Hydrogen has the highest energy content by mass of any fuel and can be used as a substitute for hydrocarbons. It has a non-polluting burning process. There are several methods for producing hydrogen, including electrolysis of water, thermo-chemical processes, and from fossil fuels. Electrolysis uses electricity to split water into hydrogen and oxygen gases. Filter press electrolyzers are most widely used due to their ability to operate at high current densities and production rates. There are challenges to storing hydrogen including its low density and challenges maintaining it as a liquid. Storage methods include high pressure gas, liquid storage using cryogenics, underground storage, and chemically storing it in metal hydrides.
Today it's easy to start using your existing wind / solar power to become a producer of clean green hydrogen - so you can produce, distribute and sell the hydrogen at the highest bidder - and thus creating a second revenue stream from your renewable power generation - extremely interesting when the guaranteed feed-in tarif comes to an end!
Small Hydro power plant. Small Hydro Power (SHP) is hydro plant with power under 10 MW as defined by United Nations Industrial Development Organization (UNIDO):
Choice of technology and site
Small hydro technology is mature and well-established in the market
Improvements: equipment designs, differents materials, control sistem
Typologies of Hydropower plants
a) Run of River Plants
b) Pondage Plants
c) Reservoir Plants
Typologies of Hydropower plants
a) Run of River Plants
A Run of River plant uses the available river flow
A Run of River plant has a little cumulative water
High cost
Typologies of Hydropower plants
b) Pondage Plants
Cumulative water flows permits storage of water for few weeks
Pondage Plant can works when the level of river is low.
Typology of hydropower plants
c) Reservoir Plants
Energy prodution of a Reservoir Plant is based on cumulative water flows
Construction of a very large dam to cumulate water
Usually this kind of plant is not a SHP
Plan SHP
Control national and regional law
Who using the water and how
Story analisis of river flow
Study hidrogeologic and hidrografic of site
Chek principal parameters (Q) river flow avieble and (H) head for calculate power of site
Pubblicity of project and consalting citizen.
Hydroelectric plants
Start easily and quickly and change power output rapidly
Complement large thermal plants (coal and nuclear), which are most efficient in serving base power loads.
Save millions of barrels of oil
SHP emissions
As all other renewable energy sources, SHP plays an important role in reducing the emissions.
Externality of SHP are very low.
This is very important and positive, expecially for Kyoto protocol.
What to do for goal with SHP
Act cordinated strategy:
Informing
Including the people in the projects
Dialogue with opponents
Implementing social compain
This document is about the Importance of Energy Storage, how to the energy can be stored and the advantages and disadvantages of the different types of Energy storage elements
Today it's easy to start using your existing wind / solar power to become a producer of clean green hydrogen - so you can produce, distribute and sell the hydrogen at the highest bidder - and thus creating a second revenue stream from your renewable power generation - extremely interesting when the guaranteed feed-in tarif comes to an end!
Small Hydro power plant. Small Hydro Power (SHP) is hydro plant with power under 10 MW as defined by United Nations Industrial Development Organization (UNIDO):
Choice of technology and site
Small hydro technology is mature and well-established in the market
Improvements: equipment designs, differents materials, control sistem
Typologies of Hydropower plants
a) Run of River Plants
b) Pondage Plants
c) Reservoir Plants
Typologies of Hydropower plants
a) Run of River Plants
A Run of River plant uses the available river flow
A Run of River plant has a little cumulative water
High cost
Typologies of Hydropower plants
b) Pondage Plants
Cumulative water flows permits storage of water for few weeks
Pondage Plant can works when the level of river is low.
Typology of hydropower plants
c) Reservoir Plants
Energy prodution of a Reservoir Plant is based on cumulative water flows
Construction of a very large dam to cumulate water
Usually this kind of plant is not a SHP
Plan SHP
Control national and regional law
Who using the water and how
Story analisis of river flow
Study hidrogeologic and hidrografic of site
Chek principal parameters (Q) river flow avieble and (H) head for calculate power of site
Pubblicity of project and consalting citizen.
Hydroelectric plants
Start easily and quickly and change power output rapidly
Complement large thermal plants (coal and nuclear), which are most efficient in serving base power loads.
Save millions of barrels of oil
SHP emissions
As all other renewable energy sources, SHP plays an important role in reducing the emissions.
Externality of SHP are very low.
This is very important and positive, expecially for Kyoto protocol.
What to do for goal with SHP
Act cordinated strategy:
Informing
Including the people in the projects
Dialogue with opponents
Implementing social compain
This document is about the Importance of Energy Storage, how to the energy can be stored and the advantages and disadvantages of the different types of Energy storage elements
Techno-Economic Study of Generating/Compressing Hydrogen Electrochemically, A...Keith D. Patch
The impending hydrogen economy will utilize hydrogen from a number of sources; most notably reformers and water electrolyzers. In the later case, the primary energy source can be conventional (fossil fuels, hydroelectric, nuclear) or renewable (solar, wind, biomass).
