RU225074U1 - Device for increasing the adhesion of the driving wheels of a locomotive to the rails - Google Patents

Abstract

The utility model relates to rail vehicles, in particular to devices for increasing the adhesion of the driving wheels of a locomotive to the rails. A device for increasing the adhesion of the driving wheels of a locomotive to the rails, containing a magnetizing winding in the form of a coil of insulated wire, connected to a power source via wires and mounted on a frame, the coil is placed between the motor-axial bearings of the traction electric motor, the coil frame is made of non-magnetic material and is motionless is fixed on the traction motor body along the axis of the wheel pair, and the gear wheel and the gearbox casing are connected to the axis of the wheel pair through a non-magnetic bushing, the stator of the traction electric motor is made in the form of two identical arcuate inductors, the length of each of which on the outer side is less than the length of a semicircle with a radius equal to the outer radius of the inductor, the ends of the inductors are connected to each other on the side opposite to the axis of the wheel pair, the traction motor housing has a recess at the location of the open ends of the inductors, covered by a casing, the coil frame is fixed to the traction motor housing using a casing, and the distance from the outer surface of the coil to the center of the traction motor shaft is less than the outer radius of the inductor, the device contains a longitudinal acceleration sensor located on the motor-axial bearing housing and connected to a signal measurement unit connected to a series-connected bandpass filter, rectifier and comparison unit, to which the unit is connected in parallel installation and a key connected between the power source and the coil, the non-magnetic bushing is made in the form of a hollow cylinder with a flange connected to the gear disk by a bolted connection, and is connected to the axle through the wheel of the wheelset by means of a hub resting on the wheel of the wheelset and connected to the wheel of the wheelset pairs of bolted connections. A distinctive feature of the proposed device for increasing the adhesion of the driving wheels of a locomotive to the rails is that inside the non-magnetic bushing there is a magnetizing winding in the form of a coil on a non-magnetic frame, supported through bearings on the axis of the wheelset and a stopper connected to the housing of the traction motor, both magnetizing windings are connected in series . The proposed device for increasing the adhesion of the driving wheels of a locomotive to the rails makes it possible to increase the performance of the locomotive by increasing its traction force, which is achieved by increasing the adhesion of the wheels to the rails as a result of an increase in the magnetic flux created by the device, passing through the contact of the wheels with the rails due to an additional winding located inside non-magnetic bushing. 2 ill.

Description

The utility model relates to rail vehicles, in particular to devices for increasing the traction force of a locomotive by increasing the adhesion of the drive wheels to the rails.

A device is known for increasing the adhesion of the driving wheels of a locomotive to the rails, containing an electromagnet connected to a current source (see Karel Kucera. Electromagnetic adhesion means for railroad locomotives. US Patent US 3307058 A dated January 20, 1964).

The disadvantage of the known device is the weak value of the generated magnetic flux, which does not allow to significantly increase the adhesion of the wheel to the rail, due to the fact that, according to the requirements for fitting the device into the dimensions of the rolling stock, a significant air gap must be created between the electromagnet and the rail.

A magnetic add-on loader for a rail vehicle is known, containing vertically arranged hydraulic cylinders mounted on the side beam of the trolley, connected to a magnet, a traverse rigidly connected to the rods of the hydraulic cylinders and hinged by means of rods with a magnet, force sensors associated with the drive (USSR Author's Certificate No. 1286453).

The disadvantage of this device is the additional resistance to movement created due to the contact of the electromagnet with the rail, which makes it impossible to use this device on a locomotive in traction mode.

A device is known for increasing the adhesion of the driving wheels of a locomotive to the rails, containing a split wheel with electromagnets placed inside (see John Otto Heinze Jr. Magnetic wheel. US Patent US 709484 A, February 24, 1902).

The disadvantage of the device is its low reliability due to the high concentration of loads in the contact of the split wheel with the rail.

A device is known for increasing the adhesion of the drive wheels of locomotives.

motif with rails, containing an electromagnet coil covering the locomotive wheel disk along the chord and connected to a current source (see Wehner David E. Electromagnetic traction increaser. US Patent US 2198928 A, December 2, 1936).

