Why flexible couping are preferred over rigid coupling?

Flexible coupling accomplishes the purpose of any coupling, but the main advantage over rigid coupling is flexible coupling is to accommodate the unavoidable misalignment between shafts in some machinery. 

The flexible coupling also allows a degree of axial movement between the coupling shafts as possible due to thermal expansion.  

As compared with a flexible coupling, the rigid coupling has limited application because rigid couplings do not have the ability to compensate for shaft misalignment, therefore, used where shafts are already positioned in precise lateral and angular alignment.

Proell governor | Construction | Working | Equation of height

A porter governor is known as a proell governor is the two balls are fixed on the upward extensions of the lower links which are in the form of bent links BAE and CDF as shown in the figure below. 


Proell governor


Now, considering the equilibrium of the link BAE which is under the action of following characteristics. 

  • The weight of the ball, mg
  • The tension in the link AO
  • The horizontal reaction of the sleeve
  • The weight of sleeve and friction 1/2 (mg+f) or 1/2 (mg-f)
  • The centrifugal force, mr’ᾠ2 
I is the instantaneous centre of the link BAE and take moments about I to find out the height relation for proell governor. 

N2 = 895×a/h×e [ 2mg + ( mg + or – f ) ( 1+k) / 2mg ] 

Difference between watt governor and proell governor

The function of the governor is to regulate the speed of an engine when there are variations in the load. For example, when the load increases, it becomes necessary to increase the supply of working fluid and when the load decreases, less working fuel is required. Let us have a deep insight into the difference between watt governor and proell governor in this article. 

Difference between Watt and Proell Governor : 

  • Watt governor is the simplest form of a centrifugal governor basically a conical pendulum with links attached to a sleeve of negligible weight and the proell governor has the balls fixed at the endpoint to the extension of the links. 
  • Watt governor is pendulum-type while the proell governor is dead-weight loaded type governor. 
  • The arm of watt governor may be connected to the spindle by two way, the pivot may be on the spindle axis, and pivot may be offset from the spindle axis but arms intersect while in proell governor the balls are fixed. 

Mechanical Vs Hydraulic disc brake | Difference between mechanical and hydraulic disc brake

The function of both braking systems are the same but there is a lot of difference between these two brakes. Mechanical disc brake also known as cable-actuated brakes rely on a braided steel cable to activate the piston that causes the compression of brake pad against the rotor when the brake lever is pulled. Hydraulic disc brake used hydro or rather fluid uses a sealed fluid-filler system as a means of actuation. Let us have a deep insight into the difference between these two braking systems. 

Difference between mechanical and hydraulic brake : 

  • A mechanical disc brake uses cables as a braking medium whereas hydraulic disc brake uses the fluid as a braking medium. 
  • The mechanical disc brake is heavier in weight as compared to hydraulic disc brake. 
  • A mechanical disc brake is less sensitive, requires more force to come to a stop and the hydraulic disc brake is more sensitive and efficient. 
  • Maintainance is frequent in mechanical disc brake whereas hydraulic brake is the maintenance free. 
  • Adjustment of brakes is easy in mechanical braking while complex in hydraulic braking.
  • The hydraulic disc brake is expensive as compared to mechanical disc brake. 
  • Hydraulic brakes give better performance for the same size rotor, but mechanical brakes are good enough if you are using a bigger rotor and set them up correctly.

Types of air filter

The air filtration manufacturer has seen its share of changes over the last decade. They have created new products that not only have improved indoor air quality but also have reduced the cost of installation. When the American Society of Heating, Refrigeration, and Air-conditioning engineers introduced IAQ standards for an air filter. Among these several types of air filters are common in common HVAC systems. 


Different types of air filter: 


Fibreglass filter: This is the most common type of air filter. Layered fibreglass fibres are laid over each other to form the filter media and reinforced with metal supports to prevent failure. 

Polyester and pleated filter: This filter is similar to fibreglass filters but typically have a higher resistance to airflow and a superior dust stopping ability. 

