Patent Description:
Electrical rotating machines, such as electric motors or generators, have become widespread and are found in numerous applications and configurations. Electric machines include a stationary component (i.e., the stator) and a rotating component (i.e., the rotor). In electric motors, a magnetic field is established in the rotor, for example via magnets mounted to the rotor or via an electrical current applied to, or induced in, a coil wound on the rotor. A second, rotating magnetic field is established as a result of a stator current produced by a controlled voltage applied to the stator. Rotation of the magnetic field in the stator causes the magnetic field in the rotor to follow the stator field, thereby causing rotation of the rotor. A shaft or other drive member is mounted to the rotor and extends outside the rotor housing providing a mechanical coupling to a device, such as a gearbox, pump, or fan that is to be driven as the rotor rotates. The amplitude and frequency of the controlled voltage applied to the stator is varied to achieve desired operation of the motor.

As is known to those skilled in the art, motor controllers, also referred to herein as motor drives, are utilized to vary the amplitude and frequency of the voltage applied to a motor to achieve desired operation of the motor. A motor controller is configured to receive power at an input, where the input power may be supplied from either an alternating current (AC) source or a direct current (DC) source. If the input power is supplied from an AC source, a rectifier section converts the AC power to DC power. The DC bus, either from the output of the rectifier section or supplied directly from the DC source, is provided to a DC bus within the motor controller. A current regulator and modulation techniques are used to control an inverter section which, in turn, supplies the required current and voltage to the motor from the DC bus to achieve desired operation of the motor.

The inverter section includes power semiconductor switching devices such as bipolar junction transistors (BJTs), insulated gate bipolar transistors (IGBTs), or metal oxide semiconductor field effect transistors (MOSFETs). The switching devices are rapidly switched on and off to alternately connect a positive DC voltage, a negative DC voltage, or a common voltage on the DC bus to the output of the inverter section. Using known switching algorithms, the voltage at the output of the inverter section will have a fundamental AC component at a desired amplitude and frequency which will provide desired operation of a motor.

The power semiconductor switching devices, however, experience power losses within the device during operation. Some power is dissipated in each device from current conducted through each device, also referred to as conduction losses. Additional power is dissipated in each device when the device transitions between OFF and ON states, also referred to as switching losses. Still additional power is dissipated in each device from other causes, also referred to as parasitic losses. The power dissipated in each device tends to be converted to heat energy within the device, causing the temperature of the device to rise. It is important to remove the heat from the power switching devices to avoid a catastrophic failure of the switching device.

Historically, motor drives have been mounted inside control cabinets. The control cabinet may include an air conditioning unit to remove heat from within the cabinet. In some applications, the cabinet itself may be located in an environmentally controlled space, such that heat generated within the motor drive may be easily removed. However, recent improvements in motor drives have resulted in the motor drive being mounted to the motor. A motor drive mounted on the motor is referred to as an integrated motor drive. Because the motor drive is mounted on the motor, it is no longer located within a control cabinet but rather is located in the manufacturing or other environment in which the controlled machine or process is located. The ambient temperature for the controlled machine or process may be greater than within a control cabinet or within a control room housing the control cabinet. Thus, heat management for an integrated motor drive is more challenging than for a cabinet-mounted motor drive.

In order to assist with dissipating heat generated in an integrated motor drive, the power semiconductor switching devices have commonly been mounted to a copper baseplate using a Direct Bond Copper (DBC) process. The copper baseplate serves as a heat sink for the DBC mounted power semiconductor devices, and the copper baseplate is mounted to the housing of the integrated motor drive. The integrated motor drive is, in turn, typically mounted to a side of the motor housing, where the outside surface of the wall for the motor drive housing that is mounted to the motor has the copper baseplate mounted to the inside surface. This mounting arrangement provides a thermal conduction path from the switching devices, through the copper baseplate, through the integrated motor drive housing, and into the housing for the motor. Heat is then be radiated out to the ambient environment from the motor housing.