However, regardless of the source of the primary energy or the method of hydrogen production, there is a common requirement that the hydrogen be sufficiently compressed to achieve adequate energy density storage and to allow the rapid transfer of gas from central to local or mobile storage systems. In the case of water electrolyzers, the hydrogen can be directly produced at elevated pressures. Independent of the source of the hydrogen, pressurization can also be accomplished subsequent to its production by the use of mechanical or electrochemical compressors.
While current electrolyzer developments have targeted hydrogen production at pressures of 340 bar and higher, careful attention must be paid to trade-offs between the electrolyzer system capital costs, operating costs, and system reliability. The technical and economic impact of varying scenarios has a profound effect on the overall economics of the hydrogen production and, ultimately, on the economics of the hydrogen economy.
A.B. LaConti, T. Norman, K.D. Patch. W. Schmitt, & L.J. Gestaut Giner, Inc.
A. Rodrigues, General Motors, Fuel Cell Activities (GM)
Proceedings of the International Hydrogen Energy Forum (Volume 2) 2004, Beijing, China
Cost Reduction of Direct Ethanol Fuel Cell by Changing Composition of Ethanol...ijsrd.com
global demand for electrical power is on the rise, while tolerance for pollution and potentially hazardous forms of power generation is on the decline. Traditional forms of power generation - primarily made up of centralized fossil fuel plants - are becoming less favored due to the lack of clean, distributed power generation technologies. The need is well recognized for clean, safe and reliable forms of energy that can provide prescribed levels of power consistently, and on demand. Most forms of non - combustion electric power generation have limitations that impact wide spread use of technology, especially as a power source of electrical power (i.e. baseload power). Fuel cell technology on other hand has advanced to the point where it is viable challenger to combustion - based plants for growing numbers of baseload power application. If the cost is reduced by changing its material, this will be added an advantage to the large production of direct ethanol fuel cell production.
I Hope You all like it very much. I wish it is beneficial for all of you and you can get enough knowledge from it. Clear and appropriate objectives, in terms of what the audience ought to feel, think, and do as a result of seeing the presentation. Objectives are realistic – and may be intermediate parts of a wider plan.
PEMFC (proton exchange membrane)
DMFC (direct methanol)
SOCF (solid oxide)
AFC (alkaline)
PAFC (phosphoric acid)
MCFC (Molten Carbonate)
PEM Fuel Cell
A fuel cell is a battery that produces DC current and voltage
Most fuel cells use hydrogen which burns cleaner compared to hydrocarbon fuels
A fuel cell will keep producing electricity as long as fuel is supplied
The energy efficiency of fuel cells is high when compared to many other energy systems
There is great interest in fuel cells for automotive and electronic applications
There will be employment for technicians particularly in Ohio’s fuel cell industry.
GDG Cloud Southlake #33: Boule & Rebala: Effective AppSec in SDLC using Deplo...James Anderson
Effective Application Security in Software Delivery lifecycle using Deployment Firewall and DBOM
The modern software delivery process (or the CI/CD process) includes many tools, distributed teams, open-source code, and cloud platforms. Constant focus on speed to release software to market, along with the traditional slow and manual security checks has caused gaps in continuous security as an important piece in the software supply chain. Today organizations feel more susceptible to external and internal cyber threats due to the vast attack surface in their applications supply chain and the lack of end-to-end governance and risk management.
The software team must secure its software delivery process to avoid vulnerability and security breaches. This needs to be achieved with existing tool chains and without extensive rework of the delivery processes. This talk will present strategies and techniques for providing visibility into the true risk of the existing vulnerabilities, preventing the introduction of security issues in the software, resolving vulnerabilities in production environments quickly, and capturing the deployment bill of materials (DBOM).
Speakers:
Bob Boule
Robert Boule is a technology enthusiast with PASSION for technology and making things work along with a knack for helping others understand how things work. He comes with around 20 years of solution engineering experience in application security, software continuous delivery, and SaaS platforms. He is known for his dynamic presentations in CI/CD and application security integrated in software delivery lifecycle.
Gopinath Rebala
Gopinath Rebala is the CTO of OpsMx, where he has overall responsibility for the machine learning and data processing architectures for Secure Software Delivery. Gopi also has a strong connection with our customers, leading design and architecture for strategic implementations. Gopi is a frequent speaker and well-known leader in continuous delivery and integrating security into software delivery.
Transcript: Selling digital books in 2024: Insights from industry leaders - T...BookNet Canada
The publishing industry has been selling digital audiobooks and ebooks for over a decade and has found its groove. What’s changed? What has stayed the same? Where do we go from here? Join a group of leading sales peers from across the industry for a conversation about the lessons learned since the popularization of digital books, best practices, digital book supply chain management, and more.
Link to video recording: https://bnctechforum.ca/sessions/selling-digital-books-in-2024-insights-from-industry-leaders/
Presented by BookNet Canada on May 28, 2024, with support from the Department of Canadian Heritage.
