ROBOTIC APPARATUS

Abstract

Described is a robotic apparatus (10) for investigating a confined area comprising: an articulated robot (20) for insertion into a confined area, the robotic apparatus further comprising a robot control system (30) for controlling the articulated robot. Further, the robot control system comprises a control unit (50), a robot driving means, a seal (70) for isolating the confined area from the external environment and at least one transmission member (80), wherein the control unit is configured to send control signals to the robot driving means, and the at least one transmission member extends from the robot driving means to connect to the articulated robot, the at least one transmission member extending through the seal.

Claims

1. A robotic apparatus for investigating a confined area, said robotic apparatus comprising: an articulated robot for insertion into a confined area, the robotic apparatus further comprising a robot control system for controlling said articulated robot, said robot control system comprising a control unit, a robot driving means, a seal for isolating the confined area from the external environment and at least one transmission member, wherein said control unit is configured to send control signals to said robot driving means, wherein said at least one transmission member extends from said robot driving means to connect to said articulated robot, said at least one transmission member extending through said seal.

2. The robotic apparatus of claim 1, wherein said at least one transmission member extends through at least one aperture in said seal.

3. The robotic apparatus of claim 2, wherein said robot control system comprises a plurality of transmission members, and each transmission member within the plurality of transmission members extends through a separate aperture in said seal.

4. The robotic apparatus of claim 1, wherein said seal comprises a plurality of sealing members.

5. The robotic apparatus of claim 4, wherein said plurality of sealing members are arranged in series.

6. The robotic apparatus of claim 1, wherein said seal comprises at least one purging cavity.

7. The robotic apparatus on of claim 1, wherein said articulated robot comprises a plurality of members connected by joints.

8. The robotic apparatus of claim 7, wherein each joint is associated with a transmission member such that said joint can be articulated with said transmission member.

9. The robotic apparatus of claim 7, wherein one or more joints are configured to be compliantly or passively articulated.

10. The robotic apparatus of claim 1, wherein said driving means is configured to act upon said at least one transmission member to articulate said articulated robot.

11. The robotic apparatus of claim 1, wherein said driving means comprises a push rod configured to insert and remove said articulated robot into said confined area.

12. The robotic apparatus of claim 11, wherein said push rod extends into a recess or aperture within said seal.

13. The robotic apparatus of claim 11, wherein said at least one transmission member extends through said push rod.

14. The robotic apparatus of claim 1, wherein each transmission member comprises at least one linear driving portion.

15. The robotic apparatus of claim 14, wherein each transmission member comprises a rotatable portion, said rotatable portion connected to said linear driving portion via a transmission coupler.

16. The robotic apparatus of claim 15, wherein said rotatable portion of said at least one transmission member is connected to a motor.

17. The robotic apparatus of claim 14, wherein said transmission coupler is located within said seal.

18. The robotic apparatus of claim 14, wherein said at least one linear drive portion of each transmission member comprises a cable.

19. The robotic apparatus of claim 14 wherein said at least one linear drive portion of each transmission member comprises a hydraulic drive.

20. The robotic apparatus of claim 14 wherein said at least one linear drive portion of each transmission member comprises a pneumatic drive.

21. The robotic apparatus of claim 14, wherein said seal is located proximate to said articulated robot.

22. The robotic apparatus of claim 14, wherein said articulated robot comprises a fixing portion for removably retaining a tool tip.

23. The robotic apparatus of claim 22, wherein said articulated robot comprises an extraction line extending from said fixing portion through said articulated robot.

24. The robotic apparatus of claim 23, wherein said extraction line extends through said seal.

25. The robotic apparatus of claim 22, wherein said extraction line terminates at a reservoir.

26. The robotic apparatus of claim 22, wherein the robotic apparatus comprises measurement or analysis means for analysing fluid within said extraction line.

27. The robotic apparatus of claim 22, wherein the articulated robot comprises an open framed structure.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0034] Embodiments of the present invention will now be described by way of example only and with reference to the accompanying drawings, in which:

[0035] FIG. 1 depicts a robotic apparatus for investigating a confined area in accordance with the present invention;

[0036] FIG. 2 depicts a side view of the plurality of transmission member within the push rod of the driving means of the robotic apparatus of FIG. 1;

[0037] FIG. 3 depicts a perspective view of the plurality of transmission members within the push rod of the driving means of the robotic apparatus of FIG. 1; and

[0038] FIG. 4 depicts a side view of the seal of the robotic apparatus of FIG. 1.

[0039] With reference to FIG. 1, there is illustrated a robotic apparatus 10 comprising an articulated robot 20 and a robot control system 30. FIG. 1 shows the robotic apparatus in use and engaged with a pipe 40.

