Comprehensive experimental platform for new energy hydrogen production, storage, and power generation technology

Comprehensive experimental platform for new energy hydrogen production, storage, and power generation technology

1. Familiar with the principles and operational strategies of hydrogen storage systems for renewable energy generation.

2. Understand the impact of renewable energy generation fluctuations on system operation and control strategies.

3. Understand the technical principles and device structures of hydrogen production through electrolysis of water, fuel cell power generation, and solid-state hydrogen storage.

4. Understand the principle of solid-state hydrogen storage and the operation process of hydrogen storage/release in storage tanks.

5. Understand the temperature evolution law and thermal management effect of PCM phase change materials.

6. Understand the structural characteristics and system operation differences of solid-state hydrogen storage tanks and gas pressure hydrogen storage tanks.

7. Learn thermal management and thermal reinforcement techniques, understand the principles and energy-saving effects of comprehensive energy management in energy systems.

twoTechnical indicators

1. System operating pressure: using solid-state hydrogen storage device, 0.3MPa-0.8MPa; Using gas pressure storage tanks, 1MPa-2MPa.

2. System operating temperature: -10°C-80°C。

3. Safety protection: It has grounding protection, leakage protection, and overcurrent protection.

4. Device dimensions: 1200 × 700 × 1750mm.

threeMain configuration and parameters

1. Simulated power generation system: Battery type: Lead acid maintenance free; Battery capacity: 12V/18V 45AH; Battery connection method: multiple sections in series; Battery protection: not terminated with a fuse; Equipment protection: battery over discharge protection, battery reverse connection protection, output overload protection, output short circuit protection, overheating protection, etc;

2. Electrolytic hydrogen production system: Input 220/50Hz, 120W, hydrogen generator uses deionized water (i.e. pure water) electrolysis, flow rate is controllable; Hydrogen purity: not less than 99.99%; Output flow rate: not less than 300ml/min; Output pressure: 0.3MPa-0.8MPa; The maximum power reaches 160W;

3. Hydrogen energy storage system:

Solid state hydrogen storage tank: The tank is made of austenitic stainless steel materialThe pressure resistance shall not be less than 1.25MPa; Hydrogen storage material: LaNi5 alloy material; Outsourcing PCM: Paraffin wax, melting point 60°C. The service life shall not be less than 10 years, equipped with precision pressure gauges and sensors,ModbusRTU / RS 485Or analog quantity4-20mA output;

Gas pressure hydrogen storage tank: made of austenitic stainless steel materialThe pressure resistance shall not be less than 1.25 MPa, and the service life shall not be less than 10 years. It shall be equipped with precision pressure gauges, precision pressure sensors, modbusRTU/RS485 or analog 4-20mA output; The hydrogen energy management system can automatically monitor and manage hydrogen pressure, hydrogen output, hydrogen shutdown, etc., enhancing the safety and efficiency of hydrogen use.

4. Fuel cell stack: rated output: 100W, 14/7.2A; Number of single cells: 24 pieces; Reactive substances: hydrogen, air; Hydrogen supply quality: dry, purity 99.99%; Air cold.

5. Thermal management system: thermal coupling between solid-state hydrogen storage tanks and fuel cell stacks; Plate heat exchanger; Plate material: 316L stainless steel; Design temperature: -20°C-100°C. Design pressure: 5 bar (maximum).

6. Automatic control and monitoring system: environmental detection sensor: temperature detection range: -40 ℃~85 ℃; Temperature detection accuracy: 0.5 ℃; Pressure monitoring range: 0-1MPA;

7. Human computer interface:

1) Built in hydrogen energy management software on-site. Touch screen size:7″；MCGS

Screen type:TFTLCD display screen; Resolution:800×480; Memory:128MSerial interface:RS232/RS485Power supply voltage:24±20%VDCAutomatic control system:

2) Main control module

AC220V/50HZInput;14Digital input,10Quantity output;

8. Exhaust gas analysis system: Temperature detection range:-40℃～85℃； Temperature detection accuracy: ±0.5℃； Humidity detection range:0-99.9%RHHumidity detection accuracy:±3%RHRange of hydrogen concentration detection:0-40000PPMSensor communication interface: isolatedRS485Or analog output;

9. Upper computer unit (with built-in hydrogen energy management software upper computer end):CPU：IntelCore i5; Memory:DDR3 8G; Hard drive:7200turn/1TBGraphics card:Intel HD GraphicScreen:22Inch high-definition display（1920*1080）.

