This application provides a polygonal spherical sampling device, belonging to the technical field of spherical field antenna measurement, and including a probe, a mounting rack and a supporting platform. The supporting platform is mounted on the mounting rack for placing an object to be tested. The number of the probes is more than or equal to six, the probes are mounted on the mounting rack and a plurality of the probes are distributed on at least two vertical planes in a three-dimensional spherical space and are arranged around the supporting platform. The vertical planes are arranged symmetrically about a vertical axis, the probes are uniformly distributed at intervals of A degrees on each vertical plane, the probes on a same horizontal plane are uniformly distributed at intervals of B degrees, both A and B are less than or equal to 90.

A battery connection device (10) for connecting to a battery (12) of a vehicle is disclosed. The battery connection device (10) comprises a top member (20), a bottom member (14) having a side wall (18) and a bottom wall (16) connected to the side wall (18), the side wall (18) being connected to the top member (20) such that the top member (20) and the bottom member (14) form a box-like enclosure (22), the bottom wall (16) further including a through-hole (24) with a circumferential face (28), an adapter member (26) arranged inside the box-like enclosure (22) and extending at least partially through the through-hole (24) for connection with the battery (12), wherein a dimension of the adapter member (26) is smaller than a dimension of the through-hole (24) such that a gap is formed between an outer face (30) of the adapter member (26) facing the circumferential face (28) and the circumferential face (28), and flexible connection member (32) connected to the adapter member (26) and to the bottom member (14) and closing the gap between the outer face (30) and the circumferential face (28), wherein the flexible connection member (32) includes an electromagnetic shielding function for shielding electromagnetic radiation and a sealing function for sealing the gap against dust and/or moisture.

A shielding housing includes a receptacle configured to receive an electrical connector assembly including an electrical connector and a mating connector connected to the electrical connector. The receptacle is formed as a straight passage with an opening at each end of the straight passage. Either end of the straight passage receives one of the electrical connector and the mating connector along a mating axis coaxial with the straight passage.

A transition for an optical fibre cable (11) through a partition. The optical fibre cable (11) is received inside a shield pipe (1, 4), which shield pipe (1, 4) is of an electrically conductive material. The shield pipe (1, 4) is received in an axial through opening (6, 21) of the holding means. One end of the shield pipe (1, 4) is received inside a holding means having a sealing function.

A modular system of plastic walls having embedded and coextensive electrically conductive components configured to electrically connect with each other when the walls are mated. The walls have joining edges that form joint seams with other walls when joined together to create an enclosure. When enough walls are used to surround a storage space, a Faraday cage is created. The walls additionally have portions of tortuous paths at each joining edge that mate with a complementary portion of a tortuous path of another wall when the walls are joined together. A torturous path seal is thereby created at each joint seam. The plastic walls can be configured in a multiplicity of combinations to create various enclosures necessary for RFID-enabled storage and tracking of medical articles. Containers, enclosures, cabinets, and drawers of differing heights and sizes can be made and they may be stacked or otherwise assembled.

An exemplary electromagnetic shielded dry bag with magnetic closure system includes an outer bag, an inner shielding liner, and a pair of embedding strips having magnets embedded therein. The outer bag is preferably comprised of water-proof material and has a fluid-sealed floor portion and an access mouth disposed oppositely thereof. First and second bag panels are disposed oppositely of one another and extend from the floor portion to the access mouth. The inner shielding liner is comprised of electromagnetic shielding material and defines an electromagnetic shielding compartment within the bag. The embedding strips are secured to respective bag panels. This securement may be by way of heat fusing of respective securement elements to the inner faces, thereby forming pockets with which the strips reside. When the closure section is magnetically retained in closed configuration, the access mouth is thereby retained in an RF-sealed and fluid-sealed configuration to protect the shielding compartment.

A modular system of medical article containers is used to form enclosures of selectable storage space. The containers are each RF shielded and include an interconnect wall for connecting to another container to form the enclosure. The interconnect walls have a complementary design. The interconnect seam of two containers includes an electrically conductive component that also interconnects the RF shields of the two containers together. The interconnect seam also includes a tortuous path seal for greater RF shielding of the enclosure. The walls of the containers include a substrate of non-electrically conductive material for weight reduction and an electrically conductive element that is coextensive with the substrate. One embodiment is a plastic substrate with a metallic mesh. The enclosure provides a Faraday cage about the interconnected containers. Enclosures of differing heights and sizes can be made, and they may be stacked or otherwise assembled.

A system and a method of providing electromagnetic compatibility (EMC) protection. A removable component is inserted into an end product. The removable component includes a retractable EMC protection apparatus. In response to the insertion of the removable component a shape memory alloy on the EMC protection apparatus is heated to a temperature above the activation temperature of the shape memory alloy. The shape memory alloy then changes from a first shape to a second shape in response to the heating. In response to the change in the shape of the shape memory alloy an EMC protection component of the EMC protection apparatus is inserted into an enclosure opening of the removable component.

A junction box used for making electrical connections to a photovoltaic panel. The junction box has two chambers including a first chamber and a second chamber and a wall common to and separating both chambers. The wall may be adapted to have an electrical connection therethrough. The two lids are adapted to seal respectively the two chambers. The two lids are on opposite sides of the junction box relative to the photovoltaic panel. The two lids may be attachable using different sealing processes to a different level of hermeticity. The first chamber may be adapted to receive a circuit board for electrical power conversion. The junction box may include supports for mounting a printed circuit board in the first chamber. The second chamber is configured for electrical connection to the photovoltaic panel. A metal heat sink may be bonded inside the first chamber.

A system and a method of providing electromagnetic compatibility (EMC) protection. A removable component is inserted into an end product. The removable component includes a retractable EMC protection apparatus. In response to the insertion of the removable component a shape memory alloy on the EMC protection apparatus is heated to a temperature above the activation temperature of the shape memory alloy. The shape memory alloy then changes from a first shape to a second shape in response to the heating. In response to the change in the shape of the shape memory alloy an EMC protection component of the EMC protection apparatus is inserted into an enclosure opening of the removable component.