Week 2:- BiW Fixture Basics Challenge

1.What is the process of project execution activity?

 

RFQ:

In BIW fixture design project begins. It starts with basic requirement or RFQ that we receive from customer. RFQ means request for quotation where in customer give his requirement specification etc. in form of some document or data to study or to work on information include such as technical offer, commercial offer, timeline of project Based on that we have processing to execute project.

1ST SPECIFICATION DISCUSSION MEETING & OFFER SUBMISSION:

In this the documents related technical offer, commercial offer project execution, timeline required to complete the project are prepared. The time required to 3D design, analysis of design, drawing & detailing, manufacturing, assembly & commissioning etc. is considered. Then cost of all operation is considered. By considering these kinds of things the offer is prepared & submitted to customer. Below fig. show document that how technical offer is made.

PO/LOI:

 Once we submitted offer customer will study the offer at the same time he will get offer from different supplier & vendor. He compares these technical offers & based on cost whichever suit best for his requirement. Then he will release LOI or PO with its terms & conditions as stated earlier.

SCHEDULE PREPARATION:

 In project each activity depends on previous activity. So if previous activity has not completed on time it will cause delay in next activity date is fixed so that it will move further. Each activity has assigned specific time i.e. when activity is starting & when it is ending? So we have some back plan so that final date comes to close final delivery date. There need to be proper scheduling to be done to complete project in time. "On time delivery is one of the major requirements from customer side also customer wants commitment must be follow in respect of time.

BOM PREPARATION:

BOM preparation is listing down of part list which includes bought out parts, vendor parts, and consumable items with quantity of each item. Through BOM preparation material budget will be fixed. 8/0 parts include motor, gear box, cylinder pneumatic & hydraulic valves etc. Also vendor parts include all machined, fabricated parts etc. whereas consumable includes like oil, grease, glue, Loctite etc.

DESIGN. CONCEPT PREPARATION:

Further step is design a concept. A concept is based on all

specification received data from customer as 3D data of car panel, drawing, drawing std.

design standard, manufacturing std. After studying all data design concept is build

CUSTOMER APPROVAL:

As design concept ready then it is send to customer for its approval, It is also known as design approval process (DAP) or customer approval process. In that customer will check that all his specification considers or not in specifications. Whether it is as per technical offer submitted then only he approves prepared concept. Some points will be raised by customer. These changes are updated to design team by project team Design team again work on it some modification or changes are necessary to improve design like clamping need to be improved or this mechanism will work fine, sensor should be of this make These changes are again updated to customer. Once he gave final approval will move further for detailing & drawing, release

DETAILING & DRAWING RELEASE:

In detailing all assemblies broken down into its child parts assembly and segregated into standard as well as manufactured for standard parts own data sheet or specification sheet prepared to purchase it from catalogue motor power, motor current rising torque produced, shaft rpm which suit for our application. For vendor parts of detail should be provided on deg. Like all dimension of part with tolerance, surface fish surface treatment hardness welding note all should be mention on drawings. These drawings finish, surface treatment, hardness, welding note all should be mention on drawing. These drawing are checked & released for manufacturing.

MANUFACTURING & B/O ORDERING:

Manufacturing department will receive all drawing to start manufacturing of items like Mylar, blade, riser, base frame. Also purchase team will place order for B/O parts like motor, gearbox, cylinder & valves. As material get ready, QC team should inspect all part received is as per specification or not otherwise it will create issue later which will waste our time

MECHANICAL & ELECTRICAL ASSEMBLY:

After qc check, parts are available for assembly. A station is integration of all mechanical as well as electrical assembly. Assembly team will do all assembly as per drawing. All stations are built as per layout Then again qc team should be involved for checking assembly as per final drawing, all coordinate dimension should beas per design data.

INTERNAL TRIAL & TESTING:

After approval of qc team, Internal trials & testing started. The first step involves putting assembly in fixture manually to check that it being fix properly, locating pin match with hole, clamping is ok, loading & unloading of part is easy. Also operating height is also checked, it is ergonomically correct. Then start taking trials on fixture for welding feasibility, gun approachability in fixture. Then go for online trial.

ONLINE TRAINING:

After successful of trial next step is online training. In online training has two mode manual & automated. In online trial system is run through control panel. All sensor, actuator, motor current & temperature, noise, all alarm, also safety should be tested. All process must be executed as per sequence also cycle time meet. In online training system run for certain cycle & actual production taken to ensure system run successfully.

