Balanced rotary helical Actuator

Information

  • Patent Application
  • 20160363141
  • Publication Number
    20160363141
  • Date Filed
    August 26, 2016
    8 years ago
  • Date Published
    December 15, 2016
    8 years ago
Abstract
This invention relates to a novel helical dual-center engagement converting mechanism and its applications in fluid-powered actuation system, more particularly to a highly reliable, simple, powerful and balanced and less expensive helical rotary actuator. This actuator comprises a self-balanced linear/rotary dual-center engagement converter, compact porting systems and easy manufacturing modules and various bodies and shaft interface with other components. This actuator also provides a rotary position control and backlash eliminating mechanism to meet various requirements with lighter weight, smaller size and higher accuracy of position and can be interfaced with different machines, such as subsea valves, earthmoving equipment, construction equipment, lifting equipment, landing gears, militarily equipment and medical devices, robotic and artificial leg and arm joints.
Description
FEDERALLY SPONSORED RESEARCH

No


SEQUENCE LISTING OR PROGRAM

No


BACKGROUND

This invention relates to a novel helical dual-center engagement converting mechanism and its applications in fluid-powered actuation system, more particularly to a highly reliable, simple, powerful and balanced and less expensive helical rotary actuator. This actuator comprises a self-balanced linear/rotary dual-center engagement converter, compact porting systems, easy manufacturing modules, various body configuration and shaft interfaces with other components. This actuator also provides a rotary position control and backlash eliminating mechanism to meet high precision requirements with lighter weight, smaller size and higher accuracy of position and can be interfaced with different machines, such as subsea valves, earthmoving equipment, construction equipment, lifting equipment, landing gears, militarily equipment and robotic and medical devices, artificial arm and leg joints.


Conventional fluid-powered helical actuators have been used in many industries for years, it is based on an old helical linear/rotary converter mechanism and includes a cylindrically shaped housing and two moving parts: a shaft and an annular piston. Helical spline teeth machined on the shaft engage a matching complement of splines on an inside diameter of the piston, an outside diameter of the piston carries a second set of helical splines that engages a ring gear integral with the housing. While conventional linear pistons with pivot joint, the rack and pinion and vane actuators still have majority market share over the helical rotary actuators, the reason is that conventional fluid-powered helical rotary actuators have many unsolved problems and disadvantages; (1) low efficiency, about 60%-70% efficiency for helical rotary actuator is in comparison with that of 90 to 98% for the rack and pinion or vane actuators, so it prevents the actuator from low pressure applications, there are fewer helical pneumatic actuators in the market in comparison with rack and pinion and vane actuators, it not only wastes lot of materials and energy but also can not be used for limited space or restrict weight applications (2) high unbalanced thrust, the unbalanced thrust is still an unsolved problem, it requires more internal parts to balance the thrust, so length of actuator becomes very longer, size of the actuator becomes bigger even there are some balanced helical actuators in the prior art, none of the trials has been commercial success (3) backlashes, due to cumulative clearances of two sets of helical teeth engagements, it increases the impact on the teeth and reduces the accuracy of moving position, life of actuator, some efforts were made in the prior art, but none of trials has been commercial success (4) high stress concentration on cylindrical bodies with helical teeth either by pinging, welding or integrating, it has been struggled for years to seek the solution, under high pressure 3000-5000 psi, the root of helical teeth on cylindrical body generates high stress concentration, this structural problem not only reduces the load capacity and increase the actuator size and weights, but also it can cause sudden break down based on Paris law and is considered to be unreliable and unsafe for critical operations where linear piston with pivot joint devices which have the same rotation function still play a key role in earthmoving equipment and landing gears (5) restrict installation position, most helical actuators are designed for either vertical or horizontal position, they are not suitable for any position between them, due to lack of proper structure and bearing (6) lack of position control, due to lack of control of rotary position and fail to close or open function, it prevents the actuator from critical applications such as military equipment, robotic devices and valve control (7) lack of interface function, most of the actuator bodies are cylindrical shape, such a shape is difficult for three dimensional joint (8) low reliability, according to Failure Modes and Effects Analysis (FMEA), a piston with internal and external helical teeth has the highest severity, with lack of redundancy, the conventional helical actuator never can compete with linear piston with pivot joint in critical applications like landing gears (9) structural inferiority (a) most cylindrical body cannot sustain high structural bending load and compression load, it prevent it from those applications like rotation with high bending or compression (b) material incomparability, since material requirement of mechanical property for body is very different from that of teeth, for the body, it requires high strength, ductile, while for the teeth, high hardness and wearing resistance are the key requirements, since the helical teethes are a part of the body, so most designs are to put the body strength first and to scarify teeth design, as a result the teeth with soft surface will be damaged first or wore out fast even with hydraulic fluid (10) difficult and expensive manufacturing, it is difficult and expensive to make helical teeth, specially internal helical teeth or internal splines on the body as an integral part, it not only makes the manufacturing process more difficult if not impossible, it is impossible to replace the teeth alone, since there is no modulization design in the actuator, conventional actuator manufacturing require large inventory for each size actuator (11) inlet and outlet ports are far away and not standardized, so it is difficult to connect the ports, especially in case of counterbalanced valve is required, additional tube and adapter is needed, it not only increase cost but also reduce reliability, any addition joint adapter and tube can cause leak.


In order to overcome the disadvantages or solve the problems of the conventional fluid-powered helical rotary actuators, many efforts have been made in the prior arts. There are four approaches to improve the conventional helical actuators in the prior arts, but those approaches work against each other within a limited scope.


The first approach is to improve the conversion mechanism. U.S. Pat. No. 3,255,806 to Kenneth H. Meyer (1966), U.S. Pat. No. 4,089,229 to James Leonard Geraci (1978) show a approach is to use a number of keys and keyway to prevent the piston sleeve from rotation under linear force, this conversion mechanism did work, but there were two drawbacks, one is to waste large internal body space due to the keyway, the other is to cause high stress concentration on the body, under 3000 -5000 psi pressure, such stress condition is unsafe and prohibited, likewise other actuators are provided with splined design to prevent the piston from rotation for valve actuations, in addition, it is expensive to make, so many other solutions came out like U.S. Pat. No. 1,056,616 to C. E Wright (1913), U.S. Pat. No.6,793,194 B1 to Joseph Grinberg (2004) the approach is to use two bars to prevent piston sleeve from rotation, the drawback is to waste a large interior housing space and it is restricted to smaller actuator applications, finally current widely acceptable helical actuator is shown in U.S. Pat. No. 3,393,610 to R. O. Aarvold (1966) disclosed a device with a pair helical gearing means between a housing and a shaft in an opposite direction, but it did not prevent the piston rotation, rather it is used as medium to generate a reaction torque between the housing and the shaft and in turn to rotate the shaft, the drawback is to waste internal space and more energy to rotate the piston and increase backlash and cost, a desirable design for this conversion mechanism is that only rotary part should be a rotary shaft, not a body or a piston, moreover the additional rotation will wear bearings and o rings faster and more than under a linear movement only, in addition the arrangement greatly restricts an engaged diameter of the piston, as a result, the output torque is greatly reduced, again, high stress concentration on the body still exists, even it become more difficulty to manufacture with internal and external teeth in a piston.


The second approach is to balance thrust force and ease consequences of the unbalanced forces on helical actuators, U.S. Pat. No. 3,255,806 to Kenneth H. Meyer (1966) shows an actuator with two actuator assembled in an opposite teeth and direction, the design become more difficulty for machining the keyways on the longer body, other effort made is shown on U.S. Pat. No. 4,745,847 to Julian D. Voss (1988) discloses a new design with four parts; a shaft, a housing, a linear piston, a rotation piston, it causes more leak paths and make the actuators more complicated and less reliable, finally U.S. Pat. No. 3,393,610 to R. O. Aarvold (1966) shows two sets of helical teeth in an opposite direction on a piston, it balances the thrust force on the piston but not on the shaft or housing, this arrangement causes a constant tension on the piston during linear/rotary converting, so the piston is subject to torsion well as tension while the load is still applied to shaft and housing, as a result the size of piston is increased while the housing and shaft are underused, so far there is no successful full balance design in the market.


