Hydraulic compression tool and hydraulic compression tool motor

Information

  • Patent Grant
  • 6668613
  • Patent Number
    6,668,613
  • Date Filed
    Tuesday, April 9, 2002
    22 years ago
  • Date Issued
    Tuesday, December 30, 2003
    21 years ago
Abstract
A transmission for connecting a rotary motor output shaft to a rectilinear actuator which is moveable rectilinearly along an actuator axis of translation. The transmission comprises a frame, an eccentric, and a rectilinear guide. The frame has a bore formed therein. The eccentric is adapted to position the frame on the rotary motor output shaft. The eccentric is rotatably mounted in the bore of the frame to rotate relative to the frame. The rectilinear guide is connected to the frame. The rectilinear guide has a slide surface adapted to be slidably seated against the rectilinear actuator allowing the frame to slide substantially rectilinearly relative to the rectilinear actuator. While this drive is especially suited for use on a hydraulic crimping tool, the drive is also suited for use with any kind of hydraulic power tool.
Description




BACKGROUND OF THE INVENTION




1. Field of the Invention




The present invention generally relates to hydraulic compression tools and, more particularly, to drives for hydraulic compression tools having rotary motors.




2. Brief Description of Earlier Developments




Hydraulic power tools are used in numerous applications to provide users with a desired mechanical advantage. One such application is in crimping tools used for making crimping connections, such as for example, crimping power connectors onto conductors, or grounding connectors onto grounding wires. Other applications include jacking devices, presses and so on. In these cases, many operators desire that the hydraulic tools be powered, or in other words that the hydraulics be actuated by a motor merely at the flip of a switch or the press of a button. Naturally, a powered hydraulic tool does away with manual pumping by the operator to actuate the hydraulics, and hence, involves much less physical effort on the part of the operator to operate the tool. In addition to the significantly smaller physical effort, another desired advantage of the powered hydraulic tool compared to manual hydraulic tools, is that the powered tool may be faster. This allows tasks to be accomplished with the tool to be completed faster with a resulting reduction in cost. Indeed, for portable hydraulic tools, such as for example, hydraulic crimping tools, which are held and supported in the hands of the operator, the operating speed (e.g. how quickly the hydraulic ram is traversed through its stroke) of the tool becomes even more important. The quicker the task can be completed, the sooner the operator can put the tool down. Powered hydraulic tools are more complex, and hence more expensive as a rule, than their manually actuated counterparts. The added complexity may also tend to make powered hydraulic tools more susceptible to breakdown. This may be frustrating to the operator, as well as costly especially for tools used in the field where repair may not be readily available. Conventional powered hydraulic tools which employ a piston pump to operate the hydraulics generally may have a spring loaded piston to provide impetus to the piston in at least one direction and/or a camming mechanism capable of reciprocating the piston during operation.




U.S. Pat. No. 6,206,663 discloses one example of a piston pump for a hydraulic tool wherein the pump has a low-pressure delivery piston which is spring loaded to drive the piston to achieve fluid delivery at low pressure. The low pressure piston is moved back counter to the spring load prestress by a high pressure piston moved by a rotating shaft.




Another example is disclosed in U.S. Pat. No. 5,727,417 in which the hydraulic drive tool has a drive assembly with a wobble plate providing axial displacement to a spring loaded piston. The spring preload on the pistons returns the pistons to a fluid delivery starting position. Still other examples are disclosed in U.S. Pat. Nos. 5,111,681 and 5,195,354 in which a motor driven hydraulic tool has a motor operatively connected to a hydraulic pump via a cam link mechanism. The cam link mechanism has a plunger with a ring shaped fitting portion which has an eccentric shaft fitted therein to rotate freely.




The present invention overcomes the problems of conventional hydraulic tools as will be described in greater detail below. In accordance with one aspect of a preferred embodiment, the piston pump is springless, reciprocated by a cam link mechanism to the motor without assistance from spring preload. Moreover, in accordance with another aspect of the preferred embodiment, the cam link mechanism between the motor and piston is simple to manufacture and install, employing large bearing surfaces which reduces the cost of the tool while increasing reliability. These aspects as well as others will be described in greater detail below.




SUMMARY OF THE INVENTION




In accordance with a first embodiment of the present invention, a hydraulic tool drive is provided. The hydraulic tool drive comprises a frame, a hydraulic ram, a pump, a motor, and a link. The frame has a hydraulic reservoir. The hydraulic ram is movably mounted to the frame. The pump has a pump piston for pumping hydraulic fluid to move the hydraulic ram relative to the frame. The motor is connected to the frame. The motor has an output shaft which rotates about an axis of rotation when the motor is operating. The link operably connects the output shaft to the pump piston for generating a reciprocating movement of the pump piston relative to the pump when the motor is operated. The link is rotatably mounted on the output shaft and is pivotable at least at one end relative to the frame, wherein at least one end of the link is pivotally connected to the pump piston by a pin.




In accordance with another embodiment of the present invention, a hydraulic tool drive is provided. The tool drive comprises a frame, a hydraulic ram, a pump, a motor, and a collar. The frame has a hydraulic reservoir. The hydraulic ram is moveably mounted to the frame. The pump is connected to the frame. The pump has a pump piston for pumping hydraulic fluid to move the hydraulic ram relative to the frame. The pump piston is moveable relative to the pump along an axis of translation. The motor is connected to the frame. The motor has a rotary output shaft. The collar is connected to the rotary output shaft and has a joint at which the collar is moveably joined to the pump piston to move relative to the pump piston along another axis of translation which is substantially orthogonal to the axis of translation of the pump piston, wherein the collar comprise a frame with a generally cylindrical bore in which the rotary output shaft is eccentrically located, the frame having a clevis at one end which forms the joint in the collar.




In accordance with another embodiment of the present invention, a hydraulic tool drive is provided. The tool drive comprises a frame, a hydraulic ram, a pump, a motor, and a collar. The frame has a hydraulic reservoir. The hydraulic ram is moveably mounted to the frame. The pump is connected to the frame. The pump has a pump piston for pumping hydraulic fluid to move the hydraulic ram relative to the frame. The pump piston is moveable relative to the pump along an axis of translation. The motor is connected to the frame. The motor has a rotary output shaft. The collar is connected to the rotary output shaft and has a joint at which the collar is moveably joined to the pump piston to move relative to the pump piston along another axis of translation which is substantially orthogonal to the axis of translation of the pump piston, wherein the drive further comprises an eccentric fixedly mounted to the rotary output shaft, the eccentric being engaged to the collar so that when the motor rotates the rotary output shaft the collar is moved in an orbital motion relative to the output shaft.




