MULTIPLE PAWL RATCHET MECHANISM

Abstract

A ratchet comprises a head portion with a circular central housing having modular inserts in the form of three flat ring like layers, two outer fixed ramped profile layers engaged into housing locking profiles with a sequential actuating layer capable of limited rotation between. Opposing direction pawls are situated within the fixed layer ramped profiles. The actuating layer has engagement and disengagement profiles at either end of its pawl recesses projecting the incumbent pawls against the fixed layer ramped profiles in the chosen direction projecting them inwards locking the pawl teeth within the driven element teeth, whilst simultaneously disengaging the pawls facing the other direction. The actuating layer biasing protrusion resiliently projected in the chosen direction by a robust sprung plunger acting from within a switch bore, in the reverse direction the actuating layer resiliently rotates against said sprung plunger allowing the pawl teeth to resiliently slide over one another.

Claims

1. A fastening tool ratchet mechanism comprising: a body defining a driven element chamber; a driven element having an outer surface provided with a plurality of driven element teeth, said driven element received in said driven element chamber; a plurality of inserts disposed in said chamber, said inserts each having a through-hole and comprising at least one fixed insert that is fixed in said driven element chamber, the through-hole of said at least one fixed insert defined by a wall that comprises recesses defining ramp surfaces; and a plurality of pawls having pawl teeth, said pawls disposed in said recesses and movable along respective said ramp surfaces to cause said pawl teeth to engage with said driven element teeth to transmit a drive force from said body to said driven element.

2. A fastening tool ratchet mechanism as claimed in claim 1, wherein said inserts are disposed one on top of another to define a stack of inserts in said driven element chamber.

3. A fastening tool ratchet mechanism as claimed in claim 1 or 2, wherein said driven element has an inner surface configured to engage said at least one fixed insert to prevent rotation of said fixed insert in said driven element chamber.

4. A fastening tool ratchet mechanism as claim 3, wherein said inner surface is provided with formations that engage with complementary formations of said at least one fixed insert.

5. A fastening tool ratchet mechanism as claimed in any one of the preceding claims, wherein said plurality of inserts comprises a rotatable actuating insert and the through-hole of said rotatable insert having a wall defining a plurality of pawl engagement projections, said rotatable actuating insert being rotatable in said driven element chamber to move said pawls along said ramp surfaces.

6. A fastening tool ratchet mechanism as claimed in claim 5, comprising three said inserts, wherein said rotatable insert is disposed between two said fixed inserts.

7. A fastening tool ratchet mechanism as claimed in claim 5 or 6, further comprising a direction changing switch to change a force applying direction of the ratchet mechanism, wherein said rotatable insert comprises a peripheral wall defining a recess having a first end wall and a second end wall and said direction changing switch is movable in said recess between said first and second end walls to selectively bear against said first and second end walls to change said force applying direction.

8. A fastening tool ratchet mechanism as claimed in claim 5, 6 or 7, wherein said plurality of pawls comprise a set of pawls that are configured such that when moved along said ramp surfaces by said pawl engagement projections to cause said pawl teeth to engage said driven element teeth, the teeth of one pawl of said set of teeth fully engage said driven element teeth and the teeth of other pawls of said set of pawls at most partially engage said driven element teeth.

9. A fastening tool ratchet mechanism as claimed in any one of the preceding claims, wherein each said insert is a planar annular member.

10. A fastening tool ratchet mechanism as claimed in any one of the preceding claims, wherein each said insert is a stamped annular member.