However, mounting the integrated motor drive to the side of the motor housing is not without drawbacks. The motor also generates heat during normal operation which is dissipated through the housing of the motor. The heat generated in the motor is a result of the current flowing in the motor, and the amount of current flowing in the motor corresponds to the torque the motor is able to produce. If additional heat is being transferred to the motor housing from the integrated motor drive, the total heat generated by the motor and the integrated motor drive must be limited.

Limiting the amount of heat generated by the motor, the integrated motor drive, or both is done by derating the devices. Derating the motor requires limiting the maximum amount of current which may be conducted by the motor and, as a result, limiting the amount of torque produced by the motor. Derating the integrated motor drive requires limiting the amount of current conducted through the power switching devices when compared to a similarly sized motor drive that is cabinet-mounted. Limiting the current in the motor drive, in turn, limits the amount of heat generated within the power switching devices. As still another option, both the motor and the motor drive may have some derating, such that the heat generated by both elements may be successfully dissipated from the motor housing.

Derating either the motor or the motor drive, however, requires larger motors or larger motor drives to handle the same power and to provide the same amount of work as a motor controlled by a cabinet-mounted motor drive. The larger devices increase the size and cost of the system.

Thus, it would be desirable to provide an improved system and method for cooling switching devices in an integrated motor drive. <CIT> discloses a motor drive apparatus. The motor drive apparatus includes a motor and an ECU with an ECU housing. The ECU housing includes a heat sink having a module receiving portion. The module receiving portion includes a heat-receiving surface and an opening portion open to one-end side of the ECU housing. The ECU further includes a control substrate received by the ECU housing to be perpendicular to the heat-receiving surface and to face the motor; a plurality of semiconductor modules each received in the module receiving portion and connected electrically with the control substrate to control a power supply of the motor. Each of the plurality of semiconductor modules includes a heat-radiating surface at an outer portion thereof. The ECU further includes a module retaining section pressing the heat-radiating surface to the heat-receiving surface to retain each of the plurality of semiconductor modules in the module receiving portion.

According to one embodiment of the invention, a system for cooling switching devices in a motor drive includes a housing for the motor drive, where the housing for the motor drive is configured to mount to a motor housing. A volume is defined within an inner periphery of the housing, and at least one switching device is mounted within the motor drive. The at least one switching device is operatively controlled to convert a first voltage present on a DC bus within the motor drive to a second voltage present at an output of the motor drive, and the second voltage is configured to control operation of a motor to which the motor drive is mounted. A circuit board, on which each of the at least one switching devices is mounted, is mounted within the volume of the housing for the motor drive. A potting material is inserted into the volume of the housing for the motor drive after the circuit board is mounted, and the potting material covers each switching device mounted on the circuit board and extends from the circuit board to the inner periphery of the housing for the motor drive. The circuit board includes at least one thermal via extending through layers of the circuit board and is positioned where each of the at least one switching devices is mounted. According to another embodiment of the invention, there is provided a method for cooling switching devices in a motor drive, the system comprising: mounting at least one switching device to a circuit board including a first side on which the at least one switching device is mounted, a second side opposite the first side, and at least one thermal via extending through layers of the circuit board between the first side and the second side of the circuit board and positioned where the at least one switching devices is mounted; mounting the circuit board with the at least one switching device in a housing for the motor drive, wherein the housing for the motor drive is configured to mount to a motor housing; filling a volume within the housing with a potting material, wherein the potting material covers the at least one switching device mounted on the circuit board and extends from the circuit board to an inner periphery of the housing for the motor drive; operatively controlling the at least one switching device to convert a first voltage present on a DC bus within the motor drive to a second voltage present at an output of the motor drive; and conducting heat generated from controlling the at least one switching device via the potting material to the housing for the motor drive, wherein the step of conducting the heat further comprises: conducting a first portion of the heat from the at least one switching device through the circuit board by the at least one thermal via; conducting the first portion of the heat from the second side of the circuit board to the inner periphery of the housing for the motor drive via the potting material, and conducting a second portion of the heat from the at least one switching device to the inner periphery of the housing for the motor drive via the potting material.

