Title of Invention	"A CERAMIC MIXTURE COMPOSITION AND PROCESS FOR PREPARING THE SAME"
Abstract	A ceramic mixture composition having negative temperature coefficient of resistance (NTC), the said composition comprising about 95.0 wt. % of tetragonal form of Mn3O4 and about 5.0 wt. % of La2O3, the said ceramic mixture is mixed with steric acid and wax, compacted and provided with two electrodes disposed from each other to form a thermistor having resistance of the order of mega ohm at a temperature of 25°C and the resistance of the thermistor drops by almost 40% with every 20°C rise in temperature and stabilizes to 250± 50 ohms at a temperature range of 330°C ± 6%.

Title of Invention

"A CERAMIC MIXTURE COMPOSITION AND PROCESS FOR PREPARING THE SAME"

Abstract

A ceramic mixture composition having negative temperature coefficient of resistance (NTC), the said composition comprising about 95.0 wt. % of tetragonal form of Mn3O4 and about 5.0 wt. % of La2O3, the said ceramic mixture is mixed with steric acid and wax, compacted and provided with two electrodes disposed from each other to form a thermistor having resistance of the order of mega ohm at a temperature of 25°C and the resistance of the thermistor drops by almost 40% with every 20°C rise in temperature and stabilizes to 250± 50 ohms at a temperature range of 330°C ± 6%.

