A technical method of extraction of gold from e waste a multi-sensor based method using microcontroller
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The document discusses a method for automating the extraction of gold from e-waste using a microcontroller and various sensors. It describes the environmental hazards of e-waste and traditional disposal methods, highlighting the need for effective recycling and extraction processes. The proposed automated system is structured into three stages and aims to improve efficiency and safety in gold recovery from e-waste.
![IJRET: International Journal of Research in Engineering and Technology eISSN: 2319-1163 | pISSN: 2321-7308
__________________________________________________________________________________________
Volume: 03 Special Issue: 07 | May-2014, Available @ http://www.ijret.org 94
A TECHNICAL METHOD OF EXTRACTION OF GOLD FROM E-
WASTE: A MULTI-SENSOR BASED METHOD USING
MICROCONTROLLER
Rohini N. Hongal1
, Roopa G. Sunagad2
, Shruti A. Gombi3
, Rohankumar Patil4
, K.Bhat5
1
Student, Department of E & CE, Basaveshwar Engineering College, Karnataka, India
2
Student, Department of E & CE, Basaveshwar Engineering College, Karnataka, India
3
Student, Department of E & CE, Basaveshwar Engineering College, Karnataka, India
4
Student, Department of E & CE, Basaveshwar Engineering College, Karnataka, India
5
Faculty, Department of IT, Basaveshwar Engineering College, Karnataka, India
Abstract
The disposal of e-wastes into the environment is hazardous as they contain chemicals. The conventional methods of disposing these e-
wastes are irrelevant and have adverse effect on the environmental conditions which is a threat to life. The objective of this paper is to
describe the recycling of e-wastes and extraction of valuable metals like gold and silver from it. The aquaregia solution based method
of extraction is the oldest and conventional method. The steps and procedures that are followed and practiced are to be done
manually which seems to be quite risky as it is a chemical process. But the aquaregia solution method of extraction can be easily
automated for precise and faster extraction. The intension of our paper is to propose an idea of an automation system for the recovery
of gold from E-waste. This system for gold recovery is solely controlled by the microcontroller. There is use of several types of
sensors, which are in turn act as input providers to the microcontroller, in order to control the whole process. There is great
advantage if it is implemented practically. It can create a sort of industrial solution as e-waste is global problem. A new trend in the
recycling industry will be created which will be a revolutionary step. The only thing is that the initial investment will be quite more.
But once implemented it can be used for long terms and for cost effectiveness.
Keywords: E- waste, Aquaregia, microcontroller, signal conditioning, solenoid valve, end point.
--------------------------------------------------------------------***----------------------------------------------------------------------
1. INTRODUCTION
The advancement of technology and the industrial revolution
changed the world’s life-style rapidly. The improvements and
advances in the field of electronics was so rigorous that a
common man has became able to have more number of
electronic gadgets increased, later the greatest disadvantage of
e-toys was its waste disposal and its management which is
challenge during these decades. Now the days of conventional
PCs are gone. These are the days of tablets and laptops. And
particularly in the electronics domain a device validates to a
maximum of two years from the day it has released to the
market. Hence the e-waste generated is found to be enormous
that poses a problem to the life and environment [1],[2]. E-
waste refers to the waste materials borne out of the electronic-
gadgets. The disposal of e-wastes into the environment is
hazardous as they contain chemicals. The conventional
methods of disposing these e-wastes are irrelevant and have
adverse effect on the environmental conditions which is a
threat to life. The objective of this paper is to describe the
recycling of e-wastes like PCBs [3], [4], batteries, SIM cards,
mother boards etc and extraction of valuable metals like gold
and silver from it [5]. Nowadays the management of e-waste is
a biggest headache in developed and developing countries like
Japan, Germany, and America and even in India too. So, in
this context proper management and recycling of e-waste is
necessary.
The methods that are known: Lime Sulphur Synthetic Solution
(LSSS) [6], Electrolytic process, aquaregia solution [7]
method and metallurgical recovery processes [8], [9]. Among
these methods the aquaregia solution method of extraction is
the oldest and conventional method which is widely practiced
everywhere to extract scrap gold, the chemicals used here are
easily available and are of reasonable cost.
The microcontroller [10] based extraction of gold from e-
waste system consists of a microcontroller, various sensors for
end point detection, efficient signal conditioning, actuators
and many final control elements.
