GB2496335A - Finger digit for robotic hand - Google Patents

Abstract

A robotic finger digit has a distal finger joint 118 coupled between a distal finger part 112 and a middle finger part 114 and a middle finger joint 120 coupled between the middle finger part 114 and a proximal finger part 116. An extend tendon 202 and a flex tendon 206 are each coupled at a first end to the distal finger joint and at a second end to an actuation device, which may for example be a motor or an air muscle device. The actuation device moves extend tendon 202 and flex tendon 206 substantially the same distance in order to flex and/or extend the robotic finger digit. Preferably a loopback tendon 204 is provided to bias the finger joint in an extended position; loopback tendon 204 may be provided with a biasing device 208.

Description

ROBOTIC HAND

TECHNICAL FIELD

The invention relates to a robotic hand. In particular, the invention relates to a motorised robotic hand. In one embodiment, the robotic hand has improved force sensing. In another embodiment, the robotic hand has improved control of digit movement.

BACKGROUND

It is desirable to use robotic devices in many industries. US Patent No: 7,168,748 62 entitled "Intelligent, Self-Contained Robotic Hand" discloses a known robotic hand comprising three fingers. However, it is desirable for a robotic hand to imitate a human hands gripping functionality and range of movement.

The human hand is capable of numerous, and a wide range of, movements. In addition, the human hand is capable of gripping objects of numerous different sizes using a wide range of forces from very delicate to very strong. The vast range of movements and functionality are difficult to mimic, since each additional range of movement requires the use of a further joint in the robotic hand. Each joint of a robotic hand requires a power supply and control means, both of which require connection to the joint. This results in a highly complex arrangements of wires, which multiplies for every additional joint. The large numbers of wires results in robotic hands being complex to produce and bulky, which in turn reduces the dexterity of the robotic hand.

The present invention aims to provide a robotic hand which more closely mimics a human hand. In addition, the present invention aims to provide a robotic hand which has more accurate control and which is less bulky than known robotic hands.

SUMMARY

According to one embodiment of the invention a robotic hand assembly is provided. The robotic hand assembly comprising: a hand section comprising: at least one digit provided with at least one actuatable joint; and a control section comprising: at least one actuation device, the at least one actuation device comprising: a sensing module configured to sense a force applied to a tendon coupled at a first end to the at least one actuatable joint; and an actuation module configured to actuate the at least one actuatable joint.

According to another embodiment of the invention the tendon comprise a first tendon and a second tendon.

According to another embodiment of the invention the sensing module comprises: a first force sensor; a second force sensor; and a connection bar coupled between the first and second force sensors.

According to another embodiment of the invention the first force sensor is configured to sense a force applied to the first tendon and the second force sensor is configured to sense a force applied to the second tendon.

According to another embodiment of the invention the first tendon is routed over the connection bar adjacent to the first force sensor, and the second tendon is routed over the connection bar adjacent to the second force sensor.

According to another embodiment of the invention the sensing module further comprises: a spool, wherein a second end of the tendon is coupled to the spool.

According to another embodiment of the invention the spool comprises a first spool and a second spooi, and wherein the second end of the first tendon is coupled to the first spool and the second end of the second tendon is coupled to the second spool.

According to another embodiment of the invention the first spool and the second spool are configured to be moveable relative to one another, in order to adjust a tension in the first and second tendons.

According to another embodiment of the invention the sensing module further comprises: a securing device configured to secure the first and second spools relative to one another.

According to another embodiment of the invention the at least one actuation device further comprises: a tensioner module configured to apply tension the tendon.

According to another embodiment of the invention the tensioner module comprises: biasing means configured to bias the tendon in a first direction to apply tension to the tendon.

According to another embodiment of the invention the biasing means comprises: a pulley provided in a recess, wherein the tendon is routed around the pulley; and a biasing device coupled to the pulley biasing the pulley towards a first end of the recess to apply tension the tendon.

According to another embodiment of the invention the biasing device comprises a spring.

According to another embodiment of the invention the actuation module comprises a motor and gears.

According to another embodiment of the invention the actuation module further comprises control means for controlling the motor and gears.

According to another embodiment of the invention the control means comprises a printed circuit board.

According to another embodiment of the invention the control section comprises: a cooling device configured to cool the at least one actuation module.

According to another embodiment of the invention the robotic hand assembly further comprises: a routing plate configured to enable routing of the tendons to the associated actuation device.

According to another embodiment of the invention the routing plate comprises: a square routing plate; or a rectangular routing plate; or a hexagonal routing plate, or a circular routing plate.

According to another embodiment of the invention the routing plate comprises a plurality of grooves, each groove for routing a tendon.

According to one embodiment of the invention a sensing module for sensing a force applied to a tendon coupled at a first end to an actuatable joint is provided. The sensing module comprising: a first force sensor; a second force sensor; and a connection bar coupled between the first and second force sensors.

According to another embodiment of the invention the tendon comprise a first and second tendon, and wherein the first force sensor is configured to sense a force applied to the first tendon and the second force sensor is configured to sense a force applied to the second tendon.

According to another embodiment of the invention the first tendon is routed over the connection bar adjacent to the first force sensor, and the second tendon is routed over the connection bar adjacent to the second force sensor.

