CN212404294U - Combined type alkali liquor circulating device and alkaline electrolyzed water hydrogen production system - Google Patents

Abstract

The utility model relates to a modular alkali lye circulating device and alkaline electrolysis water hydrogen manufacturing system, modular alkali lye circulating device is used for the alkali lye supply of alkaline electrolysis water hydrogen manufacturing, including the alkali lye filter, mend the alkali module, modular alkali lye circulation module and alkali lye circulation controller, the vapour and liquid separator liquid output of alkaline electrolysis water hydrogen manufacturing device and the alkali module of meneing are connected respectively to alkali lye filter input, alkali lye filter output is connected to the electrolysis trough formation closed loop circulation system of alkaline electrolysis water hydrogen manufacturing device through modular alkali lye circulation module, mend alkali module and modular alkali lye circulation module and all be connected to alkali lye circulation controller, modular alkali lye circulation module includes a plurality of alkali lye circulation branch roads that have different alkali lye flow ranges, the parallelly connected setting of alkali lye circulation branch road, in operation, 1 at least alkali lye circulation branch road work. Compared with the prior art, the utility model provides high adaptability under the wide power fluctuation of alkaline electrolysis water has promoted alkali lye circulation system's economical.

Description

Combined type alkali liquor circulating device and alkaline electrolyzed water hydrogen production system

Technical Field

The utility model relates to an alkaline electrolysis water hydrogen manufacturing technical field especially relates to a modular alkali lye circulating device and alkaline electrolysis water hydrogen manufacturing system.

Background

The source of hydrogen is an important issue for the development of hydrogen energy at present, and hydrogen is still used as an industrial raw material gas at present, so that the hydrogen has rich application in chemical industry, and from the source, three mature technical routes are mainly provided; firstly, hydrogen is produced by reforming fossil energy; secondly, hydrogen is produced as a by-product in industry; thirdly, electrolyzing water to produce hydrogen. In the process of hydrogen production by water electrolysis, the most mature technical route at present is an alkaline water electrolysis technology. The existing related researches do not consider the problem of alkali liquor supply of the hydrogen production by alkaline electrolysis under different power working, lack of wide power adaptability adaptation of alkaline electrolysis hydrogen production equipment starting from system alkali liquor circulation, lack of a combined alkali liquor circulation system and a control strategy of an alkaline electrolysis hydrogen production device.

SUMMERY OF THE UTILITY MODEL

The utility model aims to overcome the defects of the prior art and provide a combined type alkali liquor circulating device and an alkaline electrolyzed water hydrogen production system.

The purpose of the utility model can be realized through the following technical scheme:

the utility model provides a modular alkali lye circulating device for alkali lye supply of basicity brineelectrolysis hydrogen manufacturing, includes alkali lye filter, mends alkali module, modular alkali lye circulation module and alkali lye circulation controller, alkali lye filter input connect respectively basicity brineelectrolysis hydrogen manufacturing installation's vapour and liquid separator liquid output and mend alkali module, alkali lye filter output form closed loop circulation system through the electrolysis trough that modular alkali lye circulation module is connected to basicity brineelectrolysis hydrogen manufacturing installation, mend alkali module and modular alkali lye circulation module all be connected to alkali lye circulation controller, modular alkali lye circulation module include a plurality of alkali lye circulation branch roads that have different alkali lye flow ranges, alkali lye circulation branch road parallelly connected setting, in the course of the work, 1 at least alkali lye circulation branch road work.

The alkali supplementing module comprises an alkali liquor box and an alkali supplementing pump, the alkali liquor box is connected to an alkali liquor filter through the alkali supplementing pump, and the alkali supplementing pump is connected to an alkali liquor circulation controller.

The alkali liquor circulation branch comprises an alkali liquor circulation pump, the input end of the alkali liquor circulation pump is connected with an alkali liquor filter, the output end of the alkali liquor circulation pump is connected to an electrolytic bath of the alkaline electrolyzed water hydrogen production device through an alkali liquor flowmeter, and the alkali liquor circulation pump and the alkali liquor flowmeter are both connected to an alkali liquor circulation controller.

The alkali liquor flow range of the alkali liquor circulating pumps in the alkali liquor circulating branches arranged in parallel is configured to change according to a gradient form.