Full Text	A CERAMIC MIXTURE HAVING NEGATIVE TEMPERATURE COEFFICIENT, A THERMISTOR CONTAINING THE CERAMIC MIXTURE AND A PROCESS FOR PREPAING THEREOF TECHNICAL FIELD The present invention relates to a novel ceramic mixture having negative temperature coefficient of resistance and a process for preparing said ceramic mixture. The present Invention also relates to a thermistor prepared from the said ceramic mixture that can work at a temperature range of 330°C ± 6% and a process for preparing the said thermistor. BACKGROUND ART A thermistor is a thermally sensitive resistor whose primary function is to exihibit a change in electric resistance with a change in body temperature. Unlike a wire wound or metal film resistance temperature detector (RTD), a thermistor is a ceramic semiconductor. It has a metal sheathing (stainless steel or Inconel) and contains one or two thermocouple Sensing Wires (Chromel-Alumel-K Type) or Chromel- Constantan-E type) running parallel to the metal sheathing and insulated from each other and sheathing by a ceramic insulating compound. Depending on the type of material used, a thermistor can have either a large positive temperature coefficient of resistance (PTC) or a large negative temperature coefficient of resistance (NTC). Thermal sensors can detect temperature, infra-red source and its size, moving direction and speed, emissivity and wave length. As such these can find applications in intruder alarms, fire alarms, laser detection, thermal recording etc (Sensors and Actuators, by MoonhoLee, Mina Yoo, A-96(2002) P. 97-104). NTC sensors now a days are the most commonly used in automotive applications (Sensors, Vol IV, by W.Gopel, J. Hesse, J.N. Zemel Vol. 4, (1990)) and in precise temperature monitoring devices for temperature measurements, control and compensation. These sensors can provide precise temperature information at critical points. These type of sensors are reliable, stable, re-useable and maintenance free. A number of materials have been reported. Thermistors are polycrystalline mixtures of sintered metallic oxides (NiO, €0263) or solid solutions (MgCO in FesO) that behave essentially as semiconductors. As a result they have negative temperature coefficients of resistance. They have proved successfully in a variety of shapes as small, inexpensive, sensitive, fast response temperature sensors, within the range - 100°C to 300°C. Thermistors for above 300°C are made of oxides of rare earth elements, which are more refractory than nickel and manganese oxides and possesses higher activation energy. Thermistors for cryogenic use are mostly made from non-stoichiometric iron oxides which exhibit very low activation energy (Sensors, Vol IV, by W.Gopel, J. Hesse, J.N. Zemel Vol. 4, (1990)). NTC thermistors consist of metal oxides such as oxides of Manganese, chromium, Cobalt, copper, Iron, Nickel, Titanium with different stoichiometric ratio etc. with different combination (Measurements, Instrumentation and Sensors Hand Book by Meyer Sapoff, P. 32.25). These exhibit a monotonic decrease in electric resistance with an increase in temperature. A number of papers have also been published with different combination of La-Sr-Mn-O film Lao.7sCao.25 MnOa, L&yi Sr 1/3 MnOs pervoskite etc. for magnetoresistive sensor (4,5,6,7). However, no studies so far have been reported with 95% MnjC^ and 5% L^Oa mixture as NTC material. Another reference may be made to Journal of Applied Physics by Sam Jin Kim and Chul Sung Kim, Vol. 91, No. 1 (Jan 2001) P. 221-224. Yet another reference may be made to Physics of Manganites by T.A Kaplan and S.D. Mahanti, 1998, P. 201. One more reference may be made to Sensors and Actuators , by LI. Balcells, J. Cifre, A. Calleja, J. Fontcuberala, M. Varela and F. Benilez. 81 (2000) P. 64-666. OBJECTS OF THE INVENTION The main object of the present invention is to provide a ceramic mixture having negative thermal co-efficient (NTC). Another object of the present invention is to develop a ceramic mixture having long shelf life and can easily be used in different environment. Still another object of the present invention is to provide a ceramic mixture that has sufficient flowability for filling in long tubes having internal diameter upto 2.0 mm. Yet another object of the present invention is to provide a ceramic mixture that can be compacted into a thick mass so that the properties do not deviate. One more object of the present invention is to provide a thermistor comprising the ceramic mixture and capable of sensing temperature in the range of 300-350°C. One another object of the present invention is to provide a thermistor that has resistance of the order of mega ohms at room temperature and nearly 250 ± 50 ohms at 330°C ± 6% and there may not be much variation in its resistance after 350°C. Another object of the present invention is to develop a reliable thermistor which has negative thermal coefficient and gives reproducible results. A further object of the present invention is to provide a thermistor for use in different strategic devices like air crafts, armoured tanks, explosive store houses etc. SUMMARY OF THE INVENTION Accordingly, the present invention provides a novel ceramic mixture composition containing 95% tetragonal form of Mn^ and 5% La203 having a negative temperature coefficient of resistance and a thermistor for sensing temperature in the range of 330±6%, the said thermistor comprising the ceramic mixture along with steric acid and wax forming a base, the said base being provided with a first and a second electrodes that are being disposed away from each other. The present invention also provides a process for preparing the ceramic mixture and the thermistor. DETAILED DESCRIPTION OF THE INVENTION The present invention provides a ceramic mixture composition, said ceramic mixture comprising 95 wt. % tetragonal form of Mn3O4 and 5 wt. % La2O3. In an embodiment of the present invention, the ceramic mixture composition has resistance of the order of mega-ohms at 25°C and the resistance value drops to a value between 200 to 300 ohms at 300°C - 350°C. In another embodiment of the present invention, the ceramic mixture composition shows increase in potential from - 50 mV at 35°C to 13.9mV at 330°C. In yet another embodiment of the present invention, the ceramic mixture composition does not degrade with time. In still another embodiment of the present invention, the ceramic mixture composition works at low as well as high temperatures. The present invention also provides a process for preparing the ceramic mixture having negative temperature coefficient of resistance, the said process comprising the steps of: (a) heating MnO2 upto 1050°C for a time period ranging between 4 hr. to 5 hr to obtain tetragonal form of Mn3O4; (b) cooling the Mn3O4of step (a); (c) grinding the Mn3O4 of step (b) to obtain Mn3O4 of particle size less than 60 microns; (d) mixing the ground Mn3O4 of step (c) with 5 wt. % of La2O3; (e) grinding and sieving through a 250 size BSS mesh the mixture of Mn3O4 and La2O3 to obtain the ceramic mixture. In an embodiment of the present invention wherein in step (a), the MnO2 used is of analytical reagent grade. In another embodiment of the present invention wherein in step (a), the MnO2 is heated upto 1050°C for a time period