A mixer gun system includes a holder cap configured to separately store components in separate chambers. The components are selectively releasable through channels fluidly communicating with the separate chambers. The components are constituent materials for a bone cement mixture. A body forms a mixing chamber and is configured to receive the holder cap. The mixing chamber includes an opening corresponding with the channels for the separate chambers. A piston is disposed within the mixing chamber. A plunger is coupled to the piston and is configured to be biased toward the mixing chamber such that when the components are released into the mixing chamber a pressure developed by a biased motion of the plunger and piston infuses the components to form bone cement. Upon resetting the plunger and the piston, the bone cement is dispensed from the mixing chamber by the same biased motion. Methods of use are disclosed.

A device stores, mixes, and applies polymethylmethacrylate bone cement. The device comprises a first container for a first pasty component of the bone cement, a dispensing plunger arranged in the first container such that it can be shifted and serves for pressing the content of the first container out of a dispensing opening, a mixing facility for mixing the content of the first container, whereby the mixing facility is arranged in the first container and the mixing facility can be moved in the first container from outside for mixing, and at least one second container for at least one second component of the bone cement is arranged in or on said first container. The second container can be opened, such that the contents of the first container and second container can be mixed with each other in the first container, whereby at least a boundary surface of the first container is formed by a mobile volume compensation element.

The present invention provides an apparatus for storing gas hydrate pellets that includes: a storage tank having an inlet formed at a top portion thereof for having gas hydrate pellets injected therein; a transfer part formed at a lower portion of the storage tank so as to transfer the injected gas hydrate pellets to an outside of the storage tank; a rotating shaft vertically formed in the storage tank; a plurality of division plates coupled to the rotating shaft to partition an internal space of the storage tank, each having a bottom portion thereof formed above a top portion of the transfer part; an extension plate coupled to a lower portion of each of the division plates in such a way that the extension plate is movable up and down; and a guide formed at an upper portion of the transfer part and configured to guide the extension plate so as to allow the extension plate to be revolved by rotation of the rotating shaft without an interruption with the transfer part.

The apparatus can produce a product highly mixed and dispersed to a quasi-perfect level in a short time and has an extremely simple arrangement to reduce the processing cost. The mixing/dispersing apparatus for a liquid/liquid mixture includes an elongated thin tube into which the liquid/liquid mixture flows, an inlet provided at one end of the elongated thin tube to receive the liquid/liquid mixture, an outlet provided at the other end to discharge the liquid/liquid mixture, and a mixture pumping device for allowing the mixture to be fed under pressure into the elongated thin tube at a flow rate exceeding a critical Reynolds number. Two liquid storage boxes are provided such that one is located before the inlet provided at one end of the elongated thin tube and the other is located after the outlet, and a plurality of elongated thin tubes is provided between the liquid storage boxes.

A system can include a dry powder mixing tank, a first powder input, a second powder input, a powder output, and a detection device. The first powder input and the second powder input can introduce powders containing different substances that become mixed in the dry powder mixing tank. The detection device can detect information about amounts of different substances in a blend of powder moved out of the tank by the powder output. In some aspects, portions of the blend that do not satisfy parameters for the blend can be diverted from a receptacle for the blend based on the detected information.

A delivery system is provided that includes a device having a body extending along a longitudinal axis between proximal and distal ends. The body includes a proximal chamber, a distal chamber and a wall between the chambers. The body includes a first port in communication with the proximal chamber and a second port in communication with the distal chamber. A shaft is movably positioned within the body. The shaft extends through the wall and includes a proximal plunger positioned within the proximal chamber and a distal plunger positioned within the distal chamber. Pressure introduced through an opening in the proximal end moves the shaft such that the proximal plunger moves a fluid within the proximal chamber out of the first port and the distal plunger moves a fluid within the distal chamber out of the second port to simultaneously actuate a bone filler dispenser. Systems and methods are also provided.

An apparatus for mixing and pumping, the apparatus comprising a housing with an inlet and an outlet for receiving and expelling liquid and a material. The apparatus has a shear rotor and a stator for mixing the liquid and material and an impeller for pumping the liquid and material from the inlet, via an annular clearance between the shear rotor and the stator and to the outlet. The apparatus has a return conduit configured to return to the inlet a part of the liquid and material pumped via the annular clearance and openings in the stator.

A dilution apparatus (100) for diluting a fluidic sample in accordance with a specifiable dilution ratio, wherein the dilution apparatus (100) comprises a dilution fluid supply device (102) configured for supplying a dilution fluid at a first quantity per time, a transport fluid supply device (104) configured for supplying a transport fluid at a second quantity per time, a first fluid accommodation unit (106) configured for accommodating a first fluid volume, a second fluid accommodation unit (108) configured for accommodating a second fluid volume, and a control device (110, 112) configured for controlling the flow of the dilution fluid, the transport fluid and the fluidic sample so that in a first operation mode, the fluidic sample, being accommodated in the first fluid accommodation unit (106), is forced to flow to the second fluid accommodation unit (108) while being diluted by being mixed with dilution fluid, and in a second operation mode, the mixture of dilution fluid and fluidic sample, being accommodated in the second fluid accommodation unit (108), is forced to flow from the second fluid accommodation unit (108) to the first fluid accommodation unit (106) while being further diluted by being mixed with further dilution fluid.

An airless pump container equipped with an impregnated member and an absorbing member includes: a container main body (10); a pushing plate (20); an impregnated member (30) installed inside of the container main body (10); a shielding member (40); a pump holder (60) coupled to the upper portion of the shielding member (40); an airless pump (50) installed on the inside of the shielding member (40) and the pump holder (60); an absorbing member holder (70) coupled to the upper end of the airless pump (50); an absorbing member (90); and a moving member (100) for fixing the absorbing member (90). The impregnated member is impregnated with content in a gel-state.

A dispersing device is provided by which a dispersion with a high yield and a proper dispersing process can be carried out. The dispersing device causes a mixture of a slurry or a liquid to flow by centrifugal force toward an outer circumference between a rotor and a stator. It comprises a container, a cover assembly that closes an upper opening of the container, a stator that is fixed under the cover assembly, a rotor that is disposed to face a lower surface of the stator, and an assembly for supplying the mixture that stores an unprocessed mixture to be supplied to a gap between the rotor and the stator. The assembly for supplying the mixture has a body, a first member for injecting the mixture, and a second member for injecting the mixture.