The invention relates to a curing oven for heating compounds that are comprised in or located on electronic components. The term “curing oven” shall include reflow ovens, as the curing oven herein is also adaptable for use in reflowing processes.
Curing ovens are employed in semiconductor assembly for setting compounds such as epoxy resin and encapsulation molding compound that are introduced onto electronic components. These compounds are usually introduced onto electronic components in fluid form. They may also be suitable for reflowing. Based on the characteristics of these compounds, they may have to be heated according to specific heating profiles during the curing or reflowing process.
In particular, one implementation of curing ovens is in the curing of epoxy or reflowing of solder applied in the field of die bonding. Typically, semiconductor dice are bonded onto substrates such as leadframes using epoxy or solder as an adhesive. Epoxy is first introduced onto the substrate in fluid form at a bonding position, and a die is placed onto the epoxy at the bonding position. The epoxy or solder is then cured or reflowed by heating to solidify the bond.
Epoxy curing or reflowing using ovens is typically carried out according to specified heating profiles, such that the epoxy is exposed to various different temperatures during the curing or reflowing processes.
One common feature of prior art curing ovens is that, if the epoxy or solder compound is to be heated at different temperatures, the curing ovens must have multiple thermal zones. Thus, curing ovens typically consist of multiple thermal zones wherein each zone is maintained at a single temperature. A substrate is heated according to a specified heating profile when it travels through the different thermal zones.
The use of curing ovens requiring multiple thermal zones to conduct such heating has several disadvantages. One disadvantage is that the space occupied by the curing oven is relatively large because of the need to have multiple heating zones. Its construction is also relatively complex, as different temperature zones have to be maintained and the substrate has to be conveyed through all the different temperature zones. Hence the cost of the curing oven is high. For curing oven applications where there is small-scale production and/or space limitations, such prior art curing ovens are not economical or cost-effective.
Moreover, due to the large size of such prior art curing ovens and their construction complexity, sealing of their enclosures is difficult. Thus, where nitrogen or forming gas is required in the oven to maintain a low level of oxygen content and prevent oxidation of the substrate, a large amount of such gas has to be continuously pumped to the curing oven to compensate for the leakage. Furthermore, the interaction among the interfaces of the different thermal zones induces instability on the substrate during the curing process. The final curing result may thereby be adversely affected.
It is thus an object of the invention to provide a curing oven that is adapted to heat a compound to be processed according to a predetermined heating profile while avoiding the approach of using multiple thermal zones that are found in the above-described conventional curing ovens.
Accordingly, the invention provides an oven for curing or reflowing compounds on objects comprising: a heating chamber; a heating assembly mounted in thermal communication with the heating chamber to provide heat thereto; and a support assembly for supporting the object in the heating chamber for heating; wherein the heating assembly and support assembly are configured to be movable relative to one another for controllably positioning the object at variable distances with respect to the heating assembly, whereby to provide controlled heating of the object at different temperatures at different distances with respect to the heating assembly.
It will be convenient to hereinafter describe the invention in greater detail by reference to the accompanying drawings. The particularity of the drawings and the related description is not to be understood as superseding the generality of the broad identification of the invention as defined by the claims.
An example of a curing oven in accordance with the invention will now be described with reference to the accompanying drawings, in which:
In order to prevent oxidation of the substrate when it is being heated in the heating chamber 16, a relatively inert gas such as nitrogen gas or other forming gas is introduced into the curing oven 10 via a nitrogen gas inlet 22. Used nitrogen gas is allowed to exit the curing oven via an exhaust system, which may be in the form of nitrogen gas exhausts 24 incorporated into a top thermal insulation layer 25 of the curing oven 10. An upper heater block 26 in the upper heating assembly 12 serves to provide heat to the heating chamber 16. A gas discharge outlet such as a nitrogen gas discharge plate 28 mounted to the upper heater block 26 facilitates introduction of nitrogen gas by channeling it from the nitrogen gas inlet 22 into the heating chamber 16.