Washable air filter: This filter is not common and relies on the build-up of dust along the clothes to improve the efficiency of a filter. 

High-efficiency particulate arrestance (HEPA) filter: Air passing through this filter at a very fine scale. The US department of energy (DOE) use this filter that meets standards. 

Carbon air filter: Carbon can be treated with oxygen, which opens the carbon's pores making it highly absorbent. It uses activated carbon to trap chemicals and gases, and can also filter cigarette smoke. These activated carbon air filters are well suited to an environment where chemical must be removed from the air. 

UV light air filter: This filter use reaction that occurs when titanium dioxide is exposed to UV light. As the air stream encounters the photochemical process, harmful particles, such as mould and bacteria, are neutralized. 


Explore more information : 

Difference between air filter and cabin filter

Both air filters and cabin filters purify the air but their purpose is slightly different. The air filter cleans the air that flowing to the engine while cabin filter decontaminate air coming into the cockpit. It's important to recognize the distinction between these two filters so in this article you can check it out some difference between the air filter and cabin filter. 


Difference between the air filter and cabin filter : 

  • The air filter is often a performance upgrade, while the cabin air filter is more of a health and safety concern. 
  • The air filter is located in the engine bay under the hood inside a sealed box and is one of the important components of the engine whereas the cabin filter is located behind the glove compartment, under the dash and under the hood. 
  • The air filter prevents dirty air from getting into the engine while cabin air filter blocks dirty air from getting inside the cabin. 
  • Some old vehicle with carburettors has a big metal air filter that located in a round, bulky case made of plastic or metal whereas some vehicles have the air filter installed inside the HVAC case between the blower motor and evaporator core. 
  • The air filter prevents the bugs, dirt, debris and contaminants from entering the delicate system of an engine and allows the only pure air in and the cabin air filter blocks all the airborne allergens and other pollutants from entering the ventilation system of the vehicle. 
  • If the air filter is not replaced and allowed to block up, it can increase fuel consumption and place additional strain on the engine and driveline components whereas failure to replace the cabin air filter may cause a musty smell to emanate through the air conditioning system, and make car trips unpleasant, especially on hot days.
  • Due to a bad or clogged air filter, the turbo life of vehicle gets minimized whereas cabin filter only passes to clean air to the vehicle. 

Explore more information : 

Porter Governor | Construction | Working | Equation of height

Porter governor is same as Watt governor. If the watt governor sleeve is loaded with a heavyweight, it becomes a Porter governor. 

Let M = Mass of the sleeve
m = Mass of each ball
f = Force of friction at the sleeve
Porter Governor
Porter Governor

The frictional force always acts in the opposite direction to the motion, so when the sleeve moves up, the frictional force acts in the downward direction, and the downward force acting on the sleeve is Mg+f. Likewise, the force on the sleeve will be Mg-f when the sleeve moves down. Depending on whether the sleeve is going up or down, the net force acting on the sleeve is mg+f or Mg-f.

Forces acting on the sleeve and on each ball have been shown in the figure. 

Let h = height of the governor
r = distance of the centre of each ball from the axis of rotation

The instantaneous rotation centre of AB link is at I. It is because of the motion of its two points A and B relative to the link. The point A oscillates about the point O and B moves in the verticle direction parallel to the axis. 

Now, the equilibrium of the left-hand half of the governor and taking moments about I. We equate the equation form given below to find the height of governor. 


N2 = 895/h × [ 2mg + ( mg + or -  f ) ( 1 + k ) / 2mg ] 

This equation would provide two values of N for the governor for the same height depending upon the sleeve movement.  

Advantages and disadvantages of worm gear

Worm gear drive is used to transmit power between two non-intersecting shafts, which are at right angles to each other consists of a worm and a worm wheel. The worm is a threaded screw, while the worm wheel is toothed gear. The teeth on the worm wheel envelope the threads on the worm and give the contact between mating parts. Let us have a deep insight into the benefits and drawback of the worm gear in this article. 