The process is divided into three stages and each stage is
microcontroller controlled for the efficient and automated
mechanism. This system can be further improvised and other
precious metals like platinum and silver can be extracted with
necessary modifications in detection and control.](https://image.slidesharecdn.com/atechnicalmethodofextractionofgoldfrome-wasteamulti-sensorbasedmethodusingmicrocontroller-140824232735-phpapp01/85/A-technical-method-of-extraction-of-gold-from-e-waste-a-multi-sensor-based-method-using-microcontroller-1-320.jpg)
![IJRET: International Journal of Research in Engineering and Technology eISSN: 2319-1163 | pISSN: 2321-7308
__________________________________________________________________________________________
Volume: 03 Special Issue: 07 | May-2014, Available @ http://www.ijret.org 95
2. THE PROCESS
The treatment and management of e-waste can be broadly in
to three levels.
1. Level: Involves dismantling.
2. Level: Electrostatic separation.
3. Level: Recovery of precious metals and disposal of e-
waste.
It is necessary that the e-waste must have to undergo the first
two level treatments before extracting the precious metals
from the crushed e-waste. The waste materials should be cut to
get the metallic parts and it must be crushed. The process
presented here mainly discusses the third level. At the third
level treatment of e-waste, the metallic parts are extracted and
cut. Then they are crushed such that it is soluble in a suitable
solvent.
The concentrated hydrochloric acid (HCl) and nitric acid
(HNO3), sodium bisulphite, urea, aqueous ammonia and water
are some of the chemicals that are required for the extraction
of gold. Figure1 shows the conceptual arrangement of the
complete process. The total process can be put into three
stages for the convenience of understanding the operation and
all the stages are explained below:
2.1 Stage1
The crushed e-waste is mixed with the two chemicals in the
mixing chamber at the very first stage of this automated
process. The stage 1 consists of two chambers for this
purpose. The first chamber is for the crushed e-waste which is
regulated by the solenoid valve V1 and another for the
preparation of fresh aquaregia solution from HCl and HNO3
sub chambers. HCL and HNO3 are to be mixed thoroughly at a
ratio of 3:1. The flow rates of these two acids are controlled
for this purpose by solenoid valves V2 and V3 that allow
calculated amount of acids for the calculated amount of
crushed raw material.
Fig 1: The complete process block diagram
The uniform mixing of these two acids is achieved with the
motor assisted stirrer. Now valve V1 is opened to allow
crushed e-waste into the mixing chamber. The stirrer rotates
so that waste gets mixed with aquaregia. The mixing extent is
continued unless fizzing sound stops and the mixture turns to
dark green coloured compound. A sensitive microphone and a
colour sensor are used to detect this end point. Once these two
end points are reached, the microcontroller stops the stirrer
motor and opens valve V4. At the same time solenoid valve V5
is opened for a finite and predetermined time to add definite
quantity of urea. The next three chambers are considered as
stage2.
2.2 Stage2
Upon adding urea, fizzing sound starts and the end point is
reached when this sound ceases and foam starts developing.
One more sensitive microphone is used to detect the end point.
After the reaching of the expected end point, at this point of
time microcontroller opens V6 to displace the compound into
the next chamber which adds calculated amount of sodium
bisulphate through microcontroller operated valve V7. A
colour sensor or time based detection is enough to make the
reaction complete, resulting into brown precipitation. Next
chamber is for mixing of aqueous ammonia through valve V8.
In this chamber the compound is mixed with ammonia still a
muddy brown precipitation occurs with white vapour. This is
monitored by a sensor S4.
2.3 Stage3
Valve V10 makes the precipitate available for water rinsing. A
rinsing mechanism is used to wash the muddy brown
precipitate for a finite period to remove the acid in the
compound. Finally microcontroller opens valve V11 for
heating purpose. Heater is turned on for a time period up to
which molten gold is obtained.