The alkali liquor flow range of the alkali liquor circulating pump is specifically configured as follows:

Q_{A1_max}＞Q_{A2_max}＞…＞Q_{An_max}，

Q_{A1_min}＞Q_{A2_min}＞…＞Q_{An_min}，

wherein Q is_{A1_max}Is the maximum lye flow, Q, of the lye circulating pump in the 1 st lye circulating branch_{A2_max}Is the maximum lye flow, Q, of the lye circulating pump in the 2 nd lye circulating branch_{An_max}Is the maximum lye flow of the lye circulating pump in the nth lye circulating branch, Q_{A1_min}Is the minimum alkali liquor flow, Q, of the alkali liquor circulating pump in the 1 st alkali liquor circulating branch_{A2_min}Is the minimum alkali liquor flow, Q, of the alkali liquor circulating pump in the 2 nd alkali liquor circulating branch_{An_min}The minimum alkali liquor flow of the alkali liquor circulating pump in the nth alkali liquor circulating branch, and n is the total number of the alkali liquor circulating branches.

The alkali liquor circulation controller is configured into a microprocessor chip which can start the alkali supplement module to work according to alkali supplement flow requirements and control the corresponding alkali liquor circulation branch to work according to alkali liquor circulation flow requirements.

The system further comprises the combined alkali liquor circulating device, the input end of an alkali liquor filter in the combined alkali liquor circulating device is connected with the liquid output end of the gas-liquid separator of the alkaline electrolyzed water hydrogen production device, and a combined alkali liquor circulating module in the combined alkali liquor circulating device is connected to the electrolytic tank of the alkaline electrolyzed water hydrogen production device to form a closed-loop circulating system.

The alkaline electrolyzed water hydrogen production device further comprises an alkaline liquor circulating heat exchanger, a cooling water tank and a cooling water pump, wherein the output end of a combined alkaline liquor circulating module in the combined alkaline liquor circulating device is connected to an electrolytic bath of the alkaline electrolyzed water hydrogen production device through the alkaline liquor circulating heat exchanger, and the cooling water tank is connected to the alkaline liquor circulating heat exchanger through the cooling water pump to form a circulating heat exchange loop.

Compared with the prior art, the utility model has the advantages of as follows:

(1) the utility model adopts the alkali liquor circulating pump combined system containing different alkali liquor flow ranges, one or more alkali liquor circulating pumps can be simultaneously started, and the flow pump combination with smaller flow can meet the alkali liquor circulating demand, thereby improving the adaptability of the alkaline electrolyzed water under wide power fluctuation, improving the economy of an alkali liquor circulating system, and simultaneously reducing the flow demand of the maximum flow pump and reducing the cost due to the adoption of the combined alkali liquor circulating pump;

(2) the alkali liquor circulating pump combined framework with different accurate flow regulation intervals is adopted, and the alkali liquor flow can be accurately regulated and controlled in a wider alkali liquor flow interval, so that the accurate heat management of the alkaline electrolyzed water hydrogen production equipment is facilitated, the heat loss caused by excessive alkali liquor flow during lower alkaline electrolyzed water working power can be avoided, the standby time of the alkaline electrolyzed water hydrogen production equipment can be prolonged, and the full-period economy of the alkaline electrolyzed water hydrogen production equipment is improved.

(3) The alkali liquor circulating pump control strategy based on the current flow and the system flow demand is adopted, so that a wider accurate flow regulation and control interval can be ensured, the power loss caused by mismatching of the flow interval is reduced, and the working stability of the alkaline electrolyzed water hydrogen production equipment is enhanced.

Drawings

FIG. 1 is a schematic structural diagram of the alkaline electrolyzed water hydrogen production system of the present invention;

FIG. 2 is a block diagram of the combined type alkali liquor circulating device of the present invention;

FIG. 3 is a schematic diagram of the combined alkali liquor circulating device of the present invention;

FIG. 4 is a schematic power diagram of an alkaline electrolyzed water hydrogen production apparatus according to an embodiment of the present invention;

FIG. 5 is a schematic diagram of the demand of the flow rate of the alkaline liquid in the hydrogen production equipment by alkaline electrolysis of water according to the embodiment of the present invention;

FIG. 6 is a schematic diagram of the adjusting process of the combined type alkali liquor circulating device in the hydrogen production system by alkaline electrolysis of water in the embodiment of the present invention.

