US2102181A - Wheel cooling apparatus - Google Patents

Wheel cooling apparatus Download PDF

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US2102181A
US2102181A US115794A US11579436A US2102181A US 2102181 A US2102181 A US 2102181A US 115794 A US115794 A US 115794A US 11579436 A US11579436 A US 11579436A US 2102181 A US2102181 A US 2102181A
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valve
air
water
cooling
pipe
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Mccormick George
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    • BPERFORMING OPERATIONS; TRANSPORTING
    • B61RAILWAYS
    • B61HBRAKES OR OTHER RETARDING DEVICES SPECIALLY ADAPTED FOR RAIL VEHICLES; ARRANGEMENT OR DISPOSITION THEREOF IN RAIL VEHICLES
    • B61H11/00Applications or arrangements of braking or retarding apparatus not otherwise provided for; Combinations of apparatus of different kinds or types
    • B61H11/005Applications or arrangements of braking or retarding apparatus not otherwise provided for; Combinations of apparatus of different kinds or types in combination with rail sanding, door opening or the like

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  • the present invention relates to apparatus for cooling the wheels of railway cars and engines, in order to prevent the overheating thereof by prolonged application of the brake shoes.
  • the principal object of the invention is to provide an apparatus for applying a cooling fluid, preferably water, directly to the tread surfaces of the wheels, and to provide means whereby the application of said cooling fluid can be controlled, either manually by the engineer, or automatically by the application of the brakes or by a rise in temperature of the wheels themselves.
  • Anotherxobject of the invention is to provide means, manually or automatically controlled, for
  • a further object of the invention is toprovide a system adapted either for operation from each individual car or from the engineers cab of a train. Still further objects and advantages of the invention ,willbecome apparent from the following specification, which should be read with the understanding that the form, construction and arrangement of the several parts may be varied within the limits of the claims hereto appended, without departing from the Spirit of the invention.
  • FIG. 1 is a diagram, partly in section, of the control'apparatus and one unit of the operating apparatus as mounted on one car.
  • Fig. 2 is a section, enlarged, of a preferred form .of air-operated valve for controlling the flow of cooling .water.
  • Fig. 3 is a section, enlarged, ofv a preferred form of magnetic valve for controlling the air
  • Fig. 4 is an elevation, enlarged and partly in section, of a preferred form of delayed action switch .-for controlling thewater ejectingmechanism.
  • the reference numeral II designates a storage tank mounted in any convenient location on the car and adapted 'to contain a supply of water.
  • I2 is a discharge pipe leading from said-tank. and provided with branches I3, one leading to each truck of the car.
  • the branch pipes l3 ter- 'minatejin discharge nozzles l4 positioned above the wheels of the truck, and adapted to discharge the, water directly onto said wheels;
  • the water discharge pipe I2 is provided with a control'valve' l5, which can, if desired, be any ordinary form of manually operated valve.
  • a control'valve' l5 which can, if desired, be any ordinary form of manually operated valve.
  • a pneumatically controlled valve shown in detail in Fig. 2.
  • a spring ll holds the valve closed.
  • air under pressure is admitted to a chamber l8 above a diaphragm I! which is connected with the valve l5 by a stem 20.
  • the air for operating the valve I5 is drawn from a reservoir 2
  • the brake is controlled by the 'usual mechanism, whichIhave shown for the sake of illustration as a valve structure 25 in 20 which is adouble piston valve 26 operated in one direction by a diaphragm 21 and in the other direction by a spring 28.
  • the operating valve 25 is controlled, as usual, by the engineers valve;
  • valve 29 herein indicated as a simple form of valve 25 as a system of, levers 33 and links34, which ap- 35 ply the brake shoes 35 against the wheels 36.