11. A wrench comprising a fastening tool ratchet mechanism as claimed in any one of the preceding claims.

12. A screwdriver comprising a fastening tool ratchet mechanism as claimed in any one of claims 1 to 11.

13. A multiple pawl ratchet mechanism 1 comprising a head portion 300 having a central chamber 309 in which a driven element 200 is received, a handle portion 400 having a levering end 401 and a levered end 402, the circular central chamber 309, the inner surface 302 of which adjoining the handle portion 402 having a further recess or connection undercut 306 for the connection to the actuating layer direction biasing protrusion 804 by the resilient switch plunger 605, the head portion chamber 309 further having modular inserts in the form of preferably three layers, two outer fixed ramped profile layers 700 with a sequential actuating layer 800 capable of limited rotation between the said fixed layers 700, the fixed ramped profile layer 700 having outer locking notches 706 which mechanically engage with the corresponding head portion locking profiles 303, the said fixed profile layer 700 further utilizing first and second ramped profiles 701, 702 within its central profile 709, preferably three sets of equally spaced opposing direction pawls 500 are situated within said corresponding ramped profiles 701, 702, the middle sequential actuating layer 800 has engagement 802 and disengagement 803 profiles at either end of its pawl recesses 801, these said profiles 802, 803 project in the chosen direction the incumbent pawls 500 against the corresponding fixed layer ramped profiles 701, 702 in the chosen clockwise CWD or anticlockwise drive direction ACWD whilst simultaneously disengaging the said pawls 500 facing in the opposite direction, the said pawls 500 outer ramped profile 503 acting against the corresponding fixed layer pawl ramped profile 701 or 702 in the chosen drive direction CWD or ACWD, the engaged pawls teeth 502 engaging with the drive element teeth 202 in order to drive as required the same, the actuating layer 800 is resiliently propelled in the chosen clockwise or anticlockwise direction by in one example a known ratchet switch 600 having a robust sprung plunger 605 whose engagement face 606 acts against the said actuating layer 800 chosen sprung plunger positional indent 806, when utilized in the reverse or reposition direction R the actuating layer 800 with its incumbent pawls 500, resiliently circumferentially rotating against the said sprung plunger 605, further allowing the pawl teeth 502 engaged within the drive element teeth 202 to resiliently slide over one another during the reposition R action.

14. The ratchet mechanism 1 as claimed in claim 13, characterized whereas the head portion central chamber 309 has modular inserts in the form of preferably three layers, two outer fixed ramped profile layers 700, with a sequentially actuating layer 800 capable of limited rotation between said fixed layers 700, said actuating layer 800 resiliently propelled in the chosen clockwise CWD or anticlockwise direction ACWD by in one example a known ratchet switch 600 incorporating a robust sprung plunger 605 whose engagement face 606 acts against the said actuating layer 800 chosen direction profile 804, the fixed ramped profile layer 700 having outer locking notches 706 which mechanically engage with the corresponding head portion locking profiles 303, the said fixed profile layer 700 further utilizing first and second ramped profiles 701, 702 within its central profile 709.

15. The ratchet mechanism as claimed in claim 14, characterized by the use of a mid-located, sequentially actuating layer 800, being both planar and ring like in construction in order that it can be stamped or fine blanked in manufacture instead of using expensive machining.

16. The ratchet mechanism as claimed in claim 14 or 15, characterised by the use of a preferably mid located, sequentially actuating layer 800 incorporating a biasing protrusion 801, which is further characterized by inwardly relieved scallops usefully forming plunger contact positional indents 806 within their directional profiles 804, further usefully preventing the switch 600 from disengaging from its ordained operating position particularly when the present invention 1 is rapidly utilized in the reverse or reposition direction R.

17. The ratchet mechanism as claimed in claim 15, is further characterized by the use of top and bottom or outer located, fixed ramped profile layers 700, in the preferred iteration being both flat and ring like in construction in order that they can be easily stamped or fine blanked in manufacture instead of using expensive machining, these modular inserts 700 are robustly held in position within the head portion central chamber 309 by the use of location notches 706 in conjunction with corresponding locking profiles 303 within the head portion inner profile 302, one of the said notches 707 is preferably distinctly larger than the others corresponding with the head portion location profile 304, in order to provide a method of correct assembly orientation of the said fixed ramped profile layers 700 within the said central chamber 309.

18. The ratchet mechanism 1 as claimed in claim 17, is even further characterized by having engagement 802 and disengagement 803 profiles at either end of its actuating layer pawl recesses 810 preferably in close contact with the pawl engagement biasing 504 and disengagement biasing 505 faces, these said profiles 504, 505 project in the chosen direction the incumbent pawls 500 against the corresponding fixed layer ramped profiles 701, 702 in the chosen clockwise CWD or anticlockwise ACWD drive direction whilst simultaneously disengaging the pawls 500 facing in the opposite direction, the engaged pawls teeth 502 engaging with the drive element teeth 202 in order to drive as required the same.