In the figure, 1 is an electrolytic bath, 2 is a rectifier transformer, 3 is an alkali liquor circulating heat exchanger, 4 is a cooling water tank, 5 is a cooling water pump, 6 is a hydrogen side diaphragm regulating valve, 7 is a hydrogen side gas-liquid separator, 8 is hydrogen purification equipment, 9 is an oxygen side diaphragm regulating valve, 10 is an oxygen collecting or post-processing device, 11 is an oxygen side gas-liquid separator, 12 is an alkali supplementing pump, 13 is an alkali liquor filter, 14 is an alkali liquor circulating pump, 15 is a combined alkali liquor circulating device, 16 is an alkali liquor tank, and 17 is an alkali liquor circulating controller.

Detailed Description

The present invention will be described in detail below with reference to the accompanying drawings and specific embodiments. Note that the following description of the embodiments is merely an example of the nature, and the present invention is not intended to limit the application or the use thereof, and the present invention is not limited to the following embodiments.

Examples

As shown in fig. 1 and fig. 2, a combined alkali liquor circulating device for supplying alkali liquor for hydrogen production from alkaline electrolyzed water comprises an alkali liquor filter 13, an alkali liquor supplementing module, a combined alkali liquor circulating module and an alkali liquor circulating controller 17, wherein the input end of the alkali liquor filter 13 is respectively connected with the liquid output end of a gas-liquid separator and the alkali liquor supplementing module of the hydrogen production device from alkaline electrolyzed water, the output end of the alkali liquor filter 13 is connected to an electrolytic cell 1 of the hydrogen production device from alkaline electrolyzed water through the combined alkali liquor circulating module to form a closed-loop circulating system, the alkali liquor supplementing module and the combined alkali liquor circulating module are both connected to the alkali liquor circulating controller 17, the combined alkali liquor circulating module comprises a plurality of alkali liquor circulating branches with different alkali liquor flow ranges, the alkali liquor circulating branches are arranged in parallel, and at least 1.

The alkali supplementing module comprises an alkali liquor box 16 and an alkali supplementing pump 12, the alkali liquor box 16 is connected to the alkali liquor filter 13 through the alkali supplementing pump 12, and the alkali supplementing pump 12 is connected to the alkali liquor circulation controller 17.

The alkali liquor circulation branch comprises an alkali liquor circulation pump 14, the input end of the alkali liquor circulation pump 14 is connected with an alkali liquor filter 13, the output end of the alkali liquor circulation pump 14 is connected to the electrolytic cell 1 of the alkaline electrolyzed water hydrogen production device through an alkali liquor flow meter, and the alkali liquor circulation pump 14 and the alkali liquor flow meter are both connected to an alkali liquor circulation controller 17.

The alkali liquor flow range of the alkali liquor circulating pumps 14 in the alkali liquor circulating branches arranged in parallel is configured to change according to a gradient form.

The alkali liquor flow range of the alkali liquor circulating pump 14 is specifically configured as follows:

Q_{A1_max}＞Q_{A2_max}＞…＞Q_{An_max}，

Q_{A1_min}＞Q_{A2_min}＞…＞Q_{An_min}，

wherein Q is_{A1_max}Is the maximum lye flow, Q, of the lye circulating pump 14 in the 1 st lye circulating branch_{A2_max}Is the maximum lye flow, Q, of the lye circulating pump 14 in the 2 nd lye circulating branch_{An_max}Is the maximum lye flow, Q, of the lye circulating pump 14 in the nth lye circulating branch_{A1_min}Is the minimum lye flow, Q, of the lye circulating pump 14 in the 1 st lye circulating branch_{A2_min}Is the minimum lye flow, Q, of the lye circulating pump 14 in the 2 nd lye circulating branch_{An_min}Is the minimum lye flow of the lye circulating pump 14 in the nth lye circulating branch, n is the total number of the lye circulating branches, and the unit of the lye flow is l/h. Therefore, the flow range of the combined type alkali liquor circulating module is as follows: q_{An_min}～Q_{A1_max}+Q_{A2_max}+…+Q_{An_max}。

Compared with the alkali liquor circulating pump 14 adopting the same technical level, the maximum alkali liquor flow rate is Q if the alkali liquor circulating pump can accurately control the flow rate_maxAnd Q is_max＝Q_{A1_max}There must be a minimum flow Q that it can precisely control_minAnd the minimum flow is less than the minimum regulating flow of the combined alkali liquor circulating module, Q_min＞Q_{An_min}. Therefore, the utility model provides a combination formula alkali lye circulation system can be very big widen the accurate flow control scope of alkaline electrolysis water hydrogen manufacturing system alkali lye circulation to the gaseous speed range and the operating power interval of producing of alkaline electrolysis water hydrogen manufacturing system have been enlarged.

