electronic nose by yash pani - PowerPoint PPT Presentation

About This Presentation
Transcript and Presenter's Notes

Title: electronic nose by yash pani


1
ELECTRONIC NOSE
  • By- SHWETA SINGH
  • EN-F
  • 0902721093

2
CONTENTS
  • What is an E-Nose?
  • Analogy between an E-Nose a Biological Nose
  • How does an E-Nose work?
  • Basic Design of an E- Nose
  • How does a Sensor work?
  • Why is E-Nose better?
  • Current and Future Applications

3
WHAT IS AN ELECTRONIC-NOSE?
  • An Electronic Nose is a system that uses pattern
    of responses from an array of gas sensors to
    examine and identify a gaseous sample.

4
OUR ELECTRONIC NOSE
5
ANALOGY BETWEEN AN E-NOSE A BIOLOGICAL NOSE
  • InhalinggtPump
  • MucusgtFilter
  • Olfactory EpitheliumgtSensors
  • Enzymatic ReactionsgtReaction
  • Binding With ProteinsgtInteraction
  • Cell Membrane DepolarizedgtSignal
  • Nerve ImpulsesgtCircuitry Neural Network

6
(No Transcript)
7
HOW DOES A BIO NOSE WORK?
A ROSE?
MUCUS FILTER
RECEPTOR PROTEIN SENSOR
CIRCUIRY NN
NERVE
WOULD A ROSE SMELLED BY ANY OTHER NOSE SMELL AS
SWEET?
INPUT
8
BASIC DESIGN OF E-NOSE
9
WORKING PRINCIPLE
  • Developed to mimic human olfaction which is a
    crucial mechanism
  • Essentially the instrument contains-
  • Head space Sampling
  • Sensor array
  • Pattern recognition module

10
  • E-Nose includes three major parts-
  • A Sample Delivery System
  • A Detection System
  • A Computing System
  • Sample Delivery System
  • Enables generation of volatile compounds
  • Then injects this headspace into detection system

11
  • Detection System
  • Consists of a sensor set
  • Sensors when contacted with volatile compounds,
    develop change in electrical properties
  • This response is recorded by electronic interface
    transforming signal to digital value.
  • Types of Sensors
  • Metal oxide semiconductor
  • Conducting Polymers
  • Surface Acoustic Wave
  • Quartz Crystal Microbalance

12
  • Computing System-
  • Works to combine responses of all sensors
  • it performs global fingerprint analysis and
    provides results and representations that can be
    easily interpreted.

13
BLOCK DIAGRAM REPRESENTATION
14
  • 1. An auto sampler
  • It consists of a sample carousel, where the
    vials containing the odour-emitting sample are
    held an oven, where the sample is
    pre-conditioned a movable mechanic arm with
    syringe (A).
  •  

15
  • The electro-mechanical part of the EN used in
    this experiment consists of -
  • 2. A mass flow controller (B)- to set the flow
    of the carrier gas.
  • 3. A stained steel chamber (C) -which can contain
    up to five chemical sensors plus a humidity
    sensor.
  • 4. Control electronics (D) -permitting to steer
    the system (auto sampler, mass flow controllers
    and sensors) via PC.
  •  

16
  • The typical measurement consists of the exposure
    of the sensors to a concentration step, that is a
    change of odour concentration from zero to c
    (each component of the vector stands for a gas
    component) and back to zero again, and of the
    recording of the subsequent change in resistance.
    The classical feature extracted from the response
    curve is the relative change in resistance.

17
HOW DOES AS GENERAL SENSOR WORK?
  • Functioning is according to the change in
    resistance.
  • Sensor absorbs gas emitted from sample
  • It results in change in resistance of sensor
  • By relation VIR, Voltage drop across also
    changes
  • This voltage is measured and is given to the
    circuit for further processes.

18
An E-Nose Sensor
19
WHY IS E-NOSE BETTER?
  • Trained human sniffers are expensive
  • Individuals vary
  • Hazardous Chemicals
  • Can be done in real time for long periods

20
WHERE ELECTRONIC NOSES ARE USED?
  • Automotive
  • Food Safety
  • Telemedicine
  • Emergency Response
  • Military and Space
  • Environmental Monitoring

21
APPLICATIONS
  • In quality control laboratories for at line
    quality control such as
  • Conformity of raw materials, intermediate and
    final products
  • Batch to batch consistency
  • Detection of contamination, spoilage,
    adulteration
  • Origin or vendor selection
  • Monitoring of storage conditions.

22
  • In process and production departments
  • Managing raw material variability
  • Comparison with a reference product
  • Measurement and comparison of the effects of
    manufacturing process on products
  • Following-up cleaning in place process efficiency
  • Scale-up monitoring
  • Cleaning in place monitoring.

23
  • Possible and future applications in the
    fields of health and security
  • Detection of dangerous bacteria
  • Detection of Lung Cancer
  • Quality Control of Food Products
  • Nasal implants can warn presence of natural gas

24
  • Possible and future applications in the field
    of crime prevention and security-
  • Detection of Drug Odors
  • Bomb detection
  • Applications in Environmental Monitoring
  • For identification of volatile organic compounds
    in air, water and soil samples.
  • For environmental protection.

25
THANK YOU
26
ANY QUERRIES?
Write a Comment
User Comments (0)
About PowerShow.com