Explain the combustion & emission characteristics of using hydrogen in CI engine

 

🔥 Combustion and Emission Characteristics of Hydrogen in CI Engines

Hydrogen is a highly efficient, clean-burning alternative fuel that can be used in modified Compression Ignition (CI) engines—typically in dual-fuel or specially adapted systems. Its unique physical and chemical properties significantly influence combustion behavior and emission output.

---

✅ Combustion Characteristics of Hydrogen in CI Engines:

Property	Description
🔥 High Flame Speed	Hydrogen has a very high laminar flame speed (~2.9 m/s), resulting in rapid and complete combustion, even at lean mixtures.
💨 Wide Flammability Range	Hydrogen burns in a very wide range of air–fuel ratios (4%–75%), allowing ultra-lean combustion, which improves thermal efficiency.
⚡ High Auto-Ignition Temperature	Around 585°C, making it difficult to ignite just by compression. Hence, pilot diesel injection is required to initiate combustion in CI engines.
🧪 Low Ignition Energy	Requires only 0.02 mJ to ignite, which enhances ignition reliability with a pilot flame or residual heat.
🌡️ High Combustion Temperature	Hydrogen burns at high flame temperatures, which leads to complete oxidation but also contributes to NOx formation.
💥 Knock Tendency	Very high flame speed and low ignition energy increase knock sensitivity. Proper timing and mixture control are essential.
🛢️ Lean Burn Capability	Efficient at very lean mixtures, which helps lower in-cylinder temperatures and reduce emissions (except NOx).

---

✅ Emission Characteristics of Hydrogen in CI Engines:

Emission	Effect of Hydrogen
🌱 CO₂ (Carbon Dioxide)	Zero CO₂ emissions when hydrogen is used alone, since no carbon is present in the fuel.
🛑 CO (Carbon Monoxide)	Negligible or zero, as combustion is complete with no carbon content.
🌫️ HC (Unburnt Hydrocarbons)	Almost none, because hydrogen does not produce hydrocarbons upon combustion.
☠️ PM (Particulate Matter)	No soot or smoke, since there’s no carbon to form particulates.
⚠️ NOx (Nitrogen Oxides)	Can be high, due to high flame temperatures and availability of oxygen. However, it can be controlled by: – Lean mixtures – Exhaust gas recirculation (EGR) – Water injection or NOx after-treatment.

---

🔄 Combustion Mode Options:

1. Dual-Fuel Mode (Diesel + Hydrogen)

   • Diesel is injected as a pilot fuel to ignite the hydrogen-air mixture.

   • Enables better control over combustion timing.

   • Suitable for retrofitting existing CI engines.

2. Dedicated Hydrogen CI Mode (Advanced Research)

   • Requires modified compression ratio, spark or glow plug assist, and precise timing control.

   • Rare in commercial applications due to technical complexity.

---

🧠 Summary Table:

Characteristic	Hydrogen in CI Engine
Flame Speed	Very High – fast combustion
Ignition Temperature	High – needs pilot fuel or ignition assist
Knock Tendency	High – requires control of timing and AFR
CO₂ Emissions	Zero
CO / HC / PM	Negligible / Zero
NOx Emissions	High (due to high flame temp) – needs control
Overall Efficiency	High – especially in lean-burn operation

---

✅ Conclusion:

Hydrogen offers excellent combustion properties for CI engines, including fast, clean, and complete burning. It leads to zero carbon emissions, but controlling NOx becomes critical due to high combustion temperatures. With proper engine modifications and management systems, hydrogen can be a viable and eco-friendly fuel for future CI engine applications.

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What modifications are required in CI engine to use gaseous fuels? Explain ?

 

🔧 Modifications Required in CI Engines to Use Gaseous Fuels

Compression Ignition (CI) engines are originally designed to operate on liquid diesel fuel, which ignites by compression-induced auto-ignition. To use gaseous fuels (like CNG, LPG, biogas, or hydrogen), certain modifications are necessary because most gaseous fuels have different combustion properties, especially in terms of auto-ignition temperature and ignition delay.

---

✅ Common Gaseous Fuels Used:

• CNG (Compressed Natural Gas)

• LPG (Liquefied Petroleum Gas)

• Hydrogen

• Biogas

---

🔄 Types of Conversion Methods:

There are two primary methods to modify a CI engine for gaseous fuels:

1. Dual-Fuel Operation (Diesel + Gas):

• The engine runs on a mixture of diesel and gaseous fuel.

• Diesel acts as the pilot fuel to ignite the gas–air mixture.

2. Spark-Ignition Conversion:

• The engine is converted to a spark-ignition system.

• Used for 100% gaseous fuel operation, but involves more extensive modifications.

---

🔧 Key Modifications Required:

Component	Modification/Adaptation
🛢️ Fuel Supply System	- Add gas storage tanks (CNG cylinders, LPG tanks, etc.)- Install pressure regulators, filters, and pipelines.- Include safety shut-off valves.
🔄 Fuel Mixing System	- Introduce gas mixing unit (mixer or carburetor) to blend gas with air.- Use electronic gas injectors for precise control (in advanced systems).
🔥 Ignition System	- In dual-fuel: retain diesel injector for pilot injection.- In spark-ignition conversion: install spark plug, ignition coil, and timing system.
🧠 Engine Control System	- Modify ECU/ECM to handle gas injection timing, throttle control, and pilot injection (if needed).- Add knock sensors for safety.
🛠️ Compression Ratio	- May need to reduce compression ratio if gas has high knock sensitivity (especially for LPG or CNG in full-conversion).
🔄 Valve Timing & Material	- Use valve seat hardening and heat-resistant materials, especially with dry-burning gases like hydrogen.
🌡️ Cooling System	- May need upgraded cooling due to higher combustion temperatures in some gases (e.g., hydrogen, biogas).

