EP0124592A1 - Dispositif de couple hydraulique - Google Patents

Dispositif de couple hydraulique

Info

Publication number
EP0124592A1
EP0124592A1 EP19830903738 EP83903738A EP0124592A1 EP 0124592 A1 EP0124592 A1 EP 0124592A1 EP 19830903738 EP19830903738 EP 19830903738 EP 83903738 A EP83903738 A EP 83903738A EP 0124592 A1 EP0124592 A1 EP 0124592A1
Authority
EP
European Patent Office
Prior art keywords
shaft
inner member
brake
housing
rotation
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Withdrawn
Application number
EP19830903738
Other languages
German (de)
English (en)
Inventor
Carle A. Middlekauff
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
W H NICHOLS Co
Original Assignee
W H NICHOLS Co
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by W H NICHOLS Co filed Critical W H NICHOLS Co
Publication of EP0124592A1 publication Critical patent/EP0124592A1/fr
Withdrawn legal-status Critical Current

Links

Classifications

    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F04POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
    • F04CROTARY-PISTON, OR OSCILLATING-PISTON, POSITIVE-DISPLACEMENT MACHINES FOR LIQUIDS; ROTARY-PISTON, OR OSCILLATING-PISTON, POSITIVE-DISPLACEMENT PUMPS
    • F04C2/00Rotary-piston machines or pumps
    • F04C2/08Rotary-piston machines or pumps of intermeshing-engagement type, i.e. with engagement of co-operating members similar to that of toothed gearing
    • F04C2/10Rotary-piston machines or pumps of intermeshing-engagement type, i.e. with engagement of co-operating members similar to that of toothed gearing of internal-axis type with the outer member having more teeth or tooth-equivalents, e.g. rollers, than the inner member
    • F04C2/103Rotary-piston machines or pumps of intermeshing-engagement type, i.e. with engagement of co-operating members similar to that of toothed gearing of internal-axis type with the outer member having more teeth or tooth-equivalents, e.g. rollers, than the inner member one member having simultaneously a rotational movement about its own axis and an orbital movement