The alkali liquor circulation controller 17 is configured as a microprocessor chip which can start the alkali supplement module to work according to the alkali supplement flow demand and control the corresponding alkali liquor circulation branch to work according to the alkali liquor circulation flow demand.

The system comprises an alkaline electrolyzed water hydrogen production device, wherein the alkaline electrolyzed water hydrogen production device comprises an electrolytic tank 1 and a gas-liquid separator, the system also comprises the combined type alkali liquor circulating device, the input end of an alkali liquor filter 13 in the combined type alkali liquor circulating device is connected with the liquid output end of the gas-liquid separator of the alkaline electrolyzed water hydrogen production device, and a combined type alkali liquor circulating module in the combined type alkali liquor circulating device is connected to the electrolytic tank 1 of the alkaline electrolyzed water hydrogen production device to form a closed-loop circulating system.

The alkaline electrolyzed water hydrogen production device further comprises an alkaline liquor circulating heat exchanger 3, a cooling water tank 4 and a cooling water pump 5, the output end of a combined alkaline liquor circulating module in the combined alkaline liquor circulating device is connected to an electrolytic tank 1 of the alkaline electrolyzed water hydrogen production device through the alkaline liquor circulating heat exchanger 3, and the cooling water tank 4 is connected to the alkaline liquor circulating heat exchanger 3 through the cooling water pump 5 to form a circulating heat exchange loop. In the cooling loop, cooling liquid in the cooling water tank 4 enters the alkali liquor circulating heat exchanger 3 through the cooling water pump 5 to cool the alkali liquor, and the outlet temperature of the alkali liquor is controlled, so that the temperature of the alkali liquor is fixed when the alkali liquor enters the electrolytic water hydrogen production equipment. Meanwhile, for alkali liquor circulation, the alkali liquor at the outlet of the alkali liquor circulating pump 14 enters the alkali liquor circulating heat exchanger 3 for cooling and then enters the electrolytic bath 1.

When the water electrolysis hydrogen production system works, alternating current power supply is converted into direct current power through the rectifier transformer 2 and enters the electrolytic cell 1, the electrolytic cell 1 is the core of the system, water in alkali liquor is electrolyzed into hydrogen and oxygen which are respectively separated out on the surface of an electrode, and the volume ratio of the hydrogen to the oxygen is approximately 2: 1, and enters a hydrogen and oxygen liquid outlet pipe and enters a gas-liquid separator. In the gas-liquid separator, the mixture of hydrogen, oxygen and alkali liquor flowing out from the electrolytic bath 1 respectively flows into a hydrogen-side gas-liquid separator 7 and an oxygen-side gas-liquid separator 11, after being washed and cooled by a hydrogen washing cooler in the morning, the gas and the liquid are separated under the action of gravity, the hydrogen and the oxygen are gradually separated and overflow from the alkali liquor and are respectively discharged through a hydrogen-side diaphragm regulating valve 6 and an oxygen-side diaphragm regulating valve 9, the hydrogen is pressurized or stored after passing through a hydrogen purification device 8, and the oxygen enters an oxygen collecting or post-processing device 10.

The water electrolysis hydrogen production system has high energy consumption and needs cooling heat dissipation during normal work. In the cooling module, cooling deionized water stored in a cooling water tank 4 enters an electrolytic tank 1 through a cooling water pump 5, the temperature of the hydrogen production module is kept within a working range, and after the cooling deionized water flows out of the electrolyzed water hydrogen production module, the cooling water is cooled through an alkali liquor circulating heat exchanger 3 and enters the cooling water tank 4.

The combined alkali liquor circulating device needs to pump the gas-removed alkali liquor into the electrolytic water device again after mechanical impurities are removed. The combined alkali liquor circulating device is controlled by an alkali liquor circulating controller 17, and alkali circulating pump management liquid discharged from the gas-liquid separator is pumped into the electrolytic tank 1 by an alkali liquor circulating pump 14 after solid impurities are removed by an alkali liquor filter 13, so that an alkali liquor closed-loop system is formed. Meanwhile, as the water is continuously consumed by electrolyzing the water to produce hydrogen, the prepared electrolyte needs to be added into the alkali liquor circulation from the alkali liquor tank 16 through a supply pump.

