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Calculators Created by Abhishek Dharmendra Bansile
Abhishek Dharmendra Bansile
Vishwakarma Institute of Information Technology, Pune
(VIIT Pune)
,
Pune
https://www.linkedin.com/in/abhishek-bansile-159673204
115
Formulas Created
23
Formulas Verified
31
Across Categories
List of Calculators by Abhishek Dharmendra Bansile
Following is a combined list of all the calculators that have been created and verified by Abhishek Dharmendra Bansile. Abhishek Dharmendra Bansile has created 115 and verified 23 calculators across 31 different categories till date.
Aircraft Endurance
(1)
Verified
Mach number of moving object
Go
5 More Aircraft Endurance Calculators
Go
Automobile
(1)
Verified
Wheel Flop
Go
8 More Automobile Calculators
Go
Basic Formula
(12)
Created
Clearance factor in compressor
Go
Created
Clearance Volume given Clearance Factor
Go
Created
Compression Ratio given Pressure
Go
Created
Compression Ratio given Volume
Go
Created
Discharge Pressure given Compression Ratio
Go
Created
Discharge Volume given Compression Ratio
Go
Created
Piston Displacement Volume given Clearance Factor
Go
Created
Piston Displacement Volume given Volumetric Efficiency in Compressor
Go
Created
Suction Pressure given Compression Ratio
Go
Created
Suction Volume given Compression Ratio
Go
Created
Suction Volume given Volumetric Efficiency in Compressor
Go
Created
Volumetric efficiency in compressor
Go
Basics
(2)
Verified
Declination angle
Go
Verified
Hour angle
Go
6 More Basics Calculators
Go
Basics of Ducts
(6)
Created
Equivalent Diameter of Circular Duct for Rectangular Duct when Quantity of Air is same
Go
Created
Equivalent Diameter of Circular Duct for Rectangular Duct when Velocity of Air is same
Go
Created
Quantity of Air given Velocity
Go
Created
Reynolds Number given Friction Factor for Laminar Flow
Go
Created
Reynolds Number in duct
Go
Created
Velocity Pressure in Ducts
Go
Basics of Gas Turbines
(1)
Verified
Diffuser Efficiency
Go
16 More Basics of Gas Turbines Calculators
Go
Conceptual Design
(1)
Verified
Induced Inflow Ratio in Hover
Go
23 More Conceptual Design Calculators
Go
Condensers
(5)
Created
Heat Rejection Factor
Go
Created
Heat Rejection Factor given COP
Go
Created
Load on Condenser
Go
Created
Refrigeration Capacity given Load on Condenser
Go
Created
Work done by Compressor given Load on Condenser
Go
Continuity Equation for Ducts
(4)
Created
Cross-sectional area of duct at section 1 using continuity equation
Go
Created
Cross-sectional Area of Duct at section 2 using Continuity equation
Go
Created
Velocity of air at Duct section 1 using Continuity equation
Go
Created
Velocity of air at Duct section 2 using Continuity equation
Go
Diameter of Socket Collar
(1)
Verified
Diameter of socket collar given rod diameter
Go
4 More Diameter of Socket Collar Calculators
Go
Direct Count System
(3)
Verified
Denier Count
Go
Verified
Dram Count
Go
Verified
Grex Count
Go
2 More Direct Count System Calculators
Go
Dynamic loss in ducts
(12)
Created
Dynamic Loss Coefficient given Dynamic Pressure Loss
Go
Created
Dynamic Loss Coefficient given Equivalent Additional Length
Go
Created
Dynamic Pressure loss
Go
Created
Pressure Loss at Discharge or Exit
Go
Created
Pressure loss at suction
Go
Created
Pressure loss coefficient at inlet of duct
Go
Created
Pressure loss coefficient at outlet of duct
Go
Created
Pressure Loss due to Gradual Contraction given Pressure Loss Coefficient at Section 1
Go
Created
Pressure Loss due to Gradual Contraction given Velocity of air at point 2
Go
Created
Pressure Loss due to sudden Contraction given Velocity of Air at point 1
Go
Created
Pressure Loss due to sudden Contraction given Velocity of Air at point 2
Go
Created
