AD595CQ Analog Devices Inc, AD595CQ Datasheet - Page 8

AD595CQ

Manufacturer Part Number

AD595CQ

Description

IC THERMOCOUPLE A W/COMP 14CDIP

Manufacturer

Analog Devices Inc

Type

Low Powerr

Datasheets

1.AD595AQ.pdf (8 pages)

2.AD594AQ.pdf (4 pages)

Specifications of AD595CQ

Rohs Status

RoHS non-compliant

Function

Thermocouple Amplifier

Topology

Ice Point Compensation, Overload Detection

Sensor Type

External

Output Type

Voltage

Output Alarm

Yes

Output Fan

Voltage - Supply

5 V ~ ±15 V

Operating Temperature

-55°C ~ 125°C

Mounting Type

Through Hole

Package / Case

14-CDIP (0.300", 7.62mm)

Ic Output Type

Voltage

Sensing Accuracy Range

Â± 1Â°C

Supply Current

160ÂµA

Supply Voltage Range

5V To 30V

Sensor Case Style

DIP

No. Of Pins

Termination Type

DIP

Amplifier Type

Instrumentation

Bandwidth

15 kHz

Converter Type

Monolithic theremocouple amplifier

Current, Input Bias

0.1 μA

Current, Output

±5 mA

Current, Quiescent Supply

160 uA (Typ.) @ 25 °C

Current, Supply

160 μA

Package Type

CDIP-14

Temperature, Operating, Maximum

125 °C

Temperature, Operating, Minimum

-55 °C

Temperature, Operating, Range

-55 to +125 °C

Voltage, Supply

+5 to ±15 V

Low Impedance Voltage Output

10 mV⁄°C

Wide Power Supply Range

+ 5 V to 615 V

Low Power

1 mW typical

Filter Terminals

DIP

Rohs Compliant

Accuracy

Â± 1

Accuracy %

Sensing Temperature

Lead Free Status / RoHS Status

Contains lead / RoHS non-compliant

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Current page: 8 of 8
Download datasheet (137Kb)

AD594/AD595

THERMOCOUPLE BASICS

Thermocouples are economical and rugged; they have reason-

ably good long-term stability. Because of their small size, they

respond quickly and are good choices where fast response is im-

portant. They function over temperature ranges from cryogenics

to jet-engine exhaust and have reasonable linearity and accuracy.

Because the number of free electrons in a piece of metal de-

pends on both temperature and composition of the metal, two

pieces of dissimilar metal in isothermal and contact will exhibit

a potential difference that is a repeatable function of tempera-

ture, as shown in Figure 14. The resulting voltage depends on

the temperatures, T1 and T2, in a repeatable way.

Since the thermocouple is basically a differential rather than

absolute measuring device, a know reference temperature is

required for one of the junctions if the temperature of the other

is to be inferred from the output voltage. Thermocouples made

of specially selected materials have been exhaustively character-

ized in terms of voltage versus temperature compared to primary

temperature standards. Most notably the water-ice point of 0 C

is used for tables of standard thermocouple performance.

An alternative measurement technique, illustrated in Figure 15,

is used in most practical applications where accuracy requirements

do not warrant maintenance of primary standards. The reference

junction temperature is allowed to change with the environment

of the measurement system, but it is carefully measured by some

type of absolute thermometer. A measurement of the thermo-

couple voltage combined with a knowledge of the reference

temperature can be used to calculate the measurement junction

temperature. Usual practice, however, is to use a convenient

thermoelectric method to measure the reference temperature

Figure 14. Thermocouple Voltage with 0 C Reference

TEMPERATURE

0.035 0.010

(0.89 0.25)

0.125

(3.18)

UNKNOWN

(1.02) R

MIN

0.040

0.047 0.007

(1.19 0.18) 0.017

CONSTANTAN

PIN 1

(

0.430 (10.92)

(17.78 0.25)

0.43 +0.08

0.700 0.010

+0.003

–0.002

–0.05

TO-116 (D) Package

(

(2.54)

0.100

BSC

IRON

0.265

(6.73)

0.085 (2.16)

0.180 0.030

(4.57 0.76)

CONSTANTAN

0.290 0.010

(7.37 0.25)

0.30 (7.62) REF

(7.87 0.25)

0.31 0.01

Dimensions shown in inches and (mm).

REFERENCE

ICE POINT

OUTLINE DIMENSIONS

0.095 (2.41)

0.01 0.002

(0.25 0.05)

–8–

and to arrange its output voltage so that it corresponds to a ther-

mocouple referred to 0 C. This voltage is simply added to the

thermocouple voltage and the sum then corresponds to the stan-

dard voltage tabulated for an ice-point referenced thermocouple.

The temperature sensitivity of silicon integrated circuit transis-

tors is quite predictable and repeatable. This sensitivity is

exploited in the AD594/AD595 to produce a temperature re-

lated voltage to compensate the reference of “cold” junction of a

thermocouple as shown in Figure 16.

Since the compensation is at the reference junction temperature,

it is often convenient to form the reference “junction” by connect-

ing directly to the circuit wiring. So long as these connections

and the compensation are at the same temperature no error will

result.

3.175)

0.125

(0.812)

MIN

(7.87)

0.032

0.310

Figure 15. Substitution of Measured Reference

Temperature for Ice Point Reference

Figure 16. Connecting Isothermal Junctions

CONSTANTAN

PIN 1

(19.55 0.39)

0.600 (15.24)

0.77 0.015

(0.457)

0.018

BSC

CONSTANTAN

IRON

Cerdip (Q) Package

IRON

0.100

(2.54)

BSC

0.260 0.020

(6.6 0.51)

0.035 0.010

(0.889 0.254)

SEATING

PLANE

0.180 0.030

(4.57 0.76)

CuNi–

0.300 (7.62)

FOR PROPERLY

SCALED V

REF

= V

0.010 0.001

(0.254 0.025)

= f(T

0.148 0.015

(3.76 0.38)

)

REV. C

AD595CQ Analog Devices Inc, AD595CQ Datasheet - Page 8

AD595CQ

Specifications of AD595CQ

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