930/MK296HP [ETC]

Analog Miscellaneous ; 模拟杂项\n


型号：	930/MK296HP
厂家：	ETC
描述：	Analog Miscellaneous 模拟杂项\n
文件：	总4页 (文件大小：212K)
中文：	中文翻译
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Model 930 Programmable Current Source

Description

Features

The Model 930 is a programmable current source that

provides an output current that stays constant with changes

in load impedance. The output voltage will vary as necessary

to maintain the desired value of constant current through the

load. Output current of the Model 930 can be set by means

of an external potentiometer or by a DC voltage. It has an

internal regulator and reference circuit to make the output

currentindependentofpowersupplyvariations.Supplyvoltage

can be unregulated and can range from +12V to +32V. The

compliance voltage (maximum output voltage for highest

load impedance) is dependent on the supply voltage level and

is rated at the supply voltage less 5 Volts.

Program Output by Potentiometer Setting

or Voltage Input

Wide Supply Range from +12V to +32V

Fast Response from 10 µs to Step Change

Well Regulated 10 megohms Output Impedance

Operation

The Model 930 output current can be programmed by a 1000

ohm potentiometer or by a voltage input. To set the current

withapotentiometer,connectthepotentiometerendterminals

across pins 1 and 7 and the wiper arm to pin 3. Connect pins

9,10and11toeachother.Thiswillprovidealinearadjustment

of output current from 0.5 mA to 50 mA. This is extended to

a range of 5 mA to 500 mA on the 296HP Power Booster

Mounting Kit.

Forvoltageprogramming,thepotentiometermustberemoved

(pins 1, 3, 7 left open) and a jumper must be connected across

pins 3 and 4. As with potentiometer programming, pins 9, 10

and 11 must be connected together. When connected for

voltage programming, an input voltage of zero to +10V

provides a linear output current of +0.5mA to +50mA.

FIGURE 1.

Need more output current? It’s easy, simply parallel the

outputs of several programmable current sources. For

example, the outputs of two Model 930/MK 296HP units can

be connected to the same load to provide a combined output

of up to one ampere.

Model 930 Connected for Potentiometer Programming of I₀.

Output or Compliance Voltage

The key parameter in applying constant current sources is the

range of load impedance. This determines the range of output

voltage needed to maintain a constant current through the

varying load impedance. For example, if the load were to vary

from 1 ohm to 200 ohms and the desired constant current

were 50 mA, then the output voltage range needed would be

50 mV to 10V. The power supply must be 5 Volts greater than

the compliance voltage or 15 Volts, in this case.

197

axFACTS:

2401 Stanwell Drive

Concord, CA 94520-4841

(510) 687-4411 • Fax (510) 687-3333

http://www.calex.com

Model 930 Programmable Current Source

Mechanical Specifications

Specifications

Model

Output

930

930/MK296HP

Output Current

+0.5 to +50 mA

0 to Supply less 5 Volts

5 mA to 500 mA

0 to Supply less 6 Volts

Compliance Voltage

(Output may not be negative with respect to common

pin 6)

Stability

Output Current Regulation

Vs. Supply Volts, DC

5 mA/Volt, max.

50 mA/Volt, max.

10 mA/Volt, typ.

50 mA/Volt, max.

20 mA/Volt, typ.

100 mA/Volt, max.

120 cps rejection

Output Impedance

at DC

at 1 MHz

10 megohm, typ.

500 ohms, typ.

±5 mA/°C max.

1 megohm, typ.

10 ohms, typ.

±50 mA/°C max.

Temperature Coefficient

Programming Inputs

Potentiometer

External 1K

Voltage Input

0 to +10 Volts

Input Range

Scale Factor

Accuracy

5 mA/Volt

50 mA/Volt

±1.5% of Full Scale

±3% of Full Scale

0.2 mA, typ.

0.5 mA, max.

0.5 mA, typ.

5 mA, max.

Zero Current

Input Impedance

Frequency Response

Response Time

1 megohm, ±5%

Pin Assignments

100 ohm Load;

10 kHz, typ.

10 ohm Load;

10 kHz, typ.

Pin Assignments

Program Pot CW End

Response to step change in

load, 10 to 100 ohms in 100 ns

10 ms, max.

Voltage Program Input

Pot Swinger

Power Supply Requirements

Voltage Program

Connect to Pin 3

Potentiometer Program

to Full Scale

+12 to +32 Volts

Power Supply Postive

Power and Output Return

Program Pot CCW End

Output Current - to Load

Feedback

+14 to +32 Volts

Derate from 50 mA to

40 mA at Vs = 14 Volts

to 12 Volts

+14 to +32 Volts

Derate Output to 400 mA

at + 12 Volts

Voltage Program

Current Required:

No Load, 12 to 32 Volts

4 mA to 10 mA

Internal 20 ohm - RS

Output Transistor Emmiter

Total Current at Full Load

60 mA, max.

510 mA, max.

Power Dissipation Limits

Dissipation at 25°C, Ambient

Dissipation at 70°C, Ambient

* Power Dissipation= I₀(VS-3.5 - I₀x RL) where: VS=Supply Voltage, I₀= Output

See Curve

6 Watts, max.*

3.1 Watts, max.*

Current, RL = Load Resistance in ohms.

Derate 0.063 Watt/0° to 3.1 Watts at 70°C Ambient.

CAUTION: Heat Sink will be 100°C at 6 Watts and 25°C Ambient still air.