Advantages of worm gear : 


  • High-speed reduction: A speed reduction is as high as 100:1 can be obtained with a single pair of worm gear. 
  • The worm gear is compact with small overall dimensions, compared with equivalent spur or helical gear drives having same speed reduction. 
  • The operation is smooth and silent. 
  • Provision can be made for self-locking operation, where the motion is transmitted only from the worm to the worm wheel. This is advantageous in application like cranes and lifting devices. 
  • The worm gear has good meshing effectiveness.
  • The worm gear used for reducing speed and increasing torque. 

Disadvantages of worm gear : 


  • The efficiency is low as compared with the other types of gear drives. 
  • The worm wheel is made of phosphor bronze, which increases the cost. 
  • A considerable amount of heat is generated in worm gear drives, which is required to be dissipated by a lubricating oil to the housing walls and finally to the surroundings.
  • The power transmitting capacity is low. 
  • It is used for up to 100 kW of power transmission. 
  • Lubrication must be strictly maintained for the healthiness of worm gear. 

Difference between welding and fabrication

Welding and fabrication both are two essential processes in the metal industry. In this article, you can check it out the difference between both of these processes so let start with the definition first. 

Definition of Welding : 


Welding is a process which usually involves metals or thermoplastics by inducing melting, which is distinct from lower temperature metal joining processes such as brazing and soldering that do not melt the base metal. Welding is essentially a combination of two pieces, no design, no layout or cutting.

Definition of Fabrication : 


Fabrication is the building of metal structures by cutting, bending, welding and assembling processes. Fabrication is the process of manufacturing or inventing something. Fabrication is making something while welding is only one operation performed during the process. 

Let us have a deep insight into the difference between welding and fabrication below. 


Difference between welding and fabrication : 

  • Fabrication of metal refers to the build of metal structures and is carried out through a variety of processes such as cutting, bending, profiling, welding and assembling whereas the prepared metal from fabrication process then welded together using a variety of techniques and methods frequently involve arc, power supply in order to create an electric arc between electrode on the welding rod and the material itself. 
  • The difference between welding and fabrication is that welding is a particular method of making something by using heat to join together the metal pieces, and fabrication is creating something and does not usually use heat.

What is drilling process | Types of drills | Drilling operation formula

Drilling is the most common process of machining. The drilling process accounts for nearly 75% of all metal cutting material removed.


Drilling is an operation to create cylindrical holes by extracting the metal from solid material or by widening existing holes using multi-tooth cutting tools called drilling. There are various cutting tools available for drilling, but the most common is the twist drill.

The Egyptians drilled holes some 3000 years ago through bow drills in 1200 B.C. The bow drills are the mother of the current drilling machine for metal cutting.

Drilling characteristics 

  • The chips must exit out from the hole created by the drilling process. 
  • When chips are large or continuous, existing chips can cause problems. 
  • At the entrance and for deep holes, the drill can wander. 
  • Coolant may need to be delivered to the cutting front through the drill shaft for deep holes in large workpieces.
  • The most likely drilling on the drill press is by someone who is not a machinist in the process of powder metal cutting.
There are several apparatus needed during the drilling operation. 
  • Drilling machine
  • Center punch 
  • Hammer
  • Center drill 
  • Twist drill 
  • Coolant
  • Vernier calliper
  • Two flute drill set 
  • Center drill
  • Countersink drill 
  • Counterbore drill
  • Drill various diameter

Types of drills 


Step drill to produce a hole of two or more different diameters. 
Core drill to enlarge existing holes.
Counterboring and countersinking to produce depression on the surface to accommodate heads of screws and bolts. 
Center drill a short and stubby drill to produce holes so that workpiece can be mounted between lathe centres. 
Spot drill to start a hole. 
Spade drill to remove large and deep holes. 
Crankshaft drill for good centring. Suitable for deep holes. 
Gun drilling for deep hole making, self-centring, lubrication, and coolant passage. 
Trepanning removal of disk-shaped piece.  
Twist drills to remove the metal in large volume in a minimum period of time. 