Elevating Tactical DDD Patterns Through Object CalisthenicsDorra BARTAGUIZ
After immersing yourself in the blue book and its red counterpart, attending DDD-focused conferences, and applying tactical patterns, you're left with a crucial question: How do I ensure my design is effective? Tactical patterns within Domain-Driven Design (DDD) serve as guiding principles for creating clear and manageable domain models. However, achieving success with these patterns requires additional guidance. Interestingly, we've observed that a set of constraints initially designed for training purposes remarkably aligns with effective pattern implementation, offering a more ‘mechanical’ approach. Let's explore together how Object Calisthenics can elevate the design of your tactical DDD patterns, offering concrete help for those venturing into DDD for the first time!
Smart TV Buyer Insights Survey 2024 by 91mobiles.pdf91mobiles
91mobiles recently conducted a Smart TV Buyer Insights Survey in which we asked over 3,000 respondents about the TV they own, aspects they look at on a new TV, and their TV buying preferences.
Kubernetes & AI - Beauty and the Beast !?! @KCD Istanbul 2024Tobias Schneck
As AI technology is pushing into IT I was wondering myself, as an “infrastructure container kubernetes guy”, how get this fancy AI technology get managed from an infrastructure operational view? Is it possible to apply our lovely cloud native principals as well? What benefit’s both technologies could bring to each other?
Let me take this questions and provide you a short journey through existing deployment models and use cases for AI software. On practical examples, we discuss what cloud/on-premise strategy we may need for applying it to our own infrastructure to get it to work from an enterprise perspective. I want to give an overview about infrastructure requirements and technologies, what could be beneficial or limiting your AI use cases in an enterprise environment. An interactive Demo will give you some insides, what approaches I got already working for real.
Neuro-symbolic is not enough, we need neuro-*semantic*Frank van Harmelen
Neuro-symbolic (NeSy) AI is on the rise. However, simply machine learning on just any symbolic structure is not sufficient to really harvest the gains of NeSy. These will only be gained when the symbolic structures have an actual semantics. I give an operational definition of semantics as “predictable inference”.
All of this illustrated with link prediction over knowledge graphs, but the argument is general.
Key Trends Shaping the Future of Infrastructure.pdfCheryl Hung
Keynote at DIGIT West Expo, Glasgow on 29 May 2024.
Cheryl Hung, ochery.com
Sr Director, Infrastructure Ecosystem, Arm.
The key trends across hardware, cloud and open-source; exploring how these areas are likely to mature and develop over the short and long-term, and then considering how organisations can position themselves to adapt and thrive.
Builder.ai Founder Sachin Dev Duggal's Strategic Approach to Create an Innova...Ramesh Iyer
In today's fast-changing business world, Companies that adapt and embrace new ideas often need help to keep up with the competition. However, fostering a culture of innovation takes much work. It takes vision, leadership and willingness to take risks in the right proportion. Sachin Dev Duggal, co-founder of Builder.ai, has perfected the art of this balance, creating a company culture where creativity and growth are nurtured at each stage.
UiPath Test Automation using UiPath Test Suite series, part 3DianaGray10
Welcome to UiPath Test Automation using UiPath Test Suite series part 3. In this session, we will cover desktop automation along with UI automation.
Topics covered:
UI automation Introduction,
UI automation Sample
Desktop automation flow
Pradeep Chinnala, Senior Consultant Automation Developer @WonderBotz and UiPath MVP
Deepak Rai, Automation Practice Lead, Boundaryless Group and UiPath MVP
Connector Corner: Automate dynamic content and events by pushing a buttonDianaGray10
Here is something new! In our next Connector Corner webinar, we will demonstrate how you can use a single workflow to:
Create a campaign using Mailchimp with merge tags/fields
Send an interactive Slack channel message (using buttons)
Have the message received by managers and peers along with a test email for review
But there’s more:
In a second workflow supporting the same use case, you’ll see:
Your campaign sent to target colleagues for approval
If the “Approve” button is clicked, a Jira/Zendesk ticket is created for the marketing design team
But—if the “Reject” button is pushed, colleagues will be alerted via Slack message
Join us to learn more about this new, human-in-the-loop capability, brought to you by Integration Service connectors.
And...
Speakers:
Akshay Agnihotri, Product Manager
Charlie Greenberg, Host
Essentials of Automations: Optimizing FME Workflows with ParametersSafe Software
Are you looking to streamline your workflows and boost your projects’ efficiency? Do you find yourself searching for ways to add flexibility and control over your FME workflows? If so, you’re in the right place.
Join us for an insightful dive into the world of FME parameters, a critical element in optimizing workflow efficiency. This webinar marks the beginning of our three-part “Essentials of Automation” series. This first webinar is designed to equip you with the knowledge and skills to utilize parameters effectively: enhancing the flexibility, maintainability, and user control of your FME projects.
Here’s what you’ll gain:
- Essentials of FME Parameters: Understand the pivotal role of parameters, including Reader/Writer, Transformer, User, and FME Flow categories. Discover how they are the key to unlocking automation and optimization within your workflows.
