presentation on batteries

Browse Course Material

Course info.

• Prof. Martin Bazant

Departments

• Chemical Engineering

As Taught In

• Electronic Materials
• Analytical Chemistry
• Physical Chemistry

Learning Resource Types

Electrochemical energy systems, 10.626 lecture notes, li-ion batteries.

This resource contains information related to lecture 10.

You are leaving MIT OpenCourseWare

Battery PPT: Definition, Types and Applications

Battery PPT: Definition, Types and Applications Free Download: Batteries are a collection of one or greater cells whose chemical reactions create a glide of electrons in a circuit.

All batteries are made of 3 basic components: an anode (the ‘-‘ side), a cathode (the ‘+’ side), and some form of electrolyte (a substance that chemically reacts with the anode and cathode). When the anode and cathode of a battery is attached to a circuit, a chemical response takes place among the anode and the electrolyte. This reaction causes electrons to glide via the circuit and returned into the cathode in which any other chemical response takes place.

Table of Content

• Types of Batteries
• Primary Batteries
•   A. Lithium cell, B. Leclanche cell
• Secondary Batteries
•   A. Lead-acid Batteries, B. Nicad Batteries, C. Lithium-ion Batteries.
• Fuel cells / Flow Batteries.
•   A. Hydrogen-oxygen fuel cell.

Battery PPT : Definition, Types and Applications

Related Posts

Social media marketing ppt presentation seminar free, biomedical waste management ppt presentation free, monkey and the cap seller story ppt presentation free download, 1210 electrical engineering(eee) seminar topics 2024, 112 iot seminar topics-internet of thing presentation topics 2024.

330 Latest AI (Artificial Intelligence Seminar Topics) 2024

No comments yet, leave a reply cancel reply.

Your email address will not be published. Required fields are marked *

This site uses Akismet to reduce spam. Learn how your comment data is processed .

Socially & Environmentally responsible ���Batteries

• Managerial Skills
• What is a battery
• How it works

Zinc Carbon

Dry cell Types

Rechargeable

Nickel Metal hydrides

Applications

High Drain devices

• Digital cameras
• Remote-controlled toys
• Certain MP3 players
• High-end portable

audio-recording systems

Low drain devices

• Flashlights
• Remote Controls

Range of batteries

• Disposal & environmental implications��� - avoid usage of Mercury and Cadmium
• Most popular in India
• Has complete range of batteries
• Green initiative - paperless compliance
• Also has tie up with Nippo
• Complete range of eco friendly batteries
• Zero discharge company
• Eco - relay plantation programmes
• Battery education centre
• Safety management standards
• Clean Factory awards 07, 08, 09
• Owned by P & G
• Alkaline and Rechargeable batteries - AA and AAA
• Lasts longer than Zinc carbon batteries
• use only nontoxic inks in our packaging
• card portion of package is made from 55% recycled material
• plastic from 30% recycled material
• battery can from 40% recycled steel
• 8 million batteries sent to
• fire fighting people
• THE POWER RELIEF TRAILER
• fund the nonprofit Rechargeable Battery Recycling Corporation (RBRC)

GP batteries

• Godrej has tie up with GP batteries
• These are zinc chloride batteries and NiMh batteries

Soonabai Pirojsha Godrej Foundation

• Garden department looks after natural environment wherever the branches are present
• Has Environment group for pollution reduction
• EnCon group for energy conservation
• Involves in both community activities and environment protection
• like pollution check camps,
• tree plantation camps
• enhancing creativity in children through science shows.

Certification�

Reduce - Recycle - Reuse�

CSR activities�

Proper usage of batteries�& �Disposal

• Use Rechargeable batteries for High Drain devices
• Use zinc carbon / alkaline batteries for Low Drain devices.
• Do not buy batteries that contain Mercury / Cadmium

Alternates for batteries

• Currently there are no alternatives for the household batteries we use and there is no proper recycling mechanism available in India.
• So it is our responsibility also to ensure proper usage of it and minimize the usage wherever possible.
• http://en.wikipedia.org/wiki/Battery_(electricity)
• http://en.wikipedia.org/wiki/List_of_battery_sizes
• http://en.wikipedia.org/wiki/Rechargeable_battery
• http://www.panasonicenergy.in/eco-friendly-batteries.php
• http://www.evereadyindustries.com/
• http://www.evereadyindustries.com/investors/pdf/investor-communication.pdf
• http://www.duracell.com/en-US/company/power-relief.jspx
• http://www.duracell.com/en-US/power-those-who-protect-us/thank-you.jspx
• http://mangroves.godrej.com/pdf/CSR.pdf
• http://www.sony.co.in/section/csr

Thank you….