The disadvantage of the device is its insufficient efficiency, which does not allow to significantly increase the adhesion of the wheel to the rail due to the limited space for placing the electromagnet and the need for large gaps between the stationary electromagnet and the rotating wheel, in order to avoid jamming of the wheel when ballast stones get into the gap and crutches or bolts accidentally get in the way and nuts. Tests of the TEM2US diesel locomotive with an electromagnet coil covering the wheel disk along the chord showed an increase in adhesion properties by only 4%. (see E.A. Sitnikov, I.N. Rodionov, V.P. Grinevich. Research on increasing the traction properties of shunting diesel locomotives by using electromagnetic increases in adhesion and more optimal connection schemes for traction electric motors. VNITI Report No. I-108-82, Kolomna, 1982, page 46).

A device is known for increasing the adhesion of the driving wheels of a locomotive to the rails, containing a magnetizing winding in the form of a coil made of insulated wire, connected to a power source via wires and mounted on the axle of the wheelset on a frame that is fixedly mounted on the electric locomotive bogie and located coaxially with the axle. wheelset, the coil is placed between the wheel disk of the wheelset and a large gear, the frame is connected to the gearbox housing, the rolling bearings are located at one end of the coil frame and are connected to the stator of the traction motor, the device contains a longitudinal force sensor located on the suspension rod, an averaging filter, adder, installation unit and key, while when the locomotive implements the traction force in the suspension, which prevents the traction motor from turning around the axis, a force arises, and a signal appears at the output of the longitudinal force sensor, which is sent to the input of the averaging filter; from the output of the averaging filter, the signal is sent to one from the inputs of the adder, the second input of which receives a signal from the installation block, if the value of the signal from the output of the averaging filter becomes less than the value of the signal from the installation block, a signal appears at the output of the adder, which is supplied to the input of the key, the key opens, and from the power source to the coil a current is supplied, the magnitude of which is proportional to the magnitude of the signal from the output of the adder (patent No. 194613, Russian Federation).

The disadvantage of this device is that it can only be used for a traction drive, in which the small gear of the traction transmission is located between the rotor bearings of the traction motor, while on most domestic mainline and shunting diesel locomotives the small gear is located cantilevered at the end of the shaft traction motor, as a result of which the traction gear is located closer to the wheel center than in this device, and the space between the large gear and the wheel center disk is not enough to accommodate the coil.

A device is known for increasing the adhesion of the wheel pair of an electric locomotive to the rails, containing a wheel pair, a magnetizing winding in the form of a coil that provides electromagnetic adhesion of the wheels to the rails, made of insulated wire, installed on the axis of the wheel set and connected to a power source using wires, and the magnetizing coil installed on a frame, which is fixedly fixed on the electric locomotive bogie and located coaxially with the axis of the wheel pair with a gap in which rolling bearings are installed, located at the ends of the coil frame with the possibility of rotating the axis of the wheel pair inside it, while the current-carrying wires are placed inside the electric locomotive bogie (patent RF No. 2055748).

The disadvantage of this device is that when used on the bogie of a freight locomotive with a support-axial drive, the specified device has low efficiency, since the frame of the traction motor with a support-axial drive is located close to the axis of the wheelset (see Alekseev A.E. Traction electrical machines and converters. L., “Energy”, 1977, P. 25, Fig. 1-4), which does not allow making a coil with dimensions that provide the required value of magnetic flux.

A device is known for increasing the adhesion of locomotive wheels to rails, containing a magnetizing winding in the form of a coil of insulated wire, connected to a power source via wires and mounted on a frame, the coil is placed between the motor-axial bearings of the traction motor, the coil frame is made of non-magnetic material and is motionless fixed on the frame of the traction motor along the axis of the wheel pair, with the gear wheel and gear housing connected to the axis of the wheel pair through a non-magnetic bushing (patent No. 196905, Russian Federation).

The disadvantage of the device is the same as that mentioned above, since the frame of the traction motor with a support-axial drive is located close to the axis of the wheelset, which limits the space for placing the coil.

