The present invention relates to a semiconductor cooling arrangement for cooling semiconductor devices, such as power semiconductors. Such arrangements are advantageous in the field of inverters due to the high power losses and associated heat generated by such devices.
Electrical and electronic components generate heat as a by-product when they are in use. Overheating usually impacts performance and component lifetime and therefore electrical and particularly electronic components are typically cooled to prevent overheating.
Devices have limitations on the upper temperature at which they may be effectively operated and as limit temperatures are breached so devices may become less efficient and may fail. In most instances devices are unable to recover from failures due to overheating and the whole system in which they are a part becomes unusable, requiring repair or in many cases “burnt out” modules/systems are replaced.
Prevention being better than cure much effort has gone to making systems more robust, but ease of repair is also of value.
Many different approaches have been used to address overheating limitations: Some have sought to increase the operating limit of devices, though the scope for this is limited, whilst the majority of effort has been focussed on removal of heat from devices, sub-modules and systems. In many power electronics applications, heat sinks are used where efficient heat dissipation is required. Heat sinks absorb and dissipate heat from electrical components by thermal contact. For example, a heat sink may be soldered, bonded or otherwise mounted to a power electronic device to improve heat removal by providing a large thermal capacity into which waste heat can flow.
In high power applications the heat sink may be enlarged to improve thermal capacity. However increasing the size of a heat sink increases the weight and volume of a power supply module and correspondingly the cost. In many instances the available space for such modules particularly for automotive applications is decreasing rather than the reverse.
Considerable effort has been applied to cooling of electronic components in computing systems wherein central processing units (CPUs) have many millions of semiconducting devices integrated onto the surface of a silicon die. Though heat loss from any one device is small, integration density has led to total heat dissipation being high and is a severe limitation on speed and lifetime of CPUs.
Some of the technologies for cooling electronic components in computing systems have also been applied in cooling of high power single or low level integration semiconducting switch devices.
In US2011/103019 there is described a liquid tight enclosure providing immersion cooling of an electronic system in which a cold plate is proposed having a liquid conduit for supplying coolant to the cold plate, said cold plate having a bottom surface coupled to an electronic component of the electric system and at least one open port on the side walls. In a particular embodiment coolant supplied by a conduit enters the top of the cooling plate and is partially allowed to exit through side ports, whilst remaining coolant is caused to flow through jets directed onto high heat flux components: Side port apertures and jet orifices being dimensioned to provide optimised cooling of components.
US2011/103019 is particularly directed towards cooling of CPUs in computers and describes cooling of a high powered processor chip mounted on a substrate said substrate being electrically and mechanically attached to a processor module which is further attached to a printed circuit board.
A disadvantage of US2011/103019 is poor heat spreading through said substrate and particularly poor heat spreading through connections to said printed circuit board.
For medium power converter modules there is another order of power dissipation to contend with, currents of 100's of amps and voltages of the order of 1000V in play. For medium power converters semiconducting switch devices are used and US2011/0242760 teaches an arrangement wherein semiconducting switch devices are mounted on laminated busbars so as to maintain electrical isolation between phases.
Prior to US2011/0242760 said lamination in busbars would have been a temperature limiting feature, whereas US2011/0242760 teaches applying a liquid cooled heatsink to the said laminated busbars wherein the heatsink is electrically isolated from the busbar. Removal of heat from busbars and by thermal conduction from electrically isolated switch devices mounted thereon improves overall power capacity, before temperature rise and thermal limitation of insulation layers is again a limiting factor.
US2014204532 provides an alternate mode of cooling of heat dissipating semiconducting devices using impingement jets wherein application of jet cooling (air, or liquid in an air matrix) is controlled locally by thermally deformable nozzles made from shape memory alloy which is thermally connected to semiconducting devices to be cooled. In this way devices may be cooled when required. However US2014204532 is directed towards chip level cooling with impingement jets focussed on backside of flip-chips. Teaching of US2014204532 is to liquid-in-air jets and is thereby limited in its cooling capacity and because cooling is at chip scale, pinout configurations further limit the connectivity of such cooling arrangements.
US2011141690 speaks to the use of a high thermally conductive printed circuit board substrate on one side of which is configured into the surface, features to promote turbulence in an impinging coolant flow whilst the other side of the circuit is configured to have electrical circuitry onto which are mounted power electronic components, for instance components of a power inverter module for use in a vehicle. The electrical circuitry side is electrically isolated from the side configured to promote turbulence.
