UA152067U - Hydrogen storage and supply system - Google Patents

Abstract

The hydrogen storage and supply system 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, two electric motors, two gearboxes, dampers located in the outlet of the gas generator, a sensor for the position of the dampers, switches, a sinusoidal signal generator, a control unit, a filter, and an information processing unit and the connections that are caused by them.

Description

The useful model belongs to the field of hydrogen energy, in particular to systems of obtaining, storing and supplying hydrogen, and can be used in both stationary and non-stationary versions.

A hydrogen storage and supply system is known, which 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, switches, a sinusoidal electric voltage generator, an adder, inverting amplifier, integrators, computing device, control system, damper, which is placed in the outlet of the gas generator, to which is mechanically connected the reducer, which is connected to the shaft of the electric motor, while the first output of the pressure sensor is through the amplifier, the trigger and the first amplifier of power is connected to the control input of the electromagnetic valve, the input of which is connected to the cavity of the gas generator, its output is connected to the compensation tank, the second output of the pressure sensor is connected to the input of the second power amplifier, the first input of the control system is connected to the output of the generator sinusoidal electric voltage and with the second output ohms of the second switch, the input of which is connected to the control winding of the electric motor and to the first output of the first switch, the input of which is connected to the output of the second power amplifier, while the second output of the first switch is connected to the input of the third switch, the second output of which is connected with the first input of the adder, the output of which is connected through the phase-inverting amplifier and two integrators to the first input of the computing device and to the second input of the adder, while the output of the first integrator is connected to the second input of the computing device, the output of which is connected to the second input of the system control, the first output of this control system is connected to the control inputs of the first and second switches, and the second output of the control system is connected to the control input of the third switch (11.

The disadvantage of such a hydrogen storage and supply system is that, when monitoring its technical condition, the process of supplying hydrogen to the consumer is uncontrollable.

The closest analogue is a 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,

Z electric motors, reducers, commutator, sinusoidal signal generator, filter, control unit, information processing unit, dampers that are placed in the outlet of the gas generator, damper position sensor, the output of which is connected to the second input of the information processing unit, the first input of which is connected to the output of the filter, while the output of the water level sensor through the amplifier, the trigger and the first power amplifier is connected to the control input of the solenoid valve, through which the cavity of the gas generator is connected to the tank for compensation, the output of the pressure sensor is connected to the input of the filter and through the second power amplifier with the control winding of the first electric motor, the shaft of which is connected to the first damper through the first reducer, the output of the information processing unit is connected to the input of the control unit, its output is connected to the control input of the commutator, through which the output of the generator of the sinusoidal signal is connected through the third power amplifier to the control winding of the dru of an electric motor, the shaft of which is connected to the second valve |21 through the second reducer.

The disadvantage of such a hydrogen storage and supply system is that when monitoring its technical condition, there is no selection of functional elements of the system that meet or do not meet the requirements of regulatory documentation.

The useful model is based on the solution of the task of ensuring the selection of functional elements when determining the technical condition of the hydrogen storage and supply system.

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, electric motors, reducers, a switch, a generator of a sinusoidal signal, a filter, a control unit, an information processing unit, dampers that are placed in the outlet of the gas generator, a damper position sensor, while the output of the water level sensor is connected through an amplifier, a trigger and a first power amplifier to the control input of the electromagnetic valve, through which the cavity of the gas generator is connected to the compensation tank, the output of the sinusoidal signal generator is connected to the input of the switch, the control input of which is connected to the output of the control unit, the input of which is connected to the output of the information processing unit, to the first input of which the output of the filter is connected , the output of the second power amplifier is connected to the control winding the output of the first electric motor, the shaft of which is connected to the first damper through the first reducer 60, and the output of the third power amplifier is connected to the control winding of the second electric motor, the shaft of which is connected to the second damper through the second reducer, according to a useful model, two switches and a second valve position sensor are additionally introduced, the output of which is connected to the second input of the first switch, the output of the first position sensor is connected to the first input of the first switch, its output is connected to the second input of the information processing unit, the output of the pressure sensor is connected to the input of the filter and to the input of the second switch, the first output of which is connected to the input of the second power amplifier and to the second output of the switch, the second output of the second switch is connected to the input of the third power amplifier and to the first output of the switch, and the control inputs of the first and the second switches are connected to the output of the control unit.

The drawing shows a diagram of the hydrogen storage and supply system, which shows: 1 - gas generator; 1.1 - water; 2 - a sample of hydroreactive composition; C - gas generator outlet: 4 - water level sensor; 5 - amplifier; b - trigger; 7, 16, 19 - power amplifiers; 8 - electromagnetic valve; 9 - capacity for compensation; 10 - pressure sensor; 11-13 - switches; 14 - control unit; 15 - sinusoidal signal generator; 17, 20 - electric motors; 18, 21 - reducers; 22, 23 - dampers; 24, 25 - flap position sensors; 26 - filter; 27 - information processing unit; H5g - hydrogen. The output of the water level sensor 4 through the amplifier 5, the trigger 6 and the power amplifier 7 is connected to the control input of the electromagnetic valve 8, through which the cavity of the gas generator is connected to the capacity for compensation 9. In the outlet C of the gas generator 1, dampers 22 and 23 are placed, which are connected to reducers 18 and 21, respectively.