In accordance with still another embodiment of the present invention, a hydraulic crimping tool is provided. The tool comprises a frame, a hydraulic ram, a pump, a motor, and a transmission. The frame has a hydraulic reservoir. The hydraulic ram is movably mounted to the frame. The pump is connected to the frame. The pump has a pump piston for hydraulically moving the hydraulic ram relative to the frame. The motor is connected to the frame. The motor has a rotary output shaft to the pump piston. The transmission comprises an eccentric. The eccentric is fixable mounted onto the rotary output shaft. The transmission comprises a collar rotatable mounted onto the eccentric to rotate relative to the eccentric. The collar is movably joined to the pump piston, wherein the collar has a clevis, the pump piston being pinned to the collar in the clevis.




In accordance with yet another embodiment of the present invention, a transmission for connecting a rotary motor output shaft to a rectilinear actuator which is movable rectilinearly along an actuator axis of translation is provided. The transmission comprises a frame, an eccentric, and a rectilinear guide. The frame has a bore formed therein. The eccentric is adapted to position the frame on the rotary motor output shaft. The eccentric is rotatably mounted in the bore of the frame to rotate relative to the frame. The rectilinear guide is connected to the frame. The rectilinear guide has a slide surface adapted to slidably seat against the rectilinear actuator allowing the frame to slide substantially rectilinearly relative to the rectilinear actuator, wherein the frame has a recess formed therein, the recess being sized and shaped for movably locating at least part of the rectilinear actuator in the recess, the rectilinear guide extending across the recess.




In accordance with a further embodiment of the present invention, a hydraulic tool drive is provided. The hydraulic tool drive comprises a frame, a hydraulic ram, a pump, a motor, and a link. The frame has a hydraulic reservoir. The hydraulic ram is movably mounted to the frame. The pump has a pump piston for pumping hydraulic fluid to move the hydraulic ram relative to the frame. The motor is connected to the frame. The motor has an output shaft which rotates about an axis of rotation when the motor is operating. The link operably connects the output shaft to the pump piston for generating a reciprocating movement of the pump piston relative to the pump when the motor is operated. The link is rotatably mounted on the output shaft and is pivotable at least at one end relative to the frame, wherein the link has an end which is movably mounted to the pump piston so that the link moves freely relative to the pump piston.




In accordance with another embodiment of the present invention, a hydraulic tool drive is provided. The hydraulic tool drive comprises a frame, a hydraulic ram, a pump, a motor, and a link. The frame has a hydraulic reservoir. The hydraulic ram is movably mounted to the frame. The pump has a pump piston for pumping hydraulic fluid to move the hydraulic ram relative to the frame. The motor is connected to the frame. The motor has an output shaft which rotates about an axis of rotation when the motor is operating. The link operably connects the output shaft to the pump piston for generating a reciprocating movement of the pump piston relative to the pump when the motor is operated. The link is rotatably mounted on the output shaft and is pivotable at least at one end relative to the frame, wherein the link has a recess at one end, at least one end of the pump piston being located in the recess.




In accordance with yet another embodiment of the present invention, a transmission for connecting a rotary motor output shaft to a rectilinear actuator which is movable rectilinearly along an actuator axis of translation is provided. The transmission comprises a frame, an eccentric, and a rectilinear guide. The frame has a bore formed therein. The eccentric is adapted to position the frame on the rotary motor output shaft. The eccentric is rotatably mounted in the bore of the frame to rotate relative to the frame. The rectilinear guide is connected to the frame. The rectilinear guide has a slide surface adapted to slidably seat against the rectilinear actuator allowing the frame to slide substantially rectilinearly relative to the rectilinear actuator, wherein the rectilinear guide comprises a pin, an outer surface of the pin forming the slide surface.











BRIEF DESCRIPTION OF THE DRAWINGS




The foregoing aspects and other features of the present invention are explained in the following description, taken in connection with the accompanying drawings, wherein:





FIGS. 1-1A

respectively are a schematic view of a hydraulic compression tool and perspective view of part of the tool incorporating features in accordance with one embodiment of the present invention;





FIG. 2

is a cross-sectional elevation of a head section and pump body of the hydraulic compression tool in

FIG. 1

;





FIG. 3

is a perspective view of motor and handle portion of the hydraulic compression tool seen from a direction opposite to the direction of the view in

FIG. 1

;





FIG. 4

is a partial cross-sectional elevation view of the pump body and a power transmission of the hydraulic compression tool in

FIG. 1

; and





FIG. 5

is a perspective view of a portion of the housing for the power transmission of the hydraulic compression tool in FIG.


1


.











DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT




Referring to

FIG. 1

, there is shown a schematic view of a drive


100


used with hydraulic tool


10


incorporating features of the present invention. Although the present invention will be described with reference to the single exemplary embodiment shown in the drawings, it should be understood that the present invention can be embodied in many alternate forms of embodiments. In addition, any suitable size, shape or type of elements or materials could be used.




The present invention is described below with particular reference to a portable hydraulic tool


10


and the drive therefor, though the invention is equally applicable to any suitable type of hydraulic power tool. Referring also to

FIGS. 1A-2

, which show a partial perspective view and cross-sectional elevation view of the hydraulic crimping tool


10


, the tool generally comprises a head section


12


, a hydraulic power section


14


, a motor section


100


, and a handle


4


. The head section


12


is connected to the hydraulic power section


14


. The motor section


100


is connected to the hydraulic power section


14


generally opposite the head section. The handle section, used by the operator to support and position the tool, may extend from the hydraulic power section, also generally opposite the head section, and may incorporate the motor section at least in part. The head section generally has a static or anvil adapter


16


and movable adapter


18


. The anvil adapter


16


is located at one end of the head section. The movable adapter


18


is movably seated in the head section. The hydraulic power section


14


generally has a hydraulic cylinder


20


, a ram assembly


22


, and a pump body


24


. The ram assembly


22


is located in the cylinder


20


and is connected to the movable adapter


18


in the head section. The pump body


24


is connected to the hydraulic cylinder


20


. The hydraulic power section


14


has a pump


26


(see also

FIG. 2

) located in the pump body for pumping hydraulic fluid through the pump body into the hydraulic cylinder. The handle may include a reservoir


27


(see

FIG. 2

) for hydraulic fluid used in the hydraulic power section. The motor section


100


generally has a suitable electromechanical motor


102


having an EMF shield


103


covering the brush portion thereof and which powers a drive shaft


104


(in phantom). Drive shaft


104


and motor


102


are connected to transmission linkage


106


via gearbox


105


and adaptor plate


102




a.