Thus, the whole process is sequential in nature. A
programmed microcontroller [10] with number of sensors,
their signal conditioner and actuator can effectively control the
process. IC 8051 or any other microcontroller can effectively
monitor and control the whole process. The output of all the
sensors are signal conditioned. Since each sensor monitors
only one point or value, comparators are used to give a high or
low signal depending on the status of each chamber. This
eliminates the use of an ADC. A 4:1 digital multiplexer is
used to sequentially select the respective sensor and
corresponding parameter of process by an 8 bit
microcontroller. The microcontroller is programmed and the
algorithm for this program is explained in the proceeding
section.](https://image.slidesharecdn.com/atechnicalmethodofextractionofgoldfrome-wasteamulti-sensorbasedmethodusingmicrocontroller-140824232735-phpapp01/85/A-technical-method-of-extraction-of-gold-from-e-waste-a-multi-sensor-based-method-using-microcontroller-2-320.jpg)
![IJRET: International Journal of Research in Engineering and Technology eISSN: 2319-1163 | pISSN: 2321-7308
__________________________________________________________________________________________
Volume: 03 Special Issue: 07 | May-2014, Available @ http://www.ijret.org 97
5. CONCLUSIONS
The aquaregia solution method of extraction can be easily
automated for precise and faster extraction. The steps and
procedures that are followed and practiced are sequential in
nature and hence a microcontroller based automatic extraction
method is feasible and possible.
REFERENCES
[1] Lim Fung Chen, Haw Wai Yee, “E-waste
Management:Are we ready for it?, A study on the
awareness of COIT students toward e-waste
management” Proceedings of the 5th International
Conference on IT & Multimedia at UNITEN (ICIMU
2011) Malaysia,14 – 16 November 2011
[2] R. Widmer, et aI., "Global perspectives on e waste,"
Environmental impact assessment review, vol. 25, p.
436, 2005
[3] Z. Gongming, L. Zhihua, and Z. Xulu, “Experimental
Study on Metal Recycling from Waste PCB,” in Proc.
Int. Conf. Sustainable Solid Waste Management,
Chennai, India, 2007, pp. 155-162
[4] Youssef. Chehade,et al “Recovery of Gold, Silver,
Palladium, and Copper from Waste Printed Circuit
Boards”, International Conference on Chemical, Civil
and Environment engineering (ICCEE'2012) March 24-
25, 2012 Dubai
[5] S. R. Izatt, et al., “Sustainable Recycling of Precious
Metals,” presented at the International Precious Metals
Institute 36th Annual Conf., Las Vegas, Nevada, Jun.
9-12, 2012
[6] Li Jing-Ying,Huang Lu, “The Leaching Gold and
Silver from E-waste by LSSS Method”, Bioinformatics
and Biomedical Engineering (iCBBE), 2010 4th
International Conference on Digital Object Identifier:
10.1109/ICBBE.2010.5517461, Publication Year:
2010.
[7] http://en.wikipedia.org/wiki/Aqua_regia or aquaregia
method and application notes
[8] Antrekowitsch H., Potesser M., Spruzina W. et al.
“Metallurgical recycling of electronic scrap [J]”. The
Minerals, Metals & Materials Society, Vol.58, 2006,
pp.899-908.
[9] J. Cui, and L. Zhang, “Metallurgical recovery of metals
from electronic waste: A review,” Journal of
Hazardous Materials, vol. 158, pp. 228-256, 2008.
[10] Kenneth J. Ayala, “The 8051 Microcontroller”,
Cengage Delmar Learning India Pvt. Ltd., Edition 3,
2012.
BIOGRAPHIES
Rohini Hongal is a 8th
semester B.E student in
BEC, Bagalkot. Her interested areas are
instrumentation and embedded systems.
Shruti Gombi is a 8th
semester B.E student in
BEC, Bagalkot. Her interested areas are
instrumentation and embedded systems.
Rohankumar Patil is a 8th
semester B.E student in
BEC, Bagalkot. His interested areas are
instrumentation and VLSI design.
Krishnamurthy Bhat, is working as Head of
Dept. of Inst.Tech. in Basaveshwar Engg.
