The CPVC Pipe Fittings material that is produced to using a CPVC layer. Therefore, it meets the demand for the coveted ASTM F441 within ASTM Listing ASTM D2846. CPVC applications are made for the transportation of drinking water, controlling waste water from factory waste, as well as for fire protection systems.
CPVC (Chlorinated Polyvinyl Chloride) is another rigid pipe with three highly desirable characteristics, good mechanical strength and high chemical resistance at high temperatures and relatively in comparison to metal. It is more chlorinated than CPVC polymer.
This addition is responsible for the high temperature strength of the chlorine content and other properties that are valuable to industrial piping. For pressure piping applications, temperatures as high as 200°F are recommended, compared to PVC’s 140°F.
Petron Thermoplast CPVC SCH 80 and CPVC SCH 40 Industrial corzan cpvc Gray Piping CPVC pipe range in sizes from 1/2″ to 24″, and CPVC fittings are available for light, medium and heavy duty use.
These are environmentally friendly polymers in terms of low carbonic acid gas emissions in the manufacturing process.
PVC (Polyvinyl Chloride) and CPVC (Chlorinated Polyvinyl Chloride) pipes are both made from thermoplastic materials that are widely used in plumbing systems. However, there are several key differences between them.
One of the main differences is the temperature range that they can handle. PVC pipes are rated for use up to 140°F, while CPVC pipes can handle temperatures up to 200°F. This makes CPVC pipes more suitable for hot water applications.
Another difference is their chemical resistance. CPVC pipes are more resistant to corrosive substances than PVC pipes, making them more suitable for use in industrial and chemical applications.
In terms of cost, PVC pipes are generally less expensive than CPVC pipes, which can make them a more cost-effective option for some plumbing projects.
Finally, it’s important to note that the installation process for CPVC pipes is different from that of PVC pipes. CPVC pipes require a special solvent cement that is designed for use with the material. Therefore, it’s essential to consult with a professional plumber who has experience working with both PVC and CPVC pipes to ensure that the correct materials and installation techniques are used for your specific plumbing needs.
CPVC Pipe Fittings Manufacturers and Suppliers in India. It is a hard and strong material used for successful installation of plumbing. CPVC’s natural form or material resistance, purity, and ability to resist increased heat conditions inspire an ideal material for personal space, work, and use.
Automatic channeling with fire sprinkler system. CPVC pipe and fittings are intended for personal and commercial use in hot and cold potable water systems.
CPVC (Chlorinated Poly Vinyl Chloride) has similar physical properties to CPVC and chemical resistance properties are similar to or generally superior to CPVC piping systems. The design stress of CPVC is also 2,000psi at 73°F (23°C).
Maximum service temperature is 200 °F (110 °C) under pressure with occasional exposure to boiling water. It has proven to be an excellent piping material for hot corrosive liquids, hot and cold water delivery, and similar chemical applications above the temperature range of CPVC corzan.
· Safe for the environment
· Long last and durable
· Easy installation
· Deterioration safe
· Cost-effective
· Good for transporting warm and cold water.
· Hostile to chemical compounds.
· Cannot burn unless any external fuel effect.
· Preferred at places demanding pure water supply.
CPVC pipe fittings are components used to connect and control the flow of CPVC pipes. These fittings can be classified into various types, including:
These fittings are essential components for constructing a CPVC pipe system, ensuring a secure, leak-free connection between the pipes and controlling the flow of water.
We have all CPVC Pipes and Fittings Range in all different sizes for different uses check fittings catalogue for your require product details like- 1inch, 2inch, 3inch, 4inch and 5inch CPVC Pipe Price lists. Click on enquiry button to get free quote.
CPVC pipes and fittings are supplied by various manufacturers. They are easily approachable in Schedule 40 as well as Schedule 80 sizes. It is likewise CPVC pipes that are fit for transporting both hot and cold consumable water. However, the conveyance relies on copper tube measurements (OD), IPS pipe (OD), and wall width of SDR 11.
The CPVC Pipe and Fittings Manufacturers of distinct measurements start from 1/2″ to 24″. It is accepted in India in every quality pipe or installation and mechanical structure.
1). No.1 CPVC pipes and fittings are created for the accomplishment of increased temperature so it improves fire and ecosystem deterioration caused by chemicals.
2). CPVC pipe & fittings support hot and cold water application starting from 0° C to 93°C.
3). CPVC pipe and fittings are produced in different measurements beginning from 1/2″ to
4). 4″. It is accepted in India in every plumbing quality and mechanical framework.