  • the valve 38 shown in detail in Fig. 3, is normally held closed by a spring 39, and is openedby an ele'etroma'gnet 40 which attracts an armature 4
  • Electric-power for 1 operating the magnet 40 is supplied from any suitable source indicated at 43 in Fig. 1, which is connected with the magnet by a manual selector switch 44 and a wire 45, the return circuit being grounded on the frame of the car, as indicated at 46.
  • the switch 44 is open, as shown, the valve 38 remains closed, and the water control valve I5 is not operated automatically by the application of the brake.
  • the switch 44 is closed, however, the valve 38 is held open and the water control valve is automatically operated with the brake as described above.
  • a connection is made by pipes 41 and 48 between the air tank 2
  • the pipe 48 is controlled by a magnetic valve 49 similar in construction to the valve 38 described above.
  • connect the source of current 43 with the magnet windings of the valve 49, the return circuit being grounded. Closing of the key energizes the magnet of said valve and allows air to flow through the pipes 41 and 48 to the water valve.
  • the valve 49 is closed by a spring when the key is open.
  • thermostatic switch indicated as a pair of contacts 52 and 53, are connected by wires 54 and 55 in parallel with the contacts of the key 50.
  • the contact 53 is a bimetallic element responsive to heat, and is positioned in close proximity to the rim of one of the wheels and the brake shoe acting thereon.
  • the water pipes l2 and I3, especially the latter, are necessarily in exposed positions underneath the car, and any water which may remain in them after the closing of the water. valve is likely to freeze in cold weather. Such freezing 0 would, of course, clog the pipes and render the system inoperative. In .order to prevent this, I provide means for expelling the remaining water from the pipes l2 and I3, automatically, upon the closing of the control valve I5.
  • a pipe 56 connects the air brake valve chamber 25 with the Water pipe l2.
  • the pipe-56 is so connected with the chamber of the valve 25 that it is closed when the pistons 26 of said valve are raised to permit air to flow from thetank 2
  • I provide a pipe 51 connecting the air pipe 41 with the water pipe I 2.
  • the air pipe 51 is controlled by a magnetic valve 58 similar in construction -prises a cylinder 62 in communication with the air pipe 48 and provided with a piston 63.
  • a rod 64 connected with said piston carries a rotatable disk 65 whose periphery has frictional engagement with a stationary vertical surface 66. Electrical contact segments 61 are mounted in the disk and the vertical surface .66 and are so positioned that upon the upward stroke of the rod 64 electrical connection is not established between the said contacts.
  • the rotation of the disk 65 is limited, in both directions, by shoulders 68 and a pin 69.
  • the disk Upon the upward stroke, the disk rolls upon the surface 66 without making electrical connection between the contacts 61 until the lower shoulder 68 strikes against the pin 69. for the rest of the upward stroke, the disk slides over the surface 66, thereby altering the positional relation between the two contacts.
  • the disk Upon the downward stroke, the disk again rolls, this time in the reverse direction, and because of their altered relation due to the slippage described above, the contacts 61 now make connection and close the electrical circuit for a short period of time during the downward stroke.
  • the contacts 61 connect the windings of the magnetic valve 58 with the source of current through the wires 55, 10, and 1
  • the piston 63 is raised when air pressure is admitted to the pipe 48 to open the water valve 15, and as long as the pressure continues in said pipe 48, the magnetic valve 58 remains closed because no connection has been established between the contacts 61.
  • the piston 63 is moved slowly downwardly by a spring 12, Fig. 4, the air beneath it escaping through a bleeder port 13:
  • electrical connection is established between the contacts 61, and the magnetic valve 58, Fig. 1, is held open for a sufficient length of time to permit air to flow through the pipe 51 and to blow out the water from the pipes l2 and I3.
  • the connection is again broken between the contacts 61 and the magnetic valve 58 is again returned to its normal closed position.
  • Check valves 14 are interposed in the pipes 31 and 48 leading to the'chamber 18 of the water valve, and also in the ejector air pipes 56 and 51, in order to prevent reverse flow of air.
  • My system is adaptable either to a single car or to a train of cars.