According to another embodiment of the invention the sensing module further comprises: a spool, wherein a second end of the tendon is coupled to the spool.

According to another embodiment of the invention the tendon comprise a first and second tendon, wherein the spool comprises a first spool and a second spool, and wherein the second end of the first tendon is coupled to the first spool and the second end of the second tendon is coupled to the second spool.

According to another embodiment of the invention the first spool and the second spool are configured to be moveable relative to one another, in order to adjust a tension in the first and second tendons.

According to another embodiment of the invention the sensing module further comprises: a securing device configured to secure the first and second spools relative to one another.

According to one embodiment of the invention a tensioner module for applying tension to a tendon coupled at a first end to an actuatable joint is provided. The tensioner module comprising: a pulley provided in a recess, wherein the tendon is routed around the pulley; and a biasing device coupled to the pulley biasing the pulley towards a first end of the recess to apply tension the tendon.

According to another embodiment of the invention the biasing device comprises a spring.

According to one embodiment of the invention an actuation device for actuating a joint is provided. The actuation device comprising: a sensing module configured to sense a force applied to a tendon coupled at a first end to the joint; and an actuation module configured to actuate the at east one joint.

According to another embodiment of the invention the actuation device further comprises: a tensioner module configured to apply tension the tendon.

According to another embodiment of the invention the actuation module comprises a motor and gears.

According to another embodiment of the invention the actuation module further comprises control means for controlling the motor and gears.

According to another embodiment of the invention the control means comprises a printed circuit board.

According to another embodiment of the invention the control section comprises: a cooling device configured to cool the at least one actuation module.

According to one embodiment of the invention a robotic finger digit is provided. The robotic finger digit comprising: a distal finger joint coupled between a distal finger part and a middle finger part; a middle finger joint coupled between the middle finger part and a proximal finger part; an extend tendon coupled at a first end to the distal finger joint, and coupled at a second end to an actuation device; and a flex tendon coupled at a first end to the distal finger joint, and coupled at a second end to the actuation device, wherein the actuation device is configured to move the extend tendon and the flex tendon substantially the same distance in order to flex and/or extend the robotic finger digit.

According to another embodiment of the invention the distal finger joint is configured to enable the distal finger part to move about a first axis.

According to another embodiment of the invention the middle finger joint is configured to enable the middle finger part to move about a second axis, parallel to the first axis.

According to another embodiment of the invention the actuation device comprises a motor, or an air muscle device.

According to another embodiment of the invention the robotic finger digit further comprises: a loopback tendon coupled at a first end to the distal finger joint, and configured to bias the robotic finger digit in a extend position.

According to another embodiment of the inventEon the robotic finger digit further comprises: a biasing device provided at a second end of the loopback tendon.

According to another embodiment of the invention in use, activation of the extend tendon and the flex tendon results in actuation of the distal finger joint and the middle finger joint.

According to one embodiment of the invention a wrist joint assembly for a robotic hand is provided. The wrist joint assembly comprising: a first wrist joint configured to enable the robotic hand to move about a first axis, and coupled to a first wrist joint tendon; a second wrist joint configured to enable the robotic hand to move about a second axis orthogonal to the first axis, and coupled to a second wrist joint tendon, the second wrist joint comprising a substantially circular guide surface for the second wrist joint tendon; and an actuation device configured to actuate the first wrist joint tendon and the second wrist joint tendon substantially the same distance in order to actuate the first and second wrist joints.

According to another embodiment of the invention the first wrist joint tendon comprise a first flex wrist joint tendon and a first extend wrist joint tendon, and wherein the second wrist joint tendon comprise a second flex wrist joint tendon and a second extend wrist joint tendon

BRIEF DESCRIPTION OF THE FIGURES

For a better understanding of the invention and as to how the same may be carried into effect reference will now be made, by way of example only, to the accompanying figures, in which: Figure IA illustrates a motorised robotic hand; Figure lB illustrates a motorised robotic hand; Figure 1C illustrates schematically a motorised robotic hand; Figure 2 illustrates schematically components of a robotic hand; Figure 3A illustrates schematically components for actuating a digit of a robotic hand; Figure 3B illustrates schematically components for actuating a digit of a robotic hand; Figure 4A illustrates schematically a digit of a robotic hand; Figure 4B illustrates schematically a digit of a robotic hand; Figure 5 illustrates schematically a perspective view of components for actuating a digit of a robotic hand; Figure 6 illustrates schematically a side view cut-through of the components of figure 5; Figure 7 illustrates schematically a side view of a tensioner module; FigureS illustrates schematically a perspective view of a tensioner module; Figure 9 illustrates schematically another side view of a tensioner module; Figure 10 illustrates schematically a perspective view of a sensing module; Figure 11 illustrates schematically another perspective view of a sensing module; Figure 12 illustrates schematically a side view cut-through of a sensing module; Figure 13 illustrates schematically a perspective view of a spool; Figure 14 illustrates schematically another perspective view of a spool; Figure 15 illustrates schematically an arrangement of tendons for controlling movement of a robotic wrist section; Figure 16A illustrates a perspective view of an underside of a routing plate; and Figure 1GB illustrates a perspective view of a routing plate.