- Practical Applications in FME Form: Delve into key user parameter types including choice, connections, and file URLs. Allow users to control how a workflow runs, making your workflows more reusable. Learn to import values and deliver the best user experience for your workflows while enhancing accuracy.
- Optimization Strategies in FME Flow: Explore the creation and strategic deployment of parameters in FME Flow, including the use of deployment and geometry parameters, to maximize workflow efficiency.
- Pro Tips for Success: Gain insights on parameterizing connections and leveraging new features like Conditional Visibility for clarity and simplicity.
We’ll wrap up with a glimpse into future webinars, followed by a Q&A session to address your specific questions surrounding this topic.
Don’t miss this opportunity to elevate your FME expertise and drive your projects to new heights of efficiency.
Epistemic Interaction - tuning interfaces to provide information for AI supportAlan Dix
Paper presented at SYNERGY workshop at AVI 2024, Genoa, Italy. 3rd June 2024
https://alandix.com/academic/papers/synergy2024-epistemic/
As machine learning integrates deeper into human-computer interactions, the concept of epistemic interaction emerges, aiming to refine these interactions to enhance system adaptability. This approach encourages minor, intentional adjustments in user behaviour to enrich the data available for system learning. This paper introduces epistemic interaction within the context of human-system communication, illustrating how deliberate interaction design can improve system understanding and adaptation. Through concrete examples, we demonstrate the potential of epistemic interaction to significantly advance human-computer interaction by leveraging intuitive human communication strategies to inform system design and functionality, offering a novel pathway for enriching user-system engagements.
The Art of the Pitch: WordPress Relationships and SalesLaura Byrne
Clients don’t know what they don’t know. What web solutions are right for them? How does WordPress come into the picture? How do you make sure you understand scope and timeline? What do you do if sometime changes?
All these questions and more will be explored as we talk about matching clients’ needs with what your agency offers without pulling teeth or pulling your hair out. Practical tips, and strategies for successful relationship building that leads to closing the deal.
The Art of the Pitch: WordPress Relationships and Sales
Hydrogen energy
1.
2. Hydrogen has highest energy content per unit of mass of any chemical
fuel and can be substituted hydrocarbon in a broad range of application.
Its burning process is non polluting.
Heating value of 28000 kcal/kg is three times greater than hydrocarbon.
Easy in production because it is produced from water found in
abundance.
Hydrogen is highly flammable.
Hydrogen at ordinary pressure and temperature is a light gas with a
density only (1/14) that of air and (1/9) that of natural gas under the same
Condition.
By cooling to extremely low temperature of -253 ˚C, the gas is condensed
to a liquid with a specific gravity of 0.07, roughly (1/10) that of gasoline.
The flame speed of hydrogen burning in air is much greater than for
natural gas, and the energy required to initiate combustion is less.
Mixture of hydrogen and air are combustible over an exceptionally
wide range of compositions; thus the flammability limits at ordinary
temperature extends from 4 to 74 % by volume of hydrogen in air.
3. On the basis of source use and energy source hydrogen production are
following type-
Electrolysis or electrolytic production-In electrolysis water spit in to H2
andO2 when electric current pass through in this process two type of
electrolyzer used
Tank type electrolyzer.
Bipolar or filter press electrolyzer.
Thermo – Chemical Methods.
Some thermo chemical cyclic process.
Westinghouse ElectrochemicalThermal Sulfur Cycles.
Ispra Mark 13 Cycles.
Iodine Sulphur Cycle.
Fossil Fuel Methods
Solar energy methods.
Bio photolysis method.
Photo Electrolysis method.
4.
5. The process of splitting water into Hydrogen & Oxygen by means of a
direct electric current is known as electrolysis. This is the simplest
method of hydrogen production.
Although only the water is split, an electrolyte (KOH solution) is required
because water itself is a very poor conductor of electricity.
Theoretically 1.23 volts are required for this process but in real situation
due to the slowness of the electrode processes higher voltages are
required for the electrolysis.
Theoretically 2.8 KW-hr of electrical energy should produce from one
Cu.m of hydrogen however the actual electrical energy requirement is
generally from 3.9 to 4.6 KW-hr per Cu.m. this means that efficiency of
electrolysis is roughly 60 to 70%.
To increase the efficiency the electrode surface must be able to
catalyze the electrode processes. Platinum & nickel are normally
deposited on the electrode.
6. Diaphragms prevent electronic contact between adjacent electrodes
and passage of dissolved gas or gas bubble; from one electrode
compartment to another , without appreciable resistance to the passage
of current within the electrolyte.
Asbestos is the most suitable material for cell diaphragms.
Three major factors determine the usefulness of an electrochemical
cell for hydrogen production.
