SU932026A1 - Method and apparatus for converting kinematic energy of mechanism links to potential energy and vice versa - Google Patents

Description

(5+) METHOD FOR CONVERTING KINETIC ENERGY

THE LINKS OF THE MECHANISM IN THE POTENTIAL AND REVERSE AND DEVICE FOR ITS IMPLEMENTATION

I

The invention relates to mechanical engineering, namely, to inertial drives of metal presses for pressure treatment and can be used as a drive for various machines that require short-term efforts of significant magnitudes.

A known method for converting the kinetic energy of the links of the mechanism into a potential one and vice versa is that the leading link of the mechanism is connected to the flywheel of the inertial energy accumulator and the flywheel is rotated around its own axis, after which the battery is connected to the driven link l, the acceleration of the flywheel is performed only in one direction around its own axis of rotation.

This method is implemented, for example, using a device for converting the kinetic energy of the links of the mechanism into potential and vice versa.

Claims (2)

containing a base, a flywheel mounted on it, a flywheel accelerating drive and an output shaft, this device also contains an inertial variator including a holder with an inner profiled surface, a sleeve and mounted on the sleeve on the axles rotatably levers with rollers interacting with an inner shaped surface the cages, in the levers along their length, are made slots in which the axles are placed, the drive is equipped with three overrunning clutches, two of which connecting the accelerating motor shaft and the flywheel shaft with vnt The variable speed variable is installed with the possibility of transmitting rotation in one direction, and the third connecting the variator holder with the flywheel shaft is installed with the possibility of transmitting rotation in the direction opposite to the direction of rotation transmitted by the first two couplings, while the variator is equipped with a block inclusion coupling connecting clip and sleeve variator 2j. A disadvantage of the known method and device is that they both bake low energy intensity and efficiency. This is due to the fact that the flywheel is accelerated only in one direction - around its own axis of rotation, and also because high speeds require complex equipment with a large number of kinematic pairs and friction surfaces in order to increase power consumption. , in turn, reduces the efficiency of the device. The purpose of the invention is to increase energy consumption and efficiency. The present invention is aimed at creating a method for transforming the kinetic energy of the links of a mechanism into a potential one and vice versa, as well as devices for its implementation, the sequence of operations and the design of which, respectively, would increase energy intensity and efficiency. The goal is achieved by the way in which the kinetic energy of the links of the mechanism is transformed into potential and vice versa is that the leading link of the mechanism is connected to the flywheel of the inertial energy accumulator and the flywheel is rotated around its own axis, after which the battery is connected to the driven link , the flywheel is informed by an additional rotation about the vertical axis by the driving member and synchronizes both the rotations of the flywheel by means of a support surface. In this case, both rotations are performed by tilting the support surface and subsequent communication to the flywheel of the horizontal impulse of the portable movement, and tilting to the positive angle of the supporting surface with the flywheel and the horizontal impulse to it, during rotation, periodically twice per turn of the flywheel around the vertical axis. In the device, for converting the kinetic energy of the links of the mechanism into potential and vice versa, containing a base, a flywheel placed on it, a flywheel booster drive and an output shaft, the flywheel is made in the form of a disk, which is freely mounted on the end of the beam, the device is equipped with adjustable stops mounted on the base limiters, a drive control switch, an annular platform installed on the base of the NII with the possibility of swinging relative to it by means of cylindrical hinges and interacting with stops and limiting devices placed in its center and rigidly connected with it a hollow body, a vertical shaft mounted in a hollow body rotatably and rigidly connected at one end with a beam, and the second kinetically connected with an output shaft in the form of two power cylinders mounted on the base and placed on both sides of the platform swing axis and interacting with it, an element with two diametrically located tides is fixed on the vertical shaft, periodically interacting them with a jog drive switch. In addition, the booster drive can be equipped with an additional flip pusher that interacts with the bearing surface of the flywheel, and the stops-limiters are installed with the possibility of simultaneous extension in the direction of the platform. In this case, the flywheel is mounted on the beam with the possibility of fixation and translational movement along the axis of the vertical shaft, followed by locking. FIG. 1 shows an apparatus for carrying out the method; in FIG. 2, section A-A in FIG. one; in fig. 3 scheme of the acceleration pulse on the flywheel. The device contains a base 1, a flywheel 2 placed on it, an accelerating drive of the flywheel 2 and an output shaft 3 The flywheel 2 is made in the form of a disk, which is loosely mounted on the end of the beam k. The device is equipped with adjustable stop-limiting devices 5 and 6 installed on the base 1, a drive control switch 7, an annular platform 8 mounted on the base 1 with the possibility of swinging relative to it by means of cylindrical hinges 9 and 10 and cooperating with the limit stops 5 and 6. The device is also provided with a ring shaft 8 placed in the center of the ring platform 8 and a rigidly connected hollow body 11, a vertical shaft 12 mounted in a hollow body 1 1 rotatably and tightly connected at one end to the ball which, and the second - kinematically connected, for example, by means of a gear transmission - a pair of bevel wheels 13 and 14; with the output shaft; the 3-stage drive is made in the form of two power cylinders 15 and 6 mounted on base 1 and placed on both sides of axis 17 swing platform form 8 and interacting with it. On the vertical shaft 12, the element 18 is rigidly mounted with two diametrically located tides (not shown), periodically interacting with the limit switch 7 of the drive. The latter is equipped with an additional flip pusher 19 interacting with the supporting surface 20 of the flywheel 2, and the stops-stops 5 and 