  • the diagram (Fig. 1) shows the apparatus for a single car.
  • the brake train pipe 32 is, of course, extended to and through all the cars of the train.
  • , 60, and 55, are likewise extended throughout the train.
  • the apparatus shown below the train pipe 32 is repeated in each car, and all sets of such apparatus are controlled simultaneously by the engineer's valve 29, the selector switch 44, and the keys 59 and 59.
  • These four control elements are positioned in the englneers cab.
  • the keys 50 and 59 may, ii-desired, be duplicated in each car, so that a trainman in any car can operate the cooling system indesystem provides means for cooling the wheels,
  • the automatic control which can be operated manually or automatically, the automatic control functioning either in response to heat developed in the wheels and brakeshoes, or simultaneously with the normal operation of the brakes. It further provides means for ejecting any water that may remain in the exposed portions of the water pipes, which would be in danger of freezing in cold weather.
  • the ejecting function may be controlled manually, or may be entirely automatic, being set in operation whenever the water valve is closed.
  • means for cooling the wheels of the vehicle comprising a pipe for conducting cooling fluid to said wheels, a valve in saidpipe, means for operating said valve by air pressure, a connection between the brake controlling valve and the operating means of the cooling fluid valve, whereby said cooling fluid valve isautomatically operated simultaneously with the brake, and a second connection between'said brake valve and said cooling fluid pipe whereby air is'admitted to said pipe to eject the cooling fluid therefrom after the closing of said cooling fluid valve.
  • apparatus forcooling the wheels of said vehicle comprising means for conducting cooling fluid to saidwheels, means for automatically controlling the flow of said fluid simultaneously with the operation of said brake, and means for manually controlling said fluid independently of the operation of said brake.
  • apparatus for cooling the wheels thereof comprising a pipe for conducting cooling water to said wheels, a valve for controlling the supply of water to said pipe, airpressure actuated means for operating said valve, a source of air under pressure, a conduit con- I necting said source with said valve operating means, an air valve for controlling the supply of air to said conduit, a connection between said air conduit and said water pipe, and means for controlling said connection whereby the residual pressure remainingin said air conduit after the closing of said air valve is supplied to said pipe to eject the water therefrom.
  • apparatus for cooling the wheels thereof comprising a pipe for conducting cooling water to said wheels, a valve for controlling the supply of water to said pipe, airpressure actuated means for operating said valve, a source of air under pressure, a conduit connecting said source with said valve operating means, an air valve in said conduit, a normally closed connection between said source of air and said water pipe, and means for opening said connection automatically for a predetermined time upon the closing of said water valve.
  • apparatus for cooling the wheels of said vehicle comprising means for supplying cooling Water to said wheels, an air pressure operated valve for controlling said cooling water, means for conducting air from said brake system to said water valve whereby the latter is automatically operated simultaneously with the brakes, and electrically controlled means for conducting air from said source to said water valve to operate the latter independently of said brakes.
  • an air operated brake system means for cooling the wheels of the vehicle comprising a pipe for conducting cooling fluid to said wheels, means for controlling the flow of fluid through said pipe, and controllable means for conducting air from said brake system to said pipe to eject the cooling fluid therefrom.
  • an air operated brake system a valve for controlling the supply of air thereto; means for conducting cooling fluid to the wheels of the vehicle, an air operated valve for controlling said cooling fluid, and means for conducting air from the brake system to the cooling fluid valve whereby said cooling fluid valve is operated automatically simultaneously withthe brake.
  • an air operated brake system In a railway vehicle, an air operated brake system,- means for controlling said brake, air operated means for delivering cooling fluid to the wheels of the vehicle, and means for conducting air from the brake system to the cooling means to operate said cooling means simultaneously with the brake.