Definitions

  • This invention relates to hydraulic motors, particularly those used as vehicle wheel motors or those incorporated into heavy machinery requiring mechanical braking systems.
  • a commonly used form of hydraulic motor consists of internal gear or gerotor sets consisting of inner and outer members which have radially projecting teeth that engage with each other to form expanding and contracting chambers. These chambers provide a means of circulating fluid through the gear set in a manner which utilizes fluid pressure . for producing shaft rotation. Conversely, in a pump, shaft rotation is used to produce fluid pressure. In this way, such gear sets can be used as either hydraulic motors or pumps.
  • a central inner gear member is made to rotate eccentrically within a housing shaped for reciprocal contact with the gear member , to cause the creation of the expanding and contracting chambers.
  • the eccentric rotational movement of the inner member is transmitted through a coupling called a "dog-bone" to a centrally rotating drive shaft from which machinery movement is powered.
  • the dog-bone coupling is required because central rotation about a fixed axis is needed in machinery drive shafts.
  • the dog-bone coupling may only be used to pro ⁇ quiz central rotation at one end of the device motor housing.
  • the central shaft rotates and provides the machinery drive.
  • the centrally rotating shaft upon a fixed axis is generally supported by bearings in the relatively small area between the dog-bone coupling and the end of the housing.
  • Th --eccentrically rotating dog-bone shaft cannot be supported by bearings at all and acts as a level applying undesirable force to the central drive shaft.
  • mechanical brakes are added to machinery drive trains either between the hydraulic motor and the operating machinery or somewhere within the operating mechanical system itself.
  • Mechanical brakes are required when hydraulic motors are used to propel heavy machinery or elevate platforms, since their locked position must be assured. Any hydraulic fluid leakage which allows the hydraulic motor to turn once hydraulic pressure is turned off, causes inad ⁇ vertent back movement of machinery. This back move ⁇ ment is highly dangerous in many machinery applications. It is for this reason that hydraulic motors are either limited in use or equipped with mechanical shaft locking devices. When hydraulic motors are used as wheel motors to propel vehicles, mechanical shaft locking devices serve as parking brakes. In a common gerotor motor as described above, a mechanical brake must be installed on the central shaft.
  • the shaft may project out both ends of the motor and be used for propulsion or braking purposes at either end along its fixed axis of rotation.
  • the creation of a fixed axis of rotation is generally accomplished by allowing the outer member of the gerotor set to orbit about the center of rotation of the fixed axis of the inner member.
  • the outer member does not rotate about its own axis but merely orbits in a non-rotational manner around the fixed axis of the rotating inner member.
  • This motion is a type of circular shuttle motion in which the entire outer member moves in a circle at a small radial distance from the axis of the inner member.
  • This radial distance is the eccentricity required for the motor or pump to operate by forming expanding and contrac ⁇ ting chambers between the inner and outer members.
  • the through-shaft motors represent an improve- ent over gerotor type motors discussed above but have been unable to overcome certain deficiencies when used in heavy duty operations which generate high torque loads. These devices have been limited by both the valving and bearing arrangements in their designs.
  • U. S. Patent 4,025,243 by Stephens discloses an orbit motor with a central shaft as described above.
  • the shaft is supported by three needle bearings.
  • a motor of this type would not be able to withstand high thrust loads as needle bearings primarily control shaft bending and are not capable of withstanding thrust loads along their longitudinal axis.
  • the Stephens motor can only use needle bearings adjacent to its gear set because of its dual valving arrangment.
  • the chambers formed between the inner and outer members are ' in fluid communication with valve ports on each side of the orbiting member in order to achieve efficient valve flow. This arrangement limits the amount of room surrounding the shaft, proximate to the gear set, in which a bearing may be placed and, therefore, restricts this type device to light thrust load operations.
  • U. S. Patent 2,989,951 to Charlson discloses an orbit motor wi * y * ⁇ . a. gerotor. set of rotating inner ' and orbiting outer members.- These are fed by valving on both sides of the gerotor set. This is required as in the Stephens motor to maintain efficient valving of the gerotor set. When valving of this type is only at one end of the gerotor, the chambers would fill too slowly with fluid to properly support normal motor speeds.
