Abstract: The application relates to the technical field of control, and provides an electromagnetic brake control apparatus. The apparatus includes: a power supply management circuit, a first switch circuit, a freewheeling diode and a first control output end and a second control output end used to connect with two ends of an electromagnetic coil of the electromagnetic brake; the power supply management circuit includes: a power supply input end, a first output end and a second output end used to connect with an external power supply; an input end and an output end of the first switch circuit are respectively connected with the first output end and the first control output end, the first switch circuit is configured with a pulse width modulation function; a cathode and an anode of the freewheeling diode are respectively connected with the second output end and the first control output end.

Abstract: A hydraulically actuatable shift element (100) includes a clutch piston (101), a fast fill piston (102), a fast fill valve (103), a fast fill pressure chamber (126), and a clutch pressure chamber (117). The fast fill valve (103) includes a sealing body (132) and a control body (131). Before the actuation of the shift element (100), the sealing body (132) is in a first switching position, in which the fast fill pressure chamber (126) is connected to a pressurized oil source (108) and, after the actuation of the shift element (100) in a second switching position, seals off the fast fill pressure chamber (126) with respect to the rest of the hydraulic system. The control body (131) has a first pressure surface (A18) and a second pressure surface (A19), wherein, in the first switching position, only the first pressure surface (A18) is pressurizable from the pressurized oil source (108).

Abstract: In some examples, a cone clutch assembly includes an inner cone member defining a first friction surface; an outer cone member defining a second friction surface opposing the first friction surface; and an independent friction member positioned between the first friction surface of the inner cone member and the second friction surface of the outer cone member. The inner cone member and outer cone member are configured to be selectively engaged and disengaged from each other. When the inner cone member is engaged with the outer cone member, the first friction surface of the inner cone member frictionally engages a third friction surface of the friction member, and the second friction surface of the outer cone member engages a fourth friction surface of the friction member such that rotational motion is transferred between the inner cone member and the outer cone member via the friction member.

Abstract: A drive device with a drive unit which has an output shaft and is mechanically connected to a driven shaft of the drive device via a clutch. At least one hydraulic channel and one hydraulic cylinder flow-connected to the hydraulic channel are formed in the output shaft, wherein a hydraulic piston coupled to the clutch for operating the same is displaceably arranged in the hydraulic cylinder.

Abstract: A drive system for driving a crusher of a material crusher plant having a main drive and a power transfer unit driven by the main drive, wherein the power transfer unit drives at least one generator and a first hydraulic pump which is connected to the power transfer unit in a shiftable manner. It is provided that a shiftable fluid coupling is installed in the transmission path from the power transfer unit to the crusher, that the shiftable fluid coupling and a pump are interconnected in a fluid conveying manner in a pump circuit and that a fluid can be supplied to the shiftable fluid coupling by means of the pump. A method of operating such a crusher is also provided.

Abstract: A clutch device has a counter-pressure plate and a contact plate which is movable to a limited extent in an axial direction of the clutch device by at least one lever element to clamp a clutch plate frictionally between the counter-pressure plate and the contact plate, wherein the counter-pressure plate has at least one strap segment extending essentially in an axial direction, to which a cover component is connected.

Abstract: A method for operating a powertrain of a motor vehicle with two vehicle axles which can be driven by separate drive assemblies, wherein at least one of the two vehicle axles can be driven by an electromotive drive assembly, and wherein the at least one vehicle axle has two wheels and at least three axle portions, wherein a first axle portion has a first wheel, wherein the first and a second axle portion are coupled by a differential gear, wherein the second and a third axle portion are arranged so they can be connected together by a clutch, and wherein the third axle portion has a second wheel. During drive mode of the motor vehicle with the clutch open, the electromotive drive assembly is held at a standby rotation speed under active regulation by an electric drive control unit, wherein the standby rotation speed tracks a synchronization rotation speed.

Abstract: A clutch operating device includes a drive mechanism and an assist mechanism. The drive mechanism is configured to generate a driving force and transmit the driving force to a clutch device. The assist mechanism is a mechanism for assisting the drive mechanism and includes a pressure mechanism and a toggle mechanism. The pressure mechanism is configured to generate a pressing force. The toggle mechanism is configured to convert the pressing force of the pressure mechanism into an assist force gradually increased from a power blocked state to a power transmitted state of the clutch device.