5). CPVC is an intense temperature polyamide piping and fitting framework that is utilized for installing a water system
| Properties | CPVC | CPVC (High Impact) | Standards |
|---|---|---|---|
| Cell classification | 23447 | 24448 | ASTM D1784 |
| Specific gravity | 1.5 | 1.51 | ASTM D792 |
| Tensile strength psi at 73°F | 7500 | 7320 | ASTM D638 |
| Modulus of elasticity tensile psi at 73°F | 380000 | 423000 | ASTM D638 |
| Flexural strength psi | 11400 | 13200 | ASTM D790 |
| Izod impact ft.lbs./in. at 73°F | notched | 2.0 10.0 | ASTM D256 |
| Compressive strength psi | 10100 | 10100 | ASTM D695 |
| Poisson’s ratio | 0.33 | 0.33 | – |
| Working stress psi at 73°F | 2000 | 2000 | – |
| Coefficient of thermal expansion in./in./°F (x 10-5) | 3.8 | 3.4 | ASTM D696 |
| Linear expansion in./10°F per 100′ of pipe | 0.44 – 0.46 | 0.41 | – |
| Maximum operating temperature under pressure | 200oF (93oC) | 200oF (93oC) | – |
| Deflection temperature under load °F at 66 psi | n/a | n/a | ASTM D648 |
| Deflection temperature under load °F at 264 psi | 212 | 239 | ASTM D648 |
| Thermal conductivity BTU.in./hr.ft2.°F | 0.95 | 0.95 | ASTM C177 |
| Burning rate | Self extinguish | Self extinguish | ASTM D635 |
| Burning class | V-0 | V-0 | UL-94 |
| Flash ignition °F | 900 | 900 | – |
| Limited oxygen index (%) | 60 | 60 | ASTM D2863-70 |
| Water absorption % (24 hrs. at 73°F) | 0.03 | 0.03 | ASTM D570 |
| Schedule 40 Grey | Schedule 80 Grey |
|---|---|
| 1/2″ – 16″ | 1/2″ – 16″ |
| MATERIALS | ||||
| PROPERTIES | PVC | CPVC (STANDARD) | CORZAN CPVC (HIGH IMPACT) | STANDARDS |
| Cell classification | 12454 | 23447 | 24448 | ASTM D1784 |
| Specific gravity | 1.42 | 1.50 | 1.51 | ASTM D792 |
| Tensile strength, psi at 73°F | 7,000 | 7,500 | 7,320 | ASTM D638 |
| Modulus of elasticity tensile, psi at 73°F | 400,000 | 380,000 | 423,000 | ASTM D638 |
| Flexural strength, psi | 14,500 | 11,400 | 13,200 | ASTM D790 |
| Izod impact, ft.lbs./in. at 73°F, notched | 0.65 | 2.0 | 10.0 | ASTM D256 |
| Compressive strength, psi | 9,000 | 10,100 | 10,100 | ASTM D695 |
| Poisson’s ratio | 0.38 | 0.33 | 0.33 | |
| Working stress, psi at 73°F | 2,000 | 2,000 | 2,000 | |
| Coefficient of thermal expansion in./in./°F (x 10-5) | 3.0 | 3.8 | 3.4 | ASTM D696 |
| Linear expansion, in./10°F per 100’ of pipe | 0.36 | 0.44 – 0.46 | 0.41 | |
| Maximum operating temperature under pressure | 140°F (60°C) | 200°F (93°C) | 200°F (93°C) | |
| Deflection temperature under load, °F at 66 psi | 173 | n/a | n/a | ASTM D648 |
| Deflection temperature under load, °F at 264 psi | 160 | 212 | 239 | ASTM D648 |
| Thermal conductivity, BTU.in./hr.ft2.°F | 1.2 | 0.95 | 0.95 | ASTM C177 |
| Burning rate | Self extinguish | Self extinguish | Self extinguish | ASTM D635 |
| Burning class | V-0 | V-0 | V-0 | UL-94 |
| Flash ignition, °F | 730 | 900 | 900 | |
| Limited oxygen index (%) | 43 | 60 | 60 | ASTM D2863-70 |
| Water absorption, %, (24 hrs. at 73°F) | 0.05 | 0.03 | 0.03 | ASTM D570 |