6 are installed with the possibility of simultaneous extension to the. the direction of the platform 8. The flywheel 2 is mounted on the block with the possibility of fixation, for example, using an electromagnetic lock (not shown) and translational movement along the axis of the vertical shaft followed by locking (means for moving the flywheel 2 with the beam k and the stopper are not shown). The device works as follows. In the initial position (Fig. 1), platform 8 is inclined at a negative angle Jf and rests on stop-restraint 6, and the flywheel 2 is at its lowest point (angle oi Q). Then the flywheel drive 2 is actuated. raises the edge of platform B with the flywheel 2, and the power cylinder rod 16 is lowered and the starting plunger 19 is turned on, which pushes the flywheel 2 off the dead center and informs the impulse in the direction of rotation. The flywheel 2 rolls off the inclined support surface of the platform 8 and under the action of inertial forces, passes a new low point., Located at IBO (Fig. 3) is lifted along the support surface of the plate of form 8 to point 21 of sector No. 2. At this point element 18, through switch 7, enters the lifting mode of the platform 8, the power cylinder 16, currently under the flywheel 2, and the power cylinder 15 to the lowering mode of the platform 8, and the platform 8 changes the tilt sign and raises the flywheel 2. 3 same time when moving the flywheel 2 from point 21 to point 22 sector 2, it receives a horizontal impulse, since the rotational speed of the flywheel 2 around the vertical axis is less, the rate of change of the platform angle 8. The flywheel 2 folds the inclined bearing surface of the platform 8. At the same time, the starting plunger 13 leans back on the hinge (not indicated), and the cycle c the acceleration of the flywheel is repeated. When the flywheel 2 reaches the design speed, i.e. when the travel time of the flywheel 2 from point 21 to point 22 of any of sectors No. 1 and H ° 2 becomes equal to the impulse time, the device enters the stationary mode. Since the speeds of movement of the flywheel 2 and the impulse transmitted to it from platform 8 are equal, the flywheel 2 no longer receives an acceleration pulse, and the energy of the cylinders 15 and 16 is spent only on changing the inclination of the platform 8 and raising the flywheel 2 without accelerating the latter. Before connecting the device to the follower link 3, for example, to the press, the limit stops 5 and 6 simultaneously move upwards, and the platform 8 is set to a horizontal position, then the driven shaft 3 is connected, and the accumulated energy from the flywheel 2 is transmitted to it. To use the device as a simple converter of successive reciprocating movements of the rods of the power cylinders 15 and 16 to the rotational continuous movement of the output shaft, the flywheel 2 is fixed to the beam k using, for example, an electromagnetic lock (not shown, moves on the vertical shaft 12 in the direction from. platform 8 and stop in this position with a stopper of any known construction (not shown). When the power cylinders 15 and 16 are alternately operated, platform 8 is periodically tilted 11, a vertical shaft 12, a beam k and a flywheel 2 rigidly connected with it. Since the flywheel 2 is located on a certain arm equal to the length of the beam, and the feather: the numerical elements of the structures are located at some angle from the vertical, under the action of a torque is created in the tin, which is transmitted through a pair of gears 13 and H to the driven al Flywheel 2 can be made in a reinforced concrete structure with the aim of reducing the cost of the drive for powerful processes. The use of the proposed method and device for its implementation provides increased efficiency and power consumption of the system at a relatively small number of revolutions due to the rotation of the flywheel around its own and vertical axes of rotation. Formula 1. The method of converting the kinetic energy of the links of the mechanism into the potential and vice versa is that the leading link of the mechanism is connected to the flywheel of the inertial energy accumulator and the flywheel is rotated around its own axis, after which the battery is connected to the driven link, that, in order to increase energy intensity and efficiency, the flywheel is communicated with additional rotation about the vertical axis by the driving link and synchronizes both turns of the flywheel by means of a support surface. 2. The method according to claim 1. characterized in that both rotations are performed by tilting the support surface and subsequent communication to the flywheel of the horizontal impulse of the portable movement, and tilting to the positive angle of the bearing surface with the flywheel and telling the horizontal impulse during the rotation, periodically - twice for one revolution of the flywheel around the vertical axis. 3. A device for converting: the kinetic energy of the links of the mechanism, Mv to potential and vice versa, containing a base, a flywheel placed on it, a flywheel accelerating drive and an output shaft are distinguished by the fact that the flywheel is made in the form of a disk, which is freely fitted at the end of the beam, the device is provided with adjustable limit stops installed on the base, a drive control switch, an annular platform mounted on the base with the possibility of being rocked relative to it by means of cylindrical hinges and interacting with limit stops placed in the center of it and rigidly connected with it a hollow body, a vertical shaft mounted in the hollow body rotatably and rigidly connected with one end to the beam, and the second is kinetically associated with the output shaft, accelerating the drive is made in the form of two power cylinders mounted on the base and placed on both sides of the swing axis of the platform and interacting with it, an element with two diametrically located tides is fixed on the vertical shaft, periodically interacting with travel drive switch. . Device pop 3 characterized in that the acceleration actuator is provided with an additional tilting pusher interacting with the bearing surface of the flywheel, and the limit stops are mounted with the possibility of simultaneous extension towards the platform. 5. The device according to claim 3. characterized in that the flywheel is mounted on the beam with the possibility of fixation and translational movement along the axis of the vertical shaft with subsequent locking. Sources of information. Taken into account during the examination 1.Gulia N.V. Inertia energy accumulators. Ed. Voronezh University, Voronezh, 1973. with. SS (prototype). 2. USSR author's certificate number 605051, cl. F 16 H 33/02, 1976 (prototype).