The subject matter disclosed herein describes an improved system and method for cooling switching devices in an integrated motor drive. As previously discussed, mounting an integrated motor drive to a motor has previously required derating the motor, the motor drive, or a combination of the motor and motor drive. In addition, the DBC mounting process further requires a complex assembly process After mounting the power semiconductor switching devices to the copper baseplate, the terminals of the switching devices must be connected to a circuit board to receive control signals. The terminals of the power semiconductor devices require bond wires connected between the terminals and a circuit board substrate using a wire-bonding process that requires specialized knowledge.

In contrast, the present invention allows the power semiconductor switching devices to be mounted directly to the circuit board substrate. Each switching device may be mounted to the circuit board substrate via a "pick and place" assembly process. The terminals of the switching devices are soldered to pads on the circuit board. Mounting the switching devices via the pick and place process eliminates the wire-bonding process, simplifying construction and reducing the cost of the integrated motor drive.

As also previously discussed, the construction of integrated motor drives has previously resulted in heat transfer from the motor drive to the housing of the motor. The heat transfer was due primarily to mounting the copper baseplate to a surface of the housing for the integrated motor drive which was, in turn, mounted to a surface of the motor housing. The primary thermal conduction path from the integrated motor drive has been through the motor housing.

In contrast, the present invention contemplates that the housing for the integrated motor drive is mounted to an end of the motor housing. The integrated motor drive according to the present invention is configured to conduct heat to the sides of the motor drive housing and out to the ambient environment. Mounting the integrated motor drive to the end of the motor housing significantly reduces or eliminates the heat transfer to the motor housing and, in turn, significantly reduces or eliminates the need to derate the motor and/or integrated motor drive.

Conduction of heat to the sides of the integrated motor drive is a function of how the power semiconductor devices are mounted within the integrated motor drive. After mounting the power semiconductor switching devices to the circuit board substrate, the circuit board substrate is then mounted within the housing for the integrated motor drive and, preferably, in a generally central orientation within the housing. The circuit board substrate, however, typically provides better thermal insulation than conduction. Similarly, air around the switching devices serves as a poor thermal conductor. As a result, a potting material is provided within the housing of the integrated motor drive and around the circuit board. The potting material substantially encloses the circuit board and fills the volume within the integrated motor drive. The potting material is selected to provide good thermal conductivity between the circuit board and the housing of the integrated motor drive. The potting material is also selected to provide flexibility such that expansion and contraction of the potting material due to heating and cooling of the material does not damage the circuit board or the electronic components mounted to the circuit board. The present invention, therefore, provides a simplified construction process and reduces, or potentially eliminates, the need for derating of the motor or integrated motor drive.

Turning initially to <FIG>, an exemplary integrated motor drive <NUM> is illustrated mounted to a motor <NUM>. The integrated motor drive <NUM> includes a power section <NUM> and a control section <NUM>. The power section <NUM> includes components typically handling, for example, <NUM>-<NUM> VAC or <NUM>-800VDC, and the power section <NUM> receives power in one form and utilizes power switching devices to regulate power output to the motor <NUM> in a controlled manner to achieve desired operation of the motor <NUM>. The control section <NUM> includes components typically handling, for example <NUM> VAC or <NUM>-58VDC and, the control section <NUM> includes processing devices, feedback circuits, and supporting logic circuits to receive feedback signals and generate control signals within the motor drive <NUM>.

