Smooth Transition; Using Safe And Cost-effective Gaseous Blowing Agents

1. Smooth Transition; Using Safe And Cost-effective Gaseous Blowing Agents The Benefits of HFC-134a & HCFC-22/142b Technology

2. Agenda • Blowing Agent properties. • Semi-optimized formulations. • Blending and handling methods. • Foam Processing. • Foam Properties, Energy Consumption results. • Cost.

3. Properties Of The Blowing Agents

4. Formulations • We modified each formulation for each blowing agent to optimize flow and thermal conductivity. • Except HFC-245fa where we used published data to generate the comparison due to patent restrictions. • Our targets were: • 31.5ml/g total blowing. • 1.4-1.5 pcf free rise density. • 25% CO2 blowing from water.

5. Attributes of Formulations

6. Discussion of Formulations • HCFC-22/142b uses 15% less physical blowing agent than HCFC-141b to achieve the same total blowing and free rise density. • HCFC-22 required an increase in total blowing to achieve the target density. Due to HCFC-22’s lower molecular weight, the % physical blowing agent and % CO2 were maintained.

7. Discussion of Formulations • HCFC-124 and HFC-245fa maintained the total blowing and % CO2 blowing. However, due to higher molecular weights they use 19% and 13% more physical blowing agent. • HFC-134a had poor solubility in the polyols. Therefore, only 9.3% physical blowing agent could be achieved. The blowing level was maintained and density achieved by increased % CO2 blowing.

8. Blending and Handling GBA Mixtures Methods • Two Methods of Blending for Production. • In-line mixer supplied by several equipment suppliers. • To day tanks. • To a holding tank to supply the entire plant. • Batch method. • Same as liquid blending only under pressure. • Use of a static mixer and pressure rate blend tank required. • Supply to day tanks or holding tank.

9. Blending and Handling GBA Mixtures Methods • This project used the batch method. • A small pressure vessel with a static mixer. • Blend time was 45 minutes. • Peak pressures observed were 55 psig. • Plant trials are carried out using a large scale model of the laboratory unit.

10. Blend Units

11. Foam Dispensing • This project used a standard high-pressure impingement mix machine. • No modifications were required. • Day tanks were rate to 150 psi. • We used the following conditions. • 70oF Chemical temperatures. • 110oF mold temperature. • 2000 psi mix pressure.

12. Properties of Foams

13. Discussion of Foam Properties • The differences in thermal conductivity are reduced when the mean temperature is reduced 50oF. • Gaseous Blowing agents will achieve equal flow to liquid blowing agents. • Better plastic liner compatibility can be achieved with the gaseous blowing agents.

14. Results in Cabinets • As reported cabinets made with HCFC-124 and HFC-245fa give equal energy consumption to current HCFC-141b technology. • This is confirmed by the similar flow and low temperature thermal conductivity results for these foams. • Base on these results we expect a 2-4% increase in energy consumption for cabinets made with HCFC-22.

15. Results in Cabinets • We achieve equivalent energy consumption for cabinets made with HCFC-22/142b as those made with HCFC-141b. • The results of the HFC-134a system indicate a 5-7% energy penalty.

16. Conclusions • Gaseous blowing agent technology using HCFCs now achieves energy efficiency and other foam properties equivalent to existing liquid systems and offers significant performance improvements and environmental benefits. • HCFC-22/142b is the most cost-efficient short term replacement for HCFC-141b. It will achieve equal energy efficiency to HCFC-141b. • HCFC-22/142b technology allows easy conversion to HFC-134a.

17. Conclusions • Master batches using GBAs can be stored and processed under moderate pressure as efficiently and cost effectively. No modifications to dispensing equipment is necessary. • All of the GBAs shown can be process using the same blending modifications (batch or in-line). This allows smooth transition from HCFC-22/142b to zero ODP HFC-134a.

18. Conclusions • The improvements to GBA technology have resulted in improved HFC-134a blown foam systems. Resulting in improved energy consumption results and density reduction. • Therefore, HFC-134a will be the most cost/performance effective replacement for HCFCs.