Description

Dec. 14, 1937. MCCORMICK 2,102,181
Y WHEEL COOLING APPARATUS I Filed Dec. 14, 1936 2 ,ShQets-Sheet 1 35 as 35 as INVENTOR ATTORNEY-5 Dec. 14, 1937. I cc R m 2,102,181
WHEEL COOLING APPARATUS Filed Dec. 14, 1936 2 Sheets-Sheet 2 I 1111 m m."
INVENTOR 5M crum cf BY ATTORNEYS 4' Patented Dec. 14,
PATENT- OFFICE 2,102,181 WHEEL COOLING APPARATUS George McCormick, RedwoodCity, Calif. Application December 14, 1936, Serial No. 115,794
12 Claims.
The present invention relates to apparatus for cooling the wheels of railway cars and engines, in order to prevent the overheating thereof by prolonged application of the brake shoes.
The principal object of the invention is to provide an apparatus for applying a cooling fluid, preferably water, directly to the tread surfaces of the wheels, and to provide means whereby the application of said cooling fluid can be controlled, either manually by the engineer, or automatically by the application of the brakes or by a rise in temperature of the wheels themselves. Anotherxobject of the invention is to provide means, manually or automatically controlled, for
tions in the car trucks, in order to prevent clog-'- discharging the water from those parts of the cooling system which extend into exposed posiging of said parts by freezing of the water therein in cold weather.
A further object of the invention is toprovide a system adapted either for operation from each individual car or from the engineers cab of a train. Still further objects and advantages of the invention ,willbecome apparent from the following specification, which should be read with the understanding that the form, construction and arrangement of the several parts may be varied within the limits of the claims hereto appended, without departing from the Spirit of the invention. v I
Reference will be made to the accompanying drawings wherein Fig. 1 is a diagram, partly in section, of the control'apparatus and one unit of the operating apparatus as mounted on one car.
' Fig. 2 is a section, enlarged, of a preferred form .of air-operated valve for controlling the flow of cooling .water.
Fig. 3 is a section, enlarged, ofv a preferred form of magnetic valve for controlling the air,
which operates the cooling apparatus.
Fig. 4 is an elevation, enlarged and partly in section, ofa preferred form of delayed action switch .-for controlling thewater ejectingmechanism.
Referring more particularly to the drawings, the reference numeral II designates a storage tank mounted in any convenient location on the car and adapted 'to contain a supply of water.
I2 is a discharge pipe leading from said-tank. and provided with branches I3, one leading to each truck of the car. The branch pipes l3 ter- 'minatejin discharge nozzles l4 positioned above the wheels of the truck, and adapted to discharge the, water directly onto said wheels;
The water discharge pipe I2 is provided with a control'valve' l5, which can, if desired, be any ordinary form of manually operated valve. However,Iprefer to employ a pneumatically controlled valve shown in detail in Fig. 2. In this form 5 of valve, which is inclosed in a housing iii, a spring ll holds the valve closed. In order to open it, air under pressure is admitted to a chamber l8 above a diaphragm I!) which is connected with the valve l5 by a stem 20. Air pres- 10 sure in the chamber 18 depresses the diaphragm and opens the valve.
The air for operating the valve I5 is drawn from a reservoir 2|, Fig. 1, which may conveniently be the reservoir of the air brake system 15 of the car, from which-leads the usual brake pipe 22 with branches 23 to the brake cylinders 24 of each truck. The brake is controlled by the 'usual mechanism, whichIhave shown for the sake of illustration as a valve structure 25 in 20 which is adouble piston valve 26 operated in one direction by a diaphragm 21 and in the other direction by a spring 28. The operating valve 25 is controlled, as usual, by the engineers valve;
29 herein indicated as a simple form of valve 25 as a system of, levers 33 and links34, which ap- 35 ply the brake shoes 35 against the wheels 36.
The same operation of the brake valve 25 which admits air to the brake pipe22 also admits air. to a branch 31 of said pipe, and thence to the chamber l8 of the, water control valve I5, 40 so that when the brake is applied the water con- "trol valve I5 is also automatically opened, al-
lowing the cooling water to flow through the pipes l2 and. I3 and to discharge onto the wheels.
