What is a pu foaming catalyst? What role does it play in rigid foam insulation materials for refrigerators and ?
Polyurethane foaming catalyst is a key chemical auxiliary agent used to promote the reaction of polyurethane foam molding. In refrigerators, freezers and other refrigeration equipment, polyurethane rigid foam is widely used as a thermal insulation material, and its performance is directly related to the energy saving, service life and overall structural strength of the product.
In the polyurethane foaming process, the main functions of the catalyst are:
- Accelerate the reaction between polyols and polyisocyanates (i.e., gel reaction);
- Promoting the foaming gas generation reaction (i.e., foaming reaction);
- Control the reaction rate and foaming time to obtain the ideal cell structure;
- Improves the dimensional stability and mechanical properties of foam.
In short, the catalyst acts like a “switch”, regulating the rhythm and quality of the entire foaming process.
Why do refrigerators and freezers use polyurethane rigid foam as insulation material?
The reason why polyurethane rigid foam is the best choice for refrigerators and freezers is mainly based on the following advantages:
Characteristic | Describe |
Very low thermal conductivity | λ ≤ 0.022 W/(m·K), better than traditional materials such as EPS and XPS |
High closed porosity | ≥90%, strong waterproof and moisture-proof ability |
Excellent mechanical properties | High compression strength and good structural stability |
Strong self-adhesiveness | Can form an integrated structure with metal inner and outer shells |
Green and Environmentally Friendly | Use water or HFCs as blowing agents to reduce ODP impact |
In addition, polyurethane rigid foam can fill complex structural cavities and adapt to various special-shaped spaces, providing refrigerator manufacturers with great design flexibility. Therefore, it is one of the current mainstream and efficient insulation materials.
What types of PU foaming catalysts are there? What are their respective characteristics?
According to the different types of catalytic reactions, polyurethane foaming catalysts can be divided into the following categories:
- Gelling Catalysts
type | Chemical name | Representative Products | Features |
Amine catalysts | Triethylenediamine (TEDA), N-methylmorpholine | Polycat 46, Dabco 33-LV | Accelerate gel reaction and shorten demoulding time |
Tin catalyst | Dibutyltin dilaurate (DBTDL) | T-12, T-9 | Sensitive to ester groups, suitable for polyester formulations |
- Blowing Catalysts
type | Chemical name | Representative Products | Features |
Weakly basic amines | N,N-Dimethylcyclohexylamine (DMCHA) | Dabco DC2, PC-5 | Delay gelation reaction and promote CO₂ release |
Strong alkaline amines | Triethylenediamine (TEDA) | Polycat 41 | Fast foaming, suitable for low temperature environment |
- Delayed Action Catalysts
type | Chemical name | Representative Products | Features |
Blocked amine catalyst | Bis(N,N-dimethylaminopropyl)urea end-capped | Polycat SA-1, DC 5088 | Control reaction delay and extend operation time |
Tips: In actual production, multiple catalysts are usually used in combination to achieve the best foaming effect.
How to choose a suitable PU foaming catalyst?
The following factors need to be considered when selecting a catalyst:
Considerations | illustrate |
Foam density | The lower the density, the greater the proportion of foaming catalyst should be. |
Material temperature and mold temperature | When the temperature is low, the reaction speed needs to be accelerated, otherwise it needs to be slowed down. |
Raw material system | Polyether/polyester systems have different sensitivities to catalysts |
Environmental requirements | Whether to use tin-free catalyst (such as organic bismuth, zinc) |
Production line speed | Continuous production lines require fast demoulding, while intermittent production lines can be slightly slower |
For example, in a continuous spraying production line, a combination of fast gel and medium foaming catalyst is recommended; while in intermittent box pouring, a delayed catalyst is preferred to ensure fluidity.
Typical formula parameter reference for PU foaming catalyst
The following is a typical reference for the polyurethane rigid foam formula for refrigerators (based on 100 parts of polyol):
Components | Recommended dosage (phr) | Function |
Polyols | 100 | Main resin |
Polyisocyanate (MDI) | 130~160 | Crosslinking agent |
Water (foaming agent) | 3.5~5.0 | Sources of CO₂ |
HCFC/HFO physical foaming agent | 10~20 | Auxiliary foaming |
Surfactants | 1.5~3.0 | Stabilize foam and adjust cell structure |
Gel type catalyst | 0.3~1.0 | TEDA, DBTDL, etc. |
Foaming catalyst | 0.2~0.8 | DMCHA, PC-5, etc. |
Delayed Catalyst | 0.1~0.5 | SA-1, DC 5088, etc. |
Experimental suggestions: It is recommended to start with a low dose for preliminary testing, gradually adjust the catalyst ratio, and observe changes in pore uniformity, skin thickness, and demolding time.
Analysis of the influence of catalyst on foam performance
Impact Dimension | Excessive Catalyst Performance | Catalyst too little performance |
Cell structure | Large and uneven pore size | Fine pores but easy to collapse |
Skin thickness | Thin skin, easily damaged | Thick, dense epidermis |
Demolding time | Shortened, prone to premature cracking | Prolongation affects efficiency |
Thermal conductivity | Increase, thermal insulation performance decreases | Declining, but rising costs |
Mechanical strength | Easy to crack, low compression strength | High strength, but poor elasticity |
Therefore, a reasonable combination of catalysts is the key to achieving high-performance foams.
Development trend of environmentally friendly catalysts
As global awareness of environmental protection increases, the use of traditional tin catalysts is gradually being restricted due to potential toxicity issues. In recent years, environmentally friendly catalysts have gradually become a research hotspot:
As global awareness of environmental protection increases, the use of traditional tin catalysts is gradually being restricted due to potential toxicity issues. In recent years, environmentally friendly catalysts have gradually become a research hotspot:
type | Features | Application Status |
Organic bismuth catalyst | Non-toxic, high catalytic activity | Already used in some high-end products |
Organozinc Catalyst | Low cost and good stability | Suitable as a replacement for DBTDL |
Bifunctional amine catalyst | Possesses both gel and foaming functions | Emerging direction, still in the promotion stage |
Policy promotion:
- EU REACH regulations have restricted the use of tin-containing catalysts;
- China’s “Guidelines for Industrial Structure Adjustment” encourages the use of green catalysts.
In the future, developing new catalysts that are highly efficient, less toxic, and less expensive will become the mainstream direction of the industry.
FAQ
Q1: Is polyurethane foaming catalyst toxic?
A: Most commercial catalysts are low-toxic chemicals, but they may decompose into harmful substances at high temperatures. It is recommended to wear protective equipment and comply with safety regulations when operating.
Q2: Can the catalyst be completely omitted?
A: No. Without a catalyst, polyurethane reacts very slowly and cannot form qualified foam.
Q3: Will the catalyst affect the flame retardant properties of the foam?
A: Some amine catalysts may reduce flame retardancy and need to be used in conjunction with the addition of flame retardants.
Q4: How to determine whether the catalyst is ineffective?
A: The symptoms include longer foaming time, coarse foam cells, and difficulty in demoulding. A preliminary judgment can be made by changing the batch or testing the pH value.
Summarize
Polyurethane foaming catalyst plays an indispensable role in the rigid foam insulation materials of refrigerators and freezers. It not only determines the molding quality of the foam, but also directly affects the energy-saving performance and service life of the product.
At present, with the tightening of environmental regulations and technological progress, catalysts are developing in the direction of non-toxic, high-efficiency, multi-functional and low-cost. Enterprises should actively pay attention to the development of new materials and new processes, and reasonably select and optimize catalyst formulas to enhance product competitiveness.