Abstract: A device is provided that includes a torque-transmitting mechanism selectively engageable by radially-outward force to transfer torque between a rotatable input member and a rotatable output member. A mass is connected for rotation with the output member and is configured to move radially outward as the output member rotates to reduce torque transfer from the input member to the output member as the speed of the output member approaches the speed of the input member. Furthermore, the mass connected for rotation with the output member may create a force that causes torque transfer between the input member and the output member when the output member rotates faster than the input member.

Abstract: A multi-disc frictional engagement mechanism includes driven plates and drive plates, a clutch piston including a radially extending first pressure receiving portion, a joint piston including a radially extending second pressure receiving portion and an engaging portion which is engaged with a clutch hub to engage the clutch hub and the clutch drum such that the clutch hub and the clutch drum are not relatively rotatable when the joint piston advances, a first oil chamber which causes a hydraulic pressure to act on the first pressure receiving portion, and a second oil chamber which communicates with the first oil chamber and to which the hydraulic pressure is supplied later than to the first oil chamber to act on the second pressure receiving portion when the hydraulic pressure is supplied to the first oil chamber.

Abstract: A deployment system for user interface devices with enhanced interface capabilities and methods for manufacturing and using same. The deployment system includes a main rotating joint system and a device mounting assembly that are coupled via an extension support system. The main rotating joint system enables the deployment system to be installed at any suitable installation location, such as an armrest; whereas, the device mounting assembly is configured to receive a selected user interface device. Advantageously, the deployment system provides an enlarged internal channel for accommodating larger communication cables and a progressive clutch system for supporting the increased weight of the user interface devices. The deployment system thereby can maintain near-constant tension during deployment of the user interface devices, inhibiting drop injuries to users and damage to the user interface devices.

Abstract: A dynamic pressure control system, such as a transmission pressure control system, is provided wherein one or more of electrical current command signals provided to a pressure control solenoid valve, such as a fast response variable force solenoid pressure control valve, are progressively trimmed in a manner to improve overall system pressure control performance by improving the overall commanded current response. The invention permits use of fast response pressure control solenoid valves and obtainment of in a manner to minimize overshoot and improve steady state accuracy, so as to thereby improve precision pressure control.

Abstract: A control system for a powertrain of a vehicle includes a torque module and a damping control module. The torque module determines a first output torque and a second output torque of the engine. The second output torque is determined after the first output torque. The torque module also determines a torque difference based on the first output torque and the second output torque. The damping control module generates a damping torque in a transmission based on the torque difference.

Abstract: There is provided a method of measuring coupling ratios in a marine vessel. The vessel includes: (a) a source of mechanical power; (b) a coupling system operatively coupled via a first input shaft to the source of power and operatively coupled via a second output shaft to one or more propellers of the vessel; and (c) a controller coupled to a user interface and also to the coupling system such that the user interface is operable via the controller to control a degree of power coupling occurring in operation through the coupling system. The first and second shafts are provided with first and second rotation rate sensors respectively coupled to the controller for generating first and second rotation rate signals indicative in operation of rotation rates of the first and second shafts respectively. The method involves measuring a ratio of the first and second signals when the coupling system is in a fully coupled state.

Abstract: A method for coupling a load to a power source by means of a clutch, the method having the steps of initially increasing the pressure of the actuator to bring the pressure plates of the clutch into contact with the clutch plates gradually increasing the pressure of the actuator even further to allow the clutch plates to be engaged with the pressure plates while decreasing at least ones the pressure during a short time to create pressure dips such that the torque generated over the load is at least temporarily decreased, and levelling the pressure of the actuator to maintain the engagement of the pressure plates with the clutch plates to allow the load to be driven by the power source.

Abstract: The present invention provides a clutch having two pistons, a first piston defining a first, smaller area and a second piston, defining a second, larger area. The separate pistons are independently provided with flows of pressurized hydraulic fluid from first and second independent modulatable control valves. Engagement of the clutch may be rapid by providing hydraulic fluid to the smaller area piston, provide greater engagement force by providing hydraulic fluid to the larger area piston or a combination of speed and force by utilizing modulated or unmodulated flows of hydraulic fluid to both pistons.