| Sizes | IPEX schedule 40 | IPEX Schedule 80 | |||||
| Diameter | O.D. | Wall Thickness | I.D. | *Max. Pressure
73°F |
Wall Thickness | I.D. | *Max. Pressure |
| (in.) | (in.) | (in.) | (in.) | (psi) | (in.) | (in.) | (psi) |
| 1/4 | .540 | – | – | – | .119 | .302 | 1130 |
| 3/8 | .675 | – | – | – | .126 | .423 | 920 |
| 1/2 | .840 | .109 | .602 | 600 | .147 | .526 | 850 |
| 3/4 | 1.050 | .113 | .804 | 480 | .154 | .722 | 690 |
| 1 | 1.315 | .133 | 1.029 | 450 | .179 | .936 | 630 |
| 1-1/4 | 1.660 | .141 | 1.360 | 370 | .191 | 1.255 | 520 |
| 1-1/2 | 1.900 | .145 | 1.590 | 330 | .200 | 1.476 | 470 |
| 2 | 2.375 | .154 | 2.047 | 280 | .218 | 1.913 | 400 |
| 2-1/2 | 2.875 | .203 | 2.445 | 300 | .276 | 2.290 | 420 |
| 3 | 3.500 | .216 | 3.042 | 260 | .300 | 2.864 | 370 |
| 4 | 4.500 | .237 | 3.998 | 220 | .337 | 3.786 | 320 |
| 6 | 6.625 | .280 | 6.031 | 180 | .432 | 5.709 | 280 |
| 8 | 8.625 | .322 | 7.941 | 160 | .500 | 7.565 | 250 |
| 10 | 10.750 | .365 | 9.976 | 140 | .593 | 9.493 | 230 |
| 12 | 12.750 | .406 | 11.888 | 130 | .687 | 11.294 | 230 |
| 14 | 14.000 | .438 | 13.072 | 130 | .750 | 12.412 | 220 |
| 16 | 16.000 | .500 | 14.936 | 130 | .843 | 14.224 | 220 |
| 18 | 18.000 | .562 | 16.809 | 130 | .937 | 16.014 | 220 |
| 20 | 20.000 | .593 | 18.743 | 120 | 1.031 | 17.814 | 220 |
| 24 | 24.000 | .687 | 22.544 | 120 | 1.218 | 21.418 | 210 |
| Type | Material (Cell Classification) |
Dimensions | Commercial Classification |
|---|---|---|---|
| PVC Schedule 80 | ASTM D-1784 (12454) |
ASTM D-1785 | Type I,Grade 1, PVC 1120 |
| CPVC Schedule 80 | ASTM D-1784 (23447) |
ASTM F-441 | Type IV ,Grade 1, CPVC 4120 |
| ITEM | Test Method | SI unit | ||
| UNIT | PVC | CPVC | ||
| GENERAL | ||||
|---|---|---|---|---|
| Cell Classification | ASTM D1784 | — | 12454 | 23447 |
| Maximum Usable Temp. | — | °C | 60 | 93 |
| Specific Gravity @ 73°F(23°C) | ASTM D792 | g/cc | 1.42±0.02 | 1.55±0.02 |
| Water Absorption % increase 24 hrs@ 73°F(23°C) | ASTM D570 | % | 0.04 | 0.04 |
| Hardness, Rockwell | ASTM D785 | — | 110 – 120 | 115-125 |
| Poisson’s Ratio @ 73°F(23°C) | ASTM D638 | — | 0.38 | 0.36 |
| MECHANICAL | ||||
| Tensile Strength @ 73°F(23°C) | ASTM D638 | MPa | 49.9 | 53.1 |
| Tensile Strength @194 °F(90°C) | 〃 | MPa | — | 22.1 |
| Tensile Modulus of Elasticity @ 73°F(23°C) | 〃 | GPa | 2.83 | 2.62 |
| Tensile Modulus of Elasticity @ 194°F(90°C) | 〃 | GPa | — | 1.52 |
| Flexural Strength @ 73°F(23°C) | ASTM D790 | MPa | 96.5 | 89.6 |
| Flexural Modulus of Elasticity @ 73°F(23°C) | 〃 | GPa | 2.76 | 2.69 |
| Compressive Strength @ 73°F(23°C) ε =10% | ASTM D695 | MPa | 69.0 | 96.5 |
| Compressive Modulus of Elasticity @ 73°F(23°C) | 〃 | GPa | 0.76 | 1.00 |
| Izod Impact notched @ 73°F(23°C) | ASTM D256 | J/m | 80 | 160 |
| THERMAL | ||||
| Coefficient of Linear Expansion | ASTM D696 | m/m/°C | 6.0-8.0×10 -5 | 7.0-8.0×10 -5 |
| Coefficient of Thermal Conductivity | ASTM C177 | Watt/m/°K | 0.17 | 0.13 |
| Heat Deflection Temperature Under Load (264psiannealed) | ASTM D648 | °C | 74 | 110 |
