55 results about "Concentration cell" patented technology

The invention relates to a sensor for measuring the total content of nitrogen oxides in mixed gas. The sensor is characterized in that: the sensor comprises two inner chambers and a diffusion slit between the chambers, the first chamber is provided with an oxygen pump cell, gas to be measured can enter the first chamber, and the oxygen pump cell pumps oxygen in the gas to be measured into the chamber and oxidizes NO in the NOx mixed gas to be measured into NO2. The NO2 gas enters the second chamber through the diffusion slit between the two chambers. The second chamber is provided with a concentration cell capable of detecting the oxygen concentration in the chamber. The concentration cell and the oxygen pump cell are cooperated to allow the oxygen concentration in the second chamber to be constant and to guarantee that the oxygen in the first chamber is excessive. The second chamber is also provided with two NO2 detection electrodes. The position between the two electrodes is coated with a NO2 sensitive material. Measurement is performed by detecting the resistance value between the electrodes. The resistance value is corresponding to the NO2 concentration so as to reflect the total content of the NOx.

A thermoelectric conversion apparatus has an evaporator for heating a working medium in liquid-phase to evaporate the working medium, an electric generator for forming a concentration cell for electric power generation when it is supplied with a reactive gas and the working medium evaporated by the evaporator, and a gas-liquid separator for being supplied with a mixed gas of the working medium and a cathode off-gas discharged from the electric generator and separating the mixed gas into the working medium and the reactive gas. The thermoelectric conversion apparatus also has an anode supply passage for supplying the reactive gas separated by the gas-liquid separator to the electric generator, and a cathode supply passage for supplying the working medium separated by the gas-liquid separator through the evaporator to the electric generator.

An inter-cylinder air-fuel-ratio imbalance determination apparatus includes an air-fuel-ratio sensor in an exhaust passage of an engine. The air-fuel-ratio sensor functions as a limiting-current-type wide range air-fuel-ratio sensor when a voltage is applied, and functions as a concentration-cell-type oxygen concentration sensor when no voltage is applied. The determination apparatus causes the air-fuel-ratio sensor to function as the limiting-current-type wide range air-fuel-ratio sensor, and executes air-fuel ratio feedback control on the basis of the output value of the air-fuel-ratio sensor. When an imbalance determination parameter is obtained, the determination apparatus causes the air-fuel-ratio sensor to function as the concentration-cell-type oxygen concentration sensor, and obtains, as the imbalance determination parameter, a value corresponding to the differentiated value of the output value of the air-fuel-ratio sensor. The determination apparatus determines an inter-cylinder air-fuel-ratio imbalance state, when the absolute value of the imbalance determination parameter is greater than an imbalance determination threshold value.

The invention relates to a barium zirconate proton conductor designed by complex phase structure with a high electric conductivity and its manufacturing method. The invention is coating a layer of NaOH or sulfate around the crystal grain of the barium zirconate. The manufacturing method is: taking the BaCO3, ZrO2 and Y2O3 as raw material, water as medium, ball milling mixing for 4-10 hours, calcining for 4-12 hours in 1200-1400 DEG C; then adding 1-10% molar ZnO, ball milling mixing for 4-10 hours, adding 5-50% mol NaOH or K2SO4 or Na2SO4 or Li2SO4 in a way of hand lapping to make the mixture uniform; putting the mixing material into the die and dry pressing molding under a pressure of 50-120 MPa, and then isopressing under 200-350 MPa; sintering in the air of 1200-1500 DEG C with a heating rate of 2-10 DEG C/minute and keeping warm for 2-10 hours, then cooling to the room temperature to produce the barium zirconate proton conductor material with a high electric conductivity. The invention adopts the new designing thought of complex phase structure to establish a foundation for exploiting hydrogen gas and vapor sensor, hydrogen pump and concentration cell electrolyte material.