Substrates such as direct bonded copper or direct bonded aluminium are suggested which comprise a ceramic (usually alumina) sandwich with copper or aluminium outer layers. However though these direct bonded substrates are good thermal conductors they are also expensive to manufacture and difficult to handle and carry out repairs.
Other approaches for improved cooling of power semiconducting devices include direct immersion of components in dielectric fluids and configuring of components to form coolant channels, use of phase change liquid/gas coolant systems to increase coolant effect.
In combination with these approaches particularly for power electronic systems has been optimisation of switching speed of power semiconducting switch devices: Reasoning for this is as follows—the faster the switch speed the less time the switch device spends in resistive mode and hence less joule heating losses in the device—however fast switching speeds increase inductive losses which may also lead to voltage spikes, hence a need for large low inductance busbars and symmetric phase legs in inverter modules and costly overvoltage specified capacitors.
A compromise is reached which inevitably leads to joule heating losses in semiconducting device switches. Despite best attempts all cooling approaches to date have been deficient in their cooling abilities and cooling efficiency of power semiconductor components has been a limiting feature of maximum power handling and power density for power semiconducting switch devices and hence power inverters.
The present invention seeks to increase the power density and maximum power handling of power inverters and semiconducting switch devices respectively, by significantly improving removal of waste heat and at the same time further reducing system wide inductance and corresponding joule heating losses in semiconducting switch devices.
We have therefore appreciated the need for an improved cooling arrangement.
The present invention therefore provides a semiconductor cooling arrangement, comprising: one or more semiconductor assemblies, each assembly comprising a heatsink and one or more semiconductor power devices thermally coupled to the heatsink; a housing for housing the one or more assemblies in a chamber within the housing, the housing comprising inlet and outlet ports in fluid communication with the chamber respectively for receiving and outputting a cooling fluid, the chamber being flooded with a cooling fluid to cool the assemblies; wherein the heatsink comprises heat exchanging elements in the form of a plurality of holes in the heatsink extending through the heatsink from a front face of the heatsink, onto which the one or more semiconductor power devices are coupled, to a rear face of the heatsink opposing the front face, such that the cooling fluid flows through the holes to extract heat from the heatsink. The heatsink may have a flat form, although this may instead be shaped, or have features protruding from its surface, such as fins or other arrangements to aid the cooling.
Advantageously, the combination of the heatsink being submerged in the cooling fluid, and the presence of the holes, through which the cooling fluid flows, provides a cooling arrangement having superior cooling properties, which is well suited for applications such as inverters.
The holes may be located in the heatsink in the form of a single row of holes surrounding the periphery of each of the one or more semiconductor power devices coupled to the heatsink. Where there are two or more semiconductor power devices, there may be areas in the heatsink between the single row of holes surrounding the periphery of neighbouring semiconductor power devices that are devoid of holes. With this design, there is a balance to be made between the heatsink's ability to extract heat from the power devices, and the number of holes used to transfer that heat into the cooling fluid. Too many or too few holes will result in a heatsink that has a cooling performance that is sub-optimal.
The semiconductor power devices may be electrically coupled to the heatsink. In this configuration, and the heatsink is configured as a bus bar to electrically connect the one or more semiconductor power devices together to transmit power between the one or more semiconductor power devices. This enables the design to be compact, since the heatsink also enables the power devices to be coupled electrically with one another. This also advantageously reduces inductive pathways between the components, again improving the electrical performance of the assemblies mounted on the heatsink busbar.
The one or more semiconductor power devices may comprise an IGBT, Silicon carbide (SiC) semiconducting switch devices, metal oxide semiconducting field effect transistors (MOSFETs), or power diodes.
The one or more semiconductor power devices may be mechanically connected to or are bonded to the heatsink.
One or more of the semiconductor assemblies may be mounted to a Printed Circuit Board (PCB), the PCB providing electrical connections between the one or more semiconductor power devices. The PCB and additional lower power electrical and electronic components mounted on the PCB may also be located within the chamber and immersed in the cooling fluid.
With this arrangement of the PCB, the one or more semiconductor devices may be co-located within the chamber, and the lower power electrical and electronic components are co-located within a different area of the chamber to the one or more semiconductor power devices. Such an arrangement means that higher power devices are grouped with other high power devices, and lower power devices are group with other lower power devices, which enables better management of the cooling.
