A Review of Foot–Terrain Interaction Mechanics for Heavy-Duty Legged Robots
Abstract
:1. Introduction
2. Supporting Feet of Heavy-Duty Legged Robots
2.1. Supporting Foot Configurations of Heavy-Duty Legged Robots
2.1.1. Feet with Passive Adaptive Joints
Cylindrical Supporting Foot Configurations
Semi-Cylindrical Supporting Foot Configurations
Spherical Supporting Foot Configurations
Hemispherical Supporting Foot Configurations
Square Supporting Foot Configurations
Special Supporting Foot Configurations
2.1.2. Feet with Active Driving Joints
2.2. Plantar Patterns of Supporting Foot of Legged Robots
3. Dynamics Analysis of Robot
3.1. Models of Pressure–Sinkage for Mobile Robot
3.1.1. Models for Pressure–Sinkage at Zero Slip Conditions
A Theoretical Exploration of the Wheeled Robots
A Theoretical Exploration of the Wheel-Legged Composite Robots
A Theoretical Exploration of the Legged Robots
3.1.2. Models for Pressure–Sinkage at Non-Zero Slip Conditions
3.2. Tangential Force Models
4. Further Research
4.1. Configuration Research of Biomimetic Supporting Feet
4.1.1. Application of Bionic Technology in Supporting Feet Design
4.1.2. Design and Distribution of Plantar Patterns of Supporting Feet
4.2. Study of Effective Contact Area between Irregular Foot and Dynamic Deformable Terrain
4.3. Mechanical Behavior Modeling of Interaction between Supporting Feet and Extreme/Dynamic Environments
4.3.1. Construction of Nonlinear Tangential Force Mathematical Model
4.3.2. Construction of Resultant Force Mathematical Model
4.4. Parameterization Research of Soil Characteristics in Extreme/Dynamic Environments
4.5. Cross-Application of Multimodal Information Fusion and Foot–Terrain Interaction Mechanics
5. Conclusions
Author Contributions
Funding
Conflicts of Interest
Nomenclature
A | Contact area | δ | Sum of foot and terrain deformations |
B | Geometric parameter of plate | λN | Dimensionless function |
b | Smaller dimension of contact patch | vT | Tangential sliding velocity |
CN | Normal damping coefficient | δT | Terrain deformation |
CT | Tangential damping coefficient | δF | Feet deformation |
Cm | Model parameter | μ | Coefficient of friction |
Cf | Shape coefficient of contact surface | FN | Normal support force |
c | Soil stickiness | FT | Tangential driving force |
α | Dimensionless geometric constant | Hp | Propagation depth of soil deformation |
β | Dimensionless geometric constant | hgr | Grouser height |
i | Slip ratio | N1, N2 | Model parameter |
j | Soil shear displacement | p | Pressure |
k | Sinkage modulus | p0 | Bearing capacity |
kN | Equivalent stiffness coefficient | s | Shearing displacement |
kFN | Stiffness coefficient of foot | s0 | Model parameter |
kTN | Stiffness coefficient of terrain | sm | Model parameter |
kc | Sinkage modulus | v | Poisson’s ratio |
kΦ | Sinkage modulus | vs | Solid volume |
kS | Stiffness modulus of terrain | vr | Pore volume |
k1 | Model parameter | w | Dimensionless coefficient |
k2 | Model parameter | z | Sinkage |
m | Exponent of damping term | zo | Static sinkage |
mF | Mass of foot | zj | Dynamic sinkage |
n | Model parameter | ρ | Bulk density |
n1, n2 | Indicators of stiffness terms |
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Robot | Length × Width × Height (m3) | Legs | Foot Shape | Driving Method | Mass (kg) | Payload (kg) | References |
