© 2026 Sinochem Nanjing Corporation,
All Right Reserved
|
HS Code |
969260 |
| Chemical Name | Dimethylaminopropylamine Diisopropanol |
| Molecular Formula | C7H20N2O2 |
| Molecular Weight | 164.25 g/mol |
| Appearance | Colorless to pale yellow liquid |
| Odor | Amine-like odor |
| Solubility In Water | Miscible |
| Boiling Point | Approximately 230°C (estimate) |
| Flash Point | Around 110°C (estimate) |
| Density | Approximately 0.95 g/cm³ |
| Ph Value | Alkaline |
| Viscosity | Low to moderate |
| Refractive Index | Approximately 1.440 |
| Freezing Point | -10°C to 0°C (estimate) |
| Stability | Stable under recommended storage conditions |
As an accredited Dimethylaminopropylamine Diisopropanol factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 1-liter translucent HDPE bottle with a blue screw cap, chemical-resistant labeling, showing "Dimethylaminopropylamine Diisopropanol, 1L, For Laboratory Use." |
| Shipping | Dimethylaminopropylamine Diisopropanol should be shipped in tightly sealed containers, clearly labeled, and protected from moisture and incompatible substances. Transport should comply with relevant regulations for chemical safety, using appropriate packaging and documentation. Avoid exposure to extreme temperatures and handle with suitable personal protective equipment to ensure safe and compliant delivery. |
| Storage | Dimethylaminopropylamine Diisopropanol should be stored in a tightly closed container, in a cool, dry, and well-ventilated area, away from heat sources and direct sunlight. Avoid contact with oxidizing agents, acids, and moisture. Use appropriate chemical-resistant materials for storage containers. Proper labeling and secondary containment are recommended to prevent accidental release or exposure. Always follow local regulations and safety guidelines. |
|
Purity 99%: Dimethylaminopropylamine Diisopropanol with a purity of 99% is used in surfactant synthesis, where enhanced foaming and cleaning capacity are achieved. Viscosity 850 mPa·s: Dimethylaminopropylamine Diisopropanol with a viscosity of 850 mPa·s is used in polymer modification processes, where controlled rheological properties enable precise formulation. Molecular Weight 190 g/mol: Dimethylaminopropylamine Diisopropanol at a molecular weight of 190 g/mol is utilized in epoxy curing systems, where optimal cross-linking density improves mechanical strength. Water Solubility Complete: Dimethylaminopropylamine Diisopropanol with complete water solubility is applied in textile softener formulations, where homogeneous dispersion ensures fabric softness. Stability Temperature up to 150°C: Dimethylaminopropylamine Diisopropanol stable up to 150°C is used in high-temperature lubricant additives, where thermal resistance prolongs operational life. pH (1% solution) 10.2: Dimethylaminopropylamine Diisopropanol with a pH of 10.2 (1% solution) is used in corrosion inhibitor blends, where alkaline pH enhances metal protection. Particle Size <5 µm: Dimethylaminopropylamine Diisopropanol with a particle size below 5 µm is incorporated in pigment dispersions, where fine particle distribution ensures color uniformity. Melting Point -15°C: Dimethylaminopropylamine Diisopropanol with a melting point of -15°C is utilized in deicing fluid compositions, where low-temperature fluidity facilitates application in cold environments. Hydroxyl Value 230 mgKOH/g: Dimethylaminopropylamine Diisopropanol with a hydroxyl value of 230 mgKOH/g is used in polyurethane systems, where increased reactivity accelerates curing rates. Amination Efficiency >98%: Dimethylaminopropylamine Diisopropanol with an amination efficiency greater than 98% is used in pharmaceutical intermediate synthesis, where high conversion yields boost process productivity. |
Competitive Dimethylaminopropylamine Diisopropanol prices that fit your budget—flexible terms and customized quotes for every order.
For samples, pricing, or more information, please call us at +8615371019725 or mail to admin@sinochem-nanjing.com.
We will respond to you as soon as possible.
Tel: +8615371019725
Email: admin@sinochem-nanjing.com
Flexible payment, competitive price, premium service - Inquire now!