Pressure loss due to sudden enlargement
Go
Friction Factor
(2)
Created
Friction Factor for Laminar Flow in Duct
Go
Created
Friction Factor for Turbulent Flow in Duct
Go
Fundamentals of IC Engine
(1)
Created
Swept Volume
Go
10 More Fundamentals of IC Engine Calculators
Go
Heat Transfer in Condenser
(16)
Created
Average Coefficient of heat transfer for vapour condensing outside of horizontal tubes of diameter D
Go
Created
Heat Transfer in Condenser given Overall Heat Transfer Coefficient
Go
Created
Heat Transfer in Condenser given Overall Thermal Resistance
Go
Created
Heat transfer takes place from outside surface to inside surface of tube
Go
Created
Heat Transfer takes place from vapour refrigerant to outside of tube
Go
Created
Mean Surface area of Tube when Heat transfer takes place from outside to inside surface of tube
Go
Created
Overall Coefficient of Heat Transfer for Condensation on Vertical Surface
Go
Created
Overall Temperature difference given Heat Transfer
Go
Created
Overall Temperature difference when Heat Transfer from vapour refrigerant to outside of tube
Go
Created
Overall Temperature difference when Heat transfer takes place from outside to inside surface of tube
Go
Created
Overall thermal resistance in condenser
Go
Created
Temperature at Inside Surface of Tube given Heat Transfer
Go
Created
Temperature at Outside Surface of Tube given Heat Transfer
Go
Created
Temperature at Outside Surface of Tube provided Heat Transfer
Go
Created
Temperature of Refrigerant Vapour condensing Film given Heat Transfer
Go
Created
Thickness of Tube when Heat transfer takes places from outside to inside surface of tube
Go
Indirect Count System
(6)
Verified
Decimal Count
Go
Verified
French Count
Go
Verified
Indirect Count
Go
Verified
Metric Count
Go
Verified
Woollen Count
Go
Verified
Worsted Count
Go
Jet propulsion cycles
(1)
Verified
Velocity coefficient when nozzle efficiency is present
Go
16 More Jet propulsion cycles Calculators
Go
Load Capacities of Elements of Cotter Joint
(1)
Verified
Maximum load taken by cotter joint given spigot diameter, thickness and stress
Go
7 More Load Capacities of Elements of Cotter Joint Calculators
Go
Machining Time
(1)
Created
Cutting speed in turning
Go
7 More Machining Time Calculators
Go
Mechanical
(1)
Verified
Radius of Sphere of Influence
Go
2 More Mechanical Calculators
Go
Minimum Work Required for a Two-Stage Reciprocating Compressor
(8)
Created
Cooling ratio
Go
Created
Discharge Temperature at High Pressure Compressor given Cooling Ratio
Go
Created
Discharge Temperature at High pressure compressor when Cooling ratio is constant
Go
Created
Minimum Work required when Cooling Ratio is fixed
Go
Created
Minimum Work required when Cooling Ratio is fixed and Intercooling is Perfect
Go
Created
Minimum Work required when Temperature at end of Cooling in Intercooler is fixed
Go
Created
Suction Temperature at Low Pressure Compressor given Cooling Ratio
Go
Created
Suction Temperature at Low pressure compressor when Cooling ratio is constant
Go
Parameters
(1)
Verified
General Sewing Data
Go
11 More Parameters Calculators
Go
Power Required to Drive a Single-Stage Reciprocating Compressor
(12)
Created
Indicated Power for Double-acting Compressor
Go
Created
Indicated Power for Single-acting Compressor
Go
Created
Isentropic Power for Double-acting Compressor
Go
Created
Isentropic Power for Single-acting Compressor
Go
Created
Isentropic Work done given Isentropic Power for double-acting Compressor
Go
Created
Isentropic Work done given Isentropic Power for Single-acting Compressor
Go
Created
Isothermal Power for Double-acting Compressor
Go
Created
Isothermal Power for Single-acting Compressor
Go
Created
Isothermal Work done given Isothermal Power for Double-acting Compressor