The power section <NUM> is configured to receive a first voltage at an input <NUM> and provide a second voltage at an output <NUM>. According to the illustrated embodiment, the input <NUM> receives a DC voltage, which is provided to a positive rail <NUM> and a negative rail <NUM> of a DC bus <NUM> within the integrated motor drive <NUM>. It is contemplated that a rectifier unit or an active front end (AFE) may be provided within a control cabinet at a location remote from the integrated motor drive <NUM>. The rectifier unit or AFE receives an AC voltage, for example, from a utility grid, and converts the AC voltage to a DC voltage for delivery to the integrated motor drive <NUM>. The rectifier unit or AFE may be sized such that it may supply a DC voltage to multiple integrated motor drives <NUM> distributed about the controlled machine or process. A rectifier section will typically include electronic devices, such as diodes, suitable for passive rectification of the AC voltage to a DC voltage. An AFE will typically include other solid-state devices including, but not limited to, thyristors, silicon-controlled rectifiers (SCRs), or transistors which receive control signals to convert an AC voltage to a DC voltage for the DC bus <NUM>. According to another aspect of the invention, a rectifier unit or AFE may be included within the integrated motor drive <NUM> and the integrated motor drive <NUM> may receive an AC voltage and covert the AC voltage to a DC voltage internal to the integrated motor drive.

The DC bus <NUM> supplies the DC voltage present on the bus as an input to an inverter section <NUM>. Referring also to <FIG>, the inverter section <NUM> consists of switching elements, such as transistors, thyristors, or SCRs as is known in the art. The illustrated inverter section <NUM> includes a MOSFET <NUM> and a free-wheeling diode <NUM> connected in pairs between the positive rail <NUM> and each phase of the output voltage as well as between the negative rail <NUM> and each phase of the output voltage. Each of the MOSFETs <NUM> receives gating signals <NUM> to selectively enable the transistor and to convert the DC voltage from the DC bus <NUM> into a controlled three phase output voltage to the motor <NUM>. According to the illustrated embodiment, a processor <NUM> in the motor drive <NUM> may be configured to generate the gating signals <NUM>. Optionally, a processor <NUM> may execute a control module, as discussed further below, and provide a voltage reference signal to a gate drive module. The gate drive module converts the voltage reference signal to the gating signals <NUM> to control operation of each transistor <NUM> When enabled, each transistor <NUM> connects the respective rail <NUM>, <NUM> of the DC bus <NUM> to the inverter output <NUM>. The illustrated inverter output <NUM> supplies a three-phase AC voltage to the motor, where a first phase is present on 50U, a second phase is present on 50V, and a third phase is present on 50W. The inverter output <NUM> is connected to the motor drive output <NUM> and, in turn, to the motor <NUM>.

The processor <NUM> in the motor drive <NUM> receives a reference signal <NUM> identifying desired operation of the motor <NUM> connected to the motor drive. The reference signal <NUM> may be, for example, a position reference (θ*), a speed reference (ω*), or a torque reference (T*). The processor <NUM> also receives feedback signals indicating the current operation of the motor drive <NUM>. A position feedback device <NUM> is operatively connected to the motor <NUM> to provide a position feedback signal to the motor drive <NUM>. The position feedback signal may be an analog signal, such as a sinusoidal signal, a series of pulses, provided singularly or in quadrature, or a digital data packet according to a serial communication protocol for the position feedback device <NUM>. The position feedback signal provides angular position of the motor <NUM> to the motor drive <NUM> used to control operation of the motor <NUM>,.

As illustrated, feedback signals are provided directly to the processor <NUM>. This is for ease of illustration. Feedback signals will typically include additional logic circuits including, but not limited to, analog to digital (A/D) converters, buffers, amplifiers, and any other components that would be necessary to convert a feedback signal in a first format to a signal in a second format suitable for use by the processor <NUM> as would be understood in the art. The motor drive <NUM> may include a voltage sensor <NUM> and/or a current sensor <NUM> on the DC bus <NUM> generating a feedback signal corresponding to the magnitude of voltage and/or current present on the DC bus <NUM>. The motor drive <NUM> may also include one or more voltage sensors <NUM> and/or current sensors <NUM> on the output phase(s) of the inverter section <NUM> generating a feedback signal corresponding to the magnitude of voltage and/or current present at the output <NUM> of the motor drive <NUM>. The processor <NUM> utilizes the feedback signals and the reference signal <NUM> to control operation of the inverter section <NUM> to generate an output voltage having a desired magnitude and frequency for the motor <NUM>.

