A door sealing mechanism includes a solenoid for operating a cam mechanism to extend or retract a spring mechanism, causing a seal to engage/disengage with a floor/threshold, for allowing ease of opening/closing of the door while still providing sealing when the door is closed.

In one aspect, there is disclosed a solenoid having a bobbin with a core wire positioned about the bobbin to form a coil. A power supply wire is connected an end of the core wire and a frame is connected to the bobbin. An overmolded housing surrounds the core wire, the frame and a portion of the power supply wire.

In one aspect, there is disclosed a solenoid having a bobbin with a core wire positioned about the bobbin to form a coil. A power supply wire is connected an end of the core wire and a frame is connected to the bobbin. An overmolded housing surrounds the core wire, the frame and a portion of the power supply wire.

Provided herein is an improved a bi-stable actuator including a first core component coupleable to a housing, the first core component including a central bore containing a shaft and a shaft spring. The actuator may further include a second core component extending around the first core component, wherein the second core component and the first core component are axially moveable relative to one another, and a third core component extending within the second core component, wherein the third core component and the second core component are axially moveable relative to one another. The actuator may further include a positioning sphere extending through an opening of the first core component, wherein the positioning sphere abuts the second core component when the bi-stable actuator is in a first position, and wherein the positioning sphere abuts a detent of the shaft when the bi-stable actuator is in a second position.

Provided herein is an improved a bi-stable actuator including a first core component coupleable to a housing, the first core component including a central bore containing a shaft and a shaft spring. The actuator may further include a second core component extending around the first core component, wherein the second core component and the first core component are axially moveable relative to one another, and a third core component extending within the second core component, wherein the third core component and the second core component are axially moveable relative to one another. The actuator may further include a positioning sphere extending through an opening of the first core component, wherein the positioning sphere abuts the second core component when the bi-stable actuator is in a first position, and wherein the positioning sphere abuts a detent of the shaft when the bi-stable actuator is in a second position.

An electromechanical actuator device comprises a fixed part, a first movable part and a second movable part each arranged to move with respect to the fixed part along an actuation direction. A conductive coil (20) is wrapped around a core (28) and is housed within the fixed part (4). The first movable part (6) is coupled to the fixed part (4) by at least one restorative component (10) such that, in a working position, the first movable part (6) is separated from the fixed part (4) along the actuation direction (22) by a first actuation distance (d1). The second movable part (8) is coupled to the first movable part (6) by at least restorative component (16) such that, in the working position, the second movable part (8) is separated from the first movable part (6) along the actuation direction (22) by a second actuation distance (d2).

A solenoid valve comprising a valve portion and a solenoid portion. The valve portion has a pin, the pin having a groove. The solenoid portion has an aperture configured to receive the pin. A resilient locking device is located in the aperture, the resilient locking device configured to engage the groove when the pin has been inserted into the aperture to releasably hold the pin in the aperture. There is also a movable cap having a first and second position wherein, in the first position the movable cap does not abut the resilient locking device and wherein, in the second position, the movable cap abuts the resilient locking device so as to prevent movement of the resilient locking device out of the groove. A method of locking a valve portion to a solenoid portion of a solenoid valve is also disclosed.

A solenoid valve comprising a valve portion and a solenoid portion. The valve portion has a pin, the pin having a groove. The solenoid portion has an aperture configured to receive the pin. A resilient locking device is located in the aperture, the resilient locking device configured to engage the groove when the pin has been inserted into the aperture to releasably hold the pin in the aperture. There is also a movable cap having a first and second position wherein, in the first position the movable cap does not abut the resilient locking device and wherein, in the second position, the movable cap abuts the resilient locking device so as to prevent movement of the resilient locking device out of the groove. A method of locking a valve portion to a solenoid portion of a solenoid valve is also disclosed.

The bistable electromechanical actuator comprises an actuator shaft (7) arranged in a house (1), said shaft being movable along its longitudinal direction, a base member (11) attached to the actuator shaft (7), said base member being slidably attached to a guiding element (3, 3,3) through a stud (15), said guiding element being secured to the house and having two locking notches (2a, 2b) with a predetermined distance therebetween and further having a straight or substantially straight guiding section (2c) formed between said two locking notches in a plane parallel to the longitudinal direction of said shaft (7), wherein at least one permanent magnet is fixed to the base member (11) so that the magnetic axis of each permanent magnet is perpendicular or substantially perpendicular to the longitudinal direction of said shaft (7), and wherein at least one electromagnetic coil (13) is arranged within said house (1) so that in an idle state of the actuator, one end of each coil (13) is arranged to be adjacent to one of the at least one permanent magnet (12) in such a manner that the position of said end of the respective coil (13) is slightly offset, along the longitudinal direction of said shaft (7), with respect to the position of the permanent magnet (12) adjacent thereto.

The bistable electromechanical actuator comprises an actuator shaft (7) arranged in a house (1), said shaft being movable along its longitudinal direction, a base member (11) attached to the actuator shaft (7), said base member being slidably attached to a guiding element (3, 3,3) through a stud (15), said guiding element being secured to the house and having two locking notches (2a, 2b) with a predetermined distance therebetween and further having a straight or substantially straight guiding section (2c) formed between said two locking notches in a plane parallel to the longitudinal direction of said shaft (7), wherein at least one permanent magnet is fixed to the base member (11) so that the magnetic axis of each permanent magnet is perpendicular or substantially perpendicular to the longitudinal direction of said shaft (7), and wherein at least one electromagnetic coil (13) is arranged within said house (1) so that in an idle state of the actuator, one end of each coil (13) is arranged to be adjacent to one of the at least one permanent magnet (12) in such a manner that the position of said end of the respective coil (13) is slightly offset, along the longitudinal direction of said shaft (7), with respect to the position of the permanent magnet (12) adjacent thereto.