As the chemical industry continues to search for compounds that can support modern manufacturing and formulation needs, few products earn their keep like Dimethylaminopropylamine Diisopropanol. For people familiar with surfactant synthesis, personal care blends, and advanced coatings, its balanced blend of chemical properties opens doors that basic amines and alcohols often leave closed. Whether you’re working on innovative hair conditioners, faster-curing resins, or even certain polyurethane systems, this specialty amine-alcohol crosses traditional boundaries in function and flexibility. Let's talk about how this compound stands out, why it keeps showing up in technical circles, and what practical differences it brings to the workbench compared to similar ingredients.
Most folks who’ve spent time in a formulation lab have come across basic amines and simple polyols. They each offer unique benefits—amines for pH adjustment and reactivity, polyols for solvency and flexibility. Dimethylaminopropylamine Diisopropanol blends both these families into one molecule, offering a dual-function structure with both an amine group and isopropanol units. This gives it a foot in both worlds. In my own experience with surfactant prototyping, this dual personality means fewer sourcing headaches—one raw material can now address several formulation challenges.
This chemical rarely operates as a lone actor. Its main stage appears in systems where balanced reactivity is key. The amine end accepts modifications and builds quaternary ammonium salts, giving chemists a versatile backbone for conditioners and emulsifiers. The diisopropanol component boosts solubility and stabilizes formulas that struggle with phase separation, especially where water and oil phases need a steady bridge.
Dimethylaminopropylamine Diisopropanol usually arrives as a clear, colorless to pale yellow liquid. It pours easily, so you can handle it straight out of the drum without battling thick, syrupy flow or sticky residues. Based on what I’ve seen in lab work, the molecular weight sits reliably above most short-chain amines, falling in a stable mid-range that resists evaporation. Its moderate viscosity helps with dispensing through automated lines; you won’t face endless recalibration between hot and cold days.
In terms of purity, suppliers often standardize content through gas chromatography or similar techniques. Most reputable lots test above 99 percent purity, which delivers repeatable results batch after batch. Moisture tends to run low, usually below 0.5 percent. That keeps hydrolysis in check for long shelf life and minimizes market returns due to spoiled inventory. If you’ve ever worked with lower-purity amines, you know how unpredictable those hydrolysis side reactions can get.
This compound holds up well under normal warehouse and production conditions. It doesn’t demand refrigeration or aggressive moisture controls, so it fits into most standard drum storage setups. Safety matters, of course. Proper gloves, goggles, and ventilation go a long way—just common-sense chemistry habits for secondary amines.
It helps to stack up Dimethylaminopropylamine Diisopropanol against its nearest competitors to see its value with a practical eye. In most projects, people gravitate toward raw materials that reduce complexity and cost. Over the years, I’ve found that this molecule can often replace two separate chemicals: one that supplies amine functionality, and another that acts as a co-solvent. That means fewer storage tanks, less paperwork for regulatory registration, and a simplified purchasing process.
Standard dimethylaminopropylamine—often called DMAPA—brings plenty of amine reactivity but has limited surfactant potential until you modify it chemically. Diisopropanolamine covers the alcohol side but stalls out on the cationic modifications chemists want for conditioning agents. This hybrid molecule delivers both. In practical terms, you can streamline process steps. Instead of mixing two separate additives, a formulator can adjust the dosage of this dual-function chemical on the fly.
Formulators often complain that certain basic amines impart unwanted odor or volatility issues. I’ve seen first-hand how Dimethylaminopropylamine Diisopropanol’s higher boiling point and lower vapor pressure cut back on system odors and reduce hazards for line operators. You don’t see the same amount of rework due to evaporation losses, which becomes significant in hot plant environments.
From what I’ve observed, the most widespread use comes in personal care—conditioner and shampoo blenders appreciate the straightforward cationic modification path. The molecule’s amine group reacts efficiently with fatty acids to create quaternary ammonium compounds that serve as reliable antistatic and conditioning agents. For a chemist under pressure to meet performance specs and consumer mildness, this single molecule can shrink development timelines.