The third approach is to simplify the manufacturing process, there is few development in the field, the most internal helical teeth are as an integral part of a housing or shaft, few welding process or pining process have been tried, but for the current pressure vessel safety standards, those practices under 3000-5000 psi pressure are considered to be unsafe, so stronger, heaver body or shaft with a integral helical teeth are only the solution for now, there is no improvement in the filed


The fourth approach is to ease the backlash and improve performances of the actuator, a typical example is shown in U.S. Pat. No. 2,791,128 to Howard M. Geyer (1957) and U.S. Pat. No.4,858,486 to Paul P. Meyer (1989), a complex mechanical adjustable devices are introduced, but in most applications, such a design is considered to be impractical or too costly due to inherent disadvantage of clearance of two set of helical teeth., the fundamental adjustment mechanism is still unchanged.


So the fluid-powered actuation industry has long sought means of improving the performance of fluid-powered actuation system, eliminating the unbalanced thrust increate efficiency, increate integrity of the body strength, and increasing reliability and accuracy rotary position with less cost.


In conclusion, insofar as I am aware, no fluid-powered actuation system formerly developed provides higher system performances with a modularization structure, less parts, highly efficient, versatile, reliable, easy manufacturing at low cost.


SUMMARY

This invention provides a simple, highly reliable, modular, compact, efficient and balanced rotary actuator. This actuator comprises a novel and improved helical linear/rotary converting modules, compact porting systems and shaft/body interface modules and is much simpler for manufacturing and assembly. It is constructed as converting modules and shaft/body modules, which are easily connected to various components. It also provides rotary position controllers for 90, 180 or 360 degrees with no backlash and lighter weight, smaller space and higher accuracy of position and can be used for a combination device of a hinge and rotary actuator or a rotary actuator either under high axial load or gravity load between vertical and horizontal positions, or for quick cycle, high vibration, quick opening or closing applications and other critical applications to replace linear pistons with pivot joint devices or landing gears for aircraft or artificial or robotic leg and arm joints


The helical linear/rotary converting module can be constructed as a body, a converting unit and a shaft, the converting unit can be constructed as one piston having a two-center linear engagement means and a helical rotary engagement means with the body and the shaft, the two-center linear engagement means is constructed as a pair of a centric and eccentric section which are engaged with a centric bore and eccentric bore between the converting piston and the body or shaft, the helical rotary engagement means is constructed with a pair of helical converting means which includes spline teeth engagement, spline groove/pin and teeth engagement with balls between the converting piston and the body or the converting piston and the shaft, the converting unit can be constructed as two pistons have two pairs of the linear engagement means and rotary engagement means located and moved in an opposite direction. The body can be constructed as one piece a body or two piece split bodies, while shaft can be constructed as one pieces part with helical rotary converting means or two-center linear converting means or multiple pieces parts. The actuator includes various shapes of bodies for different applications.


The actuator can be constructed with various shape of bodies, the spherical shape of the body is constructed for supporting high axial load both on the shaft or body or installed between vertical and horizontal positions and sustain high bending and compression loads or with robotic and artificial arm and leg joints, other shape of body is provided with one end closed and other end opened for operating rotary valve, finally a split body is constructed to receive large engaged diameter of piston with smaller end shaft or large spring to generate return force.


The actuator can be constructed with position control devices. One of the feature is to combine a vane actuator and helical actuator as one unit, it not only eliminate backlash but increase output torque and improve the accuracy of rotary position, other is to provide two hard adjustable hard stop in both ends of rotation of 90, 180, 270 or 360 degree. In the manufacturing of the actuator, this invention provides other joint method to separate helical teeth from shaft or body, so the helical teeth can be manufactured replaced easily at low cost.


Accordingly, besides objects and advantages of the present invention described in the above patent, several objects and advantages of the present invention are:

  • (a) To provide a highly efficient linear/rotary converting mechanism with less energy, maxim output torque and fewer components.
  • (b) To provide a linear/rotary converting mechanism with less stress concentration, so the mechanism can be more reliable, compact and still robust for critical applications
  • (c) To provide a fluid-powered actuation system with highly optimal division of functions among the modular members in a balanced manner, so such a system allows a user to have higher integrity of a system with fewer components and reduce a system space, leakage and manufacturing and replacement cost
  • (d) To provide a directly coupling means for an actuator and other components so as to eliminate adapters, reduce the space for their connection.
  • (e) To provide a fully balanced means for an actuator, so the actuator is constructed with more powerful and reliable mechanism with less weight, parts and cost.
  • (f) To provide a fluid-powered actuation system with actuator, which has less displaced fluid volumes on both sides of pistons, so the energy loss can be reduced to a minimum level
  • (g) To provide an internal porting means for a fluid-powered actuation system, the system is not subject to external tube corrosion and breakdown and has quick response time and can be either connected through a shaft or body.
  • (h) To provide a fluid-powered actuator with high holding torque, so it is not susceptible to vibration and more stable and can be used in applications of high vibration, quick cycle.
  • (i) To provide a fluid-powered actuation system with gravity balance mechanism, so the actuator can be used between vertical and horizontal positions.
  • (j) To provide a fluid-powered actuation system without backlash, so the system becomes more stable and accurate at pre-setting position
  • (k) To provide a fluid-powered actuation system with highly reliable, inherently redundant, intrinsically safe control functions, so the system can be used for critical applications such as military operation, medical emergence care/device and aircraft landing gears
  • (l) To provide a produced-friendly, fluid-powered actuation modules with simple, flexible structures, easy manufacturing and process and various size and material selection, the modules require simple manufacturing process and flexible construction methods for different applications, so a manufacturer for the system can easily implement rapid product development and outsourcing at lower cost
  • (m) To provide a linear-rotary converting device with compact, adaptable rotary shaft and body. Therefore, the devices can use as a combination of a hinge joint and rotary actuator for robotic or artificial arm and leg joints.


Still further objects and advantages will become apparent from study of the following description and the accompanying drawings.





DRAWINGS

Drawing Figures



FIG. 10 is an exploded, quarter cut view of a helical rotary actuator embodiment of the helical linear/rotary converting mechanism of FIG. 8.



FIG. 11 is a front view of the helical rotary actuator of FIG. 10.



FIG. 12 is a cross sectional view of the helical rotary actuator of FIG. 11. Along line B-B.



FIG. 13 is a cross sectional view of the helical rotary actuator of FIG. 11. Along line C-C.



FIG. 14 is a detail view of the helical rotary actuator of FIG. 13. Along cycle of F.



FIG. 15 is an exploded, quarter cut view of an alternative embodiment of helical rotary actuator of FIG. 10.



FIG. 16 is a front view of the helical rotary actuator of FIG. 15.



FIG. 17 is a cross sectional view of the helical rotary actuator of FIG. 16 along line E-E.



FIG. 18 is a cross view of the helical rotary actuator of FIG. 16. along line D-D.



FIG. 19 is an isometric view of the helical rotary actuator of FIG. 16.



FIG. 20 is an exploded, quarter cut view of an alternative embodiment of helical rotary actuator of FIG. 10.



FIG. 21 is a detail view of the helical rotary actuator of FIG. 20. along cycle of A



FIG. 22 is a front view of a subassembly of FIG. 20.



FIG. 23 is a side view of the subassembly of FIG. 22.