ranging between 4 hr. to 5 hr. In yet another embodiment of the present invention wherein in step (b), the Mn3O4 is furnace cooled. In still another embodiment of the present invention wherein in step (c), the Mn3O4 is ground in a mortar and pestle. In one more embodiment of the present invention wherein in step (c), the Mn3O4 is sieved through a 250 size BSS mesh. In one another embodiment of the present invention wherein in step (e), the mixture of Mn3O4 and La2O3 is ground in mortar and pestle. In a further embodiment of the present invention wherein in step (e), the ground mixture is sieved through a 250 size BSS mesh. In one another embodiment of the present invention wherein in step (e), the mixture of Mn3C4 and Os is ground in mortar and pestle. In a further embodiment of the present invention wherein in step (e), the ground mixture is sieved through a 250 size BSS mesh. The present invention further provides a thermistor for sensing temperature, the said thermistor comprising the ceramic mixture having negative thermal coefficient along with steric acid and wax as a base, the said base being provided with a first and a second electrodes that are being disposed away from each other. In an embodiment of the present invention, the ceramic mixture comprises about 95 wt. % tetragonal form of Mnand about 5 wt. % LaO. In another embodiment of the present invention, the wt. % of steric acid used is 1.0. In yet another embodiment of the present invention, the wt. % of wax used is 1.0. In still another embodiment of the present invention, the thermistor is used for sensing temperature in the range of 300° to 350°C. In one more embodiment of the present invention, the resistance of the sensor drops by 30 to 50% of its original value with every 20°C rise in temperature. In one another embodiment of the present invention, the resistance of the sensor drops by 40% of its original value with every 20°C rise in temperature. In a further embodiment of the present invention, the first and second electrodes are provided on the surface of the element assembly. In an embodiment of the present invention, the first and second electrodes are provided inside the element assembly. In another embodiment of the present invention, the first and second electrodes are made of conducting material. The present invention provides a process for preparing the thermistor having negative temperature coefficient of resistance for sensing temperature, said process comprising the steps of: (a) heating MnO2 to obtain tetragonal form of M n s ; (b) cooling the MnOof step (a); (c) grinding the MnaCU of step (b) to obtain MnsO4 of particle size less than 60 microns; (d) mixing the ground MnaO of step (c) with 5 wt. % of Oa; (e) grinding and sieving the mixture of step (d) to obtain a ceramic mixture; (f) adding steric acid and wax to the ceramic mixture of step (e); (g) grinding the mixture of step (f) optionally in the presence of an alcohol and sieving, and (h) compacting and sintering the ground mixture of step (g) and providing a first and a second electrodes to obtain the thermistor. In an embodiment of the present invention wherein in step (a), the MnO2 used is of analytical reagent grade. In another embodiment of the present invention wherein in step (a), the MnO2 is taken in a silica crucible and heated upto 1050°C for a time period ranging between 4 hr. to 5 hr. in a muffle furnace. In yet another embodiment of the present invention wherein in step (c), the MnsO4 is ground in a mortar and pastel. In still another embodiment of the present invention wherein in step (c), the MnsCU is sieved through a 250 size BSS mesh. In one more embodiment of the present invention wherein in step (e), the mixture of and La is ground in mortar and pestle. In one another embodiment of the present invention wherein in step (e) ground mixture is sieved through a 250 size BSS mesh. In a further embodiment of the present invention wherein in step (f), 1% steric acid and 1% wax are added to the ceramic mixture to improve flowability and binding capacity. In an embodiment of the present invention wherein in step (g), the mixture steric acid, wax and alcohol is ground in a mortar and pestle. In another embodiment of the present invention wherein in step (g), the ground mixture is sieved through 250 size BSS mesh. In yet another embodiment of the present invention wherein if alcohol is added during grinding in step (g), the sieved mixture is gradually heated to remove the alcohol. In still another embodiment of the present invention wherein in step (h), the ground mixture is compacted and sintered to form pellets, and the first and second electrodes are deposited on an outer surface of the pellet to obtain the thermistor. In one more embodiment of the present invention wherein in step (h), the ground mixture is filled in tubes provided with the first and second electrodes, compacted and sintered to obtain the thermistor. In one another embodiment of the present invention, the first and second electrodes being deposited in step (h) are made of conducting material. The present invention relates to the development of new ceramic mixture which has negative temperature coefficient (NTC) characteristics for thermal sensing devices /sensors. Tetragonal form of manganese oxide (MnsCU) has been mixed with lanthanum oxide to form a mixture of these compounds. In order to get the desired properties, to increase its flowability and binding the mixture was ground (less than 60 microns) and mixed with stearic acid (1%) and wax (1%). This material when compacted in the form of pellets or filled in a tube with compression has resistance of the order of mega ohms and output voltage of the order of -50.00 mV at 30°C. On heating the resistance drops almost 40% of its value for every 20°C rise in temperature. The MnO2 used is of A.R. Grade, was converted to tetragonal form of MnaCU. The structure was confirmed by XRD technique. Tetragonal Mn3O4 was mixed with Lanthanum oxide (LaaCh) in the ratio 95:5. The mixture was ground and sieved through 250 BSS Mesh size (Particle size mixture. For preparing the thermistor, the ceramic mixture thus obtained is mixed with 1% Stearic acid and 1% wax to improve the flowability in the pipe of upto 2.0 mm inner diameter. This powder was filled into tubes or compacted to form pellets and sintered at 900°C for one hour so that material attains dry strength and has continuity at any two points. BRIEF DESCRIPTION OF THE ACCOMPANYING DRAWINGS Fig.l shows process flow sheet for the preparation of NTC ceramic compound working upto 350°C The present invention is described further with respect to the example, which is given by way of illustration and hence, should not be considered to limit the scope of the invention in any manner. Example 1 Manganese di-oxide (MnCh) Analytical Reagent (AR) quality was taken in silica crucibles and heated to a temperature of 1050°C in a muffle furnace. The MnO2 was kept at this temperature for 4 to 5 hours in order to convert MnO2 to Mn3O4 The structure of Mna is tetragonal and is confirmed by XRD. The material is then furnace cooled. Mn3O4 is then ground in mortar and pestle and sieved through 250 size BSS mesh ( oxide (La2O3) and ground thoroughly in mortar and pestle to obtain the ceramic