  • a motor of this type would allow for more efficient and less dis ⁇ ruptive replacement of mechanical brakes in hydraulic motor systems.
  • the device disclosed comprises a fluid displacing apparatus with inlet and outlet ports for the entry and exit of hydraulic fluid.
  • a fluid displacing apparatus with inlet and outlet ports for the entry and exit of hydraulic fluid.
  • Inside a motor housing an inner member is mounted on a central shaft for rotation about a longitudinal fixed axis of the shaft. Fluid is displaced betwen the inner member and an outer member which is mounted within the apparatus housing for eccentric orbital movement about the fixed axis of the shaft.
  • the shaft projects externally to the motor housing at one end and is supported by three bearings adjacent to the .inner and outer members.
  • Two of the bearings are thrust resistant tapered roller bearings while one of the bearings is a needle bearing.
  • the bearings serve to accommodate thrust, bending and side loads that are applied to the apparatus shaft during operation of attached heavy machinery.
  • the outer and inner members define a plurality of circumferentiaily spaced fluid chambers which vary in size in response to the rotation of the inner member and the orbital movement of the outer member.
  • the inner member has a number of semicircular shaped teeth which in the preferred embodiment are formed by rollers held within pockets of said inner member.
  • the outer member has multiple arcuately generated radial teeth on its inner diametric surface.
  • the generated teeth number one greater than the number of semicircular teeth present on the inner member.
  • the generated teeth are non-circular in order to provide for continuous reciprocal interaction with the semicircular teeth of the inner member in response to the nonrotational orbital movement of the outer member and the rotation of the inner member about a fixed axis.
  • the preferred embodiment further comprises a mechan ⁇ ical brake mounted upon the central shaft within the motor housing.
  • the brake contains a brake disk mounted upon the shaft, and a non-rotatable brake pad is mounted within the motor housing; with means provided for moving the brake pad into contact with the rotatable brake disk to arrest or prevent rotation of the central shaft.
  • a second preferred embodiment comprises a motor housing having a central rotatable shaft which projects external to the housing at both longitudinal ends of the housing. An inner and outer member are disposed in that housing as in the first embodiment above. One end of said shaft, however, is used for mounting of an external brake identical to the internal brake described above. The second end of said shaft is used to drive machinery with the rotational movement pro ⁇ vided by the motor.
  • Both embodiments provide for a compact hydraulic fluid displacing apparatus capable of supporting heavy thrust and bending loads.
  • the invention also provides for mechanical braking at a point removed from the end of the central shaft used as the drive shaft for machinery.
  • Figure 1 is a cross -section of a hydraulic motor embodying this invention. The cross section is taken along the length of the central shaft.
  • Figure 2 is a cross section of the hydraulic motor taken along line 2-2 of Figure 1 showing the internal gear set.
  • Figure 3 is a cross section of the hydraulic motor taken along line 3-3 of Figure 1 showing the internal valving.
  • Figure 4 is a partial section of the hydraulic • motor showing the working relationship of the gear set, commutator and valve.
  • Figure 5 is a partial section of the motor as shown * in Figure 4 after a slight clockwise rotation of the inner member
  • Figure 6 is a partial section of the motor as shown in Figure 5 after an additional slight clockwise rotation of the inner member.
  • Figure 7 is a plane view of a second embodiment of the invention with an external brake.
  • Figure .8 is a cross section of the second embodiment of Figure 7 taken along line 8-8 o ⁇ Figure 7.
  • Figure 1 is a lengthwise cross-section of a hydraulic motor 8 embodying the invention.
  • the motor 8 contains an integral brake shown generally at 20 and three bearings 14, 16, and 18 for accommo ⁇ dation of large bending and thrust loads.
  • the hydraulic device of Figure 1 as described below utilizes pressurized fluid to produce shaft rotation.
  • the device may also be used to produce pressurized fluid if shaft rotation is supplied to the unit. Therefore, the device may be considered as either a hydraulic motor or pump.
  • the hydraulic motor shown in Figure 1 is enclosed in a housing 9 in which a central shaft 12 is supported to rotate about a fixed axis.
  • the shaft 12 is held in rotatable position about its longitudinal axis by two tapered roller bearings 14 and 16, and a needle bearing 18.
  • the motor housing is constructed in four pieces for ease of construction and access to internal parts.
  • Motor mount housing 11 contains the tapered roller bearings 14 and 16 and the shaft exit area from which the extended shaft 12 is attached to machinery.
