FORCE AMPLIFICATION MOBILE ROBOTIC SYSTEM (EXOBOT)

Abstract

The present invention proposes a mobile robotic system capable of carrying out the movement, manipulation and precise installation of industrial loads (pipes, plates, equipment, parts, materials, etc.), using a single operator for that and presenting ease of use. The invention is basically composed of an anthropomorphic-type industrial robot (3) and a crawler mobile platform (11). The load capacity of the invention is limited by the maximum load capacity of the industrial robot employed. The precise positioning step has a special force amplification system (external exoskeleton) capable of moving a load fixed on the industrial robot wrist (position and orientation) with the force actions of an operator, directly on the robot wrist, or by means of a security extension. The robotic system can be controlled by radio control, capable of allowing both the control of the robot and the movement of the platform.

The proposed system of this invention comprises a mobile platform for all types of terrain, an industrial robotic arm, an effector for handling pipes, an effector to pick up metal plates, the respective supports of effectors in a quick tool change system, a diesel electric generator, an industrial radio control, safety sensors and a video monitor for two cameras positioned on the robot structure.

Claims

1. A force amplification mobile robotic system characterized in that it comprises a mobile platform (11), with capacity for displacement in different types of terrain, a tool changer (19), force transducers (Load Cells) (18) and (20), Video Cameras A and B (2) and (15), an industrial robot (3), an effector for pipes (4), an effector for plates (8), support of effectors (5) and (7), a power generator (9), a remote control (13), an air compressor and a real-time industrial computer.

2. The force amplification mobile robotic system according to claim 1, characterized in that it uses an industrial robot (3) with high load capacity (400 kg) and 6 degrees of freedom with the ability to move the load (position and orientation) without the need for programming, by means of a force amplification control system performed directly on the robot wrist, using only the operator's strength, in pulling, pushing and turning actions.

3. The force amplification mobile robotic system accordingly to claim 1, characterized in that it uses a guiding tool (1), which allows an operator to be able to move the load (position and orientation), over a safe distance of operation.

4. The force amplification mobile robotic system accordingly to claim 1, characterized in that there is the complete movement of a mobile platform (11) and an industrial robot (3), by means of an industrial remote control (13), totaling 8 degrees of freedom (6 in the robot+2 in the mobile platform).

Description

BRIEF DESCRIPTION OF DRAWINGS

[0016] The present invention will be described in more detail below, with reference to the attached figures which, in a schematic form and not limiting the inventive scope, represent examples of its embodiments:

[0017] FIG. 1 is a back perspective view of an embodiment of a mobile robotic system;

[0018] FIG. 2 is a side view of the mobile robotic system of FIG. 1; and

[0019] FIG. 3 is a magnified view of a portion of the mobile robotic system of FIG. 1.

DETAILED DESCRIPTION OF THE INVENTION

[0020] There follows below a detailed description of an embodiment of the present invention, of an exemplary nature and in no way limiting. Nevertheless, there will become clear to a technician skilled on the subject, from reading this description, the possible additional embodiments and variations of the present invention further comprised by the essential and optional features below.

[0021] The present invention can be used in different assembly processes (static equipment), pipelines, spheres for gas storage, construction and maintenance of refineries, tank cleaning processes, positioning of loads with precision, handling of plates for welding, temporary storage of parts and others. Its use can be both civil and military, and can act in other industrial branches, such as the nuclear, naval, railway, subway, road industry to move by means of the movement of parts and equipment directly by the action and command of an operator.

[0022] The system of this invention acts as an external exoskeleton, where an anthropomorphic industrial robot with 6 degrees of freedom supports a load of up to 400 kg, which is moved by the action of an operator, directly on the load, without the need for programming, using a remote control or a robot operator interface. Thus, its use for the movement of materials is very wide, and it is enough to carry out the correct fixation of the load in a respective effector. It is up to the operator to perform movements of pulling, pushing and rotating the load so that the robot performs, in a synchronized way, the respective movements in the directions imposed by the operator. No prior knowledge of robot programming is required by the operator. The load can be placed in any position and orientation, within the robot range of action, remaining stationary in its last position and orientation, when no external force acts on the load.

[0023] In FIG. 1 the following items are represented: Remote Guiding Wheel (1), Video Camera A (2), Industrial Robot (3), Gripper Effector (4), Gripper Effector Support (5), Robot Control Cabinet (6), Plate Gripper Effector Support (7), Plate Gripper Effector (8), Power Generator (9), Crawler Mobile Platform Motor Access (10), Crawler Mobile Platform (11), General Control Cabinet (12), System Remote Control (13), Video Monitor for Cameras A and B (14).

[0024] In FIG. 2, another view of the invention, the following items are represented, some repeated from FIG. 1: Video Camera A (2), Industrial Robot (3), Robot Control Cabinet (6), Plate Gripper Effector Support (7), Plate Gripper Effector (8), Power Generator (9), Crawler Mobile Platform Motor Access (10), Crawler Mobile Platform (11), System Remote Control (13), Video monitor of cameras A and B (14), Video camera B (15).