The drive shaft


104


is connected by transmission linkage


106


to the pump


26


. When the pump


26


is operated by the motor


102


, hydraulic fluid from reservoir


27


is pumped through the pump body


24


to the hydraulic cylinder


20


and the ram assembly


22


therein. Hydraulic fluid presses against ram assembly


22


thereby advancing the ram


30


or assembly


22


, and the movable adapter


18


, connected to the ram


30


, towards the anvil


16


. The transmission linkage


106


connecting the drive shaft


104


in the motor section


100


and the pump


26


converts rotary motion of the drive shaft into rectilinear reciprocating translation of the pump as will be described in greater detail below.




One embodiment of the hydraulic tool will be described in detail below with specific reference to the crimping tool


10


shown in

FIG. 1

, although as noted before the present invention is equally applicable to any suitable kind of hydraulic power tool. As seen best in

FIGS. 1-2

, in this embodiment, the head section


12


of the tool


10


generally has a base or collar section


42


for connecting the head section to the rest of the tool, and an upper section


44


. The upper section


44


depends from the collar section


42


. The head section


12


may be a one piece member made from suitable metal by drop forging or casting, or alternatively the section may be an assembly of independently manufactured parts. The upper section


44


may have a general scallop or general C shape, as shown in

FIG. 1A

, which defines a workspace


48


in the head section


12


. In alternate embodiments, the head section structure may have any other suitable configuration providing a workspace in which work pieces may be placed into the head section. The upper section


44


has a longitudinal portion


45


, which forms the back or spine of the C shape, and an upper end


46


. The longitudinal portion


45


may be a space frame with inner and outer walls


50


,


52


tied to each other by truss supports and curved beam end portions. The truss supports are arranged to form a series of voids in the longitudinal portion


45


which significantly reduces the weight of the head section


12


without loss in structural strength and rigidity. Reinforcing ribs


60


may be formed alongside the inner wall


50


, as shown in

FIG. 1A

, in order to further increase the rigidity of the head section


12


.




As can be realized from

FIG. 1A

, upper end


46


of section


44


is generally curved and forms the anvil adapter


16


at the top of the workspace


48


in the head section. As seen in

FIG. 1A

, in the preferred embodiment, a bore


63


is formed through the upper end


46


to the seating surface


62


of the anvil adapter


16


for mounting a die (not shown) to the anvil adapter. The curved seating surface


62


may provide a working surface against which work pieces having a round outer surface with a diameter complementing surface


62


may be seated. In the case where the work piece does not have a round outer surface which complements surface


62


, a die may be mounted using bore


63


to the anvil adapter allowing the work piece to be stably supported from the anvil adapter. The anvil adapter


16


has outer and inner stop surfaces


64


,


66


which stop the travel of the movable adapter


18


in the work space


48


(see FIG.


1


A). The inner surface


32


of the inner wall


50


is substantially flat, as seen in

FIG. 1A

, and provides a guide surface to adapter


18


as will be described below. As seen in

FIG. 1A

, in this embodiment the collar section


42


has a generally cylindrical shape with a cylindrical bore


74


(See

FIG. 2

) formed therein. In alternate embodiments, the base section of the head section may have any other suitable shape for mating the head section to the hydraulic power section


14


of the tool. In the preferred embodiment, the cylindrical collar section


42


has a lower part


76


and an upper part


78


. Similar to the exterior of the collar section, the bore


74


also has a lower portion


74


L, located in the lower part


76


of the collar, and an upper portion


74


U located in the upper part


78


. The lower portion


74


L is threaded to engage the threaded upper end of the power section


14


. The upper portion


74


U of the bore is sized to form a close running fit with the ram


30


in the hydraulic power unit. The inner surface


84


is substantially smooth and forms a bearing surface for ram


30


as will be described in greater detail below. An annular groove


85


is formed into inner surface


84


for a wiper seal


86


or O-ring.




The movable adapter


18


is preferably a one-piece member which may be cast, forged, or fabricated in any other suitable manner. The movable adapter


18


has an upper or working end


90


which faces towards the anvil adapter


16


at the top of the workspace


48


when the movable adapter is mounted in the head section


12


. The lower end


94


of the movable adapter may have a flat seating surface with may a projecting boss


92


to radially interlock adapter


18


to piston


30


and a fastener may be used to secure the adapter to the ram


30


. As seen in

FIGS. 1A-2

, the body of the movable adapter


18


between the upper and lower ends


90


,


94


has a flat face


98


positioned towards the inner surface


32


when the adapter is installed into the head section


12


. The flat face


98


is seated substantially flush against the inner surface


32


of the longitudinal portion


45


of the head section


12


. As can be realized from

FIGS. 1A-2

, the interface between the flat inner surface


32


and the flat face


98


of the movable adapter, maintains the movable adapter


18


generally aligned with the anvil


16


and prevents any rotation of the movable adapter


18


as it is advanced by the ram


30


towards the anvil


16


.




Referring now again to

FIG. 2

, the hydraulic power section


14


which is mated to the collar section


42


of the head section


12


has a housing


15


which includes both the hydraulic cylinder


20


and the pump body


24


. As noted before, the hydraulic power section


14


also has ram assembly


22


, though the hydraulic power section may use any suitable ram. The ram assembly


22


is movably mounted to the housing


15


. As shown in

FIG. 2

, ram assembly


22


generally comprises outer ram


30


, spring


300


, spring holder


302


and rapid advance ram actuator


28


. The spring holder


302


may be an elongated, one-piece member having a generally cylindrical shape. The holder


302


may have an end


304


, with a threaded portion or other means for fixedly mounting the holder into the housing


15


. The holder


302


also has a main section


308


with an external radial flange


312


projecting outwards. The flange


312


has a spring support surface


316


facing the threaded end


304


of the holder and ram seating surface


314


located on the flange opposite the support surface


316


(see FIG.


2


). As seen in

FIG. 2

, the spring holder


302


has a chamber


320


formed into the main section


308


. The chamber


320


forms a hydraulic cylinder for the rapid advance actuator


28


. The opening of the chamber


320


is located in the flanged end of the holder. The spring holder


302


also has a hydraulic fluid passage


326


which communicates with chamber


320


as seen in FIG.


2


. The spring


300


in the ram assembly


22


may be a helically wound coil spring.