College, Bagalkot, Karnataka since 2007 He has
22 years of teaching experience. His fields of
interest are sensor design and development,
electronic hardware and virtual instrumentation.](https://image.slidesharecdn.com/atechnicalmethodofextractionofgoldfrome-wasteamulti-sensorbasedmethodusingmicrocontroller-140824232735-phpapp01/85/A-technical-method-of-extraction-of-gold-from-e-waste-a-multi-sensor-based-method-using-microcontroller-4-320.jpg)
A technical method of extraction of gold from e waste a multi-sensor based method using microcontroller
- 1. IJRET: International Journal of Research in Engineering and Technology eISSN: 2319-1163 | pISSN: 2321-7308 __________________________________________________________________________________________ Volume: 03 Special Issue: 07 | May-2014, Available @ http://www.ijret.org 94 A TECHNICAL METHOD OF EXTRACTION OF GOLD FROM E- WASTE: A MULTI-SENSOR BASED METHOD USING MICROCONTROLLER Rohini N. Hongal1 , Roopa G. Sunagad2 , Shruti A. Gombi3 , Rohankumar Patil4 , K.Bhat5 1 Student, Department of E & CE, Basaveshwar Engineering College, Karnataka, India 2 Student, Department of E & CE, Basaveshwar Engineering College, Karnataka, India 3 Student, Department of E & CE, Basaveshwar Engineering College, Karnataka, India 4 Student, Department of E & CE, Basaveshwar Engineering College, Karnataka, India 5 Faculty, Department of IT, Basaveshwar Engineering College, Karnataka, India Abstract The disposal of e-wastes into the environment is hazardous as they contain chemicals. The conventional methods of disposing these e- wastes are irrelevant and have adverse effect on the environmental conditions which is a threat to life. The objective of this paper is to describe the recycling of e-wastes and extraction of valuable metals like gold and silver from it. The aquaregia solution based method of extraction is the oldest and conventional method. The steps and procedures that are followed and practiced are to be done manually which seems to be quite risky as it is a chemical process. But the aquaregia solution method of extraction can be easily automated for precise and faster extraction. The intension of our paper is to propose an idea of an automation system for the recovery of gold from E-waste. This system for gold recovery is solely controlled by the microcontroller. There is use of several types of sensors, which are in turn act as input providers to the microcontroller, in order to control the whole process. There is great advantage if it is implemented practically. It can create a sort of industrial solution as e-waste is global problem. A new trend in the recycling industry will be created which will be a revolutionary step. The only thing is that the initial investment will be quite more. But once implemented it can be used for long terms and for cost effectiveness. Keywords: E- waste, Aquaregia, microcontroller, signal conditioning, solenoid valve, end point. --------------------------------------------------------------------***---------------------------------------------------------------------- 1. INTRODUCTION The advancement of technology and the industrial revolution changed the world’s life-style rapidly. The improvements and advances in the field of electronics was so rigorous that a common man has became able to have more number of electronic gadgets increased, later the greatest disadvantage of e-toys was its waste disposal and its management which is challenge during these decades. Now the days of conventional PCs are gone. These are the days of tablets and laptops. And particularly in the electronics domain a device validates to a maximum of two years from the day it has released to the market. Hence the e-waste generated is found to be enormous that poses a problem to the life and environment [1],[2]. E- waste refers to the waste materials borne out of the electronic- gadgets. The disposal of e-wastes into the environment is hazardous as they contain chemicals. The conventional methods of disposing these e-wastes are irrelevant and have adverse effect on the environmental conditions which is a threat to life. The objective of this paper is to describe the recycling of e-wastes like PCBs [3], [4], batteries, SIM cards, mother boards etc and extraction of valuable metals like gold and silver from it [5]. Nowadays the management of e-waste is a biggest headache in developed and developing countries like Japan, Germany, and America and even in India too. So, in this context proper management and recycling of e-waste is necessary. The methods that are known: Lime Sulphur Synthetic Solution (LSSS) [6], Electrolytic process, aquaregia solution [7] method and metallurgical recovery processes [8], [9]. Among these methods the aquaregia solution method of extraction is the oldest and conventional method which is widely practiced everywhere to extract scrap gold, the chemicals used here are easily available and are of reasonable cost. The microcontroller [10] based extraction of gold from e- waste system consists of a microcontroller, various sensors for end point detection, efficient signal conditioning, actuators and many final control elements. The process is divided into three stages and each stage is microcontroller controlled for the efficient and automated mechanism. This system can be further improvised and other precious metals like platinum and silver can be extracted with necessary modifications in detection and control.