The formula for drilling operation


Cutting speed of drilling operation is the peripheral speed of the cutting edge. 

Cutting speed = π D N 

Where D =  drill diameter
N = Rotational speed in rpm 

A feed is a distance the drill penetrates per revolution ( mm / rev ). 
Each cutting edge is f / 2. 

Depth of cut is taken as half the diameter of drilling. 

Depth of cut = D / 2

Drilling time is time taken to complete the drilling operation. 

 T = L / f * N

Where, f = feed-in mm / rev

N = rotational speed ( rpm )
L = the sum of hole depth 

Material removal rate ( MMR ) is the volume of material removed by the drill per unit time. 

MMR = ( π D² / 4 ) * f * N 

What is electrochemical machining | Working principle | Application | Advantages and Disadvantages

Electro-chemical machining is one of the newest and most useful processes of metal removal by the controlled dissolution of the anode of an electrolyte cell.

The process is suited to metal and alloys which are difficult or impossible to the machine by mechanical processes.

This is based on Michael Faraday's classical laws of electrolysis, requiring basically the two-electrodes, electrolytes, a gap and a source of D.C power of sufficient capacity.


Working principle of electrochemical machining


In this machining process workpiece acts as anode and tool acts like cathode and the electrodes should be placed closely with a gap of about 0.5 mm. Anode and cathodes should be immersed in an electrolyte. A potential difference is maintained in between the electrodes as a result ions existing in the electrolytes and it migrates towards the electrodes. Positively charged ions are attracted toward the cathode and negatively charged ions are attracted towards the anode and thus the flow of current is initiated in the electrolyte. The setup is kept stationary and the tool is fed linearly the desired amount of metal is removed through the electrolysis process.

To keep the tool safe from damage by a continuous supply of electrolyte is ensured by pumping at high pressure. The temperature generated is very low and no spark produced this there may not any scope of metallurgical changes in the work material. The tool and the workpiece do not come in direct contact with each other so in this machining process negligible wear and tear are observed. By using this process dimensions up to 0.05 mm can be easily machined. 


Function of electrolyte 


The electrolytes used in this machining process are sodium chloride, sodium nitrate, potassium chloride, sodium hydroxide, sodium fluoride, sulfuric acid and sodium chlorate. 

The main function of electrolyte in this process is following below. 
  • To carries the current between the tool and workpiece.
  • Removes products of machining and other insoluble products from the cutting region.
  • To dissipates heat produced in the operation.
  • To keed the reaction continuous. 
What should be the criteria for selecting Electrolyte?
  • Required Machining rate
  • Required Dimensional Accuracy
  • Surface Texture and Integrity
The essential characteristics of Electrolytes are following below. 
  • Good electrical conductivity.
  • Non-toxicity and chemical stability.
  • Non-corrosive property.
  • Low viscosity
  • High specific heat.
The properties of Electrolytes are following below. 
  • High Electrical Conductivity.
  • High Current Efficiency for machining.
  • Good Surface finish and integrity are necessary.
  • Composition of the electrolyte and structure of the material controls the final surface texture. 

Tool material for electrochemical machining 


Copper, brass, titanium, copper-tungsten and stainless steels are most commonly used electrode material when the electrolyte is made of slats of sodium or potassium. Some material such as aluminium, graphite, bronze, platinum and tungsten carbide are also used for tool material.

Requirements of the tool material in electrochemical machining are following below.
  • Tool material is a conductor of electricity.
  • Because of the fluid pressure, it should be rigid enough to take up the load.
  • The electrolyte should be chemically inert.
  • Making it in the desired shape should be easy to machine.