Abstract: An automatic transmission includes a control system for controlling a clutch of the transmission. The control system includes a first variable flow solenoid and a second variable flow solenoid, each in selective fluid communication with the clutch. The first variable force solenoid provides hydraulic fluid within a first pressure range of 0 and 1,000 kPa. The second variable force solenoid provides hydraulic fluid within a second pressure range of 0 and 2,000 kPa. A transmission controller sends an electrical signal having a current between the range of 0 and 1 amp to one of the first and second variable flow solenoids. The pressure output of each of the first and second variable force solenoids is a function of, within their respective first and second pressure ranges, the amplitude of the current of the electrical signal to provide two distinct power gains to the single clutch.

Abstract: A transmission control unit predicts a next gear position when a predetermined gear position is achieved. In accordance with a result of the prediction, the transmission control unit operates a predetermined synchromesh to execute a standby control (pre-shift control). In the standby control, a transmission input shaft connected to a friction transfer mechanism not used for achieving a current gear position and a transmission output shaft are connected to each other via a predetermined gear train, and made standby. The transmission control unit makes different from each other an engagement load of the synchromesh when a connection of the synchromesh is done in accordance with the prediction result and an engagement load of the synchromesh when a connection of the synchromesh is done in accordance with the other condition different from the prediction result.

Abstract: A drivetrain for a motor vehicle has a friction clutch for transmitting drive torque for the motor vehicle and has an actuator arrangement for actuating the friction clutch. The actuator arrangement has a first actuator which is designed to close the friction clutch quickly with little force expenditure in order to thus quickly close up the play which is present in the open state of the friction clutch. The actuator arrangement has a second actuator which is designed such that, with a small stroke, it applies a large force for actuating the friction clutch in order to keep the friction clutch closed with little energy expenditure.

Abstract: Engagement of a clutch is at least partially controlled based upon the difference in rotational speed between the drive side of the clutch and the driven side of the clutch. As the rotational speed difference varies, the approach rate of the drive side and the driven side also varies for at least part of the total distance defined between the drive side and the driven side when the clutch is disengaged.

Abstract: A clutch mechanism has rotational driving force outputting members connected to a rotational driving force input system, rotational driving force receiving members connected to a rotational driving force output system, and a pressing mechanism for pressing the rotational driving force outputting members against the rotational driving force receiving members to keep the rotational driving force outputting members and the rotational driving force receiving members in contact with each other. The pressing mechanism has a constant load applying means and a variable load applying means for together generating the pressing force which brings and keeps the rotational driving force outputting members and the rotational driving force receiving members in contact with each other. A value of a load generated by the constant load applying means being set to be less than the maximum non-slide limit, i.e.

Abstract: A method for controlling operational sequencing of gears in an automatic transmission (102) which has been built in an auxiliary mode. In the case of such a shifting transmission it is possible that during the engagement of its transmission gear stage, impact noises or contact noises are present in the shifting procedure. This can occur by the generation of a tooth-on-tooth positioning between the toothing of a sliding collar (126) and the come-along toothing of an idler gear (130, 132). Provision is made for the control of the activation movement of the sliding collar (126) carried out in such a manner that an activation condition impact of the transmission parts, which are partakers in the shifting associated transmission part onto other transmission parts with the least possible impact force and/or with a least possible impact noise level.

Abstract: A magneto-rheological coupling (MRC) having an input assembly and an output member. The output member includes a generally cylindrical drum portion and a hub portion extending radially inwardly therefrom. The generally cylindrical drum portion has a low magnetically permeable region having a plurality of passages defined therein. Additionally, a plurality of apertures are defined by the hub portion. The plurality of passages and apertures enhance the flow of magneto-rheological fluid (MRF) within the MRC. The drum portion has a surface treatment of tungsten-carbide to enhance wear resistance. Additionally, the drum portion has an average roughness, or Ra value, of between 10 and 250 microns.

Abstract: A clutch-actuating device for a clutch in a motor vehicle power train has an actuator motor driving an actuating member and a transfer mechanism which transmits the movement of the actuating member to a clutch release element that is movable against an opposing force of a clutch spring to displace the clutch from a closed position to an open position. The transfer mechanism has a first movement range in which the movement of the actuating member in the opening direction of the clutch does not displace the clutch from its closed position, and a second movement range in which the movement of the actuating member causes a displacement of the clutch. The transfer mechanism has an interval of loose play, which is used up within the first range.

Abstract: A disk spring assembly including a flat disk between two angled plates is used in an automatic transmission clutch application. The inner peripheral edge and the outer peripheral edge of the disk are deflected in opposite directions relative to each other by the angled plates. The maximum deflection of the disk is defined by the angled plates. The stiffness of the disk increases monotonically with the deflection of the disk resulting in smooth clutch application.

