Model 9500
Automated “Two-Pressure” Humidity Generation System
FEATURES
- 0.17% * R + 0.016 RH Uncertainty 5,6
- Traceable to SI 8
- High Flow Capability of 10 to 100 L/min
- Based on NIST Proven "Two-Pressure" Principle
- Generate: RH, DP, FP, PPM, Multipoint Profiles
- Computerized Internal Transducer Calibration
- Computes System Uncertainties in Real Time
- Automatically Applies Enhancement Factors
- 9500 ControLog® Embedded Automation Software
- HumiCalc® with Uncertainty Mathematical Engine
5 Uncertainty is not specified at flow rates below 10 slpm and above 100 slpm.
6 Uncertainty values represent an expanded uncertainty using a coverage factor, k=2, at an approximate level of confidence of 95%.
8 Traceable to the International System of Units (SI) through a national metrology institute (NIST) recognized through a CIPM MRA.
SPECIFICATIONS
| SPECIFICATIONS | 1 |
|---|---|
| Relative Humidity Range (Test Chamber @ 14.7 psiA) | 5 to 98 %RH |
| Dew Point Temperature Range (Test Chamber @ 14.7 psiA) | –35 to 70 °C |
| Frost Point Temperature Range (Test Chamber @ 14.7 psiA) | –32 to 0 °C |
| Bath Temperature Range: 1 | 0 to 72 °C |
| Bath Temperature Control Stability: 2 | 0.002 °C |
| Bath Temperature Heating Rate: from 0 to 72 °C | 0.5 °C per Minute (average) |
| Bath Temperature Cooling Rate: from 72 to 0 °C | 0.5 °C per Minute (average) |
| Chamber Temperature Uniformity: 3 | 0.008 °C |
| Gas Type: | Air or Nitrogen |
| Gas Pressure Rating: (MAWP) | 350 psiG |
| Gas Flow Rate Range: | 10 to 100 L/min |
| Gas Flow Rate Specification: | ±2% of full Scale |
| Supply Pressure Specification: | ±1.25 psiG |
| Saturation Pressure - Low Range: | Ambient to 45 psiA |
| Saturation Pressure - High Range: | 45 to 325 psiA |
| Test Chamber Pressure Range: | Ambient to 23 psiA |
| Display Resolution: | 0.001 |
| Test Chamber Dimensions: | 12" H x 12" W x 12" D (30.5 cm x 30.5 cm x 30.5 cm) |
| Physical Dimensions: | 38.25” H x 60” W x 36” D (97.15 cm x 152.4 cm x 91.44 cm) |
UNCERTAINTY 5,6
| UNCERTAINTY | 5,6 | |
|---|---|---|
| Relative Humidity: 5 to 98 %RH, 10 to 100 L/min | 0.17% * R + 0.016 | |
| Example 1: If the %RH reading is 50 %RH, the uncertainty would then be: 0.17% * 50 + 0.016 = 0.101 | ||
| Example 2: If the %RH reading is 10 %RH, the uncertainty would then be: 0.17% * 10 + 0.016 = 0.033 | ||
| Dew Point: –27 to + 70 °C Dew Point (Ps <= 140 psiA), 10 to 100 L/min | 0.03 °C | |
| Dew Point: –35 to –27 °C Dew Point (Ps > 140 psiA), 10 to 100 L/min | 0.05 °C | |
| Frost Point: –22 to 0.01 °C Frost Point (Ps <= 100 psiA), 10 to 100 L/min | 0.03 °C | |
| Frost Point: –32 to –22 °C Frost Point (Ps > 100 psiA), 10 to 100 L/min | 0.05 °C | |
| Temperature: 0 to 72 °C 7 | 0.015 °C | |
| Test Chamber Pressure: Ambient to 15 psiA | 0.0021 psiA | |
| Low-Range Saturation Pressure: Ambient to 45 psiA | 0.0042 psiA | |
| High-Range Saturation Pressure: 45 to 325 psiA | 0.03 psiA | |
1 Using glycol/water as the temperature bath heat transfer fluid from 0 to 5 °C and water as the temperature bath heat transfer fluid from 5 °C to 72 °C.
2 Temperature Control Stability is defined as the maximum deviation from a best fit line, as measured by the bath temperature control sensor. If data is logged digitally, the best fit line will be defined as the average value over the 10 minute period. All measurements made with an insulated cover in place over bath.
