As heat is transferred through the well and metal stem and into the mercury, the mercury expands, pushing the column of mercury higher in the capillary above

As heat is transferred through the well and metal stem and into the mercury, the mercury expands, pushing the column of mercury higher in the capillary above.

• As heat is transferred through the well and metal stem and into the mercury, the mercury expands, pushing the column of mercury higher in the capillary above.

• Its construction is as follow;

• It is contained in a metal case with the bulb inserted into a metal thermal well.

• A metal scale is mounted behind the upper end of thermometer, and a glass covers the scale.

• This provides the complete protection for the thermometer itself, making rugged and compact instrument.

• The steam is generally protected and insulated by packing.

Thermal is well provided for purpose of preventing breakage and providing a sealing means at the point of installation.

• Thermal is well provided for purpose of preventing breakage and providing a sealing means at the point of installation.

• It is generally of brass or steal although cast iron, Monel, stainless steal, and aluminium are sometimes used.

• The temperature range in which the industrial mercury-in-glass thermometer is used is -38 to 950 degree F.

The Bimetallic thermometer is commonly used whenever the industrial mercury-in-glass thermometer is employed.

• The Bimetallic thermometer is commonly used whenever the industrial mercury-in-glass thermometer is employed.

• Its construction provides a rugged yet accurate and simple device for the indication of temperature.

• It is composed of two strips of metal welded together, each strip made from metal having different coefficient of thermal expansion.

For a bimetal in the form of straight cantilever beam, temperature changes cause to free end to deflect, and this deflection can be related quantitatively to the temperature change.

• For a bimetal in the form of straight cantilever beam, temperature changes cause to free end to deflect, and this deflection can be related quantitatively to the temperature change.

• Deflection with the temperature is nearly linear, depending mainly on coefficients of linear thermal expansion.

• Invar is universally employed as low expansion metal, it is an iron-nickel alloy containing about 36% nickel, its temp. coefficient of expansion is about 1/20 that of ordinary metals

• As high expansion metal, brass is used at lower temp and nickel at higher temperature.

The form of industrial bimetallic thermometer is shown in this figure, it is wound in the form of a helix, with one end fastened permanently to the outer casing and other end connected to pointer stem.

• The form of industrial bimetallic thermometer is shown in this figure, it is wound in the form of a helix, with one end fastened permanently to the outer casing and other end connected to pointer stem.

• A pointer is attached to upper end of stem and sweeps over a circular dial to indicate the temperature.

• A metal bulb contains the thermometer fluid, a liquid, a gas, or a liquid-vapor, and is inserted at the point at which temp is to be measured.

When the temperature surrounding whole stem changes, the bimetal expands and the helical bimetal rotates at its free end, thus turning the inside stem and pointer to a new position on the dial.

• When the temperature surrounding whole stem changes, the bimetal expands and the helical bimetal rotates at its free end, thus turning the inside stem and pointer to a new position on the dial.

• The temperature range covered by the industrial bimetallic thermometer is -40 to 800 degree F .

The liquid expansion thermometer utilizes the cubical expansion of liquid, generally mercury to indicate the temperature.

• The liquid expansion thermometer utilizes the cubical expansion of liquid, generally mercury to indicate the temperature.

• The gas expansion thermometer operates at substantially constant volume , the pressure of the gas being proportional for temperature.

• Vapor-actuated thermometer is operated by vapor pressure of liquid.

• A metal bulb contains the thermometer fluid, a liquid, a gas, or a liquid-vapor, and is inserted at the point at which temp is to be measured.

The bulb comes to the temp equilibrium with its surroundings, thereby developing a given pressure of fluid.

• The bulb comes to the temp equilibrium with its surroundings, thereby developing a given pressure of fluid.

• A metal capillary is connected to the bulb and transmits the pressure to the bulb to the receiving element at the instrument.

• The receiving element is a form of bourdon tube and is used to convert pressure of the fluid in the thermometer bulb into a motion.

• This motion is multiplied by a linkage to operate a pen arm over a moving chart for recording purposes.

• The thermal system, consisting of bulb, capillary and receiving element is a hermitically scaled unit.

The construction thermometer bulb and thermal well is shown in figure.

• The construction thermometer bulb and thermal well is shown in figure.

• the bulb is composed of cylindrical piece of metal tubing, closed at one end and with the capillary and extension neck inserted at the other end.

• The size of bulb varies considerably, depending on type of filling medium, temp span of instrument, and length of capillary tubing with which it is used.

The thermocouple pyrometer has the widest useful range and application of any temperature-measuring device.

• The thermocouple pyrometer has the widest useful range and application of any temperature-measuring device.

• It provides an accurate and reliable indication of temperature for many kinds of industrial applications.