Accuracy of electrochemical machining


Under ideal conditions with properly designed tooling, is capable of holding a tolerance of the order of (+0.02 to -0.02 mm) and less. Internal radius is greater than 0.2 mm and  0.05 mm an external radius. The taper is of the order of 0.010 mm for 10 mm depth and side over-cut is about 0.1 to 0.2 mm. Based on the work material, the surface finish of this process varies from 0.2 to 0.8 microns.

Factors which affect the accuracy are following below. 
  • Machining Voltage.
  • The feed rate of the electrode. 
  • The temperature of the electrode.
  • The concentration of electrolyte.

Application of electrochemical machining


The main application is machining of hard heat-resisting alloys. This process also used to make an aerospace component, machining of tungsten carbide and that of nozzles in alloy steels. Almost any conducting material can be machined by this method. The main process performed by the electrochemical machining process is electrochemical cutting, broaching, and drilling. 

Typically this method is used for mass production and works with extremely hard materials that are difficult to handle using other techniques but are limited to the use of electrically conductive materials.

Advantages of electrochemical machining 

  • The metal removal rate is quite high for high-strength-temperature-resistant (HSTR) materials as compared to the conventional process.
  • Accurate machining.
  • Residual stress is low.
  • Surface finish is in the order of 0.2 to 0.8 microns.
  • No direct contact between tool and workpiece.
  • Negligible wear and tear of tool material.
  • Environmental friendly.
  • Possible to machine non-rigid and open workpiece.
  • It can be a machine configuration which is beyond the capability of the conventional machining process.
  • Extremely thin sheets of metal can be worked easily without distortion.
  • A job with complex shapes can be machined easily and accurately.
  • Several holes can be done at once during drilling.
  • It is a time-saving machining process as compared to conventional machining.
  • Deburring can be done in hard to access areas.
  • Fragile and brittle materials can be machined easily without cracking or breaking.
  • The metallic workpiece is not damaged due to thermal stresses.

Disadvantages of Electrochemical Machining :

  • Power consumption is more.
  • Initial tooling can be timely and costly.
  • Non-conducting materials can not be machined.
  • The process is costly because of expensive equipment.
  • Continuous supply of electrolyte is necessary.
  • Steady voltage should be maintained during the whole process.
  • Corrosion and rust of the machine can be a hazard.
  • If hydrogen is liberated at the tool surface then it is possible to suffer from hydrogen-embitterment of the surface.
  • There may be a possibility of damages because of sparks.
  • Conventional machining produced more improved fatigue properties than electrochemical machining.

What is lathe machine | Function | Types | Operation | Cutting speed | Feed | Depth of cut

The lathe machine is one of the oldest machine tools that rotate a workpiece about an axis of rotation to perform different operations such as turning, drilling, knurling, facing and many more. In this article, you can check it out function, types, and operations, cutting speed, feed, depth of cut, machining time of the lathe machine. 

Functions of the Lathe Machine


To remove metal from a piece of work to give it the required shape and size is the main function of a lathe.

This is done by keeping the work on the device securely and rigidly and then turning it against cutting tool which extracts metal from the work in the form of chips.


Types of Lathe Machine

  • Speed Lathe Machine
  • Engine Lathe Machine
  • Bench Lathe Machine
  • Toolroom Lathe Machine
  • Capstan and Turret Lathe Machine
  • Special purpose Lathe Machine
  • Automatic Lathe Machine

Lathe Machine

Lathe Machine


Lathe Machine parts and its function 

The bed

The lathe bed is the foundation of a lathe machine. The headstock and tailstock are on either end of the bed and the carriage lies on the bed and slides over it. It is the guiding member of the lathe machine so it should be rigid to prevent deflection, avoid distortion, and must be resisted to twisting. Nickel and chromium alloyed cast iron form a suitable material for lathe bed.

The headstock

The headstock is firmly fixed on the inner ways at the left end of the lathe bed consists of a hollow spindle and mechanism for driving and altering the spindle speed. 

The tailstock

The tailstock is at the right end of the bed on the inner ways. It supports the other end of the workpiece holds a tool for performing an operation. 