- 2. IJRET: International Journal of Research in Engineering and Technology eISSN: 2319-1163 | pISSN: 2321-7308 __________________________________________________________________________________________ Volume: 03 Special Issue: 07 | May-2014, Available @ http://www.ijret.org 95 2. THE PROCESS The treatment and management of e-waste can be broadly in to three levels. 1. Level: Involves dismantling. 2. Level: Electrostatic separation. 3. Level: Recovery of precious metals and disposal of e- waste. It is necessary that the e-waste must have to undergo the first two level treatments before extracting the precious metals from the crushed e-waste. The waste materials should be cut to get the metallic parts and it must be crushed. The process presented here mainly discusses the third level. At the third level treatment of e-waste, the metallic parts are extracted and cut. Then they are crushed such that it is soluble in a suitable solvent. The concentrated hydrochloric acid (HCl) and nitric acid (HNO3), sodium bisulphite, urea, aqueous ammonia and water are some of the chemicals that are required for the extraction of gold. Figure1 shows the conceptual arrangement of the complete process. The total process can be put into three stages for the convenience of understanding the operation and all the stages are explained below: 2.1 Stage1 The crushed e-waste is mixed with the two chemicals in the mixing chamber at the very first stage of this automated process. The stage 1 consists of two chambers for this purpose. The first chamber is for the crushed e-waste which is regulated by the solenoid valve V1 and another for the preparation of fresh aquaregia solution from HCl and HNO3 sub chambers. HCL and HNO3 are to be mixed thoroughly at a ratio of 3:1. The flow rates of these two acids are controlled for this purpose by solenoid valves V2 and V3 that allow calculated amount of acids for the calculated amount of crushed raw material. Fig 1: The complete process block diagram The uniform mixing of these two acids is achieved with the motor assisted stirrer. Now valve V1 is opened to allow crushed e-waste into the mixing chamber. The stirrer rotates so that waste gets mixed with aquaregia. The mixing extent is continued unless fizzing sound stops and the mixture turns to dark green coloured compound. A sensitive microphone and a colour sensor are used to detect this end point. Once these two end points are reached, the microcontroller stops the stirrer motor and opens valve V4. At the same time solenoid valve V5 is opened for a finite and predetermined time to add definite quantity of urea. The next three chambers are considered as stage2. 2.2 Stage2 Upon adding urea, fizzing sound starts and the end point is reached when this sound ceases and foam starts developing. One more sensitive microphone is used to detect the end point. After the reaching of the expected end point, at this point of time microcontroller opens V6 to displace the compound into the next chamber which adds calculated amount of sodium bisulphate through microcontroller operated valve V7. A colour sensor or time based detection is enough to make the reaction complete, resulting into brown precipitation. Next chamber is for mixing of aqueous ammonia through valve V8. In this chamber the compound is mixed with ammonia still a muddy brown precipitation occurs with white vapour. This is monitored by a sensor S4. 2.3 Stage3 Valve V10 makes the precipitate available for water rinsing. A rinsing mechanism is used to wash the muddy brown precipitate for a finite period to remove the acid in the compound. Finally microcontroller opens valve V11 for heating purpose. Heater is turned on for a time period up to which molten gold is obtained. Thus, the whole process is sequential in nature. A programmed microcontroller [10] with number of sensors, their signal conditioner and actuator can effectively control the process. IC 8051 or any other microcontroller can effectively monitor and control the whole process. The output of all the sensors are signal conditioned. Since each sensor monitors only one point or value, comparators are used to give a high or low signal depending on the status of each chamber. This eliminates the use of an ADC. A 4:1 digital multiplexer is used to sequentially select the respective sensor and corresponding parameter of process by an 8 bit microcontroller. The microcontroller is programmed and the algorithm for this program is explained in the proceeding section.