• They can be interchanged since they are supplied to a standard calibration.

A thermocouple is composed of two dissimilar wires joined together so as to produce thermal emf.

• A thermocouple is composed of two dissimilar wires joined together so as to produce thermal emf.

• A simple thermoelectric circuit composed of two wires of different metals, A and B. assume that left-hand junction of the wire is the point of measurement.

• Then the left-hand junction is called measuring junction, right-hand junction is called reference junction, and its frequently maintained at either 32 degree F or 68 degree F.

The THOMSON EFFECT is a relation between emf generated in a single homogeneous wire and temp difference between the ends of wire.

• The THOMSON EFFECT is a relation between emf generated in a single homogeneous wire and temp difference between the ends of wire.

• The thomson emf is propotional to temp and the temp difference in wire and differs for different metals.

• The PELTIER EFFECT relates the absorption and evolution of heat at the junction of a thermocouple to the current flow in the circuit.

• It is proportional to current alone and is different from joule heating effect , which is proportional to the square of the current times the resistance.

• Thus thermocouple employs both PELTIER EFFECT and THOMSON EFFECT.

LAW OF HOMOGENEOUS CIRCUIT :-

• LAW OF HOMOGENEOUS CIRCUIT :-

• An electric current cannot be sustained in a circuit of a single homogeneous metal, however varying in section, by application of heat alone.

• LAW OF INTERMEDIATE METALS :-

• The algebraic sum of thermal emf’s in a circuit composed of any number of dissimilar metals is zero, if all the circuit is at a uniform temperature.

LAW OF INTERMEDIATE TEMPERATURE :-

• LAW OF INTERMEDIATE TEMPERATURE :-

• The thermal emf developed by any thermocouple of homogeneous metals with its junction at any two temperatures T1 and T3, respectively is the algebraic sum of the emf of thermocouple with its junctions at temperature T1 and T2 respectively, and the emf of the same thermocouple with its junction s at temperatures T2 and T3 , respectively.

Measurement of temperature with a resistance thermometer reduces to a measurement of electrical resistance.

• Measurement of temperature with a resistance thermometer reduces to a measurement of electrical resistance.

• Its techniques of resistance measurement are well advanced, and high accuracy and precision are not difficult to obtain.

• The wheatstone bridge with various modification required for use with a resistance-thermometer bulb is the most common method of measurement.

• It is basic system for measurement of resistance. A battery applies potential across two of the junction points ,and galvanometer connects the other two points.

• All resistors and slide-wires are made of manganin in order to avoid any effect due to ambient temperature changes.

All matter that has a temperature(T) greater than absolute zero emits electromagnetic radiation(photon particles) due to the internal mechanical movement of molecules.

• All matter that has a temperature(T) greater than absolute zero emits electromagnetic radiation(photon particles) due to the internal mechanical movement of molecules.

• Radiation thermometers or pyrometers are measurement instruments which determine the temperature of an object based on the infrared radiation emitted from that object.

• Types of pyrometer:-

• 1)Radiation pyrometer

• 2)Optical pyrometer

Principle :

• Principle :

• Temperature measurement is based on the measurement of radiation either directly by a sensor or by comparing with the radiation of a body of known temperature.

• The radiation pyrometer is non-contact type of temperature measurement.

• The wavelength region having high intensity is between 0.1 to 10 micrometer.

• In this region, 0.1 to 0.4 micrometer is known as ultraviolet region.

0.4 to 0.7 micrometer is known as the visible region. 0.7 micrometer onwards is the infrared region.

• 0.4 to 0.7 micrometer is known as the visible region. 0.7 micrometer onwards is the infrared region.

• With the increasing temperature, the radiation intensity is stronger towards shorter wavelengths.

• The temperature measurement by radiation pyrometer is limited within 0.5 to 8 micrometer wave length region.

• Radiation pyrometer consist of optical component to collect the radiation energy emitted by object , a radiation detector that converts the radiant energy in to an electrical signal and an indicator to read the measurement.

This pyrometer is also known as disappearing filament pyrometer.

• This pyrometer is also known as disappearing filament pyrometer.

• Main principle :

• In this type of pyrometer, the tungsten filament of an electric bulb is used as radiator.

• The intensity of radiation of filament is compared with the intensity of the radiation of the hot surface.

• When both the intensity match, the filament of bulb is disappears against the background.

The intensity of filament can be controlled by current flowing through it.

• The intensity of filament can be controlled by current flowing through it.

• The maximum temperature of the filament is 2800 to 3000 °C at the rated voltage.

• The minimum visible radiation is at 600°C . Hence we can measure the temperature in between 600°C.

INDUSTRIAL INSTRUMENTATION, by Donald Eckman.

• INDUSTRIAL INSTRUMENTATION, by Donald Eckman.