FIG. 24 is a cross sectional view of the subassembly of FIG. 22 along line F-F.



FIG. 25 is a cross sectional view of the subassembly of FIG. 22 along line G-G.



FIG. 26 is an exploded, quarter cut view of an alternative embodiment of helical rotary actuator of FIG. 10.



FIG. 27 is a front view of the helical rotary actuator of FIG. 26.



FIG. 28 is a cross sectional view of the helical rotary actuator of FIG. 27 along line I-I.



FIG. 29 is a cross sectional view of the helical rotary actuator of FIG. 27 along line H-H.



FIG. 30 is an exploded, quarter cut view of an alternative embodiment of helical rotary actuator of FIG. 10.



FIG. 31 is a front view of the helical rotary actuator of FIG. 30.



FIG. 32 is a cross sectional view of the helical rotary actuator of FIG. 31 along line K-K.



FIG. 33 is a cross sectional view of the helical rotary actuator of FIG. 30 along line J-J.



FIG. 34 is an exploded view of an alternative embodiment of helical rotary actuator of FIG. 30.



FIG. 35 is a front view of the helical rotary actuator of FIG. 34.



FIG. 36 is a cross sectional view of the helical rotary actuator of FIG. 35 along line L-L.





REFERENCE NUMBER IN DRAWING




  • 10 Single Helical Converter a,b,c,d,e,f,h


  • 11 body a,b,c,d


  • 12 Converting piston, a,b,c,d


  • 13 Shaft, a,b,c,d,e,f,g,h


  • 14 Centric section, a,b,c,d


  • 15 Eccentric section, a,b,c,d


  • 16 Centric bore, a,b,c,d


  • 17 Eccentric bore a,b,c,d


  • 18 Helical internal teeth, a,b,d


  • 19 helical external teeth a,b,d


  • 18 Helical groove, c


  • 19 Helical groove pin, c,


  • 20 Double Helical converter a,b,f


  • 21 Body, a,b,f


  • 22,22′ Converting piston a,b,f


  • 23 Shaft, a,b,f


  • 24 Centric section a,b,f


  • 25,25′ Eccentric section a,b,f


  • 26,26′ Centric bore a,b,f


  • 27,27′ Eccentric bore a,b,f


  • 28,28′ Helical internal teeth a,b,f


  • 29
    29′ Helical external teeth a,b,f


  • 1 Support ring e,f,g,h


  • 4 Centric section, e,f,g,h


  • 5 Eccentric section, e,f,g,h


  • 6 Centric bore e,f,g,h


  • 9 Retaining ring g


  • 2 Helical teeth ring, e,f,g,h


  • 3 Shaft e,f,g,h


  • 7 Eccentric bore, e,f,g,h


  • 8 Set of Balls


  • 100 Helical Actuator, a,b,c,d,e,g

  • A port, 1,2,3,4,5,6,7

  • B Port, 1,2,3,4,5,6,7


  • 101′,101 Body,


  • 102′,102 Centric bore,


  • 103′,103 Eccentric bore


  • 104′,104 body end


  • 105 Horizontal Passageway


  • 106 Spherical external surface


  • 107 Cylindrical External surface


  • 108′,108 Groove


  • 109′,109 End Vertical surface


  • 110′,110 End Horizontal surface


  • 111 End Spherical surface


  • 112 Out-vertical surface


  • 113 Horizontal surface


  • 117 Inter-vertical surface


  • 120 Center chamber


  • 121′,121 Side chamber,


  • 122′,122 Helical internal teeth right


  • 123′,123 Helical internal teeth left


  • 124 Spherical external surface


  • 125 Thread hold


  • 126 Bolt hole


  • 127 hole


  • 128 hole


  • 129 O ring groove


  • 140 Shaft


  • 141′,141 External helical teeth,


  • 142


  • 143 Centric section


  • 144 Eccentric section


  • 145′,145 end


  • 146 keyway


  • 147 center hole


  • 148′,148 Side hole


  • 160 O ring


  • 161 Oring


  • 162 Oring


  • 163 Oring


  • 164 Oring


  • 165 Spherical bearing


  • 166 bolt


  • 190 Spherical supporter


  • 191 Shell plate


  • 192 Recess surface


  • 193 Thread hole


  • 130″,130 Converting piston


  • 131′,131 Groove


  • 132′,132 Centric section


  • 133′,133 Eccentric section


  • 134′,134 Internal helical teeth


  • 135′,135 External helical teeth


  • 136′,136 Piston inward surface


  • 137′,137 Piston outward surface


  • 138′,138 Link hole


  • 139′,139 bore


  • 150 Spherical Cover


  • 151 Spherical internal surface


  • 152 Out-Vertical surface


  • 153 Horizontal surface


  • 154 Spherical external surface


  • 155 End Vertical surface


  • 156 Shaft hole


  • 157 Inter-Vertical surface


  • 158 Flat cover


  • 159 O ring groove


  • 170 Vane cover


  • 171 Vane


  • 172 Piston land


  • 173 Inward port


  • 174 Outward port


  • 175 vane Key


  • 176 Middle ring


  • 177 hole


  • 178 Inside surface


  • 179 Outside surface


  • 197 Link port


  • 198 recess


  • 180 Conical step


  • 181 Conical surface


  • 182 Conical surface


  • 183 Vane chamber


  • 184 Vane chamber


  • 185′, 185 Slot


  • 186 plug


  • 187 setscrew


  • 188 Flat screw


  • 189 spring


  • 195 Vane land


  • 196 groove



Description


FIGS. 10-14 illustrate a fluid powered helical rotary actuator 100a based on helical linear/rotary converting mechanism 20a constructed in accordance with the present invention. The actuator 100a comprises a body 101a having an eccentric bore 103a, two centric bores 102a,102a′ and pistons 130a,130a′, a shaft 140a is movably disposed in pistons 130a,130a′, body 101a is covered by a spherical cover 150a and a flat cover 158a and has standard ports A1, B1 which includes port size and distance between port A1, B1 and respectively connected to a pressurized fluid and a sink fluid (not shown), the actuator 100a is provided for rotary movements.


Pistons 130a,130a′ are axially opposed and respectively have sections 132a, 133a movably engaged with bores 102a, 103a and sections 132a′, 133a′ movably engaged with bores 102a′,103a in an opposite direction. Pistons 130a,130a′ also include internal helical teeth 134a,134a′ in inner surfaces to operatively engage with sections 141a,141a′ of the shaft 140a, a center chamber 120a is provided between inward surfaces 136a, 136a′ and bore 103a and is connected to port B1 and to grooves 131a,131a′ through gaps between teeth 134a and 141a, teeth 134a′and 141a′ and link holes 138a,138a′, while side chambers 121a,121a′ are defined respectively by cover 150a, an outward surface 137a and bore 102a and by cover 158a, an outward surface 137a′ and bore 102a′ and connected to port Al through a passageway 105 and grooves 108a,108a′.


Cover 150a is mounted on a left side of shaft 140a and has a first vertical surface 152a, spherical surface 151a, a second vertical surface 157a and a horizontal surface 153a with an o ring groove 159a, body 101a has a first vertical surface 112a, a spherical surface 111a, a second vertical surface 117a with an o ring groove 129a and horizontal surface 110a, a spherical bearing 165a is placed between surfaces 151a and 111a for providing a bearing and a seal, while o-rings 160a and 161a are respectively placed in groove 129a and groove 159a for providing a vertical seal and a horizontal seal between cover 150a and body 101a.


Referring to FIGS. 15-19, a fluid powered helical rotary actuator 100b based on fluid powered helical rotary actuator 100a comprises a spherical body 101b, pistons 130b,130b′, a shaft 140b is movably disposed in pistons 130b,130b′, body 101b is covered by two spherical covers 150b, 150b′ and has standard ports A2, B2 which includes port size and distance between port A2, B2 and respectively connected to a pressurized fluid and a sink fluid (not shown), there are other optional ports A3, B3 respectively connected to a pressurized fluid and a sink fluid (not shown), the actuator 100b is provided for rotary movements.