1. Energy Efficiency.
2. Capital cost of the plant.
3. Lifetime of the cell and its maintenance requirements.
A number of advantages can be gained from operating electrolyzer at
higher pressures a follows:
1. Reduction in specific power consumption.
2. Delivery of gas at pressure, thus eliminating the cost of gas compressor.
3. Reduction in the size of electrolysis cell.
7. Two types of electrode arrangements are used by industry for the electrolysis of
water. On this basis they are classified as follows:
1. Tank type electrolyzer, and
2. Filter press or bipolar electrolyzer.
Tank type electrolyzer:
The first application in the industry used the tank electrolyzer, in which a series of
electrodes, alternating anodes (+) and cathodes (-) are suspended vertically and
parallel to one another in a tank filled with a 20-30 % solution of KOH in
demineralized water.
8. Alternate electrodes are surrounded by porous diaphragms impermeable to gas
but permeable to the cells electrolyte, that prevent the passage of gas free from
one electrode compartment to another.
All the anodes are connected to the same positive terminal of the direct current
voltage source and all the cathodes are connected to the same negative
terminal.
The major advantage of tank type electrolyzers are two fold relatively few
parts are required and those needed are relatively inexpensive
Another advantage of this arrangement is that individual cells may be isolated
for repair or replacement simply by short circuiting the two adjacent cells
with a temporary busbar connections.
Disadvantage is that inability to handle high current densities because of
cheaper components parts.
Inability to operate at high temperatures because of heat losses from large
surfaces areas of connected cells.
9. Filter Press Electrolyzer (Bipolar Electrolyzer):
This is the most widely used electrolysis system because of its superficial
resemblance to a filter press.
Except at the ends of the cell, the electrodes are bipolar that is, one face of each
plate electrode is in anode and the other face is the cathode.
Because of the cells can be made relatively thin, a large gas output is achieved
from a relatively small volumes.
10. The filter press electrolyzer is generally preferred because it occupies less space
and can be operated at a higher current densities than the tank type.
The economics are thus more favorable, since a large production is possible in
the plant.
The filter press electrolyzers require a much closer tolerance in construction
and are more difficult to maintain.
Breakdowns in this system are rare, but when they occur it is difficult and repair
may take considerable time.
If an individual asbestos diaphragm is damaged, the entire battery must be
dismantled.
High cell voltage imply high energy costs, and low current densities imply
that the electrolyzers give small yields per unit time, leading to relatively
high capital costs. For these reasons hydrogen produced electrolytically is at
present twice as expensive as hydrogen produced from fossil fuels.
11. It is generally desirable to circulate electrolyte through the cell, thereby
separating the gas and the electrolyte and in many designs, this is accomplished
in a separating drum mounted on the top of the electrolyzer.
The filter press electrolyzer is generally preferred because it occupies less space
and can be operated at a higher current densities than the tank type.
The economics are thus more favorable, since a large production is possible in
the plant.
The filter press electrolyzers require a much closer tolerance in construction
and are more difficult to maintain.
Breakdowns in this system are rare, but when they occur it is difficult and repair
may take considerable time.
If an individual asbestos diaphragm is damaged, the entire battery must be
dismantled.
High cell voltage imply high energy costs, and low current densities imply
that the electrolyzers give small yields per unit time, leading to relatively
high capital costs. For these reasons hydrogen produced electrolytically is at
present twice as expensive as hydrogen produced from fossil fuels.
12. The overall efficiency for the conversion of primary energy from fossil & Nuclear
fuels into hydrogen by electrolysis is dependent, in the first place on the
efficiency of the generating electricity.
This efficiency is 38% for modern fossil plants and 32% for nuclear installation.
The higher conversion efficiency might be possible if the heat produced by
the primary fuel could be used directly to decompose water, without the
intermediary of electric energy. Such direct decomposition into hydrogen and
oxygen is possible, but it requires a temperature of atleast 2500˚C.
But due to temperature limitation and conversion process equipment, direct
single step water decomposition is not possible.
However a sequential chemical reaction series can be devised in which
hydrogen and oxygen are produced, water is consumed and all other
intermediates are recycled.The operation is called as thermo chemical cycle.
It is so called because energy is supplied as heat at one or more of the
chemical stage, and hydrogen and oxygen are produced separately in
different stages.
For practical reasons , primarily the availability structural and containment
materials, the maximum temperature considered to be about 950˚C.
13. Heat energy then be converted into hydrogen energy with efficiency of 50%, this
is a marked improvement over what is possible by electrolysis.
At present no commercial process for the thermal splitting of water to hydrogen
and oxygen is in operation.
Several workers have proposed many multistep reaction sequence that thermally
decompose water at lower temperatures.
2CrCL2 + 2HCL 2CrCl3 + H2
2CrCL3 2CrCL2 + Cl2
H2O + Cl2 2HCL + ½ (O2)
As can be seen, in this reaction sequences, only water is split, all other
materials are completely recycled.
14. Numerous candidate cycles have been suggested during past few years. Here ,
we shall consider only three cyclic processes which are as follows:
1. Westinghouse ElectrochemicalThermal Sulfur Cycle.
2. Ispra Mark 13 Bromine sulfur cycle.
3. Iodine Sulfur Cycle.
Westinghouse ElectrochemicalThermal SulfurCycle.