---|---|---|---|---|---|---|---|
TITAN XI | 5.0 × 4.8 × 3.0 | 4 | Cylindrical | Hydraulic | 6800 | 5200 | [16] |
TITAN IX | 10 × 16 × 5.5 | 4 | Cylindrical | Electric | 170 | - | [17] |
TITAN III | - | 4 | Cylindrical | - | 80 | - | [18] |
COMET-IV | 2.8 × 3.3 × 2.5 | 6 | Cylindrical | Hydraulic | 2120 | 424 | [19] |
Dante II | 3.7 × 2.3 × 3.7 | 8 | Cylindrical | Electric | 770 | 130 | [20] |
NMIIIA | 1.5 × 0.5 × 1 | 6 | Cylindrical | Electric | 750 | 80 | [1] |
SILO 4 | 0.31 × 0.31 × 0.3 | 4 | Cylindrical | Electric | 30 | - | [21] |
ElSpider | 1.9 × 1.9 × 1.0 | 6 | Cylindrical | Electric | 300 | 155 | [22,23] |
Octopus Robot | 1.5 × 1.5 × 1 | 6 | Cylindrical | Hydraulic | 200 | 200 | [24] |
Hexapod Robot | - | 6 | Cylindrical | Hydraulic | 3000 | - | [30,31,32] |
Legged Robot | - | 6 | Cylindrical | Electric | 4200 | - | [33,34] |
Big Dog | 1.1 × 0.3 × 1 | 4 | Semi-cylindrical | Hydraulic | 109 | 50 | [25,26] |
MBBOT | 0.85 (Height) | 4 | Semi-cylindrical | Hydraulic | 140 | - | [40,41] |
HexbotIV | 1.0 × 0.72 ×1 | 4 | Semi-cylindrical | Hydraulic | 268 | 50 | [43,44] |
LS3 | 1.7 (Height) | 4 | Semi-cylindrical | Hydraulic | 590 | 182 | [45] |
SCalf-I | 1.0 × 0.4 × 0.68 | 4 | Semi-cylindrical | Hydraulic | 65 | 80 | [46] |
SCalf-II | 1.1 × 0.45 (Length × Width) | 4 | Semi-cylindrical | Hydraulic | 130 | 140 | [47] |
SCalf-III | 1.4 × 0.75 (Length × Width) | 4 | Semi-cylindrical | Hydraulic | 200 | 200 | [48] |
Space Climber1 | 8.2 × 10 × 22 | 6 | Special | Electric | 185 | - | [49] |
Space Climber2 | 8.5 × 10 × 22 | 6 | Spherical | Electric | 23 | 8 | [50] |
TITAN XIII | 2.134 × 5.584 × 3.4 | 4 | Spherical | Electric | 5.65 | 5.0 | [51,52] |
SCOUT II | 0.55 × 0.48 × 0.27 | 4 | Spherical | Electric | 20.86 | - | [53] |
SILO 6 | 0.88 × 0.45 × 0.26 | 6 | Hemispherical | Electric | 44.34 | - | [54] |
SDU Hex | 0.98 × 0.4 × 0.1 to 0.6 | 6 | Hemispherical | Electric | 35 | - | [55] |
Landmaster | 3.6 × 2.3 × 2.6 | 6 | Square | Hydraulic | 3950 | 1000 | [1] |
Landmaster 3 | 1.4 × 1.3 × 1.0 | 6 | Square | Electric | 82 | 30 | [1] |
Petman | 1.5 (Height) | 2 | Square | Hydraulic | 80 | - | [56] |
Altas | 1.8 (Height) | 2 | Square | Electric | 150 | - | [57] |
Charlie | 8 × 4.4 × 5.4 | 4 | Special | Electric | 21.5 | - | [58,59] |
Walking Truck | 4 × 3 × 3.3 | 4 | Special | Hydraulic | 1300 | - | [60] |
TITAN VII | - | 4 | Special | - | - | - | [61] |
Plate Shape | β |
---|---|
Circular | 4 |
Square | 4 |
Rectangular | |
Elliptical |
Different Feet | Pressure–Sinkage Model |
---|---|
Foot with variable cross-sectional area | |
Foot with constant cross-sectional area |
Model Name | Model Parameters | Equation Number | References |
---|---|---|---|
Bernstein | k, n | (5) | [80,81] |
Bekker | kc, kΦ, b, n | (6) | [82,83,84] |
Reece | kc, kΦ, k1, k2, b, n, c, γ | (7), (8) | [86] |
N2M | Cm, s0, sm | (10) | [87] |
Ding | kS, λN | (11) | [88] |
Hunt–Crossley | δ, n1, n2, m, kN, kFN, kTN | (12), (13) | [89] |
Youssef–Ali | k1, k2, b, n, α, β | (14) | [91] |
Gao | KN′, CN′, n1, n2, m | (17) | [93] |
Foot Shape | kTN | nTN | μ | kTT | nTT |
---|---|---|---|---|---|
Flat circular | n | 1 | |||
Flat rectangular | n | 1 | |||
Cylindrical | 1 | ||||
Spherical | 1 |
Model Name | Model Parameters | Equation Number | References |