The inlet port in fluid communication with the chamber may be configured to flow cooling fluid more favourably in the areas of the chamber occupied by the semiconductor devices. 51% to 99% of the cooling fluid flow may be caused to flow in the areas of the chamber occupied by the semiconductor devices. Preferably 95% of the cooling fluid flows in the area occupied by the one or more semiconductor power devices, which are power devices that create the greatest amount of heat within the chamber. This arrangement advantageously targets the “hot spots” to supply the cooling fluid to those areas that need it most.
When there are two or more semiconductor assemblies located within the chamber, each assembly may be arranged such that the cooling fluid flows through the holes in one of the heatsinks and impinges on the surface of the next heatsink in the flow path of the cooling fluid. Causing the outflow of cooling fluid from one heatsink to impinge on the surface of the next heatsink greatly improves the cooling arrangement, since the cooling fluid is forced to meander through the chamber and contact as much surface of the heatsinks as possible before flowing through the holes of the heatsinks and removing further heat.
The two or more semiconductor assemblies may be arranged to be offset from one another such that the holes of one heatsink are out of alignment with the holes in the next heatsink. Again, this encourages the cooling fluid to meander through the chamber, contacting as much surface area of the heatsinks within the chamber, instead of flowing straight through the holes of each of the assemblies.
The two or more semiconductor assemblies may be arranged parallel to one another. They may instead be arranged at angles from one another in some embodiments.
One or more heatsinks may comprise a cooling fluid distributor for distributing the cooling fluid. Such a cooling fluid distributor may increase the cooling efficiency of the heatsink. This cooling fluid distributor may comprises first and second layers of a distributor attached to the rear face of the heatsink, where the rear face of the heatsink is the face of the heatsink opposing the face having the semiconductor power devices coupled thereto. The first layer may comprise an outer layer and having a plurality of holes extending between front and rear faces of the first layer, the holes being located on an area of the heatsink associated with the positions of the one or more semiconductor power devices. The second layer, sandwiched between the heatsink and the first layer, may comprise a row of holes located in a position equivalent to a periphery of each of the semiconductor power devices coupled to the heatsink, and a plurality of guides extending inward of the position of the holes in the second layer to guide cooling fluid between the holes in the first layer and the holes in the second layer.
The semiconductor cooling arrangement may comprise one or more baffle plates arranged within the housing in the flow path of the cooling fluid between the inlet and the outlet, the one or more baffle plates comprising a plurality of holes in the baffle plate extending through the baffle plate between a front face and a rear face, such that the cooling fluid flows through the holes. Such an arrangement advantageously set up impinging jets of cooling fluid, which may impinge on components or the heatsinks. The baffle plates may also provide turbulent flow of the cooling fluid.
Each of the one or more baffle plates may be arranged within the housing to be adjacent to a respective one of each of the one or more semiconductor assemblies and located in the flow path between the inlet and the respective semiconductor assembly.
Each of the one or more baffle plates may be arranged within the housing to be within 1 mm to 5 mm, preferably 2 mm, of a respective one of each of the one or more semiconductor assemblies. Such close proximity of the baffle plate enables impinging jets of cooling fluid and/or turbulent flow of the cooling fluid to impinge on the heatsink and thus remove heat from the heatsink more efficiently.
The plurality of holes of the baffle may comprise one or more groupings of a plurality of holes in each baffle plate, each grouping of a plurality of holes being associated with a respective one of each of the one or more semiconductor power devices thermally coupled to the heatsink, and each of the grouping of the plurality of holes inn the baffle plate are arranged to be in the flow path of the cooling fluid between the inlet and the respective one of each of the one or more semiconductor power devices.
Each of the one or more groupings of a plurality of holes may comprise an array of a plurality of holes. Each array of a plurality of holes may be dimensioned to be of a similar width and height of the area of the heatsink covered by the respective one or more semiconductor power devices on the heatsink.
The holes may be shaped to provide a turbulent flow of the cooling fluid.
The holes of the heatsink, and/or of the baffle (where one is present) may have a circular, rectangular, rounded rectangular or a star shape. Furthermore, the diameter of the holes increases between the front face and the rear face. This gives the holes a countersunk appearance when viewed from the rear face, and advantageously provides a hole profile that has a reduced effect on the flow rate of the cooling fluid compared to holes having straight sided profiles.
The cooling fluid may be a dielectric cooling fluid. It may be pumped so as to cause the fluid to flow between the inlet port and the outlet port. The inlet port and outlet port may be coupled to a cooling circuit comprising a heat exchanger, the heat exchanger for removing heat from the cooling fluid.