H2So4 H2O + ½ (O2) + SO2
2H2O +SO2 H2+ H2SO4
It is clear by summing reaction that overall process decomposes water into
hydrogen and oxygen and involves only sulphur oxides as recycling
intermediates.
Although electrical power is required in the electrolyzer, much smaller quantities
than those necessary for conventional electrolysis.
15. Ispra Mark 13 Cycle:
2HBr H2+ Br2 (Electrolysis)
Br2 + SO2 + 2H2O 2HBr + H2So4
H2SO4 H2O + SO2 + ½ (O2) (Thermolysis)
The somewhat lower cell voltage in the Westinghouse process is
counterbalanced by the advantage of the higher concentration of sulphuric acid
obtained in the Mark 13 process.
It should be also mentioned that incorporation of an additional element Bromine
in the Mark 13 process may also be advantageous, since it offers more
possibilities in the industrial operation of the process.
Iodine Sulphur Cycle:
Among the purely thermo chemical cyclic processes , those belonging to the
iodine sulphur family are of most interest at thee present stage.
The following three stage process has been developed by General Atomic Co. in
particular:
16. 2HI H2 + I2
I2+ SO2 + 2H2O H2SO4+ 2HI
H2SO4 H2O+ SO2+ ½ (O2)
The main difficulty in this process lies in the fact that, if side reactions are to be
avoided , the two acids can be obtained only in dilute solution in the second
stage, and are difficult to separate even on the laboratory stage.
The difficulties associated with this process have led in recent years to numerous
investigations and suggestions for modifying the process.
17. Mostly a gaseous mixture of CO and Hydrogen is formed in the first stage, in the
production of hydrogen by using a fossil fuel.
This is popular method of hydrogen production through which about 94%
hydrogen is produced by following different processes-
1. Steam reforming of gas
2. Partial oxidation of heavier hydro carbon.
3. Coal gasification
4. Pyrolysis
5. Biomass gasification
CO + H2O = CO2 + H2 + 1440 KJ/KG
To remove the CO, the mixture is submitted to the water gas shift reaction with
steam. The CO is therefore converted into CO2 with the formation of additional
hydrogen and energy.
21. Hydrogen production from solar energy there is two methods are considered –
1. Bio photolysis and
2. Photo Electrolysis.
Bio photolysis:
This method utilizes living systems (or material derived from such systems) to
split water into its constituents hydrogen and oxygen.
In normal photosynthesis in green plants the green plants the green pigment
chlorophyll takes of the energy from sunlight and in a complex series of
reactions breaks up water molecules into oxygen gas, hydrogen ions and
electrons.
The oxygen is evolved from the green plant, but the hydrogen ions and electrons
are removed by interaction with carbon dioxide (from the air) to produce simple
sugars.
Certain single cell green/ blue green algea are able to make enzyme
hydrogenase. They decompose water in sunlight to yield hydrogen and oxygen.
22. Instead of using living algae to obtain hydrogen from water, a more convenient
approach is to utilize biological materials obtained from plants or bacteria. One
advantage is the ability to vary the conditions to optimize hydrogen production.
An ultimate objective of research on the decomposition of water by sunlight is the
efficient simulation of biological processes without using biological materials.
Photo Electrolysis:
In photosynthesis , a current is generated by exposing on or both electrodes to the
sunlight. Hydrogen and Oxygen gases are liberated at the respective electrodes by
the decomposition of the water , just as an ordinary electrolysis.
Atleast one of the electrodes in the photosynthesis is usually a semiconductor;
a catalyst may be included to facilitate the electrode processes.
Research is being directed at increasing this efficiency by selection of electrode
materials, electrolyte solutions and electrode catalysts.
Electrolysis is a more attractive way of producing hydrogen with solar
radiation since it can be operated intermittently and therefore needs no
storage.
23. The solar electricity needed for electrolysis can be produced either
photoelectrically or thermoelectrically. Both technologies are available today.
HYBRIDE ELECTROLYSIS
24.
25.
26.
27. The need for storage is due to the almost inevitable mismatch between the
optimum production rate of the energy and the fluctuation in demand for
energy by the users.
In the electric energy system storage, presents considerable difficulty because
electricity itself is not readily storable.
One of the advantages often claimed for a hydrogen energy systems is that
hydrogen is storable. However, it must be realized that storage of hydrogen is
not an easy problem compared with storage of liquids fuels such as gasoline or
oil. It is only when it is compared with electricity that storage of energy as
hydrogen seems relatively easy.
There are five principal method of hydrogen production.
Compressed gas storage
Liquid storage or cryogenic storage
Line pack system
Under ground storage
Storage as a metal hydride
28. Storage can be effected in a gaseous or liquid state, or in the structure of solids.
According to the field application, it is necessary to distinguish between storage
on a large scale and on a small scale. The former applies particularly to stationary
application and the letter also to mobile ones.
Compressed Gas Storage:
Hydrogen is stored in high pressure cylinders.