---

⚙️ Working of a Dual-Fuel CI Engine:

1. Air and gas are mixed (externally or via manifold injection).

2. The mixture enters the cylinder during the intake stroke.

3. A small quantity of diesel (pilot fuel) is injected near the end of compression.

4. The diesel auto-ignites, which in turn ignites the gas–air mixture.

5. Combustion occurs as in conventional CI engines.

---

✅ Advantages of Using Gaseous Fuels in CI Engines:

• Cleaner combustion: lower CO, HC, and PM emissions

• Reduced fuel cost (especially CNG or biogas)

• Better fuel-air mixing and smoother operation

• Renewable fuel use (biogas, hydrogen)

---

❌ Challenges:

• Slight power loss (due to lower energy density of gases)

• Detonation/knock risk (especially with hydrogen or LPG)

• Needs precise control of air–fuel ratio and timing

• Storage and safety systems must be robust

---

🧠 Conclusion:

To use gaseous fuels in a CI engine, fuel supply, combustion system, ignition, and controls must be modified. The level of modification depends on whether dual-fuel or spark-ignition conversion is chosen. With proper engineering, CI engines can efficiently run on gaseous fuels, offering cost and environmental benefits.

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List down the advantages and disadvantages of using bio diesel in CI engines

 

✅ Advantages and Disadvantages of Using Biodiesel in CI Engines

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✅ Advantages of Biodiesel in CI (Compression Ignition) Engines:

Advantage	Description
🌱 Renewable Source	Produced from vegetable oils, animal fats, or waste cooking oil, making it sustainable.
🛢️ Reduces Fossil Fuel Dependence	Decreases reliance on petroleum diesel, supporting energy security.
💨 Lower Emissions	Produces lower CO, HC, and PM (particulate matter) emissions than regular diesel.
♻️ Biodegradable & Non-Toxic	Less harmful to the environment in case of spills or leaks.
🔥 Higher Cetane Number	Biodiesel typically has a higher cetane number (better combustion quality) than petroleum diesel.
🛠️ Lubricity Enhancement	Improves fuel system lubrication, reducing engine wear, especially in low-sulfur diesel systems.
🏭 Compatible with Existing Engines	Can be used in existing diesel engines without major modifications (especially blends like B20).

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❌ Disadvantages of Biodiesel in CI Engines:

Disadvantage	Description
❄️ Poor Cold Flow Properties	Biodiesel has higher cloud and pour points, leading to gelling in cold climates.
🧪 Oxidation Stability	Prone to oxidation and degradation during storage; may form gums and sediments.
🧼 Solvent Nature	Cleans fuel lines and tanks, which can clog filters initially due to loosened deposits.
🚫 Lower Energy Content	Has about 8–10% lower energy content than diesel, leading to slightly reduced power and mileage.
💧 Water Absorption	Hygroscopic nature causes water absorption, which can lead to corrosion and microbial growth.
🧯 Increased NOx Emissions	May result in slightly higher NOx emissions compared to diesel due to oxygen content and combustion temperature.
💸 Higher Production Cost	Depending on feedstock and scale, biodiesel can be more expensive than conventional diesel.

---

✅ Conclusion:

Biodiesel is a promising alternative fuel for CI engines, offering environmental and performance benefits. While it is cleaner and renewable, challenges like cold flow issues, storage stability, and cost must be addressed for wider adoption, especially in colder or cost-sensitive regions.

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Discuss the salient properties of hydrogen as a fuel

 

🔥 Salient Properties of Hydrogen as a Fuel

Hydrogen is a clean, efficient, and renewable energy carrier that can be used in internal combustion engines and fuel cells. It is gaining attention as an alternative fuel due to its zero carbon emissions when burned or used in a fuel cell.

---

✅ 1. High Energy Content

• Energy per unit mass: ~120 MJ/kg (almost 3 times that of gasoline: ~44 MJ/kg)

• Very high calorific value makes it an excellent energy source.

---

✅ 2. Wide Flammability Range

• Flammable limits in air: 4% to 75% by volume

• Allows combustion in a wide range of air–fuel mixtures, giving flexibility in engine operation.

---

✅ 3. High Flame Speed

• Flame speed: ~2.9 m/s (compared to gasoline ~0.37 m/s)

• Leads to faster combustion, allowing for lean burn operation and improved efficiency.

---

✅ 4. Clean Combustion

• Produces only water vapor (H₂O) when combusted in pure oxygen.

• In air, no CO₂ or HC emissions, only small amounts of NOx due to high flame temperature.

---

✅ 5. Low Ignition Energy

• Minimum ignition energy: ~0.02 mJ (much lower than gasoline)

• Makes hydrogen easier to ignite, even with weak spark.

---

✅ 6. Low Density (Lightest Gas)

• Gas at atmospheric conditions

• Density: 0.0899 kg/m³, very low compared to other fuels

• Needs compression or liquefaction for practical storage.

---

✅ 7. High Diffusivity

• Hydrogen diffuses rapidly in air (helps prevent local accumulation).

• But this also increases leakage risks from storage systems.

---

✅ 8. High Auto-Ignition Temperature

• Around 585°C, higher than gasoline (~280°C)

• Reduces risk of pre-ignition or knocking in IC engines.

---

✅ 9. Non-toxic and Renewable

• Hydrogen is non-toxic and environmentally friendly.

• Can be produced from renewable sources (electrolysis using solar/wind power).

---

📊 Comparison with Gasoline:

Property	Hydrogen	Gasoline
Energy per kg (MJ/kg)	~120	~44
Density (kg/m³)	~0.0899	~750
Ignition Energy (mJ)	~0.02	~0.24
Auto-ignition Temp (°C)	~585	~280
Emissions	No CO₂, HC	CO₂, HC, CO
Flammability Range (%)	4–75	1.4–7.6

---

⚠️ Challenges with Hydrogen Fuel:

• Storage and Transport: Requires high-pressure tanks or cryogenic systems.

• Leakage Risk: High diffusivity and flammability make leak detection critical.

• Infrastructure: Limited refueling stations and supply network.

