum conveyed via the grooves and through-hole.
The present platen is well-suited for use with components such as plastic ball grid array surface-mount devices (PBGA SMDs) and quad flat pack surface-mount devices (QFP SMDs).
The present platen is beneficially employed with a thermal attach and detach system (TADS) as described in co-pending patent application Ser. No. 11/290,942 to Durstan et al. The TADS system described therein can be used for thermally attaching and detaching SMCs to and from a substrate by various methods, including soldering, bonding, or brazing. The TADS system employs a “planar-heater” contact heating source, which generates heat and conveys it to a planar surface in response to an electrical current. The heater's resistance varies with its temperature, and the resistance is read to determine heater temperature and to measure SMC temperature. A vacuum means is used to grip an SMD via the present platen as described above, such that the SMC's I/O contacts are heated by thermal conduction from the planar-heater through the present platen.
Further features and advantages of the invention will be apparent to those skilled in the art from the following detailed description, taken together with the accompanying drawings.
The present platen is for use with a system which includes a contact heating source that conveys heat to a planar surface, and which uses vacuum suction to hold components to be heated in close proximity to the planar surface. One specific application for the platen described herein is with a thermal attach and detach system (TADS) for use with surface-mounted components (SMCs) such as surface-mount devices (SMDs); for this application, the present platen enables an SMC to be held in close proximity to a contact heating source via vacuum suction.
One possible TADS system with which the present platen might be used is described below, as well as in co-pending patent application Ser. No. 11/290,942 to Durstan et al. Several means by which the TADS system may grip an SMC are described; however, the present platen specifically requires that a vacuum means be provided for the purpose of gripping a component. Note that, though a specific TADS system is described herein, the present platen is generally applicable for use with systems which use a vacuum to hold components to be heated in close proximity to a heated planar surface. A discussion of an exemplary TADS system is found immediately below, and is followed by a detailed description of the present platen.
The exemplary TADS system described herein enables SMCs to be simultaneously held, heated, positioned, thermally attached to a substrate or thermally detached and removed from a substrate, with the SMC's temperature being measured at all times. Substrates and PCBs themselves can also be heated by the present system, to remove moisture before and minimize thermal stress during the attachment or removal of a component from the PCB, or to effect the component removal itself. The TADS system can be hand-held or robotically deployed. It can precisely position a planar-heater on an SMC of any size, and precisely position an SMC on a substrate or grasp and pull an SMC that is to be removed from a substrate.
An illustration of a basic TADS system is shown in
The heat required to melt the solder is provided by a “planar-heater” 14—i.e., a thin planar device which generates heat in response to an electrical current, which has a resistance that varies with its temperature. The heater is typically affixed to a cartridge 16, which is in turn affixed to a shaft assembly 17, or a plunger 18 if the shaft assembly is comprised of more than a shaft and a pin holder module (discussed below). Control electronics 20 required to control planar-heater 14 is coupled to the planar-heater via wiring 21, which is routed between the electronics and the heater through the interior of shaft assembly 17.
Note that, though only SMD's are discussed herein, the exemplary TADS system described herein can be applied to any component having a planar surface.
Common to all described methods is a “planar-heater” component. A typical implementation of this device is shown in
Though numerous materials can be used for die 36, materials with a high thermal conductivity are preferred. The metals used should not oxidize over the temperature range that the planar-heater is to operate, or the heater and its electrodes should be protected from oxidation by encapsulation. Two metal/die planar-heater combinations are preferred: (1) tungsten on aluminum nitride, and (2) platinum on alumina. Tungsten on aluminum nitride is preferred, as this type of die has a higher thermal conductivity and a more constant temperature coefficient than do platinum on alumina dies. Also, the expansion coefficient of tungsten strands is virtually identical to that of aluminum nitride, while the expansion coefficients of platinum and alumina differ by about 25%.
The planar-heater is thermally insulated except at its edges, so virtually all of its heat is directed through the SMD to the soldered I/O contacts. Control electronics 20 includes a power supply, which provides an excitation voltage and current to the heater, from which the heater's resistance, and thus its temperature, can be determined. As such, no additional temperature sensing mechanisms are required. Heating is accomplished by dissipating power in the strands 34. The dissipated power is the product of the excitation current supplied by electronics 20 and the resulting voltage drop across the length of the strand between the electrodes 32, the electrical connector pins which contact electrodes 32 (described below), and the wiring 21 between electronics 20 and the connector pins.
A planar-heater is typically affixed to a cartridge to form a “planar-heater module” (PHM); an exploded view of such a module is shown in
Protrusions (or stand-offs) 45, shown in
In use, cartridge 16 is mounted to the base of the shaft assembly 17 or a plunger 18 (described below). One way in which the cartridge can be implemented to provide electrical continuity between planar-heater 14 and electronics 20 is as follows: electrical connector pins 44 extend out of the base of the shaft assembly through an electrically and thermally insulating “pin holder module” 46, which is attached to the base of the shaft. The axis of the shaft assembly is aligned with the axis of PHM 40 as a cavity in the top of cartridge 16 is slipped over pin holder module 46 at its base. Simultaneously, electrical connector pins 44 slip into holes in cartridge 16 and extend down to planar-heater electrodes 32.
A pair of pressure spreading interface connectors 47 may be inserted between the base of pins 44 and planar-heater electrodes 32 to spread the force exerted by the spring loaded pins 44 on the electrodes over a larger area, thus reducing the pressure on electrodes 32. This substantially reduces wear on electrodes 32 and the likelihood of planar-heater cracking. Interface connectors 47 also serve to increase the cross-sectional area of electrodes 32 that can be used for current flow. The interface connectors 47 are preferably polymer or ceramic blocks (square or cylindrical), covered with electrically conductive metal to provide electrical continuity between pins 44 and electrodes 32.