This method of storage is rather expensive and very bulky because very large
quantities of steel are needed to contain quite small amounts of hydrogen.
Liquid Storage:
A more practical approach is to store the hydrogen as liquid at a low
temperature.
Liquid hydrogen boils at -253˚C and therefore must be maintained at or below
this temperature in storage.
It is commonly regarded as necessary to use vacuum- insulated storage vessels
and super insulated vessels.
A problem concerning storage of liquid hydrogen is the considerable amount of
energy required to convert hydrogen gas into the liquid phase.
29. To maintain the temperature at such a low limit some kind of primary
refrigeration, such as a liquid nitrogen plant, to precool hydrogen. The net result
is that about 25-30% of the heating value of hydrogen is required to liquefy
hydrogen.
Line Packing:
The use of line pack storage in the natural gas industry provides a relatively small
capacity storage system, but one with a very fast response time that can take
care of minute by minute or hour by hour variations in demand.
A hydrogen transmission and distribution system running on hydrogen would
have a similar capability.
Underground Storage:
The cheapest way to store large amounts of hydrogen for subsequent
distribution would probably be in underground facilities similar to those used for
natural gas; these facilities would include depleted oil and gas reservoirs.
More expensive alternatives would be caverns produced by conventional mining
or by dissolving out salt with water.
30. Since hydrogen gas tends to escape readily through a porous material, some
geologic formations that may be suitable for storing natural gas may not be
suitable for hydrogen.
Metal Hydrides (Storage in chemically bound form) :
Considerably interest has been shown recently in the possibility of storage of
hydrogen in the form of a metal hydride.
A number of metals and alloys form solid compounds , called metal hydrides, by
direct reaction with hydrogen gas.
When the hydride is heated, the hydrogen is released and the original metal(or
alloy) is recovered for further use.
Thus , metal hydrides provide a possible means for hydrogen storage.
An important property of metal hydrides is that the pressure of the gas released
by heating a particular hydride depends mainly on the temperature and not
the composition.
Several studies are being made to find a metal hydride that would satisfy the
requirements for hydrogen storage.These requirements include the following:
31. 1) The metal (or alloy) should be fairly inexpensive.
2) The hydride should contain a large amount of hydrogen per unit volume and per
unit mass.
3) The hydride should be formed without difficulty by reaction of the metal with
hydrogen gas, and it should be stable at room temperature.
4) The gas should be released at a significant pressure from the hydride at a
moderately high temperature (preferably below 100˚C)
Three of the more promising hydrides are those of Lanthanum nickel ( LaNi5),
Iron titanium (FeTi), and magnesium nickel (Mg2Ni) alloys.
In practice, energy densities of from 500 Wh/Kg (already achieved) to a
maximum of 1000 Wh/Kg can be attained.
32.
33. Pipe Lines:
Presently only few companies are capable to transport hydrogen by pipelines at
different locations.
It is of interest to compare the design of a pipeline for hydrogen with those of a
pipeline for natural gas.
The heating value of hydrogen is only 12.1 MJ/Cu.m as compared to natural gas
having the value of 38.3 MJ/Cu.m.
This implies that to deliver the same quantity of energy, three times the
quantity of hydrogen must be transmitted.
On the other side one finds that the capacity of the pipeline depends upon the
square root of the density of the gas.
As the density of the hydrogen is (1/9) times that of natural gas , so that it
indicates that the energy content of hydrogen is same as that of natural gas
for the same size pipe.
As we know that if we want to supply hydrogen to long distance then we have to
do same with the help of compressor station.
As the hydrogen compressor s have to handle three to four times the volume of
gas large compressor are required and they consume more power also.
34. The design of rotary compressors commonly used for natural gas lines appears
to be more inadequate for hydrogen operation.
In the case of design of a pipeline of hydrogen transmission the cost of fuel used
to drive the engines for compressors is also the highly deciding factor, because
the compression energy is so much higher than that of natural gas.
One of the principal concerns about hydrogen transmission is the fear of
hydrogen embrittlement of the pipeline material.
A number of metals lose their mechanical strength on exposure to hydrogen; the
phenomenon called hydrogen embrittlement, is specially significant for steel in
hydrogen under pressure.
Operating experience with common pipeline steels at pressure upto 3.5 Mpa has
shown no problems of consequence.
However the behavior at higher pressure is uncertain, and more experimental
work needs to be carried out to gen some definite data.
35. Liquid HydrogenTransportation:
Hydrogen in bulk can be transported and distributed as the liquid.
Doubled wall , insulated tanks of liquid hydrogen with capacities of 7000 gal or
more are carried by road vehicles and upto 34000 gal by rail road cars.
Distribution of liquid hydrogen by pipeline , jacketed with liquid nitrogen , has
been proposed.
The cost would be substantially greater than for gas pipeline, but it might be
justifiable for certain fuel applications where the liquid is required.
Metal HydrideTransportation:
Hydrogen is transported in the form of solid metal hydrides.
The main draw back is the weight of the hydride relative to its hydrogen content.