This invention discloses a proton conductor material of high electric conductance of La2Zr2O7matrix doped at Zr bit and its preparation method, in which, the molecular structure of the material is: La2Zr2-xMxO7-delta, and M is Yb3+, Er3+, Gd3+ or Sc3+, x is 0.01-1, delta is x/2. The preparation process includes: taking La2O3, ZrO2 and Yb2O3 or Er2O3, Gd2O3 or Sc2O3 as the raw materials to match with them according to the mol ratio of each material in terms of the molecular formula and adds dispersant in light of the mass percentage of the adjuvant then to ball-mill and mix them with the adjuvant with water or alcohol as the medium to be dried to get powder to be milled, dried, screened, synthesized and heat-preserved to get the material, which is ball-milled and pressed to be sintered in 1400-1650deg.C and cooled to the room temperature to get the material.

The invention relates to recombination doping zirconic acid lanthanum proton conductor material and its preparation method. Its chemical formula and matching is: La2-yNyZr2-xMxO7-delta;M is that Yb3+,Er3+,Gd3+,Sc3+ are doping in Zr bit, x is 0.01-1;N is Sr2+,Ca2+ are doping in La bit, y is 0.002-0.4;delta is oxygen vacant site, it depends on x and y. Dosage as proportion, water or alcohol is the medium, it is ball grinded and mixed for 4-10 hours and then dried, then synthesized in 1400DEG C, heat preserved for 2-20 hours. The synthesized material is then ball grinded, dried, screened, and loaded into die. The pressure is 50-120MPa, it is isostatic pressing, the pressure is 120-300MPa;it is adglutinated in 1400-1650DEG C, the warming-up rate is 2-10DEG C/ minute, heat preserved for 2-50 hours, then cooled to room temperature, the doping zirconic acid lanthanum material is produced. The invention adopts the recombination doping which is not reported to produce proton conductor material which possesses perfect conductivity; it lays the foundation of developing hydrogen gas and steam sensor, hydrogen pump, accelerant and concentration cell electrolyte material.

A method and apparatus for the accumulation and storage of energy in electrically reversible manner wherein a two chamber electrochemical cell(a single one or part of an array of such cells) has an electrolyte of common specie solutions in the multi-chambers associated with cell electrodes and application of voltage to the electrodes causes dissimilar concentrations of ions in two chambers so that the energy is stored and reversing polarity of the electrodes allows energy discharge and normalization of concentration. Materials may be reversibly stored in the cell as solids when exceeding the solubility limits of the electrolyte, such storage being done preferably at porous electrode surfaces.

The invention discloses a concentration cell capable of continuously generating electricity. The concentration cell capable of continuously generating electricity comprises a positive electrode, a negative electrode, an electrode partition, a high-concentration solution inlet, a low-concentration solution inlet, a high-concentration solution container, a low-concentration solution container, an electricity-generated solution outlet, a high-concentration solution supplying system and a low-concentration solution supplying system, wherein the electrode partition is clamped between the positive electrode and the negative electrode; solution channels are reserved between the electrode partition and the electrodes; the high-concentration solution inlet is correspondingly communicated with a high-concentration solution channel; the low-concentration solution inlet is correspondingly communicated with a low-concentration solution channel; solutions in the low-concentration solution container and the high-concentration solution container respectively flow into the low-concentration solution inlet and the high-concentration solution inlet; a high-concentration solution flows through the high-concentration solution channel from one side of the electrode partition; a concentration solution flows through the low-concentration solution channel from the other side of the electrode partition. Electricity-generated solutions are constantly discharged from the outlet, and an output voltage is generated between the positive electrode and the negative electrode.

The invention discloses a concentration cell comprising electrolyte solutions, a container used for containing the electrolyte solutions, a semipermeable membrane and noble electrodes. The container is partitioned into a first chamber and a second chamber, which are equivoluminal, through the semipermeable membrane; the noble electrodes are inserted into the electrolyte solutions in the first chamber and the second chamber respectively. The concentration cell is simple in structure, a stable, continuous and low-voltage low current can be obtained only by supplementing water periodically, and electrical energy which can be utilized directly can be generated by means of parallel connection of multiple concentration cells.