• NOx Emissions: Still possible in air due to high flame temperatures.

---

✅ Conclusion:

Hydrogen offers superior energy density per mass, clean emissions, and fast combustion characteristics, making it an excellent fuel for the future. However, challenges like storage, infrastructure, and safety must be addressed to enable widespread adoption.

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draw the Indian driving cycle and explain the various stage ?

🚗 Indian Driving Cycle (IDC) – Diagram & Explanation

The Indian Driving Cycle (IDC) is a standardized test procedure used to evaluate the emission and fuel consumption of vehicles under simulated urban driving conditions in India. It reflects typical traffic patterns, including frequent starts, stops, and idling.

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📉 IDC Graph (Speed vs Time)

Below is a simplified sketch of the IDC. The graph shows vehicle speed (km/h) on the Y-axis and time (seconds) on the X-axis.

Speed (km/h)
  |
  |          ___      ___
  |         |   |    |   |___         ___
  |         |   |    |     | |___    |   |
  |         |   |    |     |    |___ |   |__
  |_________|   |____|     |____|   ||      |___
 0|________________________________________________ Time (s)
   0    40   80  120  160  200  240  280     320   340

Legend:
- Speed fluctuates between 0 to ~40 km/h
- Several idling phases (flat near 0 km/h)
- Total duration: ~340 seconds
- Total distance covered: ~1 km

---

🧩 Phases of Indian Driving Cycle (IDC):

The IDC is divided into 2 parts:

---

🔹 Part 1 – Idling and Acceleration Cycles:

• Duration: ~195 seconds

• Distance: ~0.5 km

• Stages Include:

  1. Initial Idling (11s) – Engine ON, speed = 0.

  2. Acceleration to 15, 25, and 40 km/h – Simulates urban speed changes.

  3. Short cruising periods – Constant speed phases.

  4. Frequent deceleration to 0 – Simulates stops at signals or junctions.

  5. Repeated idle-stop-run patterns.

---

🔹 Part 2 – Higher Load Conditions:

• Duration: ~145 seconds

• Distance: ~0.5 km

• Stages Include:

  1. Higher acceleration phases

  2. Short bursts to 40 km/h

  3. Rapid deceleration

  4. Idle periods interspersed

• This part replicates busier traffic or medium-speed roads.

---

🧾 Key Parameters of IDC:

Parameter	Value
Total Duration	~340 seconds
Total Distance	~1.0 km
Maximum Speed	~42 km/h
Average Speed	~19 km/h
Number of Stops	~10
Purpose	Emission & mileage testing

---

✅ Why IDC Is Important:

• Used by Automotive Research Association of India (ARAI).

• Represents typical Indian driving conditions.

• Used for certifying BS-IV/BS-VI emission norms.

• Helps manufacturers calibrate engine and fuel systems accordingly.

---

🧠 Conclusion:

The Indian Driving Cycle (IDC) provides a realistic simulation of urban Indian traffic for lab testing of vehicle emissions and fuel efficiency. It emphasizes frequent acceleration, idling, and low-speed operation, mirroring actual road conditions in Indian cities.

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with help of a sketch desirable the principles of operations of FID analyser ?

 

🔍 Flame Ionization Detector (FID) – Principle of Operation with Sketch

The Flame Ionization Detector (FID) is a device used to measure the concentration of unburned hydrocarbons (UHC) in engine exhaust gases. It is highly sensitive and widely used in emission testing labs for Spark Ignition (SI) engine analysis.

---

✅ Basic Principle:

• Hydrocarbons, when burned in a hydrogen flame, produce ions and electrons.

• These ions are collected by electrodes and produce a small current.

• The current is directly proportional to the concentration of hydrocarbons in the sample.

---

🧪 Working Process:

1. Fuel (H₂) and Air are supplied to the burner to create a clean flame.

2. Exhaust gas sample is injected into this flame.

3. Hydrocarbons in the sample ionize in the flame:

   $$\text{CH}_x + O₂ \rightarrow \text{CO}_2 + \text{H}_2\text{O} + \text{ions/electrons}$$

4. A polarizing voltage is applied between electrodes.

5. The generated ions/electrons are collected, resulting in an electric current.

6. The current (picoamperes to nanoamperes) is amplified and displayed as HC concentration (ppm).

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✍️ Sketch of FID Analyzer:

Here's a labeled conceptual diagram:

          Exhaust Gas Sample
                   ↓
            ┌────────────┐
            │   Sample   │
            │   Injector │
            └────┬───────┘
                 ↓
        ┌─────────────────────┐
        │     Hydrogen + Air  │
        │      Burner (Flame) │
        └────────┬────────────┘
                 ↓
          ┌────────────┐
          │   Ionization│
          │   Region    │
          └────┬───────┘
     (Electrode + Collector Plates)
        (+)           (–)
          │           │
         [Current measured by]
        ┌────────────┐
        │ Amplifier  │
        └────┬───────┘
             ↓
       HC Reading (ppm)

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📌 Key Features:

Feature	Description
Sensitivity	Detects HC levels as low as 1 ppm
Response Time	Fast – in milliseconds
Selectivity	Responds mainly to hydrocarbons
Limitation	Does not detect CO, CO₂, NOx, or O₂

---

✅ Applications:

• Engine exhaust HC measurement

• Environmental monitoring

• Fuel system leak detection

• Emission certification and regulatory compliance

---

🧠 Summary:

The FID operates by burning hydrocarbons in a hydrogen flame, ionizing them, and measuring the resulting current. It is highly accurate for hydrocarbon measurement, making it essential for engine emission diagnostics.

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why three way catalytic converter are employed in modern IC engine driven vehicles So the plate of pollution vs air fuel ratio and conversion efficiency vs air fuel ratio for all To major pollutants SI engines?

