RU112721U1 - MECHANICAL ENERGY CONVERSION DEVICE - Google Patents

Abstract

A device for converting energy, containing a shaft and levers interacting with the elements mounted on the shaft, characterized in that the shaft has a cavity made coaxially with it, in which a carriage is placed, installed with the possibility of reciprocating movement, on the surface of which at least at least one recess with a slope along the axis of the shaft, with which the rotating ball contacts pointwise, installed with the ability to perceive the energy of the force applied to move the carriage and transmit it for conversion at the moment of forces, the rotating shaft, to the actuator, which is a system of levers, consisting of a calculated the number of levers installed with the possibility of point acceptance and point transmission of forces applied to them in such a way that the output force of the previous lever is input for the next one, while the elements installed on the shaft with which the levers interact, the device contains rigidly fixed to the wa lu brackets, the free ends of which are installed in nodes, which are frames, in which brackets and levers are fixed in tight point contact with the frames and with each other.

Description

The utility model relates to the field of energy and relates to the use of the transformed difference of the applied forces for rotation of the rotor.

A known converter of wind and wave energy, which contains rotating platforms connected with levers. On each platform a blade is installed. The energy transducer also contains kinematically coupled motion transducer and a unit for changing the orientation and fixing the position of the blade interacting with the weather vane (RU 2254494, 09/10/2003, F03D 5/04).

The disadvantages of the known energy Converter include the complexity of the design and the inability to use on land.

It is also known a device for converting wind energy, river flow, waves, containing a shaft kinematically connected with an electric generator, and radial levers interacting with overrunning clutches mounted on the shaft, while the clutch couplings with radial levers takes place in turn (RU 2409763, 14.01. 2009, F03D 5/06).

The disadvantage of this device is its attachment to a natural source of energy.

The task of the utility model is to develop an environmentally friendly stand-alone device that uses the converted difference in the applied force to rotate the rotor.

The problem is solved in that in the device for converting energy containing a shaft and levers interacting with elements mounted on the shaft, the shaft has a cavity made coaxially with it, in which a carriage is installed, mounted with the possibility of reciprocating movement, on the surface of which is made at least one recess with a slope along the axis of the shaft, with which a rotating ball is point-contacted, installed with the ability to absorb the energy applied to move the carriage and to get it for conversion at the moment of forces, a rotating shaft, to an actuator, which is a system of levers, consisting of the estimated number of levers installed with the possibility of point acceptance and point transfer of the forces applied to them in such a way that the output force of the previous lever is input for the next, while as elements mounted on the shaft with which the levers interact, the device contains brackets rigidly fixed to the shaft, the free ends of which are installed in nodes, constituting a framework in which brackets and levers are fixed in close point contact with the frames and with each other.

The accompanying drawings show: FIG. 1 is a general view of the device with a cut of the hollow part of the shaft; figure 2 - a view of a General view of the device; figure 3 is a top view of a General view of the device; figure 4 is a section bB of the General view of the device.

The device consists of a frame 1 with two bearing units 2 fixed in it, in which a multi-shaft shaft 3 is installed. In the front part of the shaft 3, inside it and coaxially with it, a cavity 4 is made, in which a carriage 5 s is mounted with the possibility of reciprocating movement made on its surface nests 6, in which the balls 7 are placed, installed in the grooves 8 with the possibility of free movement in them. The free end of the carriage 5, extending outward from the cavity 4 of the shaft 3, is connected through the bearing assembly 9 to the small shoulder of the lever operation control device 10, on the large shoulder of which there is a handle 11 with a lock 12 of the control lever 10 in the sector 13 scale.

On the surface of the carriage 5, two recesses 14 are made slanted along the axis of the shaft, in which a pair of balls 15 are installed, which contact the rods 16, which are installed in the body of the shaft 3 opposite each other and mounted in a frame 17 that spans the shaft 3 and is an input element of the device’s actuator . The frame 17 is connected by a rigid ligament 18 to a node 19 in which there is a double-sided support point of the first lever 20 in the form of balls 21 installed in point contact with the slats of the node 19 and with the lever 20 from its two opposite sides.

