Payload inertia vs. acceleration, 7 robot mounting frame, quattro s650h robot – Adept s650HS Quattro User Manual

Chapter 7: Technical Specifications

Table 7-9. Payload Mass vs. Acceleration - s800 Quattro

Platform

Payload

Maximum Acceleration

Preferred Acceleration

Type

kg

%

a

m/s

2

g

%

a

m/s

2

g

P30

10.0

90

17.6

1.8

45

8.8

0.9

P30

8.0

120

23.5

2.4

60

11.8

1.2

P30

6.0

200

39.2

4.0

80

15.7

1.6

ALL

4.0

300

58.8

6.0

120

23.5

2.4

ALL

2.0

560

109.8

11.2

240

47.0

4.8

ALL

1.5

580

113.7

11.6

320

62.7

6.4

ALL

1.0

600

117.6

12.0

320

62.7

6.4

ALL

0.1

612

120.0

12.2

320

62.7

6.4

a

% is the V+ Accel/Decel setting, which, for the Quattro, can be set as high as 1000%.

Payload Inertia vs. Acceleration

The following table provides a general guideline based on typical high-performance use. The
practical inertia for any application will vary depending on the performance requirements.

Table 7-10. Payload Inertia vs. Acceleration

Platform

60 deg.

185 deg.

P31

P32

P34

Acceleration
Value

Allowable Tool Inertia (kg-cm

2

)

100

672

75

750

188

47

250

269

30

300

75

19

500

134

15

150

37

9

750

90

10

100

25

6

NOTE: The P30 platform is not listed in this table because this platform does not
rotate. Payloads for the P30 platform should be designed with their center-of-mass
in line with the center axis of the tool flange. This will minimize induced torque
during XYZ motions.

7.7 Robot Mounting Frame, Quattro s650H Robot

NOTE: The example frame provided here was not designed to meet USDA
standards. While most mechanical specifications are the same, you will have to

Adept Quattro User's Guide, Rev F

Page 124 of 196