Note that this arrangement is merely exemplary; numerous embodiments of PHM 40 are possible, as are the ways in which electrical continuity can be provided between planar-heater 14 and electronics 20.
The PHM can be mounted to the shaft or plunger by several methods, some of which are described below. For example, as shown in
A second method might be a retainer clip, having upper fingers which slide into corresponding grooves near the bottom of the shaft, and lower fingers which attach to corresponding slots in a planar-heater cartridge.
A third method might be to use a captive nut attachment. A threaded captive nut on the shaft is retained by a lip on the pin holder module or the shaft. The captive nut attaches to mating threads on the planar-heater cartridge, allowing the cartridge, and thus a PHM, to be attached to or detached from the shaft with two turns of the captive nut.
Another possible method is to use a bayonet attachment structure. A captive nut with bayonet slots is used to connect the shaft assembly to the PHM. The captive nut is placed on a nut spring which is supported by a lip on the pin holder module or the shaft. The captive nut is then pushed down until the top of bayonet slots are below the top of the bayonet tabs, and the captive nut is rotated so that the slots align with the tabs, thereby latching the shaft to the PHM.
A ball-detent attachment structure could also be used. Here, spring loaded balls in the planar-heater cartridge fit detents in the pin holder module. The balls are loaded by a detent spring retained within holes in the cartridge by screws. When the pin holder module detent aligns with the cartridge holes, the balls are pushed into the detent by the detent springs, thereby connecting the shaft assembly to the cartridge.
Yet another possible method to use a positive latching interference fit attachment structure, where a tapered bulge on the shaft snaps into a tapered recess in the cartridge. A tapered bulge area on the base of the plunger, just above the pin holder module, provides the guide-in and snap-in pressure for the planar-heater cartridge. The tapered bulge area may or may not be a part of the pin holder module. The maximum bulge diameter should be large enough to provide a crisp snap-in and snap-out function, but not so large as to prevent easy attachment or removal.
Several methods of gripping an SMD and holding it in close proximity to a planar-heater are described below, including vacuum, mechanical, adhesive and magnetic means. The vacuum means is described first. A vacuum can be applied to the surface of an SMD either 1) around a planar-heater and/or primary platen, or 2) through a planar-heater and/or primary platen.
When a vacuum is to be applied around the planar-heater and/or primary platen, the forces used to hold the SMD, and to press the planar-heater against the SMD surface, are provided by distinct and independent mechanisms. A planar-heater module used for this vacuum method should not have any protrusions beyond its bottom surface. A primary platen that clips or slides onto a holding surface built into the planar-heater cartridge might be advantageously employed to provide a bottom surface with no protrusions.
There are many ways in which a TADS system could be arranged to apply a vacuum to the surface of an SMD around the planar-heater and/or primary platen. Several possible embodiments are described. In these design examples, the surface of a planar-heater or platen is placed against the top surface of an SMD, and a plunger housing (described below) is pressed towards the SMD, causing a vacuum sealing surface to make contact with the SMD. Then, a vacuum pump connected to a vacuum port on the shaft assembly is turned on, causing the vacuum to hold the SMD against the heating surface of the planar-heater module. As long as the vacuum is on, the shaft and SMD will move as a single unit. When the vacuum is released, the SMD is automatically released—automatic release is possible because of the pressure exerted by the planar-heater module on the SMD, which pushes the vacuum sealing surface away from the SMD surface; alternatively, a two-way switch may be installed between the vacuum pump and vacuum port, with one switch position connecting the vacuum pump to the port and the other position venting the port to air.
Perspective and sectional views of one possible implementation of this vacuum holding method are shown in
Plunger housing 50 includes a cavity (66,68,70), within which plunger 52 can slide and rotate; thus, when downward force is applied to plunger housing 50, the shaft assembly becomes shorter, and when torque is applied to the plunger housing and the plunger is stationary, the housing rotates independently of the plunger and PHM 40. Plunger compression spring 58, or, alternatively, a bellows, can transmit force through plunger 52 to the SMD surface when plunger housing 50 is pushed towards the SMD. Electrical wiring 21 from the electrical connector pins 44 to electronics 20 passes through plunger 52 and cap 60. PHM 40 fits into the bottom of plunger 52. A vacuum enclosure 74 includes a mounting surface 76 for affixing enclosure 74 to VEPC 64, which is in turn affixed to the bottom of the shaft, and a vacuum enclosure base sealing surface 78.
An O-ring groove and O-ring 80 are located near the top of vacuum enclosure 74, which forms a vacuum seal between mounting surface 76 and enclosure 74. The axial length of the O-ring seal between enclosure 74 and mounting surface 76 should be short enough to permit the enclosure axis to wobble with respect to the axis of plunger housing 50, which allows the base 82 of enclosure 74 to align the SMD surface parallel to the PHM heating surface, thus ensuring good thermal contact between these two surfaces.
Vacuum piston ring 54 is connected to the top of plunger 52. The ring limits maximum plunger travel, transmits restoring force from plunger compression spring 58 to return plunger 52 to its maximum extension when the vacuum is turned off, and provides a vacuum sealing surface for an O-ring or Teflon washer in the formation of a vacuum seal between the upper and lower volumes of plunger housing 50. The side walls of piston ring 54 are preferably machined to hold O-ring vacuum seal component 56 between ring 54 and the inner wall of plunger housing section 68 as the plunger moves up and down.
When so arranged, a vacuum applied at vacuum port 62 is conveyed to the surface of an SMD via vacuum enclosure base sealing surface 78. The force applied to the SMD surface by planar-heater module 40, created by piston ring 54 pressure on spring 58, opposes the SMD holding force created by the vacuum above the exposed surface of the SMD. These forces must be properly balanced when the SMD is suspended, or PHM 40 will ‘break’ the vacuum seal between vacuum enclosure base sealing surface 78 and the SMD surface.