DETAILED DESCRlPTION Additional advantages and novel features of the invention will be set forth in part in the description which follows, and in part will become apparent to those skilled in the art upon examination of the following and accompanying figures or may be learned by practice of the invention.

Figures 1A, 16 and 1C illustrate a motorised robotic hand. As can be seen from figures 1A, lB and 1C, a motorised robotic hand comprises a hand section 10 and a control section 20.

The hand section 10 comprises four finger digits 102, 104, 106, 108 and a thumb digit 110, which substantially imitate the digits of a human hand, a palm section 150, which substantially imitates a human palm, and a wrist section 140, 142, 144, which substantially imitates a human wrist. The control section 20 comprises a plurality of actuation devices, each actuation device comprising a tensioner module 300, a sensing module 400 and an actuation module 500. Figure l.A illustrates four actuation devices, whilst figure 16 illustrates eight actuation devices. Each actuation device enables movement of one component, such as one joint of a digit, of the robotic hand section 10. As can be seen from figure 1B, a fan may be provided in order to cool the actuation modules 500.

Figure 2 illustrates schematically exemplary components of the robotic hand section 10.

Each finger digit 102, 104, 106, 108 includes a distal finger part 112, a middle finger part 114 and a proximal finger part 116. Only the distal, middle and proximal finger parts 112, 114, 116 of finger digit 102 are labelled in figure 2. However, it is clear from figure 2 that finger digits 104,106 and 108 also include finger parts 112, 114, 116.

The distal finger part 112 and the middle finger part 114 are connected by a distal finger joint 118. The distal finger joint 118 enables the distal finger part 112 to move about an X axis X1, illustrated in figure 2, with respect to the middle finger part 114. The middle finger part 114 and the proximal finger part 116 are connected by a middle finger joint 120. The middle finger joint 120 enables the middle finger part 114 to move about an X axis X2, iUustrated in figure 2, with respect to the proximal finger part 116. Finally, the proximal finger part 116 is connected to the palm section 150 by a proximal finger joint 122. The proximal finger joint 122 enables the proximal finger part 116 to move about an X axis X3 and about a V axis VI, illustrated in figure 2, with respect to the palm section 150. Axes X1, X2 and X3 are parallel to one another. Axis V1 is orthogonal to axes X1, X2 and X3. Only the distal, middle and proximal finger joints 118, 120, 122 of finger digit 102 are labelled in figure 2. however, it is clear from figure 2 that finger digits 104, 106 and 108 also include finger joints 118, 120, 122.

The thumb digit 110 includes a distal thumb part 128, a middle thumb part 130 and a proximal thumb part 132.

The distal thumb part 128 and the middle thumb part 130 are connected by a distal thumb joint 134. The distal thumb joint 134 enables the distal thumb part 128 to move about a V axis V2, illustrated in figure 2, with respect to the middle thumb part 130. The middle thumb part 130 and the proximal thumb part 132 are connected by a middle thumb joint 136. The middle thumb joint 136 enables the middle thumb part 130 to move about a V axis V3 and an X axis X4, illustrated in figure 2, with respect to the proximal thumb part 132. Finally, the proximal thumb part 132 is connected to the palm section 150 by a proximal thumb joint 138. The proximal thumb joint 138 enables the proximal thumb part 132 to move about an X axis X5, and about a Z axis Z, illustrated in figure 2, with respect to the palm section 150.

Axes V2 and V3 are parallel to one another. Axes X4 and X5 are parallel to one another. Axes X4 and X5 are orthogonal to axes V2 and V3. Finally, axis Z1 is orthogonal to axes V2 and V3, and axes X4 and X5.

First palm joint 124 and second palm joint 126 enable movement of the palm section 150 such as the thumb digit 110 can touch the third and fourth finger digits 106 and 108.

However, other palm sections 150 may also be used. For example, the palm sections 150 illustrated in figure 1C only comprises a second palm joint 126 to enable movement of the palm section 150.

The hand section 10 is connected to the control section 20 via the wrist section 140, 142.

First wrist joint 140 enables the hand section 10 to move about an X axis X6, illustrated in figure 2, with respect to the control section 20 (not illustrated in figure 2). second wrist joint 142 enables the hand section 10 to move about a V axis V41 illustrated in figure 2, with respect to the control section 20 {not illustrated in figure 2). Axes X5 and V4 are orthogonal to one another.

The hand section 10 illustrated schematically in figure 2 is provided for illustrative purposes only and other hand sections 10 comprising different finger and thumb digit arrangements, and different palm and wrist section arrangements may be used in combination with the control section 20 of the invention.

Each joint enables movement in a first direction about an axis, and in a second direction, opposite to the first direction, about the axis. For example, in figures 3A, joint 560 enables movement of part 570 in a first direction 580A about an axis (through the page of figure 3A), and in a second direction 580B, opposite to the first direction 580A, about the axis. In figures 3B, joint 650 enables movement of part 660 in a first direction 670A about an axis (through the page of figure 38), and in a second direction 6708, opposite to the first direction 670A, about the axis.