A center chamber 120b is connected to port B2 through hole 147b, while side chambers 121b, 124b′ are connected to port A2 through holes 148b,148b′ and grooves 108b,108b′. Covers 150b,150b′ are mounted respectively on a left side and a right side of shaft 140b, a holder 190b has a cylindrical bar extended to shell 191b with a spherical recess 192b to receive actuator 100b for securing a pre-set position, holes 193b and thread holes 125b are provided for bolting between actuator 100b and holder 190b.


Referring to FIG. 20-25, a fluid powered helical rotary actuator 100c based on fluid powered helical rotary actuator 100a comprises a body 101c, pistons 130c,130c′, two vanes 171c and two vane covers 170c, a shaft 140c is movably disposed in pistons 130c,130c′, vanes 171c and vane covers 170c, body 101c is covered by two covers 158c, 158c′ and has standard ports A4, B4 which includes size port and distance between ports A4, B4 respectively connected to a pressurized fluid and a sink fluid (not shown). the actuator 100c is provided for rotary movements.


Pistons 130c,130c′ are axially opposed, movably disposed in body 101c since the left piston 130c is as the same as the right piston 130c′, only the left side piston is described here, two vane chambers 183c and 184c are defined by piston 130c, vane cover 170c, vane 171c, a vane land 195c of vane 171c and a piston land 172c of piston 130c, a center chamber 120c is connected to vane chamber 183c through gaps between shaft 140c and piston 130c, radial hole 138c and axial hole 173c and a slot 185c′, while a side chamber 121c is connected to chamber 184c through hole 174c, slot 185c, vane 171c is coupled with shaft 140c by keyway 146c and key 175c.


Referring to FIG. 26-29, a fluid powered helical rotary actuator 100d based on fluid powered helical rotary actuator 20a comprises a body 101d having a left closed end except a shaft hole 127d and a right end with a centric bore 102d to receive a middle ring 176d, pistons 130d,130d′, a shaft 140d is movably disposed in pistons 130d,130d′ and middle ring 176d, body 101d is covered by cover 158d and has standard ports A5, B5 which includes port size and distance between ports A5 and B5 respectively connected to a pressurized fluid and a sink fluid (not shown), the actuator 100d is provided for rotary movements.


Middle ring 176d is axially placed between pistons 130d,130d′ and has a centric outside surface 179d and an eccentric inside surface 178d. Pistons 130d,130d′ have respectively centric sections 132d,132d′ engaged with bore 102d and eccentric sections 133d,133d′ engaged with eccentric surface 178d. Pistons 130d,130d′ also include internal helical teeth 134d,134d′ in inner surfaces to operatively engage with external helical teeth 141d,141d′ of the shaft 140d. Middle ring 176d also includes three radial holes 177d,177d′ and is secured by two screws 187d through holes 177d, conical tips of two screws 187d are engaged with conical surfaces of 182d,182d′ for controlling inward positions of pistons 103d ,103d′, two screws 188d are threaded through cover 158d for controlling outward positions of piston of 130d, hole 176d′ is linked between port B5 and inside surface 178d .


Referring to FIG. 30-33, a fluid powered helical rotary actuator 100e based on fluid powered helical rotary actuator 100a comprises a pair of split bodies 101e,101e′ to receive a middle ring 176e and pistons 130e,130e′, bodies 101e,101e′ respectively have centric bores 102e,102e′ and eccentric bores 103e,103e′, pistons 130e,130e′ are axially opposed and respectively have sections 132e,133e engaged with bores 102e,103e and sections 132e′,133e′ engaged with bores 102e′, 103e′, a shaft 140e is movably disposed in pistons 130e,130e′ and middle ring 176e, split bodies 101e,101e′ are secured by four of bolts 166e and sealed by o-ring 164e, bodies 101e,101e′ have standard ports A6, B6 which includes size port and distance between port A6, B6 respectively connected to a pressurized fluid and a sink fluid (not shown), the actuator 100e is provided for rotary movements.


Pistons 130e,130e′ are axially opposed, movably disposed in bodies 101e,101e′, a center chamber 120e is connected to port B6, while side chamber 121e,121e′ are connected to port A6 through a passageway 105e and grooves 108e,108e′, body 101e has two holes 128e, two screws 187e are respectively threaded through holes 128e and engaged with conical surfaces 181e,181e′ defined by ring 176e and piston 130e for controlling an inward position of pistons of 130e,130e′, screws 188e are threaded through cover 158e for controlling outward positions of piston 130e and are secured by plugs 186e.


Referring to FIG. 34-36, a fluid powered helical rotary actuator 100g based on fluid powered helical rotary actuator 100e comprises a pair of split bodies 101g,101g′, spring set 189g, pistons 130g,130g′, a shaft 140g is movably disposed in pistons 130g,130g′ and a spring set 189g, split bodies 101g,101g′ are secured by four of bolts 166g and sealed by o-ring 164g, the pair of split bodies 101g,101g′ has standard ports A7, B7 which includes size of port and distance between ports A7,B7 respectively connected to a pressurized fluid and a sink fluid (not shown), the actuator 100g is provided for rotary movements.


Bodies 101g,101g′ respectively have centric bores 102g,102g′ and eccentric bores 103g,103g′, pistons 130g,130g′ are axially opposed and have respectively sections 132g,133g and sections 132g′,133g′ engaged with bores 102g, 103g and bores 102g′ and 103g′, the spring set 189g is placed between pistons 130g and 130g′ for spring return.


Operations

For the mechanisms 10a, assume that piston 12a is inserted into body 11a by engaging between sections 14a,15a, and bores 16a,17a with a clearance fit, then shaft 13a is inserted into piston 12a by engaging between helical teeth 19a and helical teeth 18s with a clearance fit, piston 12a tends to rotate under axial force, but since there is an offset between bores 16a,17, the offset only allows piston 12a to move linearly but prevents piston 12a from rotation, as a result, the helical teeth 18a on piston 12a forces helical teeth 19a as well as the shaft 13a to rotate, in case of mechanisms 10c, 10d, only difference is the helical converting means.


For the mechanisms 10b, assume that piston 12b is inserted into body 11b by engaging between helical teeth 19b and helical teeth 18b with a clearance fit then shaft 13b is inserted into piston 12b by engaging between sections 14b,15b, and bores 16b,17b with a clearance fit, piston 12b rotates under axial forces, since there is an offset between bores 16b, 17b, as a result, the offset force shaft 130b to rotate along with the piston 12b.


For mechanisms 20a, assume that shaft 23a is inserted into body 21a, then piston 22a is inserted into ring 21a from the left side by engaging between sections 24a, 25a, and bores 26a,27a with a clearance fit and between helical left teeth 29a and left helical teeth 28a, then piston 22a′ is inserted into body 21a from the right side by engaging between sections 24a′, 25a′ and bores 26a′,27a with a clearance fit and between right helical teeth 29a′ and right helical teeth 28a′, two equal but opposite forces are applied inwardly and outwardly to piston 22a and 22a′, piston 22a tends to rotate under axial forces, but since there is an offset between bores 26a,27a, the offset only allow piston 22a to move linearly but prevents piston 22a from rotation, as a result, the helical teeth 28a on piston 22a forces helical teeth 29a as well as the shaft 23a to rotate clockwise, while piston 22a′ tends to rotate under axial forces, but since there is an offset between bores 26a′,27a′, the offset allows piston 22a′ to move linearly but prevents piston 22a′ from rotation, as a result, the helical teeth 28a′ on piston 22a′ forces helical teeth 29a′ as well as shaft 23a rotate the clockwise due to opposite direction between teethes of 29a,28a and 29a′,28a′, so the axial forces balances on shaft 23a.