- 3. IJRET: International Journal of Research in Engineering and Technology eISSN: 2319-1163 | pISSN: 2321-7308 __________________________________________________________________________________________ Volume: 03 Special Issue: 07 | May-2014, Available @ http://www.ijret.org 96 3. ALGORITHM The complete process of separation can be put into sequential steps and are 1. Start the process 2. Open valves V2, V3, allow HCl and HNO3 at 3:1 ratio for a fixed time interval and then close 3. Mix the solution with stirrer by actuating the motor 4. Open valve V1, allow finite quantity of e-waste and then close 5. Mix the solution and e-waste with stirrer by actuating the motor 6. Switch on S1 and monitor for no fizzing sound and dark green liquid. 7. When S1 is low switch-off stirrer motor 8. Open valve V4 for a fixed time interval and then close 9. Open valve V5 for a fixed time interval and then close 10. Monitor S2 for no fizzing sound 11. When S2 goes low, open valve V6 a fixed time interval and then close 12. Open valve V7 for a fixed time interval and then close 13. Monitor S3 for brown precipitate 14. When S3 goes low, open valve V8 for a fixed time interval and then close 15. Open valve V9 a fixed time interval and then close 16. Monitor S4 for muddy brown precipitate 17. When S4 goes low, open valve V10 to transfer the compound to next chamber and then close 18. Rinse the mud 3-4 times using water shower 19. Open valve V11 to allow heating and then close 20. Switch on the heater to heat the mud 21. Heat until Molten Gold is obtained 4. FLOWCHART Yes Is S1 low? Open Valve V1 for fixed time and close A Open Valve V2, V3 for fixed time and close close Start the motor assisted stirrer Start Open Valve V4 for fixed time and close No A Open Valve V9 for fixed time and close Yes Open Valve V7 for fixed time and close Open Valve V8 for fixed time and close Is S3 low? Yes Is S2 low? Open Valve V6 for fixed time and close Yes Open Valve V10 for fixed time and close Rinse 3-4 times Yes Open Valve V11 for fixed time and close Heat the Mud Stop Molten Gold Open Valve V5 for fixed time and close Is S4 low?
- 4. IJRET: International Journal of Research in Engineering and Technology eISSN: 2319-1163 | pISSN: 2321-7308 __________________________________________________________________________________________ Volume: 03 Special Issue: 07 | May-2014, Available @ http://www.ijret.org 97 5. CONCLUSIONS The aquaregia solution method of extraction can be easily automated for precise and faster extraction. The steps and procedures that are followed and practiced are sequential in nature and hence a microcontroller based automatic extraction method is feasible and possible. REFERENCES [1] Lim Fung Chen, Haw Wai Yee, “E-waste Management:Are we ready for it?, A study on the awareness of COIT students toward e-waste management” Proceedings of the 5th International Conference on IT & Multimedia at UNITEN (ICIMU 2011) Malaysia,14 – 16 November 2011 [2] R. Widmer, et aI., "Global perspectives on e waste," Environmental impact assessment review, vol. 25, p. 436, 2005 [3] Z. Gongming, L. Zhihua, and Z. Xulu, “Experimental Study on Metal Recycling from Waste PCB,” in Proc. Int. Conf. Sustainable Solid Waste Management, Chennai, India, 2007, pp. 155-162 [4] Youssef. Chehade,et al “Recovery of Gold, Silver, Palladium, and Copper from Waste Printed Circuit Boards”, International Conference on Chemical, Civil and Environment engineering (ICCEE'2012) March 24- 25, 2012 Dubai [5] S. R. Izatt, et al., “Sustainable Recycling of Precious Metals,” presented at the International Precious Metals Institute 36th Annual Conf., Las Vegas, Nevada, Jun. 9-12, 2012 [6] Li Jing-Ying,Huang Lu, “The Leaching Gold and Silver from E-waste by LSSS Method”, Bioinformatics and Biomedical Engineering (iCBBE), 2010 4th International Conference on Digital Object Identifier: 10.1109/ICBBE.2010.5517461, Publication Year: 2010. [7] http://en.wikipedia.org/wiki/Aqua_regia or aquaregia method and application notes [8] Antrekowitsch H., Potesser M., Spruzina W. et al. “Metallurgical recycling of electronic scrap [J]”. The Minerals, Metals & Materials Society, Vol.58, 2006, pp.899-908. [9] J. Cui, and L. Zhang, “Metallurgical recovery of metals from electronic waste: A review,” Journal of Hazardous Materials, vol. 158, pp. 228-256, 2008. [10] Kenneth J. Ayala, “The 8051 Microcontroller”, Cengage Delmar Learning India Pvt. Ltd., Edition 3, 2012. BIOGRAPHIES Rohini Hongal is a 8th semester B.E student in BEC, Bagalkot. Her interested areas are instrumentation and embedded systems. Shruti Gombi is a 8th semester B.E student in BEC, Bagalkot. Her interested areas are instrumentation and embedded systems. Rohankumar Patil is a 8th semester B.E student in BEC, Bagalkot. His interested areas are instrumentation and VLSI design. Krishnamurthy Bhat, is working as Head of Dept. of Inst.Tech. in Basaveshwar Engg. College, Bagalkot, Karnataka since 2007 He has 22 years of teaching experience. His fields of interest are sensor design and development, electronic hardware and virtual instrumentation.