VEPC 64 allows vacuum enclosure 74 to be pushed upward along the axis of plunger housing 50, so that the PHM can be connected to connector pins 44 and the PHM can be secured to the base of plunger 52. The VEPC also prevents enclosure 74 from sliding upward along mounting surface 76, after enclosure 74 has been slid back down mounting surface 76 to its operating position near the bottom of the PHM. Many types of VEPCs are practical, including, for example, a clamshell, an O-ring, a rubber band, or a clip.
Another possible shaft assembly implementation is shown in
Another possible embodiment is arranged such that the vacuum sealing surface of vacuum enclosure 74 is placed in intimate contact with the SMD surface. When the vacuum pump is turned on, the vacuum created by the seal between the SMD and the sealing surface of enclosure 74 simultaneously holds the SMD and forces the planar-heater or primary platen into contact with the SMD surface. This embodiment holds an SMD and the heating surface of a PHM against the top surface of an SMD using the same vacuum. The PHM to SMD contact force is provided by the pressure gradient across the vacuum piston ring. As long as vacuum port 62 is being pumped, the shaft assembly and the SMD will move as a single unit, and power applied to the PHM will heat the SMD. When port 62 is vented to air, the PHM will return to its original position and the shaft assembly will release the SMD.
The two basic components of this embodiment are the shaft assembly and the vacuum enclosure. One possible implementation is shown in
The assembly shown in
Plunger housing 102 is a hollow cylinder that contains three internal sections: a plunger housing piston section 68, a plunger guide section 66, and a vacuum enclosure attachment section 70.
When downward force due to a pressure gradient is applied to piston ring 106, the plunger extension beyond the base of housing 102 is increased, and the PHM is pressed against the top surface of the SMD. Housing 102 ensures atmospheric pressure at the top surface of piston ring 106. This is accomplished with one or more vent holes 116 in the side wall, between piston ring 106 and cap 114. The holes must be located in an axial position which is never reached by piston ring 106.
The vacuum opposing spring 112 (or bellow) can transmit a restoring force through piston ring 106 when plunger housing 102 is vented. Plunger housing 102 provides a path connecting the top surface of the SMD, the bottom surface of vacuum piston ring 106, and vacuum port 62, through which a vacuum pump connected to port 62 can create a vacuum over the exposed areas of the SMD surface between the PHM and the vacuum enclosure/SMD contact surface.
Guide rings 91 as described above can provide a vacuum path inside plunger housing guide section 66. Another method of providing a vacuum path and guide surface is to bore out and thread the guide wall to the same ID as the plunger housing ID below it; then insert one or more slotted or perforated guide rings 91 to guide the plunger and permit free air flow between the upper and lower volumes of the plunger housing. There are many other means of providing these guide surfaces; the key requirement is that guide surfaces be provided for plunger 104 at a minimum of one axial position along the inside surface of housing 102.
Plunger 104 must be longer than plunger 52 discussed above, or the axial length of section 66 must be shortened and the axial length of section 68 increased so that the plunger extends far enough beyond the housing base to permit the PHM to be attached to the plunger base. Plunger 104 provides a mounting platform for a PHM, a feed-through path for wiring 21, and an area into which pin holder module 46 can be inserted. Vacuum piston ring 106 and the ID of section 68 must be large enough to ensure that the force created by a pressure gradient across the piston ring is sufficient to overcome the opposing forces and press the heating surface of the PHM firmly against the SMD surface. The principal opposing forces are: (1) vacuum opposing spring 112 force constant, and (2) friction between the section 68 ID wall and vacuum seal component 110.
Vacuum piston ring 106, when connected to the top end of plunger 104, functions to transmit compressive force to spring 112 when the volume between the piston ring and the SMD surface is evacuated through port 62. The piston ring's bottom surface uses the top end of the spring to provide a limiting and restoring force that opposes the force caused by the pressure gradient across it. The ring also provides a vacuum sealing surface for an O-ring or Teflon washer, in the formation of a vacuum seal between the upper and lower volumes of plunger housing 102.
The side walls of vacuum piston ring 106 are machined to hold an O-ring vacuum seal component 110 between the piston ring and the inner wall of plunger housing piston section 68 as the plunger moves up and down. Vacuum seal component 110 is an O-ring or Teflon washer which forms a vacuum seal between the ID of section 68 and piston ring 106.
Vacuum opposing spring 112 provides a counter (restoring) force to plunger 104 as the plunger is forced out of the base of plunger housing 102, thus limiting the pressure applied by the PHM to the SMD surface when the assembly is evacuated through port 62. The force applied to the SMD surface by the PHM, created by the pressure gradient across vacuum piston ring 106, opposes the SMD holding force created by the vacuum above the exposed surface of the SMD. These forces must be properly balanced such that the SMD is not pressed against a PCB surface; otherwise, the PHM may push the SMD with such force that the vacuum seal between vacuum enclosure 74 and the SMD surface is broken.
VEPC 64 may be any component that allows enclosure 74 to be pushed upward along the axis of plunger housing 102, so that the PHM can be connected to the electrical connector pins and the PHM can be secured to the plunger. VEPC also prevents enclosure 74 from sliding upward along mounting surface 76, after enclosure 74 has been slid back down mounting surface 76 to its operating position just above the bottom of the PHM.
In the embodiment shown in
Plunger housing 120 is a hollow cylinder that includes plunger housing piston section 68 and vacuum enclosure attachment section 70. Housing 120 includes a cavity in which plunger 122 can slide and rotate; thus, when downward force is applied to vacuum piston ring 106 caused by a pressure gradient across the ring, the plunger extension beyond the housing base is increased, and the heating surface of the PHM is pressed against the top surface of the SMD. Housing 120 ensures that there is atmospheric pressure at the top surface of ring 106. This is accomplished with one or more vent holes 116 in the side wall, between ring 106 and cap 124. The holes must be located in an axial position which is never reached by piston ring 106.