For the mechanisms 20b, the balance mechanism is the same as the mechanism 20a, while the operation is the same as mechanism 10b


For actuator 100a, assume that shaft 140a is inserted into body 101a, then piston 130a is inserted into body 101a from the left side by engaging between sections 132a,133a, and bores 102a,103a with a clearance fit and between helical teeth 134a and helical teeth 141a, then piston 130a′ is inserted into body 101a from the right side by engaging between sections 132a′,133a′ and bores 102a′,103a with a clearance fit and between helical teeth 134a′ and helical teeth 141a′.


Port A1 and port B1 are respectively connected to a pressurized fluid source/a fluid sink (not shown), there is no movement of the piston 130a,130a′ or that of shaft 140a. When a pressurized flow fluid is allowed to enter to chamber 121a,121a′ through port A1, then spilt into two flows into passageways 105a, then into grooves 108a,108a′, the flow fluids provide sufficient pressure against pistons 130a, 103a′ from outward surfaces 137a,137a′, while fluids in chambers 120a through B1 connected to the fluid sink have a lower pressure, so pressure differentials generate two equal but opposite forces against pistons 130a,130a′ inwardly and cause inward movements of two pistons 130a,130a′ in a synchronized manner, so shaft 140a is balanced in the axial direction, because of offset engagement between body 101a and piston 130a,130a′, piston 130a,130a′ are only allowed to move linearly, as a result, the helical teeth 134a on piston 130a and teeth 134a′ in piston 130a′ force helical teeth 141a, 141a′ as well as the shaft 140a to rotate clockwise. On the contrary, when the connections of ports Al and port B1 with the fluid source/the fluid sink are switched, the conditions of flow fluids are reversed, shaft 140a is rotated anti-clockwise.


For the actuator 100a installed in between vertical and horizontal positions, the gravity force or an external axial force is applied to cover 150a and shaft 140a, in turn cover 150a will distribute the load into bearing 165a and body 101a evenly due to the spherical surface engagement, then shaft 140a distribute the torsion evenly to two pistons 130a,130a′ due to the balanced arrangement of pistons 1301a,130a′.


For actuator 100b, it can be used as a combination of a hinge and an actuator, actuator 100b can installed in any position and sustain great bending as well as axial force due to spherical shape of body and cover which can cancel out most of non axial force, it also can be easily used for connecting other dimensional rotary device.


For actuator 100c, when a backlash is not allowed, actuator 100c can be used, by nature a vane actuator has no backlash, actuator 100c based on 100a can be modified by adding two the same vane actuators on both ends of pistons 130c,103c′. Ports A4, B4 are respectively connected to a pressurized fluid source/a fluid sink (not shown), there is no movement of the pistons 130c,130c′, or that of shaft 140c. When a pressurized flow fluid is allowed to enter to chamber 121c,121c′ through port A4, then spilt into two flows into passageways 105c, then through hole 174c, slot 185c into vane chamber 184c, the flow fluids provide sufficient pressure against land 195c which is keyed with shaft 140c by key 175c and keyway 146c, while low pressure fluids in vane chambers 183c enters chamber 120c through holes 173c,138c and engagement gaps between shaft 140c and piston 130c, in turn, chamber 120c is connected to the fluid sink, so pressure differentials forces lands 195c as well as shaft 140c to rotate clockwise. On the contrary, when the connections of ports A4 and port B4 with the fluid source/the fluid sink are switched, the conditions of flow fluids are reversed, shaft 140c is rotated anti-clockwise.


For actuator 100d which can be used when precision rotary position is required, piston 130d,130d are placed in center of body 101d, two screws 187d are threaded in holes 128d,177d with conical tips engaged with both conical surfaces 182d,182d′, by rotating the screw 182d,182d′, inward movement of pistons 130d,130d′ are controlled to a preset position, on the outward sides, two flat tip screws 188d are threaded through cover 158d, by rotating the screw 188d,188d′, outward movement of pistons 130d,130d′ are controlled for a pre-set position of shaft 140d.


For actuator 100e, assume that ring 176e is pressed into piston 130e, then two pistons 130e,130e′ are placed from both ends of shaft 140e, then two bodies 101e,101e′ are placed from both ends of shaft 140e by aligning up between hole 128e, conical surfaces 181d,182d and secured by bolts 166e. Port A6 and port B6 are respectively connected to a pressurized fluid source/a fluid sink (not shown), there is no movement of the piston 130e,130e′ or that of shaft 140e. When a pressurized flow fluid is allowed to enter to chamber 121e,121e′ through port A6, then spilt into two flows into passageways 105e, then into grooves 108e,108e′, the flow fluids provide sufficient pressure against pistons 130e, 130e′, while fluids in chambers 120e through port B6 connected to the fluid sink have a lower pressure, so pressure differentials move pistons 130e,130e′ inwardly in a synchronized manner then make shaft 140e to rotate clockwise. On the contrary, when the connections of ports A6 and port B6 with the fluid source/the fluid sink are switched, the conditions of flow fluids are reversed, shaft 140e is rotated anti-clockwise.


For actuator 100g which can be used for single acting application, top and bottom is interchangeable for fail closed and fail open of valve control without changing any part, assume that one set of springs 189g is placed into shaft 140g, then two pistons 130g,130g′ are placed from both ends of shaft 140g, then two bodies 101g,101g′ are placed from both ends of shaft 140g and secured by bolts 166g. Port Aland port Blare respectively connected to a pressurized fluid source/a fluid sink (not shown), there is no movement of the piston 130g,130g′ or that of shaft 140e. When a pressurized flow fluid is allowed to enter to chamber 121g,121g′ through port A7, then split into two flows into passageways 105g, then into grooves 108g,108g′, the flow fluids provide sufficient pressure against pistons 130g,130g′, while fluids in chambers 120g through port B7 connected to the fluid sink have a lower pressure, so pressure differentials move pistons 130g,130g′ inwardly in a synchronized manner then make shaft 140g to rotate clockwise and compress springs 189g. On the contrary, when the connections of ports A7 loses pressure, the pressure differentials disappears, the compressed springs force pistons 130g,130g′ to move outward and make shaft 140g rotated anti-clockwise.


Advantages

From the description above, a number of advantage of some embodiments of my helical rotary actuator become evident:

  • (1) high efficiency, with double effective areas of pistons, balance design, this embodiment increase the efficiency of helical rotary actuator from about 60%-70% to 85-95, with less materials and weights, smaller size, it opens the door to the low pressure pneumatic actuators market against rack and pinion and vane actuators
  • (2) a balanced thrust, the thrust is fully balanced on the shaft without any bearing under both inward and outward pressures, so under no time, the piston bears any external axial load, both the body and shaft take external side or axial loads evenly, so the piston can generates more torque than any helical actuator and last longer, the other benefit is vibration proof, due to left and right pistons work in an opposite direction, any axial movement will not change rotation position of shaft as long as there is no the relative position change between the left and right positions.
  • (3) no backlashes, first the dual center engagement does not add any axial clearance, second the left helical teeth and right helical teeth works against each other and cancel out any clearance in the axial direction, finally the piston with the vane actuator completely eliminate any backlashes structurally
  • (4) No high stress concentration on the body, with the dual center engagement, the body no longer has high stress concentration on the wall without the teeth or shape spline, it greatly reduce the wall thickness of the body and increase safety of the body and meet the pressure vessel standards for critical applications
  • (5)free installation position, with spherical joint between body and cover, balanced thrust, the invention provides an actuator which can be installed between any position between vertical and horizontal positions.
  • (6) precision position control, with conical and flat surfaces engagements devices, both inward and outward positions are fully controlled, now this actuator can be used for a critical applications such as military equipment, robotic devices and valve control
  • (7) versatile interface functions, most of the actuator bodies are cylindrical shape, such a shape is difficult for three dimensional joint
  • (8) high reliability, without high stress concentration on the body, high tension on the piston and balanced thrust on the shaft, this actuator has highest safety design over all existing helical rotary actuators, in addition, the dual independent pistons, porting systems provide redundant functions, if a left piston fails, the right piston still functions independently, it can be used for airplane landing gears or linear piston with pivot joint in the construction machines or lift equipment.
  • (9) optimized structural design (a) spherical body can sustain high structural bending and compression loads, it can be used for stand-along or combine with additional actuator for 2 D or 3 D position control (b) material comparability with design, now material for body can be different from that of teeth rings for design or application purpose, so teeth ring can be heat treated or hardened, while body can be ductile with anti wearing coating in ID wearing resistance, so it sustains high pressure on body and high compression and wearing on ID surface and does not scarify any design requirement and greatly increase the life of the product.
  • (10) Easy and low cost manufacturing, the dual-center mechanism with two pair of simple cyclical bore/sections engagements greatly reduce manufacturing and assembly cost and time at least by 50%, an axial distance adjustment becomes much easy, most of all, helical teeth ring can be replaced without replacing the body or shaft, with middle ring with eccentric surfaces, even the offset machining becomes simpler, moreover, teeth ring can be pre-made, only left is ID or OD,
  • (11) Standard input and out port, the novel internal port system makes standardized the port size and distance between inlet port and outlet port possible, it reduces adaptor and tube, but also increases the reliability of the connection, the ports can be directly connected with counterbalanced valve, two way to four way solenoid valve without tube or adaptors.


Conclusion, Ramifications and Scope

The dual-center engagement mechanism in helical rotary actuator completely changes the rotary/linear converting concept and provides breakthrough performances and advantages over all existing rotary actuators (1) simplicity, two simple cylindrical engagement with an offset, but magically much better than the conventional helical actuators either have complicated dual internal and external helical teeth on piston or external spline and internal helical on the piston, more effective areas for axial forces than that of conventional helical actuators, the double center engagement can be arranged as example of mechanism 20a, A left offset+A center+A right offset, so the left offset can be balanced the right left offset within the body under axial forces, or A centric+An offset+A centric, such a arrangement can reduce machining, or simple a centric bore with middle ring with a centric OD and an eccentric ID like mechanism 100d (2) robust, there is no detrimental features on the body, two cylindrical engagement convert the torsion from the piston to compression, such a compression structure greatly increase the body ability for holding the torque than any other methods on the conventional helical actuators while no space waste for keyway or helical or spline teeth or seals, in case of high cycle operation, there is no one location standing high impact force on the body unlike the conventional helical actuator, the impact force can enlarged the small fraction on teeth on the body and cause body buster. (3) compact, since there is no external helical teeth, the internal teeth diameter on piston can be made bigger with the size of the conventional helical piston, since there is no keyway or spline teeth, the seal groove can be on any place on the piston, it reduce at 50% length of the conventional helical actuator requires. (4) synergy, without the dual-center engagement mechanism, no full thrust balance can succeed, as the readers look back the history of helical actuator, as it evolves, no truly balance structure has been succeed, the reason is that the conventional helical actuator without an axial balance mechanism is already too longer at least twice as longer than that of the dual-center engagement mechanism actuator, if other half is added, it will be at four time longer than the dual-center engagement mechanism actuator, it is away beyond design scope in term of strength, stability and concentricity, and it is difficult to make, with dual-center engagement mechanism, fully balance helical actuator is about the same as the conventional one piston helical actuator


Each of embodiments of the present invention provides each advantage, each unique solution and each special modular structure to solve each problem existing for very long time, there are three interface elements, body where to hold, shaft where to rotate, fluid port where to get energy for operation, with all existing problem in mind (1) mechanism 100a is used as a hinge with rotary actuator in many lift equipment and deal with installation issue between vertical and horizontal positions, it provide a novel sandwich three seals, vertical o ring and horizontal o ring and conical or spherical bearing, which made out soft metals like bronze, or engineering plastics like peek to provide a seal between the cover and the body and, a bearing function to shift the load from the cover and shaft to the body to the body, the triple seals secure a sound sealing function in any rotation position between vertical and horizontal positions, when it is installed in vertical position, or a horizontal position or between the vertical seal or horizontal seal with no or a bit effect of gravity for seal due to spherical or conical engagement between the cover and body, while spherical bearing play a key to swift gravity load to the body as well for hard seal (2) mechanism 100b dealt with adaptability issue, it is used for providing 360 degree rotation, it is breakthrough in term of usage, it can sustain very high compression load or bending load, three of them combine can provide any three dimension position due to the spherical joint between cover and body, it can be used as robotic arm joint to replace linear piston with a pivot joint device or artificial arm or leg joint with a linear piston arm or leg, it can be used as a self motored hydraulic wheel for at 360 degree rotation (3) mechanism 100c dealt with backlash issue, the backlash causes loss of control of position, damage of output shaft or other piston or body and weakens joint between actuator and other connected part and is a nightmare for control engineers, with a conventional helical actuator, it is impossible to eliminate the backlash, or loss motion, because two sets of clearance between the body and piston, piston and shaft are caused by one piece of the piston, but with this embodiment, the two teeth engagements are separated by two pistons, there is no cumulative clearance, moreover actuator 100c solves the problem by adding two vane actuator on both sides, by nature, vane actuator has no backlash, the helical actuator provide a converting, rigid torque, the torque is not susceptible to an inlet pressure frustrations, while the vane actuator provides a soft direct torque without converting or delay, when the actuator start to rotate the shaft, a combination soft and rigid torques provides a smooth, backlash free rotation movement, by changing size of hole 174c vane torque can be either reduced or increased, moreover the vane actuator can be used as a damper when actuator acts too fast, this combination of vane actuation and two pistons arrangement solution surpass all previous efforts (4) mechanism 100d is used for applications like rotary valve actuation, it is required a body bottom connection with a valve for precision position, inward position control is provided with a pair of conical tips of screws, outward position are controlled by two flat tip screws, since the piston is not rotated unlike conventional helical actuator (5) mechanism 100e is used for lager torque output with limited axial space and precision position, with split bodies, the diameter of helical teeth can be made much larger without wasting lot material, since they are symmetric, it reduce the casting or forging mould cost, other application is used for spring return, it saves lot of money by reducing haft the spring sets in comparison with the conventional helical actuator with spring return devices, specially in subsea rotary valve applications, light weight, easy installation, versatility are the key requirements for a diver to install a valve system, the other advantage is top and button of connection can be interchanged for fail closed or fail open applications without changing any part.


Although the description above contains many specifications, these should not be construed as limiting the scope of the invention but as merely providing illustration of some of the presently preferred embodiments of this invention.


Thus, the scope of the invention should be determined by the appended claims and their legal equivalents, rather than by the examples given.