• My presentations

Auth with social network:

Download presentation

We think you have liked this presentation. If you wish to download it, please recommend it to your friends in any social system. Share buttons are a little bit lower. Thank you!

Presentation is loading. Please wait.

BATTERY MANAGEMENT SYSTEMS

Published by Steven Palmer Modified over 5 years ago

Similar presentations

Presentation on theme: "BATTERY MANAGEMENT SYSTEMS"— Presentation transcript:

Electricity Chapter 13.

Midsize Lithium Ion Battery Pack Patrick Montalbano © 2012 RIT Winter Student Research and Innovation Symposium Introduction Design, Construction,

35.1 A Battery and a Bulb In a flashlight, when the switch is turned on to complete an electric circuit, the mobile conduction electrons already in the.

Battery Power Conference 2010, 1, Li-Ion Myth-Buster Poking holes into some common beliefs about Li-Ion cells and Li-Ion BMSs. Davide Andrea.

Lithium-Ion Battery/Charger pair for imbedded MP3 player and FM transmitter Federico Carvajal Misun Heo.

A battery uses two different materials (usually metals) for the anode and cathode, immersed in an electrolyte (usually an acid in solution). A Simple Battery.

Electricity 4th grade Science.

Series and Parallel Circuits Kirchoff’s Voltage and Current Laws Circuits 1 Fall 2005 Harding University Jonathan White.

“Power for Wearables” Wearables Studio Spring 2009 Zach Eveland, 2009.

Capacitors insulating dielectric Capacitors store charge. They have two metal plates where charge is stored, separated by an insulating dielectric. To.

Design Team Ten Final Presentation ECE 480 FS08. Overview.

Welcome Connecting batteries in parallel Unexpected effects and solutions Battery Power Conference Sept Davide Andrea, Elithion.

Electric Circuits  To calculate the size of a current from the charge flow and time taken Thursday, August 06, 2015.

Design Process Analysis & Evaluation Part I Example Design: Solar Candle by Prof. Bitar.

As presented to July Battery Management Systems for Electric Vehicles.

Today 3/31  Circuits  Current  Potential (same as always)  Capacitance (energy and in circuits)  HW:3/31 “Circuits 4” Due Thursday 4/3  Exam 3 Thursday,

Rapid Development of Large Li-Ion Battery Packs using Off-the-Shelf Battery Management Systems 9/27/09, 1,

LI-PO BATTERIES. Why Li-po battery is used? Li-Po batteries (short for Lithium Polymer)- light weight have large capacities, meaning they hold lots of.

Product Engineering Processes Battery Primer A short battery primer Handbook of batteries, Linden and Reddy.

Circuits Circuits are closed paths that form a loop.

About project

© 2024 SlidePlayer.com Inc. All rights reserved.

Home Collections Infographics Batteries

Batteries Presentation Templates

Grab our best 110+ electrifying free batteries powerpoint templates and google slides themes with cool battery designs, plugs, and plus-minus symbols. all our slides are fully customizable, so you can connect your ideas with power, energy, and charging-related concepts..

Free Batteries PowerPoint Templates and Google Slides Themes to Energize Your Content!

• Creative Infographics: Our slides feature eye-catching infographics that simplify complex concepts. From bio batteries to lithium-ion powerhouses, we’ve got it all covered.
• Multicolor Visuals: Ditch the dull monochrome. Our templates burst with vibrant colors that make your content pop. Whether it’s a nuclear battery or a sliding battery cover CAD design, your slides will shine.
• Edit with Ease: Tired of rigid templates? Our slides are 100% editable. Customize graphics, tweak text, and make them truly yours. 
• Versatility: Need a portrait-oriented slide for a report? Or a landscape layout for a conference? We’ve got both! Choose from 4:3 or 16:9 formats to fit your needs.
• Royalty-Free: Our slides are royalty-free, so you can use them without any legal hiccups.

