A freeze drying plant for drying products containing liquid has a vacuum chamber configured to receive the products. A reception device has at least one reception plate onto which the products can be applied. A cooling system has a fluid circuit configured to cool and/or to heat the products by a cooling fluid conducted in the fluid circuit. The reception plate has at least one closed fluid space that is connected to the fluid circuit and that cooling fluid flows through. At least one sound generator introduces ultrasound into the products during a drying phase, with the sound generator disposed in the fluid space and being able to be flowed around by cooling fluid.

A phased array of ultrasonic transducers may create arbitrary fields that can be utilized to manipulate fluids. This includes the translation of drops on smooth surfaces as well speeding the evaporation of fluids on wetted hands. Proposed herein is the use airborne ultrasound focused to the surface of the hand. The risk is that coupling directly into the bulk of the hand may cause damage to the cellular material through heating, mechanical stress, or cavitation. Using a phased array, the focus may be moved around, thus preventing acoustic energy from lingering too long on one particular position of the hand. While some signaling may penetrate into the hand, most of the energy (99.9%) is reflected. Also disclosed are methods to couple just to the wetted surface of the hand.

A phased array of ultrasonic transducers may create arbitrary fields that can be utilized to manipulate fluids. This includes the translation of drops on smooth surfaces as well speeding the evaporation of fluids on wetted hands. Proposed herein is the use airborne ultrasound focused to the surface of the hand. The risk is that coupling directly into the bulk of the hand may cause damage to the cellular material through heating, mechanical stress, or cavitation. Using a phased array, the focus may be moved around, thus preventing acoustic energy from lingering too long on one particular position of the hand. While some signaling may penetrate into the hand, most of the energy (99.9%) is reflected. Also disclosed are methods to couple just to the wetted surface of the hand.

An ultrasonic drying method used in yarn dyeing and drying machine (200) for drying the washed and dyed wet yarns (300) in the process of dyeing one or more yarns at a desired length in one or more colors in the manufacture of products such as carpet, hand-knit, knitwear in the textile sector, and to an ultrasonic drying system (100) for performing this method, wherein the system contains an Ultrasonic booster (101) which creates sound waves to be transmitted over the wet yarn (300) bundle the excess water of which has been removed by the vacuum unit (209) to remove the water therein before the drying tunnel (210); a horn (103) which is positioned between the ultrasonic booster (101) and the wet yarn (300) to transfer the sound waves generated by the Ultrasonic booster (101) to the wet yarn (300) bundle.

An ultrasonic drying method used in yarn dyeing and drying machine (200) for drying the washed and dyed wet yarns (300) in the process of dyeing one or more yarns at a desired length in one or more colors in the manufacture of products such as carpet, hand-knit, knitwear in the textile sector, and to an ultrasonic drying system (100) for performing this method, wherein the system contains an Ultrasonic booster (101) which creates sound waves to be transmitted over the wet yarn (300) bundle the excess water of which has been removed by the vacuum unit (209) to remove the water therein before the drying tunnel (210); a horn (103) which is positioned between the ultrasonic booster (101) and the wet yarn (300) to transfer the sound waves generated by the Ultrasonic booster (101) to the wet yarn (300) bundle.

A drying apparatus can include, in some aspects, an ultrasonic transducer and an infrared heater positioned proximate to the ultrasonic transducer and configured to emit infrared light. The drying apparatus can include a plurality of ultrasonic transducers. The drying apparatus can include a delivery enclosure defining a bottom wall, the bottom wall defining a plurality of air outlets; the ultrasonic transducer mounted to the delivery enclosure; and the drying apparatus can include an air mover mounted to the delivery enclosure.

A drying apparatus can include, in some aspects, an ultrasonic transducer and an infrared heater positioned proximate to the ultrasonic transducer and configured to emit infrared light. The drying apparatus can include a plurality of ultrasonic transducers. The drying apparatus can include a delivery enclosure defining a bottom wall, the bottom wall defining a plurality of air outlets; the ultrasonic transducer mounted to the delivery enclosure; and the drying apparatus can include an air mover mounted to the delivery enclosure.

A phased array of ultrasonic transducers may create arbitrary fields that can be utilized to manipulate fluids. This includes the translation of drops on smooth surfaces as well speeding the evaporation of fluids on wetted hands. Proposed herein is the use airborne ultrasound focused to the surface of the hand. The risk is that coupling directly into the bulk of the hand may cause damage to the cellular material through heating, mechanical stress, or cavitation. Using a phased array, the focus may be moved around, thus preventing acoustic energy from lingering too long on one particular position of the hand. While some signaling may penetrate into the hand, most of the energy (99.9%) is reflected. Also disclosed are methods to couple just to the wetted surface of the hand.

A phased array of ultrasonic transducers may create arbitrary fields that can be utilized to manipulate fluids. This includes the translation of drops on smooth surfaces as well speeding the evaporation of fluids on wetted hands. Proposed herein is the use airborne ultrasound focused to the surface of the hand. The risk is that coupling directly into the bulk of the hand may cause damage to the cellular material through heating, mechanical stress, or cavitation. Using a phased array, the focus may be moved around, thus preventing acoustic energy from lingering too long on one particular position of the hand. While some signaling may penetrate into the hand, most of the energy (99.9%) is reflected. Also disclosed are methods to couple just to the wetted surface of the hand.

A method for decontaminating a low-temperature article to accomplish decontaminating a surface of the such article, and to reduce duration of operations to increase efficiency of decontamination, and a pass box used in such method.

The method includes an applying step of applying a decontamination agent to external surfaces of the article, and a drying step of irradiating the article with agent thereon with ultrasonic waves and drying the surface. In the applying step, a gas, fog or mist of the decontamination agent is supplied to a target surface to form a condensed film of the agent on the target surface. In the drying step, dry air is supplied to the target surface.