Abstract: A friction-based clutch actuation system includes a rotatable input shaft, an output shaft, at least one input clutch plate operatively supported by the input shaft, and at least one output clutch plate operatively supported by the output shaft and moveable thereon. The friction-based clutch actuation system also includes at least one electric motor and at least one piezoelectric actuator operatively connected to the at least one electric motor. The friction-based clutch actuation system further includes a controller electrically connected to the at least one electric motor and the at least one piezoelectric actuator to activate said at least one electric motor to move the piezoelectric actuator relative to the at least one output clutch plate and to activate the piezoelectric actuator to apply a force to the at least one output clutch plate to engage the at least one input clutch plate.

Abstract: A friction-based clutch actuation system includes a rotatable input shaft, an output shaft, at least one input clutch plate operatively supported by the input shaft, and at least one output clutch plate operatively supported by the output shaft and moveable thereon. The friction-based clutch actuation system also includes at least one electric motor and at least one piezoelectric actuator operatively connected to the at least one electric motor. The friction-based clutch actuation system further includes a controller electrically connected to the at least one electric motor and the at least one piezoelectric actuator to activate said at least one electric motor to move the piezoelectric actuator relative to the at least one output clutch plate and to activate the piezoelectric actuator to apply a force to the at least one output clutch plate to engage the at least one input clutch plate.

Abstract: A transmission housing having a modulatable power transmission therein which includes a clutch having interleaved clutch plates and having a central power transmitting shaft extending axially through the clutch. The clutch includes a fluid operated movable piston for effecting clutch operation by compression of the plates. The piston has a smaller piston area and a larger piston area, the smaller piston area has fluid flow directed to it at a variable fluid pressure whereby the clutch is modulatable. The larger piston area is adapted to have fluid flow directed thereto to effect maximum and unmodulatable engagement of the clutch. A spring loaded normally closed trigger valve controls fluid flow to the larger piston area in response to fluid pressure above a predetermined amount at the smaller piston area. The trigger valve is mounted on the outside of the transmission housing and is readily accessible for adjustment, for example.

Abstract: A torque transfer device is provided that includes an input member for receiving torque from an external source. An output member is disposed radially inward of the input member to define a first torque transferring region therebetween. A second torque transferring region is also disposed between the input member and output member. A source of magnetic flux is operable to provide a first level of magnetic flux that transfers torque between the input and output members by activation of the first torque transferring region. The source of magnetic flux is also operable to provide a second level of magnetic flux that transfers torque between the input and output members by activation of both the first torque transferring region and the second torque transferring region. The torque transfer device substantially eliminates the “hard” or sudden engagement of conventional electromagnetic clutches.

Abstract: A modulatable power transmission clutch including interleaved clutch plates and having a central power transmitting shaft extending axially through the clutch. The clutch includes a fluid operated movable piston for effecting clutch operation by compression of the plates. The piston has a smaller piston area and a larger piston area, the smaller piston area has fluid flow directed to it a variable fluid pressure whereby the clutch is modulatable. The larger piston area is adapted to have fluid flow directed thereto to effect maximum and unmodulatable engagement of the clutch. A spring loaded normally closed trigger valve controls fluid flow to the larger piston area in response to fluid pressure above a predetermined amount at the smaller piston area. The trigger valve is mounted in the shaft and is normally closed so that pressure fluid is directed to the smaller piston area at a variable fluid pressure whereby the clutch is modulatable.

Abstract: An electromagnetic clutch (10) for an air conditioning compressor includes a generally cylindrical pulley (11) rotatably mounted on a compressor housing (16) and having an annular friction surface (21b), a driven member (12) mounted on a compressor shaft (13) and having an annular friction surface (21a) positioned radially adjacent the first friction surface to form an annular space (21c) therebetween. A quantity of flowable magnetic material (27) is provided in the annular space (21c) and a magnetic coil (34) is fixed on the housing adjacent thereto. A control (40,46,46′) connected to the magnetic coil (34) supplies electrical power from a power supply (47) to energize the magnetic coil and create magnetic flux in the annular space (21c) polarizing the magnetic material and frictionally coupling the first and second friction surfaces (21a,21b) to cause the pulley (11) to rotate the driven member (12).