MODEL 930/MK296HP

MODEL 930

MAXIMUM DISSIPATION vs. AMBIENT TEMPERATURE

MAXIMUM PACKAGE POWER vs AMBIENT TEMPERATURE

MINIMUM VS vs. LOAD CURRENT for VOLTAGE PROGRAM

2.0

P_D= (V_S- 4 - I_LOAD

R_LOAD) I _LOAD

1.3

0.7

0.0

197

3.1 W

AMBIENT TEMPERATURE (Deg. C)

LOAD CURRENT (mA)

axFACTS:

2401 Stanwell Drive

Concord, CA 94520-4841

(510) 687-4411 • Fax (510) 687-3333

http://www.calex.com

Model 930 Programmable Current Source

Model 930/MK296HP

Mounting Kits

The Model MK 296 and MK 296HP Mounting Kits are for

resistive or voltage programming of the Model 930. The MK

296HP is a high current version with a power transistor to

increase the range to 0.5A. The Model MK 298 allows

adjustment of the “live zero” for 4 to 20 mA systems. All three

mounting kits consist of the PC board, PC connector with

built-in guides, and the necessary potentiometers. When

ordered with the Model 930 the unit will be delivered mounted.

They can be plugged into the 22-100MK Power Source Kit

(page F2) or used with any of the CALEX supplies or DC/DC

Converters.

Mounting Kit Model 930/MK296HP

For Voltage Programming

the pot must be removed

Model 930/MK296

and jumper J1 must be

added

Model 930/MK298

Mounting Kit Model 930/MK298

Note: +V_Smust be a regulated (0.1% or better) source, and

be 14 Volts to 24 Volts.

For the MK 298 the output current can be programmed for

input voltages other than 0 to 10 Volts by changing the value

of RS.

197

To Calibrate: repeat as necessary

The formula for RS is: RS = V_in(max)

10 Ι₀(max)

1. With the max V_inadjust the span pot. for max Ι_out

2. With min V_inadjust the zero pot. for min Ι_out

Where: V_in(max) = max programming (input) voltage

Ι₀= max output current

axFACTS:

2401 Stanwell Drive

Concord, CA 94520-4841

(510) 687-4411 • Fax (510) 687-3333

http://www.calex.com

Model 930 Programmable Current Source

Transducer Bridge Drive

Slip-ring Application

A bridge circuit located a significant distance from the exciting

and measuring system can be effected by unknown and or

changing drive line resistance. This can be eliminated by

driving the bridge with a constant current. The following

equation is used to determine the transducer resistance. The

voltage across the bridge is determined by the transducer

resistance.

Slip-rings are often required to interface across a rotating

boundary. As an example, consider a temperature or strain

measurement that uses a 100 ohm transducer. Used in a

bridge circuit, every 1 ohm of varying line resistance could

contribute up to 1% error for each line that crosses the slip-

ring interface.

By using the sensor as a single resistance element and

constant current excitation as in Figure 5, the errors due to the

slip-ring changing resistance can be eliminated. If the 100

ohm transducer required 10 mA of drive current, the Model

930 could be operated from a 15 Volt supply allowing the slip-

ring and line resistance to vary from zero ohms to 900 ohms

without effecting the drive to the transducer. This also

eliminates the curve fitting step required by non-linear bridge

circuit outputs.

The transducer resistance, RG, when in the upper arm, is

determined by the following equation:

RG = r (Ι x r - 3 Vo) / (Ι x r + Vo)

where r is the resistance of the 3 fixed arms of the bridge. Ι

is the constant current drive, and Vo is the bridge output

voltage. If RG is in the lower arm of the bridge, the minus and

plus signs in the equation are reversed.

The measurement path would, in most cases, contribute a

negligible error. A typical volt meter has 10 megohms input

resistance, so a 1000 ohm series resistance change due to

the slip-rings would contribute only 0.01% of reading error.

Resistance Temperature

Measurement (RTD)

RTD’s are used to make accurate and stable temperature

measurements as one arm of a Wheatstone Bridge. Although

the RTD is more linear than the thermocouple, it still requires

curve fitting for best accuracy. A bridge circuit produces a

non-linear output for a linear change and thus requires an

additional curve fit. A single RTD driven by a constant current

source eliminates the errors associated with the bridge

method, including variable line resistance, although 4 wires

are required.

The Model 930 is an excellent constant current source for this

application. The 930 scale factor is set by an external RS

value of 10,000 ohms, providing a full scale output of 100

microamp. This resistor should be a 0.1%, 25 ppm, metal film

resistor. The other resistor values shown in Figure 4 provide

a small adjustment range around a 100 microamp output

current. This low level of current minimizes RTD self heating

error and produces a voltage change of 38.5 microvolts per

degree across a standard 100 ohm RTD with an alpha of

0.00385.

FIGURE 5.

Voltage-to-Current Converter

A Model 930 can be teamed up with a Model 178

instrumentation amplifier to convert low-level transducer

bridge voltages to output currents compatible with process

control equipment. The Model 930 is connected for a voltage

input. The output current range can be selected by varying

the impedance between pins 10 and 11.

The components shown in Figure 4 will provide a current

source with a stability of 0.02% per degree ambient, from 0

to +70°C.

If a copper RTD is being used, the current source is easily

changed to 500 microamps by replacing the 10 kRS with a

2000 ohm, 0.1%, 25 ppm stable resistor.

197

FIGURE 6.

Other Applications

Other applications include charging batteries at a constant

current rate, Hall effect sensors, microplating using the

electrolytic process, and testing gyro torquers.

FIGURE 4.

axFACTS:

2401 Stanwell Drive

Concord, CA 94520-4841

(510) 687-4411 • Fax (510) 687-3333

http://www.calex.com

930/MK296HP [ETC]

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