. 45 In order to prevent automatic operation of the water valve with the brake valve, and. to
enable-the water valve to be controlled manually, independently of the operation of the brake,
I prefer to provide a magnetically operated valve 38 in the air pipe 31. The valve 38, shown in detail in Fig. 3, is normally held closed by a spring 39, and is openedby an ele'etroma'gnet 40 which attracts an armature 4| attached to the stem 42 of said valve. Electric-power for 1 operating the magnet 40 is supplied from any suitable source indicated at 43 in Fig. 1, which is connected with the magnet by a manual selector switch 44 and a wire 45, the return circuit being grounded on the frame of the car, as indicated at 46. Thus, when the switch 44 is open, as shown, the valve 38 remains closed, and the water control valve I5 is not operated automatically by the application of the brake. When the switch 44 is closed, however, the valve 38 is held open and the water control valve is automatically operated with the brake as described above.
In order to provide for manual control of the water valve l5, a connection is made by pipes 41 and 48 between the air tank 2| and the chamber I8 of the water valve. The pipe 48 is controlled by a magnetic valve 49 similar in construction to the valve 38 described above. A manually operated switch or key 59 and a wire 5| connect the source of current 43 with the magnet windings of the valve 49, the return circuit being grounded. Closing of the key energizes the magnet of said valve and allows air to flow through the pipes 41 and 48 to the water valve. The valve 49 is closed by a spring when the key is open.
There is also providedan additional means for controlling the water valve automatically by the heat generated by the braking of the wheels. A thermostatic switch, indicated as a pair of contacts 52 and 53, are connected by wires 54 and 55 in parallel with the contacts of the key 50. The contact 53 is a bimetallic element responsive to heat, and is positioned in close proximity to the rim of one of the wheels and the brake shoe acting thereon. When the temperature of the wheel rises to a predetermined value, the thermostatic contacts are closed, supplying 0 current through the wires 55 and 54 to the magnetic valve 49, and thereby admitting air to the water valve I 5. The water will flow onto the wheels until their temperature is reduced sufficiently to open the thermostatic contacts.
The water pipes l2 and I3, especially the latter, are necessarily in exposed positions underneath the car, and any water which may remain in them after the closing of the water. valve is likely to freeze in cold weather. Such freezing 0 would, of course, clog the pipes and render the system inoperative. In .order to prevent this, I provide means for expelling the remaining water from the pipes l2 and I3, automatically, upon the closing of the control valve I5. A pipe 56 connects the air brake valve chamber 25 with the Water pipe l2. The pipe-56 is so connected with the chamber of the valve 25 that it is closed when the pistons 26 of said valve are raised to permit air to flow from thetank 2| into the brake pipe 22. when the supply of air to the brakes, and also to the water valve I5, is cut off by the downward movement of the pistons 26 to the position shown in the drawings, the pipe 56 is open to the interior of the brake valve chamber and conducts the air pressure remaining therein to the water pipe l2. This air is sufficient to expel from the pipe 12 and its branches 13 the water trapped therein by the closing of the water valve 15.
To achieve the same result when the water valve is controlled either manually or thermostatically through the magnetic valve 49, I provide a pipe 51 connecting the air pipe 41 with the water pipe I 2. The air pipe 51 is controlled by a magnetic valve 58 similar in construction -prises a cylinder 62 in communication with the air pipe 48 and provided with a piston 63. A rod 64 connected with said piston carries a rotatable disk 65 whose periphery has frictional engagement with a stationary vertical surface 66. Electrical contact segments 61 are mounted in the disk and the vertical surface .66 and are so positioned that upon the upward stroke of the rod 64 electrical connection is not established between the said contacts. The rotation of the disk 65 is limited, in both directions, by shoulders 68 and a pin 69. Upon the upward stroke, the disk rolls upon the surface 66 without making electrical connection between the contacts 61 until the lower shoulder 68 strikes against the pin 69. for the rest of the upward stroke, the disk slides over the surface 66, thereby altering the positional relation between the two contacts. Upon the downward stroke, the disk again rolls, this time in the reverse direction, and because of their altered relation due to the slippage described above, the contacts 61 now make connection and close the electrical circuit for a short period of time during the downward stroke. The contacts 61 connect the windings of the magnetic valve 58 with the source of current through the wires 55, 10, and 1|, the return circuit being grounded as before, as shown in Fig. 1.
