A passage gate for allowing or preventing people to enter or to exit a passage area comprising a base portion (110) and a panel portion (120) is provided. The passage gate (100) is configured to be driven in a first operation mode and a second operation mode. When the passage gate (100) is driven in the first operation mode the panel portion (120) is slidable relative the base portion (110) between a first open position, allowing people to pass, and a closed position preventing people from passing through the passage gate (100). When the passage gate (100) is driven in the second operation mode the base portion (110) is rotatable between the closed position and a second open position for achieving a larger passage area.

The present invention relates to a method, implemented by means of a computer, for the management of accesses to premises of a building having doors and the control of opening electronic devices of said doors by a user.

The present invention concerns a motorized door for closing an area (3) at least partially defined by a frame, said Motorized door comprising: (A) a motorized driving mechanism (10) for moving a shutter between an open position (z=1) and a closed position (z=0) in a first direction () to close said area defined within said frame and in a second direction () to open said area; (B) a detection cell (5, 6) suitable for detecting an accidental event (e1), during the motion of the shutter. The motorized door further comprises a processing unit programmed to trigger a wind related safety function avoiding the yo-yo effect in case strong winds triggered the erroneous detection of an accidental event by the detection cell, said wind related safety function comprising the following steps: (C) a processing unit (CPU): (a) stop the movement of the shutter in the first direction (), and reverse said movement into the second direction () and, after a brief reverse time, t, of the order of 0.8 to 3.0 s, (b) stop said movement in the second direction () and reverse the movement back into the first direction () towards the closed position (z=0) of the shutter.

A multi-panel overhead stacking door which allows for the addition of multiple panels across an opening width. A vertical extrusion acts a guide for the panel above and/or below it. The vertical extrusion serves as a moving guide which thereby allows for the relatively easy addition of multiple panels. At each end of the door is a series of formed parts that are attached to the ends of the end panels and movably maintained with door guides. The assembled door is driven by, for example, a driven shaft, positioned at the top of or above the door opening. The shaft comprises drums to windingly and unwindingly receive a lifting member. The lifting member runs from the drum to the bottom panel assembly behind each vertical extrusion.

A sliding door system for inline closure of an opening in the wall of a structure, which may be a building or an item of furniture, for example. The sliding door system includes a door panel, a guiderail assembly having a wall mount fixedly attached to the wall above the opening and a guiderail coupled to the wall mount via a plurality of doubled-hinge assemblies that together serve to allow the guiderail to pivot towards and away from the wall. The top portion of the door panel has one ore more roller assemblies that are slidably coupled to the guiderail via rollers. A stop on the guiderail serves as a catch, or cam, that causes a closing force on the door panel to be transferred to the double-hinge assemblies and to cause the door panel to be pulled into inline closure in the opening.

The present invention concerns an auto-close door for closing an area (3) at least partially defined by a frame, said auto-close door comprising: A) A motorized driving mechanism (10) suitable for moving a leading edge (1L) of a shutter (1) in a first direction () to close said area defined within said frame and in a second direction () to open said area; B) Wave detection cells (5) suitable for detecting the presence of an obstacle within the area defined by the frame; and/or C) In addition or alternatively, an impact detector (6) suitable for detecting an impacting event with a leading edge of the shutter, D) A processing unit (CPU) programmed to carry out the following operations: a) Upon opening the area a first time by moving the leading edge of the shutter in said second direction (), maintain the area open for an opening time (t1), after which b) close the shutter, c) Record whether an obstacle and/or an impacting event is detected by the wave detector or the impact detector, upon closing the shutter; d) Count the number (n), of obstacles and/or impacting events detected during a number (N), of repetitions of the cycle defined by steps (a) to (c), and if n/N>v.sub.ref,1, wherein, v.sub.ref,1, is a first control ratio, then the opening time (t1), is prolonged to a time, t2=t1+t2, wherein t2>0; (e) Repeat steps (a) to (d) with the values t1 or t2 determined in step (d).

A building block includes a plurality of panel elements that are each rotatable relative to each other one of the plurality of panel elements; a connecting pin that passes through and rotatably connects the plurality of panel elements to each other; and a plurality of connectors, each connector rotatably attached to a respective panel element, where each one of the panel elements includes at least on locking feature configured to create a releasably fixed connection between adjacent panel elements.

A detecting system for an automatic door is provided including a TOF camera having a field of view that is limited in a first zone for a first purpose such as safety and in a second zone for another purpose such as activation or counting. The proposed system can be used for example in powered pedestrian doors, bus, rail, etc. In some embodiments, at least one ultrasound sensor system is further provided. The two technologies share hardware and information, resulting in improved safety and counting functions of the system, while reducing the amount of hardware used, space requirement and unit cost, and improving performance.

A safety door lock may include the door handle configured to be rotatable about a rotational axis and to slidably reciprocate in a horizontal direction and having a sliding groove on the side surface thereof adjacent to a door. The safety door lock may include a body combined with an inside of the sliding groove to form a rotating shaft with another door handle provided at the other side of the door and supporting sliding of the door handle so as to protrude the door handle from the front end of the door. The safety door lock may include an elastic unit fixed to the body, and elastically relaxing the door handle and the body. Other embodiments may also be provided.

An optoelectronic component includes a carrier, and a light source arranged on a surface of the carrier, said light source including at least one luminous surface formed by at least one light-emitting diode, wherein a transparent converter-free spacer is arranged on the luminous surface such that a distance is formed between the luminous surface and a spacer surface of the spacer facing away from the luminous surface, and wherein the light source is potted by a potting compound such that the spacer surface is formed extending flush with a potting compound surface facing away from the surface of the carrier and a surface formed by a spacer surface and the potting compound surface is plane.