© 2026 Sinochem Nanjing Corporation,
All Right Reserved
|
HS Code |
580818 |
| Chemical Name | 1,5-Pentanediamine Hydrochloride |
| Cas Number | 462-94-2 |
| Molecular Formula | C5H16Cl2N2 |
| Molecular Weight | 175.10 g/mol |
| Appearance | White to off-white crystalline powder |
| Melting Point | 222-226°C (decomposes) |
| Solubility | Soluble in water |
| Purity | Typically ≥98% |
| Storage Conditions | Store in a cool, dry place; keep container tightly closed |
| Odor | Slightly ammoniacal |
| Density | 1.14 g/cm³ (at 20°C) |
As an accredited 1,5-Pentanediamine Hydrochloride factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 1,5-Pentanediamine Hydrochloride, 500g, packaged in a sealed, high-density polyethylene bottle with tamper-evident cap and clear labeling. |
| Shipping | 1,5-Pentanediamine Hydrochloride is shipped in tightly sealed containers made of compatible materials, such as plastic or glass, to prevent moisture absorption and chemical degradation. Packages are labeled according to regulatory guidelines for hazardous chemicals. The chemical is typically transported under dry, cool conditions, with appropriate documentation for safe handling and transport. |
| Storage | 1,5-Pentanediamine Hydrochloride should be stored in a tightly sealed container in a cool, dry, and well-ventilated area away from incompatible substances such as strong oxidizers. Protect from moisture and direct sunlight. Ensure proper labeling and keep away from sources of ignition. Store at room temperature and follow all local, state, and federal regulations for chemical storage. |
|
Purity 99%: 1,5-Pentanediamine Hydrochloride with purity 99% is used in high-performance polyamide synthesis, where enhanced polymer strength and thermal stability are achieved. Molecular Weight 138.63 g/mol: 1,5-Pentanediamine Hydrochloride with molecular weight 138.63 g/mol is used in pharmaceutical intermediate production, where consistent reaction yields and predictable bioactivity profiles are ensured. Melting Point 210°C: 1,5-Pentanediamine Hydrochloride with melting point 210°C is used in heat-resistant resin manufacturing, where superior thermal processing and material integrity are obtained. Particle Size <100 μm: 1,5-Pentanediamine Hydrochloride with particle size less than 100 μm is used in fine chemical formulation, where rapid dissolution and homogeneous mixing are facilitated. Stability Temperature up to 150°C: 1,5-Pentanediamine Hydrochloride with stability temperature up to 150°C is used in specialty coatings production, where reliable performance under elevated application temperatures is maintained. |
Competitive 1,5-Pentanediamine Hydrochloride 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!
Across dozens of manufacturing floors and research labs, a product like 1,5-Pentanediamine Hydrochloride brings possibilities that didn’t exist a decade ago. Whenever I walk through a chemical plant or chat with the teams making new polymers, certain names come up more often, and this compound is quickly joining that crowd. Sometimes called pentamethylene diamine hydrochloride, it’s no longer stuck in the appendix of catalogs — it’s getting attention for real reasons.
People in the industry know how challenging it can get to find building blocks that fit strict demands for purity, reactivity, and flexibility. I’ve seen first-hand how impractical it can be to rely on legacy materials when regulation tightens or performance demands shift. As the push for bio-based and value-adding intermediates grows, 1,5-Pentanediamine Hydrochloride has started checking more boxes, showing practical utility beyond a narrow niche.
Straight to the facts: 1,5-Pentanediamine Hydrochloride stands out thanks to its stable crystalline state, with a solid content profile. In the real world, this means a lower risk of unwanted decomposition under ordinary handling and decent shelf stability. I’ve watched techs working with batches open the container day in and day out—without the odor or sticky residue you sometimes get from older diamines.
From my own work, I can say environmental and safety standards shape decisions more than glossy brochures do. Unlike hexamethylenediamine or some short-chain alternatives, which can be skin irritants or bring tough VOC issues, this compound proves easier to manage. It’s only fair to say every chemical has its risks, but compared to others in the diamine family, it lands in a sweet spot: less volatility, friendlier storage, fewer headaches with regulatory paperwork.
A typical product batch comes in at a purity of 99% or higher, based on HPLC or GC analysis. Moisture matters in polymer applications, and formulated samples show extremely low moisture content, often below 1%. Granule size sits in a practical range for processing equipment — easy to weigh, doesn’t clump, and flows evenly through standard feeders.