Housing 120 also provides a cavity within which vacuum opposing spring 112 (or a bellows) can transmit a restoring force through vacuum piston ring 106. The housing provides a path connecting the top surface of the SMD, the bottom surface of vacuum piston ring 106, and vacuum port 62, through which a vacuum pump connected to the port can create a vacuum over the exposed areas of the SMD surface between the PHM and the vacuum enclosure/SMD contact surface.
Housing 120 includes a vacuum piston ring guide surface 126 in plunger housing piston section 68. Cap 124 together with guide surface 126 keep plunger 122 aligned with housing 120. The inside wall of section 68 is one of the guide surfaces, and there is preferably at least one other guide ring 108 to provide another guide surface.
Plunger 122 must be longer than plunger 104 in
Vacuum piston ring 106 transmits compressive force to spring 112 when the volume between the ring and the SMD surface is evacuated through vacuum port 62. The ring's bottom surface uses the top end of spring 112 to provide a limiting and restoring force that opposes the force caused by the pressure gradient across it. The ring also provides a vacuum sealing surface for an O-ring or Teflon washer, in the formation of a vacuum seal between the upper and lower volumes of housing 120. The side walls of ring 106 should be machined to hold an O-ring vacuum seal component 110 between the vacuum ring and the inner wall of section 68 as plunger 122 moves up and down.
A washer (not shown), preferably Teflon, can be used in place of O-Ring 110. The washer is placed between ring 106 and spring 112. The bottom surface of the washer forms a vacuum seal to the ring surface and the outer circumference surface of the washer forms a vacuum seal to the inner wall of plunger housing piston section 68.
The force applied to the SMD surface by the heating surface of the PHM, created by the pressure gradient across piston ring 106, opposes the SMD holding force created by the vacuum above the exposed surface of the SMD. These forces must be properly balanced when the SMD is not pressed against a PCB surface, or the PHM may ‘break’ the vacuum seal between the vacuum enclosure and the SMD surface.
Cap 124 provides guide surface 108 for plunger 122 at the top of plunger housing 120. The cap preferably screws into housing 120; however, the cap could alternatively be bayonet mounted to the housing, or be mounted by a freely rotating gasket (bushing).
This shaft assembly would also include a VEPC and vacuum enclosure as described above, which allows the vacuum enclosure to be pushed upward along the plunger housing axis so that the PHM can be connected to the electrical connector pins and secured to plunger 122.
A vacuum enclosure 74 suitable for use with the assemblies shown in each of
The shaft assemblies described above have the vacuum passing around the PHM to reach the SMD surface. Shaft assemblies can also provided for which the vacuum passes through the PHM and/or primary platen. Here, the plunger housing and plunger are a single component, and the PHM is designed to both hold and heat the SMD. The planar-heater may or may not contain holes through which a vacuum can be applied to the SMD surface; an example of each approach is discussed below.
The forces used to hold the SMD and to press the primary platen of the PHM—referred to for this embodiment as a “vacuum planar-heater module” (VPHM) (156)—against the SMD surface are provided by the same mechanism—a vacuum created by pumping on a vacuum port. The force used to maintain contact between the planar-heater and the platen is independent of the vacuum used to hold the SMD. The platen/SMD interface is the vacuum sealing interface.
The VPHM and shaft assembly move as a single unit. The primary platen surface of the VPHM is placed in intimate contact with the SMD surface by x, y, z, θ and φ movements of the shaft assembly. Then, the vacuum pump is turned on and switched to apply a vacuum at a vacuum port. The platen contains slots or holes through which the vacuum in the VPHM holds the SMD against the platen surface. During heating, planar-heater/platen contact is maintained by spring loaded pins that press the heater towards the platen.
As long as the vacuum port is being pumped, the shaft assembly and the SMD will move as a single unit, and power applied to the planar-heater will heat the SMD. When the port is vented to air, the VPHM will release the SMD.
One possible shaft assembly embodiment suitable for this approach is shown in
Electrical conduit 160 is a hollow cylinder that provides a feed-through path for insulated lead-wires 21 that provide electrical continuity between the system's control electronics and electrical connector pins 44 which convey power to the VPHM 156. The electrical conduit has a position at its base into which pin holder module 46 can be inserted. Conduit 160 also provides a mounting position at its base for VCMA 164, which connects the base of electrical conduit 160 to the base of vacuum conduit 162, and provides a path between the VPHM and the vacuum conduit. Vacuum conduit 162 provides a vacuum path between the VPHM and ultra-torr tee 166, and a surface for holding and positioning the shaft assembly.
The VMCA 164 is comprised of a stop nut 167, vacuum gasket 168, and a vacuum conduit to VPHM connecting nut 170. The stop nut provides a mounting surface for gasket 168 and nut 170. The gasket provides a vacuum seal between the top surface of stop nut 167 and the down facing surface of VPHM nut 170. VPHM nut 170 connects VPHM 156 to vacuum conduit 162.
The ultra-torr tee 166 contains three vacuum feed-through ports:
VPHM 156 includes an electrical conduit to planar-heater terminal and guide assembly (TGA), a planar-heater 14, a primary platen 172, a platen holder 174, a platen holder to shaft assembly transition 176, and a shaft assembly transition connector assembly 178. The TGA is comprised of a cartridge 16 and, preferably, a pressure reducing connector 180. The cartridge guides the electrical connector pins 44 and electrically isolates their exposed side-walls.