Claims
  • 1. An actuation module comprising; (a) A body assembly having a body;(b) A shaft assembly having a shaft;(c) A conversion-transmission assembly having one of a plurality of configurations including; (c1) Said conversion-transmission assembly positioned between said shaft assembly and said body assembly having a helical movement converting mechanism and a movable piston, said helical movement converting mechanism including a helical engagement for providing conversions between reciprocal movements and rotary movements and a reactionary engagement for generating reactionary torques, said helical movement converting mechanism is defined by one of a plurality of arrangements inducing said helical engagement between said piston and said shaft, and said reactionary engagement between said piston and said body, said body has a front cylindrical bore defined by a fixed, centric axis and a back cylindrical bore defined by a fixed eccentric axis, parallel to said fixed centric axis, said piston has two mated cylindrical sections engaged respectively with said front centric bore and said back eccentric bore of said body for providing said reactionary engagement, said helical movement converting mechanism is defined by one of a plurality of structures including a helix spline/helix spline structure and a helix spline/non-helix spline structure, said shaft has helical splines, said piston has mated helical splines engaged with said helical splines of said shaft for providing said helical engagement, whereby said body, said piston and said shaft having a conversion means for providing conversions between reciprocal movements of said piston and rotatory movements of said shaft, and a non-friction reaction means for generating reactionary compression forces with said axises against said shaft;(c2) Said conversion-transmission assembly positioned between said shaft assembly and said body assembly having helical movement converting mechanisms, a right movable piston and a left movable piston, said helical movement converting mechanism including a helical engagement for providing conversions between reciprocal movements and rotary movements and a reactionary engagement for generating reactionary torques, said helical movement mechanism is defined by one of a plurality of arrangements inducing said helical engagement between said pistons and said shaft, and said reactionary engagement between said pistons and said body, said body has a right, cylindrical bore and at least one middle cylindrical bore respectively defined by a fixed centric axis, a fixed eccentric axis parallel to said fixed centric axis and a left cylindrical bore and said middle cylindrical bore respectively defined by said fixed centric axis and said fixed eccentric axis, said right piston has two mated cylindrical sections engaged respectively with said right bore and said middle bore of said body for providing said reactionary engagement, said left piston has two mated cylindrical sections engaged respectively with said left bore and said middle bore of said body for providing said reactionary engagement, said helical movement converting mechanism is defined by one of a plurality of structures including a helix spline/helix spline structure, and a helix spline/non-helix spline structure, said shaft has right helical splines and left helical splines, said right piston has mated right helical splines engaged with said right helical splines of said shaft for providing said helical engagement, said left piston has mated left helical splines engaged with said left helical splines of said shaft for providing said helical engagement, whereby said body, said pistons and said shaft having a conversion means for providing conversions between reciprocal movements of said pistons and rotatory movements of said shaft, and a non-friction reaction means for generating reactionary compression forces with said axises against said shaft and a balance means for balancing side loads on said left helical splines of said shaft engaged with said right piston with side forces on said left helical splines on said shaft engaged with said right piston;(d) A porting system including one of a plurality of arrangements having; (d1) said body porting including a port 1 and a port 2 and a right groove of said right bore and a left groove of said left bore on said body, said port 1 is expanding respectively to said right groove on said right bore and said left groove on said right bore of said body, said right groove connecting to a right chamber with an outward surface of said right piston, said left groove connecting to a left chamber with an outward surface of said left piston, said port 2 is through a wall of said body into a middle chamber with an inward surface of said left piston and an inward surface of said right piston;(d2) said shaft porting including an axial port 3 and an axial port 4 on said shaft, said body having a right groove of said right bore and a left groove of said left bore, said port 3 is respectively expending to a right radial hole to connect to said right groove into a right chamber with an outward surface of said right piston and a left radial hole to connect to said left groove into a left chamber with an outward surface of said left piston, said port 4 of said shaft is expanding through a middle hole into a middle chamber with an inward surface of said left piston and an inward surface of said right piston;(d3) said hybrid porting including a body porting and a shaft porting, said body porting including a port 1 and a port 2 and a right groove of said right bore and a left groove of said left bore on said body, said port 1 is expanding respectively to said right groove and said left groove, said right groove connecting to a right chamber with an outward surface of said right piston, said left groove connecting to a left chamber with an outward surface of said left piston, said port 2 is through a wall of said body into a middle chamber with an inward surface of said left piston and an inward surface of said right piston, said shaft porting including an axial port 3 and an axial port 4 on said shaft, said port 3 of said shaft is respectively expending to a right radial hole to connect to said right groove into said right chamber with said inward surface of said right piston and to a left radial hole to connect to said left groove into said left chamber with said outward surface of said left piston, said port 4 of said shaft is expanding through a middle hole into said middle chamber with said inward surface of said left piston and said inward surface of said right piston.
  • 2. The actuation module of claim 1, said body assembly further including at least one cover assembly, said cover assembly has a cover, at least one bearing, at least one vertical O-ring and at least one horizontal O-ring, said bearing having an extremal surface and an internal surface respectively defined by one of a plurality of profiles including a spherical profile and a conical prolife, said body having an edge on said right bore, said edge is defined by a mated external surface engaged with said conical internal surface of said bearing, said cover is defined by an internal mated surface engaged with said external conical surface of said bearing, a vertical O-ring groove and a horizontal O-ring groove are respectively defined between said edge and said cover, said vertical O-ring is disposed in said vertical groove, said horizontal O-ring is placed in said horizontal groove, whereby said cover assembly, and said body having a sealing means for providing seals between said body and said cover at any installed position, and a bearing means for supporting loads at any installed position.
  • 3. The actuation module of claim 1, wherein said piston is structured with one of a plurality of materials including a magnetic material, aluminum bronze, ductile iron, said bearing is structured with one of a plurality of materials including a magnetic material, aluminum, nylon, copper.
  • 4. The actuation module of claim 1, wherein said piston is structured with one of a plurality of materials including a magnetic material, aluminum bronze, ductile iron, said bearing is structured with one of a plurality of materials including a magnetic material, aluminum, nylon, copper.
  • 5. The actuation module of claim 1, said body assembly further including a position control assembly having a left screw threaded into a left side of said body assembly for controlling outward positions of said left piston, a right screw threaded into a right side of said body assembly for controlling outward positions of said right piston, at least one middle screw threaded in said body having a conical end to control inward positions of said left piston and inward positions of said right piston.
  • 6. The actuation module of claim 1, said body assembly further including a right set spring against said right piston and a left set spring against said left piston, whereby said body, said pistons and said shaft, said spring sets having a spring means for eliminating backlash between said pistons and said shaft, preventing hard hits between said shaft and said pistons at stop positions, respectively returning presetting positions of said pistons, controlling return speed without counter balance valves.
  • 7. The actuation module of claim 1, said body assembly further at least one vane assembly, said vane assembly having a vane having a land, vane cover and key, said vane cover having a link port, said land having an outward slot and an inward slot, said shaft has a keyway, said vane is disposed between a left side of said body and said left piston and covered by said vane cover, a first chamber and a second chamber are defined by said piston and said vane cover and said vane land, said first chamber is connected to said link port, a second chamber is connected to said center chamber through said inward slot and said axial port and said radial port and gaps between said shaft and said left piston, said vane is coupled with said shaft by said key and said keyway of said shaft for driving said shaft.