mixture. Stearic acid (1%) and wax (1%) was then added and again ground using alcohol. It was then slowly heated in order to remove the alcohol. The mixture was again ground and sieved through 250 BSS Mesh. The material is characterized for potential drop and resistance change. The mixture thus obtained having ceramic powder, steric acid and wax is filled in about one foot long stainless steel tubes and two sensing wires (chromel and alumel wires) are inserted into the powder inside the tube. The powder is then compacted inside the tube by ramming. These tubes were then sintered at 900°C for 4 to 5 hours so that the material becomes a hard mass. The powder can otherwise be compressed at about 10 tonnes/Inch2 in a die to make pellets/tablets. A detailed block diagram of depicting the process for preparing the ceramic mixture and the thermistor thereof is shown in Figure 1. These ceramic tablets/filled tubes with ceramic powder were characterized for potential drop and drop in resistance. The tests were repeated several times for about one year to check the stability/repeatability of the test results. The results of the test thus conducted are tabulated in Table 1 given below. The main advantages of the present invention are: • It gives NTC characteristics. • This material has resistance of the order of mega ohms at 25°C and this value drops to 200-300 ohms between 300°C-350°C. Therefore, this material has been used in fire safety sensors/devices for strategic applications. • The material has good flowability. Therefore, it is possible to fill up this material in small diameter and long tubes. • The material does not degrade with time, temperature and other environmental changes. • The chemicals are easily available and processable. We Claim: 1. A ceramic mixture composition, said ceramic mixture comprising 95 wt. % tetragonal form of Mn3O4 and 5 wt. % La2O3. 2. A ceramic mixture composition as claimed in claim 1, wherein the ceramic mixture composition has resistance of the order of 2.5-4 mega-ohms at 25 -30°C and the resistance value drops to a value between 200 to 300 ohms at 300°C - 350°C. 3. A ceramic mixture composition as claimed in claim 1, wherein the ceramic mixture composition shows increase in potential from - 50 mV at 35°C to 13.9m V at 330°C. 4. A ceramic mixture composition as claimed in claim 1, wherein the ceramic mixture composition does not degrade with time. 5. A ceramic mixture composition as claimed in claim 1, wherein the ceramic mixture composition works at low as well as high temperatures. 6. A process for preparing a ceramic mixture composition of claim 1, the said process comprising the steps of: a) heating MnO2 upto 1050°C for a time period ranging between 4 hr. to 5 hr to obtain tetragonal form of Mn3O4; b) cooling the Mn3O4 of step (a); c) grinding the Mn3O4 of step (b) to obtain Mn3O4of particle size less than 60 microns; d) mixing the ground Mn3O4 of step (c) with 5 wt. % of La2O3; e) grinding and sieving through a 250 size BSS mesh the mixture of Mn3O4 and La2O3 to obtain the ceramic mixture. 7. A process as claimed in claim 6 wherein in step (a), the MnO2 used is of analytical reagent grade. 8. A process as claimed in claim 6, wherein in step (b), the Mn3O4 is furnace cooled. 9. A process as claimed in claim 6,wherein in step (c), the Mn3O4 is ground in a mortar and pestle. 10. A process as claimed in claim 6, wherein in step (e), the mixture of Mn3O4 and La2O3 is ground in mortar and pestle. 11. A thermistor for sensing temperature wherein , the said thermistor comprising 98 % of ceramic mixture composition as claimed in claim 1 along with steric acid 1.0 wt % and wax as a base 1.0 wt %, the said base being provided with a first and a second electrodes made of conducting material that are being disposed away from each other. 12. A thermistor as claimed in claim 11, wherein the ceramic mixture comprises 95 wt. % tetragonal form of Mn3O4 and 5 wt. % La2O3. 13. A thermistor as claimed in claim 11, wherein the thermistor is used for sensing temperature in the range of 300° to 350°C. 14. A thermistor as claimed in claim 11, wherein the resistance of the sensor drops by 30 to 50% of its original value with every 20°C rise in temperature. 15. A thermistor as claimed in claim 11, wherein the resistance of the sensor drops by 40% of its original value with every 20°C rise in temperature. 16. A thermistor as claimed in claim 11, wherein the first and second electrodes are provided on the surface of the element assembly. 17. A thermistor as claimed in claim 11, wherein the first and second electrodes are provided inside the element assembly. 18. A process for preparing the thermistor of claim 14 having negative temperature coefficient of resistance for sensing temperature, said process comprising the steps of: a) heating MnO2 to obtain tetragonal form of Mn3O4 b) cooling theMn3O4 of step (a); c) grinding the Mn3O4 of step (b) to obtain Mn3O4 of particle size less than 60 microns; d) mixing the ground Mn3O4 of step (c) with 5 wt. % of La2O3 e) grinding and sieving the mixture of step (d) to obtain a ceramic mixture; f) adding steric acid and wax to the ceramic mixture of step (e); g) grinding the mixture of step (f) optionally in the presence of an alcohol and sieving, and h) compacting and sintering the ground mixture of step (g) and providing a first and a second electrodes to obtain the thermistor. 19. A process as claimed in claim 18, wherein in step (a), the MnO2 used is of analytical reagent grade. 20. A process as claimed in claim 18, wherein in step (a), the MnO2 is taken in a silica crucible and heated upto 1050°C for a time period ranging between 4 hr. to 5 hr. in a muffle furnace. 21. A process as claimed in claim 18, wherein in step (c), the Mn3O4 is ground in a mortar and pastel. 22. A process as claimed in claim 18, wherein in step (c), the Mn3O4 is sieved through a 250 size BSS mesh. 23. A process as claimed in claim 18, wherein in step (e), the mixture of Mn3O4 and La2O3 is ground in mortar and pestle. 24. A process as claimed in claim 18, wherein in step (e) ground mixture is sieved through a 250 size BSS mesh. 25. A process as claimed in claim 18, wherein in step (f), 1.0 wt. % steric acid and 1.0 wt. % wax are added to the ceramic mixture to improve flowability and binding capacity. 26. A process as claimed in claim 18 wherein in step (g), the mixture of Mn3O4, La2O3, steric acid, wax and alcohol is ground in a mortar and pestle. 27. A process as claimed in claim 18 wherein in step (g), the ground mixture is sieved through 250 size BSS mesh. 28. A process as claimed in claim 18 wherein if alcohol is added during grinding in step (g), the sieved mixture is gradually heated to remove the alcohol. 29. A process as claimed in claim 18 wherein in step (h), the ground mixture is compacted and sintered to form pellets, and the first and second electrodes are deposited on an outer surface of the pellet to obtain the thermistor. 30. A process as claimed in claim 18 wherein in step (h), the ground mixture is filled in tubes provided with the first and second electrodes, compacted and sintered to obtain the thermistor. 31. A ceramic mixture composition, a thermistor and process thereof as herein describe with reference to examples accompanying this specification.