10. Cabinet material and size: Plate: hot-dip galvanized treatment; Surface baking paint process for board materials; Steel plate thickness:2mmThe cabinet is carefully designed with a beautiful and innovative structure, making it easy to operate and read data.

11.Equipment matching3D virtual simulation software, AI simulation software management platform:

（1) ▲ User permission management: ① Support unified management of PC simulation systems and support user permission management; ② Support unified management of PC simulation systems and user permission management; ③ School administrator users: can create and manage teacher accounts and manage information such as departments/majors; ④ School administrator account: has functions such as user management, administrator password modification, and backend management. ⑤ School administrator: can manage departments and display and manage user information, and can export created information with one click;

（2) ▲ Teacher administrator: ① "Add class information - Generate class information - Add invitation code - Generate student invitation code", which can automatically assign students registered through the invitation code to the corresponding class, modify class information, update expired invitation codes, and set usage duration;

（3) ▲ Platform functions: ① Navigation bar at the top of the platform, welcome login prompt, display of user information, date, time, etc; ② The system list supports functions such as search, sorting, and classification. The sorting system supports adding time, reverse sorting, and classification sorting; Can filter system names, system categories, etc. based on keywords; ③ The system supports broadcasting, announcements, message prompts, etc;

（4) ▲ Courseware update function: ① The system can automatically detect software update function. After entering the simulation management platform, click on the courseware update icon, and you can update it with one click or select a single one based on the displayed pop-up list;

（5) ▲ Product information display function: a. Select any simulation system courseware from the list on the left, and the introduction information of the selected simulation system courseware can be displayed on the right, including the name, display image, and description information of the simulation system courseware; b. Provide a download function for simulation system courseware, click "Enter" to enter the corresponding simulation system courseware; c. Provide teaching video display function for simulation system courseware: Teaching videos associated with courseware can be displayed below the software. When the video is played, it will automatically loop and can be controlled to play/pause. It also supports full screen viewing; d. Provide courseware product manual display function: The right side of the teaching video displays electronic document information such as relevant product manuals or design drawings that have been imported into the courseware, and supports downloading locally, which can be opened and viewed at any time; e. Provide student assessment display function: The lower area of the product manual displays the statistics of students' assessment results in the system, and also provides filtering functions for colleges, classes, etc; f. Assessment details function: It can summarize and view the assessment scores of all students in the school, and evaluate the learning situation of various simulation courseware and students through charts and other forms.

（6) The software has functions such as experimental principles, experimental purposes, experimental steps, text assisted recognition equipment, simulation experiments, etc. It can view various angles from a 360 ° roaming perspective of the character; Students take the exam according to the experimental steps, and the system can score on site and upload it to the teacher's end; Can query students' previous exam scores and their use of 3D simulation software;

（7) Provide high-definition screenshots of each function of the above software in the bidding documents; And provide the software function recording of the above "▲" in the form of QR code, so that the judges can clearly see the content of each parameter, verify the simulation function of the 3D platform and software. After winning the bid, the purchaser has the right to request the winning bidder to provide a software installation package for parameter demonstration.

fourCan complete the research project

At the bottomPrinciple and composition of renewable energy generation and hydrogen storage system

At the bottomComposition and Control of Fuel Cell Control System

At the bottomThe electric stackIV polarization characteristic curve

At the bottomPower characteristic curve of fuel cell stack

At the bottomExperiment on measuring the efficiency of electrolytic hydrogen production