As shown in

FIG. 2

, the rapid advance ram actuator


28


generally includes an actuator body, spring loaded ball valve


330


and set screw. The body of the actuator


28


has a diameter sized to form a close sliding fit within chamber


320


in the spring holder


302


. The length of the actuator body is sufficient to advance the outer ram


30


through the full range of ram travel allowed by hydraulic cylinder


20


. The exterior of the body may have one or more O-ring grooves for O-rings


338


(only one is shown in

FIG. 2

) which form a hydraulic seal between the actuator


28


and chamber


320


in the spring holder


302


. As seen in

FIG. 2

, in this embodiment the actuator body has a hydraulic fluid passage


332


extending through the body allowing fluid to pass through the actuator to the ram


30


. The passage


332


includes an expanded chamber with an appropriate seat for the spring loaded check valve


330


. The passage terminates in a threaded hole for the set screw used to set the pressure at which the valve


330


opens. The ram


30


has an upper shaft section


344


, and an enlarged lower piston section


346


. The piston section


346


is sized and is provided with one or more O-rings


357


(only one is shown in

FIG. 2

for example purposes) to form a hydraulic seal between the piston


346


and cylinder


20


. The upper shaft section


344


of ram


30


is sized to form a close sliding fit with the upper portion


74


U of the bore in the collar section


42


. The upper end of the shaft section


344


provides a mating surface for mounting movable adapter


18


. The outer ram


30


has an inner chamber


356


formed therein. The opening of the inner chamber is at the rear end


354


of the ram


30


. The length of the inner chamber


356


is sufficient to admit the main section


308


of the spring holder


302


therein when the ram


30


is fully retracted as shown in FIG.


2


. As can be realized from

FIG. 2

, the surface of the chamber


356


is part of the hydraulic fluid contact surface


352


of the ram


30


.




The ram assembly


22


may be assembled by inserting the rapid advance actuator


28


into the chamber


320


of the spring holder


302


, then inserting the holder


302


, and spring


300


into chamber


356


of ram


30


and mounting retention ring


301


into the chamber. The retention ring


301


, which may be mounted into a groove in the chamber


356


, holds the spring


300


, spring holder


302


and actuator


28


inside the ram


30


. The ram assembly


22


may them be installed into the housing


15


.




Still referring now to

FIGS. 1A-2

, the housing


15


of the power section


14


is preferably a one-piece member which as noted before includes the hydraulic cylinder


20


and the pump body


24


. In alternate embodiments the power section may have a housing assembly comprising a number of housing parts. As seen in

FIG. 2

, the hydraulic cylinder


20


is located in the upper portion of the housing


15


. The annular flange


80


in the head section forms the upper end of the cylinder. The length of the cylinder is such that the ram


30


is provided with sufficient travel to advance the movable adapter


18


from the retracted position shown in

FIG. 2

to a position (not shown) abutting the stops


64


,


66


of the anvil


16


. The housing


15


has a bore


262


opening into the bottom of the hydraulic cylinder


20


for mounting the spring holder


302


, and hence the ram assembly


22


into the housing. The pump body


24


of housing


15


includes a hydraulic fluid conduit system


25


connecting the hydraulic cylinder


20


to the fluid reservoir


27


. The pump


26


is located in the conduit system


25


. The pump


26


is shown as being a one stage piston pump, although multi-stage pumps may be used equally well with the present invention. The conduit system


25


in pump body


14


shown in

FIG. 2

is merely an example of a suitable conduit system, and the hydraulic tool may use any other suitable conduit system. The conduit system


25


may have a suction conduit


210


and a supply conduit


212


. The conduit system


25


may also have a drain or return conduit


214


. The suction conduit


210


may extend between the reservoir


27


and the hydraulic chamber


20


. The suction conduit supplies hydraulic fluid to the hydraulic chamber to allow free movement to the ram


30


when advanced by the ram actuator


28


. The suction conduit


210


may have a check valve (not shown) which is closed by fluid pressure in the hydraulic cylinder. The suction conduit


210


also supplies fluid to the supply conduit


212


which communicates with suction conduit


210


. The supply conduit


212


may have a check valve (not shown) to prevent reverse flow from the supply conduit into the suction conduit when the supply conduit is pressurized by the pump


26


. The supply conduit has pump chamber or bore


222


for pump


26


. Downstream of pump chamber


222


, and hence pump


26


, the supply conduit


212


has a check valve


224


which prevents reverse flow in the conduit


212


when the pump


26


is in the suction stroke. Downstream of valve


224


, the supply conduit


212


is routed to its discharge port in the bottom of bore


262


. Thus, supply conduit


212


supplies hydraulic fluid to the chamber


320


to advance the actuator


28


in the spring holder


302


, and when valve


330


is opened by ram


30


meeting resistance, the conduit supplies fluid into chamber


20


. The supply conduit


212


also communicates with the drain conduit


214


to allow drainage of fluid from the supply conduit as well as the actuator chamber


120


in the spring holder


102


. In addition, a portion of the drain conduit


214


extends between the bottom of the hydraulic chamber


20


and the reservoir


27


thereby allowing fluid to drain from the hydraulic cylinder. The conduit


214


may have check valves (not shown) which close when fluid is pumped in the supply conduit


212


. The drain conduit


214


may also include a pressure sensing valve


228


which opens to drain the supply conduit


212


when an over pressure is sensed in the supply conduit or hydraulic chamber. The drain conduit


214


includes a plunger actuated valve


230


which when activated allows the supply conduit


212


, actuator chamber


320


and hydraulic chamber


20


to drain through conduit


214


into the reservoir


27


.




As noted before, the pump


26


is powered by the motor


102


in the motor section


100


. Referring now also to

FIG. 3

which is a perspective view looking from front to rear, of the motor section


100


of the tool, the motor section


100


generally has a housing


101


enclosing the gear box


105


, a motor


102


with a drive shaft


104


, and a transmission linkage


106


(see FIG.


3


). As seen in

FIGS. 1A and 3

, the housing has a rear section


101


R and a front portion


101


F. The rear housing portion


101


R houses the motor


102


, drive shaft


104


(See

FIG. 3

) for connection with a source of electricity via terminals


100


B. The front housing portion


101


F connects the motor section


100


to the housing


15


and houses the transmission linkage


106


between the drive shaft


104


and pump


26


. The rear housing portion


101


R is shown in

FIGS. 1A and 3

as having a generally cylindrical shape, though in alternate embodiments the housing may have any suitable shape. The housings are configured to support the motor


102


therein and may include suitable brackets (not shown) for mounting the motor casing to the housing.