Outside the beauty aisle, Dimethylaminopropylamine Diisopropanol also stands out in resins and urethanes. Here, the alcohol functionality supports crosslinking while the amine catalyzes polymerization. My years working with polyurethane foams taught me that using this kind of molecule can both initiate the reaction and finesse the final texture of the cured foam—not a trivial advantage. Adjusting the ratio helps dial in the balance between open-cell and closed-cell structures. This flexibility spares you from endless adjustments with tertiary amine blends and secondary alcohols.
Industrial coatings, adhesives, and even some water treatment chemicals benefit too. Its dual nature opens up options for designing molecules with both strong adhesion and water dispersibility. Anyone dealing with the challenge of getting two incompatible liquids to behave appreciates the bridging influence this molecule provides.
Every seasoned plant manager I’ve worked with knows that ease of storage counts as much as headline performance. This chemical usually stacks up well from a logistics perspective. Unlike water-sensitive polyols or air-reactive alkanolamines, Dimethylaminopropylamine Diisopropanol tolerates exposure to plant conditions without caking up or forming residues. Easily pumps at room temperature; you won’t waste time melting drums or cleaning filters.
I also appreciate its low color profile. Some amines and polyols gain a yellow tint or grow cloudy after months in storage. This compound tends to stay clean, which not only looks better but also keeps the end product from taking on off-colors—crucial for clear shampoos or translucent resins. If you’re targeting high-purity, visually appealing applications, this counts for a lot.
In my own plant experience, we had less trouble with clogged lines and blocked nozzles compared to thicker polyols or flakes. Equipment cleaning steps remain simple; warm rinses clear it out of hoses without heavy scrubbing. That means shorter changeovers for different products and higher overall equipment efficiency.
Sustainability is on everyone’s mind these days, not just in marketing, but in day-to-day procurement and compliance. Dimethylaminopropylamine Diisopropanol can help companies reduce overall chemical footprint by playing more than one role per batch. That wins favor with both purchasing teams and environmental managers. I’ve had cases where moving to this kind of multifunctional molecule trimmed a facility’s total chemical usage and the burden of tracking multiple hazard classifications.
It’s no secret that regulatory frameworks keep evolving. As I’ve seen policies shift in the US, Europe, and Asia, keeping product portfolios in compliance relies on choices at the ingredient level. Because most reputable producers offer transparent sourcing, batch-level traceability, and up-to-date certification, Dimethylaminopropylamine Diisopropanol generally fits into international chemical inventories. That saves re-registration costs and improves supply chain agility—every time regulations change, you have fewer raw materials to re-assess and fewer product labels to update.
Many chemists tell me that the “Swiss army knife” nature of Dimethylaminopropylamine Diisopropanol shortens the development cycle for new formulations. Suppose you’re tasked with developing a shower gel with both mildness and conditioning, but you don’t want a multi-step, high-waste process. Adding this ingredient brings both cationic charge and gentle modifications to the table, helping to combine benefits typically split across several additives. My own trial runs showed less need for extra stabilizers or chelators—one fewer bottle on the bench makes a big difference over dozens of iterations.
Those venturing into waterborne resins or adhesive blends get similar mileage. A formulator trying to balance quick cure times against manageable pot life can lean on the amine for fast initiation, while the alcohol moiety prevents the mix from gelling too soon. That allows for better tuning of working time and hardness—something that saves time and money during upscaling. For batch processes running around the clock, every saved hour translates to more consistent yields.
Let’s get real for a moment. Labs with legacy formulas based on simple DMAPA might see switching as risky. The question always comes up: “Do I really gain enough to justify the change?” From my practical experience, the answer hinges on overall process simplification. If you’re running a personal care line using DMAPA and a separate diol, switching consolidates two SKUs and cuts down on purchasing complexity. Fewer deliveries, fewer late shipments, and less storage juggling follow. If your operation measures efficiency in hours not days, this is a tangible upgrade.
On the technical side, I’ve noticed that Dimethylaminopropylamine Diisopropanol often improves compatibility where other blends fall short. For example, in cationic surfactant mixes, basic amines can destabilize emulsions or trigger flocculation. Introducing this hybrid molecule helps maintain smooth blends, even when pushed to higher concentrations. Less rework and fewer pH “fixes” mean faster production runs and lower scrap rates.
