The Concrete Test Hammer is used for non-destructively measuring the resistance of a reinforced concrete structure
The greater the resistance of the concrete, the greater the rebound impact. By comparing the values as indicated in the diagram labelled on the Test Hammer, the compressive strength can be found in Kg/cm2.
Instruction Manual and Abrasive Grinding Wheel are included with the Test Hammer, and Anvil-17 (17kgs) for callibrating Hammer is optional.
| Rebound Value Range | 10-60 |
| Rated Rebound Average on Anvil | 80±2 |
| Impact Kinetic Energy | 2.207J |
| Spring Rigidity | 7.85N |
| Impact Stroke | 75 mm |
| Hardness of the Impact Surface between Impact Hammer and Impact Rod | HRC59-63 |
| Max. Static Friction of the Pointer System | 0.5-0.8N |
| Dimensions | Ø 60 x 280 mm |
| Net Weight | 1.00kg |
| Gross Weight | 2.00kg |
The Concrete Test Hammer is used for non-destructively measuring the resistance of a reinforced concrete structure
The greater the resistance of the concrete, the greater the rebound impact. By comparing the values as indicated in the diagram labelled on the Test Hammer, the compressive strength can be found in Kg/cm2.
Instruction Manual and Abrasive Grinding Wheel are included with the Test Hammer, and Anvil-17 (17kgs) for callibrating Hammer is optional.
| Rebound Value Range | 10-60 |
| Rated Rebound Average on Anvil | 80±2 |
| Impact Kinetic Energy | 2.207J |
| Spring Rigidity | 7.85N |
| Impact Stroke | 75 mm |
| Hardness of the Impact Surface between Impact Hammer and Impact Rod | HRC59-63 |
| Max. Static Friction of the Pointer System | 0.5-0.8N |
| Dimensions | Ø 60 x 280 mm |
| Net Weight | 1.00kg |
| Gross Weight | 2.00kg |