Become an expert with SlideEgg

How To Do A Battery Design PowerPoint

We're here to help you, what are batteries powerpoint templates.

This deck contains an attractive collection of slides made using the shapes of batteries, plugs, and lightbulbs. The main goal of the presentation is to connect user content to facts about energy as a whole.

Where can we use these Batteries Templates?

These templates can be used in brainstorming sessions, campaigns to raise awareness of power use, and other energy-related content that calls for compelling and impactful designs.

How can I make Batteries Slides in a presentation?

You can insert pictures of Batteries to make your presentation. You have this fantastic option of readymade templates with creative, realistic visuals to make your display more interesting.

Who can use these Batteries Templates?

These templates can be used by those who wish to describe the efforts of human resources, the proportion of sales and marketing, the proportion of product or service quality, and the function of corporate policies and procedures.

Why do we need to use the Batteries slides?

Battery slides can be an excellent tool for effectively communicating your point in your presentations. This will be a cutting-edge way to convey your messages.

Where can I find Batteries templates for free?

It is very easy to download free slides with millions of choices. Jump into Slide Egg and get your desired templates at zero cost.

Slidesgo.net is an independent website that offers free powerpoint templates and is not part of Freepik/any particular brand. Read the privacy policies

battery Powerpoint templates and Google Slides themes

Discover the best battery PowerPoint templates and Google Slides themes that you can use in your presentations.

Four battery graphs PowerPoint Diagram Template

Charging battery powerpoint diagram template, eco friendly electric car powerpoint templates, slidesgo categories.

• Abstract 13 templates
• Agency 15 templates
• All Diagrams 1331 templates
• Brand Guidelines 3 templates
• Business 195 templates
• Computer 66 templates
• Education 97 templates
• Finance 54 templates
• Food 57 templates
• Formal 60 templates
• Fun 6 templates
• Industry 91 templates
• Lesson 67 templates
• Marketing 57 templates
• Marketing Plan 19 templates
• Medical 71 templates
• Military 21 templates
• Nature 119 templates
• Newsletter 5 templates
• Real Estate 46 templates
• Recreation 53 templates
• Religion 30 templates
• School 557 templates
• Simple 5 templates
• Social Media 8 templates
• Sports 46 templates
• Travel 26 templates
• Workshop 4 templates

Slidesgo templates have all the elements you need to effectively communicate your message and impress your audience.

Suitable for PowerPoint and Google Slides

Download your presentation as a PowerPoint template or use it online as a Google Slides theme. 100% free, no registration or download limits.

Want to know more?

• Frequently Asked Questions
• Google Slides Help
• PowerPoint help
• Who makes Slidesgo?

An official website of the United States government

Here’s how you know

Official websites use .gov A .gov website belongs to an official government organization in the United States.

Secure .gov websites use HTTPS A lock ( Lock A locked padlock ) or https:// means you’ve safely connected to the .gov website. Share sensitive information only on official, secure websites.

JavaScript appears to be disabled on this computer. Please click here to see any active alerts .

Track 1b: Small Format Batteries - Collection Systems and Locations

On this page:

Presentation Slides

As required by the Bipartisan Infrastructure Law, EPA is developing battery collection best practices and voluntary battery labeling guidelines to improve battery collection and recycling and reduce safety incidents that threaten waste management worker safety. EPA is developing battery collection best practices for state, Tribal, and local governments to recycle batteries in a manner that is technically and economically feasible, environmentally sound and safe, and optimizing value and use of materials, including critical minerals.

On April 11, 2024, EPA hosted the first virtual meeting for Track 1b: small format battery collection as part of EPA’s battery collection best practices initiative. During the meeting, EPA first shared an overview of universal waste and batteries to provide additional context on how the battery collection and labeling initiative intersects with universal waste regulations. Representatives from Vermont Department of Environmental Conservation and Chittenden Solid Waste District shared the history of the state’s battery stewardship program, sharing best practices for battery collection and raising consumer awareness. The South Bayside (California) Waste Management Authority presented curbside battery collection challenges and successes, including public outreach strategies to improve collection rates and reduce fires.