Joints 122, 136 and 138, illustrated in figure 2, can be thought of as essentially two separate joints. Proximal finger joint 122 comprises a first proximal finger joint enabling movement in a first direction about axis X3, and in a second direction, opposite to the first direction, about axis x3, and a second proximal finger joint enabling movement in a first direction about axis V1. and in a second direction, opposite to the first direction, about axis V1. Middle thumb joint 132 comprises a first middle thumb joint enabling movement in a first direction about axis Y3, and in a second direction, opposite to the first direction, about axis V3 and a second middle thumb joint enabling movement in a first direction about axis X4, and in a second direction, opposite to the first direction, about axis X4. Proximal thumb joint 138 comprises a first proximal thumb joint enabling movement in a first direction about axis X5, and in a second direction, opposite to the first direction, about axis X5 and a second proximal thumb joint enabling movement in a first direction about axis Z1, and in a second direction, opposite to the first direction, about axis 4.

Two tendons are attached, at a first end, to each joint. The two tendons are also connected, at a second end, to an actuation device (such as control section 20 of figures 1A to 1C) in order to actuate each joint in the first direction, and in the second direction, opposite to the first direction. An actuation device is required for each joint.

In one embodiment, one tendon could be used, looped around and connected to the joint at a mid section. The first and second ends of the tendon being connected to an actuation device in order to actuate the joint in the first direction and in the second direction, opposite to the first direction.

Figures 3A and 3B illustrates schematically components for actuating a joint. Figure 3A illustrates schematically a motor driven actuation device (such as control section 20 of figures 1A to 1C) and figure 3B illustrates an air muscle driven actuation device.

The motor driven actuation device of figure 3A comprises a motor 505; gears 510; a first spool 520; a first force sensor 530A; a second force sensor 5306; a first tensioner 5404; a second tensioner 540B; a first tendon 550A; a second tendon 55GB; a second spool 560; and a part 570. The motor 505 is connected to the gears 510, which in turn are connected to the first spool 520. The first spool 520 is connected to a first end of the first and second tendons SSOA, SSOB, via the first and second force sensors 530A, 5306 and the first and second tensioners 540A, 5406 respectively. The first and second tendons 5504, 5506 are also connected at a second end to the part 570 via the second spool 560, Activation of the first tendon 550A in direction A, by means of the motor 505 and gears 510, results in rotation of the spool in a first direction about an axis running through the page of figure 3A, and thus movement of the part 570 in a direction 580A. Activation of the second tendon 55GB in direction + A, by means of the motor 505 and gears 510, results in rotation of the spool 560 in a second direction about an axis running through the page of figure 34, opposite to the first direction, and thus movement of the part 570 in a direction

C

-I

The first and second tendons 5504, SSOB, are connected to the first and second force sensors 530A, 5308 via the first and second tensioners 540A, 54GB respectively. The first and second force sensors 530A, 5308 sense the amount of force applied to each tendons 550A, 55DB. control of the amount of force applied to each of the first and second tendons 550A, 5508 can be used to control the amount of movement of each of the first and second tendons 5504, 5508, and thus the amount of movement of the part 570 in direction SBOA or in direction 5808.

The air muscle driven actuation device of figure 3B comprises an air inlet 600; first inlet valve 610A; second inlet valve 6108; first outlet valve 615A; second outlet valve 6158; first pressure sensor 6204; second pressure sensor 6208; first air muscle 630A; second air muscle 6308; first tendon 6404; second tendon 64DB; a spool 650; and a part 660. The air inlet 600 is connected to the first and second inlet valves 610A, 6108, which in turn are connected to the first and second air muscles 630A, 63DB via the first and second pressure sensors 620A, 62DB respectively. The first and second air muscle 630A, 6306 are connected to the first and second tendons 640A, 64DB respectively, which are connected to the part 660 via the spool 650.

When air is provided in the first air muscle 630A, via the first inlet valve 6104, the first air muscle 6304 expands in direction + E and contracts in direction + C. Contraction of the first air muscle 630A in direction + C result in the first tendon 6404 moving in direction + C and rotation of the spool 650 in a first direction about an axis running through the page of figure 3B. This results in movement of the part 660 in a direction 6704. In order to provide air to the first air muscle 630k the first outlet valve 615A is closed, toe second inlet valve 6108 is closed, and the second outlet valve 6158 is open. contraction of the first air muscle 6304 in direction + C, results in extension of the second air muscle 6308 in direction -C and contraction of the second air muscle 6306 in direction -E. Conversely, when air is provided in the second air muscle 6306, via the second inlet valve 6106, the second air muscle 6309 expands in direction + E and contracts in direction + C. Contraction of the second air muscle 6306 in direction + C result in the second tendon 6406 moving in direction + C and rotation of the spool 650 in a second direction, opposite to the first direction, about an axis running through the page of figure 36. This results in movement of the part 660 in a direction 6709. In order to provide air to the second air muscle 6306, the second outlet valve 6159 is closed, the first inlet valve S1OA is closed, and the first outlet valve 615A is open. Contraction of the second air muscle 6306 in direction C, result in extension of the first air muscle 630A in direction -C and contraction of the first air muscle 630A in direction -E. The first and second air muscles 630A, 63DB are connected to the first and second pressure sensor 620A, 6208 respectively. The first and second pressure sensor 620A, 6206 sense the amount of air pressure applied to each air muscle 630A, 6309. The amount of air pressure applied to each air muscle 630A, 6308 is niodulated by the first and second inlet valves 610A, 6106, and the first and second outlet valves 615A, 6159. Control of the amount of air pressure applied to each air muscle 630k 6306 can be used to control the amount of movement of each of the first and second tendons 640A, 6408, and thus the amount of movement of the part 660 in direction 670A or indirection 6706.