[0025] According to FIGS. 1 and 2, the mobile robotic system of force amplification is formed by a crawler mobile platform (11), with locomotion capacity in any terrain, wherein it receives an anthropomorphic industrial robot with six degrees of freedom (3), totaling eight degrees of freedom considering the movement of the mobile platform. The structure of the mobile platform (11) further has the function of supporting all other equipment, such as: the Gripper effector (4), the Plate Gripper Effector (8), the supports of other effectors (5) and (7), the electrical power generator (9), the robot control cabinet (6), an air compressor, a hydraulic unit (not visible) and other equipment and sensors.

[0026] In order to increase the safety of moving the load, an extra guiding device (1) can be added to the exoskeleton system, to allow the operator to manipulate the load at a distance of 1.0 m from its respective perpendicular shadow. This ensures that, in the event of a failure in the fastening system, the fall of the load does not hit the operator, especially his lower limbs, such as feet and legs. This guiding device (1) consists of a 1.0 m long aluminum tube with a control wheel. The pulling, pushing and rotating actions of the load can be applied to this wheel, without prejudice to the system exoskeleton capacity.

[0027] Load fixing depends exclusively on the type of effector used (also referred to as tool or gripper). To allow the exchange between different types of effectors, the robot is equipped with a tool changer (19), shown in FIG. 3, for industrial use, formed by a master coupler (master), fixed to the robot wrist (3), and other slave couplers (tools), each one properly fixed to the effectors.

[0028] The present invention uses two types of effectors, one being exclusive for handling pipes (called Gripper) (4) and another for steel plates (Plate Gripper) (8). However, the invention is not limited only to pipes and plates, since it is possible to use different types of effectors, for which it is necessary to install a slave coupler in this new effector.

[0029] Tool changers can be of any type and model, as long as they meet the requirements of load, moment of inertia and fast exchange of signals between the robot and the tool. The tool change operation uses compressed air to open, close and lock the master coupler on the slave. Due to this, but not limited to the use of compressed air, the invention uses an air compressor to provide this source of energy (not visible, as it is installed inside the mobile platform). Other models of tool changers can be used in the invention, which can be electrical, mechanical or hydraulic in nature.

[0030] The system is not limited to the use of a crawler mobile platform (11), but can be a mobile platform with wheels of any material, metallic or rubber crawler, use on rails or any locomotion system for industrial use and for any type of terrain (asphalt, earth, mud, snow, grass, concrete, etc.), as long as it has the capacity to support the robot mass, the respective load of up to 400 kg, the changers and effectors. The energy source of the mobile platform (10) is not limited to the use of diesel engines, and may be based on gasoline, alcohol, natural gas, LPG (Liquefied Petroleum Gas) or electric, by means of battery banks of any type, in addition to fuel cells or turbines.

[0031] The electric power generator (9) is not limited to the use of diesel; it can be a gasoline, alcohol or any other type of fuel generator, provided that it performs the function of a generator. This equipment can still be installed together with the motor of the mobile platform (10), taking advantage of part of the motor energy of the platform motor.

[0032] The robot control cabinet (6) can be unified with the general control cabinet of the invention (12), thus having a single cabinet to house all the electrical and electronic equipment of the invention.

[0033] In order to assist the operator in conditions of difficult access, the system has two video cameras (2) and (15) with the purpose of sending the images in real time to a portable monitor (14), fixed next to the system remote control (13), which is attached to the operator's waist by means of a belt. This system does not hinder the movement of the operator's arms, leaving them free for other operations.

[0034] The invention is limited to loads of up to 400 kg due to the operational limitations of the used industrial robot (3). Since there is a wide range of load capacity (payload) for industrial robots available on the market, the invention can work with larger or smaller loads, as long as another robot is used.

[0035] The invention makes use of two load cells (18) and (20), with different operational limits, as shown in FIG. 3. The higher capacity load cell (20) is intended to monitor the load on the effector and detect load collision, with usage range compatible with the robot capacity (400 kg). The lower capacity load cell (18) is used in the exoskeleton control cycle, fixed to the guiding ring (16), as shown in FIG. 3. The latter is responsible for measuring the operator's force and torque actions (pulling, pushing and turning) and transmit the same to the robot (3) in a real-time control cycle, thus realizing the main function of this invention. The guiding ring (16) can be operated directly with the operator's hand or indirectly with the remote guiding tool (1). Activation buttons (17) and (21), both shown in FIG. 3, act as a safety button, releasing the robot movements only when they are pressed. This prevents the robot from making any unwanted movements if the operator drops the load or the wheel.

[0036] The exoskeleton function of the invention (or assisted operation) is implemented in a real-time algorithm executed in an industrial computer, installed inside the general control cabinet (12). This program interprets the signals from the load cell (18) and performs the respective movement of the industrial robot (3). The industrial computer used represents a high-performance, high-reliability and fail-safe embedded system.

[0037] The industrial robot (3) can also be controlled by means of a remote control (13), which is an alternative movement when the load is out of the reach of the operator. In certain positions, the robot wrist can reach a height of 5.5 m, thus requiring the use of the remote control (13) to place the wrist and, consequently, the effector with the load, at a suitable height for operator-assisted operation. This remote control is also responsible for moving the mobile platform (11), since there is no cabin or manual movement controls. These movement functions using the remote control (13), both of the robot (3) and the mobile platform (11), are implemented in the control cycle of the industrial computer.