An evacuated bottle system including a bottle defining a hollow interior, the bottle having a neck with a rim defining an opening; a cap assembly supported on the bottle, the cap assembly including a funnel having a first portion and a second portion, the first portion being insertable within the interior of the bottle and the second portion engaging a portion of the bottle to support the funnel above the rim, the funnel defining a bore that fluidly communicates with the hollow interior of the bottle; a self-sealing membrane that covers the bore formed by the funnel to selectively seal the hollow interior of the bottle; a cap attachable to the bottle, the cap including a cover portion that extends at least partially over the self-sealing membrane to restrain movement thereof, the cover portion being axially spaced from the self-sealing membrane to define a gap that permits axial movement of the self-sealing membrane to selectively open the bottle to fluid communication outside of the bottle.

A waste collection unit for collecting medical waste through a suction line. The waste collection unit includes a manifold receiver having an opening in fluid communication with a canister. A suction pump is configured to draw a vacuum, and a vacuum regulator is configured to regulate the vacuum draw. A light assembly positioned near the opening of the manifold receiver may include a first light and a second light. The light assembly may be arranged to direct the first light towards a manifold configured to be removably received in the manifold receiver. The light assembly may be arranged to direct the second light arcuately around at least a portion of the opening of the manifold receiver. The first light may emit light of different colors based on a commanded or measured level of the vacuum draw.

Embodiments of negative pressure wound therapy systems, apparatuses, and methods for operating the systems and apparatuses are disclosed. In some embodiments, the apparatus includes a negative pressure source, a connector port, at least one switch, and a controller. The negative pressure source is connected through the connector port to either (i) a wound dressing having a canister configured to store fluid aspirated from the wound or (ii) a wound dressing without a canister between the connector port and the wound dressing. The controller determines, based on a signal received from the at least one switch, whether the canister is positioned in the fluid flow path and adjusts one or more operational parameters of negative pressure wound therapy based on the determination. The switch is activated by the connection of either the canister or canisterless wound dressing to the apparatus.

The invention relates to a system for drainage of fluids or wound secretion from body and/or tissue openings of the human or animal body comprising a bag-like reservoir for collecting the fluid or wound secretion, with an upper inlet opening and a lower outlet opening, and a pre-evacuated container with an inlet opening, wherein the inlet opening of the pre-evacuated container is connected to the lower outlet opening of the bag-shaped reservoir.

A method for operating an elastically mounted forming machine which is path-bound or force-dependent, in which method a working stroke of a ram device operatively connected to the drive is initiated by means of a drive, and a predefined forming process is carried out on a workpiece by moving the ram device during said working stroke, in particular due to the interaction of an upper tool located on the ram device with a lower tool located on a tool table, wherein the inertial forces and/or moments of inertia occurring during operation owing to the initiation of the working stroke and/or owing to an imbalance in the drive are at least partially compensated. The method, wherein at least one kinematic variable (s(t),v(t),a(t)) of a rigid body motion of the elastically mounted forming machine is detected during the operation thereof, wherein the time at which the working stroke is initiated is adapted to an instantaneous phase position of the at least one kinematic variable (s(t),v(t),a(t)) of the rigid body motion in order to generate inertial forces and/or moments of inertia so as to counteract the rigid body motion of the forming machine.

A lid adapter for coupling with a lid of a collection container where the lid includes an outlet vent. The lid adapter including a housing including a top surface and one or more side panels that are configured to couple with a top of the lid and a port coupled to the top surface and configured to rotate between a first position and a second position, wherein when the lid adapter is coupled to the lid and the port is in the first position, a fluid seal is established between a distal end of the port and the top of the lid surrounding the outlet vent thereby enabling fluid flow from the outlet vent and through the port. When the port is in the second position, the fluid seal is not established, and when the port is in the first position, the port is disposed perpendicularly to the top surface.

A self-placeable external catheter is disclosed that includes a catheter body having at least a top side and a bottom, a wicking area disposed on the top side, a finger covering extending from the bottom side of the catheter body creating a cavity configured to receive a user finger, and an aperture formed in the bottom side of the catheter, wherein the wicking area receives urine such that the urine passes through the wicking area, through the catheter body and through the aperture. The catheter tubing may be inserted into the aperture such that the urine passes through the wicking area, through the catheter body and through the aperture into the catheter tubing. An opening of the cavity may face a proximal side of the catheter body and the wicking area may include gauze.

A portable drain system having a subdermal drain and a container in fluid communication with the subdermal drain is disclosed. The subdermal drain is configured to drain fluid from a surgical site. The container provides a negative pressure to the subdermal drain. The container draws and receives the fluid. The container includes at least one sensor in which the at least one sensor is configured to detect at least one of fluid color, fluid volume in the container, and orientation of the container.

The present disclosure discloses a device for automatically collecting snot, which comprises a suction nozzle, a collecting cup, a cup holder and a shell component which are detachably connected in sequence, wherein the shell component is a hollow cavity. The present disclosure generates negative pressure suction through the air pump, and then the suction air enters the inner collecting cup through the air suction pipe, the cup holder air inlet, the air inlet channel and the micropore in sequence. Finally, the suction sucks the snot in the nose of a user into the inner collecting cup through the suction nozzle, effectively solving the problem of snot reflux.

Examples relate to devices, systems, and methods for collecting and measuring discharged urine. A urine collection system includes a urine collection device configured to collect urine discharged from a user and a urine collection container in fluid communication with the urine collection device and sized and dimensioned to receive the urine discharged from the user. The urine collection system also includes a flow meter having a communication interface and positioned between the urine collection container and the urine collection device. The flow meter is configured to detect a flow property of the urine at least related to a volume of the urine entering the urine collection container and the communication interface is configured to wirelessly communicate to a computing device at least one of the detected flow property or the volume of the urine including the volume of the urine discharged from the user entering the urine collection container.