RU2483940C1 - Hybride powertrain (versions) - Google Patents

Abstract

FIELD: transport.

SUBSTANCE: set of inventions relates to machine building and may be used as powertrain transport vehicles. The hybrid powertrain in the first and the second versions contains multirange continuously variable transmission which includes varying link. Vrying link contains two reversible electric machines. Transmission from flywheel storage shaft to output shaft of multirange continuously variable transmission is made as three-link differential. To one of differential links the flywheel shaft is kinematically attached, to the other link the input shaft of multirange continuously variable transmission is kinematically attached, and to the third link the reversible electric machine is kinematically attached. Three electric machines are electrically connected with each other being capable to exchange electric power. The hybrid powertrain in the first version contains standalone source of mechanical energy. The hybrid powertrain in the second version contains electric energy accumulator.

EFFECT: higher powertrain efficiency in all modes of vehicle movement.

3 cl, 2 dwg

Description

The invention relates to mechanical engineering and can be used as a power unit for both stationary and transport vehicles.

Hybrid power units of vehicles are known, including a heat engine, electric accumulators, an electromechanical transmission comprising an electric generator, an electric motor, a control system and a mechanical transmission with a simple (single) separation of the power flow, where differential mechanisms are present (see, for example, N. V. Gulia, “Amazing Mechanics”, Moscow: ENAS, 2006, p.167, Toyota Prius hybrid vehicle circuit).

The disadvantage of this device, taken as an analogue, is the low specific power for the recovery of braking energy, which, firstly, is associated with a low specific power of electric accumulators, and secondly, with a reduced power of electric machines in the hybrid transmission, not designed to pass the full braking power vehicle. In transmissions with separation of the power flow, including electromechanical, only part of the power passing through the transmission passes through the electric machines. This allows you to perform electric machines with reduced dimensions and weight, and also increases the efficiency of the transmission, since losses in electric machines are approximately proportional to the mechanical power passing through them. From this point of view, it is advantageous to carry out the transmission so that the power of electric machines is minimal. But in this case, energy recovery during braking of the vehicle will become ineffective, since the power of the electric machines is not enough to transfer to the electric accumulator a significant part of the braking power, often exceeding the installed power of the main engine of the vehicle. The recovery of braking energy is a significant factor in increasing the efficiency of the vehicle.

The use of energy as a storage device for the recovery of flywheel drives, which can receive and give incomparably greater specific power than, for example, electrochemical batteries, and at the same time have a significantly higher specific energy consumption than, for example, supercapacitors, provides a slight increase in efficiency. , N.V. Gulia, “Amazing Mechanics”, Moscow: ENAS, 2006, p. 162). This led to the creation of power units of vehicles, including an electrochemical energy source, an electric transmission and a flywheel energy storage device with electric power take-off, which was carried out in a hybrid electric car - taxi, developed in the USA (see, for example, N.V. Gulia “Amazing Mechanics ", M .: ENAS, 2006, pp. 169-170). This device is also taken as an analogue.

The disadvantage of an analog device is the large installed capacity of electric machines and high energy losses during the transfer of energy to the flywheel and vice versa due to the multiple conversion of its shape.

There is also known the design of the power plant of a vehicle with a flywheel drive, and the drive from the flywheel shaft of the flywheel drive to the subsequent transmission elements on the wheels of the transport machine includes a three-link differential mechanism and two energetically coupled electric machines (see US patent No. 4233858, class F16H 37/06 , 1980). This design allows you to increase the efficiency and specific power of the transfer compared to gears with a purely electric power take-off from the drive. The described design is also taken as an analog.

The disadvantage of the analogue design is a narrow range of effective regulation of the gear ratio, the expansion of which will lead to a sharp increase in the installed capacity of electric machines and a decrease in transmission efficiency.

