Wednesday, May 29, 2013

PID Diagrams for Dummies with Examples.

Hi all,

Before you read this post it is advised that you go through the post where we have discussed about various symbols that are used to make P&ID diagrams.
Now we have understood the symbols let us know see how P&ID diagrams are created and how processes are implemented using P&ID diagrams. This convention simplifies the many control devices that need to be used. For the sake of brevity, sensors, transmitters, indicators, and controllers will all be labeled on a P&ID as a controller. The type of controller specified (i.e. temperature or level) will depend on the variable one wished to control and not on the action needed to control it.

For instance, consider if one must control the temperature of fluid leaving a heat exchanger by changing the flow rate of cooling water. The actual variable to be controlled in this case is temperature, and the action taken to control this variable is changing a flow rate. In this case, a temperature controller will be represented schematically on the P&ID, not a flow controller. Adding this temperature controller to the P&ID also assumes that there is a temperature sensor, transmitter, and indicator also included in the process.
PID - control designation.png
As you can see on the P&ID above, these controllers are represented as circles. Furthermore, each controller is defined by what it controls, which is listed within arrow boxes next to each controller. This simplifies the P&ID by allowing everyone the ability to interpret what each controller affects. Such P&IDs can be constructed in Microsoft Office Visio.

Sample Diagram

Below is a sample P&ID Diagram that is actually used in an industrial application. It is clearly more complicated than what has been detailed above, however, the symbols used throughout remain the same.
Table 10: Sample P&ID Diagram SampleP&ID.JPG

Example 1

Describe the following controlled process in words:

Teamnex1b.jpg

Answer: Reactants enter a jacketed CSTR where a reaction takes place and the products exit. The reactor is cooled via a coolant water stream. The temperature inside the reactor vessel is monitored with a temperature controller (also contained in the controller is a sensor, indicator, and transmitter), which electrically controls a valve. The valve can alter the flowrate of the coolant water stream, thereby controlling the temperature inside the reactor. A pressure controller is also present which feeds back to an inlet valve. Therefore, we can deduce that this reaction is most likely gas phase and if the CSTR becomes too full (high pressure) the inlet valve will close.

Example 2

Draw a proper P&ID diagram of the following process:

A storage tank is filled with condensed products formed via the CSTR in Example 1. The tank contains a level controller at a set point on the top of the tank. If this tank were to fill, materials would get clogged up in the reactor. Therefore, if the tank reaches 90% of its total capacity, the level controller will send an electric signal, which opens an emergency drainage line located at the bottom of the tank. The level controller will also activate an alarm alerting plant engineers that there is a problem with the storage tank. Finally, the level controller will also close the inlet valve to the storage tank.

Teamnex2c.jpg

Example 3

Below is a P&ID diagram of the transesterification process to produce biodiesel. Soybean oil, methanol, and the sodium methoxide catalyst are pumped in to the reactor. The temperature of the reactor is regulated by the circulation water. The resulting biodiesel is then pumped out of the reactor and goes on to other processes so that it can be sold. Below is a P&ID of the process that is missing the valves, pumps, and sensors. Add the pumps, sensors, and valves that are needed to successfully control the process.
Wiki.jpg
Solution:
Wiki sol.jpg


Example 4

Below is a example problem of a typical P&ID problem. A is a liquid at Tamp but boils at Trx. B and P are high boiling point liquids and C is a solid. The reaction for the process is 2A+B+C-->P at Trx. Ais fed in excess.

Che466control.jpg
Below is the solution to the problem above.
Che466solution.jpg


How to read PID Diagrams (Understanding the symbols)

 How to read PID Diagrams (Understanding the symbols)


Hi all,

This is the part 1 of the tutorial on How to read PID diagrams. In order to understand a diagram one should know what every symbols signifies so that it can be understood and used properly lets start with all the symbols in part 1.

 Lines

Line symbols are used to describe connectivity between different units in a controlled system. Below is the list of most commonly used lines in a PID Diagram.

 Each and every line has a different meaning kindly observe the differences keenly.

the "main process" refers to a pipe carrying a chemical. "Insulated" is straightforward, showing that the pipe has insulation. "Trace heated" shows that the pipe has wiring wrapped around it to keep the contents heated. "Lagged" indicates on a P&ID that the pipe is wrapped in a cloth or fiberglass wrap as an alternative to painting to improve the appearance of the pipe see here for more information. The last column in Table 1 shows pipes that are controlled by a controller. "Electrical impulse" shows that the manner in which information is sent from the controller to the the pipe is by an electrical signal, whereas "pneumatic impulse" indicates information sent by a gas.
In addition to line symbols, there are also line labels that are short codes that convey further properties of that line. These short codes consist of: diameter of pipe, service, material, and insulation. The diameter of the pipe is presented in inches. The service is what is being carried in the pipe, and is usually the major component in the stream. The material tells you what the that section of pipe is made out of. Examples are CS for carbon steel or SS for stainless steel. Finally a 'Y' designates a line with insulation and an 'N' designates one without it. Examples of line short codes on a P&ID are found below in Figure A.
PID - line labeling.png
Figure A: Line Labels
This is useful for providing you more practical information on a given pipe segment.
For example in stream 39 in Figure A, the pipe has a 4" diameter, services/carries the chemical denoted 'N', is made of carbon steel, and has no insulation.