PACKAGING:

After trial get successful customer give approval to dispatch system To dispatch whole system needs to disassemble station wise & pack properly. Delicate material should be packed properly otherwise there is chance of damage aesthetically or functionally during transportation During packaging labeling, special handling instruction should be pasted on particular parts to convey message of taking care during handling & transportation by air

 DISPATCH:

All material transported at customer site through tracks, container, and ships or Installations: All system is assembled & installed at customer and as per layout approved Initially in DAP. All station, robots, conveyor mounted as per distance specified in layout Robot arm should be reachable to station pick & drop point. It shouldn't foul with other Robot arm should be reachable to station, pick & drop point. It shouldn't foul with other equipment. Also some adjustment should be provided for levelling purpose at robot conveyor base, station base frame like levelling stud to align with other equipment Layout is always specified at the time of initial design stage & it has to be approved by customer.

TRIAL & TRAINING AT CUSTOMER END:

Once installation is done trial start at customer end. So there will be production trial, online trial. Production trial is necessary because at the time of designing fixture, it also committed no of unit that will be manufactured from that fixture also whether it is meeting quality, bench mark or not. Also in technical offer it is committed that there will be 100 units per 8hrs shift will manufactured from that fixture with weld quality. So during production trial fixture capability will be ensured. Once this goal is achieved then there will be training to operator, staff member, engineers to let them to understand how process is working?

BUY OFF MEETING:

Once training is completed there is buy off meeting between customer & project team with discussion on if other things need to be incorporated, anything missing that described in LO/PO or offer submission. Then customer will raise point or sometimes customer wants modification that will lead to extra quotation, extra costing according work is done as per buy of meeting

FINAL HANDOVER:

Once all points raised by customer will be closed then all will go for final handover All data technical manual soft hard documents will submit to customer. These are main project activity

2.What are the types of joining processes?

Joining processes include welding, brazing, soldering, mechanical fastening, and adhesive bonding. Mechanical fastening can be used to provide either temporary or permanent joints, while adhesive bonding, welding, brazing, and soldering processes are mainly used to provide permanent joints. Mechanical fastening and adhesive bonding usually do not cause metallurgical reactions. Consequently, these methods are often preferred when joining dissimilar combinations of materials and for joining polymer-matrix composites that are sensitive to extreme heat. Welding processes are divided into two broad classes: fusion welding and solid-state welding.

Joining includes welding, brazing, soldering, adhesive bonding of materials.

They produce permanent joint between the parts to be assembled.

They cannot be separated easily by application of forces.

They are mainly used to assemble many parts to make a system.

Welding is a metal joining process in which two or more parts are joined

or coalesced at their contacting surfaces by suitable application of heat

or/and pressure.

Sometimes, welding is done just by applying heat alone, with no pressure

applied

In some cases, both heat and pressure are applied; and in other cases only

pressure is applied, without any external heat.

In some welding processes a filler material is added to facilitate

coalescence(Joining)

Types:
1.Metallurgical
2.Mechanical

 

Welding:

Welding is process of permanently joining material welding joins different metal/ alloys with a number of processes in which heat is supplied either electrically or by means of torch. Welding is done by application of heat or both heat & pressure, Pressure may be employed, but this is not in many processes essential. The welding process involves applying heat to the work piece. The heat applied should be such that the work piece should melt, i.e., the temperature at which welding is done, should be more than the melting point of the work piece to be welded. Welding is a fabrication or sculptural process that joins materials, usually metals or thermoplastics, by using high heat to melt the parts together and allowing them to cool, causing fusion Welding is distinct from lower temperature metal-joining techniques such as brazing and soldering, which do not melt the base metal In addition to melting the base metal, a filler material is typically added to the joint to form a pool of molten material (the weld pool) that cools to form a joint that, based on weld configuration (butt, full penetration, fillet, etc.), can be stronger than the base material (parent metal). Pressure may also be used in conjunction with heat or by itself to produce a weld Welding also requires a form of shield to protect the filler metals or melted metals from being contaminated or oxidized. Many different energy sources can be used for welding including a gas flame (chemical), on electric arc (electrical), a laser, an electron beam friction and ultrasound While often an industrial process, welding may be performed in many different environments, including in open air, underwater and in outer space Welding is a hazardous undertaking and precautions are required to avoid bums electric shock vision damage, inhalation of poisonous gases and fumes, and exposure to intense ultraviolet radiation

Brazing

It is a joining process in which a filler metal is melted and distributed by capillary

action between the faying (contact) surfaces of the metal parts being joined.

• In brazing, the filler metal has a melting temperature above 450°C, but below the

melting point of base metals to be joined.