19. The ratchet mechanism 1 as claimed in any one of claims 13 to 18, is further characterized whereas the actuating layer 800 is resiliently propelled in the chosen clockwise CWD or anticlockwise ACWD direction by a robust sprung plunger 605 whose engagement face 606 acts against the said actuating layer 800 chosen direction profile 804, when utilized in the reverse or reposition direction R the actuating layer 800 with its incumbent pawls 500, resiliently circumferentially rotating back against the said resilient sprung plunger 605, further allowing the pawl teeth 502 engaged within the drive element teeth 202 to resiliently slide over one another during the reposition or reverse action R, in one example the sprung plunger 605 is incorporated within a known dual direction ratchet switch 600 having a direction lever 601.

20. The ratchet mechanism 1 as claimed in any one of claims 13 to 19, is further characterized by the use of at least two sets of pawls 500 within their corresponding pawl recesses 701, 702 the utilized drive pawls 500 are arranged to sequentially engage at the same time, the actuating layer engagement profiles 802 acting simultaneously upon the pawl engagement biasing faces 504, robustly engaging the pawl teeth 502 within the drive element teeth 202 during the drive sequence, whilst simultaneously disengaging the pawls 500 facing in the opposite direction.

21. The ratchet mechanism as claimed in any one of claims 13 to 20, is further characterized by the use of at least three sets of pawls 500 within their corresponding pawl recesses 701, 702, the utilized drive pawls 500 can be arranged to sequentially engage at the same time causing the actuating layer engagement profiles 802 to act simultaneously upon the pawl engagement biasing faces 504, robustly engaging the pawl teeth 502 into the drive element teeth 202 during the drive sequence, the driven element 200 thereby gripped in a manner by the three operated pawls 500 similar to a three jaw chuck reducing the requirement for robust axle bearing surfaces within the closure portions 307. This configuration results in an extremely robust dual direction ratchet mechanism 1, this arrangement further provides a superior amount of pawl teeth 502 to be capable of full engagement within the drive element teeth 202 during the drive sequence yet with the correct ramped profile 701, 702 angles chosen, effortlessly disengage the pawl ramp profiles 503 from their corresponding fixed pawl recess ramped profiles 701, 702 in the reverse or reposition direction R, the pawl ramp profiles 503 having a suitable gap 710 within the pawl recess engagement ramp profiles 701, 702 during the reverse or reposition R action to allow the pawl teeth 502 to adequately disengage from the drive element teeth 202.

22. The ratchet mechanism as claimed in any one of claims 13 to 21, is further characterized by the use of at least two but preferably three sets of pawls 506, 507, 508 within their corresponding pawl recesses 703, 704, 705, the utilized drive and disengaged pawls 500 arranged to sequentially engage whereas each actuating layer pawl recesses 810, engagement and disengagement profiles sets 807, 808, 809 are located in one example, one third of a tooth 202 out from the corresponding said corresponding sets 807, 808 or 809 causing the actuating layer engagement profiles 802, 803 to act to robustly fully engage the pawl teeth 502 of only one pawl 500, into the drive element teeth 202 during the drive sequence, the six pawls 500 divided into three sets of pawls 506, 507 and 508 and each of the three sets 506, 507, 508 is clocked differently to the drive element teeth 202 such that when the drive pawl 500 of one set 506, 507 or 508 is engaged with the drive element teeth 202, one or other of the pawl set 506, 507 or 508 drive teeth 502 is only partially engaged (e.g., one third of the pawl tooth 502 arc engaged) and the remaining set 506, 507 or 508 pawl drive teeth 502 are partially disengaged (e.g., one third of the pawl tooth 502 arc disengaged), this arrangement can provide a coarse tooth pattern of for example 72 teeth to be utilized whilst providing a drive teeth equivalent to 72 times 3 or 216 equivalent toothed dual direction ratchet 1.

