Polycarboxylate Superplasticizer For example, self-consolidated concrete and slump retention beyond two hours without significant set time extension have been made possible with PCEs. I was fortunate to be on the R&D/marketing team for a major chemical admixture company that launched the first group of polycarboxylate-based admixtures in the 1990s. Like all new technologies introduced into the building industry, there has been a long learning curve which underscores the highly diverse set of materials and applications with concrete construction. This article summarizes a few key performance attributes which have been learned from both commercial concrete applications and the research laboratory. Some of the benefits provided by polycarboxylate superplasticizers have been discussed and previously published in The Concrete Producer. The term “polycarboxylate” actually applies to a very large family of polymers, which chemists can design to impart a special performance to concrete mixtures. Subsequent to the introduction of so-called general purpose PCE superplasticizers, new PCE products have been developed especially designed to provide high early strength and different levels of slump retention, as well as provide different capabilities to manage air contents in concrete. One such class of polycarboxylates has little impact on initial slump, but because of a time-release function built into the PCE polymer, concrete slump increases generally in a predictive manner as a function of mixing time (see Figure 1). Thus, such a product can be added at various dosages to an already admixed concrete to dial in slump retention as a function of job conditions (haul time, temperature, delay before discharge, etc). Very often, a superplasticizer will be formulated with a blend of two or more PCEs to achieve a combined performance of both early strength and long slump life. Researchers will continue to actively manipulate PCE polymer structure to meet the ever changing material and construction requirements. This remarkable strength difference, obtained by merely changing the superplasticizer type from a PNS to a polycarboxylate, was verified from a scientific study, and can be useful in reducing cement contents while still meeting strength specifications. Interestingly, the strength difference does not seem to be associated with increased heat of hydration, but rather is related to a denser microstructure produced by the combination of a calcium-based accelerating or corrosion-inhibiting admixture and polycarboxylate-based admixture. The PCE superplasticizer replaced both the PNS/lignin and Type A water-reducing products at about one-third the dosage rate. Also, note the 50% drop in AEA dosage rate with the PCE admixed concrete to obtain the same air content. To summarize, though the concrete industry has learned much about harnessing the versatility and understanding the limitations of PCE-based superplasticizers, chemists, working with concrete technologists, will continue to modify the polymer structure to achieve new capabilities for the production, placement and service life of concrete mixtures. by-Ara PCE based plasticizer Shanghai Hongyun New Construction Materials Co., Ltd , https://www.hongyunpce.com
Explanation and indication of model specifications for wires and cables, with a focus on power cables. For more information, contact us at 0316-5961266 or 13231669130.
Power cables come in various types and models, and their designation follows specific rules. Understanding the cable model helps identify its material, structure, and performance. Below is a detailed breakdown of how power cable models are structured and interpreted.
The first letter of a cable model usually represents the type of insulation, conductor material, inner sheath, or special features. For example:
- **Z** stands for paper insulation (zhi)
- **L** indicates aluminum conductor (lv)
- **Q** refers to lead sheath (qian)
- **F** means phase-separated (fen)
- **ZR** denotes flame-retardant (ziran)
- **NH** stands for fire-resistant (naihuo)
The number following the letters typically represents the outer sheath structure. It’s usually two digits, where the first digit shows the armor type and the second shows the outer layer. For instance:
- **0** means no armor and no outer layer
- **2** indicates double steel tape armor
- **4** refers to thick steel wire armor
- **1** means fiber outer layer
- **2** stands for PVC sheath
- **3** refers to polyethylene sheath
The general arrangement of a power cable model includes:
1. Insulation material
2. Conductor material
3. Inner sheath
4. Outer sheath
Cable products are identified by their model, rated voltage, and specifications. For example, **VV42-10 3×50** means:
- **VV**: PVC-insulated copper cable
- **42**: Thick steel wire armor and PVC sheath
- **10**: Rated voltage of 10kV
- **3×50**: Three cores, each with a cross-sectional area of 50 mm²
Here’s a breakdown of common codes used in power cable models:
1. **Insulation Type**:
- **V** – PVC
- **X** – Rubber
- **Y** – Polyethylene
- **YJ** – Cross-linked polyethylene
- **Z** – Paper
2. **Conductor Material**:
- **L** – Aluminum
- **T** – Copper (often omitted in the model)
3. **Inner Sheath**:
- **V** – PVC sheath
- **Y** – Polyethylene sheath
- **L** – Aluminum sheath
- **Q** – Lead sheath
- **H** – Rubber sheath
- **F** – Neoprene sheath
4. **Special Features**:
- **D** – Non-drip
- **F** – Phase separation
- **CY** – Oil-filled
- **P** – Dry insulation
- **S** – Shielded
- **Z** – DC application
5. **Armor Layer**:
- **0** – No armor
- **2** – Double steel tape
- **3** – Thin steel wire
- **4** – Thick steel wire
6. **Outer Sheath**:
- **0** – No outer sheath
- **1** – Fiber layer
- **2** – PVC sheath
- **3** – Polyethylene sheath
7. **Fire Protection**:
- **ZR** – Flame-retardant
- **NH** – Fire-resistant
For **oil-filled cables**, the model also includes the product code and structural details. A typical example is **CYZQ102 220/1×4**, which means:
- **CY** – Self-contained oil-filled
- **ZQ** – Paper insulation with lead sheath
- **102** – Radial copper strip reinforcement, unarmored, PVC sheath
- **220** – Rated voltage of 220kV
- **1×4** – Single core, 400mm² cross-section
The outer sheath of oil-filled cables is coded as follows:
- **Strengthening Layer**:
- **1** – Copper strip radial reinforcement
- **2** – Stainless steel strip radial reinforcement
- **3** – Steel strip radial reinforcement
- **4** – Longitudinal stainless steel strip reinforcement
- **Armor Layer**:
- **0** – No armor
- **2** – Steel belt armor
- **4** – Thick steel wire armor
- **Outer Layer**:
- **1** – Fiber layer
- **2** – PVC sheath
- **3** – Polyethylene sheath
Understanding these codes allows engineers and technicians to quickly identify the right cable for a specific application. Whether you're working on low-voltage or high-voltage systems, knowing how to interpret cable models is essential for safe and efficient installations. For more details, feel free to contact us at 0316-5961266 or 13231669130.
The Polycarboxylate Family
Explanation and representation of model specifications for wire and cable. Take power cable as an example.
Some 20 years ago, a new type of Superplasticizer based on polycarboxylate polymers (PCE) was commercially introduced to the North American concrete construction industry. Just as the application of naphthalene-based admixtures starting in the 1970s enabled significant improvements in the numerous engineering properties of plastic and hardened concrete, polycarboxylates have further extended the performance of concrete mixtures.