• Join produced by this welding is stronger than soldering.
• This process offers better corrosion resistance.
• Filler used in brazing include Cu and Cu alloys, silver alloys and Al alloys.
• In this process heating is done by torch, furnace, induction, resistance, bath

dipping infrared techniques.

Advantages of brazing

• Brazing can be used to join a large variety of dissimilar metals.
• Pieces of different thickness can be easily joined by brazing
• Thin-walled tubes & light gauge sheet metal assemblies not joinable by welding can be joined by brazing.
• Complex & multi-component assemblies can be economically fabricated with the help of brazing.
• Inaccessible joint areas which could not be welded by gas metal or gas tungsten arc spot or seam welding can be formed by brazing.

Applications:

1)Automobile – Joining Tubes

2) Pipe/Tubing joining (HVAC)

3) Electrical equipment - joining wires

4) Jewellery Making

 

Soldering

Soldering is similar to brazing and can be defined as a joining process in which a filler metal with melting point not exceeding 450°C is melted and distributed by capillary action between the faying surfaces of the metal parts being joined.  As in brazing, no melting of the base metals occurs, but the filler metal wets and combines with the base metal to form a metallurgical bond.

Filler metal, called Solder, is added to the joint, which distributes itself between the closely fitting parts.

• Strength of the joint is weak
• Corrosion resistance is less

SOLDER: Alloys of Tin and Lead. Tin is chemically active at soldering

temperatures and promotes the wetting action required for successful joining.

Applications:

1) Printed Circuit Board (PCB) manufacture

2) Pipe joining (copper pipe)

Easy to solder: copper, silver, gold

Difficult to solder: aluminium, stainless steels

Adhesive bonding:

Adhesive bonding (also referred to as gluing or glue bonding) describes a water bonding technique with applying an intermediate layer to connect substrates of different types of materials. Those connections produced can be soluble or insoluble. The commercially available adhesive can be organic or inorganic and is deposited on one or both substrate surfaces. Adhesives, especially the well-established SU-8, and benzocyclobutene (BCB), are specialized for MEMS or electronic component production. The procedure enables bonding temperatures from 1000 °C down to room temperature. The most important process parameters for achieving a high bonding strength are adhesive material, coating thickness, bonding temperature, processing time, chamber pressure, tool pressure

Adhesive bonding has the advantage of relatively low bonding temperature as well as the absence of electric voltage and current Based on the fact that the wafers are not in direct contact, this procedure enables the use of different substrates, silicon, glass metals and other semiconductor materials A drawback is that small structures become wider during patterning which hampers the production of an accurate intermediate layer with tight dimension control. Further, the possibility of corrosion due to out-gassed products. thermal instability and penetration of moisture limits the reliability of the banding process. Another disadvantage is the missing possibility of hermetically sealed encapsulation due to higher permeability of gas and water molecules while using organic adhesives Below figure shown for an additional information

Diffusion bonding:

Diffusion bonding or diffusion welding is a solid-state welding technique used in metalworking, capable of joining similar and dissimilar metals. It operates on the principle of solid-state diffusion, wherein the atoms of two solid, metallic surfaces intersperse themselves over time. This is typically accomplished at an elevated temperature, approximately 50-70% of the absolute melting temperature of the materials. Diffusion bonding is usually implemented by applying high pressure, in conjunction with necessarily high temperature, to the materials to be welded, the technique is most commonly used to weld sandwiches of alternating layers of thin metal foil, and metal wires or filaments Currently, the diffusion bonding method is widely used in the joining of high strength and refractory metals within the aerospace and nuclear industries.

2.Mechanical joining

Mechanical joining is a process for joining parts through clamping or fastening using screws, bolts of rivets Advantages of mechanical joining include versatility, ease of use, and the option to dismantle the product in cases where regular maintenance requires it The ability to join dissimilar materials is another benefit. A drawback of using mechanical joining is the lack of a continuous connection between parts, because the joint is achieved through discrete points. Also, holes created for joining are vulnerable to fractures and corrosion

Mechanical joining-also called joining by forming - has become interesting for the automotive industry due to the request to reduce fuel consumption and thereby emissions order to reduce weight on the car body, the usage of lightweight materials in the body white application has increased. This includes aluminium, high-strength steel alloys, prymers and composites. Here the different type of mechanical joining becomes important. All mechanical joining methods are cold forming techniques. One general Benes for all mechanical joining methods is the mobility of the material after joining At the same time mechanical joining offers an impressive strength.