The parts 570 and 660, may represent, for example, one of the finger or thumb digits 102, 104, 106, 108, 110 of the hand section 10, such as the distal finger part 112, or proximal thumb part 132 of figure 2. In this case, the spools 550, 650, represent the distal finger joint 118 and (one of) the proximal thumb joint 138 respectively. The parts 570 and 660, may also represent, for example, one of the other parts of the hand section 10, for examp!e the palm section 150 of figure 2, in which case the spools 560, 650 may represent first wrist joint 142. In addition, parts 570 and 660, may also represent, for example, the third finger digit 106 of figure 2, in which case the spools 560, 650 may represent first palm joint 124, The motor driven actuation device of figure 3A is advantageous over the air muscle driven actuation device of figure 3B. This is because in order to move the part 570, the motor driven actuation device only requires one motor 505 and one set of gears 510, whereas in order to move the part 660, the air muscle driven actuation device requires two air muscles 630A, 630B and four valves 610A, blOB, 615A, 615B. Consequently, the air muscte driven actuation device is larger than the motor driven actuation device. In addition, the motor driven actuation device is capable of providing more accurate movement for the part 570 than the air muscle driven actuation device.

Each joint of the robotic hand section 10 requires its own actuation device in order to actuate that joint. For example, in the hand section 10 illustrated in figure 2, each finger digit 102, 104, 106, 108 requires four actuation devices, and the thumb digit 110 requires five actuation devices. In addition, the palm section 150 requires two actuation devices, and the wrist 140, 142 requires two actuation devices. In total, the hand section 10 illustrated in figure 2 requires twenty five actuation devices.

Different arrangements of the hand section may require a different number of actuation devices. For example, the palm section 150 may not be required to move, or may only be required to have limited movement, in which case both of, or one of, the joints 124, 126 may not be required, resulting in fewer actuation devices.

In addition, a human finger digit, in most instances, is not capable of moving the distal finger part 112, without also moving the middle finger part 114. consequently, in order to realistically mimic a human hand, the distal finger joint 118 and middle finger joint 120 may be actuated together, as described with reference to figures 4A and 4B below. In this instance, each finger digit 102, 104, 106, 108 would require three actuation devices, and the hand section 10 illustrated in figure 2 requires only twenty one actuation devices.

Figure 4A illustrates schematically a first arrangements for connecting a distal finger joint 118 and a middle finger joint 120 for actuation together. Although not illustrated in figures 4A and 4B, a distal finger part is connected to the distal finger joint, the distal finger joint 118 and a middle finger joint 120 are connected by a middle finger part, and the middle finger joint 120 and proximal finger joint 122 are connected by a proximal finger part.

As can be seen in figure 4A, a first end of an extend tendon 202 is connected to the middle finger joint 120 at middle connection point 120A. A second end of the extend tendon 202, opposite to the first end of the extend tendon 202, is connected to an actuation device (not illustrated). A first end of a loopback tendon 204 is connected to the distal finger joint 118 at distal connection point liSA. A second end of the loopback tendon 204, opposite to the first end of the loopback tendon 204, is provided with a loopback tendon nodule 122A. A biasing device 208, in one embodiment a spring, is provided on the loopback tendon 204 between the loopback tendon nodule 122A and point 204. The loopback tendon nodule 122A and the biasing device 208 are provided in a channel (not illustrated). Finally, a first end of a flex tendon 206 is connected to the distal finger joint 118 at distal connection point 118A. A second end of the flex tendon 206, opposite to the first end of the flex tendon 206, is connected to the actuation device (not illustrated).

The extend tendon 202 and the flex tendon 206 may be guided through, or around the proximal finger joint 122, so as not to hamper movement of the proximal finger joint 122.

The extend tendon 202 and the flex tendon 206 are not connected to the proximal finger joint 122. In addition, the flex tendon 206 is not connected to the middle finger joint 120.

Activation of the actuation device to which the extend tendon 202 and flex tendon 206 are connected results in the distal finger part moving about the distal finger joint 118 and the middle finger part moving about middle finger joint 120, such that the finger digit bends or straightens.

In order to bend the finger digit, the flex tendon 206 is pulled in direction + A resulting in the distal finger part (not illustrated) moving about the distal finger joint 118. In addition, the ioopback tendon 204 is pulled in direction -A, resulting in the loopback tendon nodule 122A being pulled along the channel (in direction -A) compressing the biasing device 208. Since the distal finger joint 118 is connected to the middle finger joint 120 by a middle finger part, movement of the distal finger joint 118, results in movement of the middle finger part, resulting in movement of the middle finger joint 120, ultimately bending the finger digit.