Full Text

A CERAMIC MIXTURE HAVING NEGATIVE TEMPERATURE COEFFICIENT,
A THERMISTOR CONTAINING THE CERAMIC MIXTURE
AND A PROCESS FOR PREPAING THEREOF
TECHNICAL FIELD
The present invention relates to a novel ceramic mixture having negative temperature
coefficient of resistance and a process for preparing said ceramic mixture. The present
Invention also relates to a thermistor prepared from the said ceramic mixture that can
work at a temperature range of 330°C ± 6% and a process for preparing the said
thermistor.
BACKGROUND ART
A thermistor is a thermally sensitive resistor whose primary function is to exihibit a
change in electric resistance with a change in body temperature. Unlike a wire wound
or metal film resistance temperature detector (RTD), a thermistor is a ceramic
semiconductor. It has a metal sheathing (stainless steel or Inconel) and contains one
or two thermocouple Sensing Wires (Chromel-Alumel-K Type) or Chromel-
Constantan-E type) running parallel to the metal sheathing and insulated from each
other and sheathing by a ceramic insulating compound. Depending on the type of
material used, a thermistor can have either a large positive temperature coefficient of
resistance (PTC) or a large negative temperature coefficient of resistance (NTC).
Thermal sensors can detect temperature, infra-red source and its size, moving
direction and speed, emissivity and wave length. As such these can find applications
in intruder alarms, fire alarms, laser detection, thermal recording etc (Sensors and
Actuators, by MoonhoLee, Mina Yoo, A-96(2002) P. 97-104). NTC sensors now a
days are the most commonly used in automotive applications (Sensors, Vol IV, by
W.Gopel, J. Hesse, J.N. Zemel Vol. 4, (1990)) and in precise temperature
monitoring devices for temperature measurements, control and compensation. These
sensors can provide precise temperature information at critical points. These type of
sensors are reliable, stable, re-useable and maintenance free. A number of materials
have been reported.
Thermistors are polycrystalline mixtures of sintered metallic oxides (NiO,
€0263) or solid solutions (MgCO in FesO) that behave essentially as
semiconductors. As a result they have negative temperature coefficients of resistance.
They have proved successfully in a variety of shapes as small, inexpensive, sensitive,
fast response temperature sensors, within the range - 100°C to 300°C. Thermistors
for above 300°C are made of oxides of rare earth elements, which are more refractory
than nickel and manganese oxides and possesses higher activation energy.
Thermistors for cryogenic use are mostly made from non-stoichiometric iron oxides
which exhibit very low activation energy (Sensors, Vol IV, by W.Gopel, J. Hesse,
J.N. Zemel Vol. 4, (1990)).
NTC thermistors consist of metal oxides such as oxides of Manganese, chromium,
Cobalt, copper, Iron, Nickel, Titanium with different stoichiometric ratio etc. with
different combination (Measurements, Instrumentation and Sensors Hand Book by
Meyer Sapoff, P. 32.25). These exhibit a monotonic decrease in electric resistance
with an increase in temperature. A number of papers have also been published with
different combination of La-Sr-Mn-O film Lao.7sCao.25 MnOa, L&yi Sr 1/3 MnOs
pervoskite etc. for magnetoresistive sensor (4,5,6,7). However, no studies so far have
been reported with 95% MnjC^ and 5% L^Oa mixture as NTC material.
Another reference may be made to Journal of Applied Physics by Sam Jin Kim and
Chul Sung Kim, Vol. 91, No. 1 (Jan 2001) P. 221-224.
Yet another reference may be made to Physics of Manganites by T.A Kaplan and S.D.
Mahanti, 1998, P. 201.
One more reference may be made to Sensors and Actuators , by LI. Balcells, J. Cifre,
A. Calleja, J. Fontcuberala, M. Varela and F. Benilez. 81 (2000) P. 64-666.
OBJECTS OF THE INVENTION
The main object of the present invention is to provide a ceramic mixture having
negative thermal co-efficient (NTC).
Another object of the present invention is to develop a ceramic mixture having long
shelf life and can easily be used in different environment.
Still another object of the present invention is to provide a ceramic mixture that has
sufficient flowability for filling in long tubes having internal diameter upto 2.0 mm.
Yet another object of the present invention is to provide a ceramic mixture that can be
compacted into a thick mass so that the properties do not deviate.
One more object of the present invention is to provide a thermistor comprising the ceramic mixture and capable of sensing temperature in the range of 300-350°C. One another object of the present invention is to provide a thermistor that has resistance of the order of mega ohms at room temperature and nearly 250 ± 50 ohms at 330°C ± 6% and there may not be much variation in its resistance after 350°C.
Another object of the present invention is to develop a reliable thermistor which has negative thermal coefficient and gives reproducible results.
A further object of the present invention is to provide a thermistor for use in different strategic devices like air crafts, armoured tanks, explosive store houses etc.
SUMMARY OF THE INVENTION
Accordingly, the present invention provides a novel ceramic mixture composition containing 95% tetragonal form of Mn^ and 5% La203 having a negative temperature coefficient of resistance and a thermistor for sensing temperature in the range of 330±6%, the said thermistor comprising the ceramic mixture along with steric acid and wax forming a base, the said base being provided with a first and a second electrodes that are being disposed away from each other. The present invention also provides a process for preparing the ceramic mixture and the thermistor.
DETAILED DESCRIPTION OF THE INVENTION
The present invention provides a ceramic mixture composition, said ceramic mixture comprising 95 wt. % tetragonal form of Mn3O4 and 5 wt. % La2O3.
In an embodiment of the present invention, the ceramic mixture composition has resistance of the order of mega-ohms at 25°C and the resistance value drops to a value between 200 to 300 ohms at 300°C - 350°C.
In another embodiment of the present invention, the ceramic mixture composition shows increase in potential from - 50 mV at 35°C to 13.9mV at 330°C.