  • a mounting flange 72 allows for the affixing of the motor to a machinery frame during motor usage and serves to transmit reaction forces generated by motor operations.
  • Gear set housing 10 contains the two -gear members 30, 32 as well as the valve plate 48. The housing is designed, as discussed below, to prevent outer member 32 from rotating.
  • Commuta or housing 13 houses a commutator 57 which serves to conduct fluid from the inlet port 46 and outlet port to the valve plate 48.
  • the commutator housing 13 also supports needle bearing 18 which supports the shaft in the brake area 20.
  • Brake housing 21 supports the brake 20 used to lock the shaft 12 and prevent rotation as required for safe machinery operations.
  • FIG. 1 is a cross section of the motor of
  • FIG- 1 which shows the fluid chambers 52 in which hydraulic fluid is circulated.
  • high pressure fluid causes rotation of an inner member 30 as the chambers get larger and smaller due to the eccentric movement of outer member 32.
  • High pressure fluid enters the hydraulic motor at inlet port 46 ( Figure 1) .
  • gallery 47 At the base of the inlet 46 is gallery 47, which serves to conduct fluid to eight inlet commutator ports 54 (also shown in Figure 3 in dotted lines) .
  • the gallery or plenum 47 is an open annulus in the commutator 57 connecting all the high pressure ports 54 and equalizing fluid pressure amongst them.
  • High pressure fluid flows through a valve plate 48 which is affixed to shaft 12 and rotates with it. Plate 48 has a plurality of fluid transmission ports 56. The valve plate 48 and ports 56 are shown in detail in Figure 3 in solid lines.
  • valve plate selectively allows fluid from the commutator ports to enter the chambers between the rotating inner member 30 and non-rotating outer member 32 shown in Figure 2.
  • the high pressure fluid upon entering chambers 52 causes the chambers to expand and thereby rotate the central motor shaft 12.
  • This fluid is removed from the motor chambers 52 through valve plate 48 which selectively opens passages from the contracting chambers to the low pressure commutator ports 49.
  • these ports 49 are also connected together with a gallery or plenum 51. This annular plenum equalizes fluid pressure and conducts the fluid to an outlet port similar to the inlet port 46. From this outlet port fluid is discharged from the motor and returned to a fluid source.
  • the inner member 30 ( Figure 2) is mounted upon shaft 12 which rotates about a fixed center.
  • the inner member 30 comprises a plurality of circumferen- tially spaced semicircular gear teeth 61.
  • the teeth 61 consist of circular cylinders, or rollers, 61 which are . held at a uniform radius from the center of rotation.
  • the outer member 32 has a non-circular, or generated, inner surface 33 with teeth 35 numbering one greater (eight) than the number of teeth (seven) on the inner member.
  • the outer member 32 moves eccentrically within the housing 10 but does not rotate about its axis 92.
  • the center point of the outer member, axis 92, moves in a circular orbit about the axis of rotation 90 of the inner gear 30.
  • the radius E of the circle made by the outer gear's center in its movement defines the amount of the outer member's eccentric movement.
  • Rotational movement of outer member 32 is pre ⁇ vented by rollers 73 mounted in the housing 10. These rollers are trapped in gear housing 10 in order to prevent rotation of the outer member 32 but do allow for the eccentric movement, or orbiting of the outer gear center, around the fixed center 90 of the inner member 30 shaft 12.
  • the " inner peripheral surface of the outer, or inter ⁇ nally generated member (IGR) 32 is precisesly generated by a grinding or other shaping mechanism in a sinusoidal- like shape which utilizes the eccentric movement of the outer member 32 to provide for continuous contact of the outer member with the teeth of the rotating inner member.
  • the teeth of the inner member are main ⁇ tained in constant contact thereby with the outer member 32.
  • the smooth generated surface 33 is a low friction working surface which allows easy rotation of the inner member 30.
  • inlet port 46 To operate the motor high pressure fluid is provided at inlet port 46.
  • gallery 47 At the base of inlet 46 is gallery 47, and the gallery or plenum serves to conduct the fluid to eight stationary commutator inlet ports 54 shown in Figure 3 in dotted lines.
  • the plenum 47 is an open annulus in the commutator connecting all the high pressure ports 54 and equalizing pressure amongst them.
  • Valve plate 48 is fixedly attached to shaft 12 adjacent to an inner member 30 as shown in Figures 1 and 3.
  • the valve plate 48 therefore rotates in con ⁇ junction with the inner member 30.
  • seven valve ports 56 (shown in solid lines in Figure 3) open passages from the gear set chambers 52 to the commu ⁇ tator at high and low pressure ports, 49 and 54 respec ⁇ tively.
  • Figures 4, 5, and.6 show the relationships of the gear set, valving and commutator ports as the motor operates.
  • the gear set is shown in phantom and the commutator ports in dotted lines.