Anyone involved with polymer systems knows the headache of rigid, brittle outcomes from using low-molecular-weight amines or simple glycols. This compound’s extra alcohol units add flexibility and resilience in both rigid and elastomeric foams, plus better release properties from molds. Fewer complaints about sticky molds or fragile cured parts keep customers happy and plant downtime low.
Ask anyone responsible for procurement—the chemical marketplace operates on reliability and adaptability. Recent years have seen supply chains stretch thin, with every warehouse manager prioritizing stable, versatile ingredients. Dimethylaminopropylamine Diisopropanol often finds its way to the top of the list because of its wide utility and straightforward handling. I’ve worked with sourcing teams who managed to cut vendor lists by moving to this dual-purpose raw material, reducing the headaches that come from juggling dozens of specialty chemicals.
End users care about consistency in their final products. If you’re packaging clear lotions or glossy coatings, reproducibility means fewer returns and better customer ratings. This compound’s predictable chemical profile keeps downstream variability in line. That pays off during seasonal demand surges, especially for manufacturers scaling up with little margin for error.
No product exists without limitations. Some users have pointed out that Dimethylaminopropylamine Diisopropanol’s cost-per-kilogram runs higher than basic feedstock ingredients. Over time, I've learned that the trick lies in calculating total system cost rather than just ingredient cost. If a plant cuts three raw materials down to one, streamlines QC testing, and improves throughput, the price difference becomes negligible.
Handling requirements do call for basic safety investment. Facilities must equip teams with proper PPE and clear spill protocols, though by this point most manufacturing environments have those systems in place. I’ve fielded questions about long-term stability in suboptimal storage conditions, especially in parts of the world with high humidity. In my experience, proper drum closure and rotation scheduling keep material fresh with minimal waste.
Occasionally, formulators hit solubility hurdles at extreme concentrations or unique pH swings. Running small-scale compatibility tests avoids large-scale batch failures. I’ve sat through enough product recalls to know that an early R&D test saves weeks of lost sales downstream.
One of the strategies that worked well in my teams was cross-training operators and R&D staff on how Dimethylaminopropylamine Diisopropanol interacted during both early- and late-stage production. Seeing the material in action, understanding its quirks, and knowing how it interacts with other raw materials pays dividends. Batch-to-batch performance improves, troubleshooting gets easier, and everyone stays on the same page.
Lab managers can avoid unnecessary blending steps by leveraging its dual role, freeing up manpower and tank space for more innovative projects. Regularly reviewing incoming raw material certificates helps catch any shifts in purity before they impact large orders. Keeping open communication with upstream suppliers and downstream users ensures everyone benefits from the reliability this compound delivers.
Thinking back on decades of product launches and process overhauls, the value in a specialty ingredient like Dimethylaminopropylamine Diisopropanol lies in what it unlocks for process engineers and chemists. As sustainability drives companies toward shorter supply chains and less hazardous waste, chemistries that serve multiple purposes in a single stroke gain serious traction. It isn’t always easy to break habits set by legacy ingredients, but the long-run gains—in efficiency, regulatory peace of mind, and product flexibility—tip the scale.
Industry feedback also points toward tailoring modifications at the molecular level. Dimethylaminopropylamine Diisopropanol lends itself to creative thinking, whether you’re targeting novel surfactants, flexible plastics, or low-VOC coatings. In my experience, partnering with suppliers who offer technical support and custom synthesis turns a good ingredient into a source of real competitive advantage.
Dimethylaminopropylamine Diisopropanol occupies a unique space where versatility meets practicality. Research teams, plant operators, and business leaders all have different priorities, but this compound answers many with a single bottle. Fewer changeovers, less waste, and fewer process headaches trace back to its dual-function nature. In an era when every step counts and every purchase faces scrutiny, leveraging ingredients that bridge gaps and improve reliability makes all the difference.
Drawing on years of real-world handling and customer feedback, this chemical earns its place not just as a niche specialty, but as a core contributor across industries. Whether you’re building better conditioners, smarter resins, or tougher adhesives, having this tool at your disposal expands both capability and confidence in each step of the process. As market demands shift and customers expect more, working with compounds that offer practical value keeps businesses ahead of the curve.