The one or more semiconductor assemblies may be configured to form an inverter for converting between DC and AC.
When the inverter is configured to convert DC to AC, the inverter may comprise one or more electrical inputs for receiving one or more DC voltages, and one or more electrical outputs for outputting one or more AC voltages. The output of the inverter may power an electric motor.
When the inverter is configured to convert AC to DC, the inverter may comprise one or more electrical inputs for receiving one or more AC voltages, and one or more electrical outputs for outputting one or more DC voltages. The output of the inverter may charge a battery or other electrical storage device.
The inverter may be configurable as a bidirectional inverter for converting DC to AC and AC to DC, the bidirectional inverter comprising one or more DC ports for receiving or outputting one or more DC voltages, and one or more AC ports for inputting or outputting one or more AC voltages.
The present invention will now be described, by way of example only and with reference to the accompanying figures, in which:
In brief, the present invention relates to a semiconductor cooling arrangement in which one or more semiconductor assemblies are located in a chamber within a housing. The housing comprises inlet and outlet ports for receiving and outputting a cooling medium. The chamber is flooded with a cooling medium to cool the assemblies. The assemblies themselves each comprise a heatsink and one or more semiconductor power devices thermally coupled to the heatsink. The heatsink comprises heat exchanging elements in the form of a plurality of holes in the heatsink extending through the heatsink from one surface to another surface such that the cooling medium flows through the holes to extract heat from the heatsink.
With reference to
Semiconductor devices 110 are thermally connected to a thermal and electrically conductive capping material 150 which is also linked to the substrate 160 by electrically insulating but thermally conducting columns or walls 170. Heat dissipated in semiconducting devices 110 finds escape in to circuit board/substrate 160 and thereafter columns/wall 170 to capping material 150, heat from semiconducting devices 110 also finds a more direct link to capping material 150 by way of a thermal conducting but electrically insulating medium 140. Capping material 150 becomes the preferred heatsink by virtue of coolant fluid which is pumped into cavity 180 through port(s) 130 and exiting to a heat exchanger (not shown) via port(s) 120. Direction of coolant flow is shown by arrows. This indirect cooling approach maintains electrical isolation of semiconductor devices, but imposes thermal resistance between said devices and the eventual heatsink coolant fluid by using electrically insulating interposers.
In
It will be understood by those of reasonable skill in the art the arrangement of semiconducting devices 200 shown in
A more elaborate approach to immersion cooling, also demonstrating the current prior art, is shown in
This cooling approach is effective for bare die, but requires flip-chip packaging and is not supportive of high packing densities nor high current, low inductance interconnects between devices
With reference to
The combined heatsink-busbars 420 comprise holes 430 that have been drilled to allow coolant medium to pass through and thereby remove heat from the heatsink-busbar 420 whilst minimising loss of heat spreading potential of the heatsink-busbar 420 available to heat dissipating semiconducting devices 110 mounted thereon. In its purist form, the invention relies on the heatsink with holes, where the heatsink, as part of the semiconductor module (that is the module comprising the switching components 110 and the heatsink 420), is submerged in a cooling medium. The cooling medium flows around the module and through the holes, which are configured to extract heat from the heatsink as the medium flows through the holes.
Being modular, multiple assemblies can be housed within the chamber comprising the cooling medium such that all of the assemblies are cooled. Such an arrangement is shown in
The use of dielectric fluid immersion and fluid jet impingement cooling of semiconductor submodules and semiconducting device switches combined with the holes in the heatsinks is particularly advantageous in cooling the switches.
The use of heatsinks as electrical interconnection between heat dissipating power semiconducting devices is also advantageous, since this provides very low inductance, which means the devices can be driven harder and switched faster. Preferably the devices are soldered or equivalently bonded to the heatsink busbars in order to provide for a low electrical and thermal resistance between the switches and the heatsink.
All of these advantages provide a surprising improvement in power handling ability for power devices, such as power inverters, using the cooling arrangement of the present invention. Power densities are improved significantly over the present-day best in class power inverter module. Inverters utilising the present invention can be half the size of inverters of the prior art having the same power ability.
In
An input port(s) 490 provides coolant fluid into casing 480 and first sub-module 440a may provide a barrier to coolant flow except through hole arrays 430a, which may cause jetting of the cooling medium through the holes on to the subsequent sub-module 440. Spacing/distribution of said holes 430 will influence the cooling of semiconductor devices 110, with too many holes 430 surrounding a device, or too small a gap between holes 430 preventing heat spreading away from said device 110. Holes 430 may be in a single array as shown 430a or in a double or more concentric array (not shown).