Then, meeting attendees split into breakout groups to discuss other successful collection strategies for small format batteries, including policy options, outreach campaigns, and funding strategies. Participants also discussed what types of materials would be most helpful for EPA’s final collection best practices toolkit. EPA wrapped up the call by providing dates and goals for upcoming meetings and encouraging participants to submit additional input via [email protected] .

• Ellen Meyer, Batteries and Critical Minerals Senior Scientist, Resource Conservation and Sustainability Division​, U.S. EPA.
• Pat Wise, Program Analyst, Resource Conservation and Sustainability Division​, U.S. EPA.
• Mia Roethlein, Environmental Analyst, Vermont Department of Environmental Conservation.
• Gary Winnie, Hazardous Waste Facility Manager, Chittenden Solid Waste District.
• Julia Au, Senior Outreach, Education & Compliance Manager, Rethink Waste South Bayside Waste Management Authority.
• Pat Tallarico, Facilitator, Eastern Research Group Support Team.
• Slide Presentation for Collection Systems and Locations for Small Format Batteries Meeting (pdf) (4.9 MB)
• Bipartisan Infrastructure Law Home
• Review Funding Announcements
• Cleanup, Revitalization and Recycling
• Electric and Low-emission School Buses
• Investments in Tribal Communities
• Pollution Prevention
• Water Infrastructure
• Humboldt, IA
• Livermore Falls, ME

Got any suggestions?

We want to hear from you! Send us a message and help improve Slidesgo

Top searches

Trending searches

11 templates

67 templates

21 templates

environmental science

36 templates

9 templates

holy spirit

Battery chart infographics, it seems that you like this template, free google slides theme, powerpoint template, and canva presentation template.

Look at your cell phone and watch how much battery is left. Do you think that this little detail can be used to represent other kinds of data? This theme is the basis of our infographics. Choose the design that you like the most and, taking into account the colors, make visual representations of your information.

Features of these infographics

• 100% editable and easy to modify
• 30 different infographics to boost your presentations
• Include icons and Flaticon’s extension for further customization
• Designed to be used in Google Slides, Canva, and Microsoft PowerPoint and Keynote
• 16:9 widescreen format suitable for all types of screens
• Include information about how to edit and customize your infographics

How can I use the infographics?

Am I free to use the templates?

How to attribute the infographics?

Attribution required If you are a free user, you must attribute Slidesgo by keeping the slide where the credits appear. How to attribute?

Related posts on our blog.

How to Add, Duplicate, Move, Delete or Hide Slides in Google Slides

How to Change Layouts in PowerPoint

How to Change the Slide Size in Google Slides

Related presentations.

Premium template

Unlock this template and gain unlimited access

Popular Searches

• Master’s of AI Engineering
• Engineering Magazine
• Covid updates
• Manufacturing Futures Institute
• student organizations
• Rethink the Rink

Social Media

• @CMUEngineering
• CMUEngineering
• College of Engineering

Undergraduates present research at Meeting of the Minds 2024

by E. Forney

Engineering undergraduate students had a wonderful showing at Meeting of the Minds, displaying posters, giving presentations, and demonstrating projects they have worked on this past academic year.

• Learn more about Meeting of the Minds

For one day at the end of each spring semester, the Cohon University Center becomes a hub of academic posters, presentations, and demonstrations of projects that undergraduate students have been working on throughout the year. Here are some highlights of what Engineering undergraduates are researching at Carnegie Mellon University.

Gravity-fed hydroponic rainwater management

Kate Hanson is a junior in civil and environmental engineering . Her project was inspired by a sight that Pittsburgh natives may remember from downtown a few years ago—a large green wall on a building owned by PNC Bank, brightening the intersection of Sixth Ave. and Grant St. The green wall has since been taken down due to the cost of upkeep, but this got Hanson wondering: was there a way to create a green wall that wasn't cost prohibitive?