As shown in fig. 3, the operation process of the alkaline electrolyzed water hydrogen production system comprises the following steps:

(1) acquiring the alkali supplement flow demand and the alkali liquor circulation flow demand of the alkaline electrolyzed water hydrogen production device;

(2) when alkali supplement is needed, starting an alkali supplement module, and supplementing alkali liquor according to the alkali supplement flow demand calculated;

(3) according to the alkali liquor circulation flow demand, firstly judging whether the combined alkali liquor circulation module has alkali liquor circulation flow data, if so, executing the step (4), otherwise, starting an alkali liquor circulation branch with the highest alkali liquor flow range;

(4) judging whether the alkali liquor circulation flow demand is in the alkali liquor flow range of the currently started alkali liquor circulation branch, if so, keeping the current alkali liquor circulation branch running, and otherwise, executing the step (5);

(5) selecting a corresponding alkali liquor circulation branch according to the alkali liquor circulation flow demand for operation, specifically: reducing the primary alkali liquor circulation branch when the alkali liquor circulation flow demand is lower than the lower limit of the alkali liquor flow range of the current alkali liquor circulation branch; when the demand of the alkali liquor circulation flow is higher than the upper limit of the alkali liquor flow range of the current alkali liquor circulation branch, the primary alkali liquor circulation pump 14 is lifted;

(6) after the alkali liquor circulation branch needing to be operated is determined, the microprocessor chip starts the alkali liquor circulation pump 14 corresponding to the alkali liquor circulation branch, before the alkali liquor is conveyed to the alkaline electrolytic water hydrogen production equipment, actual alkali liquor flow data obtained through an alkali liquor flowmeter and the flow demand of the alkali liquor circulation pump 14 obtained through calculation are sent to the flow control module of the alkali liquor circulation pump 14, and the alkali liquor flow of the currently started alkali liquor circulation pump 14 is accurately controlled through the flow control module.

This embodiment has set up an alkaline electrolysis water hydrogen manufacturing system, wherein combination formula alkali lye circulating device sets up 4 alkali lye circulation branch roads, the flow range of the 1 st alkali lye circulating pump is 300 ~ 400l/h, the flow range of the 2 nd alkali lye circulating pump is 200 ~ 300l/h, the flow range of the 3 rd alkali lye circulating pump is 100 ~ 200l/h, the flow range of the 4 th alkali lye circulating pump is 5 ~ 100l/h, the alkali lye flow range of combination formula alkali lye circulating device is 50 ~ 400l/h from this, therefore, the flow interval that the device can accurate control is far greater than the single alkali lye circulating pump of equal technical level far away.

Referring to fig. 4, the working power of the alkaline water electrolysis hydrogen production equipment is constantly changed with time, so that the corresponding alkaline liquid flow demand of the alkaline liquid circulation equipment at different times can be calculated as shown in fig. 5.

FIG. 6 is a process for adjusting the combined type alkali liquor circulating device in the hydrogen production system by alkaline electrolysis of water:

before the time when t is 0h, the flow of the alkaline liquid required by the alkaline electrolytic water hydrogen production equipment is stabilized at 340l/h, so that the 1 st alkaline liquid circulating pump is started by the combined type alkaline liquid circulating system, and the flow interval of the pressure of the alkaline liquid circulating pump can be accurately controlled to be 300-400 l/h, so that the 1 st alkaline liquid circulating pump is started.

And when t is 1-4 h, the alkali liquor flow required by the alkaline electrolytic water equipment is gradually reduced to 300l/h, and the alkali liquor flow is equal to the lower limit of the 1 st alkali liquor circulating pump flow of 300l/h in the 1 st alkali liquor circulating pump adjusting interval, so that the 1 st alkali liquor circulating pump is still started.

When t is 5h, the alkali liquor flow required by the alkaline water electrolysis equipment is gradually reduced to 290l/h, the alkali liquor flow is not in the 1 st alkali liquor circulating pump adjusting interval and is smaller than the 1 st alkali liquor circulating pump flow lower limit 300l/h, the first-stage alkali liquor circulating pump needs to be reduced, and therefore the 2 nd alkali liquor circulating pump is started.