As a prototype, a device was selected that is as close as possible to the invention both in terms of the combination of essential features and the effect achieved - this is a hybrid electric vehicle power unit described and presented on the diagrams on page 163 of N.V. Gulia’s book “Amazing Mechanics” (M. : ENAS, 2006). The prototype device includes a flywheel drive, a supervator, an autonomous electric energy source (battery or electrochemical generator) with an electric motor acting as a vehicle engine, kinematically connected with both the input shaft of the supervariator and the flywheel shaft (super flywheel) of the flywheel energy storage device, with the possibility of both separate and simultaneous connection. A supervariator is a multi-band multi-threaded stepless transmission with a varying link and a complex (two-time) separation of the power flow, due to the presence of at least two differential mechanisms in the differential transmission (see RU patent No. 2410587, authors: Gulia N.V., Davydov V.V. .). The output shaft of the supervariator is kinematically connected to the propulsion device (drive wheels) of the vehicle.

The prototype device eliminates the main drawback of analog devices, since the drive’s flywheel is made with mechanical power take-off, and the power that is supplied to the flywheel or is taken from the flywheel can be several times higher than the installed power of the varying supervator link. The necessary range of gear ratio adjustment is achieved due to the presence of several relatively narrow stepless ranges connected by honey, therefore the installed power of the varying link (mechanical variator, electric or hydraulic variator) can be very small (optimum for a vehicle - 10 ... 15% of the total transmitted mechanical power) .

The disadvantage of the prototype device is that the varying link of the supervariator is made in the form of a mechanical variator, which does not allow the use of electrical energy from an autonomous source without the use of an additional traction motor. Another disadvantage is the constant gear ratio between the flywheel shaft and the input shaft of the supervator. To efficiently charge the flywheel from the engine, it is necessary to have an adjustable gear ratio between the engine and the flywheel shaft, since the speed of the flywheel changes significantly as the amount of energy stored in it changes, and the optimal engine speed can be in a narrower range.

The objective of the invention is the creation of a power unit based on a heat engine that provides high efficiency in all modes of movement of a vehicle (car), small dimensions, weight and cost.

Another objective of the invention is the creation of a power unit based on an electric energy storage device that provides high efficiency in all modes of movement of a vehicle (electric vehicle), a uniform load of an electric energy storage device, small dimensions, weight and cost.

This problem is solved by the fact that a hybrid power unit is proposed that includes at least one autonomous source of mechanical rotational energy, a multi-band multi-threaded continuously variable transmission from said autonomous source of mechanical rotational energy to a consumer of mechanical energy, and also a flywheel with transmission from the flywheel shaft to the input shaft of the aforementioned transmission, characterized in that the multi-range multi-threaded continuously variable transmission includes a variable link, containing It consists of two reversible electric machines, and the transmission from the flywheel drive shaft to the input shaft of a multi-band multi-threaded continuously variable transmission is made in the form of a three-link differential mechanism, the flywheel shaft is kinematically connected to one of its links, the input shaft of a multi-range multi-stream multi-stream continuously variable transmission is kinematically connected to the other link, and the third link is kinematically connected to a reversible electric machine, and all three of the mentioned electric machines are electrically ki are connected with each other with the possibility of exchanging electrical power.

Another feature of the invention is that the hybrid power unit contains a controlled friction clutch between the output shaft of an autonomous source of mechanical rotational energy and the input shaft of a multi-range multi-threaded continuously variable transmission.

This problem is also solved by the fact that the proposed hybrid power unit, including at least one drive of electric energy, a flywheel drive, multi-band multi-threaded continuously variable transmission, as well as transmission from the flywheel shaft to the input shaft of the said transmission, characterized in that the multi-range multi-threaded continuously variable transmission includes a variable link containing two reversible electric machines, and the transmission from the shaft of the flywheel drive to the input shaft of a multi-range the continuous flow transmission is made in the form of a three-link differential mechanism, the flywheel shaft is kinematically connected to one of the links, the input shaft of a multi-band multi-threaded continuously variable transmission is kinematically connected to the other link, and a reversible electric machine is kinematically connected to the third link, all three of the mentioned electric machines are electrically connected with each other and with an electric energy storage device with the possibility of exchanging electrical power.

These differences allow you to get a technical effect, which consists mainly in ensuring how efficient energy is transferred from its sources - a flywheel, a heat engine and an energy storage device - to a consumer of this energy, taking into account the specifics of the machine - with low power, with peak loads, energy recovery .