Pressure reducing connector 180 provides electrical continuity between pins 44 and planar-heater 14, and distributes the force, exerted on the planar-heater electrodes by the spring-loaded connector pins, over a much larger area. Planar-heater 14 heats primary platen 172. It may (as in
Primary platen 172 serves to center planar-heater 14, conduct heat from the heater to an SMD surface, provide a vacuum sealing interface with an SMD, and provide a vacuum feed-through via slots or holes from the SMD surface to the VPHM. Two platen/planar-heater configurations are described:
1. Primary platen 172 is larger than the planar-heater, as shown in
2. The primary platen 172 surface area is the same as that of the planar-heater, as shown in FIG. 14—except for the centering recess wall of the platen. A vacuum feed-through path is provided by holes 184 in the planar-heater that are aligned with slots 182 in the platen.
Primary platen holder 174 is preferably a high temperature thermoplastic or ceramic that provides an opening through which the platen, mounted on the platen holder rim, can make direct contact with the SMD surface. Holder 174 also provides a low thermal conductivity path between platen 172 and the platen holder to shaft assembly transition 176, and a vacuum sealing interface with the shaft assembly transition connector assembly 178. If the platen holder is a ceramic, then a gasket (not shown) should be included between the sealing surfaces of holder 174 and transition 176.
Shaft assembly transition 176 is perpendicular to the shaft assembly axis, and has a rectangular cross-section from the primary platen holder 174 to the spring 186 of transition connector assembly 178. Above the surface upon which spring 186 rests, transition 176 has a circular cross-section. The lip of the lower portion of transition 176 forms a vacuum interface with platen holder 174. The upper portion of transition 176 is threaded to fit VPHM nut 170 that holds and centers VPHM 156 on vacuum conduit 162. Transition 176 is not connected to the VPHM nut until it is connected to platen holder 174 with transition connector assembly 178.
Transition connector assembly 178 holds primary platen holder 174 tightly against shaft assembly transition 176. It is comprised of two components: spring 186 and a clip 188. The clip is open on two sides; the bottom of the other two sides of the clip are hook shaped. Connection of platen holder 174 to transition 176 is accomplished as follows: spring 186 is inserted around the circular cross-section of transition 176, as shown in
A TADS system may also employ a mechanical means to hold an SMD in contact with the primary platen or planar-heater surface of a PHM. One method is to use what are referred to herein as “micro-grippers” (MG). Two types are described: type 1) a “micro-gripper planar-heater module” (MGPHM), where the MGs are attached to the cartridge 16 and are part of the PHM cartridge, and type 2) MGs that are not part of the PHM and which can be moved independently of the PHM. Two examples of type 1 MGs and one example of type 2 MGs are described below, though numerous other implementations are possible.
One example of a type 1 MG is shown in
The micro-grippers in
The amount of force applied to claws 200 is proportional to the force constant of springs 204. The force applied to an SMD's side-walls is easily changed by replacing the two springs. By application of a calibrated force, the actuating system can determine when the claws are attached and how much force is applied. The PHM is electrically connected to external control electronics 20, and physically connected to the bottom of a shaft, by the methods described above. For example, in
A second type 1 MG embodiment is illustrated in
One possible shaft assembly that might be used with the micro-gripper embodiment of
The IDs of plunger housing guide section 66 and plunger piston ring 246 are large enough to allow the surfaces of plunger 52 and housing 242 to move in opposite directions. A hollow knob 248 fits through the cap nut and rests on piston ring 246. The ID of the lower part of the knob is large enough to allow it to fit over and slide freely over the outside wall (OD) of plunger 52. The length of the large ID in the lower part of knob 248 is longer than the axial penetration length of the plunger into it. This additional length is the distance that spring 58 can be depressed by plunger piston ring 246.
In the resting position, the claws 200 are in the closed (gripping) position. When knob 248 is depressed, plunger housing 242 is forced downward, through counter pressure by spring 58 until micro-gripper arms 201 are pushed down and the claws are in the open (non-gripping) position. When pressure on knob 248 is released, spring 58 pushes piston ring 246 back to the top of section 68, causing the claws to close.
A shaft assembly capable of providing air actuation for the micro-gripper of
An embodiment of a type 2 MG is illustrated in
The shaft assembly (SA), shown in cross-section in
Plunger housing 249 is a hollow cylinder that performs three functions: 1) it provides a cavity within which plunger 18 can slide and rotate, 2) it provides a cavity within which spring 250 can provide a restoring force when compressed between nut 251 and cap 252 as the plunger housing is pressed downward, which causes claws 200 to be pushed down below the PHM (a bellows could be used instead of spring 250), and 3) it provides a position for cap 252 which guides electrical wires 21 out through plunger housing 249.
Plunger 18 performs two functions: 1) a feed-through path for insulated lead-wires 21, and 2) a position at its base into which pin holder module 46 can be inserted. Spring 250 provides a counter (restoring) force to plunger 18 as the plunger is forced into plunger housing 249.
Cap 252 guides the top of plunger 18 through the top end of plunger housing 249 and centers it. The cap screws into the plunger housing; however, the cap could be bayonet mounted to the plunger housing, or it could be mounted by a freely rotating gasket (bushing).
Claws 200, through arms 253, shown in
In
The linear actuator 255 may be connected to plunger 18 instead of plunger housing 249, or it may be connected to a completely independent x, y, z, Φ and φ motion control assembly. In this embodiment, the claw arms 253, and thus the claws 200 move independently of the PHM.
All degrees of freedom of this embodiment can be controlled manually, pneumatically, electrically, magnetically or hydraulically.
An SMD might also be gripped with the use of an adhesive preform interposed between the primary platen or planar-heater and the SMD. The adhesive preform attaches itself to planar surfaces and releases the same planar surfaces after heating. Plan and sectional views of an adhesive preform are shown in
An adhesive preform as described herein can be fabricated as follows:
1. Carrier 260 is cut into a rectangular shape, with a width approximately equal to the length of one side of the target SMD and a length sufficient to cover the length of the other side of the SMD and provide an exposed holding tab.