And when t is 8-10 h, the alkali liquor flow required by the alkaline electrolytic water equipment is gradually reduced to 210l/h, and the alkali liquor flow is greater than the lower limit of the 2 nd alkali liquor circulating pump flow by 200l/h in the adjusting interval of the 2 nd alkali liquor circulating pump, so that the 2 nd alkali liquor circulating pump is still started.

At t 11h, the alkali lye flow demand of alkaline electrolysis water hydrogen manufacturing equipment drops to 190l/h gradually, and the 2 nd alkali lye circulating pump is launched at present to the combination formula alkali lye circulating system, and the flow interval that the 2 nd alkali lye circulating pump can accurate control alkali lye is 200 ~ 300l/h, and the alkali lye flow need not reduce one-level alkali lye circulating pump in the alkali lye circulating pump regulation interval, consequently launches the 3 rd alkali lye circulating pump.

12 ~ 13h, the alkali lye flow demand of alkaline electrolysis water hydrogen manufacturing equipment drops to 110l/h gradually, and 3 rd alkali lye circulating pump has been launched to the combined type alkali lye circulating system, and the interval that 3 rd alkali lye circulating pump can the accurate control alkali lye flow is 100 ~ 200l/h, and the alkali lye flow demand is in the regulation interval of 3 rd alkali lye circulating pump, consequently still launches 3 rd alkali lye circulating pump.

When t is 14h, the alkali liquor flow demand of the hydrogen production equipment by alkaline electrolysis falls to 70l/h, the 3 rd alkali liquor circulating pump is started by the combined alkali liquor circulating system, the interval in which the 3 rd alkali liquor circulating pump can accurately control the alkali liquor flow is 100-200 l/h, the alkali liquor flow demand is smaller than the lower limit of the adjusting interval of the 3 rd alkali liquor circulating pump, the first-stage alkali liquor circulating pump needs to be reduced, and therefore the 4 th alkali liquor circulating pump needs to be started.

14 ~ 15h, the alkali lye flow demand of alkaline electrolysis water hydrogen manufacturing equipment keeps at 70l/h, and the combined type alkali lye circulating system has started the 4 th alkali lye circulating pump, and the interval that the 4 th alkali lye circulating pump can the accurate control alkali lye flow is 50 ~ 100l/h, and the alkali lye flow demand is in the regulation interval of 4 th alkali lye circulating pump, consequently still starts the 4 th alkali lye circulating pump.

When t is 16-18 h, the alkali liquor flow of the alkaline electrolytic water hydrogen production equipment rises and is kept at 100l/h, the 4 th alkali liquor circulating pump is started in the combined alkali liquor circulating system, the interval in which the 4 th alkali liquor circulating pump can accurately control the alkali liquor flow is 50-100 l/h, the alkali liquor flow demand is in the regulating interval of the 4 th alkali liquor circulating pump and is equal to the upper limit of the regulating interval, and therefore the 4 th alkali liquor circulating pump is still started.

When t is 19h, the lye flow of the alkaline water electrolysis hydrogen production equipment rises to 120l/h, the 4 th lye circulating pump is started by the combined lye circulating system, the interval that the 4 th lye circulating pump can accurately control the lye flow is 50-100 l/h, the lye flow demand is not in the adjusting interval of the 4 th lye circulating pump and is greater than the upper limit thereof, the first-level lye circulating pump needs to be lifted, and therefore the 3 rd lye circulating pump needs to be started.

19 ~ 20h, the alkali lye flow of alkaline electrolysis water hydrogen manufacturing equipment keeps at 120l/h, and 3 rd alkali lye circulating pump has been launched to combined type alkali lye circulating system, and the interval that 3 rd alkali lye circulating pump can accurate control alkali lye flow is 100 ~ 200l/h, and the alkali lye flow demand is in the regulation interval of 3 rd alkali lye circulating pump, consequently still launches 3 rd alkali lye circulating pump.

The above embodiments are merely examples and do not limit the scope of the present invention. These embodiments may be implemented in other various manners, and various omissions, substitutions, and changes may be made without departing from the technical spirit of the present invention.