Mechanical fastening:

The joining of material combinations which cannot be easily welded such as pre-painted steel or very dissimilar metal. Ex. Al application in auto body makes use of mechanical fastening to overcome the poor inherent weld ability of AL

The joining of materials in application where high fatigue life is critical compared to static strength.

The joining of materials where high tool life is of relative importance screw, bolts etc.

 

Self-piercing riveting

Self-piercing riveting is high speed mechanical fastening for point joining sheet material, typically steel & aluminium alloys. It is single step technique generally using a semi tubular rivet to clinch the sheet in mechanical joint. There is also process variant which utilizes solid rivets

As name suggest pre drilled hole are not required allowing joint to be made rapidly in one operation The process cycle is shown in cross section below

 

 

 

 

Hemming & seaming process:

 Hemming & seaming are two similar metal working processes in which a sheet metal edge is rolled over on to itself. Hemming is process in which edge is rolled flush to itself, while seam joins edges of two materials. Hems are commonly used to reinforce an edge, hide burrs and rough edges, and improve appearance Seams are commonly used in the food industry on canned goods, on amusement park cars, in metal rooting (with a roof seamer). and in the automotive industry. The process for both hemming and seaming are the same, except that the tonnage requirement is greater for seaming. The process starts by bending the edge to an acute angle. A flattening die is then used to flatten the hem. Below figure illustrate hem formation.

 

3.What is Resistance Welding & its application in the automotive sector?

RESISTANCE WELDING:

Resistance welding is one of the oldest of electric welding process in use by industry today. The weld is made by a combination of heat, pressure and time. As the name resistance welding implies, it is the resistance of the material to bewelded to causes current to flow and localized heating in the part. The pressure exerted by the tongs and electrode tips, through which the current flows, hold the parts to be welded in intimate contact before, during and after the welding current time cycle. The required amount of time to current to flow in the joint is determined by material thickness and type, the amount of current flowing and the cross-section area of the welding tip contact surfaces.
Practically all metals can be resistance welded and the operation is quite fast.

• Weld nugget is generated by this process
• RW uses no shielding gases, flux, or filler metal.
• electrodes that conduct electrical power to the process are non-consumable

Current: 5000 to 20,000 A

Voltage: < 10V

Duration of current: 0.1 to 0.4 s (in spot-welding operation)

- Resistance in the welding circuit is the sum of (1) resistance of the electrodes,

(2) resistances of the sheet parts, (3) contact resistances between electrodes and

sheets.

Resistance at the welding surfaces depends on surface finish, cleanliness,

contact area, force. No paint, oil, dirt, and other contaminants should be present

to separate the contacting surfaces.

Advantages:

no filler rod required, high production rates, automation and mechanization is possible.

Disadvantages: restricted to lap joint, costly equipment

Resistance spot welding

Importance: a typical car body has got app. 15, 000 spot welds.

In this process, the fusion of electrodes is done by electrodes having opposing charges at

one location. The sheet thickness has to be less than 3 mm for a good spot weld.

The shape of electrode tip is important like round, hexagonal, square etc. The nugget

shape will be app. 5-10 mm in this case.

Electrodes in RSW: (i) Copper based, (ii) Refractory metal (Cu, Tungsten

combinations)
Steps in spot welding

This is the simplest form of resistance welding and does not possesses any problem for welding sheets ranging up to 12.5 mm in thickness.

• For best results the surfaces to be welded must be free from scales and foreign matter.

• Spot welding machines are available in three different types: stationary single spot, portable single spot and multiple spot welding machines.

• Stationary single spot machines can be further classified into rocker arm type and direct pressure type.

Resistance Seam Welding:

• In principle, seam welding is similar to spot welding except that it uses disc shaped electrodes as

• Unlike spot welding the disc shaped electrodes are not separated after each weld but maintain a continuous pressure over the work pieces.

• Two common types of seam weld are Lap seam welding and Butt seam welding.

• The electrode current is timed to flow in pulses so that a row of welds is produced along the interface.
• 

 

4.What is fusion welding & types of fusion welding with its application in the automotive sector?

Fusion welding processes can be grouped according to the source of the heat, for example, electric arc, gas, electrical resistance and high energy.

These processes include:

Arc Welding Processes - with the most common processes being:

Shielded Metal Arc Welding (SMAW), also known as manual metal arc welding (MMA or MMAW), flux shielded arc welding or stick welding. Suitable for welding ferrous and non-ferrous materials in all positions.