2. Two sheets of high temperature transfer tape 262 are cut to the approximate dimensions of the target SMD.
3. The sides of sheets 262 with exposed adhesive are attached to opposite sides of carrier 260.
Removal of an SMD using an adhesive preform is illustrated in
Desoldering SMD 10 and the separation of the SMD from the planar-heater surface and adhesive preform disposal proceeds as follows. After SMD 10 is heated and desoldered from PCB 12, the shaft assembly is lifted and the SMD is removed from the PCB and the SMD is then separated from the surface of planar-heater 14. The adhesive preform is then peeled from the surface it is still in contact with, leaving virtually no adhesive residue on the surfaces of the planar-heater or target SMD, due primarily to the carrier permeations which allow the adhesive from both sheets to bond to each other, and the fact that the adhesive becomes weaker and less elastic after exposure to high temperature.
A magnetic approach might also be used to grip an SMD. This method uses a magnet and a magnetic preform to attach the surface of an SMD to a primary platen or planar-heater surface. The magnet can be a permanent magnet or an electromagnet. The magnetic preform adhesively attaches to an SMD surface, and is magnetically held against the surface of a planar-heater or platen. The magnet can be positioned on the top surface of the PHM or within the PHM, or it can be the platen itself.
One possible embodiment of a magnetic preform 268 is shown in plan and sectional views in
Removal of the target SMD and magnetic preform 268 disposal is as follows. First, the SMD is heated until desoldered from PCB 12, and is lifted away from the PCB. Second, the magnetic preform with the SMD attached is slid off the surface of planar-heater 14 or primary platen, using the tab on carrier 270. Third, the adhesive 274 is peeled from the surface of SMD 10, leaving virtually no adhesive residue on the SMD. If an electromagnet is used instead of a permanent magnet, the SMD would be released from the planar-heater surface when the current through the electromagnet is switched OFF.
The TADS system can also be used to heat a substrate, such as a PCB. This can be useful to, for example, drive out moisture and reduce thermal stresses that might be induced in a PCB when using the SMD rework methods described above. The substrate heating methods described below can be used to achieve temperatures of up to 300° C. The heating methods will be illustrated in the context of SMD technology, though they can be used for other applications as well.
Two conductive heating methods are described: (1) planar-heater, and (2) ball bath heater. Both methods employ the same control circuitry. Plan and sectional views illustrating the planar-heater conductive heating method are shown in
Temperature sensor 302 is attached to the insulating material of planar-heater 300, or to the primary platen 304, with a high temperature adhesive. The signal from the temperature sensor is routed back to the controller via wiring 308; the controller is arranged to use the temperature sensor signal to determine the power required for planar-heater 300 to achieve and maintain a target temperature. Examples of possible temperature sensors include thermocouples and resistance temperature detectors (RTDs).
The primary platen 304 is attached to planar-heater 300 as shown in
Support assembly 306 is comprised of a thermal insulator 310 and a support base 312. Thermal insulator 310 prevents heat generated by planar-heater 300 from conducting away from the PCB. Ideally, the surface area of thermal insulator 310 should be the same as or larger than that of primary platen 304, for maximum PCB heating uniformity and minimum planar-heater power requirements. However, the surface area of thermal insulator 310 can be less than half that of platen 304 and still provide satisfactory heating uniformity at temperatures below 300° C.
The controller provides power, communication and control needed for the operation and control of the planar-heater conductive heating system. In operation, the controller receives a signal from temperature sensor 302 that varies with planar-heater temperature, and is arranged to provide the current to planar-heater 300 needed to achieve a desired temperature.
Plan and sectional views illustrating the ball bath conductive heating method are shown in
Heating element(s) 400 may be one or more probe-type heaters, a heating coil, a five-sided enclosure containing heaters in its walls, or one or more planar-heaters; in this description, heating element 400 is a planar-heater as described above. Here, however, (1) heating element 400 heats a plurality of stainless steel balls in which it is embedded, and (2) the heating element does not support the PCB.
Temperature sensor 402 is not attached to the planar-heater or primary platen; instead, it is embedded in a plurality of steel balls that can be attracted by a magnetic field. The signal from the temperature sensor is conveyed through wiring 406 to the controller, which uses the signal to determine the power required for the planar-heater to achieve and maintain a target temperature.
Ball bath heating assembly 404 is comprised of a containment box 408, a magnetic base 410, one or more permanent magnets or electromagnets 412, and thermally conductive balls with magnetic properties 414; the balls are preferably electrically conductive as well. Containment box 408 contains heating element 400, magnetic base 410, temperature sensor 402, magnets 412 (unless a magnetic field can be generated from the walls of the containment box), and thermally conductive balls 414. Heating element 400 is inserted at the base of the containment box, magnetic base 410 is placed on top of the heating element, and magnets 412 are arrayed on top of the magnetic base. The containment box is then filled with thermally conductive balls 414. Magnetic base 410 holds magnets 412 in prescribed positions, and the magnets hold the thermally conductive balls in position and prevents them from migrating.
Thermally conductive balls 414 support and heat PCB 12 by transferring heat from heating element 400. The thermally conductive balls, typically about 0.075″ in diameter, conform themselves to an irregular surface such as a PCB surface populated with SMDs and other components, thereby providing uniform heat transfer to irregular surfaces. The controller would be similar to that described above for the planar-heater conductive heating method: the controller receives a signal from temperature sensor 402 that varies with the temperature of thermally conductive balls 414, and is arranged to provide the current to heating element 400 needed to achieve a desired temperature.
As noted above, the planar-heater or heating element used in the above-described methods is operated with external electronics; these are referred to below as the “power control and monitoring electronics” (PCME). The PCME typically include a microprocessor and program memory, and are preferably arranged such that planar-heaters having different sizes and/or electrical characteristics, corresponding to different SMD sizes, for example, can be accommodated. This is preferably achieved by including a reference table function in the PCME's program memory which provides a specific current excitation profile for each planar-heater size. In this way, planar-heater size can be automatically determined by applying a known constant current through the planar-heater and measuring the resulting voltage across the heater. With a known voltage and a known current, the planar-heater resistance is calculated. Each planar-heater size has a qualified room-temperature resistance and calibration table, allowing the software in the PCME to correctly adapt to the specific planar-heater installed. Heater types and calibration tables might also be user-selectable.