23. The ratchet mechanism 1 as claimed in any one of claims 13 to 22, is further characterized by its utilization as a ratcheting screwdriver, comprising a handle portion 400 with a proximal end 403 and a distil end 404, the handle proximal end 403 robustly incorporates the housing 900 encapsulated ratchet mechanism 1 with an outer facing direction biasing switch ring 607 within its profile, the housing 900 is connected to the driven element portion 201, of the rotatable elongate shaft 208 of the screwdriver in order to transmit motion and torque to the elongate shaft 208 as required, in the direction CWD, ACWD required, the housing 900 having a central chamber 901 in which the said driven element portion 200 of the elongate shaft 208 is received, the preferably die cast housing 900 having a generally circular central chamber 901, the inner surface of which 901, adjoining the direction biasing switch ring direction ascertaining recess 608, has a rocker switch connection slot 907 for the required outward connection to the direction biasing switch ring 607, by the intermediate rocker switch plunger housing 612, which further incorporates axles 610 capable of positional rotation within a corresponding moulded axle slot 910 formation located within the housing wall 904, the rocker switch plunger housing 612 further incorporates a robust resilient sprung plunger 605 within its related bore 611, the said housing chamber 901 having in one example for ease of manufacture, modular inserts in the form of preferably three layers, two outer fixed ramped profile layers 700 with a sequential actuating layer 800 capable of limited rotation between said fixed layers 700, the fixed ramped profile layer 700 having locking notches 706 on their periphery which mechanically engage with the corresponding housing chamber locking profiles 902, the said fixed ramped profile layer 700, further utilizing ramped profiles 701, 702 within their central profile 709, preferably three sets 506, 507, 508 of generally equally spaced opposing direction pawls 500 are situated within said corresponding fixed ramped profile sets 703, 705, 706, the middle sequential actuating layer 800 has engagement 802 and disengagement 803 profiles at either end of its pawl recesses 810, these said profiles 802, 803 project in the chosen direction the incumbent pawls 500 against the corresponding said fixed layer ramped profiles 701, 702 in the chosen clockwise CWD or anticlockwise drive direction ACWD whilst simultaneously disengaging the pawls 500 facing in the opposite direction, the said pawls outer ramped profile 503 acting against the corresponding said fixed layer pawl ramped profile 701, 702 in the chosen drive direction causing the engaged pawls teeth 502 to engage with the drive element teeth 202 in order to drive as required the same, in order to activate the screwdriver in the chosen direction the operator rotates the said switch ring 607 into its required position, thereby swivelling the intermediate rocker switch 609 around its axles 610 whereby the actuating layer 800 is resiliently propelled in the chosen clockwise CWD or anticlockwise ACWD direction by the said rocker switch internal sprung plunger 605, the sprung plunger engagement face 606 acting against the said actuating layer 800 chosen direction profile 804, utilized in the reverse or reposition direction R the actuating layer 800 with its incumbent pawls 500, resiliently circumferentially rotating against the said resilient sprung plunger 605, further allowing the pawl teeth 502 engaged within the drive element teeth 202 to resiliently slide over one another during the reverse or reposition action R, in order to ensure the continuance of the chosen switched direction CWD or ACWD the housing 900 can further employ a bore 908 with a sprung ball detent 614 which can act against a suitable indent 615 within the switch ring 607 as a locator.

24. The ratchet mechanism as claimed in claim 23, is further characterized by the known direction biasing switch ring 607 with its rocker switch actuating profile 608 acts upon the novel intermediate rocker switch 609 actuating profile 613 in order to swivel into engagement its incumbent sprung plunger 605 engagement face 606, resiliently acting against the actuating layer direction profile 804 in the desired direction, the said rocker switch 609 having axles 610 which are retained, can rotate, and also move radially as required in the housing moulded axle slots 910 during the direction switching CWD, ACWD process, the robust switch spring 604 usefully acting in both directions, urging the said rocker switch actuating profile 613 into engagement with the switch ring direction actuating profile 608, whilst further acting to propel the sprung plunger engagement face 606 against the actuating layer direction profile 804.

25. The ratchet mechanism 1 as claimed in claim 23 or 24, is further characterized by its utilization as a dual direction ratcheting screwdriver ratchet 1 whereas the direction biasing switch ring 607 clockwise CWD or anticlockwise direction switch direction ACWD being identical to that of the screwdriver shaft 208.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0031] The features, advantages, and objects of the embodiments of the present invention will become more apparent from the detailed description as set forth below, when taken in conjunction with the drawings in which like referenced characters identify correspondingly throughout, and wherein:

[0032] FIG. 1 is a perspective view of the ratchet mechanism incorporating a switch and a fastener drive profile;

[0033] FIG. 2 is a perspective view of the ratchet mechanism incorporating a switch and a spigot for connection with known sockets;

