Facilities and Testing
Black Liquor Evaporator Scaling Facility. A bench-scale heated pressure vessel is used to concentrate weak black liquor and determine when soluble scale precipitates. During an evaporation run, we monitor the size distribution of the particles in the liquor to determine the solids content when crystallization begins. After crystallization filtered samples of the crystals can be collected for chemical analysis and determination of the crystal species. This information can help diagnose scaling problems in multiple effect evaporators. We also have the capability to measure the boiling point rise as well as viscosity during evaporation, over a range of solids and temperatures.
Portable Fouling Test Unit (PTFU). RBI has patented a device consisting essentially of two (or more) annular flow test cells in parallel. One cell serves as the reference while the other(s) serve as simultaneous test cases. Each cell is made up of an electrically heated rod within an insulated tube. Process fluid (e.g. black liquor) flows in the annulus and scale forms on the rod. By using multiple cells, different conditions, such as Reynolds number or surface temperature, can be compared with respect to scale formation. Anti-fouling additives can also be evaluated with direct comparison to a reference cell containing no additive. The PTFU is designed for air transport, and fits in two large Pelican-type cases. We are pursuing funding to build and test a prototype in a mill.
Viscometers Two Brookfield viscometers are available for testing. The online unit can be used in conjunction with the bench top evaporator to measure viscosity over a wide range of conditions up to 140 °C, 40 psig and up to 72% solids content. An offline bench top unit is also available for measurements at low pressure.
Laminar Entrained Flow Reactor (LEFR) This reactor can be used to study combustion chemistry. The LEFR allows tight control over temperature, residence time, and gas composition. We have studied sulfur release and recapture, potassium and chloride chemistry, heavy metal release, and NOx/NH3 chemistry. A is used to burn small black liquor particles (100 microns).
Model Char Bed Reactor. A 4-inch square crucible placed within furnace serves as a small scale char bed reactor. Gas composition and temperature are controlled to mimic the conditions in a recovery boiler bed using the mill’s own liquor to form the char. Particles in the range of 1 to 100 microns are ejected from the bed and entrained by the rising gases. Such particles contribute to convective pass fire-side fouling in recovery boilers. These particles are sampled by deposition on a cooled probe (for SEM) as well as dissolved in a wet scrubber (for chemical analysis). A visual camera captures the char bed surface activity. In addition, char bed chemistry and kinetics can be studied.
Single Drop Reactor. The combustion behavior of black liquors can be measured using this furnace, the data includes the times for drying, devolatilization, and char burning in an environment similar to what is found in recovery boilers. In addition the swelling behavior of burning particles can be determined. This fundamental data provides a basis for understanding and modeling the behavior of in-flight combustion of black liquor droplets.
Understanding Crystallization during Evaporation
IPST has been a global leader in kraft process chemical recovery research and development since the 1970s. A recent focus of our work has been a cutting-edge investigation of sodium salt crystallization during black liquor evaporation. We have been able to relate observed crystallization phenomena to the costly problem of evaporator fouling and plugging. Our activity in this field now ranges from fundamental studies of crystal structure to mill testing of fouling reduction concepts. Our results also have applications in a range of other industrial processes from nuclear waste remediation to aluminum refining. The long term goal of our team is to help the pulp and paper industry reduce oil and gas use 1) by maximizing steam and power generation from black liquor - a biomass fuel byproduct of the wood pulping process, and 2) by reducing steam consumption in black liquor evaporators. Our work also helps mills remain profitable by reducing the manufacturing costs associated with lost production for equipment cleaning. Our strengths in sensors and controls, evaporator fouling, and liquor cycle optimization also supports the deployment of a new generation of technology including integrated forest biorefinery concepts and black liquor gasification.
How to Request Testing
- Send e-mail to firstname.lastname@example.org with details regarding the nature of the request, the tests required and the problem or issue that is to be resolved. Provide billing contact name and address.
- Samples via courier (UPS, FedEx, DHL, etc.) may be sent to the attention of:
RBI at Georgia Tech
500 10th St. NW
Atlanta, GA. 30318-5794
If sending by U.S. mail replace the ZIP code with 30332-0620
- A Purchase Order for an amount to cover the costs for the requested testing is required.
Georgia Institute of Technology
Bursar’s Office/A/C Receivable
225 North Avenue, NW
Lyman Hall, Suite #111
Atlanta, GA 30332-0257
A copy of the Purchase Order sent via fax to 404-894-4778 is requested.
- The sender should have the name of the appropriate RBI contact and phone number on their invoices/P.Os
- Receipt of samples coupled with e-mail detailing testing requirements and any background information initiates the generation of an internal project and officially starts the project.
- The work request is queued with others in order of time of receipt of samples. Work requests may be expedited under special circumstances.
- A report will be issued within the agreed turnaround time.
- Bills are sent separately by mail through the GT accounting system.