| Specific Heat | ASTM D2766 | J/°K/g | 1.1 | 1.1 |
| ELECTRICAL | ||||
| Volume Resistivity | ASTM D257 | ohm/cm | >1.0 x 10 15 | >1.0 x 10 15 |
| Dielectric Strength | ASTM D149 | volt/mm | >1000 | >1000 |
| Dielectric Constant | ASTM D150 | — | 3 | 3 |
| Power Factor | 〃 | — | 0.01-0.02 | 0.01-0.02 |
| Electrical Conductivity | — | — | Non Conductor | Non Conductor |
| FIRE PERFORMANCE | ||||
| Flammability Rating | UL-94 | — | V-0 | V-0 5VB 5VA |
| Flame Spread Index | 〃 | — | < 10 | <10 |
| Average Time of Burning | ASTM D63 | 5 sec | <5 | <5 |
| Average Extent of Burning | 〃 | mm | <10 | <10 |
| Burning Rate | 〃 | mm/min | Self Extinguishing | Self Extinguishing |
| Limiting Oxygen Index (LOI) | ASTM D2863 | LOI | 45 | 60 |
| ITEM | Test Method | SI unit | ||
| UNIT | PVC | CPVC | ||
| GENERAL | ||||
|---|---|---|---|---|
| Cell Classification | ASTM D1784 | – | 12454 | 23447 |
| Maximum Usable Temp. | – | °C | 60 | 93 |
| Specific Gravity @ 73°F (23°C) | ASTM D792 | g/cc | 1.42±0.02 | 1.55±0.02 |
| Water Absorption % increase 24 hrs@ 73°F (23°C) | ASTM D570 | % | 0.04 | 0.04 |
| Hardness Rockwell | ASTM D785 | – | 110 – 120 | 115-125 |
| Poisson’s Ratio @ 73°F (23°C) | ASTM D638 | – | 0.38 | 0.36 |
| MECHANICAL | ||||
| Tensile Strength @ 73°F (23°C) | ASTM D638 | MPa | 49.9 | 51.0 |
| Tensile Strength @194 °F (90°C) | – | MPa | – | 20.7 |
| Tensile Modulus of Elasticity @ 73°F (23°C) | – | GPa | 2.90 | 2.62 |
| Tensile Modulus of Elasticity @ 194°F (90°C) | – | GPa | – | 1.38 |
| Flexural Strength @ 73°F (23°C) | ASTM D790 | MPa | 89.6 | 82.7 |
| Flexural Modulus of Elasticity @ 73°F (23°C) | – | GPa | 2.90 | 2.76 |
| Compressive Strength @ 73°F (23°C) ε =10% | ASTM D695 | MPa | 69.0 | 103.4 |
| Compressive Modulus of Elasticity @ 73°F(23°C) | – | GPa | 0.76 | 1.10 |
| Izod Impact, notched @ 73°F (23°C) | ASTM D256 | J/m | 66 | 162 |
| THERMAL | ||||
| Coefficient of Linear Expansion | ASTM D696 | m/m/°C | 6.0-8.0×10 -5 | 7.0-8.0×10 -5 |
| Coefficient of Thermal Conductivity | ASTM C177 | Watt/m/°K | 0.16 | 0.13 |
| Heat Deflection Temperature Under Load (264psi, annealed) | ASTM D648 | °C | 80 | 102 |
| Specific Heat | ASTM D2766 | J/°K/g | 1.1 | 1.1 |
| ELECTRICAL | ||||
| Volume Resistivity | ASTM D257 | ohm/cm | >1.0 x 10 15 | >1.0 x 10 15 |
| Dielectric Strength | ASTM D149 | volt/mm | >1000 | >1000 |
| Dielectric Constant | ASTM D150 | – | 3 | 3 |
| Power Factor | 〃 | – | 0.01-0.02 | 0.01-0.02 |
| Electrical Conductivity | – | – | Non Conductor | Non Conductor |
| FIRE PERFORMANCE | ||||
| Flammability Rating | UL-94 | V-0 | V-0 5VB | 5VA |
| Flame Spread Index | 〃 | – | <10 | <10 |
| Average Time of Burning | ASTM D635 | sec | <5 | <5 |
| Average Extent of Burning | – | mm | <10 | <10 |
| Burning Rate | – | mm/min | Self Extinguishing | Self Extinguishing |
| Limiting Oxygen Index (LOI) | ASTM D2863 | LOI | 45 | 60 |
an important engineering thermoplastic due to its:
High heat distortion temperature.