The output of the position sensor 24 of the damper 22 is connected to the second input of the switch 13, the first input of which is connected to the output of the position sensor 25 of the damper 23. The output of the switch 13 is connected to the second input of the information processing unit 27, the output of which is connected to the inputs control switches 11-13, and its first input is connected to the output of the filter 26. The output of the pressure sensor 10 is connected to the input of the filter 26 and to the input of the switch 11, the first output of which is connected through the power amplifier 16 to the control winding of the electric motor 17, the rotor of which is connected to the gearbox 18. The second output of the commutator 11 is connected to the first output of the commutator 12 and through the power amplifier 19 - to the control winding of the electric motor 20, the rotor of which is connected to the gearbox 21. The second output of the commutator 12 with connected to the first output of the switch 11. The input of the switch 12 is connected to the output of the generator

From a sinusoidal signal 15.

The hydrogen storage and supply system works as follows:

The hydrogen generation process is carried out as a result of the interaction of water 1.1 with a sample of hydroreactive composition 2. During hydrogen generation, water level control 1.1 in the gas generator cavity 1 is ensured using a water level sensor 4. When the water level exceeds the standard value according to the signal from the water level sensor 4, which comes through the amplifier 5, the trigger b and the power amplifier 7 to the control input of the solenoid valve 8, water 1.1 from the cavity of the gas generator 1 through this solenoid valve enters the tank for compensation 9.

The pressure value in the cavity of the gas generator 1 is maintained by controlling the position of the valves 22, 23, which are located in the outlet C of the gas generator 1. When the pressure value in the cavity of the gas generator 1 deviates from the standard value, a corresponding signal appears at the output of the pressure sensor 10. This signal through the switch 11, the power amplifier 16, the electric motor 17 is sent to the reducer 18, with the help of which the position of the damper 22 changes, as a result of which a change in the pressure value in the cavity of the gas generator 1 is ensured to the standard value.

At the same time, a sinusoidal signal of a fixed frequency is sent from the sinusoidal signal generator 15 to the input of the power amplifier 19. This signal, with the help of the electric motor 20 and the reducer 21, controls the valve 23, the position of which changes according to the sinusoidal law. The position of this damper is determined by the position sensor 25, the signal from the output of which is fed through the switch 13 to the second input of the information processing unit 27. The first input of this unit receives a sinusoidal signal from the output of the filter 26, which is tuned to the frequency of the sinusoidal signal generator 15. In the information processing unit 27, the ratio of the amplitudes of the signals arriving at its first and second inputs is determined. This ratio is compared with the a priori set value, and after receiving the result of the comparison, the information processing unit 27 issues a corresponding signal to the control unit 14. According to the command from the control unit 14, the switches 11-13 are switched and the signal from the pressure sensor 10 through the switch 11 is sent to the input of the amplifier power 19 and with the help of an electric motor 20 and a reducer 21, the position of the damper 25 is changed in such a way as to counter the change in pressure in the gas generator 1 cavity. with the help of the electric motor 17 and the reducer 18, the position of the damper 22 is changed according to the sinusoidal law.

The position of the damper 22 is determined by the position sensor 24, the output of which is connected to the second input of the information processing unit 27. The first input of this unit receives a signal from the output of the filter 26 and the information processing unit 27 determines the ratio of the amplitudes of the incoming sinusoidal signals to its first and second inputs . This result is compared with a priori given value. If the parameters of links 16-22 and 19-25 are the same, then the coincidence of the result of the first comparison with the result of the second comparison indicates that the technical condition of the hydrogen storage and supply system meets the requirements of regulatory documents. The information processing unit 27 issues a corresponding signal to the control unit 14 and the operation cycle of the hydrogen storage and supply system is repeated.

In the event that the results of the first and second comparison of the amplitudes of the sinusoidal signals in the information processing unit 27 do not coincide with the a priori set values, the information processing unit 27 issues a signal indicating that the technical condition of the gas generator 1 of the hydrogen storage and supply system is not meets the requirements of regulatory documents. If there is a situation where, during one comparison of the amplitude of the sinusoidal signals in the information processing unit 27, there is a coincidence with the a priori set value, and during another comparison, such a coincidence is absent, then the information processing unit 27 issues a signal indicating that the corresponding link ( power amplifier, electric motor, reducer and damper) does not meet the requirements of regulatory documents.

Thus, the introduction of two switches, the second damper position sensor and the connections caused by them ensure the selection of functional elements when the technical condition of the hydrogen storage and supply system is determined.

Sources of information: 1. Patent of Ukraine Mo 131810, IPC 018 3/06, E17S 13/10, 2019. 2. Patent of Ukraine Mo 150662, IPC 018 3/06, RI7S 13/00, 2022.

Claims (1)

USEFUL MODEL FORMULA З Hydrogen storage and supply system, which 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, electric motors, reducers, a commutator, a sine wave generator, a filter, a block control, an information processing unit, dampers that are placed in the outlet of the gas generator, a damper position sensor, while the output of the water level sensor is connected through the amplifier, trigger and first power amplifier to the control input of the electromagnetic valve, through which the cavity of the gas generator is connected to capacitor for compensation, the output of the sinusoidal signal generator is connected to the input of the switch, the control input of which is connected to the output of the control unit, the input of which is connected to the output of the information processing unit, to the first input of which the output of the filter is connected, the output of the second power amplifier with connected to the control winding of the first electric motor, the shaft of which is connected to the first damper through the first reducer, and the output of the third power amplifier is connected to the control winding of the second electric motor, the shaft of which is connected to the second damper through the second reducer, which differs in that two commutators and a second damper position sensor, the output of which is connected to the second input of the first switch, the output of the first position sensor is connected to the first input of the first switch, its output is connected to the second input of the information processing unit, the output of the pressure sensor is connected to the filter input and with the input of the second switch, the first output of which is connected to the input of the second power amplifier and to the second output of the switch, the second output of the second switch is connected to the input of the third power amplifier and to the first output of the switch, and the control inputs of the first and second switches are connected with the output of the control unit.