In order to straighten the finger digit, the extend tendon 202 is pulled in direction ÷ A, resulting in movement of the middle finger joint 120. Since the distal finger joint 118 is connected to the middle finger joint 120 by a middle finger part, movement of the middle finger joint 120, results in movement of the distal finger joint 118. In addition, the Ioopback tendon 204 is moved in direction + A and the biasing device 208 is released, ultimately straightening the finger digit.

The biasing device 208 biases the finger digit in the straight position (illustrated in figure 4A) and helps to straighten the finger digit after bending.

Figure 4B illustrates schematically a second arrangements for connecting a distal finger joint 118 and a middle finger joint 120 for actuation. As can be seen in figure 4B, a first end of an extend tendon 202 is connected to the distal finger joint 118 at distal connection point lisA.

A second end of the extend tendon 202, opposite to the first end of the extend tendon 202, is connected to the actuation device (not illustrated). A first end of a loopback tendon 204 is connected to the distal finger joint 118 at distal connection point liSA. A second end of the loopback tendon 204, opposite to the first end of the loopback tendon 204, is provided with a loopback tendon nodule lilA. A biasing device 208, in one embodiment a spring, is provided on the loopback tendon 204 between the loopback tendon nodule 122A and point 204. The loopback tendon nodule 122A and the biasing device 208 are provided in a channel (not illustrated). Finally, a first end of a flex tendon 206 is connected to the distal finger joint 118 at distal connection point liSA. A second end of the flex tendon 206, opposite to the first end of the flex tendon 206, is connected to the actuation device (not illustrated).

The extend tendon 202 and the flex tendon 206 may be guided through, or around the proximal finger joint 122, so as not to hamper movement of the proximal finger joint 122.

The extend tendon 202 and the flex tendon 206 are not connected to the proximal finger joint 122. In addition, the extend tendon 202 and the flex tendon 206 are not connected to the middle finger joint 120.

Activation of the actuation device to which the extend tendon 202 and flex tendon 206 are connected results in the distal finger part moving about the distal finger joint 118 and the middle finger part moving about middle finger joint 120, such that the finger digit bends or straightens.

In order to bend the finger digit, the flex tendon 206 is pulled in direction + A resulting in the distal finger part (not illustrated) moving about the distal finger joint 118. In addition, the Ioopback tendon 204 is pulled in direction -A, resulting in the loopback tendon nodule 122A being pulled along the channel (in direction -A) compressing the biasing device 208. Since the distal finger joint 118 is connected to the middle finger joint 120 by a middle finger part, movement of the distal finger joint 118, results in movement of the middle finger part, resulting in movement of the middle finger joint 120, ultimately bending the finger digit.

In order to straighten the finger digit, the extend tendon 202 is pulled in direction + A, resulting in movement of the distal finger joint 118. Since the distal finger joint 118 is connected to the middle finger joint 120 by a middle finger part, movement of the distal finger joint 118, results in movement of the middle finger joint 120. In addition, the loopback tendon 204 is moved in direction + A and the biasing device 208 is released, ultimately straightening the finger digit.

The biasing device 208 biases the finger digit in the straight position (illustrated in figure 48) and helps to straighten the finger digit after bending.

The connecting arrangements of figure 4A and 48 can utilise either a motor driven actuation device, such as illustrated in figure 3A, or an air muscle driven actuation device, such as illustrated in figure 38.

The connecting arrangement of figure 46 is advantageous over the connecting arrangement of figure 4A, since the extend tendon 202 and the flex tendon 206 of figure 48 are required to move substantially the same distance in order to bend and straighten the finger digit. In contrast, in the connecting arrangement of figure 4A, the flex tendon 206 is required to move a substantially greater distance than the extend tendon 202 in order to bend and straighten the finger digit. The result of having both tendons 202, 206 moving substantially the same distance is more accurate movement control, and simpler actuation control.

In one embodiment, the loop back tendon 204 may be an elasticated material. In this embodiment, the biasing device 204 may not be required.

Figures 5 illustrate a perspective view of one of the plurality of actuation devices provided in the control section 20 of figures 1A, 18 and 1C. As stated previously, each actuation device comprises a tensioner module 300, a sensing module 400 and an actuation module 500.

Each actuation device enables movement of one component, such as one joint of a digit, of the robotic hand section 10, by controlling movement of a flex tendon 250 and an extend tendon 255. Although not illustrated the flex tendon 250 and extend tendon 255 may be connected to any joint of the robotic hand section 10.

Figure 6 illustrates a side view of the actuation device of figure 5. The casing surrounding the tensioner niodule 300 and the sensing module 400 has been removed in order to more clearly describe the components of the tensioner module 300 and sensing module 400. The tendon 250 is connected to the actuation module 500 via the tensioner module 300 and the sensing module 400.

ifl this embodiment, the actuation module 500 comprises a motor and gears. The motor and gears may be assembled as a single unit. A motor and gears are well known to a person skilled in the art and thus are not described in further detail in this application. In addition, each set of motor and gears may be provided with its own printed circuit board (PCB) for controlling the motor and gears. In the arrangement illustrated in figures 1A and 18, the PCB is integrated onto the back of each motor. However alternative arrangements may be utilised.