---|---|---|---|
Coulomb | μ | (26) | [99,100] |
Hunt–Crossley | f, Ct | (27) | [89] |
Ding | βF | (28) | [93] |
Ding–Janosi | s, K′, μf, smax, κ | (30), (31) | [94] |
Feet of Large Legged Animals | Walking Mode | Characteristics | Design Elements |
---|---|---|---|
Ostrich feet | Digitigrade | The didactyl foot structure of ostriches comprises only the 3rd and 4th toes. The 3rd toe has a larger contact area with the terrain than the 4th toe. |
|
Camel feet | Plantigrade | When camel feet walk in the sand, they come into contact with the terrain with a thick finger pillow (subcutaneous layer), which can play an elastic buffering effect and have less impact on the sand. |
|
Horse feet | Unguligrade | A horse’s hoof usually has a curved shape, similar to an inverted U-shaped shape. The weight of a horse is mainly concentrated on the hoof wall, not the bottom of the hoof. The bottom of a horse’s hoof is usually flat or slightly raised. |
|
Elephant feet | Semiplantigrade | There is a thick fat foot pad beneath the root bone and metatarsal bone of an elephant’s foot. During the weight-bearing process, the weight is distributed across the entire foot pad, giving the elephant’s feet a stronger load-bearing structure. |
|
Terrain Mechanical Parameters | Dry Sand | Sandy Loam | Clayey Soil | Snow |
---|---|---|---|---|
n | 1.1 | 0.7 | 0.5 | 1.6 |
c (kPa) | 1.0 | 1.7 | 4.14 | 1.0 |
φ (°) | 30.0 | 29.0 | 13.0 | 19.7 |
kc (kPa/mn−1) | 0.9 | 5.3 | 13.2 | 4.4 |
kΦ (kPa/mn) | 1528.4 | 1515.0 | 692.15 | 196.7 |
K (m) | 0.025 | 0.025 | 0.01 | 0.04 |
Property | Viking 1 | Viking 2 | |
---|---|---|---|
Sandy Flats | Rocky Flats | Bonneville and Beta | |
Bulk density (g/cm3) | 1 to 1.6 | 1.8 | 1.5 to 1.8 |
Particle size (surface and near surface) | |||
10 to 100 μm (%) | 60 | 30 | 30 |
100 to 2000 μm (%) | 10 | 30 | 30 |
Angle of internal friction (°) | 20 to 30 | 40 to 45 | 40 to 45 |
Cohesion (kPa) | - | 0.1 to 1 | 1 |
Adhesion (kPa) | - | 0.001 to 0.01 | - |
Symbol | Meaning |
---|---|
n | 1 |
kc (kN/mn+1) | 1.4 |
kΦ (kN/mn+1) | 820 |
c (kPa) | 0.17 |
φ (°) | 35 |
K (m) | 1.78 |
Lunar Soil | Lunar Soil Density ρ (g/cm3) |
---|---|
Apollo 11 | 1.36 to 1.8 |
Apollo 12 | 1.15 to 1.93 |
Apollo 14 | 0.89 to 1.55 |
Apollo 15 | 0.87 to 1.51 |
Apollo 16 | 1.1 to 1.89 |
Luna 16 | 1.115 to 1.793 |
Luna 20 | 1.040 to 1.798 |
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Share and Cite
Zhuang, H.; Wang, J.; Wang, N.; Li, W.; Li, N.; Li, B.; Dong, L. A Review of Foot–Terrain Interaction Mechanics for Heavy-Duty Legged Robots. Appl. Sci. 2024, 14, 6541. https://doi.org/10.3390/app14156541
Zhuang H, Wang J, Wang N, Li W, Li N, Li B, Dong L. A Review of Foot–Terrain Interaction Mechanics for Heavy-Duty Legged Robots. Applied Sciences. 2024; 14(15):6541. https://doi.org/10.3390/app14156541
Chicago/Turabian StyleZhuang, Hongchao, Jiaju Wang, Ning Wang, Weihua Li, Nan Li, Bo Li, and Lei Dong. 2024. "A Review of Foot–Terrain Interaction Mechanics for Heavy-Duty Legged Robots" Applied Sciences 14, no. 15: 6541. https://doi.org/10.3390/app14156541
APA StyleZhuang, H., Wang, J., Wang, N., Li, W., Li, N., Li, B., & Dong, L. (2024). A Review of Foot–Terrain Interaction Mechanics for Heavy-Duty Legged Robots. Applied Sciences, 14(15), 6541. https://doi.org/10.3390/app14156541