[0040] In use, the robot control system 30 remains external to the pipe 40 whereas the articulated robot 20 is located within the pipe 40. Additionally, in use, the longitudinal axis of the robot control system 30 is substantially parallel to the longitudinal axis of the articulated robot 20. Further, in use, the longitudinal axis of the robotic apparatus 10 is substantially co-axial with the longitudinal axis of the pipe 40.

[0041] As illustrated in FIG. 1, the robot control system 30 comprises a control unit 50, a robot driving means 60, a seal 70 and a plurality of transmission members 80. In alternative embodiments, the plurality of transmission members 80 may be a single transmission member.

[0042] The control unit 50 comprises a driver control board. During operation, the control board sends send control signals to the robot driving means 60. The control unit 50 has a user interface such that user input commands the control unit 50. The user interface may be a virtual reality (VR) system, a manually controlled joystick or an alternative envisioned by the skilled person.

[0043] The robot driving means 60 allows for articulation of the articulated robot 20 and transmission of the articulated robot 20 in to and out of a pipe 40. To achieve these functions, the robot driving means 60 comprises a drive unit (not shown) and a push rod 90.

[0044] In use, the drive unit controls the operation of the articulated robot 20 inside the pipe 40, whereas the push rod is used to manoeuvre the articulated robot 20 into the pipe 40. Here, the push rod 90 applies a linear force to the articulated robot 20 to introduce it into the pipe 40. A similar, but opposite ‘pulling’ linear motion is exerted by the push rod 90 on the articulated robot 20 to remove the articulated robot 20 from the pipe.

[0045] The drive unit comprises at least one motor, the characteristics controlled by the control unit 50. In an alternative embodiment, the drive unit comprises a linear actuator instead of a motor. The drive unit provides the linear force to insert and remove the articulated robot 20 into the pipe to the push rod 90. The push rod 90 extends parallel to the longitudinal axis of the robot control system 30. Additionally, the push rod 90 can be continuously and/or incrementally moved along a pathway that extends substantially coaxially to the pipe 40, such that the articulated robot 20 can be inserted and or removed from the pipe 40 as required.

[0046] With reference to FIG. 2, the plurality of transmission members 80 extend from the drive unit, through the push rod 90 and the seal 70, such that they connect to the articulated robot 20. As such, the plurality of transmission members 80 connect the drive unit to the articulated robot 20, allowing the articulated robot 20 to be controlled by a user via the control system 30.

[0047] In this embodiment, each of the plurality of transmission members 80 comprises a rotatable portion 100 and a linear driving portion 110. The rotatable portion 100 of each of the transmission members is connected to the drive unit, and the linear driving portion 110 of each transmission member is connected to the articulated robot 20. The rotatable portion 100 of each transmission member is connected to its respective and/or complimentary linear driving portion 110 via a transmission coupler 120. As such, the transmission coupler 120 converts the rotational motion of each rotatable portion 100 to a linear motion in the respective linear driving portion 110.

[0048] In an alternative embodiment, wherein the drive unit supplies linear rather than rotational motion, the rotatable portion 100 is instead a second linear driving portion.

[0049] The longitudinal axes of the plurality of transmission members 80 are substantially parallel to each other and further substantially parallel to the longitudinal axis of the robot control system 30. In this way, the articulated robot 20 can be controlled in a manner that ensures it retains a reduced diameter enabling it to operate within narrow pipes.

[0050] With reference to FIG. 3, the driving means 60 has a substantially circular cross section. A substantially circular cross section is preferred as this maximises the cross-sectional area available for the driving means 60 within any given pipe. As can be seen in FIG. 3, the rotatable portions 100 of the plurality of transmission members 80 are evenly spaced about two circular paths, an inner path 130 and outer path 140. The centre point of the inner path 130 and the outer path 140 are at the centre point of the circular cross section of the driving means 60.

[0051] The plurality of transmission members 80 are equally divided between the inner path 130 and the outer path 140. As a result of this, the spacing between the plurality of transmission members 80 is smaller around the inner path 130 than the outer path 140. In another embodiment, the inner path 130 and outer path 140 are mounted on offset longitudinal planes to reduce the diameter of the drive unit.

[0052] The linear drive portion 110 of each of the transmission members within the plurality of transmission members 80 comprises a cable which connects to a joint of the articulated robot 20. Together, the cables transfer motion from the drive unit to the joints of the articulated robot 20. Every joint of the articulated robot 20 can be articulated independently of every other joint of the articulated robot 20. In this way, the movement of the articulated robot 20 can be precisely controlled.