 

Why Three-Way Catalytic Converters (TWC) Are Used in Modern IC Engine Vehicles

A Three-Way Catalytic Converter (TWC) is employed in modern SI engine-driven vehicles primarily to simultaneously reduce all three major pollutants in the exhaust:

1. CO (Carbon Monoxide)

2. HC (Unburned Hydrocarbons)

3. NOx (Oxides of Nitrogen)

---

Functions of a TWC:

• Oxidation of CO → CO₂

  $$2CO + O₂ \rightarrow 2CO₂$$

• Oxidation of HC → CO₂ + H₂O

  $$CₓHᵧ + O₂ \rightarrow CO₂ + H₂O$$

• Reduction of NOx → N₂ + O₂

  $$2NO \rightarrow N₂ + O₂$$

---

Why It’s Called “Three-Way”:

It performs three reactions simultaneously:

• 2 oxidation reactions (for CO and HC)

• 1 reduction reaction (for NOx)

But for the TWC to work effectively, the air-fuel ratio (A/F ratio) must be kept very close to stoichiometric (≈ 14.7:1 for gasoline) using a closed-loop control system with oxygen sensors (lambda sensors).

---

Air-Fuel Ratio vs Pollutant Emissions Chart (Qualitative)

Below is a simplified conceptual chart of pollution vs. air-fuel ratio:

Emissions vs. Air-Fuel Ratio
|
|          NOx
|          /\
|         /  \
|        /    \
|       /      \
|------/--------\----- A/F Ratio (14.7)
|     /          \    \
|    /            \    \
|   /              \    \
|  /                \    \
| CO                  \    HC
|----------------------------->
     Rich             Lean

• CO and HC are high on rich side (A/F < 14.7).

• NOx peaks at stoichiometric or slightly lean conditions (A/F ~14.7–15.5).

• Best compromise point is at stoichiometric ratio, where the TWC can act on all pollutants effectively.

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Conversion Efficiency vs Air-Fuel Ratio

This graph shows how effective the catalytic converter is at different A/F ratios:

Conversion Efficiency (%)
|
|        NOx
|       /‾‾‾\
|      /     \
|-----/       \----- A/F Ratio (14.7)
|    /         \    CO, HC
|   /           \   /
|  /             \ /
| /               /
|/               /
|---------------------->
   Rich       Stoichiometric      Lean

• Maximum conversion efficiency for all three pollutants occurs around stoichiometric (λ = 1).

• If the mixture is too rich: high CO and HC, poor NOx reduction.

• If the mixture is too lean: high NOx, poor CO and HC conversion.

---

Conclusion:

Modern IC engines use Three-Way Catalytic Converters because:

• They are most effective when A/F ratio is precisely controlled near stoichiometric.

• They significantly reduce CO, HC, and NOx emissions simultaneously.

• They are essential for meeting strict emission norms like Bharat Stage VI / Euro 6.

Therefore, engine control units (ECUs), oxygen sensors, and TWC together form a closed-loop emission control system in modern SI engine vehicles.

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explain the mechanism of formation of COUPHC and NOx emissions ?

 

Mechanism of Formation of Emissions in IC Engines

In internal combustion engines (both SI and CI), incomplete and high-temperature combustion processes lead to the formation of harmful emissions. The major pollutants are:

• CO – Carbon Monoxide

• UHC – Unburned Hydrocarbons

• NOx – Oxides of Nitrogen

---

1. Formation of CO (Carbon Monoxide):

Mechanism:

• CO is formed when there is incomplete combustion of fuel due to insufficient oxygen.

• In a rich mixture (more fuel than air), not all carbon gets oxidized to CO₂. Instead:

$$\text{C (from fuel)} + \frac{1}{2}O_2 \rightarrow CO$$

Causes:

• Rich air-fuel mixtures (especially in SI engines at full throttle)

• Poor mixing in CI engines

• Inadequate combustion time

• Low combustion temperatures

---

2. Formation of UHC (Unburned Hydrocarbons):

Mechanism:

• Hydrocarbons (HCs) are part of fuel that fail to burn or partially burn.

• They escape the combustion process and appear in the exhaust.

Key Sources:

• Crevice volumes: Fuel-air mixture gets trapped in small gaps (e.g., piston ring grooves) and escapes combustion.

• Wall quenching: Flame extinguishes near the cooler cylinder walls before complete combustion.

• Incomplete combustion during cold starts or misfires.

• Fuel impingement: In CI engines, some fuel hits cylinder walls or piston crown and doesn't vaporize properly.

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3. Formation of NOx (Oxides of Nitrogen):

Mechanism:

• NOx (mostly NO and NO₂) is formed due to high-temperature oxidation of nitrogen in the intake air.

• Follows the Zeldovich Mechanism, which occurs significantly above 1800°C:

$$\text{N}_2 + O \rightarrow NO + N \\ \text{N} + O_2 \rightarrow NO + O$$

Conditions Favoring NOx Formation:

• High combustion temperatures

• High pressure and excess oxygen (lean mixtures)

• Long residence time at peak temperature

• Common in both SI (lean operation) and CI (diesel) engines

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Summary Table:

Pollutant	Cause	Engine Condition
CO	Incomplete oxidation of fuel	Rich mixtures, low oxygen
UHC	Unburned fuel	Flame quenching, misfire, cold start
NOx	High temperature oxidation of nitrogen	High combustion temp, lean mixtures

---

Conclusion:

Understanding the mechanism of emission formation helps in designing control strategies like:

• Optimizing air-fuel ratios

• Using EGR (Exhaust Gas Recirculation)

• Catalytic converters

• Improving combustion chamber design

This leads to better engine performance with reduced environmental impact.

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What do you understand by thermodynamics analysis of CI engine combustion process. Explain in detail giving a governering equations.

 

Thermodynamic Analysis of CI Engine Combustion Process

The thermodynamic analysis of a Compression Ignition (CI) engine (commonly called a diesel engine) involves understanding how pressure, temperature, volume, and heat release change during the engine cycle, especially during combustion. This analysis helps in predicting performance, efficiency, and emissions.

