An air venting device for venting air from a fluid system, the air venting device comprising an air chamber, a sensor and an air venting valve. The sensor can detect a fluid level in the air chamber without coming into contact with the fluid and the air venting valve can be driven on the basis of this sensor measurement.

Acoustophoretic devices for separating particles from a non-flowing host fluid are disclosed. The devices include a substantially acoustically transparent container and a separation unit, with the container being placed within the separation unit. An ultrasonic transducer in the separation unit creates a planar or multi-dimensional acoustic standing wave within the container, trapping particles disposed within the non-flowing fluid and causing them to coalesce or agglomerate, then separate due to buoyancy or gravity forces.

A sulfuric acid recovery device includes a first recovery tank configured to recover sulfuric acid; a concentration meter configured to measure a concentration of hydrogen peroxide in the sulfuric acid; a discharge pipe configured to discharge the sulfuric acid from the first recovery tank to a second recovery tank; a circulation pipe with a maximum installation height position equal to or lower than a maximum installation height position of the discharge pipe and with a flow path formed, causing the sulfuric acid to return to the first recovery tank; a first valve configured to open and close a flow path of the discharge pipe; a pump configured to feed the sulfuric acid discharged to at least the circulation pipe of the circulation pipe and the discharge pipe; and a control circuit configured to control opening and closing of the first valve in accordance with the concentration of the hydrogen peroxide.

The present disclosure provides methods for removing defects nanotube application solutions and providing low defect, highly uniform nanotube fabrics. In one aspect, a degassing process is performed on a suspension of nanotubes to remove air bubbles present in the solution. In another aspect, a continuous flow centrifugation (CFC) process is used to remove small scale defects from the solution. In another aspect, a depth filter is used to remove large scale defects from the solution. According to the present disclosure, these three methods can be used alone or combined to realize a low defect nanotube application solutions and fabrics.

The disclosed technology includes techniques for improving efficiency of heat transfer devices, specifically condensers. An exemplary embodiment provides a device for condensing vapor bubbles comprising a quantity of liquid, a vapor source, and an acoustic transducer. The vapor source can be configured to introduce a plurality of vapor bubbles in the quantity of liquid. The acoustic transducer can be configured to provide acoustic energy to the quantity of liquid such that at least a portion of the acoustic energy is transferred to the plurality of vapor bubbles causing at least a portion of the plurality of vapor bubbles to condense in the quantity of liquid.

Provided is a centrifuge that preferably performs processes such as dispersion of a material to be processed while enhancing convenience for users. A centrifuge 1 of the present invention includes an ultrasonic wave generation source 10 that generates ultrasonic waves and a storage container 20 that stores a material to be processed M. The centrifuge 1 of the present invention also includes a rotation mechanism 30. The rotation mechanism 30 rotates the storage container 20 around a rotation axis L tilted relative to a virtual line V extended in a vertical direction in such a manner that the ultrasonic waves from the ultrasonic wave generation source 10 are constantly applicable to the material to be processed M.

An acoustic technique designed to increase the gas-dissolution rate of a bubble in a liquid media is proposed. Increased gas-dissolution rate is achieved by increasing the bubble's surface-to-volume ratio via bubble fragmentation. This is achieved by attaching an electroacoustic transducer to the system or load in which bubbles travel and exciting the transducer at the frequency of resonance. The electric resonance of the transducer attached to the system corresponds in frequency to the mechanical resonance of the system or load which allows for achieving such state without the use of an internally placed hydrophone to certify the resonance state. The acoustic bubble fragmentation technique increased the dissolution rate 4 to 5 times of bubbles with initial diameters between 150 and 550 m in distilled water and in medical grade saline solution.

An acoustic technique designed to increase the gas-dissolution rate of a bubble in a liquid media is proposed. Increased gas-dissolution rate is achieved by increasing the bubble's surface-to-volume ratio via bubble fragmentation. This is achieved by attaching an electroacoustic transducer to the system or load in which bubbles travel and exciting the transducer at the frequency of resonance. The electric resonance of the transducer attached to the system corresponds in frequency to the mechanical resonance of the system or load which allows for achieving such state without the use of an internally placed hydrophone to certify the resonance state. The acoustic bubble fragmentation technique increased the dissolution rate 4 to 5 times of bubbles with initial diameters between 150 and 550 m in distilled water and in medical grade saline solution.

A degasser for at least partially degassing a gas-containing liquid, in particular for a sample separation device, includes a liquid accommodation volume for accommodating the gas-containing liquid during degassing, a negative pressure chamber in which a negative pressure, compared to the liquid accommodation volume, is to be generated, a gas permeable membrane separating the liquid accommodation volume from the negative pressure chamber and arranged so that ultrasound forces at least part of gas of the gas-containing liquid to move through the membrane by a combination of the negative pressure and the ultrasound, and an ultrasound source including an electroactive material and configured for generating ultrasound for actuating the gas-containing liquid and/or the gas permeable membrane.

The present invention provides a liquid supplying unit, including: a nozzle; a liquid supply pipe configured to supply a treatment liquid to the nozzle; and an impurity removing unit installed in the liquid supply pipe to remove an impurity in the treatment liquid, in which the impurity removing unit includes: a measuring unit configured to measure a characteristic of the impurity in the treatment liquid and form impurity data; a vibrating unit configured to apply vibration to the treatment liquid; a capturing unit configured to adsorb the impurity in the treatment liquid to which the vibration is applied; and a control unit configured to control the measuring unit and the vibration unit, and when the impurity data exceeds a reference data range, the control unit operates the vibrating unit.