[0034] FIG. 3 is a front view of the ratchet mechanism operated in the clockwise direction, the closure washer is removed (not shown) and a part of the handle levered end and the switch are shown in section for display purposes;

[0035] FIG. 4 is a front view of the ratchet mechanism operated in the anti-clockwise direction, the closure washer is removed (not shown) and a part of the handle levered end and the switch are shown in section for display purposes;

[0036] FIG. 5 is a perspective view of the ratchet mechanism, the parts shown dismantled for display purposes;

[0037] FIG. 6 is a perspective view of the internal parts of ratchet mechanism plus the switch, the parts shown dismantled for display purposes;

[0038] FIG. 7 is a perspective view of the assembled internal parts of the ratchet mechanism plus the switch;

[0039] FIG. 8 is a perspective view of the screwdriver version of the device being used by an operator;

[0040] FIG. 9 is a perspective view of the screwdriver housing with the intermediate rocker switch and switch ring shown separately;

[0041] FIG. 10 is a perspective view of the screwdriver housing internals, the mechanism biased in the clockwise direction;

[0042] FIG. 11 is a perspective view of the screwdriver housing internals, the mechanism biased in the anti-clockwise direction; and

[0043] FIG. 12 is a perspective view of the screwdriver ratchet mechanism, the parts shown dismantled for display purposes.

REFERENCE TO THE DRAWINGS

[0044] Following is a listing of the various components used in the best mode preferred embodiment and alternative embodiments. For the ready reference of the reader the reference numerals have been arranged in ascending numerical order.

TABLE-US-00001 11 Multiple Pawl Ratchet 200/Driven Element 201/Driven Element Circumferential Toothed Portion 202/Driven Element Teeth 203/Driven Element Spigot 204/Driven Element Fastener Operating Profile 205/Screwdriver Driven Element 206/Screwdriver Driven Element Teeth 207/Screwdriver Tip 208/Screwdriver Shaft 300/Head Portion 301/Head Portion Outer Profile 302/Head Portion Inner Profile 303/Head Portion Ramped Layer Locking Profiles 304/Head Portion Ramped Layer Location Profile 305/Head Portion Switch Bore 306/Head Portion Connection Undercut 307/Head Portion Closure Portion 308/Head Portion Closure Clip 309/Head Portion Central Chamber 4001 Handle Portion 4011 Handle Levering End 4021 Handle Levered End 4031 Screwdriver Handle Proximal End 4041 Screwdriver Handle Distal End 5001 Pawl 5011 Pawl Toothed Face 5021 Pawl Teeth 5031 Ramp Profile 5041 Pawl Engagement Biasing Face 5051 Pawl Dis-Engagement Biasing Face 5061 Pawl Set A 5071 Pawl Set B 5081 Pawl Set C 600/Switch 6011 Switch Operating Lever 602/Switch Axle 6031 Switch Axle Plunger Bore 6041 Switch Spring 6051 Switch Sprung Plunger 6061 Sprung Plunger Engagement Face 607/Direction Biasing Switch Ring 6081 Switch Ring Direction Ascertaining Recess 6091 Intermediate Rocker Switch 6101 Rocker Switch Axles 611/Rocker Switch Plunger Bore 612/Rocker Switch Plunger Housing 613/Rocker Switch Actuating Profile 614/Switch Ring Spring and Ball Detent 615/Switch Ring Detent Indent 616/Plunger Cylinder 617/Switch Ring Clip 618/Switch Ring Clip Groove 700/Fixed Ramped Profile Layer 701/First Ramped Profile 702/Second Ramped Profile 703/Ramped Profile Set A 704/Ramped Profile Set B 705/Ramped Profile Set C 706/Fixed Layer, Locking Notch 707/Fixed Layer, Location Notch 708/Fixed Layer, Centralizing Face 709/Fixed Layer, Central Profile 710/Fixed Layer, Pawl Recess Gap 800/Actuating Layer 8011 Actuating Layer Biasing Protrusion 8021 Pawl Engagement Profile 8031 Pawl Disengagement Profile 8041 Actuating Layer Direction Profile 8051 Actuating Layer Transfer Profile 8061 Actuating Layer Resilient Plunger Positional Indent 807 Pawl Engagement Set A 8081 Pawl Engagement Set B 8091 Pawl Engagement Set C 8101 Actuating Layer Pawl Recesses 9001 Housing 9011 Housing Central Chamber 9021 Housing Central Chamber Locking Profiles 9031 Housing Screwdriver Shaft Axle Bore 9041 Housing Wall 9051 Housing Gripping Ribs 9061 Housing Closure Clip Groove 907/Housing Rocker Switch Connection Slot 9081 Housing Ball Detent Bore 9091 Housing Switch Ring Clip Groove 9101 Housing Molded Axle Slot CWDI Clockwise Direction ACWDI Anti - Clockwise Direction RI Reverse or Reposition