---

Phases of CI Engine Combustion

In a CI engine, combustion occurs in multiple stages after fuel is injected into high-temperature, high-pressure air. The main phases are:

1. Ignition Delay: Time between the start of injection and start of combustion.

2. Premixed Combustion: Rapid burning of fuel that has mixed with air during delay.

3. Diffusion Combustion: Controlled burning of remaining fuel as it mixes with air.

4. Late Combustion: Final stages of burning as pressure and temperature fall.

---

Thermodynamic Modeling of Combustion

To analyze the process, the First Law of Thermodynamics is applied to the control volume of the cylinder contents:

Governing Equation (First Law for Open System):

$$\frac{dQ}{d\theta} = \frac{dU}{d\theta} + p\frac{dV}{d\theta}$$

Where:

• $\frac{dQ}{d\theta}$ = heat released per crank angle degree

• $\frac{dU}{d\theta}$ = change in internal energy

• $p$ = cylinder pressure

• $V$ = cylinder volume

• $\theta$ = crank angle

For ideal gases:

$$dU = m c_v dT$$

So the heat release rate becomes:

$$\frac{dQ}{d\theta} = m c_v \frac{dT}{d\theta} + p\frac{dV}{d\theta}$$

This is the basic thermodynamic equation used to calculate the rate of heat release (ROHR) during combustion from in-cylinder pressure data.

---

Wiebe Function (Heat Release Model)

The Wiebe function is often used to model the fraction of fuel burned $x_b$ over crank angle $\theta$:

$$x_b(\theta) = 1 - \exp\left[-a\left( \frac{\theta - \theta_0}{\Delta \theta} \right)^m\right]$$

Where:

• $a$, $m$ = empirical constants

• $\theta_0$ = start of combustion

• $\Delta \theta$ = combustion duration

• $x_b$ = mass fraction of fuel burned

Then:

$$\frac{dx_b}{d\theta} = \text{Heat release rate (HRR) model}$$

---

Assumptions in Thermodynamic Analysis:

• Air-standard cycle or single-zone combustion.

• Ideal gas behavior.

• No mass loss or gain during combustion.

• Homogeneous air-fuel mixture (simplified case).

---

Applications of Thermodynamic Analysis:

• Estimating indicated power and efficiency.

• Designing combustion chambers.

• Predicting in-cylinder pressure and temperature profiles.

• Optimizing injection timing and fuel burn rate.

---

Conclusion:

Thermodynamic analysis of CI engine combustion provides deep insight into combustion behavior, performance, and efficiency. Using the First Law of Thermodynamics and empirical models like the Wiebe function, engineers can predict heat release, pressure variations, and optimize engine parameters for better performance and reduced emissions.

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What do you understand by turbo charging? Why SI engines are not usually turbo charged.Give the boost pressure range for SI & CI engines

 (i) Turbocharging Explanation 

Turbocharging:
Turbocharging is a method used to increase the power output of an internal combustion engine by forcing more air into the combustion chamber. A turbocharger consists of a turbine and a compressor mounted on the same shaft.

• The turbine is driven by exhaust gases from the engine.

• This drives the compressor, which compresses and forces more air into the engine’s intake manifold.

• More air means more oxygen, allowing more fuel to be burned, resulting in increased power without increasing engine size.

---

Why SI (Spark Ignition) Engines Are Not Usually Turbocharged:

1. Knocking (Pre-ignition) Risk:

   • Turbocharging increases the intake pressure and temperature, which raises the compression temperature inside the cylinder.

   • This increases the likelihood of knocking, a major issue in SI engines due to uncontrolled combustion.

2. Lower Compression Ratios Required:

   • To avoid knocking, turbocharged SI engines need lower compression ratios, which reduces their thermal efficiency at low loads.

3. Complex Fuel-Air Mixture Handling:

   • SI engines operate with a pre-mixed air-fuel charge. Compressing this mixture can lead to backfires or hot spots that cause ignition too early.

4. Cost and Complexity:

   • Turbocharging requires intercoolers, stronger pistons, and better engine management systems, making it expensive and complex, especially in smaller gasoline engines.

---

Boost Pressure Range:

Engine Type	Typical Boost Pressure Range
SI Engines	0.3 to 0.6 bar (or 4.4 to 8.8 psi)
CI Engines	0.7 to 1.5 bar (or 10.3 to 22 psi)

• CI (Compression Ignition) engines are more robust and operate with excess air, allowing higher boost pressures without knocking.

• Modern turbocharged diesel engines can handle much higher boost due to their stronger components and non-throttle operation.

---

Summary:
Turbocharging improves power output and efficiency by increasing intake air pressure. While widely used in CI engines, SI engines are less frequently turbocharged due to knocking, complexity, and thermal limitations.

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How does a lean burn engine differ from conventional engine?

 

🔍 Difference Between Lean Burn Engine and Conventional Engine

A lean burn engine is designed to operate with a leaner air-fuel mixture (i.e., more air and less fuel) than a conventional spark-ignition (SI) engine, which typically runs closer to the stoichiometric air-fuel ratio.

---

⚙️ 1. Air-Fuel Ratio (A/F Ratio)

Feature	Lean Burn Engine	Conventional Engine
Air-Fuel Ratio	Greater than 16:1 (often 20–22:1)	Around 14.7:1 (stoichiometric)
Purpose	To save fuel and reduce emissions	To ensure full combustion and power

---

🔥 2. Combustion Characteristics

Feature	Lean Burn Engine	Conventional Engine
Combustion Speed	Slower, requires better ignition control	Faster, naturally stable
Flame Propagation	May be uneven or incomplete	Complete and uniform

---

🌿 3. Emissions

Feature	Lean Burn Engine	Conventional Engine
CO₂ and HC Emissions	Lower due to less fuel	Higher due to richer mixture
NOₓ Emissions	Higher (due to higher combustion temperatures with excess oxygen)	Controlled with catalytic converters

---

⚡ 4. Fuel Economy & Efficiency

Feature	Lean Burn Engine	Conventional Engine
Fuel Efficiency	Higher	Lower
Power Output	Slightly lower at full throttle	Higher, optimized for power

---

✅ Summary

Aspect	Lean Burn Engine	Conventional Engine
A/F Ratio	Lean (> 16:1)	Stoichiometric (~14.7:1)
Fuel Economy	Better	Moderate
Emissions (CO, HC)	Lower	Higher
NOₓ Emissions	Higher	Lower (with 3-way catalysts)
Engine Control	More complex (needs sensors, advanced ECU)	Simpler control

---

🧠 Conclusion:

Lean burn engines offer better fuel economy and lower CO/HC emissions, but may require advanced engine management systems to handle ignition, NOₓ emissions, and cold-start conditions.

