Ceramic Plunger
Ceramic plungers use the ultra-hard and wear-resistant properties
of modern engineering ceramic materials and can be assembled using
ceramic metallization bonding, welding, inlaying and sleeve
connection technology. They are ideal substitutes for similar metal
pumps and have been widely used in medical equipment, environmental
engineering, petroleum, chemical and other industries.
Ceramic plunger description: Ceramic plunger is made of
high-quality imported raw materials, cold isostatically pressed,
and stainless steel metal parts are assembled by high-temperature
sintering. As one of the main components of the plunger pump, the
ceramic plunger matches the plunger sleeve. The ceramic plunger is
a shaft plunger with regular shape and high dimensional accuracy.
Not only does it have high requirements for shape and position
accuracy, but wear resistance and corrosion resistance are
especially its most important properties. The performance of metal
plungers is much lower than that of ceramic plungers. Ceramic
plungers are resistant to high temperature, wear, corrosion, and
impact, and have a longer service life. They are widely used in
various liquid pumps, metering pumps, high-pressure pumps, mud
pumps, etc.
| Feature | Description |
|---|
| High Strength | Advanced ceramic materials provide exceptional physical properties
and structural integrity |
| Wear Resistance | Superior wear resistance compared to traditional materials |
| Corrosion Resistance | Excellent resistance to acids and alkalis, withstands erosion from
strong acids and bases |
| High Precision | Manufactured using special processes with high-precision advanced
ceramic materials |
| High Temperature Resistance | Withstands high temperatures and pressures without deformation or
aging |
| Long Service Life | 3-10 times longer service life compared to metal components |
| Number | Diameter(mm) | Cylindrical surface roughness(μm) | End face bevel surface roughness(μm) | Roundness(mm) |
| 1 | Φ2.00±0.001 | Ra0.1 | Ra0.2 | O≤0.002 |
| 2 | Φ3.00±0.001 | Ra0.1 | Ra0.2 | O≤0.002 |
| 3 | Φ4.00±0.001 | Ra0.1 | Ra0.2 | O≤0.002 |
| 4 | Φ5.00±0.001 | Ra0.1 | Ra0.2 | O≤0.002 |
| 5 | Φ6.00±0.001 | Ra0.1 | Ra0.2 | O≤0.002 |
| 6 | Φ7.00±0.001 | Ra0.1 | Ra0.2 | O≤0.002 |
| 7 | Φ8.00±0.001 | Ra0.1 | Ra0.2 | O≤0.002 |
| ... | ... | ... | ... | ... |
| 39 | Φ40.00±0.002 | Ra0.1 | Ra0.2 | O≤0.002 |