The device of various versions of the hybrid power unit is presented in figures 1 and 2.

Figure 1 shows a hybrid power unit based on a flywheel drive with a dual-stream power output and an autonomous energy source, such as a heat engine with a starting system and clutch. The flywheel drive, located in a sealed housing 1, includes a flywheel 2, the shaft of which is connected to the internal Central gear 3 of the differential mechanism 4 (circled by a dashed line). The external central gear wheel 5 of the differential mechanism 4 is connected to the rotor 6 of the electric machine, the fixed stator 7 of which is electrically connected to the control system of the said electric machine, for example, an inverter 8. The carrier 9 of the differential mechanism 4 is driven by a shaft 10, sealed with, for example, a magneto-liquid seal 11, the drive gear wheel 12. The driven gear wheel 12 is rigidly connected to the input shaft 13 of a multi-band multi-threaded continuously variable transmission (supervariator). The output shaft of the heat engine 14 is also connected to the input shaft 13 through the clutch 15. The shaft 13 passes in the example specific embodiment of the supervator through the hollow rotor of the electric machine 16 and is connected to the carrier 17 of the differential mechanism of the first separation 18 (circled by a dashed line), which first divides the flow power coming from the shaft 15, and part of the power is sent to a variable link, including reversible adjustable electric machines 19 and 16, controlled, respectively, by inverters 20 and 21, and the remaining I power flow portion is sent to the differential mechanisms 22 and 23 (outlined by a dashed line) for the subsequent (second) of the separation.

The differential mechanism of the second separation of direct modes 22 and the differential mechanism of the second separation of reverse modes 23 together with the differential mechanism of the first separation 18 form a differential block 24 (circled by a dashed line).

The input shaft 13 of the supervariator is also connected to the carrier 25 of the differential mechanism 23 and to the central external gear 26 of the differential mechanism 22, the carrier 27 of which, like the central external gear 28 of the differential mechanism 23, is kinematically connected to the matching gear 29 (circled by a dashed line). The shaft of the electric machine 19, fixed, like the electric machine 16, on the supervator case 30, is connected to a gear wheel 31 leading the central gear 32 of the differential mechanism of the first division 18, which in turn is connected to a common central internal gear 33 of the differential mechanisms 22 and 23. The central inner gear 34 of said differential mechanism 18 is connected to the hollow rotor of the electric machine 16.

Part of the power from the wheel 32 after its first separation in the differential mechanism 18 is supplied to the matching gear 29 through the link 35 connecting them.

Matching gear 29 is made planetary and consists of planetary gear 36 (circled by a dashed line) and planetary gear 37 (circled by a dashed line), the central inner wheels 38 and 39 of which are connected, respectively, with link 35 of the differential mechanism 18 and with the central external gear 28 differential gear 23. To the carrier 27 of the differential gear 22 and to the central external gear 28 of the differential gear 23 are also connected, respectively, the gear coupling 40 and 41, made with the possibility of together with the corresponding coupling halves 42 and 43 located on the axially movable elements 44 and 45, connected with the possibility of transmitting torque with the carrier 46 matching gear 29. The carrier 46 is connected to the output shaft 47. Elements 44 and 45 are axially moved by forks 48 and 49, the central external gears 50 and 51 of the planetary gears 36 and 37 are arranged to be braked with brakes 52 and 53, respectively.

Figure 2 presents a diagram of the proposed device according to the second embodiment. The difference between the device of FIG. 2 and the device of FIG. 1 is the presence of an electric energy storage device 54 and the absence of the heat engine 14 of FIG. 1.

The energy storage device 54, for example an electrochemical battery, is electrically connected to inverters 8, 20 and 21, controlling the electric machines 7, 19 and 16, respectively. Thus, the energy storage device 54 plays the role in the device of FIG. engine 14, with the difference that engine 14 supplied mechanical rotational energy to the device, and electric energy storage 54 supplied electrical energy that was transformed into mechanical energy in these electric machines.

In both embodiments of the device, the output shaft 47 of the supervator results in a payload, for example, a propulsion device (drive wheels) of a vehicle.