Output port(s) not shown may be to the outside of the semiconducting system and to separately mounted heat exchanger and pump (not shown)
Whilst
The input and output port(s) could also be configured to provide preferential flow of cooling medium in desired areas of the chamber. For example, the assemblies may be configured such that the power semiconductor devices (which produce the most heat) are grouped together, and the lower power components (capacitors and resistors and the like) may be grouped together, but separately from the power semiconductor devices. In such an arrangement, the input and output port(s) may be configured to provide more cooling medium flow to the power semiconductor components, and a comparatively reduced flow of the cooling medium to the lower power components. For example, 51% to 99% of the flow may be attributed to the areas of the chamber holding the higher power components, and 49% to 1% (respectively) of the cooling medium flow attributed to the lower power electronics. A preferred ratio of cooling medium flow is considered 95%/5% higher power devices to lower power devices.
This may be achieved by using separate input ports configured to feed different areas of the chamber with the cooling medium, where the input port feeding the area of the chamber holding higher power devices has a greater bore than the input port feeding the area of the chamber holding the lower power devices.
Heatsink-busbars 420 are preferably made from electrically and thermally conducting material such as copper or aluminium or their alloys or any material which will both thermally and electrically conduct and provide electrical interconnection between semiconductor devices 110 and provide thermal pathways for heat dissipated in semiconductor devices to dissipate. Heatsink-busbars of the present invention are an integral part of the electronics electrical circuit.
Means of bonding/attaching/mounting semiconducting devices 110 to heatsink-busbars 420 may be mechanical e.g. via nut and bolt, or by soldering or brazing, or by using a room temperature liquid metal, or by electrically and thermally conductive adhesive or by vibration welding or any method that achieves thermal and ohmic electrical connection.
Heatsink-busbars of the present invention may be planar as represented in
Three phases are denoted by letters U, V, W and single phase “U” module is shown by a dashed outlined. Capacitors 711 and 712 enable splitting of DC supply rail +ve and −ve DC as may be seen in
Given the demonstrable advantageous cooling performance of the cooling arrangement of the present invention, such an inverter can be made having a significantly smaller footprint for the same performance levels of a much larger inverter(s).
With reference to
Thermal resistance for semiconducting devices 110 that are electrically connected to heatsinks 420 is considerably lower than if said devices 110 were electrically isolated from said heatsinks 420 by a non-electrically conductive layer. In the prior art, achieving similar thermal resistance values between multiple devices that are electrically isolated from heatsinks to which they are mounted is difficult to achieve in production and the weakest link (highest thermal resistance) becomes a limit on power dissipated. Uniformity of thermal and electrical connection is high for semiconducting devices 110 soldered to heatsink-busbars 420 and high uniformity can be achieved in production.
With excellent thermal connection achieved between semiconductor devices 110 and heatsink-busbars 420 enabled by solder connection, there is considerable thermal advantage gained through immersion of sub-modules 440 in a flowing coolant fluid and yet further considerable thermal advantage found by increasing the local surface area for heat removal by drilling or stamping holes 430 in said heatsink-busbar in an array peripheral to said mounted semiconducting devices 110.
Laminar flow of a coolant medium has low efficiency in removing heat from a substrate because said coolant medium has low velocity and may even be stationary in layers close to solid surfaces and in this instance heat is transferred by diffusion. In contrast flow of coolant medium through arrays of holes 430a, generates turbulent flow even for apparently low flow rates of coolant medium and turbulence is further enhanced by impingement on solid surfaces orthogonal to general coolant flow direction (shown by arrows 800), said coolant medium having to change direction before again being caused to flow through new arrays of holes 430a by virtue of offsets between said arrays.
An additional means of increasing the cooling ability of the heatsink and to ensure turbulent flow is shown in
In embodiments sequences of plates 910, 920, 240 are sandwiched
Whereas heatsink-busbar 240 is electrically and thermally conducting, there is no such requirement for plates 910 and 920 which may or may not be insulating and may advantageously be polymer injection moulded or stamped or otherwise mass produced.