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discuss the characterstics of DIand IDI diesel engine

 Sure! Here's a clear and detailed answer for your (ii) part: Characteristics of DI and IDI diesel engines (8 marks):

---

Characteristics of DI (Direct Injection) and IDI (Indirect Injection) Diesel Engines

---

Direct Injection (DI) Diesel Engines

Definition:
In DI engines, fuel is directly injected into the main combustion chamber (cylinder) above the piston.

Characteristics:

• 🔹 High Thermal Efficiency: Less heat loss, better fuel economy.

• 🔹 Higher Power Output: Due to better combustion efficiency.

• 🔹 Better Cold Start with Modern Systems: (Earlier DI engines had poor cold start; now glow plugs help.)

• 🔹 Lower Fuel Consumption: More complete combustion.

• 🔹 High Injection Pressure Needed: Fuel must atomize finely to mix with air.

• 🔹 More Noisy: Sharp combustion noise (diesel knock) if not controlled.

• 🔹 More Complex Injection System: Need precise control.

• 🔹 Less Heat Loss: Because combustion happens in the main chamber.

---

Indirect Injection (IDI) Diesel Engines

Definition:
In IDI engines, fuel is first injected into a small pre-combustion chamber. Combustion starts there and then spreads to the main chamber.

Characteristics:

• 🔸 Lower Thermal Efficiency: Some heat is lost in pre-chamber walls.

• 🔸 Lower Power Output: Less efficient than DI engines.

• 🔸 Better Cold Starting: Easier to start in cold climates without much help.

• 🔸 Higher Fuel Consumption: Because of lower efficiency.

• 🔸 Lower Injection Pressure: Fuel does not need very high pressure.

• 🔸 Smoother and Quieter Operation: Less diesel knock.

• 🔸 Simpler and Cheaper Injection System: No need for very high precision.

• 🔸 More Heat Loss: Heat is absorbed by pre-combustion chamber.

---

Comparison Table

Feature	DI Engine	IDI Engine
Injection Location	Direct into main chamber	Into pre-combustion chamber
Fuel Efficiency	High	Lower
Power Output	Higher	Lower
Cold Starting	Harder (but improved today)	Easier
Engine Noise	Higher	Lower
Injection Pressure	Very High	Moderate
System Complexity	High	Simple
Heat Loss	Less	More

---

Summary

• DI engines are more fuel-efficient and powerful, but noisier.

• IDI engines are smoother and quieter, but less efficient and consume more fuel.

---

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Explain with a (P-θ) diagram the various stages of combustion in a CI engine

Of course! Here’s a complete and structured answer for your 12(a)(i):

---

Stages of Combustion in a Compression Ignition (CI) Engine

(With (P–θ) diagram)

In a CI engine (diesel engine), fuel is injected into compressed hot air inside the cylinder.
There is no external spark — combustion happens due to self-ignition after fuel injection.

The combustion process can be divided into four main stages:

---

1. Ignition Delay Period

• Definition: Time between start of injection and start of combustion.

• What happens:

  • Fuel atomizes, vaporizes, mixes with hot air.

  • Chemical reactions begin, but no visible combustion.

• Effect:

  • Longer delay = more fuel accumulates → leads to sudden, harsh combustion (diesel knock).

---

2. Rapid Pressure Rise (Uncontrolled Combustion Phase)

• Definition: The sudden burning of the accumulated fuel-air mixture after ignition delay.

• What happens:

  • Combustion starts rapidly, causing a sharp rise in cylinder pressure and temperature.

• Effect:

  • If ignition delay was long, this stage becomes very violent.

---

3. Controlled Combustion (Mixing-Controlled Combustion)

• Definition: The combustion phase where the burning rate is controlled by the rate of fuel injection and air-fuel mixing.

• What happens:

  • Freshly injected fuel continues to burn steadily.

• Effect:

  • Smoother pressure rise or even pressure stabilization.

---

4. After-Burning (Late Combustion)

• Definition: Burning of remaining fuel droplets that did not burn in earlier phases.

• What happens:

  • Combustion continues into early expansion stroke.

• Effect:

  • Pressure slowly decreases after peak.

---

P–θ Diagram Explanation

• X-axis = Crank Angle (θ)

• Y-axis = Cylinder Pressure (P)

A basic sketch description:

Pressure
   |
   |                       Peak Pressure
   |                     /\
   |                    /  \    <- Controlled Combustion
   |                   /    \
   |      Rapid       /      \
   |   Pressure Rise /        \
   |                /          \
   |               /            \    <- After-Burning
   |______________/              \_____________ Crank Angle (θ)
     Start of      Ignition
     Injection      Delay

✅ Label the stages clearly in your diagram:

• Start of Injection

• Ignition Delay

• Rapid Pressure Rise

• Controlled Combustion

• After-Burning

---

Summary of Combustion Stages

Stage	Characteristics
Ignition Delay	Fuel injection starts, no combustion yet
Rapid Pressure Rise	Sudden combustion of accumulated fuel
Controlled Combustion	Burning rate controlled by injection/mixing
After-Burning	Slow burning of remaining fuel

---

Important Points

• Short ignition delay = smoother operation, less knocking.

• Efficient fuel injection and atomization = better combustion.