DETAILED DESCRIPTION

[0045] As required, detailed embodiments of the present invention are disclosed herein; however, it is to be understood that the disclosed embodiments are merely exemplary of the invention that may be embodied in various forms. The figures are not necessarily to scale, some features may be exaggerated to show details of particular components. Therefore specific structural and functional details disclosed herein are not to be interpreted as being limiting, but merely as a basis for the claims and as one skilled in the art to variously employ the invention.

[0046] FIGS. 1-7 illustrate the embodiments of a multiple pawl ratchet mechanism 1 comprising a head portion 300 having a central chamber 309 in which a driven element 200 is received, a handle portion 400 having a levering end 401 and a levered end 402. The circular central chamber 309, the inner surface 302 of which adjoining the handle portion 402 having a further recess or connection undercut 306 for the connection to the actuating layer direction biasing protrusion 804 by the resilient switch plunger 605. The head portion chamber 309 further having modular inserts in the form of preferably three layers, two outer fixed ramped profile layers 700 with a sequential actuating layer 800 capable of limited rotation between the said fixed layers 700. The fixed ramped profile layer 700 having outer locking notches 706 which mechanically engage with the corresponding head portion locking profiles 303, the said fixed profile layer 700 further utilizing first and second ramped profiles 701, 702 within its central profile 709, preferably three sets 506, 507, 508 of equally spaced opposing direction pawls 500 are situated within said corresponding ramped profiles 701, 702. The middle sequential actuating layer 800 has engagement 802 and disengagement 803 profiles at either end of its pawl recesses 801, these said profiles 802, 803 project in the chosen direction the incumbent pawls 500 against the corresponding fixed layer ramped profiles 701, 702 in the chosen clockwise CWD or anticlockwise drive direction ACWD whilst simultaneously disengaging the said pawls 500 facing in the opposite direction, the said pawls 500 outer ramped profile 503 acting against the corresponding fixed layer pawl ramped profile 701 or 702 in the chosen drive direction CWD or ACWD. The engaged pawls teeth 502 engaging with the driven element teeth 202 in order to drive as required the same. The actuating layer 800 is resiliently propelled in the chosen clockwise or anticlockwise direction by in one example a known ratchet switch 600 having a sprung plunger 605 whose engagement face 606 acts against the said actuating layer 800 chosen sprung plunger positional indent 806, when utilized in the reverse or reposition direction R the actuating layer 800 with its incumbent pawls 500, resiliently circumferentially rotating against the said sprung plunger 605, further allowing the pawl teeth 502 engaged within the drive element teeth 202 to resiliently slide over one another during the reposition R action.

[0047] FIGS. 1 and 2 further illustrate the ratcheting mechanism 1, denoting an elongate handle operator levering end 401 at one end and a levered end 402 incorporating a head portion 300 with a drive element spigot 203 or alternately a fastener operating profile 204 incorporated within the drive element 200. The drive direction switch 600, closure portion with its retaining clip 308 are further shown.