Claims (8)

1. A combined type alkali liquor circulating device is characterized by being used for supplying alkali liquor for hydrogen production by alkaline electrolyzed water, comprising an alkali liquor filter (13), an alkali liquor supplying module, a combined type alkali liquor circulating module and an alkali liquor circulating controller (17), the input end of the alkali liquor filter (13) is respectively connected with the liquid output end of a gas-liquid separator of the alkaline electrolyzed water hydrogen production device and the alkali supplementing module, the output end of the alkali liquor filter (13) is connected to an electrolytic tank (1) of the alkaline electrolyzed water hydrogen production device through a combined alkali liquor circulating module to form a closed-loop circulating system, the alkali supplementing module and the combined type alkali liquor circulating module are both connected to an alkali liquor circulating controller (17), the combined alkali liquor circulating module comprises a plurality of alkali liquor circulating branches with different alkali liquor flow ranges, the alkali liquor circulating branches are arranged in parallel, and at least 1 alkali liquor circulating branch works in the working process.

2. The combined lye circulating device of claim 1 wherein the lye supplementing module comprises a lye tank (16) and a lye supplementing pump (12), said lye tank (16) being connected to the lye filter (13) by the lye supplementing pump (12), said lye supplementing pump (12) being connected to the lye circulation controller (17).

3. The combined alkali liquor circulating device according to claim 1, wherein the alkali liquor circulating branch comprises an alkali liquor circulating pump (14), an input end of the alkali liquor circulating pump (14) is connected with an alkali liquor filter (13), an output end of the alkali liquor circulating pump (14) is connected to the electrolytic tank (1) of the alkaline electrolyzed water hydrogen production device through an alkali liquor flow meter, and the alkali liquor circulating pump (14) and the alkali liquor flow meter are both connected to an alkali liquor circulating controller (17).

4. The combined lye circulation device of claim 2 wherein the lye circulation pumps (14) in the lye circulation branches arranged in parallel are arranged to have a lye flow range which varies in a gradient fashion.

5. The combined lye circulating device of claim 4 wherein the lye circulating pump (14) has a lye flow range which is specifically configured as:

Q_{A1_max}＞Q_{A2_max}＞…＞Q_{An_max}，

Q_{A1_min}＞Q_{A2_min}＞…＞Q_{An_min}，

wherein Q is_{A1_max}Is the maximum lye flow of a lye circulating pump (14) in the 1 st lye circulating branch, Q_{A2_max}Is the maximum lye flow of a lye circulating pump (14) in the 2 nd lye circulating branch, Q_{An_max}Is the maximum lye flow of a lye circulating pump (14) in the nth lye circulating branch, Q_{A1_min}Is the minimum lye flow of a lye circulating pump (14) in the 1 st lye circulating branch, Q_{A2_min}Is the minimum lye flow of a lye circulating pump (14) in the 2 nd lye circulating branch, Q_{An_min}Is the minimum lye flow of the lye circulating pump (14) in the nth lye circulating branch, and n is the total number of the lye circulating branches.

6. The combined lye circulating device of claim 1 wherein the lye circulating controller (17) is configured as a microprocessor chip which enables the lye circulating module to be activated according to the lye flow requirements and controls the operation of the corresponding lye circulating branch according to the lye circulating flow requirements.

7. An alkaline water electrolysis hydrogen production system comprises an alkaline water electrolysis hydrogen production device, wherein the alkaline water electrolysis hydrogen production device comprises an electrolytic cell (1) and a gas-liquid separator, and is characterized by further comprising the combined type alkaline liquid circulation device according to any one of claims 1 to 6, the input end of an alkaline liquid filter (13) in the combined type alkaline liquid circulation device is connected with the liquid output end of the gas-liquid separator of the alkaline water electrolysis hydrogen production device, and a combined type alkaline liquid circulation module in the combined type alkaline liquid circulation device is connected to the electrolytic cell (1) of the alkaline water electrolysis hydrogen production device to form a closed-loop circulation system.

8. The system for producing hydrogen by using alkaline electrolyzed water as defined in claim 7, characterized in that the device for producing hydrogen by using alkaline electrolyzed water further comprises an alkaline liquid circulating heat exchanger (3), a cooling water tank (4) and a cooling water pump (5), wherein the output end of the combined alkaline liquid circulating module in the combined alkaline liquid circulating device is connected to the electrolytic tank (1) of the device for producing hydrogen by using alkaline liquid circulating heat exchanger (3), and the cooling water tank (4) is connected to the alkaline liquid circulating heat exchanger (3) by using cooling water pump (5) to form a circulating heat exchange loop.

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