Arc-stattor and ring electric motors are known, in which torque is transmitted contactlessly by an electromagnetic field (see Tolkachev E.A. Arc-stattor and linear synchronous machines with magnetoelectric excitation. Leningrad State University Publishing House, 1975, P. 127.). It is known that in an arc motor the rotor is part of a circle (see Burmakin A.M. Low-speed arc motor asynchronous motor for pumping units of low-yield oil wells. Abstract of the dissertation for the scientific degree of Ph.D. Ekaterinburg, 2011, P. 7 Fig. 1 ), which allows the outer surface of the coil to be brought closer to the motor rotor in a place not occupied by the arc stator (in the recess, if the total length of one or several arc stators is more than half the length of a circle with a radius equal to the radius of the stator arc, but less than the length of a circle with a radius equal to stator arc radius). It is known that the design features, principle of operation and energy of arc-stator asynchronous electric motors determine the possibility of their use in the traction drive system of locomotives (see A.I. Ivakhin. Implementation options and dynamic properties of the asynchronous traction drive of locomotives with arc-stator electric motors / “Heavy Engineering”, no. 10, M., NPO "Central Research Institute of Mechanical Engineering Technology", 2012, p.

A device is known for increasing the adhesion of the driving wheels of a locomotive to the rails, containing a magnetizing winding in the form of a coil of insulated wire, connected to a power source via wires and installed on a frame, the coil is placed between the motor-axial bearings of the traction electric motor, the coil frame is made of non-magnetic material and fixedly mounted on the traction motor housing along the axis of the wheel pair, wherein the gear wheel and the gearbox casing are connected to the axis of the wheel pair through a non-magnetic bushing, characterized in that the stator of the traction electric motor is made in the form of two identical arcuate inductors, the length of each of which on the outer side is less than the length semicircle with a radius equal to the outer radius of the inductor, the ends of the inductors are connected to each other on the side opposite to the axis of the wheel pair, the traction motor housing has a recess at the location of the ends of the inductors, distant from each other, covered by a casing, the coil frame is fixed to the traction motor housing with using a casing, and the distance from the outer surface of the coil to the center of the traction motor shaft is less than the outer radius of the inductor (RF patent No. 208748).

The disadvantage of the device is that when the locomotive operates on sections of the track where the traction force required for the movement of the train can be realized without the influence of a magnetic field on the contact of the wheel with the rail, passing current through the magnetizing winding leads to additional energy consumption due to losses in the magnetizing winding itself and due to additional resistance to movement from the occurrence of eddy currents in the moving parts of the undercarriage, in which a magnetic flux is created.

A device is known for increasing the adhesion of the driving wheels of a locomotive to the rails, containing a magnetizing winding in the form of a coil of insulated wire, connected to a power source via wires and installed on a frame, the coil is placed between the motor-axial bearings of the traction electric motor, the coil frame is made of non-magnetic material and is fixedly fixed on the traction motor housing along the axis of the wheel pair, and the gear wheel and gear housing are connected to the axis of the wheel pair through a non-magnetic bushing, the stator of the traction electric motor is made in the form of two identical arcuate inductors, the length of each of which on the outer side is less than the length of a semicircle with a radius, equal to the outer radius of the inductor, the ends of the inductors are connected to each other on the side opposite to the axis of the wheel pair, the traction motor housing has a recess at the location of the open ends of the inductors, covered by a casing, the coil frame is fixed to the traction motor housing using a casing, and the distance from the outer surface coil to the center of the traction motor shaft is less than the outer radius of the inductor, the device contains a longitudinal acceleration sensor located on the housing of the motor-axial bearing and connected to a signal measurement unit connected to a series-connected bandpass filter, rectifier and comparison unit, to which they are connected in parallel installation unit and key connected between the power source and the coil (RF patent No. 213746).

The disadvantage of the device is that due to the small thickness of the non-magnetic bushing, part of the magnetic flux created by the coil is closed through the gear wheel and the traction motor housing, which reduces the magnetic flux flowing through the contact of the wheel and the rail, thereby reducing the adhesion of the wheel to the rail and locomotive performance, since the ability to increase the magnetic field created by the coil is limited by the size of the coil and the permissible heating of the coil wires.