Heating is accomplished by dissipating power in the strands of a planar-heater. The dissipated power is the product of the excitation current supplied by the PCME and the resulting voltage drop across the length of the strand between the electrodes 32, wiring 21 and electrical connector pins 44.
In a preferred embodiment, a constant current is supplied by the PCME during heating, to avoid thermal overshoot instabilities that can result from voltage control. The temperature of a planar-heater is directly proportional to the power per unit area dissipated in its strands. Thus, large planar-heaters require more power dissipation than smaller planar-heaters to reach the same temperature. Each planar-heater preferably has a programmed reference table as described above to provide the correct excitation current to heat a specific planar-heater size to a desired temperature. Maximum temperatures greater than 1,000° C. are possible; however, maximum temperatures of ˜300° C. are anticipated for SMDs.
The PCME are preferably arranged such that a pre-programmed temperature ramp and time profile can be initiated by pressing a button on the PCME controller or by depressing a foot switch. Note that if the drive circuitry is AC or pulsed DC, the strands should be patterned such that current-generated magnetic fields are cancelled in the heater. If this is not done, the planar-heaters can induce potentially damaging voltages in the target or nearby SMDs.
The voltage drop across the strand length increases with temperature by a known amount, defined by the temperature coefficient of resistance (TCR) of the strand metal. The TCR information is programmed into a microprocessor. Since the PCME is controlling and reading current and voltage supplied to the planar-heater, the PCME can continuously read the temperature of the planar-heater and adjust its excitation current such that planar-heater temperature is precisely controlled. When used for SMD rework, the controlled temperature should be just enough so that the SMD contacts are hot enough to cause the solder holding them to the PCB to flow, or to solder a new SMD to a PCB without causing the solder of one SMD contact to flow to another contact.
A block diagram for one possible PCME embodiment is shown in
Once the footswitch is depressed, planar-heater power supplies 506 and 508 are enabled; these can be a single variable power supply, or separate power supplies as shown. The microprocessor provides control words to a digital-to-analog converter (DAC) 510, which sets the planar-heater current via a constant current controller 512, which ensures that a precision-regulated current is supplied to the planar-heater. The feedback mechanism for closed-loop control of the planar-heater temperature consists of a heater voltage monitor 514, typically a differential amplifier, and a heater current monitor 516. The outputs of circuits 514 and 516 are sent to microprocessor 500 via an analog-to-digital converter (ADC) 518 for measurement. The digitized current and voltage values are used by microprocessor 500 to calculate resistance and power, and are converted to temperature via the appropriate lookup table for the planar-heater type in use. The entire process is managed by microprocessor and memory system 500, with status information preferably provided to a display 520 for a user to monitor. An overcurrent shutdown circuit 522 can be used to prevent excessive currents in the case of malfunction in the wiring, planar-heaters, or other circuit failures, by disconnecting the power supplies if the current exceeds a predetermined value.
A PCME functional process flow diagram is shown in
The soldering or desoldering process is terminated at decision block 624. If the footswitch is released, or a predetermined “end of desoldering” event occurs (including but not limited to timer time-out, detection of sudden rise in temperature, or loss of current control), the decision block path goes to “end desoldering” 626, where power to planar-heater 14 is removed for cool down.
Not included in this functional description are ancillary functions such as calibration and programming processes, data logging of process measurements (voltage, current, resistance, temperature, power, time, planar-heater type, calendar date, firmware version, etc.), and additional user interfaces for control of the desoldering process (voice activation, multiple heater controls for top and bottom heating, custom event programming, etc.).
Note that the block and flow diagrams of
As discussed above, a TADS system may employ a vacuum which is conveyed around the sides of the planar-heater to hold the SMC, with a primary platen affixed to the planar-heater used to convey heat to an SMC. However, this arrangement limits the minimum SMC size that can be held by vacuum and simultaneously heated to a size larger than the primary platen. In addition, it limits heating to the top surface of the SMC. These limitations may be overcome with the use of a “secondary” platen per the present invention.
A secondary platen (SP) is a thermally conductive structure, located between a part or component to be contact heated and the contact heating source. The present SP holds the component by means of a vacuum, which would typically be conveyed around the contact heating source and through the SP. The SP also serves to conductively transmit heat from the contact heating source to the component.
The use of an SP as described herein serves to extend the range of part sizes and shapes that can be manipulated and heated by a single contact heating source. The present SP can be used when attaching a part to or detaching a part from another part or a printed circuit board by thermal means; it is particularly useful when handling SMDs, as well as for hybrid-circuit manufacturing, such as for flip chip bonding.
An SP as described herein may also find use for the connection and sealing of hydrocarbon parts such as polyamides, acrylics and plastics. It can also be used for imprinting (stamping) holographic images into plastics (e.g., credit cards) and fabrics (e.g., currency and paper).
In the field of surface mount technology (SMT), the present SP can be used to aid in the positioning and holding of SMDs on printed circuit boards (PCBs), such that SMD solder contact pins, balls, pads or leads can be accurately positioned on the PCB soldering pads or in the PCB through-hole soldering positions. The SP is useful for devices being soldered to a PCB, and for devices being de-soldered and detached from a PCB.