At the bottomExperimental study on flow measurement and control of electrolytic hydrogen production

At the bottomCell stack output and exhaust gas analysis experiment

At the bottomSolid state hydrogen storage tank storage/Evolution curves of temperature, pressure, and concentration during hydrogen release process

At the bottomComparative testing experiment on the performance of different hydrogen storage technology systems

At the bottomComparative experiment on control of different hydrogen storage technology systems

At the bottomstore/PCM temperature evolution curve during hydrogen release process

At the bottomComparative testing experiment of different thermal management schemes for solid-state hydrogen storage tanks

At the bottomSolid state hydrogen storage tank storage/Composition and Control of Hydrogen Release Control System

At the bottomPrinciple and composition of thermal management coupling between solid-state hydrogen storage tanks and fuel cells

At the bottomComposition and Control of Coupled Thermal Management Control System

At the bottomDesign principle and composition of comprehensive energy management for hydrogen storage system

At the bottomComprehensive Energy Management Testing and Analysis Experiment of Hydrogen Energy Storage System

At the bottomMeasurement and Control of Hydrogen Energy Storage System Parameters

At the bottomSimulate fluctuations and control of renewable energy generation

At the bottomHuman computer interface design and communication control

Series experimental platform and module optional installation

1、 Series experimental platform

1. Hydrogen storage new energy generation experimental platform

(1) Platform equipment

Simulated power generation system, electrolysis of water for hydrogen production, fuel cell power generation, solid-state hydrogen storage tank (with thermal enhancement), plate heat exchanger, load, sensors, etc

(2) Capable of completing research projects

At the bottomPrinciple and composition of renewable energy generation and hydrogen storage system

At the bottomComposition and Control of Fuel Cell Control System

At the bottomThe electric stackIV polarization characteristic curve

At the bottomPower characteristic curve of fuel cell stack

At the bottomExperiment on measuring the efficiency of electrolytic hydrogen production

At the bottomExperimental study on flow measurement and control of electrolytic hydrogen production

At the bottomCell stack output and exhaust gas analysis experiment

At the bottomSolid state hydrogen storage tank storage/Evolution curves of temperature, pressure, and concentration during hydrogen release process

At the bottomSolid state hydrogen storage tank storage/Hydrogen release control

At the bottomPrinciple and composition of thermal management coupling between solid-state hydrogen storage tanks and fuel cells

At the bottomComposition and Control of Coupled Thermal Management Control System

At the bottomMeasurement and Control of Hydrogen Energy Storage System Parameters

At the bottomSimulate fluctuations and control of renewable energy generation

At the bottomHuman computer interface design and communication control

2. Hydrogen storage new energy generation PCM thermal management experimental platform

(1) Platform equipment

Simulated power generation system, electrolysis of water for hydrogen production, fuel cell power generation, solid-state hydrogen storage tank（PCM thermal management, with heat enhancement, plate heat exchangers, loads, sensors, etc

(2) Capable of completing research projects

At the bottomPrinciple and composition of renewable energy generation and hydrogen storage system

At the bottomComposition and Control of Fuel Cell Control System

At the bottomThe electric stackIV polarization characteristic curve

At the bottomPower characteristic curve of fuel cell stack

At the bottomExperiment on measuring the efficiency of electrolytic hydrogen production

At the bottomExperimental study on flow measurement and control of electrolytic hydrogen production

At the bottomCell stack output and exhaust gas analysis experiment

At the bottomSolid state hydrogen storage tank storage/Evolution curves of temperature, pressure, and concentration during hydrogen release process

At the bottomstore/PCM temperature evolution curve during hydrogen release process

At the bottomComparative testing experiment of different thermal management schemes for solid-state hydrogen storage tanks

At the bottomSolid state hydrogen storage tank storage/Composition and Control of Hydrogen Release Control System

At the bottomPrinciple and composition of thermal management coupling between solid-state hydrogen storage tanks and fuel cells