3 Chamber Temperature Uniformity is defined as the maximum temperature difference between any two locations over the temperature range of 0 °C to 72 °C when using a thermal insulator over the bath, such as hallow bath balls. Locations are defined at the center of the chamber lid access ports, approximately 5" into the chamber.
4 Refer to "Model_9500_Uncertainty_Analysis.pdf" for more information.
5 Uncertainty is not specified at flow rates below 10 slpm and above 100 slpm.
6 Uncertainty values represent an expanded uncertainty using a coverage factor, k=2, at an approximate level of confidence of 95%.
7 Includes saturation temperature, chamber temperature, bath temperature, pre-saturator temperature, and exp-valve temperature.
UTILITIES
| UTILITIES | Specs |
|---|---|
| Electrical Power: | 200-220/208-230 V~, 50/60 Hz, 20 A, 3 Ø, 4 Wire |
| Gas Supply: | 350 psiG @ 100 L/min |
| Cooling Water: | 2 gpm (8 L/min) Maximum @ 21 °C |
ENVIRONMENTAL
| ENVIRONMENTAL | |
|---|---|
| Operating Temperature: | 15 to 30 °C |
| Storage Temperature: | 0 to 50 °C |
| Humidity: | 5 to 95% Non-condensing |
PRINCIPLE OF OPERATION
The “two-pressure” humidity generation process involves saturating air or nitrogen with water vapor at a known temperature and pressure. The saturated high pressure air flows from the saturator, through a pressure reducing valve, where the air is isothermally reduced to test pressure at test temperature. Humidity generation by the 9500 does not depend upon measuring the amount of water vapor in the air, but rather is dependent on the measurements of temperature and pressure alone. System precision is determined by temperature and pressure measurement accuracy, and on the constancy of the measurements throughout. When setpoint equilibration has been reached, the indication of saturation temperature, saturation pressure, test temperature, and test pressure, may be used in the determination of all hygrometric parameters.
Elemental Schematic of the 9500 generator.
COMPUTER CONTROL
9500 Main Computer Screen
Control / Display Screen
The Model 9500 Humidity Generator encompasses a high-performance stand-alone Data Acquisition/Computer that performs all functions required for humidity generation and control. The Data Acquisition System employs 24 bit I/O modules with integrated signal conditioning to acquire data and control the operation of generating humidity. The Computer utilizes an embedded based operating system in conjunction with specialty software to control and interface with the human to machine interface (HMI) computer running ControLog. ControLog is an embedded software application that fully automates the operation of the Thunder Scientific 9500 Humidity Generator and allows various device connections through a number of different interfaces. Data from the generator and attached devices is automatically retrieved and stored for viewing in either numerical or graphical format in real time or post process. Data can be transferred off the system via a USB drive for further viewing, post processing and printing using an external Windows PC (not included). The ControLog software also provides the primary interface to the operator via the multi-point touch LCD and keyboard.
Temperature Calibration Screen
Temperature Calibration Coefficients Screen
Temperature Controlled Bath: The 9500 humidity generating system incorporates a computer controlled temperature bath. Bath temperature is digitally controlled by the computer at any value between 0 °C and 72 °C using PID (proportional-integral-derivative) algorithms. The test chamber, saturators, heat exchangers, and connecting tubing are immersed in approximately 20 gallons of distilled water that is circulated at the rate of 50 gallons per minute by a magnetically coupled centrifugal pump. Fast fluid circulation provides the temperature conditioning of these components, resulting in long term bath stability and uniformity. This allows a very stable humidity to be generated.
Pressure And Flow Control: Pressure control and mass flow control are accomplished through computer actuation of electromechanical valve assemblies. Saturation pressure, chamber pressure, and mass flow are measured continuously and controlled using PID algorithms similar to those employed in temperature control.
Calibration: Proper calibration of the temperature and pressure transducers ultimately determines the accuracy of the generator. The 9500 employs an integral programmatic calibration scheme allowing the transducers to be calibrated while they are electrically connected to the humidity generator. Coefficients for each transducer are calculated by the computer and stored to memory.
9500 Test Chamber
9500 Test Chamber View
The 9500 humidity generating system incorporates a completely immersed test chamber, with internal dimensions of 12" x 12" x 12" (305 mm x 305 mm x 305 mm). Test chamber pressure range is ambient to 20 psiA. The main chamber cover is removable utilizing quick release hold downs. Removal of the chamber cover allows a full 12 inch by 12 inch access to the test space. Access is also available through two 3.65" diameter ports in the chamber cover or two 1.125" inside diameter port cover adapters.