After the upfront cost of installation, green walls require two main resources to maintain themselves: a supply of water to nourish the plant life and energy to work the water pumps. Pittsburgh is a city with heavy rainfall, so water comes from the sky for free. But making sure it is distributed along a wall in times of heavy or sparce rain without using an expensive pump was the calculation that Hanson tackled.

In her project, Hanson envisioned a long pipe system installed on the vertical face of any given wall, feeding the plant life. In times of heavy rain, flooding would be avoided by added a bobber below the rain collection tank. Working like a toilet flushing system, the floating bobber would be chained to a small door at the bottom of the tank. As the water level rises, the bobber rises, bringing the chain and door with it, allowing water to rush through the door until the water level lowers the bobber once more.

In dryer times, there may not be enough water to reach up to the roots of the plants from the bottom of the pipes. To make a small amount of water stretch further, the pipes are fitted with ribbed floors. These floors take up volume that water would otherwise fill, displacing the water level to raise it up to the plant roots. 

Hanson received the Undergraduate Environmental Award for her poster. She is advised by Greg Lowry , professor of civil and environmental engineering, and will continue her research with the Swartz Center for Entrepreneurship to hopefully bring green walls to life in Pittsburgh. For a first installation, she has her sights set on Wean Hall, specifically the front face of the cube-like protrusion that houses a classroom above the fifth-floor entrance of the building.

Creating gold nanoparticles to sort chiral medicines

Alexander Henry (Harry) Burton is a sophomore studying chemical engineering and biomedical engineering . He worked on research in the all-undergraduate research lab overseen by Nisha Shukla , a special faculty member within the College. His research occurs at the nanoscale. In the lab, he can manipulate gold nanoparticles to give them a specific chirality, making them adept at sorting through chiral medicines.

Why gold? You may have asked the same question at the dentist's office. And the answer would be the same—gold is a largely non-reactive element, meaning that it does not interact with medicine or the human body in negative ways. Gold also has the added benefit of being easy to manipulate into different shapes at the nanoscale since it easily absorbs chiral amino acids, changing the gold into a desired chiral shape.

Chirality is a characteristic of nanoparticles that describes how they attach to other nanoparticles. You can think of it like the molecules having a clockwise or counterclockwise structure—a clockwise structure can never fit in with another clockwise structure, a counterclockwise structure can never fit in with another counterclockwise structure. Cells in our bodies have chirality. Therefore, to best administer medicine that needs to attach at the cellular level, clockwise medicine should be given to those with counterclockwise cells and vice versa. However, since the nanoparticles of medicine are basically identical, sorting out clockwise from counterclockwise particles is a difficult task.

That's where the gold comes in. By adding small amounts of chiral gold to the medicine, you can sort it into clockwise and counterclockwise parts. The counterclockwise medicine latches on to clockwise gold and vice versa, making it ready for administration into bodies.

When asked if the research was expensive, due to the nature of gold, Burton laughed and said, “It is expensive, but my lab’s principal investigator said it was okay.” The cost of the knowledge gained from the research outweighs the monetary price of gold.

Slug battery: an enzymatic fuel cell

Theophilos (Theo) Cockrell is a junior in electrical and computer engineering . He gave a presentation on a project he completed alongside post-doc Kevin Dai, Ph.D. candidate Michael J. Bennington, and Victoria Webster-Wood , an associate professor in mechanical engineering. They work in the Biohybrid and Organic Robotics Group , which seeks to find ways to bring electronic sensors to marine biomes for environmental sensing purposes. 

Getting an electrical device to survive underwater is no easy task. Typical circuit boards cannot be exposed to water. Solar power is limited the further down you dive. And there is an abundance of marine life that researchers try their best not to disturb while placing sensors. So Cockrell’s group tried a novel approach—put a sensor inside a sea creature and power it off of the creature itself.

Cockrell developed an Enzymatic Fuel Cell (EFC), an implantable battery that charges based on organic input, such as glucose and oxygen in an animal’s circulatory system. For their model animal, they chose Aplysia californica —California sea hare—a kind of sea slug that has a convenient body cavity where a fuel cell can fit without harming the slug. This slug has suitable chemistry in the hemolymph transported by its open circulatory system.