The lever 20 is the first lever of the actuator of the device, which is a single lever system, consisting of the estimated number of interconnected levers mounted on the brackets of the shaft 3, with the possibility of interaction with each other in the so-called nodes, including balls 21, tightly pressed to the levers, brackets and strips forming these nodes, and providing their point contact. The described design of the actuator together with the shaft forms the rotor of the device.

The large arm of the lever 20 is installed in the node 22, rigidly connected by a bundle 23 with the node 24, in which the small shoulder of the lever 25 is installed.

The bilateral support point of the lever 25 in the form of balls 21 is located in the node 26, in which it is in point contact with the big shoulder of the lever 27, and the big shoulder of the lever 25 in turn contacts the first bracket 29 of the shaft 3 relative to the control lever 10.

The small lever arm 20 is installed in the node 30, rigidly connected by a bundle 31 with the node 32, in which the large lever arm 33 is mounted, and its bilateral support point in the form of balls 21 is placed in the node 34 of the link 35 with the node 36, in which the bilateral support point is installed in the form of balls 21 of the crank arm 37, located in the same plane with the bracket 38 of the shaft 3.

Figure 2 shows that the levers 20 and 25 are installed parallel to each other and perpendicular to the axis of rotation of the shaft 3 and together with the bracket 29 of the shaft 3 form the first lever cell, initiating the transfer of the converted difference of the total magnitude of the applied forces to the leading bracket 39 of the actuator of the device.

The second lever cell is formed by the brackets 40 and 41 of the shaft 3 together with the crank lever 42, mounted in the same plane with the bracket 43 and the lever 37, which is connected with the small arm through the node 44 to the arm 38, and connected with the large arm through the node 45 to the arm 43. The bilateral support point of the lever 27 is located in the node 46, paired with the node 47, in which, similarly to the node 36, the bilateral support point of the cranked lever 42 is installed. One shoulder of the lever 42 is connected by the node 48 to the bracket 40, and its other shoulder is connected by the node 49 to the bracket 41.

The third lever cell (see figure 4) form a cranked lever 50 and the bracket 51 of the shaft 3, mounted in the same plane perpendicular to the axis of rotation of the shaft 3.

Between the second and third lever cells, an arm 52 of the shaft 3 is connected, connected by a node 53 to the small arm of the lever 27. The end of the arm 52 is connected to a node 54 paired with the node 55, in which there is a double-sided fulcrum of the crank lever 50, which is connected by its small arm through the node 56 with the bracket 51 of the shaft 3.

The small shoulder of the lever 33 through the node 57 is connected to the small shoulder of the last lever 58, the bilateral support point of which is located in the node 59, paired with the node 60, which houses the large shoulder of the crank lever 50. The large shoulder of the last lever 58 through the node 61, ligaments 62 and node 63 acts on the end of the leading bracket 39 of the shaft 3, which is part of the output shaft 64 of the rotor of the device.

The device operates as follows.

The design of the claimed device allows you to convert the mechanical energy of the force applied to the control lever 10 through the actuating lever mechanism in the energy of the reverse rotation of the rotor.

To bring the device into rotation in one of the sides, move the control lever 10 so that the latch 12 switches to a position, for example, “+” on the scale of sector 13. In this case, the force applied to the large shoulder of the lever 10 by the small shoulder of the lever 10 through the bearing assembly 9 on the carriage 5, which, moving to the right inside the cavity 4 (see Fig. 1), by the sloping surface of the recess 14 presses on the ball 15, which acts on the rod 16, which transfers force to the frame 17 and then through the bundle 18 to the node 19, in which when transferring force to the lower a first support point each lever 20 comes first transformation reaction of the applied force.

The lever 20 distributes the force applied to it by the gear ratio of its small and large shoulders in the form of different total values up on both sides of the shaft 3.

