Abstract: A module for multiple network pluggable optics is disclosed. The module includes a Printed Circuit Board (PCB); a faceplate connected to the PCB; a plurality of cage assemblies connected to the PCB, each cage assembly is configured to receive a pluggable optical module via a corresponding opening in the faceplate; and a shared heat exchanger that is integrally formed and substantially covers the plurality of cage assemblies, wherein the shared heat exchanger is configured to cool multiple pluggable optics in the plurality of cage assemblies.

Abstract: A module for multiple network pluggable optics is disclosed. The module includes a Printed Circuit Board (PCB); a faceplate connected to the PCB; a plurality of cage assemblies connected to the PCB, each cage assembly is configured to receive a pluggable optical module via a corresponding opening in the faceplate; and a shared heat exchanger that is integrally formed and substantially covers the plurality of cage assemblies, wherein the shared heat exchanger is configured to cool multiple pluggable optics in the plurality of cage assemblies.

Abstract: A platform includes a housing with a front side, a rear side opposite the front side, a right side adjacent to both the front side and the rear side, and a left side opposite the right side and adjacent to both the front side and the rear side, wherein airflow in the platform is between the front side and the rear side or between the front side and the front side; one or more modules in the housing each including a plurality of cages supporting removable interface cards, wherein the airflow includes an air path that is over the one or more modules between a bottom portion of the one or more modules and a top portion of the one or more modules; and at least one dust cap in one of the plurality of cages, wherein the dust cap includes an air filter medium enabling airflow at an intermediate point of the air path.

Abstract: A module for multiple network pluggable optics is disclosed. The module includes a faceplate, a plurality of cage assemblies, and a plurality of springs. The faceplate includes a front face, a first wall extending from the front face, the first wall including a heat exchanger, and a second wall extending from the front face, the second wall being offset from the first wall. The plurality of cage assemblies is positioned at least partially within a volume defined by the front face and the first and second walls. Each cage assembly is configured to receive a pluggable optical module. The plurality of springs are configured with one or more springs positioned between each cage assembly and the second wall to push the plurality of cage assemblies towards the first wall such that each pluggable optical module received into one of the plurality of cage assemblies is pressed against the heat exchanger.

Abstract: A platform includes a housing with a front side, a rear side opposite the front side, a right side adjacent to both the front side and the rear side, and a left side opposite the right side and adjacent to both the front side and the rear side, wherein airflow in the platform is between the front side and the rear side or between the front side and the front side; one or more modules in the housing each including a plurality of cages supporting removable interface cards, wherein the airflow includes an air path that is over the one or more modules between a bottom portion of the one or more modules and a top portion of the one or more modules; and at least one dust cap in one of the plurality of cages, wherein the dust cap includes an air filter medium enabling airflow at an intermediate point of the air path.

Abstract: A module for multiple network pluggable optics is disclosed. The module includes a faceplate, a plurality of cage assemblies, and a plurality of springs. The faceplate includes a front face, a first wall extending from the front face, the first wall including a heat exchanger, and a second wall extending from the front face, the second wall being offset from the first wall. The plurality of cage assemblies is positioned at least partially within a volume defined by the front face and the first and second walls. Each cage assembly is configured to receive a pluggable optical module. The plurality of springs are configured with one or more springs positioned between each cage assembly and the second wall to push the plurality of cage assemblies towards the first wall such that each pluggable optical module received into one of the plurality of cage assemblies is pressed against the heat exchanger.

Abstract: The present disclosure provides pluggable optical modules that are prevented from reaching potentially dangerous temperatures when a fiber optic connector is not present and engaged with the associated module housing. Further, the present disclosure provides fiber optic connectors and/or pluggable optical modules that incorporate a port heat shield external to the associated face plate when the pluggable optical modules and fiber optic connectors are engaged, thereby preventing a user from contacting potentially hot and dangerous metallic surfaces of the module housings, as well as providing access for cooling air flow. The solutions presented herein are equally applicable to fixed optical ports and connectors as well.

Abstract: The present disclosure provides pluggable optical modules that are prevented from reaching potentially dangerous temperatures when a fiber optic connector is not present and engaged with the associated module housing. Further, the present disclosure provides fiber optic connectors and/or pluggable optical modules that incorporate a port heat shield external to the associated face plate when the pluggable optical modules and fiber optic connectors are engaged, thereby preventing a user from contacting potentially hot and dangerous metallic surfaces of the module housings, as well as providing access for cooling air flow. The solutions presented herein are equally applicable to fixed optical ports and connectors as well.

Abstract: The present disclosure provides pluggable optical modules that are prevented from reaching potentially dangerous temperatures when a fiber optic connector is not present and engaged with the associated module housing. Further, the present disclosure provides fiber optic connectors and/or pluggable optical modules that incorporate a port heat shield external to the associated face plate when the pluggable optical modules and fiber optic connectors are engaged, thereby preventing a user from contacting potentially hot and dangerous metallic surfaces of the module housings, as well as providing access for cooling air flow. The solutions presented herein are equally applicable to fixed optical ports and connectors as well.

Abstract: The present disclosure provides pluggable optical modules that are prevented from reaching potentially dangerous temperatures when a fiber optic connector is not present and engaged with the associated module housing. Further, the present disclosure provides fiber optic connectors and/or pluggable optical modules that incorporate a port heat shield external to the associated face plate when the pluggable optical modules and fiber optic connectors are engaged, thereby preventing a user from contacting potentially hot and dangerous metallic surfaces of the module housings, as well as providing access for cooling air flow. The solutions presented herein are equally applicable to fixed optical ports and connectors as well.

Abstract: An optical transceiver cooling assembly includes stacked cages mounted to a PCB. A heat radiator also is mounted on the PCB. Cooling devices (e.g., heat pipes) are coupled to the heat radiator and at least one of the cages. In some embodiments, the cages may include a divider that extends beyond the cage and is coupled to at least one of the cooling devices outside the cage. In some embodiments, the cooling devices extend into the cage and may be coupled together.

Abstract: An optical transceiver cooling assembly includes stacked cages mounted to a PCB. A heat radiator also is mounted on the PCB. Cooling devices (e.g., heat pipes) are coupled to the heat radiator and at least one of the cages. In some embodiments, the cages may include a divider that extends beyond the cage and is coupled to at least one of the cooling devices outside the cage. In some embodiments, the cooling devices extend into the cage and may be coupled together.

Abstract: An optical transceiver cooling assembly includes stacked cages mounted to a PCB. A heat radiator also is mounted on the PCB. Cooling devices (e.g., heat pipes) are coupled to the heat radiator and at least one of the cages. In some embodiments, the cages may include a divider that extends beyond the cage and is coupled to at least one of the cooling devices outside the cage. In some embodiments, the cooling devices extend into the cage and may be coupled together.

Abstract: An optical transceiver cooling assembly includes stacked cages mounted to a PCB. A heat radiator also is mounted on the PCB. Cooling devices (e.g., heat pipes) are coupled to the heat radiator and at least one of the cages. In some embodiments, the cages may include a divider that extends beyond the cage and is coupled to at least one of the cooling devices outside the cage. In some embodiments, the cooling devices extend into the cage and may be coupled together.