Turning next to <FIG>, one embodiment of an integrated motor drive before insertion of potting material <NUM> is illustrated. The motor drive <NUM> includes a housing <NUM> where the sides <NUM> are shown as transparent to view the arrangement of circuit boards <NUM> within the motor drive. The housing <NUM> includes a first end <NUM>, configured to be mounted to an end of a housing for the motor <NUM>, and a second end <NUM> opposite the first end. Four sides <NUM> extend between the first end <NUM> and the second end <NUM> to define a box-like structure for the housing <NUM>. With reference also to <FIG>, a volume <NUM> is defined within an interior of the housing <NUM>. The volume <NUM> extends from an inner surface of the first end <NUM> to an inner surface of the second end <NUM> and within the inner periphery of each side <NUM>.

According to the embodiment illustrated in <FIG>, three circuit boards <NUM> are inserted into the volume <NUM> of the housing <NUM>. An end cap <NUM> on the first end <NUM> of the housing may be removed to allow insertion into the housing <NUM>. It is contemplated that the interior surface of the second end <NUM> may include a mounting bracket in which each circuit board <NUM> is inserted. It is contemplated that a first circuit board 90A and a third circuit board 90C generally include the processor <NUM>, memory <NUM> and all additional logical components for the control section <NUM> of the motor drive <NUM>. The second circuit board 90B may generally include the power switching devices <NUM> and each of the other components from the power section <NUM> of the motor drive. The illustrated embodiment is not intended to be limiting and it is contemplated that there may be either less than or more than three circuit boards <NUM> included within the integrated motor drive <NUM>. It is further contemplated that components from the control section <NUM> or from the power section <NUM> may be distributed among any combination of circuit boards <NUM> according to application requirements. After inserting the circuit boards <NUM> into the volume <NUM> of the housing <NUM> and making any required electrical connections to the circuit boards, the remainder of the volume is filled with a potting material <NUM> to at least a sufficient height to cover the circuit boards <NUM>.

With reference to <FIG>, an integrated circuit package <NUM> may include one or more MOSFETs <NUM>. The integrated circuit package <NUM> is mounted to one of the circuit boards <NUM>. Each circuit board <NUM> is a multi-layer board. According to the illustrated embodiment, the circuit board <NUM> includes four layers 92A-92D. The number of illustrated layers is not intended to be limiting and it is contemplated that the circuit board <NUM> may have fewer than or greater than four layers 92A-92D. The integrated circuit package <NUM> is mounted to solder pads <NUM> on the first layer 92A of the circuit board. A first solder pad 95A and a second solder pad 95B are illustrated for each of two terminals from the integrated circuit package <NUM>. Each terminal would be mounted to a separate solder pad. The solder pads <NUM> are connected via traces on the circuit board to other electronic devices according to the circuit board layout and design.

Each layer <NUM> of the circuit board <NUM> is typically made up of a dielectric material. Each dielectric material is electrically insulating and is commonly a poor thermal conductor as well. To improve thermal conduction from the first layer 92A of the circuit board <NUM> to the fourth layer 92D of the circuit board, a series of thermal vias <NUM> are located beneath the footprint of the integrated circuit package <NUM>. Additionally, the copper material <NUM> from which traces may be formed is left beneath the integrated circuit package <NUM> and between each layer <NUM>. The vias <NUM> are also copper material and may be filled, providing a solid copper path between the layers <NUM> of the circuit board <NUM>. The integrated circuit package <NUM> may be electrically mounted to the solder pads <NUM> and the body of the integrated circuit package <NUM> may contact or be located proximate a top layer of copper material <NUM>. The body of the integrated circuit package <NUM> is not electrically conductive, but heat radiates or is conducted from the body of the integrated circuit package <NUM> to the copper layer <NUM> and through the vias <NUM> to the lower surface of the circuit board <NUM>.