[0048] FIGS. 3 and 4 further illustrates the ratchet mechanism 1, with the closure portion 307 removed (not shown), the biasing switch 600 and head portion 300 shown partially in section. The sprung plunger 605 engagement face 606 urged against the actuating layer plunger positional indent 806 of the actuating layer direction biasing protrusion 804, the switch spring 604 further resiliently acting to circumferentially bias the actuating layer 800 in the chosen anti-clockwise ACWD as in FIG. 3 or clockwise CWD as in FIG. 4 direction. The circular central chamber 309, the inner surface 302 of which adjoining the handle portion 402 having a further recess or connection undercut 306 for the connection to the actuating layer direction biasing protrusion 804 by the resilient switch plunger 605. The head portion chamber 309 further having modular inserts in the form of preferably three layers, two outer fixed ramped profile layers 700 with a sequential actuating layer 800 capable of limited rotation between the said fixed layers 700. The fixed ramped profile layer 700 having outer locking notches 706 which mechanically engage with the corresponding head portion locking profiles 303, the said fixed profile layer 700 further utilizing first and second ramped profiles 701, 702 within its central profile 709, preferably three sets of equally spaced opposing direction pawls 506, 507, 508 are situated within said corresponding ramped profiles 701, 702. The middle sequential actuating layer 800 has engagement 802 and disengagement 803 profiles, said profiles 802, 803 project in the chosen direction the incumbent pawls 500 against the corresponding fixed layer ramped profiles 701, 702 in the chosen clockwise CWD or anticlockwise ACWD drive direction whilst simultaneously disengaging the said pawls 500 facing in the opposite direction, the said pawls 500 outer ramped profile 503 acting against the corresponding fixed layer pawl ramped profile 701 or 702 in the chosen clockwise or anticlockwise drive direction CWD or ACWD. The engaged pawls teeth 502 engaging with the driven element teeth 202 in order to drive as required the same. When utilized in the reverse or reposition direction R the actuating layer 800 with its incumbent pawls 500, resiliently circumferentially rotating against the said sprung plunger 605, further allowing the pawl teeth 502 engaged within the drive element teeth 202 to resiliently slide over one another during the reposition R action.

[0049] Further shown in FIGS. 3 and 4 is an example of the present invention 1 whereas the utilized drive and disengaged pawls 500 are arranged to sequentially engage whereas each actuating layer 800 engagement and disengagement profile set A, B and C 807, 808 and 809 are located one third of a tooth out from the corresponding said corresponding sets 807, 808 and 809 causing the actuating layer engagement profiles 802 to act to robustly fully engage the pawl teeth 502 of only one pawl 500, into the driven element teeth 202 during the drive sequence.

[0050] The six pawls 500 divided into three sets of pawls, set A 506, set B 507 and set C 508, and each of the said three sets 507, 508 and 509 is clocked differently to the drive element teeth 202 such that when the drive pawl 507, 508 or 509 of one set is engaged with the drive element teeth 202, one or other of the pawl set drive teeth 502 is only partially engaged (e.g., one third of the pawl tooth 502 arc engaged) and the remaining set pawl drive teeth 502 are partially disengaged (e.g., one third of the pawl tooth arc disengaged).

[0051] FIGS. 5 and 6 further illustrate in perspective the multiple pawl ratcheting mechanism 1, denoting the parts shown dismantled for display purposes. The handle 400 and its levered end 402, incorporating the head portion 300, head portion outer surface 301, inner surface 302, locking profiles 303, location profile 304, switch bore 305, connection undercut 306, closure portion 307, closure clip 308 and central chamber 309. The driven element 200, circumferential toothed portion 201, element teeth 202 and element spigot 203. The pawls 500, toothed face 501, engagement biasing face 504 and disengagement biasing face 505. The switch 600, operating lever 601, axle 602, axle plunger bore 603, spring 604, sprung plunger 605 and plunger engagement face 606. Fixed ramp profile layer 700, first ramped profile 701, second ramped profile 702, ramped profile set A 703, ramped profile set B 704, ramped profile set C 705, locking notch 706, location notch 707 and centralizing face 708. Actuating layer 800, biasing protrusion 801, pawl engagement profile 802, pawl disengagement profile 803, direction profile 804, pawl engagement set A 807, pawl engagement set B 808 and pawl engagement set C 809.

[0052] FIG. 7 further illustrates in perspective the multiple pawl ratcheting mechanism 1, driven element 200, switch 600, fixed ramped profile layer 700 and actuating layer 800 in isolation in order to demonstrate their internal function. The fixed layer locking notches 706 secure the said fixed layer 700 from circumferential motion. The said switch operation lever 601 directing the sprung plunger 605 engagement face 606 into the actuating layer resilient plunger positional indent 806 within the actuating layer direction profile 804 resiliently urging the actuating layer in the anticlockwise direction ACWD. Further shown are the drive element spigot 203, the closure portion 307 and its clip 308.

