The present disclosure provides, in one aspect, method of controlling an autonomous cleaning robot, the method comprising: navigating the autonomous cleaning robot to a docking station; sensing that the autonomous cleaning robot is navigating to the docking station; increasing a vacuum power of a vacuum assembly of the autonomous cleaning robot to reduce an amount of debris from an airflow channel proximate to an inlet of a cleaning bin disposed in the autonomous cleaning robot; and then decreasing the vacuum power of the vacuum assembly of the autonomous cleaning robot.

According to an embodiment, an LGA socket includes a center substrate, first and second insulator and a plurality of pairs of contacts. The center substrate is configured by a multi-layer structure including a ground layer and a plurality of through holes formed through the center substrate. The first insulator is arranged around the plurality of through holes on an upper surface of the center substrate. The second insulator is arranged around the plurality of through holes on a lower surface of the center substrate. The plurality of pairs of contacts are inserted into the through holes from an upper side and from a lower side of the through holes and are soldered via the through holes to be electrically connected to each other.

According to an embodiment, an LGA socket includes a center substrate, first and second insulator and a plurality of pairs of contacts. The center substrate is configured by a multi-layer structure including a ground layer and a plurality of through holes formed through the center substrate. The first insulator is arranged around the plurality of through holes on an upper surface of the center substrate. The second insulator is arranged around the plurality of through holes on a lower surface of the center substrate. The plurality of pairs of contacts are inserted into the through holes from an upper side and from a lower side of the through holes and are soldered via the through holes to be electrically connected to each other.

Embodiments disclosed herein relate to a base plate and/or a sensor assembly part of an ostomy appliance. In embodiments, the base plate and/or the sensor assembly part comprises a first adhesive layer, a masking element, and a plurality of electrodes. The first adhesive layer includes a stomal opening with a center point and a proximal surface configured to be attached to a skin surface of a user. The masking element is arranged on a distal surface of the first adhesive layer, and is more insulative than the first adhesive layer. Further, the plurality of electrodes are arranged on a distal side of the first adhesive layer. Each electrode includes a sensing part and a conductor part and the masking element is arranged between the conductor parts and the first adhesive layer.

A stand having a base, an arm attached to the base, an electrical connector, and an adjustable mounting head attached to the arm. The adjustable mounting head includes a plurality of keepers actuated by a button, wherein the plurality of keepers are each configured to engage a respective one of a plurality of receivers on a case for an electronic device such that the case is removably attachable to the adjustable mounting head for holding the case and an installed electronic device on the stand in a preferred orientation. The mounting head includes electrical contacts electrically connected to the electrical connector of the stand and configured to contact an electrical interface of the case for providing the electrical power from the electrical connector of the stand to the installed electronic device through the electrical contacts of the mounting head and through the case.

A stand having a base, an arm attached to the base, an electrical connector, and an adjustable mounting head attached to the arm. The adjustable mounting head includes a plurality of keepers actuated by a button, wherein the plurality of keepers are each configured to engage a respective one of a plurality of receivers on a case for an electronic device such that the case is removably attachable to the adjustable mounting head for holding the case and an installed electronic device on the stand in a preferred orientation. The mounting head includes electrical contacts electrically connected to the electrical connector of the stand and configured to contact an electrical interface of the case for providing the electrical power from the electrical connector of the stand to the installed electronic device through the electrical contacts of the mounting head and through the case.

An opening/closing mechanism that allows a cover member to be biased according with the degree of opening. A solution is that an opening/closing mechanism of an opening/closing body, comprises: a cover member 15 opening and closing around a shaft center of a third shaft 33 and disposed on a base portion 23, and an opening/closing body 10 in which the cover member 15 is biased toward an opening direction by a biasing force of a spring member 21 wherein a spring support portion 35 is provided on the base portion 23, and a spring receiver 37 is provided on the cover member 15, and in accordance with more opening of the cover member 15, a distance from the spring base portion 41b of the spring member 21 to an abutting position in the spring extending portion 41a with the spring receiver 37 becomes longer and the biasing force decreases.

An opening/closing mechanism that allows a cover member to be biased according with the degree of opening. A solution is that an opening/closing mechanism of an opening/closing body, comprises: a cover member 15 opening and closing around a shaft center of a third shaft 33 and disposed on a base portion 23, and an opening/closing body 10 in which the cover member 15 is biased toward an opening direction by a biasing force of a spring member 21 wherein a spring support portion 35 is provided on the base portion 23, and a spring receiver 37 is provided on the cover member 15, and in accordance with more opening of the cover member 15, a distance from the spring base portion 41b of the spring member 21 to an abutting position in the spring extending portion 41a with the spring receiver 37 becomes longer and the biasing force decreases.

An improved LED lighting system is provided for overhead ceiling lighting, as well as for other uses. The LED lighting system comprises elongated linear lamps having an LED luminary as a source of illumination and configured to operate as a node of an automated networked lighting system. The linear LED lamps include an interface connector operable to connect to a data network to receive control data and power signals from an external device connected to the network for use in powering LED emitters and controlling one or more operational characteristics of the linear LED lamps. The system includes support connector assemblies for securing the linear LED lamps to a channel member of an overhead dropped ceiling grid.

Systems and methods involve implementations such as a container assembly including an interior area, a first side interior bounding the first border of the interior area, a second side interior bounding the second border of the interior area, a third side interior bounding the first portion of the third border of the interior area, a fourth side interior bounding the first portion of the fourth border of the interior area, wherein the second portion of the third border of the interior area is unbonded by any side, and wherein the second portion of the third border of the interior area is unbonded by any side. In addition, other aspects are described in the claims, drawings, and text forming a part of the present disclosure.