In yet another embodiment of the present invention, the ceramic mixture composition does not degrade with time.
In still another embodiment of the present invention, the ceramic mixture composition works at low as well as high temperatures.
The present invention also provides a process for preparing the ceramic mixture having negative temperature coefficient of resistance, the said process comprising the steps of:
(a) heating MnO2 upto 1050°C for a time period ranging between 4 hr. to 5 hr to obtain tetragonal form of Mn3O4;
(b) cooling the Mn3O4of step (a);
(c) grinding the Mn3O4 of step (b) to obtain Mn3O4 of particle size less than 60 microns;
(d) mixing the ground Mn3O4 of step (c) with 5 wt. % of La2O3;
(e) grinding and sieving through a 250 size BSS mesh the mixture of Mn3O4 and La2O3 to obtain the ceramic mixture.
In an embodiment of the present invention wherein in step (a), the MnO2 used is of analytical reagent grade.
In another embodiment of the present invention wherein in step (a), the MnO2 is heated upto 1050°C for a time period ranging between 4 hr. to 5 hr.
In yet another embodiment of the present invention wherein in step (b), the Mn3O4 is furnace cooled.
In still another embodiment of the present invention wherein in step (c), the Mn3O4 is ground in a mortar and pestle.
In one more embodiment of the present invention wherein in step (c), the Mn3O4 is sieved through a 250 size BSS mesh.
In one another embodiment of the present invention wherein in step (e), the mixture of Mn3O4 and La2O3 is ground in mortar and pestle.
In a further embodiment of the present invention wherein in step (e), the ground mixture is sieved through a 250 size BSS mesh.

In one another embodiment of the present invention wherein in step (e), the mixture
of Mn3C4 and Os is ground in mortar and pestle.
In a further embodiment of the present invention wherein in step (e), the ground
mixture is sieved through a 250 size BSS mesh.
The present invention further provides a thermistor for sensing temperature, the said
thermistor comprising the ceramic mixture having negative thermal coefficient along
with steric acid and wax as a base, the said base being provided with a first and a
second electrodes that are being disposed away from each other.
In an embodiment of the present invention, the ceramic mixture comprises about 95
wt. % tetragonal form of Mnand about 5 wt. % LaO.
In another embodiment of the present invention, the wt. % of steric acid used is 1.0.
In yet another embodiment of the present invention, the wt. % of wax used is 1.0.
In still another embodiment of the present invention, the thermistor is used for sensing
temperature in the range of 300° to 350°C.
In one more embodiment of the present invention, the resistance of the sensor drops
by 30 to 50% of its original value with every 20°C rise in temperature.
In one another embodiment of the present invention, the resistance of the sensor drops
by 40% of its original value with every 20°C rise in temperature.
In a further embodiment of the present invention, the first and second electrodes are
provided on the surface of the element assembly.
In an embodiment of the present invention, the first and second electrodes are
provided inside the element assembly.
In another embodiment of the present invention, the first and second electrodes are
made of conducting material.
The present invention provides a process for preparing the thermistor having negative
temperature coefficient of resistance for sensing temperature, said process comprising
the steps of:
(a) heating MnO2 to obtain tetragonal form of M n s ;
(b) cooling the MnOof step (a);
(c) grinding the MnaCU of step (b) to obtain MnsO4 of particle size less than 60
microns;
(d) mixing the ground MnaO of step (c) with 5 wt. % of Oa;
(e) grinding and sieving the mixture of step (d) to obtain a ceramic mixture;
(f) adding steric acid and wax to the ceramic mixture of step (e);
(g) grinding the mixture of step (f) optionally in the presence of an alcohol and
sieving, and
(h) compacting and sintering the ground mixture of step (g) and providing a first
and a second electrodes to obtain the thermistor.
In an embodiment of the present invention wherein in step (a), the MnO2 used is of
analytical reagent grade.
In another embodiment of the present invention wherein in step (a), the MnO2 is taken
in a silica crucible and heated upto 1050°C for a time period ranging between 4 hr. to
5 hr. in a muffle furnace.
In yet another embodiment of the present invention wherein in step (c), the MnsO4 is
ground in a mortar and pastel.
In still another embodiment of the present invention wherein in step (c), the MnsCU is
sieved through a 250 size BSS mesh.
In one more embodiment of the present invention wherein in step (e), the mixture of
and La is ground in mortar and pestle.
In one another embodiment of the present invention wherein in step (e) ground
mixture is sieved through a 250 size BSS mesh.
In a further embodiment of the present invention wherein in step (f), 1% steric acid
and 1% wax are added to the ceramic mixture to improve flowability and binding
capacity.
In an embodiment of the present invention wherein in step (g), the mixture
steric acid, wax and alcohol is ground in a mortar and pestle.
In another embodiment of the present invention wherein in step (g), the ground
mixture is sieved through 250 size BSS mesh.
In yet another embodiment of the present invention wherein if alcohol is added during
grinding in step (g), the sieved mixture is gradually heated to remove the alcohol.
In still another embodiment of the present invention wherein in step (h), the ground
mixture is compacted and sintered to form pellets, and the first and second electrodes
are deposited on an outer surface of the pellet to obtain the thermistor.
In one more embodiment of the present invention wherein in step (h), the ground
mixture is filled in tubes provided with the first and second electrodes, compacted and
sintered to obtain the thermistor.
In one another embodiment of the present invention, the first and second electrodes
being deposited in step (h) are made of conducting material.
The present invention relates to the development of new ceramic mixture which has
negative temperature coefficient (NTC) characteristics for thermal sensing
devices /sensors. Tetragonal form of manganese oxide (MnsCU) has been mixed with
lanthanum oxide to form a mixture of these compounds. In order to get the
desired properties, to increase its flowability and binding the mixture was ground (less
than 60 microns) and mixed with stearic acid (1%) and wax (1%). This material when
compacted in the form of pellets or filled in a tube with compression has resistance of
the order of mega ohms and output voltage of the order of -50.00 mV at 30°C. On
heating the resistance drops almost 40% of its value for every 20°C rise in
temperature.
The MnO2 used is of A.R. Grade, was converted to tetragonal form of MnaCU. The
structure was confirmed by XRD technique. Tetragonal Mn3O4 was mixed with
Lanthanum oxide (LaaCh) in the ratio 95:5. The mixture was ground and sieved
through 250 BSS Mesh size (Particle size mixture. For preparing the thermistor, the ceramic mixture thus obtained is mixed
with 1% Stearic acid and 1% wax to improve the flowability in the pipe of upto 2.0
mm inner diameter. This powder was filled into tubes or compacted to form pellets
and sintered at 900°C for one hour so that material attains dry strength and has
continuity at any two points.
BRIEF DESCRIPTION OF THE ACCOMPANYING DRAWINGS
Fig.l shows process flow sheet for the preparation of NTC ceramic compound
working upto 350°C
The present invention is described further with respect to the example, which is given
by way of illustration and hence, should not be considered to limit the scope of the
invention in any manner.
Example 1
Manganese di-oxide (MnCh) Analytical Reagent (AR) quality was taken in silica
crucibles and heated to a temperature of 1050°C in a muffle furnace. The MnO2 was
kept at this temperature for 4 to 5 hours in order to convert MnO2 to Mn3O4 The
structure of Mna is tetragonal and is confirmed by XRD. The material is then
furnace cooled. Mn3O4 is then ground in mortar and pestle and sieved through 250
size BSS mesh ( oxide (La2O3) and ground thoroughly in mortar and pestle to obtain the ceramic
mixture. Stearic acid (1%) and wax (1%) was then added and again ground using
alcohol. It was then slowly heated in order to remove the alcohol. The mixture was
again ground and sieved through 250 BSS Mesh. The material is characterized for
potential drop and resistance change. The mixture thus obtained having ceramic
powder, steric acid and wax is filled in about one foot long stainless steel tubes and
two sensing wires (chromel and alumel wires) are inserted into the powder inside the
tube. The powder is then compacted inside the tube by ramming. These tubes were
then sintered at 900°C for 4 to 5 hours so that the material becomes a hard mass. The
powder can otherwise be compressed at about 10 tonnes/Inch2 in a die to make
pellets/tablets. A detailed block diagram of depicting the process for preparing the
ceramic mixture and the thermistor thereof is shown in Figure 1. These ceramic
tablets/filled tubes with ceramic powder were characterized for potential drop and
drop in resistance. The tests were repeated several times for about one year to check
the stability/repeatability of the test results. The results of the test thus conducted are
tabulated in Table 1 given below.
The main advantages of the present invention are:
• It gives NTC characteristics.
• This material has resistance of the order of mega ohms at 25°C and this value
drops to 200-300 ohms between 300°C-350°C. Therefore, this material has
been used in fire safety sensors/devices for strategic applications.
• The material has good flowability. Therefore, it is possible to fill up this
material in small diameter and long tubes.
• The material does not degrade with time, temperature and other environmental
changes.
• The chemicals are easily available and processable.

