Provided is an electrical junction box configured promptly release the electrical junction box from a state where water has intruded therein, thereby preventing the occurrence of a vehicle fire due to submersion. An internal circuit includes a high-voltage circuit bus bar and a low-voltage circuit bus bar having a lower potential than the high-voltage circuit bus bar, and a lower case includes a bottom wall and a peripheral wall protruding from a peripheral edge portion of the bottom wall toward an upper case. A high-voltage circuit region where the high-voltage circuit bus bar is disposed, a low-voltage circuit region where the low-voltage circuit bus bar is disposed, and a dividing wall divides these regions are provided inside the peripheral wall, and a height dimension of the dividing wall from the bottom wall is configured to be greater than a height dimension of the peripheral wall from the bottom wall.

A junction box assembly configured to shield the eyelet terminal includes a power distribution box and a bottom housing. A bottom housing is configured to mate with an undersurface of the power distribution box. The eyelet terminal is disposed within the bottom housing. A first connection housing is disposed in the bottom housing. The first connection housing is configured to house a first bus bar having a female connector. The first bus bar is electrically connected to the eyelet terminal. A second connection housing is disposed on an undersurface of the power distribution box. A second bus bar is mounted within an inner space of the power distribution box and a connecting portion of the second bus bar is disposed within the second connection housing. The first connection housing engages the second connection housing within the bottom housing so as provide a shielded.

Embodiments disclose a power distributor for a vehicle, comprising a printed circuit board for diagnosis and/or for controlling a power supply of a plurality of electrical loads connected to the power distributor, and a bus bar comprising a plurality of first plug contact parts. According to the present disclosure, the printed circuit board comprises a switch part for collectively controlling the power supply of multiple electrical loads via the bus bar disposed separately from the printed circuit board, wherein the first plug contact part of the bus bar together with a second plug contact part disposed on the printed circuit board form a plug contact pair, and a load connected to the respective second plug contact part can be supplied via each plug contact pair.

An embodiment is directed to a module-to-module power connector configured to form connections between battery modules installed in a battery housing of an energy storage system. The module-to-module power connector includes electrical interfaces and busbar(s) configured to form one or more electrical connections terminals of adjacent battery modules. The busbar(s) is flexibly configured to permit a defined range of movement of the electrical interfaces during insertion of the respective battery modules into respective battery module compartments. The module-to-module power connector may further be arranged inside in a tunnel space, whereby holes are defined in a battery module mounting area housing the battery modules that open into the tunnel space.

A power distribution box assembly with a plurality of separating walls to separate different power sources and from each other is provided. The power distribution box assembly includes a plurality of eyelet posts and busbars for powering a plurality of electric devices. First separating walls are configured to separate each eyelet post from each other. Each of the first separating walls is taller than the eyelet posts. A pair of second separating walls spaced apart from each other and open to a slit define a busbar housing. The busbar housing is configured to receive a portion of one of the busbars so as to separate the busbars from each other. Accordingly, the eyelet terminal housing is dimensioned so as to prevent a tool from contacting two eyelet posts or busbars at the same time.

Provided is an electrical junction box configured promptly release the electrical junction box from a state where water has intruded therein, thereby preventing the occurrence of a vehicle fire due to submersion. An internal circuit includes a high-voltage circuit bus bar and a low-voltage circuit bus bar having a lower potential than the high-voltage circuit bus bar, and a lower case includes a bottom wall and a peripheral wall protruding from a peripheral edge portion of the bottom wall toward an upper case. A high-voltage circuit region where the high-voltage circuit bus bar is disposed, a low-voltage circuit region where the low-voltage circuit bus bar is disposed, and a dividing wall divides these regions are provided inside the peripheral wall, and a height dimension of the dividing wall from the bottom wall is configured to be greater than a height dimension of the peripheral wall from the bottom wall.

Provided are a terminal table and a terminal table unit allowing a plurality of busbars to be connected certainly and easily with reactor busbars of reactor securing members that are connected with reactors included in reactor units having an error. A sensor terminal table 30 includes a plurality of sensor busbars 40 and a sensor-attached holding body holding the plurality of sensor busbars 40. The sensor busbars 40 each include a reactor-side connection portion 40a on the bottom side in a height direction H and a top connection portion 40b on the top side in the height direction H. The reactor-side connection portion 40a is connectable with a reactor re, and the top connection portion 40b is connectable with an IPM or a fuel cell FC. At least one of the plurality of sensor busbars 40 is a movable busbar 41 or 43 attached to the sensor-attached holding body 31 so as to be movable in the height direction H with respect to the sensor-attached holding body 31. The movable busbar 41 or 43 has the reactor-side connection portion 40a connectable with the reactor re.

The present invention includes a novel class of highly specific protease inhibitors. In one embodiment, the inhibitors of the invention are -helical in structure. In another embodiment, the present invention represents the first demonstration of a highly specific cysteine protease inhibitor.

Some embodiments of the present disclosure are directed to a hybrid distribution unit that can distribute both power and data connections from a power and fiber cables (or from a hybrid cable containing both power and fiber) within a compact enclosure that helps reduce the overall footprint of the hybrid distribution unit mounted on a cellular tower. Some embodiments may also include circuit protection features, such as fuses or circuit breakers. Other embodiments may be described or claimed.

The invention relates to a terminal block splitter connector including an insulating housing, the first conductive metal component, the second conductive metal component, the first fixing component, the second fixing component, the first wire inlet group, the second wire inlet group, the first push button, and the second push button. The first and second push button match with the first and second conductive metal component for on-line and off-line control of the first and second conductive metal component. A conductive connection plate is installed on the bottom of the insulating housing for power connection of the first and second conductive metal component. The first and second pin group are respectively mounted on the bottom of the first and second conductive metal component. The first and second socket group are installed on the conductive connection plate and respectively correspond to the first and second pin group.