In terms of physical format, you’ll usually get it in off-white crystalline granules. Every so often, specification sheets list details like melting point and pH when dissolved, but unless you’re running strict analytics, the take-home message is consistency. My experience tells me the material dissolves rapidly in water, helping in downstream syntheses with no special tricks. It’s reasonably dense, so storage volume stays manageable even for operations pushing large throughputs.
I’ve talked with engineers using pentanediamine hydrochloride to make polyamides. They appreciate its ability to form strong, yet flexible chains, steering new types of Nylon — beyond the reach of classic 1,6-hexamethylenediamine. Product designers chasing higher bio-content in plastics also find it useful, especially with mounting demand for renewable or partially renewable polymers.
In curing agents for epoxy and urethane resins, you see real-world benefits. Its amine value lines up with requirements for rapid, thorough crosslinking, which means fast cycle times and durable, evenly cured products. Those working on adhesives, coatings, or solvent systems will notice smoother compatibility and more even dispersal. Compared to legacy polyamines, the hydrochloride salt acts as a more predictable ingredient, making process output less vulnerable to heat spikes or fluctuations in pH — important factors in a busy production line.
In my own lab, using 1,5-Pentanediamine Hydrochloride opens up reaction space where traditional amines couldn’t deliver. Its two primary amine groups, spaced five carbons apart, bring nice versatility in both linear and crosslinked compounds. Whether you’re producing textile fibers, modifying water treatment resins, or adding biofunctionality to construction materials, this compound offers a consistency I haven’t always found in its chemical cousins.
Let’s get real about choices: With any industrial feedstock, it’s natural to ask if new products deliver enough upside to justify a switch. Compared to hexamethylenediamine or shorter-chain diamines like putrescine, 1,5-Pentanediamine Hydrochloride has taken on scrutiny from both purchasing managers and process engineers. Their concerns usually center on price, ease of integration, safety handling, and long-term supply stability.
On price, some years ago this material carried a premium tag. Lately, competition among suppliers and improvements in production routes — especially routes leveraging fermentation — have trimmed costs closer to established alternatives. I’ve talked with buyers who used to pass over this compound but now routinely order it, not just for niche jobs, but as a regular part of their sourcing strategy.
Ease of integration holds weight across operations. A classic issue comes from amines clumping in humid air, gumming up feeders, or staking out an entire day for limited production runs. Here, 1,5-Pentanediamine Hydrochloride holds up well. Regular checks show it remains flowable in workshop environments, and the hydrochloride salt form seems less prone to forming hard lumps, compared to other forms that risk caking. It translates to less wasted time and fewer service calls.
Another edge comes in downstream purity and the nature of byproducts. Some diamines can throw off unwanted secondary amines or contribute residual odor to end-products — a concrete hassle for consumer applications. Using 1,5-Pentanediamine Hydrochloride, it’s easier to produce cleaner reaction streams, reducing the need for excess purification runs.
Sustainability weighs on every development manager’s mind, especially in markets where end-users want clear proof of renewable content. While most diamines trace their roots to petrochemical pipelines, pentanediamine hydrochloride offers routes from sustainable feedstocks — an advantage for companies chasing higher Environmental, Social, and Governance (ESG) scores. In discussions with R&D, I’m hearing more about enzymatic or fermentative routes from plant-derived sugars, tilting the sustainability balance further toward this compound.
No one compound solves every problem. Despite its upside, some users report compatibility headaches with highly specialized equipment that originally handled only legacy hexamethylenediamine. There’s also a learning curve, especially when dialing in reaction times and optimizing formulations for high-speed, high-yield processes. In larger operations, quality control teams keep a keen eye on possible impurities and batch-to-batch consistency, which varies with less reputable suppliers.
Some regulatory frameworks still treat newer diamines—regardless of safety profile—with a level of caution that can slow rapid adoption. Regions with complex notification requirements or extra labeling demands nudge teams to stick with familiar, pre-approved compounds. Without industry-wide recognition or global standardization, roll-out can face delays that frustrate both users and producers.
On sourcing, early enthusiasm sometimes bumps up against availability issues. If supply chains get squeezed, companies relying on pentanediamine hydrochloride for mission-critical products may need to dual-source or keep inventories higher than usual. As markets for high-bio-content or specialty polyamides expand, good long-term contracts and diverse supplier bases matter more than clever marketing.