It is known (see Luzhnov Yu.M., Pruntsev A.P. The influence of a constant magnetic field on the friction of solids. - Proceedings of MIIT, 1974, issue 467) that the coefficient of friction (adhesion) in a metal-to-metal contact, in addition to physical properties of the friction pair depends on the magnetic field strength in the contact patch and can be increased. For a more detailed study of the influence of the magnetic field on the coefficient of friction of the metal-to-metal system, tests were carried out on special installations (see V.P. Tikhomirov, V.I. Vorobyov, D.V. Vorobyov, G.V. Bagrov, M .I. Borzenkov, I.A. Butrin. Modeling of wheel-rail adhesion. Orel, Orel State Technical University, 2007, pp. 95-101). The test results showed that for the studied models of “steel on steel” contact, when creating strong magnetic fields in the zone of their contact, it is possible to increase the coefficient of friction (adhesion) by more than 20%. Currently, this phenomenon is explained primarily by the effect of magnetoplasticity, one of the main reasons for which is considered to be an increase in the mobility of dislocations under the influence of an external electromagnetic field under the influence of electron spins localized on defects in the crystal lattice (see Poletaev V.A., Potemkin D.A. Energy analysis of the influence of a magnetic field on the mechanical properties of steel. Bulletin of Ivanovo State Energy University (ISUE) - 2007 No. 3.

Closest to the claimed is a device for increasing the adhesion of the driving wheels of a locomotive to the rails, containing a magnetizing winding in the form of a coil of insulated wire, connected to a power source via wires and installed on a frame, the coil is placed between the motor-axial bearings of the traction electric motor, the coil frame is made made of non-magnetic material and fixedly mounted on the body of the traction electric motor along the axis of the wheel pair, and the gear wheel and the gear housing are connected to the axis of the wheel pair through a non-magnetic bushing, the stator of the traction electric motor is made in the form of two identical arc-shaped inductors, the length of each of which on the outer side is less than the length a semicircle with a radius equal to the outer radius of the inductor, the ends of the inductors are connected to each other on the side opposite to the axis of the wheel pair, the traction motor housing has a recess at the location of the open ends of the inductors, covered by a casing, the coil frame is fixed to the traction motor housing using a casing, and the distance from the outer surface of the coil to the center of the traction motor shaft is less than the outer radius of the inductor, the device contains a longitudinal acceleration sensor located on the motor-axial bearing housing and connected to a signal measurement unit connected to a series-connected bandpass filter, rectifier and comparison unit, to which the installation block and the key are connected in parallel, connected between the power source and the coil, the non-magnetic bushing is made in the form of a hollow cylinder with a flange connected to the gear disk by a bolted connection, and is connected to the axle through the wheel of the wheelset by means of a hub resting on the wheel of the wheelset and connected to the wheel of the wheelset by a bolted connection (RF patent No. 216864).

The disadvantage of the device is that the magnetic flux created by the coil is limited due to limitations in the diameter and length of the coil and the amount of current passed through it. This leads to a limitation in the ability to increase the adhesion coefficient due to the magnetic flux and the ability to increase the traction force and productivity of the locomotive.

The technical result of the claimed utility model is to increase the performance of the locomotive by increasing the adhesion of the track to the rails.

The technical result is achieved by the fact that in a device for increasing the adhesion of the driving wheels of a locomotive to the rails, containing a magnetizing winding in the form of a coil of insulated wire, connected to a power source via wires and mounted on a frame, the coil is placed between the motor-axial bearings of the traction electric motor, the frame The coil is made of non-magnetic material and is fixedly mounted on the body of the traction motor along the axis of the wheel pair, and the gear wheel and the gear housing are connected to the axis of the wheel pair through a non-magnetic bushing, the stator of the traction motor is made in the form of two identical arc-shaped inductors, the length of each of which is on the outer side less than the length of a semicircle with a radius equal to the outer radius of the inductor, the ends of the inductors are connected to each other on the side opposite to the axis of the wheel pair, the traction motor housing has a recess at the location of the open ends of the inductors, covered by a casing, the coil frame is fixed to the traction motor housing using a casing , and the distance from the outer surface of the coil to the center of the traction motor shaft is less than the outer radius of the inductor, the device contains a longitudinal acceleration sensor located on the housing of the motor-axial bearing and connected to a signal measurement unit associated with a series-connected bandpass filter, rectifier and block comparison, to which the installation unit and the key are connected in parallel, connected between the power source and the coil, the non-magnetic bushing is made in the form of a hollow cylinder with a flange connected to the gear disk by a bolted connection, and is connected to the axle through the wheel of the wheelset by means of a hub resting on the wheel wheelset and connected to the wheel of the wheelset by a bolted connection, inside the non-magnetic bushing there is a magnetizing winding in the form of a coil on a non-magnetic frame, supported through bearings on the axis of the wheelset and a stopper connected to the body of the traction motor, both magnetizing windings are connected in series.