With the large arm, lever 20 transmits the converted moment of lower force through the assembly 22, the bundle 23 and the assembly 24 to the small arm of the arm 25, the upper support point of which transfers the converted resultant moment of force through the ball 21 through the lower ball 21 of the assembly 26 to the large arm of the arm 27, and with a shoulder, lever 25 transmits a transformed moment of a lower force through a ball 21 in a node 28 to an arm 29. With a smaller shoulder, a lever 20 simultaneously transmits a converted moment of a greater force through a node 30, a bundle 31, and a node 32 to a large shoulder of a lever 33, which the pore transmits the converted resultant moment of force from the first lever cell to the second through the node 34, the bundle 35, the node 36 to the fulcrum of the crank lever 37, which transfers the converted moment of greater force through the node 44 to the bracket 38 with the small shoulder, and transfers the converted moment to the smaller forces through the assembly 45 to the bracket 43.

The lever 27 by the upper support point transmits the resulting moment of force from the first lever cell to the second lever cell through the node 46 and the unit 47 paired with it to the upper support point of the cranked lever 42, which transmits the moment of force through the node 49 with the right shoulder (see Fig. 2) on the bracket 41, and its left shoulder transfers the moment of force through the node 48 to the bracket 40. At the same time, the lever 27 with the small shoulder in the node 53 transmits the converted moment of greater force to the bracket 52.

The small arm lever 33 transfers the transformed moment of greater force through the node 57 to the small arm of the last lever 58, which transfers the resulting moment of force to the third lever cell with the lower ball 21 of the support lever through the node 59, the unit 60 paired with it to the large arm of the crank lever 50, which the transformed resulting moment of force through the coupled nodes 55 and 54 transfers to the end of the bracket 52. With a small shoulder, the lever 50 transfers the converted moment of greater force through the node 56 to the bracket 51.

The large arm of the lever 58 transmits the converted moment of lesser force through the node 61, the bundle 62, and the node 63 to the end of the driving bracket 39, driving the shaft 3, which is mated to the output shaft 64 of the rotor.

To brake the shaft 3 and change the direction of its rotation by the handle 11, the control lever 10 is moved to the neutral position of the lock 12 and to the “-” position of the sector scale 13. In this case, the carriage 5 moves to the left side inside the cavity 4 (see Fig. 1) , and the sloping surface of the lower recess 14 presses on the ball 15, which acts on the rod 16, which transfers the force to the frame 17 and then through the bundle 18 to the node 19, in which the transmission of force occurs at the upper support point of the first lever 20, where the first transformation reactions from attached with ly and operation of actuator lever mechanism is similar to that described, but with the transfer of torques converted via the balls 21 installed in nodes oppositely to those employed when the latch 12 in the "+" sector scale 13.

The technical result of the claimed device is the ability to use the converted difference of the applied forces to rotate the rotor in a stand-alone environmentally friendly device. This result is achieved by the fact that the design of the lever system of the actuator converts the smaller component of the applied force F ₁ and the larger component of the applied force F ₂ , which are directed along the same line of action in opposite directions, while their equal total values are mutually compensated without a remainder, and the uncompensated difference applied force F ₃ (F ₂ -F ₁ = F ₃₎ is used by converting it into a moment of force, which brings the rotor from rest, bringing it in a controlled or the reverse rotation can.

Claims (1)

A device for converting energy, comprising a shaft and levers interacting with elements mounted on the shaft, characterized in that the shaft has a cavity made coaxially with it, in which a carriage is installed, mounted with the possibility of reciprocating movement, on the surface of which at least at least one recess with a slope along the axis of the shaft, with which the rotating ball is point-contacted, installed with the ability to receive the energy of the force applied to move the carriage and transmit it to the formation of a rotational shaft at the moment of force, to an actuating mechanism, which is a system of levers, consisting of the calculated number of levers installed with the possibility of point acceptance and point transfer of the forces applied to them in such a way that the output force of the previous lever is input for the next one, while the quality of the elements mounted on the shaft, with which the levers interact, the device contains brackets rigidly fixed to the shaft, the free ends of which are installed in nodes representing and frames in which the brackets and levers are fixed in close point contact with the frames and with each other.