A wireless process variable transmitter for use in an industrial process includes a process variable sensor configured to sense a process variable of the industrial process and provide a process variable sensor output. A battery power source includes a plurality of battery power banks each having a primary cell battery, a low voltage cut-off circuit electrically connected to the primary cell battery which provides an electrical connection to the primary cell battery while a voltage of the primary cell battery is above a threshold, and an ideal diode having an input electrically connected to the primary cell battery through the low voltage cut-off and providing a power bank output. A power sharing node has an input connected to the battery power bank output of each of the plurality of battery power banks and having a shared power output which provides power to circuitry of the wireless process variable transmitter.

The present disclosure relates to systems, methods, apparatuses, devices, and techniques for providing electronic consoles. The electronic consoles can include a modular assembly that permits components to be arranged if varying configurations. Additionally, the electronic consoles can be configured to operate in various operational modes, including an extended reality (XR) mode, a desktop mode, and a television set top box mode. The electronic consoles can execute extended reality applications, including virtual reality applications, augmented reality applications, and/or mixed reality applications.

Apparatuses are provided for adapting USB, Thunderbolt, and similar connections to an Ethernet connection with dynamic multiplex power supply. The apparatuses of this disclosure are adapted to connect and power a peripheral device via its Ethernet port from a USB, Thunderbolt, or similar connection of a host computer. A power multiplexer is utilized in conjunction with a current detection circuitry and a PoE enable logic block to provide and regulate dynamic multiplex power supply from a multiplicity of power sources including an external direct current and a USB or Thunderbolt connection from a host computer.

An electrical power distribution system with least one converter module having a converter to make electrical DC voltage power with adjustable maximum power values available on a multiplicity of electrical output interfaces of the converter module up to a maximum module power value and a temperature control apparatus having a temperature measuring apparatus. The temperature control apparatus is coupled upstream of the at least one converter module to adapt the maximum module power value of the at least one converter module as a function of the temperature of the power distribution system as measured by the temperature measuring apparatus. The temperature control apparatus is designed to create a profile of the temperatures measured by the temperature measuring apparatus as a function of the maximum power values made available by the converter.

An electrical power distribution system with least one converter module having a converter to make electrical DC voltage power with adjustable maximum power values available on a multiplicity of electrical output interfaces of the converter module up to a maximum module power value and a temperature control apparatus having a temperature measuring apparatus. The temperature control apparatus is coupled upstream of the at least one converter module to adapt the maximum module power value of the at least one converter module as a function of the temperature of the power distribution system as measured by the temperature measuring apparatus. The temperature control apparatus is designed to create a profile of the temperatures measured by the temperature measuring apparatus as a function of the maximum power values made available by the converter.

A power distribution device has a resin part covering a portion of a power line and a portion of a signal line and having a switch adjacent to one surface of the resin part, and a cooling part disposed adjacent to a back surface of the resin part opposite to the one surface. The power line and the signal line each have, inside the resin part, a laid-out portion extending in a planar direction orthogonal to an arrangement direction in which the one surface and the back surface are arranged, and a led-out portion extending from the laid-out portion toward the one surface. The laid-out portion of the power line and the laid-out portion of the signal line are located in a projection area of the cooling unit projected in the arrangement direction, and are separated from each other and arranged in the arrangement direction.

A power distribution device has a resin part covering a portion of a power line and a portion of a signal line and having a switch adjacent to one surface of the resin part, and a cooling part disposed adjacent to a back surface of the resin part opposite to the one surface. The power line and the signal line each have, inside the resin part, a laid-out portion extending in a planar direction orthogonal to an arrangement direction in which the one surface and the back surface are arranged, and a led-out portion extending from the laid-out portion toward the one surface. The laid-out portion of the power line and the laid-out portion of the signal line are located in a projection area of the cooling unit projected in the arrangement direction, and are separated from each other and arranged in the arrangement direction.

A load operating device includes a power supply device which is detachable from a load and can supply power to the load in a state of being attached to the load and an electrical connection device which is provided integrally with the load and electrically connects the power supply device and the load in a state where the power supply device is attached to the load. The power supply device has a capacitor which stores power to be supplied to the load and a processing unit in which a power supply circuit from the capacitor to the processing unit via the electrical connection device is established in a state where the power supply device is electrically connected to the electrical connection device.

A load operating device includes a power supply device which is detachable from a load and can supply power to the load in a state of being attached to the load and an electrical connection device which is provided integrally with the load and electrically connects the power supply device and the load in a state where the power supply device is attached to the load. The power supply device has a capacitor which stores power to be supplied to the load and a processing unit in which a power supply circuit from the capacitor to the processing unit via the electrical connection device is established in a state where the power supply device is electrically connected to the electrical connection device.

A light emitting load driving device includes a first constant current source structured to be serially connected to a first light emitting load group; a second constant current source structured to be serially connected to a second light emitting load group; a first load connection terminal structured to be connected to the first light emitting load group; a second load connection terminal structured to be connected to the second light emitting load group; and a control circuit structured to be supplied a first voltage applied to the first load connection terminal, a second voltage applied to the second load connection terminal, and a reference voltage applied to the control circuit, wherein the control circuit is structured to select a minimum voltage between the first voltage and the second voltage, and the control circuit is structured to equalize the minimum voltage and the reference voltage.