An activation mechanism for an aerosol dispenser is presented having a first housing structure, an actuation member movably arranged in the first housing structure, wherein the first housing structure is provided with an actuation member opening in level with the axial position of the actuation member, and an activation member slidably attached to the first housing structure, the activation member slides between a non-triggering position and a triggering position relative to the first housing structure, wherein the activation member has a radially flexible tab portion that is offset from the actuation member opening when the activation member is in the non-triggering position, restricting radial flexing of the tab portion, and wherein the tab portion aligns with the actuation member opening when the activation member is in the triggering position, thereby enabling the tab portion to flex radially inwards to cause movement of the actuation member.

An arrangement for activating an aerosol dispenser having a conveying tube for conveying a liquid; a movable holding member holding the conveying tube; a rotatable base; and a container chamber between the holding member and the base, wherein the arrangement is configured to transmit a loading rotation of the base to a substantially axial loading movement of the holding member towards the base, and wherein the holding member has a locking structure exposed to the container chamber. An aerosol dispenser having the arrangement and a method for activating an aerosol dispenser are also provided.

A tensioning arrangement for an aerosol dispenser is presented where the tensioning arrangement has a conveying tube; an elastic member arranged to store mechanical energy from a substantially axial tensioning movement of the conveying tube; a rotatable member; a transmission mechanism configured to transmit a tensioning rotation of the rotatable member to the tensioning movement of the conveying tube, wherein the transmission mechanism has a cam profile and a cam follower arranged to follow the cam profile, wherein the cam profile has at least one priming structure; and wherein the tensioning arrangement is configured such that the conveying tube makes a temporary priming movement towards an initial position when the cam follower passes each priming structure during the tensioning movement of the conveying tube by means of the tensioning rotation of the rotatable member. An aerosol dispenser is also provided.

A locking mechanism for an aerosol dispenser is presented having a first body structure, a second body structure rotatably attached to the first body structure, a spindle rotatably attached to the second body structure, the spindle having an actuator rotationally cooperating with the first body structure such that rotation of the first body structure relative to the second body structure causes rotation of the actuator and of the spindle, a movable element arranged around the spindle, the spindle being rotatable relative to the movable element, wherein rotation of the spindle causes movement of the movable element along the spindle from an initial position to a final position, and a locking element, wherein in the final position the movable element applies a radial force onto the locking element causing the locking element to bend in the radial direction thereby preventing rotation between the first body structure and the second body structure.

A drug delivery device, in particular a nebulizer or inhaler, for dispensing a fluid includes a cartridge having a collapsible container within which the fluid is disposed, a mechanism to help the collapsing process and to prevent the collapsed container from expanding again, hence preventing the forming of vapor and gas bubbles within, where the mechanism is adapted to pressurize the fluid within the container during withdrawal of the fluid.

A fluid delivery apparatus comprises a first piston body, a second piston body, a fluid delivery pipe, and a sealing element. The first piston body has a first through hole, a first connecting portion, an accommodation space and a buffer space. The second piston body has a second through hole and a second connecting portion disposed inside the accommodation space. The fluid delivery pipe is accommodated in the first through hole and the second through hole, and movable between a first position and a second position. The sealing element encircles the fluid delivery pipe. When the fluid delivery pipe is at the first position, the sealing element is accommodated in the accommodation space. When the fluid delivery pipe is at the second position, a first part of the sealing element is accommodated in the accommodation space, and a second part of the sealing element is accommodated in the buffer space.

An apparatus (100) for metered dispensing of a liquid from a container (3) and a spray applicator having the apparatus (100). The apparatus (100) comprises a base body (5) and a nozzle body (16) having an outlet nozzle. The nozzle body (16) is mounted so as to be displaceable relative to the base body (5) from a dispensing to a clamping position. The apparatus (100) comprises a reset spring (14) for moving the nozzle body (16) from the clamping to the dispensing position. The nozzle body (16) and the valve body form a burst chamber (19). By pressure on the trigger mechanism (26), the locking of the valve body (10) is triggered and the spray burst spring (7) presses the valve body (10) in the nozzle direction. A non-return valve is arranged upstream in the valve body. The spray burst chamber is connected to the outlet nozzle.

Inhalation device for generation of an aerosol of a medically active liquid, said inhalation device comprising a check valve (4); a housing (1), inside this housing (1) a reservoir (2) for storing said medically active liquid (L), downstream this reservoir (2) a pumping unit (3) for generation of a pressure connected to a means for the delivery of mechanical energy (6) to said pumping unit (3), and downstream said pumping unit (3) a nozzle (5); wherein the pumping unit (3) comprises a hollow cylindrical part (3A) and a piston (3B), the cylindrical part (3A) having an interior space (3C) configured to receive an end portion (3B′) of said piston (3B), wherein said cylindrical part (3A) and said piston (3B) are linearly moveable relative to one another such as to form a pumping chamber (3D) having a variable volume.

A method for producing a cartridge is proposed, where a fluid is filled into an opening of a container and a closure part is inserted into the container, thereby moving a movable piston arranged within the container.

The inhalation device for medically active liquids (F) for generation of an aerosol comprises a housing (1), a reservoir (2), a pumping device with a pumping chamber (3), and a nozzle (6), wherein the interior volume of the pumping chamber (3) is changeable by means of linear relative motion of the pumping chamber to the riser pipe (5). Said linear relative motion can be effected by a relative rotation of a rotatable part (1A) which is part of, or connected to, the housing (1) with respect to a second part (1B) of said housing (1), in that said relative rotation can be transferred by means of a gear mechanism into said relative translational motion. A means for the storage of potential energy (7) is provided which is chargeable by means of said relative rotation, and wherein said energy is releasable to said pumping device when released by activation of a release means. A blocking device is provided which is adapted to block activation of the release means and/or release of the means for the storage of potential energy (7) during rotation of the rotatable part (1A) and/or during loading of the means for the storage of potential energy (7). Also, a method for the prevention of undesired emission of medically active liquid or aerosol from an inhalation device is disclosed.