Metal Inert Gas Welding (MIG)

also known as Gas Metal Arc Welding (GMAW). MIG and MAG welding are the most common arc welding processes, in which an electric arc forms between a consumable wire electrode and the work piece leading them to melt and join. Both use a shielding gas to protect the weld from airborne contaminants, or oxidation in the case of MIG welding.

 

Tungsten Inert Gas welding (TIG)

also known as Gas Tungsten Arc Welding (GTAW). This arc process uses a non-consumable tungsten electrode to create the arc between the electrode and the base plate. An inert shielding gas is used to protect from oxidation or other atmospheric contamination. This process can be used autogenously on thin parts, but will require the addition of a wire, rod, or consumable to be added for thicker parts.

Plasma Arc Welding (PAW) 

This process uses an electric arc created between an electrode and the torch nozzle. The electric arc ionises the gas (usually argon) in the chamber creating what is called a 'plasma.' It is then forced through a fine bore copper nozzle that constricts the arc and directs it to the work piece, allowing the plasma arc to be separated from the shielding gas (which is usually made from a mixture of argon and hydrogen).

Submerged Arc Welding (SAW)

This frequently-used arc welding process uses a continuously-fed consumable electrode and a blanket of fusible flux which becomes conductive when molten and provides a current path between the work piece and the electrode. The flux also prevents spatter and sparks while suppressing ultraviolet radiation and fumes.

Flux Cored Arc Welding (FCAW). Developed as an alternative to SMAW, this process uses a continuously fed consumable electrode with a flux and a constant voltage or constant current power supply. Sometimes using a shielding gas this process can also just use the flux to provide protection from the atmosphere.

 

5.What is the 3-2-1 principle?

The 3-2-1 principle is a Component holding principle where three pins are located on the 1st principle plane, i.e. either XY, YZ, ZX. And two pins are located on the 2nd plane which is perpendicular to the 1st plane, and at last one pin on the plane which is mutually perpendicular to the 1st and 2nd planes. By using this method Component can be arrested in all six degrees of freedom

The best and most cost effective method of part location is referred to as 3-2-1 principle. Minimum three locator blocks to establish part plane. Round locating pin (2) in a round hole that defines location in four directions (4 way) perpendicular to the plane previously established. Round locating pin (1) in a slot that defines two of the directions of the other pin (2 way)

From 3-2-1 principle it changes to N-2-1, this depends on the complexity of the panel/part.

An assembly station typically consists of two or more assembly fixtures. Each fixture holds a single part to be assembled with other parts. Locating pins and blocks are locating tools that are widely used as fixtures to determine the part location and orientation.

A 3-2-1 fixture for rigid parts is assumed for each station. A typical 3-2-1

fixture contains several key components:

(i) A four-way pin/hole to precisely locate a part in the two directions;

(ii) A two-way pin/slot to locate a part in the one direction;

these two pins constrain the part rotation and translation in two directions.

(iii)Three shaded locating blocks to locate a part in the one direction. The combination of the locating tools (pins and blocks) constrains all six degrees of-freedom of a rigid part. Since the degree of wear-out of locating blocks is very slight compared to that of locating pins.

 

6.Define Body coordinate system?

Vehicle Orientation:

All vehicle product drawings are identified numerically relative to three vehicle

planes described and shown below.

1. Transom line (TL), “X”, Length (L)
2. Bow line (BL), “Y”, Width (W)
3. Water line (WL), “Z”, Height (H)

A Coordinate system is a reference system consisting of a set of points, lines and surfaces used to define the positions of paints in space in either two or three dimensions. In general, BCS is also called as car line and body line.

X-Longitudinal direction (Fore/After or Front O line- FOL)

Y-Transverse direction (Cross car or Centre O line-COL)

Z-Vertical direction (Up & Down or Bottom O line - BOL)

The origin of the body coordinate system (OX) is defined at the front centre of a vehicle. It indicates a length of a car and the coordinate system (O2) is below the underbody indicates the height of the care and the coordinate system (OY) is the starting point is the centre of car body indicates width of the car.

7.Elaborate Body plane system & its essentials.

Body planes:

Body planes are the reference planes in an automotive car. These planes are used to define the GD&T of all car parts in a automotive domain

Body planes are generally considered to be present at the driver position or sometimes at the engine location or at the front end of the car, depending on the customer.

The measurements from the body planes to the parts are called as bodyline dimensions

These body planes are essential for the below reasons It defines the exact position of each product in the vehicle from the fixed origin

It ensures flawless design for assembly

while designing lines, all the designs are carried out relative to the bodyline.

it assists in easy location of different parts in a vehicle,

it aims in creating a standardized system

it assists in Quality Checks