The piston 63 is raised when air pressure is admitted to the pipe 48 to open the water valve 15, and as long as the pressure continues in said pipe 48, the magnetic valve 58 remains closed because no connection has been established between the contacts 61. When the airis cut oif from the pipe 48, the piston 63 is moved slowly downwardly by a spring 12, Fig. 4, the air beneath it escaping through a bleeder port 13: During this slow downward movement, electrical connection is established between the contacts 61, and the magnetic valve 58, Fig. 1, is held open for a sufficient length of time to permit air to flow through the pipe 51 and to blow out the water from the pipes l2 and I3. At the end of the downward movement of the piston 63, the connection is again broken between the contacts 61 and the magnetic valve 58 is again returned to its normal closed position.
Check valves 14 are interposed in the pipes 31 and 48 leading to the'chamber 18 of the water valve, and also in the ejector air pipes 56 and 51, in order to prevent reverse flow of air.
My system is adaptable either to a single car or to a train of cars. The diagram (Fig. 1) shows the apparatus for a single car. For train operation, the brake train pipe 32 is, of course, extended to and through all the cars of the train. The wires 41, 5|, 60, and 55, are likewise extended throughout the train. The apparatus shown below the train pipe 32 is repeated in each car, and all sets of such apparatus are controlled simultaneously by the engineer's valve 29, the selector switch 44, and the keys 59 and 59. These four control elements are positioned in the englneers cab. The keys 50 and 59 may, ii-desired, be duplicated in each car, so that a trainman in any car can operate the cooling system indesystem provides means for cooling the wheels,
which can be operated manually or automatically, the automatic control functioning either in response to heat developed in the wheels and brakeshoes, or simultaneously with the normal operation of the brakes. It further provides means for ejecting any water that may remain in the exposed portions of the water pipes, which would be in danger of freezing in cold weather. The ejecting function may be controlled manually, or may be entirely automatic, being set in operation whenever the water valve is closed.
I claim:
1. In a railway vehicle having an air operated brake and a valve for controlling the supply of' air thereto, means for cooling the wheels of the vehicle comprising a pipe for conducting cooling fluid to said wheels, a valve in saidpipe, means for operating said valve by air pressure, a connection between the brake controlling valve and the operating means of the cooling fluid valve, whereby said cooling fluid valve isautomatically operated simultaneously with the brake, and a second connection between'said brake valve and said cooling fluid pipe whereby air is'admitted to said pipe to eject the cooling fluid therefrom after the closing of said cooling fluid valve.
2. In a railway vehicle having a brake system,
apparatus forcooling the wheels of said vehicle comprising means for conducting cooling fluid to saidwheels, means for automatically controlling the flow of said fluid simultaneously with the operation of said brake, and means for manually controlling said fluid independently of the operation of said brake.
3. In a railway vehicle, means for cooling the wheels thereof, brakes for said wheels, means for operating said brakes, means for automatically operating said cooling means simultaneously with the operation of said brakes, and means for operating said cooling means independently of the operation of said brakes.
4. In a railway vehicle, means for cooling the wheels thereof, brakes for said wheels, means for operating said brakes, means for automatically operating said cooling means simultaneously with the'operation ofsaid brakes, means for operating said cooling means independently of the operation of said brakes, and means responsive to the heat generated by the braking of said wheels for operating said cooling means independently of said brake operating means.