• Combustion quality controls engine performance, emissions, and noise.

---

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Discuss the different types of combustion chamber employed in SI engine.

Sure! Here's a simple and organized explanation:

---

Types of Combustion Chambers in SI Engines

The combustion chamber is the space where the air-fuel mixture burns inside the engine.
A good combustion chamber ensures fast burning, less knocking, better efficiency, and low emissions.

In Spark Ignition (SI) engines, several designs are used:

---

1. Hemispherical Combustion Chamber (Hemi-head)

• Shape: Half-sphere (dome-shaped).

• Spark plug is located centrally.

• Allows large valves and good airflow (breathing).

• Fast flame speed, good power output, and resists knocking.

✅ Advantages: High efficiency, better performance.
❌ Disadvantages: Difficult and expensive to manufacture.

---

2. Wedge-Shaped Combustion Chamber

• Shape: Wedge like a slice of cake 🍰.

• Simpler and compact design.

• Spark plug usually placed at one side.

• Creates swirling motion in the mixture → improves combustion.

✅ Advantages: Simple design, better fuel economy.
❌ Disadvantages: Flame travel is longer (higher knock risk compared to hemi).

---

3. Penton Roof (or Bathtub) Combustion Chamber

• Roof is shaped like a slanted penthouse or bathtub.

• 2 valves at an angle + centrally located spark plug.

• Provides good swirl and fast combustion.

✅ Advantages: Good power and efficiency balance.
❌ Disadvantages: More complex valve arrangement.

---

4. Toroidal (Bowl-in-Piston) Combustion Chamber

• A bowl-shaped depression on the piston crown.

• Common in modern compact engines.

• Generates strong turbulence for better mixing and burning.

✅ Advantages: Compact design, good for emissions control.
❌ Disadvantages: Complex piston design.

---

5. Turbulent Combustion Chamber

• Chamber designed to create high turbulence when piston moves up.

• High turbulence = better mixing = faster combustion.

✅ Advantages: Reduces knocking and improves efficiency.
❌ Disadvantages: Can be noisy and cause mechanical wear.

---

Summary Table

Type	Key Feature	Main Advantage
Hemispherical (Hemi)	Dome-shaped, central spark plug	High performance, knock resistant
Wedge-Shaped	Wedge form, side spark plug	Simplicity and economy
Pentroof/Bathtub	Slanted roof, angled valves	Balance of power and economy
Toroidal (Bowl-in-piston)	Bowl in piston top	Compact, clean burning
Turbulent Chamber	High turbulence created	Faster combustion

---

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Explain the various factors that affect knock in SI engines(8)

Of course! Here’s a clear and simple explanation:

---

Factors Affecting Knock in SI Engines:
(Knock = sudden, uncontrolled combustion causing a "pinging" or "knocking" sound)

Knock happens when the unburned air-fuel mixture ahead of the flame front auto-ignites due to high temperature and pressure.
Many factors influence whether knocking occurs:

---

1. Compression Ratio:

• Higher compression ratios increase temperature and pressure in the cylinder.

• ➔ Higher risk of knock if fuel quality isn’t good enough.

• (Higher compression = more tendency to knock.)

2. Fuel Quality (Octane Number):

• Fuels with higher octane number resist knocking better.

• ➔ Low-octane fuels knock easily, while high-octane fuels are more stable.

3. Air-Fuel Ratio:

• Lean mixtures (too much air) tend to burn slower and can increase knocking.

• Rich mixtures (more fuel) cool the combustion and reduce knock chances.

4. Engine Temperature:

• Hotter engines increase cylinder temperatures.

• ➔ Higher temperatures = greater tendency to knock.

5. Spark Timing:

• If the spark is too advanced (spark happens too early), the mixture burns early, causing high pressures and knocking.

• Retarding the spark can help reduce knock.

6. Engine Speed (RPM):

• At higher speeds, there is less time for auto-ignition to occur, so knocking reduces.

• At low or medium speeds, knock can happen more easily.

7. Engine Design Factors:

• Combustion chamber shape, spark plug location, and cooling system efficiency can impact knocking.

• A good design promotes fast and smooth flame propagation, reducing knock chances.

8. Ambient Conditions:

• High ambient temperature and pressure (like hot weather) increase engine knocking tendency.

---

Summary Table:

Factor	Effect on Knocking
High compression ratio	Increases knocking
Low octane fuel	Increases knocking
Lean air-fuel mixture	Increases knocking
High engine temperature	Increases knocking
Advanced spark timing	Increases knocking
High engine speed (RPM)	Reduces knocking
Efficient combustion chamber	Reduces knocking

---

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Describe the various stages of combustion in a SI engines with the(P-θ) diagram

 Alright! Let’s break it down simply:

---

Stages of Combustion in a Spark Ignition (SI) Engine
(with help of the Pressure vs Crank Angle (P–θ) diagram):

In an SI engine, combustion after the spark plug fires happens in three main stages:

---

1. Ignition Delay (Preparation Phase)

• Spark plug fires but no immediate rise in pressure.

• During this time, small amounts of fuel-air mixture start to ignite.

• Flame kernel forms and grows slowly.

• (On P–θ diagram: pressure slightly increases but still close to compression pressure.)

---

2. Rapid Combustion (Flame Propagation Phase)

• The flame spreads rapidly across the combustion chamber.

• Most of the fuel burns here.

• A rapid rise in pressure and temperature happens because combustion releases a lot of energy.

• (On P–θ diagram: sharp peak in pressure.)

---

3. After-Burning (Late Combustion Phase)

• Remaining unburned mixture (especially near walls) burns slowly.

• Pressure starts falling because the piston is moving down (expansion stroke).

• Combustion is incomplete compared to the rapid combustion phase.

• (On P–θ diagram: pressure gradually decreases after the peak.)

---

🔵 P–θ Diagram Overview:

• X-axis = Crank Angle (θ)

• Y-axis = Cylinder Pressure (P)

• Before spark: Pressure rises due to compression.