  • 8. An actuation module comprising; (a) At least one body assembly having a body;(b) At least one shaft assembly having a shaft;(c) A least one conversion-transmission assembly having one of configurations including; (c1) A conversion-transmission assembly positioned between said shaft assembly and said body assembly having a helical movement converting mechanism and a movable piston, said helical movement converting mechanism including a helical engagement for providing conversions between reciprocal movements and rotary movements and a reactionary engagement for generating reactionary torques, said helical movement converting mechanism is defined by one of a plurality of arrangements inducing said helical engagement between said piston and said shaft, and said reactionary engagement between said piston and said body, said body has a front cylindrical bore defined by a fixed, centric axis and a back cylindrical bore defined by a fixed eccentric axis, parallel to said fixed centric axis, said piston has two mated cylindrical sections engaged respectively with said front centric bore and said back eccentric bore of said body for providing said reactionary engagement, said helical movement converting mechanism is defined by one of a plurality of structures including a helix spline/helix spline structure and a helix spline/non-helix spline structure, said shaft has helical splines, said piston has mated helical splines engaged with said helical splines of said shaft for providing said helical engagement, whereby said body, said piston and said shaft having a conversion means for providing conversions between reciprocal movements of said piston and rotatory movements of said shaft, and a non-friction reaction means for generating reactionary compression forces with said axises against said shaft;(c2) Said conversion-transmission assembly positioned between said shaft assembly and said body assembly having helical movement converting mechanisms, a right movable piston and a left movable piston, said helical movement converting mechanism including a helical engagement for providing conversions between reciprocal movements and rotary movements and a reactionary engagement for generating reactionary torques, said helical movement mechanism is defined by one of a plurality of arrangements inducing said helical engagement between said pistons and said shaft, and said reactionary engagement between said pistons and said body, said body has a right, cylindrical bore and at least one middle cylindrical bore respectively defined by a fixed centric axis, a fixed eccentric axis parallel to said fixed centric axis and a left cylindrical bore and said middle cylindrical bore respectively defined by said fixed centric axis and said fixed eccentric axis, said right piston has two mated cylindrical sections engaged respectively with said right bore and said middle bore of said body for providing said reactionary engagement, said left piston has two mated cylindrical sections engaged respectively with said left bore and said middle bore of said body for providing said reactionary engagement, said helical movement converting mechanism is defined by one of a plurality of structures including a helix spline/helix spline structure, and a helix spline/non-helix spline structure, said shaft has right helical splines and left helical splines, said right piston has mated right helical splines engaged with said right helical splines of said shaft for providing said helical engagement, said left piston has mated left helical splines engaged with said left helical splines of said shaft for providing said helical engagement, whereby said body, said pistons and said shaft having a conversion means for providing conversions between reciprocal movements of said pistons and rotatory movements of said shaft, and a non-friction reaction means for generating reactionary compression forces with said axises against said shaft and a balance means for balancing side loads on said left helical splines of said shaft engaged with said right piston, with side forces on said left helical splines on said shaft engaged with said right piston.
  • 9. The actuation module of claim 9, wherein said module having a porting system having one of a plurality of arrangements including (a) a body porting (b) a shaft porting (c) a hybrid porting; (a) Said body porting including a port 1 and a port 2 and a right groove of said right bore and a left groove of said left bore on said body, said port 1 is on an external surface of said body expanding respectively to said right groove on said right bore and said left groove on said right bore of said body, said right groove connecting to a right chamber with an outward surface of said right piston, said left groove connecting to a left chamber with an outward surface of said left piston, said port 2 is through a wall of said body into a middle chamber with an inward surface of said left piston and an inward surface of said right piston;(b) Said shaft porting including an axial port 3 and an axial port 4 on said shaft, said body having a right groove of said right bore and a left groove of said left bore, said port 3 is expending to a right radial hole to connect to said right groove into a right chamber with an outward surface of said right piston and a left radial hole to connect to said left groove into a left chamber with an outward surface of said left piston, said port 4 of said shaft is expanding to a middle hole into a middle chamber with an inward surface of said left piston and an inward surface of said right piston;(c) Said hybrid porting including a body porting and a shaft porting, said body porting including a port 1 and a port 2 and a right groove of said right bore and a left groove of said left bore on said body, said port 1 is on an external surface of said body expanding respectively to said right groove and said left groove on said right bore of said body, said right groove connecting to a right chamber with an outward surface of said right piston, said left groove connecting to a left chamber with an outward surface of said left piston, said port 2 is through a wall of said body into a middle chamber with an inward surface of said left piston and an inward surface of said right piston, said shaft porting having an axial port 3 and an axial port 4, said port 3 of said shaft is expending to a right radial hole to connect to said right groove into said right chamber with said inward surface of said right piston and a left radial hole to connect to said left groove into said left chamber with said outward surface of said left piston, said port 4 of said shaft is expanding to a middle hole into said middle chamber with said inward surface of said left piston and said inward surface of said right piston.
  • 10. The actuation module of claim 9, where said body assembly including at least one cover assembly, said cover assembly has a cover, at least one bearing, at least one vertical O-ring and at least one horizontal O-ring, said bearing is defined by one of a plurality of profiles including a spherical profile and a conical prolife, said body having an edge on said right bore, said edge is defined by a mated external surface engaged with said conical bearing, said cover is defined by an internal mated surface engaged with said conical bearing, a vertical O-ring groove and a horizontal O-ring groove are respectively defined between said edge and said cover, said vertical O-ring and is disposed in said vertical groove, said horizontal O-ring is placed in said horizontal groove, whereby said cover assembly, said shaft and said body having a sealing means for providing seals between said body and said cover at any installed position under loads, and a bearing means for supporting loads at any installed position.
  • 11. An actuation module comprising; (a) A body assembly having a body;(b) A shaft assembly having a shaft;(c) A conversion-transmission assembly positioned between said shaft assembly and said body assembly having helical movement converting mechanisms, a right movable piston and a left movable piston, said helical movement converting mechanism including a helical engagement for providing conversions between reciprocal movements and rotary movements and a reactionary engagement for generating reactionary torques, said helical movement mechanism is defined by one of a plurality of arrangements inducing said helical engagement between said pistons and said shaft, and said reactionary engagement between said pistons and said body, said body has a right, cylindrical bore and at least one middle cylindrical bore respectively defined by a fixed centric axis, a fixed eccentric axis parallel to said fixed centric axis and a left cylindrical bore and said middle cylindrical bore respectively defined by said fixed centric axis and said fixed eccentric axis, said right piston has two mated cylindrical sections engaged respectively with said right bore and said middle bore of said body for providing said reactionary engagement, said left piston has two mated cylindrical sections engaged respectively with said left bore and said middle bore of said body for providing said reactionary engagement, said helical movement converting mechanism is defined by one of a plurality of structures including a helix spline/helix spline structure, and a helix spline/non-helix spline structure, said shaft has right helical splines and left helical splines, said right piston has mated right helical splines engaged with said right helical splines of said shaft for providing said helical engagement, said left piston has mated left helical splines engaged with said left helical splines of said shaft for providing said helical engagement, whereby said body, said pistons and said shaft having a conversion means for providing conversions between reciprocal movements of said pistons and rotatory movements of said shaft, and a non-friction reaction means for generating reactionary compression forces with said axises against said shaft and a balance means for balancing side loads on said left helical splines of said shaft engaged with said right piston, with side forces on said left helical splines on said shaft engaged with said right piston.(d) A porting system including a port 1 and a port 2 and a right groove of said right bore and a left groove of said left bore on said body, said port 1 is expanding respectively to said right groove on said right bore and said left groove on said right bore of said body, said right groove connecting to a right chamber with an outward surface of said right piston, said left groove connecting to a left chamber with an outward surface of said left piston, said port 2 is through a wall of said body into a middle chamber with an inward surface of said left piston and an inward surface of said right piston;(e) A spring assembly including a right set spring against said right piston and a left set spring against said left piston, whereby said body, said pistons and said shaft assembly, said spring assembly having a spring means for eliminating backlash between said pistons and said shaft, preventing hard hits between said shaft and said pistons at stop positions, respectively returning presetting positions of said pistons, controlling return speed without counter balance valves.(f) A position control assembly having a left screw threaded into a left side of said body assembly for controlling outward positions of said left piston, a right screw threaded into a right side of said body assembly for controlling outward positions of said right piston, at least one middle screw threaded in said body having a conical end to control inward positions of said left piston and inward positions of said right piston.
CROSS-REFERENCE TO RELATED APPLICATION

This is a division of application Ser. No. US 2012/0079901 A1 filed on Sep. 15, 2011 by Jianchao Shu, now pending to be allowed.

Divisions (1)
Number Date Country
Parent 13200002 Sep 2011 US
Child 15249345 US