Figure 7 illustrates a side view of the tensioner module 300 comprising a first pulley 310, a second pulley 320 and a third pulley 330. The tendon 250 is routed through the tensioner module 300 around the first, second and third pulley 310, 320, 330 respectively. The tendon 250 may be connected at first end 250A to a joint of the robotic hand section 10 (not illustrated). The tendon 250 may also be connected at a second end 2508 to the sensor module 400 (not illustrated).

The tensioner module 300 also comprises a tendon biasing device 350, in one embodiment a spring. A first end 350A of the spring is provided in a recess 360 in the tensioner module 300, such that the first end 350A of the spring cannot move. A second end 350B of the spring is connected to the second pulley 320. The second pulley 320 is provided in a curved recess 340. The second end 3508 of the spring, and thus the second pulley 320, is biased towards a second end 3408 of the recess 340 in order to maintain tension in the tendon 250, keeping the tendon 250 taught.

In one embodiment, the first end 350A of the spring is provided behind the tendon 250, whilst the second end 3508 of the spring is provided in front of the tendon 250.

Figure 9 illustrates a side view of the tensioner module 300 where the second pulley 320 has moved along the recess 340 towards a first end 340A of the recess 340.

Figure 8 iflustrates a perspective view of the tensioner module 300. As can be seen from figure 8 the two (flex and extend) tendons 250, 255 of each joint are fed into a single tensioner module 300. Tendon 250 is fed into side 300A of the tensioner module 300 illustrated in figures 7, 8 and 9. Tendon 255 is fed into side 3008 of the tensioner module 300, which is a mirror image of side 300A.

The tensioner module 300 is advantageous since it maintains tension in the tendons 250, 255, which result in more accurate control of the joint to which the tendons 250, 255 are attached.

Figure 10 illustrates a perspective view of the sensor module 400. A second end 2508 of tendon 250 and a second end 2558 of tendon 255 are provided froni the tensioner module 300.

The sensor module 400 comprises a spool comprising a first (top half) spool 440 and a second (bottom half) spool 430, a first side piece 450A (not illustrated), a second side piece 45GB, a first force sensor 410A, a second force sensor 4108, and a connection bar 420 connecting the first and second force sensors 410A, 4108. The first force sensor 410A and second force sensor 41DB may be any force sensor or strain gauge as known in the art.

The tendon 250 is connected to the first spool 440, and the tendon 255 is connected to the second spool 430. Figures 13 and 14 illustrate the first and second spools 430, 440 in more detail. Figures 14 is an exploded view. As can be seen from figures 13 and 14, the first spool 440 comprises a first groove 445, and the second spool 430 comprises a second groove 435.

An end of the tendon 250 is trapped within the first groove 445 in order to securely fasten the tendon 250 to the first spool 440. in one embodiment, a knot is tied in the end of the tendon 250 and glue is provided in the first groove 445, such that the knotted end of the tendon 250 is securely fastened to the first groove 445 of the first spool 440. The tendon 250 is then wrapped several times around the first spool 440 and routed over the connection bar 420 next to the first force sensor 410A as illustrated in figures 10. An end of the tendon 255 is trapped within the second groove 435 in order to securely fasten the tendon 255 to the second spool 430. In one embodiment, a knot is tied in the end of the tendon 255 and glue is provided in the second groove 435, such that the knotted end of the tendon 255 is securely fastened to the second groove 435 of the second spool 430. The tendon 255 is then wrapped several times around the second spool 430 and routed over the connection bar 420 next to the second force sensor 41GB as illustrated in figures 10.

Although first and second grooves 445, 435 have been described, any means for securely attaching the tendons 250, 255 to the first and second spools 440, 430 can be utilised.

The first and second spools 440, 430 are provided as two separate devices so that they can be rotated with respect to each other, in order to adjust the tension in the tendons 250, 255.

When the tension in the tendons 250, 255 has been adjusted as required, the first and second spools 440, 430 can be fixed in position. In one embodiment, a screw (not illustrated) may be provided through the first and second spools 440, 430 in order to fixed the relative positions of the first and second spools 440, 430. The screw acts to lock the first and second spools 440, 430 so that they do not rotate with respect to each other. When the screw is loosened, the first and second spools 440, 430 can be rotated with respect to each other effectively tightening and loosening the tension in the tendons 250, 255.

Figures 11 and 12 illustrates the sensor module 400 without second side piece 450B and second force sensor 410B in order to more clearly illustrate the components of the sensor module 400.

Figure 11 is a perspective view of the sensor module 400. As can be seen in figure 11, the tendons 250, 255 are routed over the connection bar 420, the tendon 250 is routed next to the first force sensor 410A and the tendon 255 is routed next to the second force sensor 4108 (illustrated in figure 10). Consequently, the first force sensor 410A is capable of detecting force applied to the tendon 250, whilst the second force sensor 4108 is capable of detecting force applied to the tendon 255. The arrangement of the first and second force sensors 410A, 4108 and the connection bar 420 of the sensing module 400 is advantageous since is enables the first and second force sensors 410A, 4108 to detect force from the tendons 250, 255 respectively, without restricting movement of the tendons 250, 255.