The invention relates to a sensor based on a concentration cell principle. The sensor is used for quantitatively detecting glucose concentration in human blood. As shown in the figures, the sensor comprises two electrodes (1) and (2), wherein the electrodes are in contact with solutions in two electrochemical pools (3) and (4), respectively; the two electrochemical pools have ion exchange through a nafion film (5); electro-active materials are contained in the two electrochemical pools (3) and (4). In the detection process, to-be-detected matter in a sample changes the concentrations of the electro-active materials in the electrochemical pools by reacting, thereby changing an electric signal (such as current or voltage) between the two electrodes; quantitative detection is performed by detecting a relation between the electric signal detected by (6) and the concentration of the to-be-detected matter. A reference electrode (such as a silver/silver chloride electrode) required by traditional electrochemical sense is not required by the sensor, the two electrodes can be made of the same material (such as graphite), the manufacturing technique is simple, and the cost is low; the influences of interfering matter in a sample on the detection can be eliminated, and thus the detection accuracy is increased.

The solar driven concentration cell comprising a cathode half-cell, an anode half-cell and a transparent covering or lid extending over both half-cells and sloping downwardly from the cathode half-cell to the anode half-cell, wherein heat from the sun causes solvent from the half-cells to evaporate and subsequently condense on an inside surface of the covering or lid and wherein condensed solvent is then pulled by gravity substantially into the anode half-cell, whereby a concentration gradient is maintained across the electrodes of the cell to extend the useful life of the concentration cell.

The present invention belongs to the applicatino of motive electricity generation. High heat source and oxygen concentration cell pile are made to constitute power generator. High temperature heat source produces heat to make the oxygen concentration cells in high temperature working state, and the oxygen concentration cell pile comprising many oxygen concentration cells connected serially and parallelly is inside the oxygen chamber. The oxygen supplying device connected to the oxygen chamber supplies oxygen for the oxygen chamber. The inner cavity of the oxygen concentration cell has lower oxygen pressure in the inner cavity than in the outer cavity. The present invention has high power generating efficiency, less high speed rotating parts, and less environmental pollution.

The invention belongs to a barium zirconate proton conductor material with a multi-phase structure and a preparation method thereof. Burdening is conducted according to the following ratio: BaCO3:ZrO2:Sc2O3=1:1:0.05-0.30 mole, ball-milling and mixing are conducted by taking water as a medium, and then calcining is conducted to obtain a Sc2O3-doped BaZrO3 matrix material; ZnO of 1-10% mole is added, then CaF2, BaF2 or NaF of 5-50% mole is added by taking the matrix material as a benchmark after the ball-milling, mixing and sieving, and grinding mixture to be even; the mixture is put into a mould to be molded by dry pressing, and subjected to 200-350 MPa isostatic pressing; and the mixture is sintered in air atmosphere at 1200-1500 DEG C, and then naturally cooled to room temperature, thus obtaining the barium zirconate proton conductor material with the multi-phase structure. The invention provides a new idea for conducting multi-phase structure and doping modification on a barium zirconate proton conductor simultaneously, and solves the restriction of grain boundaries on material conductivity through microscopic structure design and control, with the material conductivity being expected to be above 10-2 S/cm, thus laying a foundation for the development of hydrogen and steam sensors, hydrogen pumps and concentration cell electrolyte materials.

This invention relates to chips of two-way serial sheet oxygen sensors for testing oxygen concentration in car tail-gas including: a limit current oxygen sensor, a concentration cell oxygen sensor, a heater, a sealed cavity, a cavity, in which, said limit current oxygen sensor, the concentration cell oxygen sensor, the heater and the sealed cavity are static-pressed to molding to be sintered to an entity. This invention also relates to the two-way serial sheet oxygen sensors and the chip is composed of a limit current oxygen sensor, concentration cell oxygen sensor to integrate ZrO< 2 > electrolyte, a porous film, a heater and a porous Pt electrode as one.

The invention relates to a power generating device, in particular to an ionic concentration cell capable of efficiently and continuously generating power. The ionic concentration cell comprises a low-concentration solution inlet, a high-concentration solution inlet, a solution outlet, a positive electrode and a negative electrode, and can form a stable solution interface where a high-concentration solution is in contact with a low-concentration solution. The concentration cell has the advantages that the power generation efficiency is high and the structure is simple.