As seen in

FIG. 1A

, the front portion


101


F of the housing


101


preferably includes a support plate


120


, and a cover


122


. In alternate embodiments, the front portion of the housing may have any other suitable configuration. The support plate


120


is at the rear and the cover


122


is at the front. The cover


122


may be removably mounted to both the support plate


120


and housing


15


as will be described in greater detail below. As seen best in

FIG. 3

, the support plate


120


may be is a substantially flat plate member which may be stamped from sheet metal or cut from plastic sheets. The support plate


120


may include a cutout


123


complementing the exterior of the pump body


24


. The support plate


120


may also have a number of fastener holes


124


for fasteners used to mount the cover


122


to the plate


120


. As can be realized, a bore (not shown) is formed into the plate


120


to allow output shaft


104


to extend through the plate. The support plate


120


may be attached to the front end


118


of the gear box


105


by any suitable means such as welding, brazing, or bonding using adhesives or fasteners. The front cover


122


is seen best in FIG.


5


. The cover may be a one-piece member made of metal which is cast or drop-forged, or otherwise may be made of plastic by injection molding for example. Further, the support plate


120


and cover


122


could be fabricated as a single piece instead of two separate components. The cover


122


has an end wall


126


surrounded on three sides by peripheral wall


128


. The peripheral wall


128


has a general U-shape. As seen in

FIG. 5

, at the ends


130


the wall


128


flares outward defining attachment pads


132


for attaching the cover


122


to the pump body


24


. The attachment pads


132


have curved seating surfaces


133


conforming to the curvature of the exterior of the pump body


24


. Fastener holes


134


are formed through the pads for mechanical fasteners (not shown) such as for example machine screws used to attach the cover


122


to the pump body. The peripheral wall


128


has a rear seating surface


135


for seating against the support plate


120


. The seating surface may be substantially flat or may be provided with a groove for a seal gasket (not shown) to be placed between the cover and support plate at mounting. Longitudinal fastener holes


136


are included in the peripheral wall


128


corresponding to fastener holes


124


in the support plate


120


. End wall


126


has a bore


138


used to mount an end bearing (not shown) supporting the front end


105


of the output shaft


104


(see FIG.


3


). A bearing (not shown) may be installed into bore


138


to close the front of the bore. The end wall


126


and peripheral wall


128


form a chamber


140


sufficiently deep to accommodate the transmission linkage


106


inside the chamber. Bore


138


is located in end wall


126


so that when the cover


122


is mounted to support plate


120


, the bore


138


is aligned with the output shaft


104


.




The motor


102


is preferably a single speed DC motor, although any suitable electro-mechanical motor may be used including an AC motor. An example of a suitable motor is an 18V DC Mabuchi motor, model RS-775 WC.8514. An advantage of the DC motor is that it may be readily powered using conventional batteries. A suitable reduction gear box


105


is mated to the drive shaft of the motor


102


. For example, in the event the rotary speed of the motor drive shaft is higher than the desired rotary speed of the output shaft


104


at the transmission


106


, the reduction gear box couples the motor shaft to the output shaft


104


such that the output shaft


104


would be coupled to an output end of the reduction gear. The reduction gear box may be of any suitable type such as for example, a planetary reduction gear rated for the rotary speed and torque of the motor. The reduction ratio across the reduction gear may be any suitable ratio to provide the output shaft


104


with a desired rotary speed. As noted before, the output shaft


104


may extend from the motor


102


, or in the case a reduction gear is used, from the output end of the gear to the transmission linkage


106


. The output shaft


104


may be solid or hollow, and may be made from metal such as for example steel or aluminum alloy, or from non-metallic materials such as plastic having adequate stiffness and strength to withstand the forces and torques which the shaft is subjected. As seen in

FIG. 3

, the output shaft


104


has a key


142


or other suitable interlocking features such as for example radial splines, or teeth with which to engage and transfer torque to a mating component. The output shaft


104


is supported by suitable bushings or bearings (not shown) to support torque and pump loads on the shaft. The output shaft


104


protrudes from plate


120


sufficiently for the front end


105


of the shaft to be rotatably supported in the bore


138


of the end wall


126


(See FIG.


5


). The portion of the output shaft


104


extending in chamber


142


formed between the support plate


120


and end wall


126


in the front housing section


101


F provides a mounting surface for the transmission linkage


106


.




Referring now to

FIGS. 3 and 4

, the transmission linkage


106


generally includes eccentric


144


, bearing


146


, collar link


148


and slider mechanism


150


. The eccentric


144


and bearing


146


are used to rotatably mount the collar link


148


on the output shaft


104


, and the slider mechanism


150


is used to connect the collar link


148


to the pump


26


as will be described in greater detail below. The eccentric


144


is preferably a one-piece member which may be forged or machined from metal such as for example aluminum alloy. In alternate embodiments with low force environments, the eccentric may be made from non-metallic material such as plastic, ceramic or composite material having sufficient compression strength to withstand compression loads between the output shaft and collar link. As will be described further below, the mounting configuration of the eccentric


144


on the shaft


104


and in the collar link results in the compression loads between the collar link and shaft, during operation of the tool


10


, being distributed over a wide area. The eccentric


144


has a substantially circular outer surface


152


. The center of the outer surface


152


is located at location C


2


in the position shown in FIG.


4


. The eccentric


144


has a substantially circular inner bore


154


with the center located at location C


1


in the position shown in FIG.


4


. As can be realized from

FIG. 4

, the circular inner bore


154


is eccentric relative to the circular outer surface


152


with the corresponding centers (at locations C


1


and C


2


respectively) separated by a distance D. The distance D is about a half of the total stroke of the pump


26


in the pump body


24


. The inner bore


154


in the eccentric is shaped and sized to form a close or light press fit with the output shaft


104


. Accordingly, the inner bore


14


has a keyway


155


which closely conforms to the key


142


of the shaft


104


. The location of the keyway


155


in the eccentric


144


is shown in

FIG. 4

as being substantially in line with the offset D between the center of the inner bore


154


and the center of the outer surface


152


only for example purposes, and in alternate embodiments, the keyway


155


may be positioned anywhere along the surface of the inner bore. The close fit between the inner bore


154


of the eccentric


144


and the output shaft


104


prevents impact or slap between eccentric and shaft operation, thereby preventing impact loads on the shaft and during eccentric, reducing operating noise and increasing pump efficiency.




In the preferred embodiment, the bearing


146


in the transmission linkage


106


is a radial caged needle bearing such as a Torrington® B 1210 bearing. The bearing


146


may be a sealed self lubricating bearing or an open bearing. In alternate embodiments, the bearing


146


may be any other suitable bearing or bushing rated to rotate at a rotational speed of up to about 1300 RPM or more for an indefinite time. The inner race (not shown) of the bearing is sized to form a light force fit with the outer surface


152


of eccentric


144


.