The carriage

The carriage consists of several parts such as saddle, cross-slide, compound slide, toolpost, and apron that serve to support, move and control the cutting tool. 

The saddle is an H-shaped casting fits over the bed and slides along with the ways carried the cross-slide and tool post. 

The cross-slide comprises of casting machined on the underside for attachment to the saddle. 

The compound rest is mounted on top of the cross-slide used for obtaining angular cuts and short tapper. 

The tool post is located on the top of the compound rest to hold the tool and enable it to be adjusted to a working position. There are different types of tool post such as single screw tool post, four-bolt tool post, open side tool post, and four-way tool post. 

The apron is linked with the saddle and hands over the front of the bed contains gears, clutches, and levers for operating the carriage by hand and power feeds. 

Feed Mechanism 

The movement of tool related to the work is called a feed. A lathe machine may have three types of feed such as longitudinal, angular and cross. 

Gearbox 

The gearbox is placed below the headstock and contains gears.

Operations performed on Lathe Machine


An operations which are performed in a lathe either by holding the workpiece between centres or by a chuck are following below. 
  • Straight turning
  • Shoulder turning
  • Chamfering
  • Thread cutting
  • Facing
  • Knurling
  • Filling
  • Taper turning
  • Eccentric turning
  • Polishing
  • Grooving
  • Spinning
  • Spring winding
  • Forming
Operations which are performed by holding the work by a chuck or a faceplate or an angle plate are following below. 
  • Drilling
  • Reaming
  • Borning
  • Counterboring
  • Taperboring
  • Internal thread cutting
  • Tapping
  • Undercutting
  • Parting-off
Operations which are performed by using special attachments are following below. 
  • Grinding
  • Milling

Lathe Machine precaution

  • Do not use hand to support the work piece you can using the work holding device.
  • Use the brush to clean the chip.
  • While the machine is in operating condition no any adjustment done by the operator. 
  • Before starting the operation makes sure that all parts are secured tightly. 
  • Not to keep a chuck handle attached by the chuck. 
  • Do not touch the table to a rotating chuck. 
A lathe is one of the most flexible machine tools in the manufacturing industry today due to its versatility. 

Cutting speed of Lathe Machine 


The speed of cutting tool at which the metal is removed by the tool from the workpiece is called the cutting speed. It is the peripheral speed of the work expressed in meters per minute. 

Cutting speed = Πdn/1000 m/min

Where, d = Diameter of the work piece 
n = RPM

A feed of Lathe Machine 


The distance the tool advances of each revolution of the work is called a feed of cutting tool. The feed is expressed in millimetres per revolution. 

Depth of cut of Lathe Machine 


The perpendicular distance measured from the machine surface to the uncut surface of the workpiece is called depth of cut. 

Depth of cut = d1-d2/2

d1=Diameter of the work surface before machining
d2=Diameter of the machined surface 

Machining time of Lathe Machine 


The machining of the lathe machine can be calculated for a particular operation if the speed of the job, feed and length of the job is known. It is calculated by the below formula. 

Machining time = l/s×n min 

Where, l=Length of the job 

s=Feed of the job 
n=RPM of the workpiece

Advantages and disadvantages of mass production

Mass production is the manufacture of discrete parts using a continuous process justified by a very large volume of production. In a line or product layout, the machines are arranged in this type of production system. In simple words, the manufacture of large quantities of goods using machinery and techniques such as assembly line and labour division. Let us have a deep insight into the advantages and disadvantages by using mass production in this article. 


Advantages of mass production : 

  • Higher rate of production with reduced cycle time. 
  • Standardization of product and process sequence. 
  • Higher capacity utilization due to line balancing. 
  • Less skilled operators are required so minimize labour cost. 
  • Lower in process inventory. 
  • Manufacturing cost per unit is low. 
  • Material handling can be completely automatic. 
  • Production planning and control are easy. 
  • An economic process incurs fever labour costs, material costs, efficiently utilizes resources, while at the same time decreasing total expenditure per unit.
  • Rate of production is fast due to automation and efficiency.  
  • The quality of the product is consistent. 
  • Different demands of customers can be met. 