Go
Created
Isothermal Work done given Isothermal Power for Single-acting Compressor
Go
Created
Polytropic Work done given Indicated Power for Double-acting Compressor
Go
Created
Polytropic Work done given Indicated Power for Single-acting Compressor
Go
Pressure Loss in Ducts
(5)
Created
Length of Duct given Pressure Loss due to Friction
Go
Created
Pressure drop in circular duct
Go
Created
Pressure drop in square duct
Go
Created
Pressure loss due to friction in ducts
Go
Created
Total Pressure required at Inlet to Duct
Go
Rectangular Section Is Subjected To Eccentric Load
(1)
Verified
Maximum stress when subjected to eccentric axial load
Go
21 More Rectangular Section Is Subjected To Eccentric Load Calculators
Go
Riveted Joints
(1)
Verified
Diameter of rivets for lap joint
Go
16 More Riveted Joints Calculators
Go
Volumetric Efficiency of a Reciprocating Compressor
(11)
Created
Actual volume of refrigerant
Go
Created
Actual Volume of Refrigerant given Volumetric Efficiency
Go
Created
Clearance factor
Go
Created
Clearance Volume of Compressor given Stroke Volume
Go
Created
Expanded Clearance Volume given Actual Volume of Compressor
Go
Created
Stroke Volume of Compressor
Go
Created
Stroke Volume of Compressor given Volumetric efficiency
Go
Created
Total Volume of Refrigerant in Compressor given Actual Volume
Go
Created
Total Volume of Refrigerant in Compressor given Clearance Factor
Go
Created
Total Volume of Refrigerant in Compressor given Stroke Volume of Compressor
Go
Created
Volumetric Efficiency in Compressor given Clearance Factor
Go
Width of Cotter
(1)
Verified
Width of cotter by bending consideration
Go
1 More Width of Cotter Calculators
Go
Work Done by a Two-Stage Reciprocating Compressor with Intercooler
(8)
Created
Total Work done per cycle in Compressor during Complete Intercooling given Suction Temperature
Go
Created
Total Work done per cycle in Compressor during Complete Intercooling given Suction Volume
Go
Created
Total Work done per cycle in Compressor during incomplete Intercooling given Temperature
Go
Created
Total Work done per cycle in Compressor during Incomplete Intercooling given Volume
Go
Created
Work done per cycle in High Pressure Compressor during incomplete intercooling given suction Temp
Go
Created
Work done per cycle in High pressure Compressor during incomplete intercooling given suction volume
Go
Created
Work done per cycle in Low Pressure Compressor during incomplete intercooling given Suction Temp
Go
Created
Work done per cycle in Low pressure Compressor during incomplete intercooling given suction volume
Go
Work Done by Reciprocating Compressor with Clearance Volume
(4)
Created
Suction Temperature given Work done by Compressor
Go
Created
Work done by Reciprocating Compressor given Suction Temperature
Go
Created
Work Done by Reciprocating Compressor given Volume before Compression and after Expansion
Go
Created
Work Done given Polytropic Index for Compression and Expansion
Go
Work done by Single-Stage, Single Acting Reciprocating Compressor without Clearance Volume
(8)
Created
Work done during isentropic compression
Go
Created
Work done during isentropic Compression given Specific Heat Capacity Constant Pressure
Go
Created
Work done during Isothermal Compression given Pressure and Volume Ratio
Go
Created
Work done during Isothermal Compression given Temperature and Compression Ratio
Go
Created
Work done during Isothermal Compression given Temperature and Pressure Ratio
Go
Created
Work done during Isothermal Compression given Temperature and Volume Ratio
Go
Created
Work done during Isothermal Compression given Volume and Pressure Ratio
Go
Created
Work done during polytropic compression
Go
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