The operation of the device of figure 1 is as follows. In steady-state modes of vehicle movement, the power of the heat engine 14 is transmitted to the propulsion device through a supervator. The electric machine 7 is de-energized in this mode, the rotor 6 rotates freely, so the epicycle 6 can rotate in any direction at any speed, which is determined by the magnitude and direction of the rotation speed of the two other links of the differential mechanism 4 - the carrier 9 and the sun wheel 3. Thus, when de-energized electric machine 7 flywheel 2 has no power connection with the input shaft 13 of the supervator.

The operation of multi-band continuously variable transmission (supervator) is as follows. The rotation of the input shaft 13 is supplied to the carrier 17 of the differential mechanism 22 of the first separation of the power flow and the carrier 25 of the differential mechanism 23 of the second power flow separation of the direct modes, as well as the central external gear 26 of the differential mechanism 22 of the second power flow separation of the reverse modes connected to the carrier 25. Further, rotation from the central outer gear 32 is supplied to the common central inner gear 33 of the differential mechanisms 22 and 23 of the second power flow separation. Through the said differential mechanism 18 of the first separation — its central gears 34 and 32 — the shaft 13 is connected to the shaft of the electric machine 19 and the hollow rotor of the electric machine 16, and due to the differential mechanism 18 only part of the power is sent through the electric machines 19 and 16. Thanks to the second separation of the power flow in differential mechanisms 22 and 23, this part of the power is further reduced and, for small ranges of regulation of the gear ratio of the supervariator, averages about 10% of the total gear my supervariatorom mechanical power. Drove 27 of the differential mechanism 22 and the external gear 28 of the differential mechanism 23 transmit the total power that has partially passed through electric machines 19 and 16, playing the role of a varying link, and partially through the gears of the differential mechanisms 18, 22 and 23, to the planetary matching gear 29. The purpose of the matching gear 29 is to convert the rotational speeds that are regulated in a relatively narrow range, issued by the aforementioned carrier 27 and the wheel 28, into continuously, without interrupting the power flow, adjustable the rotation range of the output shaft 47 of the transmission. For example, when the rotation speed of the shaft 13 is 2000 min ^-1 , and the gear ratio of the varying link (the ratio of the rotation speed of the shaft 13 to the rotation speed of the link 35) changes from infinity to unity, with an electric transmission efficiency of about 0.8, the rotation speed of the link 35 increases from 0 to 2000 min ^-1 , and the speed of carrier 27 increases from 1150 to 2000 min ^-1 . Passing through the planetary gear 36 with a braked wheel 50 with a gear ratio of about 3 (the first range), the rotation speeds of the carrier 46 and, consequently, the output shaft 47, vary from 0 to 670 min ^-1 . If you connect the coupling halves 40 and 42 (third range), then the rotation frequency of the carrier 46 and, therefore, the output shaft 47 will change from 1150 to 2000 min ^-1 . When changing the gear ratios of the varying link in the opposite direction (from one to infinity), the frequency of rotation of the wheel 28 will change within 2000 ... 3450 min ^-1 with an efficiency of about 0.96. Passing through the planetary gear 37 with the braked wheel 51 with the same gear ratio 3 (second range), the rotational speeds of the wheels 28 are converted to the rotational speed of the carrier 46 and shaft 47 within 670 ... 1150 min ^-1 with an efficiency of about 0.95. When connecting the coupling halves 41 and 43 (fourth range), the carrier speed 46 and, therefore, the output shaft 47 will change from 2000 to 3450 min ^-1 . Thus, the rotational speed of the output shaft 47 changes steplessly with the transition from direct separation modes to reverse separation modes in the intervals 0 ... 670, 670 ... 1150, 1150 ... 2000, 2000 ... 3450 min ^-1 . At the time of switching between the first and second, as well as between the third and fourth ranges, the wheels 38, 39 and the coupling halves 40 and 41 simultaneously have a rotational speed of 2000 min ^-1 , and at the time of switching between the second and third speed ranges of the wheel 39 and the coupling half 40 correlate as the gear ratio of the planetary matching gear (about 3). Switching is performed with overlapping, that is, the next range is turned on immediately before the previous one is turned off, which eliminates the interruption of power flow. The required gear ratio of the varying link is achieved by adjusting the electric machines 19 and 16 by means of inverters 20 and 21. The general kinematic range of regulation of multi-band continuously variable transmission tends to infinity with an average efficiency of 0.96, starting from the second range.

