ConeWango Evolution X Liners - 1 Case (100)

Description

Two hinge points permit
bending in the natural direction
of the milking machine.
Thin inner walls and
reinforced outer walls cause
the Evolution X barrel to assume an oval shape during milking.
Operates at some of
t
he lowest
accepted vacuum levels in the industry.
Engineered
for virtually no slippage.
Twist-resistant
from top to bottom.
Milks out quickly,
clearly and completely.
Accommodates
a wide range of teat sizes.
Fits perfectly
into stainless steel 06 style shells
A short milk tube that’s long on benefits.
Two hinge points
permit bending in the natural direction of the milking machine.
Can accommodate
a range of animals with various teat placements.
Lengthwise ribs
allow SMT to compress without kinking, for unrestricted milk flow.
Operates at some of
t
he lowest
accepted vacuum levels in the industry.
Engineered
for virtually no slippage.
Twist-resistant
from top to bottom.
Milks out quickly,
clearly and completely.
Accommodates
a wide range of teat sizes.
Fits perfectly
into stainless steel 06 style shells
There’s no telling how low you can go. Unique barrel design brings comfort to a whole new (vacuum) level.
Patented barrel
features a combination of thicker and thinner side walls that allow for fast milking at relatively low vacuum levels.
Thick wall sections
resist collapse before thin wall sections, causing the barrel to assume an oval shape during milking.
Oval shape
results in a shorter distance for barrel wall movement from open to collapse.
Benefits of low vacuum:
Greater overall cow comfort
with unparalleled milking comfort.
Reduced risk of ringing and teat congestion.
Reduced risk
of teat end hyperkeratosis.
Increase in Residual Vacuum available for Massage (RVM).
Easier unit removal.
Faster tissue recovery.
No liner works harder to milk gentler.
No more slip-ups.
Two-stage, controlled collapse
reduces slippage for improved udder health.
Variation in barrel wall thickness
results in a progressive, two-stage,
controlled collapse.
In first stage,
inner walls come together at an engineered collapse point while outer walls resist collapse.
In second stage,
air continues to flow up side channels past teat, feeding
the vacuum chamber.
Controlled collapse
provides greater
stability with virtually no slippage in field
tests at
significantly lower vacuum
.