The essence of the claimed utility model is illustrated by a drawing, where Fig. 1 shows a general view of a device for increasing the adhesion of the driving wheels of a locomotive to the rails, and Fig. 2 - cross section of the traction motor and the axle of the wheelset.

A device for increasing the adhesion of the driving wheels of a locomotive to the rails (Fig. 1) contains a magnetizing winding 1 in the form of a coil 2 made of insulated wire, connected to a power source 3 using wires 4 and installed on a frame 5. Coil 2 is placed between motor-axial bearings 6 traction electric motor 7, located in the housing 8. The frame 5 of the coil 2 is made of non-magnetic material and is fixedly mounted on the housing 8 of the traction motor 7 along the axis 9 of the wheel pair 10, and the gear 11 and the gear housing 12, mounted on the housing 8, are connected to the axis 9 of the wheel pair 10 through a non-magnetic bushing 13. The frame 5 of the coil 2 is fixed to the housing 8 of the traction motor 7 using a casing 14. The longitudinal acceleration sensor 15 is placed on the housing of the motor-axial bearing 6 and is connected to the signal measurement unit 16, which through series-connected strip filter 17, rectifier 18 and connection comparison unit 19 with installation unit 20 and switch 21 connected between power sources 3 and coil 2. Stator 22 of traction motor 7 (Fig. 2) is made in the form of two identical arc-shaped inductors 23. The length of each of the inductors 23 on the outer side will be equal to L _and =πR _and ϕ/180, where R _and is the radius of the inductor 23 on the outer side, and ϕ is the angle between the ends of the inductor 23 in degrees. Since ϕ<180°, then L _and is less than the length of a semicircle with a radius equal to R _and , and the two inductors 23 together form only part of the circle. The ends of the inductors 23 are connected to each other on the side opposite to the axis 9 of the wheel pair 10, along the line B ₁ B ₂ , and the opposite ends of the inductors 23 are not closed to each other. The housing 8 of the traction motor 7 has a recess at the location of the ends of the inductors 23, distant from each other. The recess is closed by a casing 14. The distance L from the outer surface of the frame 5 of the coil 2 to the center of the shaft 24 of the traction motor 7 is less than the value of R _and (radius of the inductor 23 on the outside). The non-magnetic bushing 13 is made in the form of a hollow cylinder with a flange 25 connected to the gear disk 11 by a bolted connection 26, and is connected to the axis 9 of the wheel pair 10 through the wheel 27 of the wheel pair 10, by means of a hub 28 resting on the wheel 27 of the wheel pair 10 and connected with wheel 27 of wheel pair 10 with bolted connection 29.

Inside the non-magnetic sleeve 13 there is a magnetizing winding 30 in the form of a coil 31 on a non-magnetic frame 32, supported through bearings 33 on the axis 9 of the wheel pair 10 and a stopper 34 connected to the housing 8 of the traction motor 7, both magnetizing windings 1 and 30 are connected in series.

A device for increasing the adhesion of the driving wheels of a locomotive to the rails works as follows.

When current is passed through the windings 1 and 30 connected in series in the form of coils 2 and 31 from the power source 3, a magnetic flux arises passing through the axle 9 of the wheelset, both wheels of the wheelset and the rails (not shown in Fig. 1), which leads to changes in physical and mechanical properties in the contact zone of metal bodies (wheels with rails) and changes the coefficient of adhesion of wheels with rails. The casing 14 prevents dust and dirt from getting inside the traction motor 7. Due to the design of the stator 22 of the traction motor 7 in the form of two arc-shaped inductors 23, not closed to each other on the side of the axis 9 of the wheel pair 10, and the presence of a recess in the housing 8 of the traction motor 7, it becomes possible to increase the magnetic flux passing through the wheels and rails by increasing the outer diameter of the coil 2, since the outer diameter of the frame 5 of the coil 2, in contrast to the analogues discussed above, can be increased to sizes with the same value of the traction transmission center and gear ratio, with in which the distance from the outer surface of the frame 5 of the coil 2 to the center of the shaft 24 of the traction motor 7 is less than the radius of the inductor 23 on the outside, since the coil 2 is located in the recess.