An alternative way of increasing the cooling ability of the heatsink and to ensure turbulent flow is shown in
The baffle plate 445 comprises one or more regions 446 of through-holes in the plate. The through holes 446 may be arranged in a similar form to that of the through-holes in the heatsinks (as shown in
The plate may be made of metal or a dielectric. Preferably, the plate 445 is made of a dielectric, as this allows the plate 445 to be located very close to the heatsink without voltage concerns, for example within approximately 2 mm. The close proximity of the baffle plate 445 to the heatsink increases the cooling effect of the turbulent cooling medium. Furthermore, when the baffle plates are made from a dielectric material, and when located closely with the heatsinks, this enables neighbouring heatsinks to be located closer together due to the dielectric nature of the baffle plates, adding a layer of electrical insulation between the heatsinks.
Whilst
As with the device shown in
The input port(s) 490 provides coolant fluid into casing 480. The baffle plate 445 causes jetting of the cooling medium through the through-holes on to the subsequent sub-module 440a. Since it is preferred to have each baffle plate 445 very close to the respective heatsinks, it is possible that two baffle plates 445 may be preferred between the inlet 490 and the first sub-module 440a; a first between the inlet and a second baffle plate, and the second baffle plate very close to the first sub-module 440a. Preferably, each sub-module heatsink is co-located closely with a respective baffle 445 as described above in order to create the turbulent flow of cooling medium.
The combination of the holes in the heatsink, combined with the use of baffles as described above makes for an effective cooling mechanism. The baffle plates cause jet impingement on the back surface of the heatsink, and turbulent flow, which increases the heat transfer from the surface of the heatsink into the cooling medium. The heatsink has holes that let the fluid pass through it, which cools the semiconductor power devices bonded to the front of the heatsink. The holes in the heatsink are placed around the power devices to get maximum surface area close to the hot power devices backs. The fluid then mixes and swirls around the fronts of the power devices before being forced through the next baffle plate. This then repeats.
It has been demonstrated that have lots of swirl (turbulence) around the fronts of the power devices and the legs accounts for up to 30% of the heat removed from the power device package.
Advantageously, having mixing of the fluid while it swirls so that the next set of jets have the average temperature avoid hot spots down the line of heatsinks.
Furthermore, the baffle(s) used as shown in
a, b, c and
Whilst the holes are shown in an array, for example when used in the baffle plate, such holes may be used in the configuration used for the heatsink, that is a single row of holes surrounding a profile of the semiconductor power device.
A commonly used symbol
Whilst we have described the inverter being configured to convert a DC voltage to an AC voltage, for example for powering an electric motor, the inverter could instead be configured as an inverter to convert an AC voltage into a DC voltage. Such inverters may be useful for charging a battery or other electrical storage device. Furthermore, the inverter may instead be configured into a bidirectional inverter, which may covert between AC to DC and DC to AC voltages.
Coolant medium used in the present invention is a dielectric fluid for example, a poly alpha olefin (PAO), fluorocarbon fluid such as Fluoronert™, coolant fluids may be single or dual phase and cooling may be derived from liquid heat capacity or heat of vaporisation, such coolant media are well known and are useful for cooling electronic components, and systems e.g. semiconductor devices, capacitors and resistors and sub-assemblies assembled to form inverters and controllers. Said coolant may also be used to cool electric machines e.g. motors/generators that may be powered/controlled by said electronic systems.
In an example application of the above discussed aspects, a semiconductor arrangement is made from standard robust power (packaged) device IGBTs solder bonded to an aluminium heatsink, used as a busbar, 2 mm in thickness where IGBT devices are peripherally surrounded by 2 mm diameter holes spaced 2 mm apart. Additional control and low heat dissipating devices and power storage capacitors are mounted to standard printed circuit board in the usual manor and interconnected with IGBT devices via their pin legs. The whole inverter arrangement is submerged in a dielectric fluid where the cooling fluid is preferentially flowed across the busbar mounted components and through the peripheral holes in the heatsink.
It is found that a 100 kW channel cooled power inverter with 90% efficiency is improved in thermal capacity by 50% in the same physical envelope such that 150 kW inverter power is available from this example. Additionally it is found that power devices of different voltage potential when submerged in a dielectric fluid can be mounted in closer proximity than is possible in an air environment providing potential for even greater power density.
No doubt many other effective alternatives will occur to the skilled person. It will be understood that the invention is not limited to the described embodiments and encompasses modifications apparent to those skilled in the art lying within the scope of the claims appended hereto.
Number | Date | Country | Kind |
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1701486.1 | Jan 2017 | GB | national |
Filing Document | Filing Date | Country | Kind |
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PCT/GB2018/050260 | 1/30/2018 | WO | 00 |