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Model 12C Cryogenic Temperature Monitor

Specifications


UpUp Model 12C General Specifications

Input Channels

The Model 12C has two input channels, each of which may be independently configured for any of the supported sensors. Each input is independent. There is no scanning or multiplexing.

Sensor Connection: 4-wire differential. DB9 Connectors.

Sensor Types: See Supported Sensor Table.

Sensor Selection: Front Panel or remote interface.

Input Configurations: See input specifications table.

Excitation Modes: Constant-Current or Constant-Voltage.

AC Excitation Frequency: 1.625Hz bipolar square wave.

Voltage Excitations: 10mV. Minimum excitation current is 100nA, maximum is 1.25mA.

Sample Rate:15Hz per channel.

Digital Resolution: 24 bits.

Measurement Accuracy: See input specifications table.

Measurement Drift: 30ppm/oC.

Isolation:Input channels are not isolated.

Measurement Filter: 0.5, 1, 2, 4, 8, 16, 32 and 64 Seconds.

Calibration Curves: Built-in curves for industry standard sensors plus eight user curves with up to 200 entries each. Interpolation is performed using a Cubic Spline.

User Interface

Display Type: Graphics TFT LCD, 4mm and 8mm character height.

Number of Inputs Displayed: Up to eight.

Keypad: 4-key sealed Silicon Rubber.

Temperature Display: Six significant digits, autoranged.

Display Update Rate: 0.5 Seconds.

Display Units: K, C, F or native sensor units.

Display Resolution: Up to seven significant digits.

Data Logging

Data logging is performed to an internal 800 entry circular buffer and is time-stamped with a real-time clock. Buffer memory is non-volatile and will retain valid data without AC power. All eight input channel temperatures are recorded.

Status Outputs

Audible and Visual Alarms: Independent audible remote and visual alarms.

Relays: Two dry-contact relays. N.O. contacts available. Contact ratings: 10A@125VAC or 5A@30VDC.

Remote Interfaces

Maximum reading rate for all interfaces is 10 rdg/s.

Ethernet: Connects to any Ethernet Local Area Network. Electrically isolated. TCP and UDP servers provide remote control by using an ASCII command language. HTTP provides built-in web server. SMTP sends e-mail based on alarm conditions.

RS-232: Standard null modem. Data rates are 9600, 19,200, 38,400 and 57,200 Baud. Connector is a DB-9 plug.

IEEE-488.2 (GPIB): External Option, field installable.

Programming Language: IEEE-488.2 SCPI compatible.

LabVIEW™drivers available for all interfaces.

General

Ambient Temperature: 25°C ± 5°C for specified accuracy.

Mechanical: 5.6”W x 2.9”H x 8.8”D.

Weight: 3.5 Lbs.

AC Power Requirement: IEEE-802.3af Power over Ethernet (requires powered hub or injector) or 5 - 48V AC/DC

AC Power Switch: Front panel.

Conformity: European CE certified.

Calibration: NIST traceable.

UpUpModels 12C Supported Sensors

Silicon Diode sensors from Cryo-con or any other manufacturer are directly supported over their full 1.4 to 500K range using built-in calibration curves and sensor data. Plus, non-volatile Flash memory is available for several custom or calibrated sensors.

Platinum RTD sensors can use built-in DIN 43760 (IEC 750) standard setups for 100Ω or 1,000Ω devices. The DIN standard is used for temperatures from 70K to 1020K and extends it down to 30K for cryogenic use. A unique feature of Model 12C is the use of an AC ratiometric resistance bridge to cancel low frequency noise.

The Model 12C provides robust support for the Negative Temperature Coefficient (NTC) sensors commonly used by cryogenic applications. They include Ruthenium-oxide, Cernox™, Carbon-Glass, Germanium, Carbon-Ceramic and several others. Since they have a negative temperature coefficient, the constant-voltage measurement method will reduce, rather than increase, power dissipation in the sensor as temperature decreases. By maintaining the lowest possible power level, sensor self-heating is minimized and useful temperature range is greatly increased.

An additional advantage to constant-voltage biasing is that NTC resistors lose sensitivity in the upper part of their range. By auto-ranging excitation current to maintain a constant voltage, sensitivity and noise immunity in that range is greatly improved.

Sensor excitation used in conjunction with the constant-voltage feature is a 1.625Hz bipolar square wave. This effectively cancels thermal EMF induced offset errors that sometimes occur in cryogenic systems.

page Listing of Supported Sensors

Thermocouple sensors are supported by using an optional external module that provides amplification, cold-junction compensation and connection to copper. The module is powered by the monitor and connects directly to any of the sensor inputs.


Model 12C Supported Sensors
  Temperature Range Example Sensors
Diode 1.4 - 500K Cryo-con S900 / S950
SI-440, 430, 410
Lakeshore DT-670, 470
Platinum RTD 14 - 1200K Cryo-con CP-100
Cryo-con GP-100
Cryo-con XP-100
Cryo-con XP-1K
Rhodium-Iron 1.4 - 800K Oxford PHZ 0002
Germanium
 Thermistor
500mK - 400K AdSem, Inc.
Carbon Glass 1.4 - 325K Lakeshore CGR-1-500

CLTS

4K - 300K

Vishay CLTS-2B

Cernox™ 500mK - 325K Lakeshore, all types
Carbon-Ceramic 500mK - 300K TMi-A1
Ruthenium Oxide 500mK - 200K SI RO-600

UpUp

Model 12C Input Specifications


Input Specifications
  Diode sensors PTC resistor sensors NTC resistor sensors
Constant-Voltage
Input Configuration Constant-Current DC Constant-Current AC Constant-Voltage AC
Input Range 0.1V - 1.8V 1.0mA: 0.1 -400Ω
100µA: 1.0 - 4.0KΩ
Minimum: 5Ω
Maximum: 100KΩ
Accuracy:
% Rdg ± % Range
0.004% ± 80μV< 0.01% ± 0.0005% 14 to 30K: 0.05% ± 0.05%
0.5 to 2M: 0.15% ± 0.15%
Resolution:
% Range
10μV 0.0003% 0.0003%
Excitation 10μA DC 1.0mA, 100μA 10mV
1.25mA to 100nA

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Specifications subject to change without notice. ©Cryogenic Control Systems, Inc. 1998 - 2017