Aerodynamic device for a motor-vehicle including a panel structure located under the front part of the motor-vehicle and elastically biased towards a raised position and configured to be moved towards a lowered position due to an airflow which invests the motor-vehicle during travel. The aerodynamic device includes a bag structure provided inside of a cavity for receiving in its interior the airflow which invests the motor-vehicle during travel, in such a way that above a predetermined threshold value of the motor-vehicle speed, the bag structure is inflated and pushes the panel structure towards its lowered position.

A fluid delivery system illustratively includes a spout, at least one valve in fluid communication with the spout, and a disinfectant device, illustratively an antibacterial device, fluidly coupled to the spout. The faucet is configured to selectively flow water through the disinfectant device in response to a user input to the faucet. In another illustrative embodiment, the fluid delivery system includes an outer housing, a plurality of fluid devices supported by the outer housing, and an ozone generator fluidly coupled to the fluid devices.

A sterilizing system according to the present invention includes a water supply apparatus provided with a filter unit having a plurality of filters, a water tank storing water purified by the filter unit, a water cock and water tank connection passages, and a sterilizer to sterilize the water supply apparatus, wherein the sterilizer comprises a sterilizing water generator, a circulation pump, a circulation passage, a rinsing water supply passage, a first drain passage and a first drain valve.

The present invention provides a water treatment device comprising: a filtering unit for filtering raw water; a storing unit comprising a first chamber for storing purified water, which has passed through at least a predetermined number of filters provided in the filtering unit and thus has been filtered, and a second chamber, the volume of which changes according to the volume change of the first chamber; an extraction unit installed to provide the user with the purified water that has been filtered; an sterilizing water supply unit for supplying sterilizing water in order to sterilize/disinfect the storing unit; and a control unit for controlling the driving of the sterilizing water supply unit and the opening/closing of a channel for supplying the sterilizing water.

An electrochemical cell for treating a fluid, the electrochemical cell comprising: at least two opposing electrodes defining a flow path for the fluid between the electrodes, where at least one of the electrodes is formed of electrically conductive diamond material; drive circuitry configured to apply a potential across the electrodes such that a current flows between the electrodes when the fluid is flowed through the flow path between the electrodes; and a housing in which the electrodes are disposed, the housing comprising pressure seals configured to containing the fluid within the fluid path and a support structure for supporting the electrodes, wherein the support structure and the pressure seals are configured such that the electrochemical cell has an operating pressure in a range 2 to 10 bar within which the electrodes are supported without fracturing and within which the fluid is contained within the flow path, wherein the electrodes are spaced apart by a distance in a range 0.5 mm to 4 mm, and wherein the drive circuitry is configured to apply a potential across the electrodes giving a current density 15,000 Amp/m.sup.2 over an electrode area of at least 20 cm.sup.2 for an operating voltage of no more than 20 V.

A method is provided for sanitizing a reverse osmosis system to supply high-purity permeate. Included in the method is supplying raw water to a feed tank and to a filter module using a raw-water inlet line having an inlet valve. A primary circuit is provided, and has a first pump connected to the filter module. A secondary circuit is provided, and has a second pump and a heater, both of which are connected to the filter module. The primary circuit is separated from the secondary circuit using a semipermeable membrane disposed in the filter module. The secondary circuit of the reverse osmosis system is cleaned or disinfected while the raw-water inlet line is in a disconnected state and the inlet valve is in a closed state using the second pump and the heater.

The present invention provides electrodes for transferring a charge comprising a plurality of members for making electrical contact. The electrodes are suitable for treating aqueous, substantially aqueous and nonaqueous fluids including wastewater, solvents and gases. Water maybe treated using the electrodes to provide higher dissolved oxygen or lower levels of contaminants after treatment. Furthermore, the electrodes may be useful in precipitation reactions such as electrowinning methods. The electrodes may also be capable of altering biological characteristics of organisms such as algae and bacteria.

A water treatment plant, having at least one storage container for storing water to be treated, an evaporator for evaporating the water to be treated, a condenser for condensing the water evaporated in the evaporator, the condenser being fed on the cooling water side with water to be treated, which is flowing to the evaporator. The storage container is arranged above the evaporator, and the condenser is arranged at the level of the base of the evaporator, the storage container being closable in an airtight manner and opening with an outlet into an overflow pot, the surface height of which is arranged slightly below a vapor outlet of the evaporator. The overflow pot is connected to the cooling water inlet of the condenser. A cooling water outlet of the condenser is connected to an inlet of the evaporator.

A preparation method and use of a graphite felt (GF)-supported metal-organic framework (MOF) cathode material is disclosed. The preparation method includes the following steps: preparing an iron salt, Pluronic F127, a weak acid, 2-aminoterephthalic acid, and a carbon felt; adding the iron salt and Pluronic F127 to deionized water and stirring a resulting mixture; adding the weak acid and 2-aminoterephthalic acid to the mixture, and stirring a resulting mixture to obtain an MOF precursor solution; adding the MOF precursor solution together with a pretreated carbon felt to a reactor, and sealing the reactor for hydrothermal reaction; and washing and vacuum drying a reaction product to obtain the cathode material. With a porous structure and a large specific surface area (SSA), the cathode material significantly increases the output of H.sub.2O.sub.2 when used in an electric Fenton system.

A trace metal analysis detector and method of operating the same to detect metals in various fluid samples using boron doped diamond working electrodes.