In the illustrated embodiment, nitrogen gas is introduced to the curing oven 10 via the nitrogen gas inlet 22 and channeled through a nitrogen gas inlet duct 50 before being distributed into nitrogen gas channels 54 formed in the upper heater block 26. The discharge plate 28 mounted to the upper heater block 26 has a plurality of nitrogen discharge holes 52. The nitrogen gas travels from the nitrogen gas channel 54 through the nitrogen discharge holes 52 into the heating chamber 16.
Used nitrogen gas then flows into an exhaust plate 27 through a plurality of exhaust channels 56. From the exhaust plate 27, nitrogen gas exits from the curing oven 10 through nitrogen gas exhaust outlets 24.
Nitrogen gas is also introduced into the curing oven 10 via a nitrogen gas inlet nozzle 30 coupled to the lower heating assembly 14. A cooling plate 36 is mounted onto the lower heater block 34 so that the temperature of the substrate is further controllable by exposing it near to the lower heating assembly 14. Heating means such as a lower heater block 34 in the lower heating assembly 14 provides heat to the cooling plate 36 and heating chamber 16. As will be described in more detail below, the cooling plate 36 includes a plurality of support wire slots 73 for receiving support wires that can be lowered below the top surface of the cooling plate 36.
Also coupled to the lower heating assembly 14 are cooling means, such as a compressed air inlet nozzle 32 that is operable to introduce cooling compressed air to the lower heating assembly 14 in order to lower the temperature of the cooling plate 36 and in the region around the lower heating assembly 14. Compressed air channels 76 incorporated in the lower heater block 34 help to cool the heater block 34 and cooling plate 36 if necessary in order to expeditiously counteract the heating effects from the lower heater block 34. A mounting plate 40 mounts the lower heating assembly 14 to the curing oven 10, and it is further enclosed with a bottom thermal insulation layer 42. Heater wire housings 74 are located at the side of the lower heater block 34 to shield cables and wires used to operate the lower heater block 34.
There is also a substrate support assembly comprising support rods 44 mounted on a support base 46 for supporting the substrate while it is being heated in the heating chamber 16. The substrate support assembly is configured to be movable relative to the upper heating assembly, as well as the lower heating assembly 14, for controllably positioning the object at variable distances with respect to the upper and lower heating assemblies 12, 14. This is to enable heating of the substrate at different temperatures at different distances with respect to the heating assemblies 12, 14.
Compressed air is introduced into the lower heating assembly 14 via the compressed air nozzle 32, which enters a network of compressed air channels 76 formed in the lower heater block 34. The compressed air can be used to cool the lower heating assembly 14, and counteracts heating by the lower heater block 34. The compressed air channels 76 are preferably distributed throughout the lower heater block 34 for distributing compressed air in the lower heating assembly 14, and may comprise one or more layers of connected channels.
The upper heating assembly 12 is the major heating source for the substrate. The lower heating assembly 14 may in one implementation be configured for use as a constant temperature block, and its temperature is preferably lower than that of the upper heating assembly 12. In the preferred embodiment, the lower heating assembly 14 is adapted to provide temperature control offering substrate heating and/or cooling by delivering heat to or extracting heat from the substrate. This can be done by thermal conduction, for example, by utilizing the cooling plate 36 mounted on the lower heating assembly 14.
Accordingly, it would be appreciated that in this preferred embodiment, the region around the upper heating assembly 12 is set higher than the temperature around the lower heating assembly 14, and both heating means and cooling means are comprised in the lower heating assembly to maintain, increase or decrease the temperature of the cooling plate 36 and/or the lower region of the heating chamber 16 relatively quickly as necessary.