(Shown with the optional 4 Port Chamber lid)
APPLICATIONS
The test chamber can accommodate various solid state sensors, chilled mirror hygrometers, psychrometers, hygrothermographs, and material samples for environmental testing. Virtually any humidity and temperature may be generated, for any length of time, within the operational limits of the generator. The output or recording of the device under test may then be compared with the generator’s printed data for analysis.
Chilled Mirror Hygrometers: Install the actual chilled mirror head into the chamber or insert a sample tube through the test port and draw a sample through the chilled mirror head and you can: verify mirror temperature measurement accuracy (calibration) when the hygrometer is in thermal equilibrium with its environment; perform operational checks of the heatpump and optical components before and after mirror cleaning and balancing; determine whether the hygrometer is controlling the mirror deposit in the liquid phase or ice phase when operating at dew and frost points below 0 °C; determine if the hygrometer is correctly calculating other humidity parameters; determine hygrometer’s repeatability, stability, and drift characteristics.
Humidity Sensors And Chart Recorders: Insert your humidity probes through a test port in the chamber or install the hygrothermograph into the chamber and you can: determine humidity calibration accuracy and/or characterize humidity sensitivity by subjecting the humidity sensor to a variety of humidity levels; perform operational checks such as the sensing systems capability to correctly calculate and display other humidity parameters; determine the repeatability, stability, hysteresis, and drift characteristics of various humidity sensing systems.
Environmental Testing: The 9500 can serve as a test bed for evaluation and R&D of humidity sensors, humidity sensing systems, and humidity sensitive products, e.g., polymers, composites, film, magnetic medium, pharmaceuticals, soil hydrology, consumables, electronics, optics, etc.
REFERENCE DOCUMENTS
Model 9500 Humidity Generation System Documents
Series 9500 operation and maintenance manual for the automated two-pressure humidity generator.
- 9500 Humidity Generator Manual (11.6 MB)
- Model 9500 Humidity Generator Data Sheet (3.2 MB)
Model 9500 Uncertainty Analysis
This document describes a complete uncertainty analysis of the Model 9500 in accordance with NIST Technical Note 1297. Each error source is identified, quantified, and combined to form an expanded uncertainty using a coverage factor, k=2, at an approximate level of confidence of 95%.
Product Options
Here are the options available for the Model 9500 humidity generation system.
Model 9500 Humidity Generator
Model 9500 Humidity Generator includes:
- Certificate of Calibration with Data Traceable to (SI)
- ControLog® Embedded Automation Software
- HumiCalc® Humidity Conversion Software with Uncertainty
- Computer (HMI) is an Advantech UTC-520
- USB Cherry Electronics Brand Keyboard & Mouse
- Power Cord Assembly
- 1/4” MPT Air In Plug
- 3 Each 1/2” MPT Water and Air In Plugs
- 3/4” MPT Cap Plug
- 2 Cooling Water Hose Assemblies
- Electrical Power: 200-220/208-230 V~, 50/60 Hz, 20 A, 3 Ø, 4 Wire
4 Port Chamber Lid Assembly
The 4 Port Chamber Lid (C4PL) has 4 separate instrument feed thru ports to calibrate several humidity probes at the same time.
Specify this option code when ordering. (C4PL)
Insulated Bath Covers (IBC)
The Insulated Bath Covers (IBC) provide a much better insulation for the 9500 chamber bath which allows the system to achieve a faster temperature stabilization.
The bath covers are made with a polished stainless steel and a compact insulation inside plus they have chrome handles for easy removal and they have probe cable slots in three locations.
Specify this option code when ordering. (IBC)
Get QuoteAuxiliary item for this model
Cooling Water Hose (CWH) Assembly
The Cooling Water Hose (CWH) is used to feed water into the condenser to cool the system down. The system is provided with these hoses at the time of purchase, but you can add these as replacements for the system.
Specify this part code when ordering. (CWH)
Get QuoteClick the "Get Quote" button or go to the RFQ page for a quote.
Shipping Weights & Measures
| Model | Dimensions | Weight |
|---|---|---|
| 9500 Generator | 48" x 72" x 53" (123 x 183 x 135 cm) | 1400 lbs. (635 kg) |