During operation of the motor drive <NUM>, the potting material <NUM> is configured to provide a thermal conduction path for heat generated within each integrated circuit package <NUM> to the housing <NUM> for the motor drive. As previously discussed, the MOSFETs <NUM> in the inverter section <NUM> of the integrated motor drive <NUM> generate heat during operation. Switching losses, conduction losses, and parasitic losses, result in heat being built up within each of the integrated circuit packages <NUM>. Because the potting material <NUM> envelopes the circuit boards <NUM>, potting material <NUM> is in contact with a top surface of the integrated circuit package <NUM>, as well as the outer layers <NUM> of the circuit board <NUM>. A portion of the heat generated in each integrated circuit package <NUM> is transmitted through the circuit board <NUM> via the thermal vias <NUM> and the copper material <NUM> in the circuit board <NUM>. Another portion of the heat generated in each integrated circuit package <NUM> is transmitted directly to the potting material <NUM>. Some of the heat which is initially transmitted through the circuit board <NUM> may radiate outward within the circuit board <NUM>. The potting material <NUM> is in contact with the circuit board <NUM> and with the thermal vias <NUM> and copper material <NUM> on the lower layer 92D of the circuit board. Thus, the heat generated by the MOSFETs <NUM> within the integrated circuit packages <NUM> is conducted either directly from the integrated circuit package or indirectly via the circuit board <NUM> to the potting material <NUM>.

Historically, potting material is typically used on circuit boards in small amounts to help affix a circuit component to the circuit board. For example, a lead-mounted capacitor may have leads inserted through and then soldered to the circuit board. The body of the capacitor extends away from the circuit board. However, vibration on the device in which the circuit board is mounted may cause the body of the capacitor to similarly vibrate Over time, the vibration may cause the leads to move back and forth and eventually break off from the circuit board. Potting material may be applied at the base of the capacitor which becomes rigid when dried. The potting material holds the lead-mounted capacitor to the circuit board and helps prevent vibration between the component and the board which, in turn, helps prevent a failure of the connection to the board. This potting material, however, is not suitable for use in large amounts to fill the volume <NUM> within the housing <NUM> of the motor drive <NUM>.

The present inventors have determined that a potting material <NUM> which has good thermal conductivity and which has some elasticity is desirable for filling the volume <NUM> of the housing <NUM>. Many potting materials are thermally insulating materials. The present invention contemplates using the potting material <NUM> to establish a thermal conduction path between the circuit board <NUM> and the housing <NUM> of the motor drive <NUM>. According to one aspect of the invention, the potting material <NUM> has a thermal conductivity of at least <NUM> W/(m·K). According to a preferred embodiment of the invention, the potting material <NUM> has a thermal conductivity of at least <NUM> W/(m·K).

Additionally, the potting material <NUM> will be conducting heat away from the switching devices <NUM> in the inverter section <NUM> of the motor drive <NUM>. In some applications, a motor <NUM> may operate in a near continuous operating state, such that a constant amount of thermal energy is generated by the switching devices <NUM>. In other applications, a motor <NUM> may start and stop for varying durations of time. During periods of operation, thermal energy is generated by the switching devices <NUM> which, in turn, is transferred to and heats the potting material <NUM>. During periods of inactivity, no thermal energy is generated by the switching devices <NUM>, allowing the heat within the potting material <NUM> to dissipate through the housing <NUM>, cooling the potting material <NUM>. Heating and cooling of the potting material <NUM> will cause expansion and contraction of the potting material <NUM>. If a rigid potting material is selected, as discussed above, the expansion and contraction of the potting material would exert force on the electronic components mounted to the circuit boards <NUM>. Expansion and contraction of a rigid material could damage the components on the circuit boards <NUM>. Thus, potting material <NUM> with some elasticity is desirable.

