A tamper resistant lock. A lock has a lock housing with housing indentation. A cylinder is rotatably housed within the housing. A locking pin is connected to the cylinder and is inserted into the housing indentation when the lock is in a locked position and the locking pin is clear of the housing indentation when the lock is in an unlocked position. An anti-tampering mechanism is positioned between the housing and the cylinder. The anti-tampering mechanism receives a user's key and also includes a relative motion hole. A key extension portion is rotatably inserted inside the anti-tampering mechanism body and includes a relative motion indentation. The key extension portion is keyed to the cylinder. A lock ball is inserted into the relative motion hole and the relative motion indention, thereby preventing relative motion between the anti-tampering mechanism body and the key extension portion. A flexible band is wrapped around the anti-tampering mechanism body and covers the lock ball and holds the lock ball in place in the relative motion hole and relative motion indentation. The flexibility of the flexible band is sufficient to permit the lock ball to leave the relative motion indentation while simultaneously retaining the lock ball in the relative motion hole if the anti-tampering mechanism body is rotated while the locking pin is inserted into the housing indentation, thereby permitting relative motion between the anti-tampering mechanism body and the key extension portion. In a preferred embodiment the tamper resistant lock is a padlock.

A lock (100) comprising a plurality of buttons (111), each button (111) having an axis along which each of the buttons (111) may be axially pressed between an un-pressed position and a pressed position, a locking plate (120), an actuator (114) configured to drive the locking plate (120): a locking mechanism (122) having an unlocked and a plurality of locked states, the plurality of locked states corresponding to different selections of buttons (111) having been pressed into their pressed positions; and a latch (117); in which, when the locking mechanism (122) is in the unlocked state, the locking plate (120) can be driven by the actuator (114) from a locked position into an 10 unlocked position so as to disengage the latch (117) and unlocking the lock (100), but when the locking mechanism (122) is in one of the locked states, the locking mechanism (122) prevents the locking plate (120) being moved by the actuator (114): the lock (100) further comprising a decoupling mechanism (200) by means of which the actuator (114) can drive the locking plate (120), the decoupling mechanism (200) being arranged to decouple the actuator (114) from the locking plate (120), so as to reduce any feedback indicative of which of the unlocked states the locking mechanism (122) is in passing from the locking plate (120) to the actuator (114). In one example, the decoupling mechanism (200) comprises a driven member (201) driven for motion by the actuator (114), a first resilient member (202) connecting the driven member (201) with the locking plate (120) and a second resilient member (203) connecting the locking plate (120) to a fixed member fixed relative to a housing of the lock (100); and in which the first (202) and second (203) resilient members each have a spring constant, with the spring constant of the first resilient member (202) being greater than the spring constant of the second resilient member (203).

A door latch (100, 400, 500, 600, 1200, 1300, 1400, 1500, 1600, 1700, 1800, 1900) resists opening of a door (200) beyond a predetermined amount when it is engaged and also allows the opening of the door when it is disengaged. The door latch includes a catch (220, 220, 3220) and a base (191) that is connected to a deformable member (140, 3140, 4140, 5140, 6140) at a joint (90). The joint configures the door latch and may include a pin (190). The catch (e.g., a hook) engages a catching portion (e.g., a loop 148, 3148, 6148) of the deformable member when engaged. The deformable member may stretch at least five percent when resisting an intrusion load (F) on the door. The base may mount to a door frame (300), and the catch may mount to the door. A spring (180) may urge the deformable member toward engagement. A shield (280, 2280, 4280, 5280, 6280) may protect the deformable member and resist cutting and may pivot with the deformable member urged by the spring. A finger pocket (296) may be used to overcome the spring. A detent (187) may retain a disengaged configuration (70), and a button (130) on the pin may be depressed to release the detent. A keeper (260) may retain an engaged configuration (50), even when the intrusion load alternates. An armed configuration (40) may automatically transition to the engaged configuration upon the door reaching the predetermined amount and may be manually transitioned to the disengaged configuration upon operator manipulation. The deformable member may hyperelastically deform.

The invention relates to a door lock provided with an oblique bolt. The objective is to decrease the external force directed into to deadlocking organs. The oblique bolt consists of slanted surfaces on both sides such that the tip part is narrower at its tip than in the back part of the tip part. The tip part has recesses in its lower part and upper part, which extend from the tip to the back part. Both recesses have a turning piece. Additionally, the oblique bolt has a support piece and flexing organs. The turning pieces guide external force up to a given turning angle via the support piece and flexing organs into the deadlocking organs.

An example lockset generally includes a housing, a bolt, a turnhub, and a spindle. The bolt is mounted in the housing for movement between an extended position and a retracted position. The turnhub is rotatably mounted in the housing and engaged with the bolt. Rotation of the turnhub in a bolt-extending direction drives the bolt toward the extended position, and rotation of the turnhub in a bolt-retracting direction opposite the bolt-extending direction drives the bolt toward the retracted position. The spindle engaged with the turnhub, is operable to exert torque on the turnhub in the bolt-retracting direction, and is selectively operable to exert torque on the turnhub in the bolt-extending direction. The housing includes a pair of stops configured to limit rotation of the spindle to a predetermined angular range.

An exemplary torque-limiting spindle includes an input member, an output member, a clutch mechanism, and a bias mechanism. The input member extends along a longitudinal axis, is configured for connection with a handle, and includes a first engagement feature. The output member extends along the longitudinal axis, is configured for connection with a rotatable member of a lockset, and includes a second engagement feature. The clutch mechanism includes the first engagement feature and the second engagement feature. The bias mechanism is engaged with the input member and the output member and exerts a biasing force urging the first engagement feature and the second engagement feature into engagement with one another.

A declutching system for handle arrangement of a motor vehicle includes: an axle whereon are arranged a housing and a declutching member. The declutching system presents two positions: a clutch position wherein the declutching member blocks the housing in rotation around the axle by cooperating with at least one cam of the housing, and a declutch position wherein the declutching member allows the housing to rotate around the axle. The declutching member includes a body to which extends at least one reversible deformable leg. In the clutched position, the at least one reversible deformable leg cooperates with the at least one cam of the housing and blocks into rotation the housing around the axle. In the declutched position, the at least one reversible deformable leg is deformed in the direction of the body and thereof enabling the rotationally displacement of the housing around the axle.