Electric heating and welding

 Electric  Heating 

Introduction .      When the current  is pass through  a  conductor , it gets heated  up  due  to   i^2R  losses   and this  heating   characteristic   of the  electric  current  is being  utilized  in industrial  and  domestic  appliances  

                             Heating  ia required  for domestic  purposes  such  as  cooking  and heating  of building  where as for industrial  purposes  and heating  is  required  for melting  of metals , Harding  and tempering  and in welding  . 

  

Advantage  of Electric heating  and over other  system  of  heating  :

The main advantage of electric heating over other system of heating (i.e. coal, gas  or oil)  heating  are : 

1. Economical. Electric heating is economical as Electrical furnaces are cheaper in initial cost as well as maintenance cost .it does not require any attention so there is a considerable savings in labour cost over other  systems of heating more more over the electric energy is also cheap as it is produced on large scale

2.cleanliness.  since  dust and ash are completely  eliminated in electric heating  system  so it  is clean  system and  cleaning  costs  are rendered  to a minimum. 

3. Absence  of fuel  gases.  Since  no fuel  gases  are produced in this  system.  The atmosphere  around  is clean  and pollution  free.

4.Ease of cantrol : Simple accurate and reliable temperature of furnace can be had with the help of manual or automatic devices .desired temperature can be had in electric heating system which is not convenient  in other  heating  systems 

 

5. Efficiency. It has  been  practically  found that 75 to 100%  of heat produced  by electric  heating  can be successfully  utilized  as the source  can be bought  directly  to the point where  heat  is required  there  by reducing  the losses  .

6. Automatic  protection. Automatic protection against over current or 

Overheating can be provided through suitable Switchgear in electric heating system

 

7. Better  working  conditions: Electric heating system produces no irritation noise and also the radiation losses are low . Thus working with electric furnace is convenient and cool

8.safety .  Electric heating  is  quite  safe  and responds quickly.  

9. Upper limit  temperature. There is is no upper limit to the temperature  obtainable of the  except the ability of the material to with stand heat 

10.special heating requirement: certain requirements  of heating such as uniform heating of one particular  portion of the  job without effecting others, heating of non  conducting materials, heating with no  oxidation can be met only in electric  heating system 

Heating element:

The heating  effect of the electric current  can be produced  by passing electric current  through. Heating  element  and the material  used for heating element  must  have following  properties 

1.if should have  high specific  resistance  so that  a small length of wire (R=pl/a,o=Ra/l) is sufficient to produced the required amount  heat 

2. It should have high melting point so that high temperature can be  obtained 

3. It should have low temperature Coefficient since for accurate temperature control the resistance ,should have nearly constant at all temperature and this possible only if the resistance does not change with temperature

4. It should not oxidize at Higher temperatures otherwise it's life is shortened and needs frequent replacement

The most commonly used the heating elements are either lalloy of Nickel and chromium or Nickel chromium iron, Nickel chromium aluminium ,Nickel copper. the use of iron reduces the cost but lower 

 the life of element

Design  of Heating Element. 

The heating element is used for electrical heating may be a circular or rectangular like Ribbon but Ribbon type of  element requires more wattage per unit area. hence circular heating element is preferred. by knowing the electrical input  and its voltage size and length of heating element required to produce the temperature can be calculated 

Causes of failure of heating element 

There are so many causes are there for the failure of heating element some of them are explained below

1.formation of Hot spots:  hot spots are the points  in heating element which are at Higher temperature then the main body of the element .hot spots may be due to any of the following causes;

(a).  High rate of locker oxidation may reduce the cross section of the element wire thereby increasing the resistance at that spot the thus more heat will be produced locally giving rise to the the break dawn of the element

(b) shielding of element by support  etc.will reduce the  local heat losses by radiation and causes  a rise of temperature of shielded  portion  of the  element   therefore  minimum  number  of supports  without  producing  distortion  of the  element  should  be used 

(a).Due to  too high  element    temperature   insufficient  support  for the element  or selection  of  wrong   material . Sagging  and  wrapping  of element   may  result  which may cause  uneven  spacing  of section  there by producing  hot spots.

2.Oxidation of intermittency of operation  . At high  temperature , oxide scale  is the formed  on the  heating  element  which  is continuous  and tenacious  and is so starting  that it prevents  further  oxidation  of inner   metal of element  , However  ,if the element  used quit often  layer is subjected  to thermal  stresses  due to frequent  cooling  and  heating  thereby  the  oxide  layer  cracks  and   flakes  off exposing  further  fresh  metal  to oxidation   thereby  producing  hot spots 

3 Embrittlement due to grain ,growth:    All heating  alloys  containing  iron  tend to form large brittle  grains at high  temperatures . When cold  the elements are very brittle  and  liable to rupture  easily  on slightest  handling  and jerks . 

 Modes of Transfer of heat :

  The heat from one body  to another  body  can be transferred  by any one of following  method 

1. Conduction       2.convection      3.Radiation 

1.conduction : in this method  ,heat is traveles  without  the actual  movement  of practice  (molecules) .The  flow of  heat from one part  to other  part is dependent  upon  the temperature  difference  between  these parts .  It is also  applicable   when  two bodies  at different  temperature  are joined  together  . The  hearted  molecules  of the substance  tramsfer their heat to the adjacent  molecules  and this heat  flow  will invariably   take place so long  as tnere is different  in temperature .

              For example when one end of solid is heated the molecules at that end absorb  the heat  energy and  begin to vibrate rapidly when these is molecule collide with during molecular energy is per set them with internal begin to vibrate faster to pass some on energy to their molecule the heat is transfer one molecule to another molecule without their actual movement

            If the heat is to be conducted from one object to another object, the following conditions must be met

       1.  The objects should be bodily in conctact with each other.

2.   The temperature ofthe two bodies should be different i.e. temperature gradient should exixt.

Definition of conduction:  the process in which heat is transferred from one practical to another in direction of fall of temperature without the actual movement of particles of medium is called conduction. 

  The rate of conduction of heat along a substance depends upon the temperature gradient and expressed in Mj/hr/m^2/m/c^0 or in watts /cm^2 in case of electric heating.

   In a place of thickness t meters having X-sectional area of its two parallel faces A sq.meters and temperature of two faces is T1and T2 absolute, the quantity of heat transferred through it during T hours given by 

            Q=kA

     Where K is coefficient of thermal conductivity for material in Mj/hr/m^2/m/c^0

2. Convection:

                 Def. The process of heat transference in which heat is transferred from one place another  (from hotter to colder one) by actual movement of particles of medium is calles convection. 

        For example: in cases of heater used for heating buildings,  the air in contact with a heat radiator element in a room receives heat from contact with the element. The heated air expands and rises, cold air flowing into takes place. Thus in this way the room gets heated up.

          A similar action takes place in an electric water heater, a continuous floe of water passing upwards across the immersed heating element, with the result that the whole of the water in the tank becomes hot.

        The quantity of heat absorbed from the heater bay convection depends mainaly upon the temperature of the heating element above the surrounding  and upon the size of surface of the heater. It also depends partion of the heater.

            Heat dissipation is given the following expression 

                           H=a(T2-T2)b  W/m^2 

Where a, b - constants whose values depends on the heating surface facilitates for heating etc.

       T1, T2- temperature of the heating surface and fluid in 0c.

3. Radiation:

          Def.  The process of transmission of heat in which heat energy is transferred from hotter body to colder body without heating the medium in between is called radiation. 

   For example: we receive energy from the sun by radiation through there in distance of about 150

 million Kms between sun 

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Arc heating  and Resistance  heating