36.
37. Hydrogen Gas can be utilised in the following ways:
For residential uses
For industrial uses
For as an alternative transport fuel
For as an alternative fuel for aircraft.
For electric power generation (Utilities)
For ResidentialUses:
Electricity for lighting and for operating domestic appliances could be
generated by fuel cell in which Hydrogen is used as a fuel.
Hydrogen can be used in domestic cooking with the help of changing in the
design of burner, including the hole size and air supply system.
Hydrogen can be useful in radiant space heaters, because of the possibility of
flameless combustion on a catalytic surface. These devices would be operate
spontaneously when the gas was turned on and no pilot light or other ignition
system would be required. Because of the low combustion temperature ,
nitrogen oxide formation would be negligible and venting would be
unnecessary.
38. Industrial Uses:
Many potential uses for hydrogen in industry, either as a fuel or a chemical
reducing (oxygen removal) agent if the economics were favorable.
Hydrogen gas could also be used with advantage, instead of coal or coal derived
gases, to reduce oxide ores (iron ore) to the metal (iron)
RoadVehicles:
The use of hydrogen as a fuel in I.C. Engines has attracted interest as a means of
conserving petroleum products and of reducing atmospheric pollution.
Because of fuel as a gas, the conventional carburetor of a S.I Engine must be
modified for use with hydrogen.
The hydrogen gas under pressure is injected through a valve directly into the
engine cylinder, and the air is admitted through the another intake valve. Since
they both supplied separately, an explosive mixture does not occur except in the
cylinder.
The engine power output is controlled by varying the pressure of hydrogen gas .
The hydrogen is required to be stored as a compressed gas.
Another modification arises from the high speed of the hydrogen flame in the
air; this require that ignition time be retarded compared to gasoline engine.
39. They can utilize a higher proportion of the energy in the fuel than gasoline
engine.
The amount of CO and hydrocarbons in the exhaust would be very small since
they would originate only from the cylinder lubricating oil.
However the nitrogen oxides level due to high combustion temperature may be
high, it may be reduced by reducing the combustion temperature by injecting
water vapour into cylinder from the exhaust .
The other way to utilised hydrogen as a fuel is thee use of fuel cells. Electricity
generated by the fuel cells could be utilized to operate electric motors to propel
the vehicles.
For vehicles the storage of hydrogen can be as compressed gas, liquid and metal
hydrides.
Air Craft Application:
The earliest application of liquid hydrogen fuel is expected to be in a jet air craft;
this possibility was demonstrated in a subsonic air craft in 1957.
The main advantage is the much lower overall weight of the fuel and the
storage tank than for ordinary jet fuel.
40. The volume of liquid hydrogen would be greater than regular jet fuel, but this
could be accommodate on the large aircraft.
The cool liquid hydrogen could be used directly of indirectly to cool the engine
and the air frame surfaces of a high speed aircraft.
If the hypersonic aircraft is developed , the liquid hydrogen may be the only
practical fuel.
Because of the smaller total weight it is possible to achieve shorter take off runs,
steeper climbing paths and/or smaller engine thrust.
It may also be possible to decrease the size and weight of the engines.
Hydrogen’s favorable diffusion properties and high thermal conductivity lead to
better mixing even with shorter combustion chamber.
The wide range of ignition for hydrogen air mixtures (5 to 75 % by volume) makes
the engine more readily controllable, especially under partial loads, and reduces
the emission of noxious substances.
The heat required to vaporize and heat up the hydrogen for the engines can be
obtained through the certain sections of the outer skin of the wings. In this way
the boundary layer is cooled so as to produce laminar flow, resulting in a lowering
of the aerodynamic drag and hence of the fuel consumption, this could not be
achieved to the same extent in any other way.
41. Electric Power Generation:
It is unlikely that hydrogen would serve as a major fuel for electrical power
generation by a utility. However, its substitution for natural gas in peak hours is
possible.
Hydrogen could also be used as a means for storing and distributing electrical
energy.
This also comprises the production of electricity by using hydrogen in fuel cell
systems.
It is also important that the conversion efficiency of the fuel cells is independent
of the load factor over a wide range, so that a high efficiency can be obtained
even with partial loads.
Furthermore , with fuel cells which are at high temperatures high grade waste
heat can be used for thermal energy production.
Presently the research and development work is in progress with the object of
developing fuel cell power stations for the centralized and local generation of
electricity.
42.
43. Not Explosive In Open Air
Not Decomposing
Not Self-Igniting
Not Oxidizing
NotToxic
Not Corrosive
Not Polluting
Not Cancer Causing
44. Currently more expensive
Hydrogen is more difficult to store and distribute.
45. The BHU Murugappa - Chettair research center Chenni and IIT Kharagpur are
leading institute.
BHU develop metal hydride with storage capacities 2.4 weight%
MNRE stared projects in 22 universities / institute
In IISc Bangalore research work on progress on hydrogen based fuel cell
Some other project in progress in private sector BHEL installed 200 kw fuel cell
based power plant