• After spark:

  • Little delay → Pressure rises sharply (rapid combustion) →

  • Peaks → Then pressure falls gradually during expansion.

---

Simple Sketch of P–θ Diagram (text version):

Pressure
   |
   |                /\
   |               /  \   (Peak Pressure after Rapid Combustion)
   |              /    \
   |             /      \
   |            /        \
   |           /          \
   |__________/            \_________ Crank Angle (θ)
         (Spark)

---

Quick Recap:
➔ Ignition Delay → Rapid Combustion → After-Burning

---

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Discuss the air fuel ratio requirements of SI engine?

Air-Fuel Ratio (A/F Ratio) Requirements in SI Engine:
(SI = Spark Ignition engine, like petrol engines)

The air-fuel ratio is the amount of air compared to fuel (by weight) in the mixture that enters the engine for combustion.

The ideal (stoichiometric) air-fuel ratio for petrol is about 14.7:1 —
➔ This means 14.7 parts of air for every 1 part of fuel.

But depending on engine operating conditions, the required air-fuel ratio changes:

---

Different Air-Fuel Ratios in SI Engines:

1. Idle Condition:
   ➔ Engine running at very low speed without load.
   ➔ Requires a richer mixture (A/F ratio around 12:1 to 14:1) for smooth operation.

2. Acceleration (High Power Demand):
   ➔ When you press the accelerator for fast speed or overtaking.
   ➔ Needs a rich mixture (around 11:1 to 13:1) to produce more power and prevent knocking.

3. Cruising / Steady Driving:
   ➔ When driving at constant speed (like highway driving).
   ➔ Can use a lean mixture (around 15:1 to 16:1) for better fuel economy.

4. Deceleration (Throttle Off):
   ➔ When slowing down or engine braking.
   ➔ Mixture can be made very lean or fuel can be almost cut off.

5. Cold Start:
   ➔ Engine starting at cold temperatures.
   ➔ Needs a very rich mixture (even richer than 11:1) to ensure combustion because fuel vaporizes poorly when cold.

---

Summary Table:

Condition	Air-Fuel Ratio	Type of Mixture
Idle	12:1 to 14:1	Rich
Acceleration	11:1 to 13:1	Rich
Cruising/Steady	15:1 to 16:1	Lean
Deceleration	Very Lean	Very Lean
Cold Start	Very Rich	Very Rich

 

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What do you understand by CRDI system give its salient feauters.

 Of course! Here’s a clear and simple explanation:

---

CRDI System (Common Rail Direct Injection):

It is a modern fuel injection system used mainly in diesel engines.
In CRDI, fuel is supplied to the engine’s injectors from a common high-pressure rail (pipe).
Each injector is electronically controlled to deliver precise amounts of fuel directly into the combustion chamber.

In short:
➔ Common rail = a shared fuel pipe under high pressure
➔ Direct injection = fuel sprayed directly into the combustion chamber
➔ Electronic control = very precise timing and quantity of fuel injected

---

Salient Features of CRDI System:

1. High Injection Pressure:
   ➔ Fuel is injected at very high pressure (up to 2000+ bar) for better atomization and complete combustion.

2. Precise Control:
   ➔ Electronic control unit (ECU) adjusts the injection timing and quantity very accurately for different engine conditions.

3. Multiple Injections per Cycle:
   ➔ Instead of a single big shot of fuel, CRDI can inject small amounts multiple times (pilot, main, and post-injections) in one cycle for smoother combustion.

4. Improved Fuel Efficiency:
   ➔ Better combustion = less fuel consumption.

5. Lower Emissions:
   ➔ Reduces harmful gases like NOx, CO, and unburned hydrocarbons.

6. Better Engine Performance:
   ➔ More power, quicker response, and smoother running.

7. Less Noise (Lower Engine Knock):
   ➔ Controlled fuel injection makes the engine quieter compared to older diesel engines.

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What is multi valve engine indicate its advantages.

 Here’s a simple and clear explanation:

---

Multi-Valve Engine:
A multi-valve engine is an engine that has more than two valves per cylinder — usually three, four, or even five valves (typically 2 intake + 2 exhaust in a 4-valve setup).

• In a traditional engine: 2 valves per cylinder (1 intake, 1 exhaust)

• In a multi-valve engine: 3, 4, or 5 valves per cylinder (more intake and exhaust valves)

---

Advantages of Multi-Valve Engine:

1. Better Breathing (Improved Airflow):
   ➔ More valves allow more air-fuel mixture to enter and more exhaust gases to leave the cylinder, improving combustion.

2. Higher Power Output:
   ➔ With better airflow, the engine can burn fuel more efficiently, producing more power.

3. Higher Engine Speed (RPM):
   ➔ Smaller, lighter valves can open and close faster, allowing the engine to run at higher RPMs without valve float.

4. Better Fuel Efficiency:
   ➔ More complete combustion leads to better mileage and lower emissions.

5. Improved Cooling of Valves:
   ➔ More valves mean each valve is smaller and dissipates heat faster, reducing the chances of engine knocking or valve damage.

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List down 4 properties that are important in the selection of fuel for an engine?

 Sure! Here's a neat list for you:

---

Four important properties for selecting a fuel for an engine:

1. Calorific Value:
   ➔ The amount of energy released when a certain amount of fuel is burned.
   ➔ Higher calorific value means more energy output and better efficiency.

2. Ignition Quality:
   ➔ For petrol engines: Octane Number (resistance to knocking).
   ➔ For diesel engines: Cetane Number (ease of ignition).
   ➔ Good ignition quality ensures smooth and efficient combustion.

3. Volatility:
   ➔ Ability of the fuel to vaporize easily.
   ➔ Important for proper air-fuel mixing, especially during cold starts.

4. Viscosity:
   ➔ Thickness or flow resistance of liquid fuel.
   ➔ Affects fuel injection and atomization, especially in diesel engines.

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