  • Figure 4 is a cross-section of the gear set and valving in which the motor is shown operating in a clockwise direction.
  • Chamber 52A is shown to be in ⁇ creasing in size as it is being filled with high pressure fluid from commutator port 54A through valve port 56A..
  • Chamber 52B as at its maximum volume and is not in communication with any commutator port.
  • Figure 5 shows the same elements as Figure 4 after the motor has rotated a small fraction of a turn from the position shown in Figure 4.
  • the outer member 32 axis 92 has continued on its orbit about the inner member 30 axis 90.
  • chamber 52A has raeached maximum dimensions.
  • Chamber 52A as shown is now sealed and out of fluid communication with the commutator due to the rotation of the valve port 56A.
  • Chamber 52B has begun to decrease in size, and the valve plate allows lower pressureizid to be withdrawn from the chamber 52B through valve port 56B, by commutator port 49C.
  • Figure 6 shows a further progression of the motor as chamber 52A and 52B both become smaller and have their low pressure fluid withdrawn through valve ports 56A- * and 56B.
  • valve plate 48 acts to open that chamber only to the low pressure commutator ports 49 until the chamber volume reaches its minimum and the low pressure fluid has departed, at which point the valving " switches the connection back to high pressure only so that the chamber may refill to maximum si-ze. High pressure and low pressure fluid is thereby intermittently fed and released from chambers 52 between the inner rotor 30 and the outer 32.
  • valve plate 56 The seven valve ports 56, or field elements, on the valve plate 56 are activated eight times per revolution. This continual release of fluid pressure for rotational energy in each of the seven chambers " 52 provides high torque for a small amount of rotation. Given a similar fluid input pressure, a traditional gerotor set with only two valve ports would spin at a much faster speed and lower torque than a motor valved as above. It is for this reason that this motor is considered a high torque low speed motor.
  • An additional advantage of the rotating valve plate 48 is that it permits a high level of fluid volume to pass in and out of the opening and closing chambers 52 of the gear set at a very rapid rate.
  • Shallow depressions 80 ( Figure 3) on the surface of the valve permit fluid from the commutator 48 to be positioned between the commutator housing 13 and the rotating valve plate. These shallow depres ⁇ sions 80 prevent chafing between the commutator housing and the rotating valve plate and aid in balancing of the valve plate. As with any rotating
  • valve plate rotates with the centrally rotating inner gear 30, such eccentric movement is to be avoided. It is thus shown that the chambers 52 created by the reciprocal members 30 and 32 are driven into rota ⁇ tional movement by the injection of high pressure fluid and the withdrawal of low pressure fluid. The fluid energy is thereby used to produce shaft rotation and work. Since the inner gear rotates centrally, valving may be accomplished with a centrally located valve plate and commutator that need not accommodate any eccentrically moving characteristics of the motor...
  • valve and commutator ports allow for the placement of valve and commutator ports at a larger radial dis ⁇ tance from the shaft than was ever before possible.
  • This allows for the placement of large support bear ⁇ ings 14, 16, and 18 in the unused annulus surrounding the shaft adjacent to the working members 30, 32 and . the valve plate 48 in order to more fully support the central shaft 12.
  • This arrangement is in sharp divergence from previous valving arrangements of common gear and gerotor motors.
  • Commonly known gerotor motors have a generated outer peripheral surface on their inner members. This ' shaping requires valving at a closer radius to the central shaft than in the present invention; as a result, bearings cannot be placed adjacent to the rotating members.
  • Bearings 14 and 16 are opposed tapered roller bearings which permit heavy radial and thrust loads.
  • the bearings are placed adjacent to the gear set member 30, 32 for maximum motor support.
  • Each tapered roller bearing is composed of an outer race 34, rollers 36 in a cage (not shown) and an inner race
  • Inner race 38 is affixed to the shaft 12 so that the movement of the race 38 follows the shaft movement.
  • Outer race 34 is mounted to the stationary motor mount housing 11.
  • a needle bearing 18 in the commutator housing 13 sup ⁇ ports the shaft.
  • the needle bearing 18 supports the shaft 12 in the brake area 20.
  • Needle bearings 18 permit moderate rotational speeds in this application. Rotational speeds are maintained at less tha -2000 RPM with a minimum of friction.
  • the needle bearing accommodates shaft bending and side loads. In some applications a sleeve bearing may be preferred instead of the needle bearing shown.
  • the needle bearing 18 consists of needle rollers 100 which rotate between the rotating shaft 12 and the stationary commutator 57 surrounding the shaft 12.