The input shaft 13 of the supervariator can be driven not only from the heat engine 14, but also from the flywheel drive. The control of the transmitted torque is made by applying to the electric machine 7 the electromagnetic moment of the desired direction and magnitude. When the direction of the electromagnetic moment changes, the flywheel accumulator switches from the motor mode to the regenerative braking mode. Moreover, depending on the ratio of the rotation frequencies of the sun wheel 3 and carrier 9, as well as the direction of the electromagnetic moment, the electric machine 7 can both generate and consume electric power. The amount of electric power is a small part (on average 10%) of the total power generated or absorbed by the flywheel drive. The power of the electric machine 7 is consumed or generated respectively by the electric machines 19 and 16 so as to maintain a zero energy balance. Thus, electric machines of relatively low installed power control the total flows of mechanical power between the heat engine, flywheel drive and the vehicle propulsion, providing high efficiency of the power unit and its small size and weight.

In an embodiment of a power unit for an electric vehicle (FIG. 2), there is no heat engine, and the power required for movement is supplied to the common DC link of inverters 8, 20 and 21 from the electric energy storage 54. In steady-state driving modes, the energy balance of electric cars is negative, and the power not exceeding approximately 20% of the maximum mechanical power transmitted by the supervator is generated by the electric energy storage device 54. At a higher power requirement, energy is also taken from the macho Wick 2 in the form of mechanical energy. This power is summed with the electric power received from the drive 54, which is converted into the form of mechanical energy by means of electric machines 7, 19 and 16 through inverters 8, 20 and 21, and transmitted to the vehicle propulsion.

During intensive braking with the release of high powers, the kinetic energy of the vehicle is sent to the flywheel 2 through a supervariator and a differential mechanism 4. When braking with low intensity, the power is converted into electric energy through electric inverters 7, 19 and 16 through inverters 8, 20 and 21 and transferred to electrical energy storage 54. Thus, the hybrid power plant of figure 2 reduces peak loads on the electrical energy storage 54 and thereby increases its efficiency and mileage electric A life between charges.

Claims (3)

1. A hybrid power unit, comprising at least one autonomous source of mechanical rotation energy, a multi-band multi-threaded continuously variable transmission from said autonomous source of mechanical rotation energy to a consumer of mechanical energy, as well as a flywheel drive with transmission from the flywheel shaft to the input shaft of the said transmission the fact that a multi-range multi-threaded continuously variable transmission includes a variable link containing two reversible electric machines, and before from the flywheel drive shaft to the input shaft of a multi-band multi-threaded continuously variable transmission is made in the form of a three-link differential mechanism, the flywheel shaft is kinematically connected to one of its links, the input shaft of a multi-range multi-threaded continuously variable transmission is kinematically connected to the other link, and the kinematically connected reverse link is connected to the third link moreover, all three of these electrical machines are electrically connected to each other with the possibility of exchange of e electric power. 2. The hybrid power unit according to claim 1, characterized in that it comprises a controlled friction clutch between the output shaft of an autonomous source of mechanical rotational energy and the input shaft of a multi-range multi-threaded continuously variable transmission. 3. A hybrid power unit, including at least one electric energy storage device, a flywheel storage device, a multi-band multi-threaded continuously variable transmission, and also a transmission from the flywheel shaft to the input shaft of the said transmission, characterized in that the multi-range multi-threaded continuously variable transmission includes a variable link containing two reversible electric machines, and the transmission from the shaft of the flywheel drive to the input shaft of a multi-band multi-threaded continuously variable transmission is made in a three-link differential mechanism, to one of the links of which the flywheel shaft is kinematically connected, to the other link is the input shaft of a multi-band multi-threaded continuously variable transmission, and a reversible electric machine is kinematically connected to the third link, all three of the mentioned electric machines are electrically connected to each other and to electric energy storage with the possibility of exchanging electrical power.

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