Disadvantages of mass production : 

  • Breakdown of one machine will tend to stop an entire production line. 
  • High investment in production facilities. 
  • Setup cost will be high.
  • Identical products made very quickly. 
  • The cycle time is determined by the slowest production operation. 
  • Line layout needs major change with the changes in product design. 
  • Labours are not very motivated because of a repetitive process. 
  • As a production line is difficult to adapt, this production system is not flexible. 
  • Components for different jobs may need to be stored increases costs.

There is clearly a place for mass production, primarily with companies seeking to make consistent, on-demand product while keeping costs low and ensuring quality standards. Share your experiences regarding mass production in the comments section below.

Advantages and disadvantages of batch production

Batch production is a manufacturing process in which a job passes in lots of batches through the functional departments and each batch can have a different routing. It is common in more than just bakeries and small businesses that produce in controlled quantities. Let us have a deep insight into the advantages and disadvantages of batch production in this article. 

Advantages of batch production : 

  • Products can be produced in mass quantities, reducing the overall cost per each quantity. 
  • Machinery is not always on that saves the energy costs. 
  • Better utilization of plant and machinery. 
  • Promote functional specialization. 
  • The cost per unit is lower than the production of job orders.
  • Generally lower capital cost because of lower investment in plant and machinery.
  • Companies only focus on a small group of products, leading to greater quality control and product expertise. 
  • Smoother and more consistent production flow over time lends itself to repeat order. 
  • Job satisfaction exists for operators. 
  • It has the flexibility to produce a variety of different products.
  • It is ideal for seasonal orders, or trial runs of a new product. 
  • It reduces inventory. 
  • Reducing the risk of simply concentrating on one product. 
  • Labour cost reduced so the final price is lower. 
  • Production is faster. 
  • Begins to take advantage of economies of scale. 

Disadvantages of batch production : 

  • Each batch must be tested for quality and uniformity before batches can be produced, causing ideal downtime. 
  • Machine must be stopped and recalibrated between batches, also causing downtime. 
  • High storage cost for large batches for the same products. 
  • Work is less interesting and repetitive works can demotivate workers. 
  • Material handling is complex of irregular and longer flows. 
  • Production planning and control are complex. 
  • If the prototype has an error all the rest of the same products will have that fault as the machine replicates exactly so the loss of material and time would be costly. 
  • Labour is required to move items from one stage of batch process to another.
  • If lots are small, the cost of the units will be high.
  • Larger stock of raw materials must be kept. 

There is clearly a place for batch production, primarily with companies seeking to make consistent, on-demand product while keeping costs low and ensuring quality standards. Share your experiences regarding batch production in the comments section below.

Advantages and disadvantages of job shop production system

Job shop production is characterized by the manufacture within prefixed time and cost of one or more quality products designed and manufactured in accordance with customer specifications. This is characterized by low volume and high product variety. A workshop consists of machines for general use arranged in different departments. Let us have a deep insight into the advantages and disadvantages of job shop production in this article. 


Advantages of job shop production : 

  • Low volume and high variety of products can be produced because of general-purpose machines and facilities. 
  • Highly skilled operators who can take up each job as a challenge gives them a learning opportunity. 
  • The full potential of operators can be utilized. 
  • The opportunity exists for creative methods and innovative ideas. 
  • Large inventory of material, tools and parts.
  • Easy of supervision.
  • High utilization of expensive machines. 

Disadvantages of job shop production :

  • High cost due to frequent setup changes. 
  • Large space requirements. 
  • Production planning is complicated. 
  • Higher inventory levels at all levels and higher inventory costs as a result.
  • The conflict between resource utilization and customer service. 
There is clearly a place for job shop production, primarily with companies seeking to make consistent, on-demand product while keeping costs low and ensuring quality standards. Share your experiences regarding job shop production in the comments section below.