Figure 12 is a side view of the sensor module 400 and only irfustrates tendon 2508.

As illustrated in Figures 5 and 6 the sensor module 40015 connected to the actuation module 500. In one embodiment, the shaft of the motor is connected to the first and second spools 440, 430.

Referring again to figures 1A, 18 and 1C, the control section 20 comprises a routing plate 700. The routing plate 700 is also illustrated in figures iSA and 168. The routing plate 700 provides standardised routing of the tendons from the hand section 10 to the control section 20. In particular, the routing plate 700 provides routing for each pair of tendons associated with each joint of the hand section 10, to the associated actuation device which will control movement of that joint.

The routing plate 700 is approximately square in shape, having four sides. Each side having eight grooves 710, one groove 710 for each tendon. Each pair of tendons connecting to an actuation device, in the control section 20. Each side of the control section 20 provided with four actuation devices. In addition, the routing plate 700 has four grooves 720 (illustrated in figure 158) connected to four guide holes 725 at it's centre and four routing holes 730 for routing a further eight tendons. Each pair of tendons connecting to an actuation device, in the control section 20. The centre of the control section 20 the control section 20 provided with four actuation devices. Consequently, the robotic hand of figures 1A and 18 comprises independent joints, each connected to one of twenty actuation devices.

The routing plate 700 is not limited to being approximately square in shape, and different shaped routing plates 700 may be utilised, such as, for example, approximately rectangular in shape, approximately hexagonal in shape, approximately circular in shape etc. As can be seen in figures 1A and 16 each pair of tendons is routed through the wrist section 140, 142, 144 and then fed to a tensioner module 300 of the actuation devices. As discussed with reference to figure 2 the wrist section has two wrist joints 140, 142. The first wrist joint enables the hand section 10 to move about an X axis X6, and the second wrist joint 142 enables the hand section 10 to move about a Y axis V4. The fourth V axis V4 is orthogonal to the sixth X axis X5. The first and second wrist joints 140, 142 can aiso be seen in figure 1A.

Figure 15 illustrates schematically a pulley arrangement for routing the tendons of the first and second wrist joints 140, 142 to the actuation devices provided at the centre of the control section. Referring to figure 15, tendon 140A is the flex tendon of the first wrist joint and tendon 1408 is the extend tendon of the first wrist joint 140. The tendon 142A is the flex tendon of the second wrist joint 142 and tendon 142B is the extend tendon of the second wrist joint 142.

When the tendons are provided about a circular joint such as the first wrist joint 140 it is possible for the flex and extend tendons 140A, 1408 to be moved substantially the same distance in order to flex and extend the hand section 10 about the first wrist joint 140.

However, it is difficult to make the second wrist joint 142 also a circular joint, Consequently, components 144 (illustrated in figure 1A), which have a curved outer surface, are provided in order to guide the tendons 142A, 142B of the second wrist joint 142. Although components 144 do not form a perfect circle, the curved surfaces 144 are such that the flex and extend tendons 142A, 1428 can be moved substantially the same distance in order to flex and extend the hand section 10 about the second wrist joint 142.

The wrist joint arrangement is advantageous since it reduces backlash Those skilled in the art will appreciate that while the foregoing has described what is considered to be the best mode and, where appropriate, other modes of performing the invention, the invention should not be limited to the specific configurations and methods disclosed in this description of the preferred embodiment. Those skilled in the art will recognise that the invention has a broad range of applications in many different types of robotics, and that the embodiments may take a wide range of modifications without departing from the inventive concept as defined in the appended claims.

Claims (1)

1. <claim-text>CLAIMS1. A robotic finger digit comprising: a distal finger joint coupled between a distal finger part and a middle finger part; a middle finger joint coupled between the middle finger part and a proximal finger part; an extend tendon coupled at a first end to the distal finger joint, and coupled at a second end to an actuation device; and a flex tendon coupled at a first end to the distal finger joint) and coupled at a second end to the actuation device, wherein the actuation device is configured to move the extend tendon and the flex tendon substantially the same distance in order to flex and/or extend the robotic finger digit.</claim-text> <claim-text>2. The robotic finger digit of claim 1, wherein the distal finger joint is configured to enable the distal finger part to move about a first axis.</claim-text> <claim-text>3. The robotic finger digit of claim 1 or 2, wherein the middle finger joint is configured to enable the middle finger part to move about a second axis, parallel to the first axis.</claim-text> <claim-text>4. The robotic finger digit of any preceding claim, wherein the actuation device comprises a motor, or an air muscle device.</claim-text> <claim-text>5. The robotic finger digit of any preceding claim, further comprising: a loopback tendon coupled at a first end to the distal finger joint, and configured to bias the robotic finger digit in a extend position.</claim-text> <claim-text>6. The robotic finger digit of claims, further comprising: a biasing device provided at a second end of the loopback tendon.</claim-text> <claim-text>7. The robotic finger digit of any preceding claim, wherein in use, activation of the extend tendon and the flex tendon results in actuation of the distal finger joint and the middle finger joint.</claim-text>