5. In a railway vehicle, means for cooling the wheels thereof, brakes for said wheels, means for operating said brakes, means for operating said cooling means simultaneously with the operation brakes therefor, means for cooling said wheels,
. means responsive to the heat generated by the braking of said wheels for operating said cooling means, and means for manually operating said cooling means independently of said heat responsive operating means.
7. In a railway vehicle, apparatus for cooling the wheels thereof comprising a pipe for conducting cooling water to said wheels, a valve for controlling the supply of water to said pipe, airpressure actuated means for operating said valve, a source of air under pressure, a conduit con- I necting said source with said valve operating means, an air valve for controlling the supply of air to said conduit, a connection between said air conduit and said water pipe, and means for controlling said connection whereby the residual pressure remainingin said air conduit after the closing of said air valve is supplied to said pipe to eject the water therefrom.
8. In a railway vehicle, apparatus for cooling the wheels thereof comprising a pipe for conducting cooling water to said wheels, a valve for controlling the supply of water to said pipe, airpressure actuated means for operating said valve, a source of air under pressure, a conduit connecting said source with said valve operating means, an air valve in said conduit, a normally closed connection between said source of air and said water pipe, and means for opening said connection automatically for a predetermined time upon the closing of said water valve.
9. In a railway vehicle'having an air brake system including a source of air under pressure and a brake controlling valve, apparatus for cooling the wheels of said vehicle comprising means for supplying cooling Water to said wheels, an air pressure operated valve for controlling said cooling water, means for conducting air from said brake system to said water valve whereby the latter is automatically operated simultaneously with the brakes, and electrically controlled means for conducting air from said source to said water valve to operate the latter independently of said brakes.
10. In a railway vehicle, an air operated brake system, means for cooling the wheels of the vehicle comprising a pipe for conducting cooling fluid to said wheels, means for controlling the flow of fluid through said pipe, and controllable means for conducting air from said brake system to said pipe to eject the cooling fluid therefrom. 11. In a railway vehicle, an air operated brake system, a valve for controlling the supply of air thereto; means for conducting cooling fluid to the wheels of the vehicle, an air operated valve for controlling said cooling fluid, and means for conducting air from the brake system to the cooling fluid valve whereby said cooling fluid valve is operated automatically simultaneously withthe brake.
12. In a railway vehicle, an air operated brake system,- means for controlling said brake, air operated means for delivering cooling fluid to the wheels of the vehicle, and means for conducting air from the brake system to the cooling means to operate said cooling means simultaneously with the brake.
GEORGE MCCORMICK.
US115794A 1936-12-14 1936-12-14 Wheel cooling apparatus Expired - Lifetime US2102181A (en)

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Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2471858A (en) * 1943-07-12 1949-05-31 Lockheed Aircraft Corp Brake cooling means
US2645730A (en) * 1950-01-31 1953-07-14 Electro Mecanique De Laveyron Cooling system for electric brakes
US2655054A (en) * 1947-07-21 1953-10-13 Gen Motors Corp Cross drive for heavy vehicles
US2667238A (en) * 1941-02-19 1954-01-26 Clayton Manufacturing Co Cooling means for dynamometers
DE1246794B (en) * 1960-05-14 1967-08-10 Friedmann Kg Alex Automatic lubricating device for intermittent operation

Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2667238A (en) * 1941-02-19 1954-01-26 Clayton Manufacturing Co Cooling means for dynamometers
US2471858A (en) * 1943-07-12 1949-05-31 Lockheed Aircraft Corp Brake cooling means
US2655054A (en) * 1947-07-21 1953-10-13 Gen Motors Corp Cross drive for heavy vehicles
US2645730A (en) * 1950-01-31 1953-07-14 Electro Mecanique De Laveyron Cooling system for electric brakes
DE1246794B (en) * 1960-05-14 1967-08-10 Friedmann Kg Alex Automatic lubricating device for intermittent operation

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