The collar link


148


is preferably a one-piece member although in alternate embodiments, the link may be an assembly of parts. The collar link may be made from metal, such as aluminum alloy by casting, forging or even pressing and sintering, or otherwise may be formed from plastic. In alternate embodiments with low force environments, non-metallic material such as plastic, or ceramic may be used. The collar link may have a main section


156


and a collar section


158


as seen in FIG.


4


. The main section


156


has a substantially circular bore


160


formed therein. The bore


160


has a center which is located at location C


2


when the collar link


148


is positioned as shown in FIG.


4


. The bore


160


is sized to form a light press fit with the outer race (not shown) of bearing


146


. As seen in

FIG. 4

, in the preferred embodiment, two arms


162


depend from the main section


156


at opposite edges of the clevis link and form the clevis section


158


. Also as seen in

FIG. 4

, each arm


162


has a bore


164


formed therethrough. The bores,


164


in each arm are aligned with each other and substantially orthogonal to the bore


160


in the main section


156


. The arms


162


define a recess


166


in between. In the preferred embodiment, the recess


166


is centrally located below


160


, though in alternate embodiments the recess may be offset from the bore.




Still referring to

FIGS. 3 and 4

in the preferred embodiment, the slider mechanism


150


comprises a pin


168


and a sleeve bearing or bushing


170


capable of sliding freely upon the pin


168


. The pin


168


may be an elongated cylindrical member made from metal or plastic. The pin


168


is sized to be inserted through the bores


164


in the arms


162


of the collar link


148


as shown in FIG.


4


. At least a portion


172


of the pin has an outer surface with a surface roughness suitable for sliding bushing


170


back and forth over the pin without damage to the bushing. The outer ends of the pin


168


may form a press fit with the bores


164


in the clevis arms


162


. In addition the outer ends of the pin may have annular grooves (not shown) formed into the outer surface for snap rings


174


used to axially lock the pin into the collar link


148


.




As noted before, the slide mechanism


150


also includes slide bushing


170


. The slide bushing


170


is preferably a one-piece member. The bushing may be made from oil-impregnated bronze material, or from a lubricious plastic or composite material incorporating Teflon™ or from any other surface material. The bushing


170


has a cylindrical bore


176


sized to form a close sliding fit with the sliding portion


172


of the pin. This fit allows for the bushing


170


to slide freely along the pin


168


in the direction indicated by arrow X in

FIG. 4

, as well as rotate freely about the pin in the direction indicated by arrow R


1


in FIG.


3


. The close sliding fit between bushing


170


and pin


168


also ensures that there is no impact or slap between bushing and pin in a direction orthogonal to that indicated by arrow X in FIG.


4


. The exterior of the bushing


170


may have any suitable shape which allows the bushing to be located in recess


166


of the clevis section


158


. The bushing


170


may have an attachment section


174


for fixedly attaching the bushing to the pump


26


. For example, the attachment section


174


may include a post (not shown) which can be inserted into a mating bore in the pump, or conversely a collar (not shown) which may be placed around the pump to fixedly secure the bushings


170


to the pump


26


. The pin


168


and bushing


170


provide a pivotable joint


171


between the collar link


148


and pump


26


.




The transmission link


106


may be assembled and mounted to the output shaft


104


in a number of equally suitable ways, one of which is described below for example purposes. The eccentric


144


may be press fit into the inner race of bearing


146


. The bearing


146


may then be press fit into the bore


160


of the collar link


148


. The pin


168


may be inserted at any suitable time through the bores


164


of the clevis arms


162


securing the bushing in the collar link. The bushing


170


may be attached to the pump


26


before placement into the collar link


148


or after the bushing is secured to the link. After the pin


168


is inserted into the collar link


148


, snap rings


174


may be placed around the pin locking the pin axially in the link. The slip fit between the pin


168


and bores


164


allows the pin to spin in the bores though in alternate embodiments the pin may not be free to spin in the bores. In alternate embodiments, the pin may be staked or pinned to the clevis arms thereby fixing the pin in the link in all directions. The transmission linkage assembly


106


may then be mounted onto the output shaft


104


.




The transmission linkage


106


is mounted onto shaft


104


by sliding the eccentric


144


, which may be already positioned in the collar link as noted before, over the end


105




a


of the shaft


104


. The keyway


155


on the eccentric is aligned with the key


142


on the shaft


104


, and the shaft enters into bore


154


of the eccentric. As can be seen in

FIGS. 3 and 4

, the shaft centerline and axis of rotation of the shaft R is located at location C


1


, the center of the eccentric bore


154


. Hence, the shaft


104


is eccentric to the bore


160


in the collar link


148


, the shaft centerline at C


1


is being offset distance D from the center of bore


160


at C


2


. However, the shaft


104


contacts the surface of bore


154


in the eccentric around the circumference of the eccentric, and the outer surface of the bearing


146


contacts the surface of bore


160


in the collar link


148


around the circumference of the bearing. This allows the shaft


104


with the eccentric


144


thereon to rotate freely relative to the collar link


148


. Though the eccentric


144


is free to spin relative to the collar link


148


, the eccentricity between the axis of rotation R of the shaft


104


at C


1


and the center of the bore


160


at C


2


causes the eccentric to rotate about axis R relative to the collar link while moving the collar link


148


in an orbital motion about axis R. The orbit motion of the collar link


148


about axis R has an orbit radius equal to distance D (see FIG.


4


).




After mounting the transmission linkage


106


in the shaft


104


, the end bearing (not shown) may be placed on end


105




a


of the shaft and the gear box


105


mounted to support plate


123


. The motor section


100


may then be mounted to the housing


15


as shown in FIG.


1


A. In the preferred embodiment, the pump


26


has already been secured to the slide bushing


170


. Accordingly, when the motor section


100


is placed against the housing


15


, the pump


26


is inserted into pump chamber


222


of the pump body


24


. The motor section


100


is then secured by inserting fasteners through the fastener holes


134


of the cover


122


(see

FIG. 5

) into the housing


15


.




After the motor section


100


is mounted to housing


15


, the tool


10


may be operated by energizing the motor


102


. The motor


102


is preferably provided with a control, such as an on/off switch with which the operator controls the motor. When energized, the motor rotates the output shaft


104


about axis R. As noted before, the rotation of the shaft


104


, with eccentric


144


thereon, causes the collar link


148


to move in an orbital motion about axis R. The orbital motion of the collar link


148


has components along orthogonal directions indicated by arrows X and Y in FIG.