Certified for use up to 200°F (93.3°C).
Relatively low material cost.
Has successfully replaced and outlasted
metals and other costly materials.
Inherent chemical resistance.
Corrosion-free piping to maintain
pressure ratings, flow rates and fluid
purity, and to prevent costly repairs.
Simple and superior installation.
Solvent welding fuses the piping
and fitting at the molecular level,
maintaining system performance.
Fire-related safety advantages.
Heat transfer coefficient is approximately
1/300th that of steel, and the material
does not sustain burning and requires no
flame to install.
Certified pressure rating.
Pressure rated in accordance with
ASTM D2837, having a Hydrostatic
Design Basis (HDB) of 4000 psi at 72°F
(23°C) and 1000 psi at 180°F (82.2°C).
COMPATIBLE WITH:
COMMON USES:
COMPATIBLE WITH:
COMMON USES:
COMPATIBLE WITH:
COMMON USES:
COMPATIBLE WITH:
COMMON USES:
COMPATIBLE WITH:
COMMON USES:
COMPATIBLE WITH:
COMMON USES:
Cement Application
Aggressively work a medium layer of cement into the fitting socket. Avoid puddling the cement in the socket. On bell end pipe do not coat beyond the socket depth or allow cement to run down into the pipe beyond the spigot end.
Cement Application
Apply a second full, even layer of cement on the pipe.
Assembly
Without delay, while the cement is still wet, assemble the pipe and fittings. Use sufficient force to ensure that the pipe bottoms
in the fitting socket. If possible, twist the pipe a quarter turn as you insert it.
Assembly
Hold the pipe and fitting together for approximately 30 seconds to avoid push out. After assembly, a joint should have a ring or bead of cement completely around the juncture of the pipe and fitting. If voids in this ring are present, sufficient cement was not applied and the joint may be defective.
Joint Cleaning
Using a rag, remove the excess cement from the pipe and fitting, including the ring or bead, as it will needlessly soften the pipe and fitting and does not add to joint strength. Avoid disturbing or moving the joint.
| Temperature
Range (oF) |
Temperature
Range (oC) |
Pipe Size (in) & system operating pressure | |||||||
| 1/2 to 1-1/4 | 1-1/2 to 2 | 2-1/2 to 8 | 10 to 14 | >16 | |||||
| <160psi | 160 – 370psi | <160psi | 160 – 315psi | <160psi | 160 – 315psi | <100psi | <100psi | ||
| 60 to 100 | 16 to 38 | 15 min | 6 hr | 30 min | 12 hr | 1-1/2hr | 24 hr | 48 hr | 72 hr |
| 40 to 60 | 4 to 16 | 20 min | 12 hr | 45 min | 24 hr | 4 hr | 48 hr | 96 hr | 6 days |
| 0 to 40 | –18 to 4 | 30 min | 48 hr | 1 hr | 96 hr | 72 hr | 8 days | 8 days | 14 days |
* The figures in the table are estimates based on laboratory tests for water applications (chemical
applications may require different set times). In damp or humid weather allow 50% more cure time (relative
humidity over 60%).
Note 1: Due to the many variables in the field, these figures should be used as a general guideline only.
Note 2: Joint cure schedule is the necessary time needed before pressurizing the system.
It is recommended for temperatures as high as 200°F compared with 140°F of CPVC. Eslon Sch80 CPVC Pipe ranging in sizes from 1/2” through 24”. These are available for light, medium, and heavy duty use. These are environmentally friendly poly- mer in terms of low carbonic acid gas emission in manufacturing process.
CPVC (Chlorinated Polyvinyl Chloride) is another rigid pipe which has three highly-desirable characteristics, good mechanical strength at high temperatures and higher chemical resistance and relatively compared to metal. CPVC polymer is more chlorinated into PVC polymer. This extra chlorine is responsible for the material’s high-temperature strength and other properties which are valuable for industrial piping.
Petron Thermoplast is among India’s greatest CPVC pipe manufactures and suppliers. These are employed for different factory and residential conveyance applications. It is also considered safe for fire sprinkler frameworks.
However, over temperatures can weaken the plastic and check 1 inch, 2 inch, 3 inch, 4 inch and 5 inch CPVC Pipe Price lists and all range sizes available here.