We Claim:
1. A ceramic mixture composition, said ceramic mixture comprising 95 wt. %
tetragonal form of Mn3O4 and 5 wt. % La2O3.
2. A ceramic mixture composition as claimed in claim 1, wherein the ceramic mixture composition has resistance of the order of 2.5-4 mega-ohms at 25 -30°C and the resistance value drops to a value between 200 to 300 ohms at 300°C - 350°C.
3. A ceramic mixture composition as claimed in claim 1, wherein the ceramic mixture composition shows increase in potential from - 50 mV at 35°C to 13.9m V at 330°C.
4. A ceramic mixture composition as claimed in claim 1, wherein the ceramic mixture composition does not degrade with time.
5. A ceramic mixture composition as claimed in claim 1, wherein the ceramic mixture composition works at low as well as high temperatures.
6. A process for preparing a ceramic mixture composition of claim 1, the said process comprising the steps of:

a) heating MnO2 upto 1050°C for a time period ranging between 4 hr. to 5 hr to obtain tetragonal form of Mn3O4;
b) cooling the Mn3O4 of step (a);
c) grinding the Mn3O4 of step (b) to obtain Mn3O4of particle size less than 60 microns;
d) mixing the ground Mn3O4 of step (c) with 5 wt. % of La2O3;
e) grinding and sieving through a 250 size BSS mesh the mixture of Mn3O4 and La2O3 to obtain the ceramic mixture.

7. A process as claimed in claim 6 wherein in step (a), the MnO2 used is of analytical reagent grade.
8. A process as claimed in claim 6, wherein in step (b), the Mn3O4 is furnace cooled.