Identification Letters

The following letters are used to describe the control devices involved in a process. Each device is labeled with two letters. The first letter describes the parameter the device is intended to control. The second letter describes the type of control device.
Table 2: First Identification Letter
TeamNfirstletter.gif
Table 3: Second Identification Letter
TeamNsecondletter.gif

For example, the symbol “PI,” is a “pressure indicator.”

Valve Symbols

The following symbols are used to represent valves and valve actuators in a chemical engineering process. Actuators are the mechanisms that activate process control equipment.

Table 4: Valve Symbols
Valves.gif
Table 5: Valve Actuator Symbols
Actuators.gif

The following page offers an overview of different industrial valve types.

General Instrument or Function Symbols

Instruments can have various locations, accessibilities, and functionalities in the field for certain processes. It is important to describe this clearly in a P&ID. Below is a table of these symbols commonly used in P&IDs.
FunctionSymbols.jpg
Discrete instruments are instruments separate or detached from other instruments in a process. Shared display, shared control instruments share functions with other instruments. Instruments that are controlled by computers are under the "computer function" category. Instruments that compute, relay, or convert information from data gathered from other instruments are under the "Programmable logic control" section.
For example, a discrete instrument for a certain process measures the flow through a pipe. The discrete instrument, a flow transmitter, transmits the flow to a shared display shared control instrument that indicates the flow to the operator. A computer function instrument would tell the valve to close or open depending on the flow. An instrument under the "Programmable logic control" category would control the valve in the field if it was pneumatically controlled, for instance. The instrument would gather information from discrete instruments measuring the position of the actuator on the valve, and would then adjust the valve accordingly.
In the chart above, it is necessary to know where the instrument is located and its function in order to draw it correctly on a P&ID. A primary instrument is an instrument that functions by itself and doesn't depend on another instrument. A field mounted instrument is an instrument that is physically in the field, or the plant. Field mounted instruments are not accessible to an operator in a control room. An auxiliary instrument is an instrument that aids another primary or auxiliary instrument. Primary and auxiliary instruments are accessible to operators in a control room.

Transmitter Symbols

Transmitters play an important role in P&IDs by allowing the control objectives to be accomplished in a process. The following are commonly used symbols to represent transmitters.

Below are three examples of flow transmitters. The first is using an orifice meter, the second is using a turbine meter, and the third is using an undefined type of meter.

Table 6: Transmitter Symbols
Sensortable1.gif


The location of the transmitter depends on the application. The level transmitter in a storage tank is a good example. For instance, if a company is interested in when a tank is full, it would be important for the level transmitter to be placed at the top of the tank rather than the middle. If the transmitter was misplaced in the middle because a P&ID was misinterpreted then the tank would not be properly filled. If it is necessary for the transmitter to be in a specific location, then it will be clearly labeled.

Miscellaneous Symbols

The following symbols are used to represent other miscellaneous pieces of process and piping equipment.

Table 7: Process Equipment
Equipment 1.gif
Equipment 3.gif
Equipment.gif

Table 8: Line Fittings
Line fittings.gif

Table 9: Pipe Supports
Pipe supports.gif

Sunday, April 7, 2013

JOBS JOBS JOBS they are nowhere to be found.

Hi all,
The scenario today is very very bad please make the fullest use of all the opportunities that you get.Please enhance your skills and keep yourself updated about things happening around you.Prepare for various govt exams and jobs.They pay you good and are secure and reliable compared to others.Please share your knowledge with others too. It will help
God bless us all.....:)

Monday, March 4, 2013

LIC AAO 2013 Exams Reasoning and Numerical Ability sample solved paper.


LIC AAO Numerical Ability Objective Solved Question Paper




1. In a division sum, the divisor is 10 times the quotient and 5 V times the remainder. If the
remainder is 46, the dividend is:
(1) 4236
(2) 4306
(3) 4336
(4) 5336
Ans. (4)

2. 15 men take 21 days of 8 hours each to do a piece of work. How many days of 6 hours
 each would 21 women take, if 3 women do as much work as 2 men?
(1) 18
(2) 20
(3) 25
(4) 3
Ans. (4)

3. The mean temperature of Monday to Wednesday was 37°C and of Tuesday to Thursday
 was 34° C. If the temperature on Thursday was 4/5th that of Monday, then what was the
temperature on Thursday?
(1) 36.5°C
(2) 36°C 
(3) 35.5°C
(4) 34°C
Ans. (2)

4. On 1st January every year, a person buys N.S.C. (National Savings Certificates) of
 value exceeding that of his last year’s purchase by Rs. 100. After 10 years he finds that
 the total value of the certificates held by him is Rs.54.500. Find the value (in Rupees)
of the certificates purchased by him in the first year? Hint: consider NSC gives a return
 at the rate of 8.00 % per annum.
(1) 4,000
(2) 4,800
(3) 5,000
(4) 6,000
Ans. (3)