In the event of a sudden deterioration in the conditions of adhesion of the wheels to the rails, the sliding of the wheels on the rail increases, frictional self-oscillations occur, which lead to periodic changes in the torque in the axis 9, periodic longitudinal accelerations of the motor-axial bearings 6 and the appearance of periodically changing signals at the output of the longitudinal acceleration sensor 15 and output of signal measurement block 16. A periodically changing signal from the output of the signal measurement unit 16 is fed to the input of the bandpass filter 17, which passes only a signal with a frequency corresponding to the natural frequency of the wheelset 10, in order to avoid false alarms of the device. The signal from the output of the bandpass filter 17 is rectified by the rectifier 18 and is supplied to the input of the comparison block 19, the other input of which receives a signal from the installation block 20, the value of which is determined based on the test results. If the magnitude of the signal from the output of the rectifier 18 is greater than the magnitude of the signal from the output of the installation block 20, a signal appears at the output of the comparison block 19, which is sent to the key 21. The key 21 opens and supplies current from the power source 3 to the windings 1 and 30 connected in series in the form of coils 2 and 31, a magnetic flux arises passing through the axle 9 of the wheelset 10, both wheels of the wheelset 10 and the rails, which leads to a change in the physical and mechanical properties in the contact zone of metal bodies (wheels with rails) and increases the coefficient of adhesion of the wheels with the rails.

The stopper 34 prevents the rotation of the coil 31 around its axis, while the axis 9 of the wheel pair rotates freely inside the coil 31 thanks to the bearings 33.

Due to the fact that, in addition to winding 1 in the form of coil 2, the magnetic flux is also created by winding 30 in the form of coil 31, the created magnetic flux is greater in comparison with the prototype, in which the magnetic flux was created only by winding 1 in the form of coil 2, the device achieves higher coefficient of adhesion than the prototype.

The technical and economic effect of the claimed utility model is that, thanks to the additional winding placed inside the non-magnetic bushing, the magnetic flux created by the device, passing through the contact of the wheels with the rails, increases, which increases the coefficient of adhesion of the wheels with the rails, the traction force of the locomotive and its productivity.

Claims (1)

A device for increasing the adhesion of the driving wheels of a locomotive to the rails, containing a magnetizing winding in the form of a coil of insulated wire, connected to a power source via wires and mounted on a frame, the coil is placed between the motor-axial bearings of the traction electric motor, the coil frame is made of non-magnetic material and is motionless is fixed on the traction motor body along the axis of the wheel pair, and the gear wheel and the gearbox casing are connected to the axis of the wheel pair through a non-magnetic bushing, the stator of the traction electric motor is made in the form of two identical arcuate inductors, the length of each of which on the outer side is less than the length of a semicircle with a radius equal to the outer radius of the inductor, the ends of the inductors are connected to each other on the side opposite to the axis of the wheel pair, the traction motor housing has a recess at the location of the open ends of the inductors, covered by a casing, the coil frame is fixed to the traction motor housing using a casing, and the distance from the outer surface of the coil to the center of the traction motor shaft is less than the outer radius of the inductor, the device contains a longitudinal acceleration sensor located on the motor-axial bearing housing and connected to a signal measurement unit connected to a series-connected bandpass filter, rectifier and comparison unit, to which the unit is connected in parallel installation and a key connected between the power source and the coil, the non-magnetic bushing is made in the form of a hollow cylinder with a flange connected to the gear disk by a bolted connection, and is connected to the axle through the wheel of the wheelset by means of a hub resting on the wheel of the wheelset and connected to the wheel of the wheelset pairs with a bolted connection, characterized in that inside the non-magnetic sleeve there is a magnetizing winding in the form of a coil on a non-magnetic frame, supported through bearings on the axis of the wheelset and a stopper connected to the housing of the traction motor, both magnetizing windings are connected in series.