9. A process as claimed in claim 6,wherein in step (c), the Mn3O4 is ground in a mortar and pestle.
10. A process as claimed in claim 6, wherein in step (e), the mixture of Mn3O4 and La2O3 is ground in mortar and pestle.
11. A thermistor for sensing temperature wherein , the said thermistor comprising 98 % of ceramic mixture composition as claimed in claim 1 along with steric acid 1.0 wt % and wax as a base 1.0 wt %, the said base being provided with a first and a second electrodes made of conducting material that are being disposed away from each other.
12. A thermistor as claimed in claim 11, wherein the ceramic mixture comprises 95 wt. % tetragonal form of Mn3O4 and 5 wt. % La2O3.
13. A thermistor as claimed in claim 11, wherein the thermistor is used for sensing temperature in the range of 300° to 350°C.
14. A thermistor as claimed in claim 11, wherein the resistance of the sensor drops by 30 to 50% of its original value with every 20°C rise in temperature.
15. A thermistor as claimed in claim 11, wherein the resistance of the sensor drops by 40% of its original value with every 20°C rise in temperature.
16. A thermistor as claimed in claim 11, wherein the first and second electrodes are provided on the surface of the element assembly.
17. A thermistor as claimed in claim 11, wherein the first and second electrodes are provided inside the element assembly.
18. A process for preparing the thermistor of claim 14 having negative temperature coefficient of resistance for sensing temperature, said process comprising the steps of:

a) heating MnO2 to obtain tetragonal form of Mn3O4
b) cooling theMn3O4 of step (a);
c) grinding the Mn3O4 of step (b) to obtain Mn3O4 of particle size less than 60 microns;

d) mixing the ground Mn3O4 of step (c) with 5 wt. % of La2O3
e) grinding and sieving the mixture of step (d) to obtain a ceramic mixture;
f) adding steric acid and wax to the ceramic mixture of step (e);
g) grinding the mixture of step (f) optionally in the presence of an alcohol and sieving, and
h) compacting and sintering the ground mixture of step (g) and providing a first and a second electrodes to obtain the thermistor.
19. A process as claimed in claim 18, wherein in step (a), the MnO2 used is of analytical reagent grade.
20. A process as claimed in claim 18, wherein in step (a), the MnO2 is taken in a silica crucible and heated upto 1050°C for a time period ranging between 4 hr. to 5 hr. in a muffle furnace.
21. A process as claimed in claim 18, wherein in step (c), the Mn3O4 is ground in a mortar and pastel.
22. A process as claimed in claim 18, wherein in step (c), the Mn3O4 is sieved through a 250 size BSS mesh.
23. A process as claimed in claim 18, wherein in step (e), the mixture of Mn3O4 and La2O3 is ground in mortar and pestle.
24. A process as claimed in claim 18, wherein in step (e) ground mixture is sieved through a 250 size BSS mesh.
25. A process as claimed in claim 18, wherein in step (f), 1.0 wt. % steric acid and 1.0 wt. % wax are added to the ceramic mixture to improve flowability and binding capacity.
26. A process as claimed in claim 18 wherein in step (g), the mixture of Mn3O4, La2O3, steric acid, wax and alcohol is ground in a mortar and pestle.
27. A process as claimed in claim 18 wherein in step (g), the ground mixture is sieved through 250 size BSS mesh.
28. A process as claimed in claim 18 wherein if alcohol is added during grinding in step (g), the sieved mixture is gradually heated to remove the alcohol.
29. A process as claimed in claim 18 wherein in step (h), the ground mixture is compacted and sintered to form pellets, and the first and second electrodes are deposited on an outer surface of the pellet to obtain the thermistor.

30. A process as claimed in claim 18 wherein in step (h), the ground mixture is filled in tubes provided with the first and second electrodes, compacted and sintered to obtain the thermistor.
31. A ceramic mixture composition, a thermistor and process thereof as herein describe with reference to examples accompanying this specification.

Documents:

2934-DELNP-2004-Abstract-(06-11-2008).pdf

2934-delnp-2004-abstract.pdf

2934-DELNP-2004-Claims-(06-11-2008).pdf

2934-delnp-2004-claims.pdf

2934-DELNP-2004-Correspondence-Others-(06-11-2008).pdf

2934-delnp-2004-correspondence-others.pdf

2934-DELNP-2004-Description (Complete)-(06-11-2008).pdf

2934-delnp-2004-description (complete).pdf

2934-delnp-2004-drawings.pdf

2934-delnp-2004-form-1.pdf

2934-delnp-2004-form-18.pdf

2934-DELNP-2004-Form-2-(06-11-2008).pdf

2934-delnp-2004-form-2.pdf

2934-DELNP-2004-Form-3-(06-11-2008).pdf

2934-delnp-2004-form-3.pdf

2934-delnp-2004-form-5.pdf

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Patent Number

227829

Indian Patent Application Number

2934/DELNP/2004

PG Journal Number

07/2009

Publication Date

13-Feb-2009

Grant Date

20-Jan-2009

Date of Filing

29-Sep-2004

Name of Patentee

COUNCIL OF SCIENTIFIC AND INDUSTRIAL RESEARCH

Applicant Address

RAFI MARG, NEW DELHI-110 001, INDIA.

Inventors:

#	Inventor's Name	Inventor's Address
1	RAM PRAKASH BAJPAI	CENTRAL SCIENTIFIC INSTRUMENTS, ORGANISATION, CHANDIGARH,INDIA
2	MADAN LAL SINGLA	CENTRAL SCIENTIFIC INSTRUMENTS, ORGANISATION, CHANDIGARH,INDIA
3	VIJAY RAJARAM HARCHEKAR	CENTRAL SCIENTIFIC INSTRUMENTS, ORGANISATION, CHANDIGARH,INDIA
4	BALDEV RAJ	CENTRAL SCIENTIFIC INSTRUMENTS, ORGANISATION, CHANDIGARH,INDIA

PCT International Classification Number

H01 B1/00

PCT International Application Number

PCT/IB03/00784

PCT International Filing date

2003-02-25

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1			NA