Cockrell worked to test variables that could help perfect the so-called slug battery. Many factors can change the effectiveness of the battery, such as whether the electronics are rolled up or lying flat, the addition of certain chemical compounds on the battery, and the use of synthesized saline or hemolymph from the slug around the battery. The team was able to produce promising findings in vitro (in the lab) and hopes to move their tech in vivo (into a specimen) in the future.

Material characterization of metal additive manufacturing

Lauren Fitzwater is a junior studying materials science and engineering who is also minoring in additive manufacturing . She gave a presentation about the research she did as the only undergraduate student in the Engineering Materials for Transformative Technologies (EMIT) Lab which is overseen by Sneha Prabha Narra , an assistant professor of mechanical engineering. Alongside Ph.D. students Misha Khrenov and Justin Miner, Fitzwater explored the lack of fusion (LOF) boundary in laser powder bed fusion (L-PBF) of Inconel-718 (IN718).

There are a few acronyms to break down there: IN718 is a strong, non-corrosive nickel chromium alloy that is used in the production of jet engines and turbines. L-PBF is a manufacturing process that uses lasers to selectively melt metal powder to form it into the desired shape. LOF is a type of defect that can result from this form of additive manufacturing where pores form in the hardened metal where the melt pools have failed to overlap.

For typical L-PBF printing, parameters like laser speed and power will be carefully selected to avoid LOF and other defects like keyholing and metal balling up. Fitzwater noticed that the sweet spot was pretty rigid and difficult to achieve, and wondered if she couldn’t find a way to make the target a bit bigger. She noticed that traditional LOF research does not take into account melt pool geometry variability, instead basing calculations on average melt pool widths and depths.

The result for average melt pool geometry ends up being mostly a linear relation—a faster, more powerful laser will produce more defects. But Fitzwater tested a variety of melt pool sizes and found that the sweet spot started to wiggle around a bit more, resulting in a wavy pattern that showed that the laser could go faster and be more powerful at certain sizes. She hopes this research can be used in the future to improve the accuracy of process maps.

Fitzwater said after her presentation that finding this research opportunity with the EMIT lab opened her eyes to the world of additive manufacturing, a career path she had not previously considered. 

FRESH-printing meat from lab-grown cells

Daniel Aluko is a sophomore studying mechanical engineering and biomedical engineering. He works in the lab of Rosalyn Abbott , assistant professor of biomedical engineering, to study effective methods for 3D printing lab-grown meat . The hope is to offer alternatives to traditional meat, which is tasking on the environment and presents ethical issues around the treatment of livestock. 

Most people are familiar with 3D printers that extrude plastic—a rigid material that rapidly dries and takes form, holding itself aloft or supported on thin supports. However, when printing with something organic, the material cannot attach to itself quickly and take form without support since it is often squishy. This is why Aluko uses Freeform Reversible Embedding of Suspended Hydrogels (FRESH) 3D printing. With the FRESH method, lab-grown fat cells called adipocytes are added to a base of alginate, a neutral polymer formed from seaweed. This creates a viscous liquid referred to as bioink that is somewhere between castor oil and molasses in consistency. This bioink is then extruded into a support bath where it crosslinks or cures into the desired shape. The support bath is basically a clear jelly that melts away at body temperature, so it sloughs away from the final printed meat with ease.

Aluko was advised by biomedical engineering Ph.D. student Lindsey Huff. His role in the project was to test variables to ensure the best quality prints. Adipocytes are somewhat delicate and large, so ensuring that they remain intact throughout the print is crucial for a successful outcome. He studied the speed of extrusion, the gauge of the printing needle, and the viscosity of the bioink. By simulating extrusion in fluid flow software, Aluko was able to test multiple combinations of factors to find a happy medium between them all.

Aluko hopes to see the research also work for myocytes (muscle cells) which are smaller and more likely to hold up to anything that adipocytes can handle. As a sophomore, he hopes to explore other areas of research in his remaining years as an undergraduate at CMU. By getting an early start in research, he has time to compare FRESH 3D printing work to other areas of interest, such as biomechanics or biomedical devices. Exploring multiple areas will allow Aluko to better decide what he might like to study, should he choose to pursue a Ph.D. in the future.