  • the roller 100 rotates against a hardened portion of the central shaft 12 as an inner race and * the commu ⁇ tator housing 13 as an outer race.
  • Needle rollers 100 are held within a cage (not shown) as they rotate.
  • bearings 14, 16 and 18 are oil fed bearings that utilize the hydraulic fluid of the internal gear set for lubri ⁇ cation.
  • Check valve 50 permits the tapered roller bearings 14 and 16 to be lubricated from the inlet port 46 by way of the gear set. The pressure from the inlet port 46 is normally higher than the hydraulic. fluid pressure in the roller bearing area. This pressure normally holds the check valve 50 in the closed position.
  • valve 50 automatically opens to prevent over-pressurization of roller bearings 14 and 16 by allowing fluid to be released * by way of passage 67.
  • Vent port 58 is normally plugged with plug 60 except when high back pressure must be removed from seal 19.
  • Needle bearing 18 is lubricated with hydraulic fluid which is allowed to seep past valve plate 48.
  • an integral shaft locking brake 20 In the first embodiment shown in Figure 1, the brake 20 is provided adjacent to the motor and disposed within the same housing assembly.
  • the brake 20 is a multidisk ' type, having three rotary disks 22.
  • the disks are permanently affixed to shaft 12 by close tolerance spline 105.
  • shaft rotation is arrested or prevented.
  • Normally, the non-contacting position of braking element 24 is maintained by springs 26. In this posi ⁇ tion the disks 22 are free to rotate with the shaft 12.
  • piston plate 28 is moved into position to push the brake pads 24 against the disks 22 and thereby arrest any motion of the shaft 12.
  • fluid applied at port 110 flows to annular cavity 112 and maintains fluid pressure on the piston 28 which releases the brake and unlocks the shaft.
  • the cavity 112 may be connected to inlet port 46 by a channel so that the pressurized fluid used for motor operation would maintain the brake in the un- locked position. In this method removal of inlet pressure acts as a failsafe to automatically lock the shaft.
  • Hydraulic fluid is sealed from leakage into the brake area by seals 42 and 44. Seal 42 seals fluid from the mechanical piston plate 28. Seal 44 prevents fluid from the motor elements and needle bearing 18 from leaking into the brake.
  • the integral brake arrange ⁇ ment eliminates misalignment since the brake is mounted directly upon the central rotating shaft of the hydraulic motor. Also eliminated are stresses generated by machinery which are transmitted directly to the motor without prior transmission through the brake.
  • the brake in the preferred embodiment is of a standard ultidisk design. However, several different mechanical designs could be used for the same purpose, such as drum brakes or single disk brakes. It should be noted that the brake described above is intended for use as a parking brake. Use of this brake for arresting or slowing motion of the hydraulic motor during operations might result in overheating. Provisions have not been made for extensive brake cooling in this design.
  • Figures 7 and 8 display a second embodiment of the invention.
  • a brake 76 is mounted externally to the heavy duty motor.
  • the hydraulically activated portions of the heavy duty motor in Figures 7 and 8 are identical to the hydraul ⁇ ically activated portions of the motor shown in Figures
  • FIG. 7 an d 8 also utilizes the advantages of the through shaft, compact valving and heavy duty bearing arrangement of the first embodiment to allow for an improved external mechanical brake mounting arrangement.
  • a mechanical brake 76 similar to the type manufactured by Ausco and detailed in the first embodiment. This type brake is fully described in U. S. Patent 3,863,038 to Kreitner et al.
  • the through shaft 12 extends external to the motor 78, both through the motor mount housing 11 where it may be connected to machinery and " through commutator housing 103 where the shaft is used by the brake 76.
  • Brake 76 is used to lock the shaft 12 as required in machinery operation.
  • Figure 8 is a cross-section along line 8-8 of Figure 7.
  • the cross-section is along the shaft and shows the same bearing arrangement adjacent to the gear set as discussed in the first embodiment above to support the central shaft 12.
  • bearings 14 and 16 are tapered roller bearings.
  • Bearing 18 is a needle bearing. Bearings 14 and 16 permit heavy radial, and thrust loads, and bearing 18 prevents shaft bending and is specially adapted for use in high torque low speed motors.
  • the valving arrangement is the same as discussed in reference to Figures 4-6 above and allows the placement of the bearings adja ⁇ cent to the gear set.
  • the assembled motor housing consists of three pieces.
  • the motor mount housing 11 and the gear set housing 10 are identical to those discussed in the first embodiment.
  • w ⁇ o in this embodiment is formed as a motor end suitable for attachment of an independent brake 78. Except for the extension of the shaft 12 beyond the motor housing for the mounting of independent brake 78, this embodiment is in all respects the same as that previously discussed.