In order to allow expansion and contraction of the potting material <NUM> within the volume <NUM> of the housing <NUM> and avoid damaging components on the circuit boards <NUM>, a soft potting material <NUM> is selected. The soft potting material <NUM> allows for compression against an electronic component without pushing the component off of the circuit board <NUM>. The soft potting material further allows for the potting material to expand upward within an upper void <NUM> within the housing <NUM>. The potting material <NUM> is filled within the housing <NUM> for a sufficient volume <NUM> to cover the circuit boards <NUM>. The potting material envelopes the circuit boards and fills the volume <NUM> around the circuit boards <NUM> to an inner periphery of the housing <NUM> for the motor drive <NUM>. However, some volume is retained above the potting material <NUM> to define the upper void <NUM> when the end cap <NUM> is affixed to the housing <NUM>. According to one aspect of the invention, the potting material <NUM> has a hardness less than or equal to seventy on a Shore A hardness scale. According to a preferred embodiment of the invention, the potting material <NUM> has a hardness less than or equal to <NUM> on the Shore A hardness scale. According to one embodiment of the invention, LOCTITE® SI <NUM>™ is selected as the potting material <NUM>.

Use of the potting material <NUM> within the integrated motor drive <NUM> and mounting the housing <NUM> for the motor drive <NUM> to the end of the motor housing, allows for operation of the integrated motor drive <NUM> with little or no derating of the motor drive <NUM> in comparison to a cabinet-mounted motor dive. Previous integrated motor drives using DBC and mounting to a side surface of the motor required derating of the motor drive between about thirty and forty percent (<NUM>-<NUM>%). Eliminating the prior derating allows motor drives of smaller size and less cost to be mounted to the motor <NUM> for an integrated motor drive package.

It should be understood that the invention is not limited in its application to the details of construction and arrangements of the components set forth herein. The invention is capable of other embodiments and of being practiced or carried out in various ways. Variations and modifications of the foregoing are within the scope of the present invention. It also being understood that the invention disclosed and defined herein extends to all alternative combinations of two or more of the individual features mentioned or evident from the text and/or drawings. All of these different combinations constitute various alternative aspects of the present invention. The embodiments described herein explain the best modes known for practicing the invention and will enable others skilled in the art to utilize the invention.

Claim 1:
A system for cooling switching devices in a motor drive, the system comprising:
a housing (<NUM>) for the motor drive (<NUM>), wherein:
the housing (<NUM>) for the motor drive (<NUM>) is configured to mount to a motor housing, and
a volume (<NUM>) is defined within an inner periphery of the housing (<NUM>);
at least one switching device (<NUM>) mounted within the motor drive (<NUM>), wherein:
the at least one switching device (<NUM>) is operatively controlled to convert a first voltage present on a DC bus (<NUM>) within the motor drive (<NUM>) to a second voltage present at an output (<NUM>) of the motor drive (<NUM>), and
the second voltage is configured to control operation of a motor (<NUM>) to which the motor drive (<NUM>) is mounted;
a circuit board (<NUM>) on which each of the at least one switching devices (<NUM>) is mounted, wherein the circuit board (<NUM>) is mounted within the volume (<NUM>) of the housing (<NUM>) for the motor drive (<NUM>); and
a potting material (<NUM>), wherein:
the potting material (<NUM>) is inserted into the volume (<NUM>) of the housing (<NUM>) for the motor drive (<NUM>) after the circuit board (<NUM>) is mounted, and
the potting material (<NUM>) covers the at least one switching device (<NUM>) mounted on the circuit board (<NUM>) and extends from the circuit board (<NUM>) to the inner periphery of the housing (<NUM>) for the motor drive (<NUM>),
wherein the circuit board (<NUM>) includes at least one thermal via (<NUM>) extending through layers (92A, 92B, 92C, 92D) of the circuit board (<NUM>) and positioned where each of the at least one switching devices (<NUM>) is mounted.