[0053] FIGS. 7 to 12 further illustrate in perspective a further utilization of the present invention whereas the dual direction ratchet 1 is incorporated into a dual direction ratcheting screwdriver using a direction biasing switch ring 607 to determine the operating direction of the said ratchet 1. In the first aspect, the present invention provides a dual direction, ratcheting screwdriver 1, comprising a handle portion 400 with a proximal end 403 and a distil end 404, said handle proximal end 403 robustly incorporates the housing 900 encapsulated ratchet mechanism 1 with its outer facing direction biasing switch ring 607 within its profile. The housing 900 is connected to the screwdriver driven element portion 205, of the rotatable elongate shaft 208 in order to transmit motion and torque to the said shaft 208 as required, in the direction required. The housing 900 having a central chamber 901 in which the said driven element portion 205 of the said shaft 208 is received. The preferably die cast housing outer wall 904, has a connection slot 907 for the required outward connection to the direction biasing ring switch 607 direction ascertaining recess 608 by the intermediate rocker switch 609, which further incorporates axles 610 capable of positional rotation within corresponding molded axle slot shaped formations 910 located within said housing outer wall 904. The rocker switch plunger housing 612 further incorporates a resilient sprung plunger 605 within its related bore 611. The said housing central chamber 901 having in one example for ease of manufacture, modular inserts in the form of preferably three layers, two outer fixed ramped profile layers 700 with a sequential actuating layer 800 capable of limited rotation between the said fixed layers 700. The fixed ramped profile layer 700 having outer locking notches 706 which mechanically engage with the corresponding housing central locking profiles 902, the said fixed profile layer 700 further utilizing first and second ramped profiles 701, 702 within said central profile 709, preferably three sets of equally spaced opposing direction pawls 500 are situated within said corresponding ramped profiles 701, 702. The middle sequential actuating layer 800 has engagement 802 and disengagement 803 profiles at either end of its pawl recesses 801, these said profiles 802, 803 project in the chosen direction the incumbent pawls 500 against the corresponding fixed layer ramped profiles 701, 702 in the chosen clockwise CWD or anticlockwise drive direction ACWD whilst simultaneously disengaging the said pawls 500 facing in the opposite direction, the said pawls 500 outer ramped profile 503 acting against the corresponding fixed layer pawl ramped profile 701 or 702 in the chosen drive direction CWD or ACWD. The engaged pawls teeth 502 engaged with the screwdriver driven element teeth 206 in order to drive as required the same. The actuating layer 800 is resiliently propelled in the chosen clockwise or anticlockwise direction by the intermediate rocker switch 609 having a sprung plunger 605 whose engagement face 606 acts against the said actuating layer 800 chosen sprung plunger positional indent 806, when utilized in the reverse or reposition direction R the actuating layer 800 with its incumbent pawls 500, resiliently circumferentially rotating against the said sprung plunger 605, further allowing the pawl teeth 502 engaged within the drive element teeth 202 to resiliently slide over one another during the reposition R action.

[0054] FIG. 8 further illustrates in perspective the dual direction ratchet 1 incorporated into a dual direction ratcheting screwdriver. An operator gripping the handle portion 400, further illustrated the direction biasing switch ring 607 anticlockwise direction switch direction ACWD being identical to that of the screwdriver shaft 208.

[0055] FIGS. 9, 10 and 11 further illustrate in perspective and front profile, the dual direction ratchet 1 incorporated into a dual direction ratcheting screwdriver. The known direction biasing switch ring 607 with its rocker switch actuating profile 608 acts upon the novel intermediate rocker switch 609 actuating profile 613 in order to swivel into engagement its incumbent sprung plunger 605 engagement face 606, resiliently against the actuating layer direction profile 804 in the desired direction. The said rocker switch 609 having axles 610 which are retained, can rotate and also move radially as required in the housing molded axle slots 910 during the direction switching process. The switch spring 604 usefully acting in both directions, urging the said rocker switch actuating profile 613 into engagement with the switch ring direction actuating profile 608, whilst further acting to propel the sprung plunger engagement face 606 against the actuating layer direction profile 804.

[0056] Although certain example methods and apparatus have been described herein, the scope of coverage of this patent is not limited thereto. On the contrary, this patent covers all methods, apparatus, and articles of manufacture fairly falling within the scope of the appended claims either literally or under the doctrine of equivalents.