At the bottomComposition and Control of Coupled Thermal Management Control System

At the bottomMeasurement and Control of Hydrogen Energy Storage System Parameters

At the bottomSimulate fluctuations and control of renewable energy generation

At the bottomHuman computer interface design and communication control

3. Hydrogen storage new energy generation thermal enhancement comparative experimental platform

(1) Platform equipment

Simulated power generation system, electrolysis of water for hydrogen production, fuel cell power generation, solid-state hydrogen storage tank (with detachable heat transfer structure), plate heat exchanger, load, sensors, etc

(2) Capable of completing research projects

At the bottomPrinciple and composition of renewable energy generation and hydrogen storage system

At the bottomComposition and Control of Fuel Cell Control System

At the bottomThe electric stackIV polarization characteristic curve

At the bottomPower characteristic curve of fuel cell stack

At the bottomExperiment on measuring the efficiency of electrolytic hydrogen production

At the bottomExperimental study on flow measurement and control of electrolytic hydrogen production

At the bottomCell stack output and exhaust gas analysis experiment

At the bottomSolid state hydrogen storage tank storage/Evolution curves of temperature, pressure, and concentration during hydrogen release process

At the bottomComparative Test Experiment on Thermal Enhancement Design of Solid State Hydrogen Storage Tanks

At the bottomComparative testing experiment of natural convection and forced convection heat transfer in solid-state hydrogen storage tanks

At the bottomSolid state hydrogen storage tank storage/Composition and Control of Hydrogen Release Control System

At the bottomPrinciple and composition of thermal management coupling between solid-state hydrogen storage tanks and fuel cells

At the bottomComposition and Control of Coupled Thermal Management Control System

At the bottomMeasurement and Control of Hydrogen Energy Storage System Parameters

At the bottomSimulate fluctuations and control of renewable energy generation

At the bottomHuman computer interface design and communication control

4. Hydrogen storage new energy generation - hydrogen storage technology comparative experimental platform

(1) Platform equipment

Simulated power generation system, electrolytic water hydrogen production, fuel cell power generation, solid-state hydrogen storage tank (with thermal enhancement), gaseous hydrogen storage tank, plate heat exchanger, load, sensor, etc

(2) Capable of completing research projects

At the bottomPrinciple and composition of renewable energy generation and hydrogen storage system

At the bottomComposition and Control of Fuel Cell Control System

At the bottomThe electric stackIV polarization characteristic curve

At the bottomPower characteristic curve of fuel cell stack

At the bottomExperiment on measuring the efficiency of electrolytic hydrogen production

At the bottomExperimental study on flow measurement and control of electrolytic hydrogen production

At the bottomCell stack output and exhaust gas analysis experiment

At the bottomSolid state hydrogen storage tank storage/Evolution curves of temperature, pressure, and concentration during hydrogen release process

At the bottomComparative testing experiment on the performance of different hydrogen storage technology systems

At the bottomComparative experiment on control of different hydrogen storage technology systems

At the bottomSolid state hydrogen storage tank storage/Composition and Control of Hydrogen Release Control System

At the bottomPrinciple and composition of thermal management coupling between solid-state hydrogen storage tanks and fuel cells

At the bottomComposition and Control of Coupled Thermal Management Control System

At the bottomMeasurement and Control of Hydrogen Energy Storage System Parameters

At the bottomSimulate fluctuations and control of renewable energy generation

At the bottomHuman computer interface design and communication control

5. Hydrogen storage new energy generation - refrigeration and consumption experimental platform

(1) Platform equipment

Simulated power generation system, electrolysis of water for hydrogen production, fuel cell power generation, solid-state hydrogen storage tank（PCM thermal management, heat enhancement, plate heat exchanger, thermoelectric refrigeration, air supply device, load, integrated energy management system, sensors, etc

(2) Capable of completing research projects

At the bottomPrinciple and composition of renewable energy generation and hydrogen storage system