With steady work, many of these growing pains find answers. Process engineers can fine-tune equipment to handle pentanediamine hydrochloride without major capital spending — usually by adjusting feed rates, drying protocols, or using anti-caking liners. Training programs covering handling and first-aid bridge the gap for operators who may be more familiar with legacy compounds. I often recommend connecting directly with suppliers for bulk trial shipments, letting production lines adjust before full-scale launch.
Transparency also pushes the compound forward. Reliable third-party analytics and supplier assurances on purity and traceability help buyers feel confident about switching. Rather than relying only on marketing claims, robust method validation and round-robin testing among labs set higher trust bars throughout the chain.
On the regulatory front, industry groups can collaborate to establish unified safety and usage guidelines. By presenting consensus data and real-world outcomes to authorities, companies speed up recognition and reduce uncertainty. When end-users know packaging, handling, and disposal all match up with local and international standards, roll-out becomes smoother, even across strict regions.
For companies seeking to tell a stronger sustainability story, the move toward bio-based pentanediamine hydrochloride stands as a real differentiator. I’ve seen brands gain market share by letting their supply chain achievements take center stage — verifying claims with life-cycle analyses and eco-certifications. Many customers, from textile giants to medical device makers, want ingredients traced back to renewable sugars or non-food biomass. Producers investing in green chemistry draw interest from buyers eager to align with evolving ESG standards.
Forward-thinking manufacturers turn to 1,5-Pentanediamine Hydrochloride not just to claim “newness,” but because it unlocks formulation options old-school ingredients couldn’t. In fiber production, it builds in a mix of toughness and ductility that designers crave for next-generation textile applications. Automotive suppliers chasing lighter, tougher polymers use it to tune polyamides for either flexibility or impact warmth — choices dictated by safety and lifecycle costs.
Water treatment, coatings, and adhesives all gain from the compound’s amine chemistry. Each amine group engages under standard reaction conditions, adding value across crosslinking, chain extension, or surface grafting. In markets jostling for edge in wear resistance or barrier properties, these extra handles pay off. And because the hydrochloride salt behaves predictably in both aqueous and non-aqueous processes, product developers find it easier to map out pilot runs before scaling up.
Academics studying biodegradable plastics or specialty elastomers keep reporting new structures built from pentanediamine hydrochloride. In my own review of peer literature, I’ve spotted a steady climb in patent filings touching this ingredient — a sign that technical and commercial interest spreads far beyond a handful of large firms.
Day to day, every shift in input material comes down to a blend of cost, performance, and safety. Operators likely look first at price and availability, but quality managers track purity and waste. Marketing and sustainability teams ask for renewable content and clean certifications. 1,5-Pentanediamine Hydrochloride fits these goals more often than many realize, especially once supply chains mature.
A key reason for its staying power: risk reduction. With supply volatility in other diamines linked to commodity markets or political uncertainty, more buyers seek alternate feedstocks. The potential for bio-based production insulates manufacturers from price shocks or supply squeezes tied to oil futures.
Safety also factors in. In my workshops with plant managers, teams report smoother audits after shifting to compounds that carry less acute toxicity or irritation risk. Fewer spill incidents mean less downtime, and in plants where every hour offline cuts deep into margins, these practical savings add up.
On performance, end-use customers often notice subtle improvements once they pivot to new polymers or resins containing pentanediamine hydrochloride. Finished materials gain the slight edge in resilience or workability—qualities noticed by busy production crews and not just by lab analysts.
Industry doesn’t stand still. Ongoing investments in biotechnology, reaction engineering, and supply chain transparency will keep pushing 1,5-Pentanediamine Hydrochloride into broader application. Manufacturers continue to broaden its usage in composite materials, medical polymers, antimicrobial agents, and finishings that demand tough regulatory compliance.
I predict more partnerships between raw material producers and downstream processors — not just short-term sales, but joint R&D targeting ever-greater control over polymer architecture. With grassroots knowledge-sharing, from bench chemists up to C-suite strategists, this compound will continue moving from niche roles to backbone positions in modern manufacturing.
The market’s appetite for greener, lighter, tougher products keeps growing alongside new regulatory pressure and social responsibility demands. In this setting, compounds like 1,5-Pentanediamine Hydrochloride are getting their moment — not just as options, but as answers, offering clarity where old solutions fall short.