5. An employee may claim Rs. 7.00 for each km when he travels by taxi and Rs. 6.00
 for each km if he drives his own car. If in one week he claimed Rs. 675 for traveling
90km, how many kms did he travel by taxi?
(1) 135
(2) 155
(3) 162
(4) 170
Ans. (1)


6. A certain number of two digits is three times the sum of Its digits. If 45 be added
to it, the digits are reversed. The number is
(1) 72
(2) 32
(3) 27
(4) 23
Ans. (3)


7. On a Rs.10, 000 payment order, a person has choice between 3 successive
discounts of 10%, 10% and 30%, and 3 successive discounts of 40%, 5% and
 5%. By choosing the better one he can save (in Rupees):
(1) 200
(2) 255
(3) 400
(4) 433
Ans. (2)


8. A, B and C started a business with their investment in the ratio l: 3:5. After
4 months, A invested the same amount as before and B as well as C withdrew
 half of their Investments. The ratio of their profits at the end of the year was:
(1) 5: 6: 10
(2) 6: 5: 10
(3) 10:5:6
(4) 4:3:5
Ans. (1)

9. Three pipes A, B and C can fill a cistern in 6 hours. After working at it
 together for 2 hours, C is closed and A and B can fill the remaining part in
 7 hours. The number of hours taken by C alone to fill the cistern is:
(1) 12
(2) 14
(3) 16
(4) 18
Ans. (2)


10. River is running at 2 kmph. It took a man twice as long to row up as to
row down the river. The rate (in km ph) of the man in still water is:
(1) 8
(2) 10
(3) 4
(4) 6
Ans. (4)


11. A sum of money becomes Rs.13, 380 after 3 years and Rs. 20.070 after
 6 years on compound interest. The sum (in Rupees) is:
(1) 8800
(2) 8890
(3) 8920
(4) 9040
Ans. (3)

12. A rectangular carpet has an area of 120sq. metres and a perimeter of 46
 metres. The length of its diagonal (in metres) is:
(1) 11
(2) 13
(3) 15
(4) 17
Ans. (4)

13. Three yeas ago the average age of A and B was 18 years. While C Joining
them now, the average becomes 22 years. How old (in years) is C now?
(1) 24
(2) 27
(3) 28
(4) 30
Ans. (1)

14. A man’s basic pay for a 40 hours’ week is Rs. 200. Overtime Is paid at
25% above the basic rate. In a certain week, he worked overtime and his
 total was Rs. 300. He therefore worked for a total of (in hours):
(1) 52  
(2) 56
(3) 58
(4) 62
Ans. (2)

15. Rs. 600 are divided among A, B and C so that Rs. 40 more than 2/5th
 of A’s share, Rs. 20 more than 2/7th of B’s share and Rs.10 more
than 9/17th of C’s may all be equal. What is A’s share (in Rupees)?
(1) 150
(2) 170
(3) 200 
(4) 280
Ans. (1)

16. A train B speeding with 120 kmph crosses another train C running in the
 same direction, in 2 minutes. If the lengths of the trains B and C be l00m
 and 200m respectively, what is the speed (In kmph) of the train C?
(1) 111
(2) 123
(3) 127
(4) 129
Ans. (1)

17. A merchant has 1000 kg of sugar, part of which he sells at 8% profit
and the rest at 18% profit. He gains 14% on the whole. The quantity (in kg.)
sold at l8% profit is:
(1) 560
(2) 600
(3) 400
(4) 640
Ans. (2)

18. A well with 14m inside diameter is dug l0m deep. Earth taken out of it,
 has been evenly spread all around it to a width of 2lm to form an embankment
. The height (in metres) of the embankment is:
(1) ½
(2) 2/3
(3) ¾
(4) 3/5
Ans. (2)

19. What are the total marks obtained by L in History, Geography and Mathematics?
(1) 221.8
(2) 253
(3) 180.2
(4) 184
(5) None of these
Ans. (3)

20.  What is the percentage of candidates qualified in. 1998 and
1999 together from all the States over the candidates appeared
 from all the States in these two years
(the value upto two decimal points)?
(1) 10.84
(2) 10.32
(3) 10.62
(4) 10.34
(5) None of these
Ans. (4)

21. What approximately is the percentage of candidates qualified
 from States C and D together over the candidates appeared from these two States in 1997?
(1) 10
(2) 12.5
(3) 15
(4) 20
(5) 9.5
Ans. (1)

22. I. 2x2 - 7x + 6=0
II. 4y2 =9
Ans. (5)


23. I. 4x2 =49
II. 9y2 – 66y + 121=0
Ans. (1)

24. I. 9x2 – 18x + 5= 0
II. 2y2 – 9y + 10 =0
Ans. (1)

25. If the income of Company A had increased by, 10% in year
 2000 from year 1999 and profit earned in 1999 was 20% what
was its expenditure in 1999? (The value upto two decimal
places in crores)
(1) 36.36
(2) 32.32
(3) 30.30
(4) Can’t be determined
(5) None of these
Ans. (5)

God bless us all.....:)