Abstract

Un appareil compact (8) de déplacement d'un fluide possède des paliers (14, 16, 18) adjacents à un jeu d'engrenages (30, 32) composé d'un organe intérieur (30) et d'un organe extérieur (32) formant des chambres espacées circonférentiellement pour le déplacement du fluide. Le dispositif possède un arbre central fixe (12) qui tourne autour d'un axe fixe et assure la fixation intégrale ou indépendante d'un dispositif de freinage mécanique (20) pour bloquer l'arbre (12). Le dispositif (8) est généralement utilisé comme moteur à faible vitesse et couple élevé pour propulser des machines lourdes où l'on rencontre de fortes poussées et de grandes charges de flexion.
EP19830903738 1982-11-01 1983-10-28 Dispositif de couple hydraulique Withdrawn EP0124592A1 (fr)

Applications Claiming Priority (2)

Application Number Priority Date Filing Date Title
US43841982A 1982-11-01 1982-11-01
US438419 1982-11-01

Publications (1)

Publication Number Publication Date
EP0124592A1 true EP0124592A1 (fr) 1984-11-14

Family

ID=23740585

Family Applications (1)

Application Number Title Priority Date Filing Date
EP19830903738 Withdrawn EP0124592A1 (fr) 1982-11-01 1983-10-28 Dispositif de couple hydraulique

Country Status (4)

Country Link
EP (1) EP0124592A1 (fr)
JP (1) JPS59501989A (fr)
DK (1) DK320284D0 (fr)
WO (1) WO1984001800A1 (fr)

Families Citing this family (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US4981423A (en) * 1989-10-03 1991-01-01 Trw Inc. Hydraulic motor with wobble-stick and brake assembly
US6062835A (en) * 1997-01-14 2000-05-16 Eaton Corporation Gerotor motor and parking lock assembly therefor
US6068460A (en) * 1998-10-28 2000-05-30 Eaton Corporation Two speed gerotor motor with pressurized recirculation
US6336729B1 (en) 1999-05-20 2002-01-08 Richard Pavelle Emergency light device
US6132194A (en) * 1999-06-03 2000-10-17 Eaton Corporation Low cost compact design integral brake
EP1882855A3 (fr) * 2006-07-25 2008-04-30 Kinshofer GmbH moteur hydraulique

Family Cites Families (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
DE1503362C3 (de) * 1963-03-09 1974-06-12 J.P. Sauer & Sohn Gmbh Gegruendet 1751, 2300 Kiel Haltebremse für einen Drehkolbenmotor
DE1528998A1 (de) * 1965-03-05 1970-03-19 Danfoss As Verteilerventil fuer eine Zahnradpumpe oder einen Zahnradmotor
US3910733A (en) * 1969-09-18 1975-10-07 Leslie H Grove Rotary mechanism having at least two camming elements

Non-Patent Citations (1)

* Cited by examiner, † Cited by third party
Title
See references of WO8401800A1 *

Also Published As

Publication number Publication date
JPS59501989A (ja) 1984-11-29
DK320284A (da) 1984-06-29
DK320284D0 (da) 1984-06-29
WO1984001800A1 (fr) 1984-05-10

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