[0053] A seal 70 defines a boundary between the inside of the pipe 40 and the external environment. The seal 70 extends across the entrance of the pipe 40. The transmission coupler 120 is located within the seal 70. Embodiments where the transmission coupler 120 is located partially or wholly within the seal 70 are envisioned by the applicant. In use, the seal 70 is located near the end of the driving means 60, such that the control unit 50 and driving means 60 are external to the pipe 40. The seal 70 forms a barrier around the transmission coupler 120, such that the environment within the pipe 40 is contained and separated from the general environment.

[0054] As illustrated in FIG. 4, the seal 70 comprises a series of seals with a primary seal 150, a secondary seal 160 and a tertiary seal 170. The primary seal 150 is located such that it is the first seal between the pipe 40 and the external environment and the tertiary seal 170 is the seal furthest removed from the pipe 40. The use of multiple seals helps increase the security of the seal 70 as a whole, and acts as a redundancy or fail-safe mechanism.

[0055] A purging seal cavity 180 is present between the primary seal 150 and the secondary seal 160. The purging seal cavity 180 may be checked for contaminants from within the pipe to determine if the primary seal 150 has been compromised. Additionally, the purging seal cavity 180 may be filled with a known gas mixture. In this case, the composition of the gas mixture within the purging seal cavity 180 may be analysed to determine if the primary seal 150 has been compromised, or both the secondary seal 160 and tertiary seal 170 have been compromised and air from the external environment has entered the purging seal cavity 180.

[0056] It is also envisaged that the seal may contain a number of purging seal cavities, each potentially filled with a different known gas mixture, such that the failure of any one of the primary seal 150, secondary seal 160 or tertiary seal 180 can be identified in isolation.

[0057] The articulated robot 20 is built such that it is able to withstand the conditions of the confined area of a pipe 40. The articulated robot 20 is suitable for use in both high and low pressure environments, as well as in a vacuum, and can withstand hazardous and non-hazardous substances present in the pipe 40. The articulated robot 20 has an open frame structure, such that there are no voids in the articulated robot 20 and pressure is equalised between the articulated robot 20 and the pipe 40.

[0058] Within the robot control system 30 is at least one safety device that ensures that, even under power failure, the articulated robot 20 is not pushed out or pulled into the confined area due to a differential pressure between the confined area and external environment.

[0059] The articulated robot 20 can be inserted into the pipe 40 through a standard tapping point. As the drive means 60 is located outside of the pipe 40, the articulated robot 20 is sized such it can enter the pipe 40 up to an 8 inch (20 cm) diameter tapping point. The articulated robot 20 comprises a plurality of joints connecting a plurality of members. The plurality of members are attached end to end, such that the longitudinal axis of each member is substantially parallel to the longitudinal axis of the articulated robot 20. The length of the individual members decreases as the distance from the drive means 60 increases, with the longest member located at the end of the articulated robot 20 tethered or connected to the drive means 60. As such, given the members are shortest in length distal from the drive means 60, the motion of the articulated robot 20 can be controlled with greater precision at the end of the articulated robot 20 furthest removed from the robot control system 30 and drive means 60.

[0060] The articulated robot 20 further comprises a fixing portion 190 for removably retaining a tool tip 200. In the described embodiment of the invention, the tool tip 200 comprises a camera and two LED lights. In use, images and other information from the camera can be communicated through the articulated robot 20 and the robot control system 30 to the control unit 50, so that the user may respond and operate the robotic apparatus 10 accordingly. For example, the user may use a virtual reality (VR) headset to control the articulated robot 20. Additionally, the user may be able to control and operate the articulated robot 20 via monitoring images from the camera displayed on a screen. In the described embodiment, signals from the camera are communicated through the articulated robot via cables, although wireless transmission of the signal is also envisaged.

[0061] The tool tip 200 further comprises a material extraction line 210. The material extraction line 210 is configured such that unwanted material, such as fluid or material causing a blockage, can be removed from the pipe 40 during operation of the robotic apparatus 10. The articulated robot 20 comprises an extraction line 210 extending from the tool tip 200 through the articulated robot 20. The extraction line 210 is flexible such that it does not inhibit the articulation of the articulated robot 20 during use. To aid in the extraction of material, the extraction line 210 may be connected to a pump of vacuum source which depressurises the extraction line 210 such that material is removed from the pipe 40 via suction. The extraction line 210 continues through the seal 70 and terminates at a reservoir 220 external to a pipe 40. Alternatively, the extraction line 210 may feed directly into an external drain. The fluid being removed from the tool tip 200 exits via an on-line analyser which determines the constituents of the material or a particular parameter of interest.

[0062] The tool tip 200 comprises at least one tool to aid inspection and maintenance tasks, including but not limited to a location system, spectroscopy, eddy current, ultrasonic analyser and laser ablation or other physical means to remove scaling and deposits.