4


. Collar motion in the direction indicated by arrow Y brings the pin


168


in the collar link


148


against the slide bushing


170


thereby actuating the pump


26


in the Y direction in and out of the chamber


222


in the pump body. Collar motion in the X direction slides the pin


168


inside the slide bushing


170


. Thus, the transmission linkage


106


transforms the rotational motion of the shaft


104


into reciprocating rectilinear motion of the pump


26


inside the pump body


24


. One revolution of the shaft


104


actuates the pumping through one in/out cycle in chamber


222


. Actuation of the pump


26


in the pump body


24


draws hydraulic fluid from the suction conduit


210


(see

FIG. 2

) and supplies it under pressure through the supply conduit


212


to the ram assembly


22


to move the movable adapter


18


of the tool


10


.




As can be realized from

FIGS. 3 and 4

, the freedom of movement of the pivotable joint between the collar link


148


and pump


26


accommodates misalignment between the motor section, particularly the location and angle of axis of rotation R relative to the location or shaft


104


of the pump bore


222


in the pump body. For example, if the motor section


100


when mounted to housing


15


and the shaft


104


is positioned such that axis R is inclined rather than orthogonal to bore


222


, or the collar link is not positioned directly over the bore


222


, the pivotable joint


171


between collar link


148


and pump


26


allows the pump


26


to nevertheless be installed true in the pump bore


222


, and the transmission linkage


106


to operate without binding or excessive wear of either the slider mechanism


150


or the bearing


146


. The pivotable joint


171


between pump


26


and link


148


allows the bearing


146


to remain true on the shaft


104


and in the collar link so that the bearing may rotate freely. The cylindrical surfaces of the pin


168


and slide bushing


170


, which effect the pivoting freedom of joint


171


, also allow the slide bushing


170


to slide freely along the pin (in the direction indicated by arrow X) regardless of whether the collar link


148


is angled relative to the pump


26


.




The full circumferential contact between the eccentric


144


and bearing


146


and the bearing


146


and collar link


148


provides large bearing surfaces which in turn reduces contact stress on these components with a commensurate reduction in wear and an increase in the life of the component. Similarly the large bearing surfaces between the pin


168


and slide bushing reduces contact stress between these components. For example, for a slide bushing


170


having a length of 0.5 inch and a pin with a diameter of 0.31 inch, the contact stress from a 750 lbs. load on the pump


26


is about 3100 psi. Stresses of this order of magnitude are low relative to the yield stress of many metal alloys including light and inexpensive aluminum allows without heat treatment. Contact stresses of the magnitude noted above may also be readily supported by non-metallic materials such as plastic without creep or deformation of the material. Aluminum alloys or plastic are inexpensive and easy to shape or machine. Aluminum alloys or plastic are also light. Thus, use of aluminum alloys or plastic in manufacturing components such as the transmission linkage


106


of the tool


10


, reduces the weight of the tool


10


, as well as manufacturing cost in comparison to conventional hydraulic power tools. The transmission linkage


106


continuously transfers power from the shaft


104


to the pump


26


actuating the pump both into and out of the pump chamber


222


. This facilitates very high pump speeds without limitations due to spring response as in conventional hydraulic tools. The high pump speeds achievable with tool


10


allow crimping operations to be completed faster than using conventional hydraulic crimping tools.




In sharp contrast to drive


100


and tool


10


, conventional hydraulic tools that use springs as the primary device to return the piston pump to its home position have several disadvantages. Springs have a finite life, require additional room to package, and can produce “valve hop”. Valve hop is a condition when the spring response does not coincide with the speed of the device. In hydraulic tools, the spring may cause “piston hop”, where the piston pump may not stay fully engaged with the drive shaft. Such a condition would produce less pump stroke and therefore a relatively longer crimp cycle time. In addition, the spring preload against the piston drives up the power demand during pump operation (i.e. the motor is working against hydraulic pressure and spring preload on the piston) thereby consuming more power. This is significant in battery powered tools. In the case of conventional hydraulic tools employing a cam link mechanism as disclosed in U.S. Pat. Nos. 5,111,681 and 5,195,354, the manufacture of such a mechanism may involve either welding of two components or considerable machining time. In addition, the parts of the cam mechanism would most likely need heat treatment. Also alignment of the annular portion of the mechanism to the shaft may be very difficult. It is preferred to have the needle bearing outer race in full contact with the contoured inner portion. However, in the conventional tools, the bearing is not in full contact and bearing life may be reduced. Also since the needle bearing outer race is allowed to translate within the contoured cavity, ample clearance may exist between the outer bearing race and contoured surface, primarily, clearance in the direction of piston pump movement. The subject clearance may be relatively small in this direction, however, such clearance is not desired because it may produce a “rapping” sound and create excessive wear. Wear can result because there is a substantial load being applied to a relatively small contact point. The contact point in this case is the apex of the needle bearing outer race. The present invention overcomes the above noted problems or conventional hydraulic tools as previously described.




It should be understood that the foregoing description is only illustrative of the invention. Various alternatives and modifications can be devised by those skilled in the art without departing from the invention. Accordingly, the present invention is intended to embrace all such alternatives, modifications and variances which fall within the scope of the appended claims.