The heating chamber 16 is arranged such that the upper heating assembly 12 is operative to create different isotherms in the heating chamber 16 that are located at different distances from the upper heating assembly 12. Consequently, a number of isotherms are established in the heating chamber, although it essentially comprises only one heating zone. Different isotherms have different isotherm values. Therefore, the substrate can be heated at different temperatures by positioning it at different isotherm positions.
A heating profile is created primarily by adjusting the relative distance between the upper heating assembly 12 and the substrate. Less importantly, the heating profile can be created by adjusting the relative distance between the lower heating assembly 14 and the substrate. The upper heating assembly 12 provides a convection and radiation heat to the substrate. Since the amount of heat transferred to the substrate changes with the separation distance between the substrate and the upper heating assembly 12, the larger the separation distance, the lower the amount of heat transferred to the substrate.
The curing oven 10 should have an adequate zone depth in order to provide sufficient temperature variation in the heating chamber 16 to heat a substrate according to the specified heating profile. The substrate support assembly should have minimal thermal mass to elevate or lower the substrate to specified positions in the heating chamber 16 so as to locate the desired isotherm at particular times during the curing process without contributing to its temperature. Depending on the required heating profile, the substrate support assembly is programmable to position the substrate at particular distances from the upper heating assembly 12 for specified durations.
In use, the system should be aware of the heating temperatures at different distances from the upper heating assembly 12 in order to accurately control heating of the substrate according to the required heating profile. The preferred method for doing this is to pre-calibrate the curing oven 10 to obtain a graph representing the temperatures at different separation distances from the upper heating assembly 12 in the heating chamber 16, based upon predetermined temperatures of the upper and lower heating assemblies 12, 14 and predetermined nitrogen gas flow rates. During heating, the substrate can be positioned for heating at different temperatures by referring to the said graph produced during calibration. Furthermore, it is preferred that a temperature sensor (not shown) is mounted to the substrate support assembly adjacent to the substrate position at the same or similar distance from the upper heating assembly 12 as the substrate for determining in real time the temperature to which the substrate is exposed. This allows for more accurate online determination of the heating temperature.
In the preferred embodiment of the invention described above, the curing oven 10 therefore comprises a primary temperature-controlled heating assembly 12 at the top as well as a temperature-controlled heating assembly 14 at the bottom. With the specified temperature controls on both upper and lower heating assemblies and the ability to provide independent time intervals at each portion of the heating profile, various heating profiles such that those shown in
It should also be appreciated that other orientations of the heating sources are possible, such as locating the primary heating assembly at the bottom of the curing oven 10 instead of at the top. Further, with a suitable transportation mechanism, it is also feasible to put the temperature-controlled heating assembly at the side of the heating chamber 16 and control the temperature at which the substrate is heated by changing its relative distance to the heating assembly. It may also be possible to move a temperature-controlled heating source instead of moving the substrate by keeping the substrate stationary, or to move both relative to each other.
An advantage of the preferred embodiment of the current invention is that it employs a single-zone concept in which the heating profile for a substrate is created inside a single thermal zone. Therefore, the size and construction complexity of the curing oven can be substantially reduced. This is especially beneficial for small-scale production facilities and where there are space constraints that prevent the installation of conventional multiple-zone curing ovens.
Moreover, as the oven size is relatively small, sealing becomes easier and therefore, the consumption of nitrogen or forming gas to maintain a low level of oxygen content to prevent oxidation is correspondingly lower. The single zone concept also eliminates the need for zonal interaction and the instability that this might cause. A more thermally stably environment is thereby provided for the substrate in the curing process.
Furthermore, unlike multiple-zone ovens that have differences of separation distances between the substrate and heating devices in different zones that may result in inconsistent heating, the curing oven according to the preferred embodiment of the invention is capable of providing a continuously consistent temperature range and zone depth since the distance of the substrate to the heating device is controllable.
The invention described herein is susceptible to variations, modifications and/or additions other than those specifically described and it is to be understood that the invention includes all such variations, modifications and/or additions which fall within the spirit and scope of the above description.
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