UA146167U - HYDROGEN STORAGE AND SUPPLY SYSTEM - Google Patents

Abstract

Hydrogen storage and supply system comprising a gas generator, a sample of a hydroreactable composition, a water level sensor, an amplifier, a trigger, power amplifiers, a solenoid valve, a compensating tank, a pressure sensor, an electric motor, a reducer and a damper located in the outlet of the gas generator connected to the output of the gearbox, the input of which is mechanically connected to the rotor of the electric motor, the output of the water sensor is connected via an amplifier, trigger and first power amplifier to the control input of the solenoid valve, through which the gas generator is connected to the tank. the output of the pressure sensor is connected to the input of the second power amplifier. Additionally, a temperature sensor, a power amplifier and an algebraic adder are introduced, the output of which is connected to the control winding of the electric motor, the output of the second power amplifier is connected to the first input of the algebraic adder, and its second input is connected to the output of the power amplifier. to the output of the temperature sensor.

Description

The useful model belongs to the field of hydrogen energy, in particular, it concerns systems for obtaining, storing and supplying hydrogen.

A hydrogen storage and supply system is known, which includes a gas generator, a sample of a hydroreactive composition, a water level sensor, an amplifier, a trigger, power amplifiers, solenoid valves, a compensation tank, a pressure sensor, the output of which is connected through the power amplifier to the control input of the solenoid valve, which is connected to the gas generator, the water level sensor through the amplifier, the trigger and the second power amplifier is connected to the control input of the second solenoid valve, the output of which is connected to the tank for compensation, and the input is connected to the gas generator (11.

The disadvantage of such a hydrogen storage and supply system is that it does not ensure a continuous supply of hydrogen to the consumer.

Closest to the claimed hydrogen storage and supply system is a hydrogen storage and supply system that includes a gas generator, a hydroreactive composition sample, a water level sensor, an amplifier, a trigger, power amplifiers, a solenoid valve, a compensation tank, a pressure sensor, an electric motor , a reducer and a damper, which is placed in the outlet of the gas generator and is mechanically connected to the output of the reducer, the input of which is mechanically connected to the rotor of the electric motor, the control winding of which is connected to the output of the power amplifier, the input of which is connected to the output of the pressure sensor, while the output of the water level sensor is connected through the amplifier, the trigger and the second power amplifier to the control input of the solenoid valve, which connects the gas generator to the compensation tank

II.

The disadvantage of such a hydrogen storage and supply system is that when the pressure sensor fails, it becomes impossible to control the hydrogen generation process.

The useful model is based on the task of ensuring the hydrogen generation process in the hydrogen storage and supply system in the event of a pressure sensor failure.

The problem is solved by the fact that in the hydrogen storage and supply system, which contains a gas generator, a sample of a hydroreactive composition, a water level sensor, an amplifier, a trigger, power amplifiers, a solenoid valve, a compensation tank, a pressure sensor, an electric motor, a reducer and a damper, which placed in the outlet of the gas generator and mechanically connected to the output of the reducer, the input of which is mechanically connected to the rotor of the electric motor, the output of the water sensor is connected through an amplifier, a trigger and the first power amplifier to the control input of the electromagnetic valve through which the gas generator connected to the compensation tank, and the output of the pressure sensor is connected to the input of the second power amplifier, a temperature sensor, a power amplifier and an algebraic adder are additionally introduced, the output of which is connected to the control winding of the electric motor, the output of the second power amplifier is connected to the first input algebraic adder, and its second input is connected to the output of the power amplifier, the input of which is connected to the output of the temperature sensor.

The drawing shows the scheme of the hydrogen storage and supply system, which shows: 1- gas generator; 1.1 - water; 2 - a sample of hydroreactive composition; C - water level sensor; 4 - amplifier; 5 - trigger; 6, 11, 12 - power amplifiers; 7 - electromagnetic valve; 8 - capacity for compensation; 9 - pressure sensor; 10 - temperature sensor; 13 - algebraic adder; 14 - electric motor; 14.1 - control winding; 14.2 - rotor; 15 - reducer; 16 - damper; 17 - outlet of the gas generator.

The output of the water level sensor C through the amplifier 4, the trigger 5 and the power amplifier 6 is connected to the control input of the solenoid valve 7, which connects the gas generator 1 to the compensation tank 8. The outputs of the pressure sensor 9 and the temperature sensor 10, respectively, through the power amplifiers 11 and 12 are connected to the inputs of the algebraic adder 13, the output of which is connected to the control winding 14.1 of the electric motor 14. The rotor 14.2 of this electric motor is connected through the reducer 15 to the valve 16, which is located in the outlet 17 of the gas generator 1.

The hydrogen storage and supply system works as follows.

The cavity of the gas generator 1 is filled with water 1.1, the level of which is controlled by the water level sensor 3. At the same time, the interaction of water 1.1 with the sample of the hydroreactive composition 2 begins, as a result of which hydrogen begins to flow to the consumer through the outlet 17. When the water level of the nominal value is exceeded, a signal is sent to the control input of the electromagnetic valve 7 through the amplifier 4, the trigger 5 and the power amplifier 6, according to which part of the water enters the tank for compensation 8.

With the help of pressure sensors 9 and temperature 10, the pressure and temperature in the cavity of the gas generator 1 are monitored. When the pressure or temperature values deviate from the nominal values, the signals from the pressure sensors 9 or temperature 10 are sent through the corresponding power amplifiers 11 or 12 and through the algebraic adder 13 on the control winding 14.1 of the electric motor 14. With the help of the valve 16, which is connected to the reducer 15, the area of the outlet opening 17 of the gas generator 1 is changed in such a way as to eliminate the deviation of the parameters of the gas generator 1 relative to their nominal values.

If the pressure sensor 9 fails, the control of the hydrogen generation process in the gas generator 1 will be provided by the signal from the temperature sensor 10.

Thus, the introduction of a temperature sensor, a power amplifier, an algebraic adder and connections between them ensure the process of hydrogen generation in case of failure of the pressure sensor of the hydrogen storage and supply system.

Sources of information: 1. Abramov Yu. A. Fire and explosion hazard of hydrogen storage and supply systems based on hydroreactive compounds/ Yu. A. Abramov, R. V. Kornienko, V. I. Kryvtsova. - Kh.: APBU, 2005. -114 p. 2. Patent of Ukraine Mo 122905, IPC СО18 Z3/06, 2018.

Claims (1)

UTILITY MODEL FORMULA A hydrogen storage and delivery system that includes a gas generator, a sample hydroreactive composition, a water level sensor, an amplifier, a trigger, power amplifiers, a solenoid valve, a compensation tank, a pressure sensor, an electric motor, a reducer, and a damper placed in the outlet of the gas generator and is mechanically connected to the output of the reducer, the input of which is mechanically connected to the rotor of the electric motor, the output of the water sensor is connected through an amplifier, a trigger and the first power amplifier to the control input of the solenoid valve, through which the gas generator is connected to the tank for compensation, and the output of the pressure sensor is connected to the input of the second power amplifier, which is characterized by the fact that a temperature sensor, power amplifier and algebraic adder are additionally introduced, the output of which is connected to the control winding of the electric motor, the output of the second power amplifier is connected to the first input of the algebraic adder, and its second input from connected to the output of the power amplifier, the input of which is connected to the output of the temperature sensor. I have TYA. in ХОВ dev ХЕ я 000 Computer keyboard!. Skvortsova.d (00000000 SE "Ukrainian Institute of Intellectual Property", str. Glazunova, 1, m. Kyiv - 42, 01601