Imperial Rye 90 Artificial Turf
110 oz, 1.75" Height, S Blade.
Imperial Rye 90 artificial turf is a soft and plush option. It recovers at an average rate and looks like new after brushing. Turf temperature under the direct sun is higher than average due to its body being so full. The material is resistant to wear and tear and was designed for heavy use.
See the results and test specifications below.
Meter showed 72 degrees of angle adjustment.
Softer than average.
The tennis ball jumped 19 inches. This grass provides double the cushion of our office carpet.
Blades recovered 90%
The recorded temperature is 139.1 degrees. This is 10.7 degrees warmer than a piece of plastic under the same conditions.
Wear and Tear
Blades kept their shape, recovered to 80%. Wear is slightly visible. No structural damage to blades or backing.
Every test we conduct is measured and compared to a test item for easier understanding.
- How do you measure turf softness?
We brush the turf 5 times with an angle measurement tool that is resistant to friction. The softer the turf, the less movement we will see on the ruler.
The fewer degrees on the ruler, the softer the turf.
- How do you measure cushion?
We drop a tennis ball #3 from 6 ft. above directly on the surface of the turf to measure the cushion. The less it bounces, the more cushion the artificial grass provides.
We compare results to the bounce carpet provides for clarity.
- How do you determine turf recovery?
We place a 30lb weight on the artificial grass material for 5 minutes, then wait 15 minutes at room temperature and measure blade length compared to the original.
- How do you measure temperature?
We measure the temperature under the direct sun after 30 minutes of exposure without wind.
As a data backup, we compare this to the temperature of a stainless steel plate under the same conditions.
- How do you assess wear and tear?
We apply an abrasive brush to the turf for a period of 30 seconds and observe the blade's structure afterward. We look for damage, twist, recovery, and blade structure deformation.