LANXESS has developed a new concept for radar sensors with integrated thermal management that will benefit autonomous driving. The radar sensors are an essential component of, for example, distance control, lane change monitoring, collision avoidance and blind spot monitoring systems.

The sensors have to be dust- and water-proof and so are designed as fully enclosed systems. But this makes it difficult for heat to be effectively dissipated from the inside, which, in turn, can impair the performance of the electronics and durability of the sensors.

“This is why we developed a concept that allows heat to be dissipated by means of thermally conductive plastics in combination with metallic cooling elements,” introduced Gregor Jaschkewitz, application developer in the High Performance Materials (HPM) business unit at LANXESS. “The individual sensor components are assembled using integrated snap fits and hot rivets, a process that is much less costly and time-consuming than using screws.”

For a radar sensor, this new concept from LANXESS involves the following individual components: a front cover (“radome”), radar absorber, PCB – including antennas – and back cover with an integrated cooling element.

LANXESS develops concept for radar sensors with integrated thermal management.

The radome faces away from the vehicle and has to be made from a plastic offering a high degree of transmission for the radar waves. PBT is a well suited material here because it has a low dielectric constant (Dk) and loss factor (Df).

The back cover is the most complex part of the whole assembly. It is manufactured in a plastic-metal compound (hybrid) technique with polyamide 6 and a metallic cooling element. This enables engineers to leverage the huge design freedom offered by the injection molding process, allowing them to integrate features such as reinforcement and cooling ribs as well as slots for connectors and the strain-relieved attachment of cables.

Most importantly of all, however, the surface of the metallic cooling element can be overmoulded with thin areas of plastic. “The heat generated on the electronic components of the PCB can be efficiently dissipated from the whole assembly through these plastic areas. This effect is supported by thermally conductive polyamide 6 from our Durethan BTC product range as injection molding material,” said Gregor Jaschkewitz.

Another benefit of the hybrid design is that the metallic cooling element shields the electronics inside the radar sensor against electromagnetic radiation, which means that its function is not impaired by external radiation. The assembly can be sealed with O-rings or sealing lips created in a two-component injection molding process.

With most concepts for plastic radar sensors, the radome and back cover have always traditionally been made from thermoplastics that can be welded to each other to create a fully enclosed assembly. This generally meant that the same plastics had to be used for joining the two components. “Our approach, however, places fewer restrictions on the choice of materials and makes it easier to use tailor-made compounds,” pointed out Gregor Jaschkewitz.

LANXESS expects that sensors for driver assistance systems will offer a wealth of opportunities for its Durethan polyamides and Pocan polyesters. “We want to benefit from the huge growth potential in this application segment and advance technological innovation with our own ideas – like the concept for radar sensors,” added Dr. Christopher Hoefs, a global application development expert in HPM. For example, the business unit also recently unveiled a concept for the modular design of charging connections for electric vehicles.

In addition, HPM has pooled its knowhow in material, application, process and technology development under the HiAnt brand in order to support partners and customers in projects.

LANXESS has developed a new concept for radar sensors with integrated thermal management that will benefit autonomous driving. The radar sensors are an essential component of, for example, distance control, lane change monitoring, collision avoidance and blind spot monitoring systems.

The sensors have to be dust- and water-proof and so are designed as fully enclosed systems. But this makes it difficult for heat to be effectively dissipated from the inside, which, in turn, can impair the performance of the electronics and durability of the sensors.

“This is why we developed a concept that allows heat to be dissipated by means of thermally conductive plastics in combination with metallic cooling elements,” introduced Gregor Jaschkewitz, application developer in the High Performance Materials (HPM) business unit at LANXESS. “The individual sensor components are assembled using integrated snap fits and hot rivets, a process that is much less costly and time-consuming than using screws.”

For a radar sensor, this new concept from LANXESS involves the following individual components: a front cover (“radome”), radar absorber, PCB – including antennas – and back cover with an integrated cooling element.

LANXESS develops concept for radar sensors with integrated thermal management.

The radome faces away from the vehicle and has to be made from a plastic offering a high degree of transmission for the radar waves. PBT is a well suited material here because it has a low dielectric constant (Dk) and loss factor (Df).

The back cover is the most complex part of the whole assembly. It is manufactured in a plastic-metal compound (hybrid) technique with polyamide 6 and a metallic cooling element. This enables engineers to leverage the huge design freedom offered by the injection molding process, allowing them to integrate features such as reinforcement and cooling ribs as well as slots for connectors and the strain-relieved attachment of cables.

Most importantly of all, however, the surface of the metallic cooling element can be overmoulded with thin areas of plastic. “The heat generated on the electronic components of the PCB can be efficiently dissipated from the whole assembly through these plastic areas. This effect is supported by thermally conductive polyamide 6 from our Durethan BTC product range as injection molding material,” said Gregor Jaschkewitz.

Another benefit of the hybrid design is that the metallic cooling element shields the electronics inside the radar sensor against electromagnetic radiation, which means that its function is not impaired by external radiation. The assembly can be sealed with O-rings or sealing lips created in a two-component injection molding process.

With most concepts for plastic radar sensors, the radome and back cover have always traditionally been made from thermoplastics that can be welded to each other to create a fully enclosed assembly. This generally meant that the same plastics had to be used for joining the two components. “Our approach, however, places fewer restrictions on the choice of materials and makes it easier to use tailor-made compounds,” pointed out Gregor Jaschkewitz.

LANXESS expects that sensors for driver assistance systems will offer a wealth of opportunities for its Durethan polyamides and Pocan polyesters. “We want to benefit from the huge growth potential in this application segment and advance technological innovation with our own ideas – like the concept for radar sensors,” added Dr. Christopher Hoefs, a global application development expert in HPM. For example, the business unit also recently unveiled a concept for the modular design of charging connections for electric vehicles.

In addition, HPM has pooled its knowhow in material, application, process and technology development under the HiAnt brand in order to support partners and customers in projects.