At the bottomComposition and Control of Fuel Cell Control System

At the bottomThe electric stackIV polarization characteristic curve

At the bottomPower characteristic curve of fuel cell stack

At the bottomExperiment on measuring the efficiency of electrolytic hydrogen production

At the bottomExperimental study on flow measurement and control of electrolytic hydrogen production

At the bottomCell stack output and exhaust gas analysis experiment

At the bottomSolid state hydrogen storage tank storage/Evolution curves of temperature, pressure, and concentration during hydrogen release process

At the bottomstore/PCM temperature evolution curve during hydrogen release process

At the bottomComparative testing experiment of different thermal management schemes for solid-state hydrogen storage tanks

At the bottomSolid state hydrogen storage tank storage/Composition and Control of Hydrogen Release Control System

At the bottomPrinciple and composition of thermal management coupling between solid-state hydrogen storage tanks and fuel cells

At the bottomComposition and Control of Coupled Thermal Management Control System

At the bottomComposition and operational efficiency testing experiment of refrigeration system

At the bottomExperimental Study on Energy Storage System Operation under Simulated Climate Temperature

At the bottomRefrigeration control experiment under simulated climate temperature

At the bottomMeasurement and Control of Hydrogen Energy Storage System Parameters

At the bottomSimulate fluctuations and control of renewable energy generation

At the bottomHuman computer interface design and communication control

6. Hydrogen storage new energy generation - comprehensive energy management experimental platform

(1) Platform equipment

Simulated power generation system, climate temperature simulation device, electrolytic water hydrogen production, fuel cell power generation, solid-state hydrogen storage tank (with heat enhancement), plate heat exchanger, thermoelectric refrigeration/Heating, air supply devices, integrated energy management systems, loads, sensors, etc

(2) Capable of completing research projects

At the bottomPrinciple and composition of renewable energy generation and hydrogen storage system

At the bottomComposition and Control of Fuel Cell Control System

At the bottomThe electric stackIV polarization characteristic curve

At the bottomPower characteristic curve of fuel cell stack

At the bottomExperiment on measuring the efficiency of electrolytic hydrogen production

At the bottomExperimental study on flow measurement and control of electrolytic hydrogen production

At the bottomCell stack output and exhaust gas analysis experiment

At the bottomSolid state hydrogen storage tank storage/Evolution curves of temperature, pressure, and concentration during hydrogen release process

At the bottomComparative Test Experiment on Thermal Enhancement Design of Solid State Hydrogen Storage Tanks

At the bottomComparative testing experiment of natural convection and forced convection heat transfer in solid-state hydrogen storage tanks

At the bottomSolid state hydrogen storage tank storage/Composition and Control of Hydrogen Release Control System

At the bottomPrinciple and composition of thermal management coupling between solid-state hydrogen storage tanks and fuel cells

At the bottomComposition and Control of Coupled Thermal Management Control System

At the bottomrefrigeration/Composition and operational efficiency testing experiment of heating system

At the bottomExperimental Study on Energy Storage System Operation under Simulated Climate Temperature

At the bottomRefrigeration under simulated climate temperature/Heating Control Experiment

At the bottomDesign principle and composition of comprehensive energy management for hydrogen storage system

At the bottomComprehensive Energy Management Testing and Analysis Experiment of Hydrogen Energy Storage System

At the bottomMeasurement and Control of Hydrogen Energy Storage System Parameters

At the bottomSimulate fluctuations and control of renewable energy generation

At the bottomHuman computer interface design and communication control

2、 Optional modules for the series experimental platform

At the bottomSimulated power generation system (battery)

At the bottomLighting simulation-PV power generation module

At the bottomClimate temperature simulation module

At the bottomPCM thermal management module

At the bottomTank thermal strengthening testing module

At the bottomHydrogen storage technology comparison module

At the bottomhydrogen storage tank-Fuel cell coupled thermal management module

At the bottomControl strategy regulation module

At the bottomrefrigeration/Heating load module

At the bottomIntegrated Energy Management Module