Claims
  • 1. A transmission for connecting a rotary motor output shaft to a rectilinear actuator which is movable rectilinearly along an actuator axis of translation, the transmission comprising:a frame with a bore formed therein; an eccentric adapted to position the frame on the rotary motor output shaft, the eccentric being rotatably mounted in the bore of the frame to rotate relative to the frame; and a rectilinear guide connected to the frame, the rectilinear guide having a slide surface adapted to be slidably seated against the rectilinear actuator allowing the frame to slide substantially rectilinearly relative to the rectilinear actuator, wherein the frame has a recess formed therein, the recess being sized and shaped for movably locating at least part of the rectilinear actuator in the recess, the rectilinear guide extending across the recess.
  • 2. The transmission according to claim 1, wherein the frame slides relative to the rectilinear actuator along an axis of translation substantially orthogonal to the actuator axis of translation.
  • 3. A transmission for connecting a rotary motor output shaft to a rectilinear actuator which is movable rectilinearly along an actuator axis of translation, the transmission comprising:a frame with a bore formed therein; an eccentric adapted to position the frame on the rotary motor output shaft, the eccentric being rotatably mounted in the bore of the frame to rotate relative to the frame; and a rectilinear guide connected to the frame, the rectilinear guide having a slide surface adapted to be slidably seated against the rectilinear actuator allowing the frame to slide substantially rectilinearly relative to the rectilinear actuator, wherein the rectilinear guide comprises a pin, an outer surface of the pin forming the slide surface.
  • 4. The transmission according to claim 3, wherein the rectilinear guide extends through an aperture in the rectilinear actuator.
  • 5. A hydraulic tool drive comprising:a frame with a hydraulic reservoir; a hydraulic ram movably mounted to the frame; a pump connected to the frame, the pump having a pump piston for pumping hydraulic fluid to move the hydraulic ram relative to the frame; a motor connected to the frame, the motor having an output shaft that rotates about an axis of rotation when the motor is operating; and a link operably connecting the output shaft to the pump piston for generating reciprocating movement of the pump piston when the motor is operating, wherein the link is rotatably mounted on the output shaft and is pivotable at least at one end relative to the frame, wherein the link has an end which is movably mounted to the pump piston so that the link moves freely relative to the pump piston.
  • 6. The drive according to claim 5, wherein the link has a bore formed therein for mounting the link onto the output shaft, the output shaft being eccentrically positioned in the bore when the link is mounted to the output shaft.
  • 7. The drive according to claim 5, further comprising an eccentric fixedly mounted to the output shaft, the eccentric having an inner bore which is concentric with the output shaft and having an outer surface which is concentric with a bore in the link in which the eccentric is seated.
  • 8. The drive according to claim 5, further comprising a bearing concentrically mounted into a bore in the link, the bearing being located between a portion of the output shaft in the bore and the perimeter wall of the bore.
  • 9. A hydraulic tool drive comprising:a frame with a hydraulic reservoir; a hydraulic ram movably mounted to the frame; a pump connected to the frame, the pump having a pump piston for pumping hydraulic fluid to move the hydraulic ram relative to the frame; a motor connected to the frame, the motor having an output shaft that rotates about an axis of rotation when the motor is operating; and a link operably connecting the output shaft to the pump piston for generating reciprocating movement of the pump piston when the motor is operating, wherein the link is rotatably mounted on the output shaft and is pivotable at least at one end relative to the frame, wherein the at least one end of the link is pivotally connected to the pump piston by a pin.
  • 10. A hydraulic tool drive comprising:a frame with a hydraulic reservoir; a hydraulic ram movably mounted to the frame; a pump connected to the frame, the pump having a pump piston for pumping hydraulic fluid to move the hydraulic ram relative to the frame; a motor connected to the frame, the motor having an output shaft that rotates about an axis of rotation when the motor is operating; and a link operably connecting the output shaft to the pump piston for generating reciprocating movement of the pump piston when the motor is operating, wherein the link is rotatably mounted on the output shaft and is pivotable at least at one end relative to the frame, wherein the link has a recess in one end, at least one end of the pump piston being located in the recess.
  • 11. The drive according to claim 10, wherein the link has a pin which extends across the recess.
  • 12. The drive according to claim 10, wherein the pump piston has a slide bushing located at the at least one end of the pump piston.
  • 13. The drive according to claim 12, wherein the pin extends through the slide bushing, the slide bushing being seated against the pin when the link moves the pump piston, the pin sliding rectilinearly on the slide bushing.
  • 14. The tool according to claim 13, wherein when the link moves the pump piston, the link slides on the slide bushing in a direction substantially orthogonal to a reciprocating movement direction of the pump piston.
  • 15. The drive according to claim 13, wherein the slide bushing is made of at least in part from an oil impregnated bronze material or a lubricious non-metallic material.
  • 16. A hydraulic tool drive comprising:a frame with a hydraulic reservoir; a hydraulic ram movably mounted to the frame; a pump connected to the frame, the pump having a pump piston for pumping hydraulic fluid to move the hydraulic ram relative to the frame, the pump piston being movable relative to the pump along an axis of rotation; a motor connected to the frame, the motor having rotary output shaft; and a collar connected to the rotary output shaft and having a joint at which the collar is movably joined to the pump piston to move relative to the pump piston along another axis of translation which is substantially orthogonal to the axis of translation of the pump piston, wherein the collar comprises a frame with a generally cylindrical bore in which the rotary output shaft is eccentrically located, the frame having a clevis at one end which forms the joint in the collar.
  • 17. The drive according to claim 16, wherein the joint between the collar and the pump piston is adapted to allow the collar to move in two independent degrees of freedom relative to the pump piston.
  • 18. The drive according to claim 17, wherein one of the two independent degrees of freedom is provided by the collar being able to move along the other axis of translation, and another of the two degrees of freedom is provided by the collar being able to pivot about the other axis of translation.
  • 19. The drive according to claim 16, wherein the collar comprises a pin mounted in the frame to extend through the clevis.
  • 20. The drive according to claim 16, wherein the pump piston includes a linear slide bearing, the linear slide bearing being seated against a slide surface of the collar located at the joint of the collar to the pump piston.
  • 21. A hydraulic tool drive comprising:a frame with a hydraulic reservoir; a hydraulic ram movably mounted to the frame; a pump connected to the frame, the pump having a pump piston for pumping hydraulic fluid to move the hydraulic ram relative to the frame, the pump piston being movable relative to the pump along an axis of rotation; a motor connected to the frame, the motor having a rotary output shaft; and a collar connected to the rotary output shaft and having a joint at which the collar is movably joined to the pump piston to move relative to the pump piston along another axis of translation which is substantially orthogonal to the axis of translation of the pump piston, wherein the drive further comprises an eccentric fixedly mounted to the rotary output shaft, the eccentric being engaged to the collar so that when the motor rotates the rotary output shaft the collar is moved in an orbital motion relative to the output shaft.
  • 22. A hydraulic crimping tool comprising:a frame with a hydraulic reservoir; a hydraulic ram movably mounted to the frame; a pump connected to the frame, the pump having a pump piston for hydraulically moving the hydraulic ram relative to the frame; a motor connected to the frame, the motor having a rotary output shaft; and a transmission connecting the rotary output shaft to the pump piston, the transmission comprising an eccentric fixedly mounted onto the rotary output shaft and a collar rotatably mounted onto the eccentric to rotate relative to the eccentric, the collar being movably joined to the pump piston, wherein the collar has a clevis, the pump piston being pinned to the collar in the clevis.
  • 23. The tool according to claim 22, wherein the collar is movably joined to the pump piston to allow the collar to move in two independent degrees of freedom relative to the piston.
  • 24. The tool according to claim 22, wherein the collar is movably joined to the pump piston so that the collar is free to slide rectilinearly relative to the pump piston, and is free to pivot relative to the pump piston.
  • 25. The tool according to claim 22, wherein the collar has a bore, the eccentric being concentrically disposed in the bore and holding the collar eccentric relative to the rotary output shaft.
  • 26. The tool according to claim 22, wherein the pump piston has a linear slide bushing located in the clevis of the collar, the collar having a slide surface in the clevis which slides along the linear slide bushing when the motor rotates the rotary output shaft.
  • 27. The tool according to claim 22, further comprising a housing connected to the frame for housing the transmission connecting the rotary output shaft to the pump piston.
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