The density of SMDs on PCBs is increasing, the minimum size of SMDs is decreasing, and the complexity of the integrated circuits (ICs) within SMDs is increasing. Increased SMD density makes contact heating of only the SMD to be soldered or desoldered very important. In some cases, SMDs as small as 0.0079″ in diameter must be held in place during soldering, thus making contact heating an ideal solution. Complex ICs are easier to package in plastic ball grid array type SMD packages (referred to as PBGA-type SMDs), and have become very common; for this package type, holding the SMD in a precise position above the PCB during soldering is required to avoid collapse of the SMD when the solder balls become liquid. The present SP is beneficial to the performance of this task.
As noted above, an SP in accordance with the present invention is for use with a system which includes a contact heating source that conveys heat to a planar surface and which uses vacuum suction to hold a component to be heated in close proximity to the planar surface. One possible embodiment of an SP 700 per the present invention is shown in
The SP includes a through-hole 706 which extends from its top surface to its bottom surface. At least one groove 708 is recessed into the top surface; each groove runs from a portion of the SP's top surface that extends beyond the contact heating source's planar surface to through-hole 706, such that a vacuum applied to the portion of a groove which extends beyond the planar surface is conveyed to bottom surface 702 via grooves 708 and through-hole 706.
In one embodiment, bottom surface 702 includes a raised rim portion 710 around its perimeter; the portion of the bottom surface within raised rim 710 is referred to herein as the “recessed portion” 712. Through-hole 706 is located within the recessed portion. The through-hole may be, for example, round, elliptical, or rectangular, and is preferably centered within recessed portion 712.
In the example shown in
SMD 714 is held against SP 700 by means of a vacuum applied to a vacuum enclosure 726, which is conveyed around the sides of planar-heater module 722, and then delivered via SP grooves 708 to the bottom opening of through-hole 706. The portion of raised rim 710 that contacts rim 720 of SMC 714 thus serves as a vacuum sealing surface for the applied vacuum, as well as the heat transfer surface.
In
When heated, both SMD cap 716 and SP 700 may expand. If SMD cap 716 expands faster than the SP rim depth, the height of cap 716 may become greater than the SP rim depth, and the cap may push the SP rim heating/vacuum-seal surface away from the top of SMD rim 720. For this reason, the distance between the top of SMD rim 720 and recessed portion 712 should be greater than the height of SMD cap 716. Note that it is not essential that the recessed portion of an SP's bottom surface and the top surface of the component being held be planar, as long as a planar rim surface exists for vacuum/thermal contact.
An SP structure suitable for holding and heating a QFP-type SMD 729 is shown in
As before, SP 737 includes grooves 744 recessed into its top surface, which run from portions of the SP's top surface that extend beyond planar-heater module 736 to a through-hole 746.
In this exemplary arrangement, a bellows 748 is placed between the bottom opening of through-hole 746 and the top surface of SMD 729. In this design, the vacuum sealing surface and the primary heat transfer surface are different. The primary heat transfer surfaces are the vertical walls that form the raised rim 740 of SP 737; the SP is designed such that, when holding SMD 729, its vertical walls are in direct contact with the SMD's I/O pins 750. The bellows surface that contacts the top surface of SMD 729 serves as a vacuum sealing surface 752. The bellows also serves to facilitate good thermal contact between the pins 750 and a rigid SP rim heating surface 740 during thermal expansion/contraction: the bellows will shorten or lengthen to keep the SP rim heating surface in direct contact with the SMD's pins, regardless of any differences in thermal expansion/contraction coefficients that may exist between the SMD body and the SP material.
An alternative SP arrangement suitable for use with a QFP-type SMD replaces raised rim 740 with a thermally conductive flexible metal strip. In this case, the SMD fits within the recessed portion formed by the metal strip, with the SMD's I/O pins in direct contact with the metal strip. In this case, the SP's bottom surface may be simply a flat surface with a through-hole, as the flexible metal strip will straighten or bend to maintain thermal contact with the pins, regardless of differences in expansion coefficients between the QFP body and the SP material.
Another SP design, suitable for holding and heating chips or SMDs having a flat top surface, where heating is to be transferred through the SMD body, typically to solder balls on the opposite side, is shown in
As before, one or more grooves 768 convey a vacuum from a vacuum enclosure 770 to a through-hole 772. For this embodiment, recessed portion 766 around hole 772 serves as both the heat transfer surface and the vacuum sealing surface. SMDs as small as 0.0079″ by 0.0079″ have been successfully held by vacuum, and attached and detached by soldering and de-soldering, respectively, using this type of SP.
Attachment clips 774 may be fitted over the bottom of SP 760 and onto the side walls of vacuum enclosure 770. As before, thermal insulation pads 776 may be bonded to the clips or the vacuum enclosure.
Note that the SPs described herein, as well as the heating and vacuum systems with which they are used, may be implemented in many different ways. It is only necessary that the SP include top and bottom surfaces, a through-hole which extends from the top surface to the bottom surface, and at least one groove recessed into the top surface so that a vacuum applied to the groove can be conveyed to the bottom surface via the groove and through-hole. A means of attaching the SP such that its top surface is in close thermal proximity to a contact heating source's planar surface is also needed, such that the SP conveys heat between the planar surface and a component being held to the SP by vacuum suction.
While particular embodiments of the invention have been shown and described, numerous variations and alternate embodiments will occur to those skilled in the art. Accordingly, it is intended that the invention be limited only in terms of the appended claims.
This application claims the benefit of provisional patent application No. 60/901,905 to Devey et al. filed Feb. 16, 2007, and is a continuation-in-part of patent application Ser. No. 11/290,942 to Durston et al. filed Nov. 29, 2005, which claimed the benefit of provisional patent application No. 60/631,913 to Durston et al. filed Nov. 29, 2004 and provisional patent application No. 60/684,539 to Durston et al. filed May 24, 2005.
Number | Date | Country | |
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60901905 | Feb 2007 | US | |
60631913 | Nov 2004 | US | |
60684539 | May 2005 | US |
Number | Date | Country | |
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Parent | 11290942 | Nov 2005 | US |
Child | 12029777 | US |