CA1288706C - Transit vehicle friction brake deceleration control system - Google Patents
Transit vehicle friction brake deceleration control systemInfo
- Publication number
- CA1288706C CA1288706C CA000546088A CA546088A CA1288706C CA 1288706 C CA1288706 C CA 1288706C CA 000546088 A CA000546088 A CA 000546088A CA 546088 A CA546088 A CA 546088A CA 1288706 C CA1288706 C CA 1288706C
- Authority
- CA
- Canada
- Prior art keywords
- brake
- emergency
- air
- friction
- service
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Expired - Lifetime
Links
Landscapes
- Regulating Braking Force (AREA)
Abstract
ABSTRACT OF THE DISCLOSURE
An improved friction brake system for a transit vehicle is disclosed. The conventional friction brake system for a transit vehicle utilizes an integral service brake and emergency-parking brake actuator. The service brake portion is air powered while the emergency-parking brake portion is spring powered. It has been conventional to apply full service air brake and emergency spring brake during emergency stops. An accelerometer switch is typi-cally connected in circuit with the service brake portion to prevent the service brake from turning on if their is sufficient deceleration. The accelerometer switch often does not react quickly enough to prevent the onset of the service brakes. The present invention utilizes a time delay switch to delay the onset of service brakes until after the spring-activated emergency brakes react.
An improved friction brake system for a transit vehicle is disclosed. The conventional friction brake system for a transit vehicle utilizes an integral service brake and emergency-parking brake actuator. The service brake portion is air powered while the emergency-parking brake portion is spring powered. It has been conventional to apply full service air brake and emergency spring brake during emergency stops. An accelerometer switch is typi-cally connected in circuit with the service brake portion to prevent the service brake from turning on if their is sufficient deceleration. The accelerometer switch often does not react quickly enough to prevent the onset of the service brakes. The present invention utilizes a time delay switch to delay the onset of service brakes until after the spring-activated emergency brakes react.
Description
38~i FIELD OF INVENTION
The present invention relates to braking systems in general and, in particular, to a Eriction braking system or a rubber tire transit vehicle.
BRIEF DESCRIPTION OF THE DRAWINGS
For a better understanding of the invention, reference may be had to the accompanying drawings in which:
Figure 1 is a elevational end view of a typical transit vehicle.
Figure 2 is a cross-sectional elevational view of a friction brake actuator showing the air-actuated service brake containment portion in the actuated condition, and the spring-activated emergency parking brake containment portion in a spring-off position.
Figure 3 is a cross-sectional elevational view of the friction brake actuator showing the spring in the parking or emergency position with the service brake containment portion not actuated by air.
Figure ~ is a schematic diagram of the prior art friction braking system.
Figure 5 is a schematic diagram of the riction braking system of the present invention.
Figure 6A is a graph showing the deceleration characteristic utilizing the prior art friction braking system upon application of the emergency brakes.
Figure 6B is a graph of the prior art system showing the - deceleration characteristic upon the system experiencing a broken spring in the emergency brakes.
~28~ 6 1a 67880-52 Figure 6C is a graph of the deceleration characteristic of the present invention upon application of the emergency brakes under normal operation.
Figure 6D is a graph of the deceleration characteristics of the fric-tion brake system of -the present invention with a spring failure.
, ~ 2~38~6 BACKGROUND OF THE INVENTION
Modern transit vehicles such as used in San Francisco's Bart system and the Orlando and Atlanta airports utilize a combination of dynamic or regenerative braking and friction braking to bring the vehicles to a controlled stop. These modern systems have been described in articles such as 'IAtlanta Airport People Mover," by Thomas C. Selis, Manager, in the Conference Record of the 28th IEEE Vehicular Technology Group in Denver, Colorado, on March 22, 1978, and also in an article " Recent Applications of Microprocessor Technology to People Mover Systems," by Michael P. McDonald et al., in the Conference Record of the 29th IEEE Vehicular Technology Group Conference in Chicago, Illinois, March 28, 1979.
U.S. Patent No. 3,398,992 issued to Joseph C. Littmann, dated August 27, 1968, discloses a brake control system for hydraulic brakes on a trailer connected to a towing vehicle. The Littmann patent teaches variation of the pressure o the fluid in the hydraulic system to vary the degree of braking. U.S. Patent ~0 No., 4,384,330 issued to Matsuda et al., dated ~ay 17, 1983, discloses a brake control system for an automotive vehicle for controlliny application release of brake pressure in order to prevent the vehicle from skidding. Another deceleration control system is disclosed in UOS. Patent No. 3,751,116 issued to Thomas H. Engle, dated ~ugust 7, 1983, which discloses a railway brake controller which modulates the train line brake-controlling signal as required to maintain balance between a command force indicative of a desired rate of retardation and a feedback force developed by ~8706 a liquid-filled column subjec-t to the actual rate o~ retardation.
Another brake control apparatus is disclosed in U.S. Patent No.
4,410,154 issued to Thomas C. Matty, dated October 18, 1983, and assigned to the present assignee. The Matty reference discloses a transit vehicle control apparatus which determines a safe brake velocity for a vehicle in relation to a speed control relationship including roadway system design deceleration, the deceleration of the vehicle in relation to inertial space and the deceleration of the vehicle in relation to the roadway. The Matty patent teaches the use of microprocessor-based technology to accomplish braking control.
The typical transit vehicle or "people mover" as part of the braking system includes friction drum brakes of the same kype that are used on tractor trailers and which are well known in the art. The friction brakes are controlled by friction brake actuators which are typically integral units having a fail-safe design such that if the actuators suffers loss of air pressure, a spring causes the friction brakes to engage. Referring to Fig.
6A, there is shown a typical deceleration curve upon the application of the emergency brake spring-activated system. As apparent from graph 6A, there is typically an initial spike or a high deceleration rate which may produce an uncomfortable jerk for passengers on the transit vehicle. This spike occurs as a result of the service brakes which are air-activa-ted being fully applied during an emergency stop having a faster response time than the spring-activated system. An accelerometer which is typically connected in circuit with the service brakes is typically too slow to retard the onset of the service brakes even though sufficient ~.
87~
deceleration is being supplied by the spring activated system~ A
typical prior art system producing this response is shown in Fig.
4.
S~MMARY OF_T~IE I~VENTION
The present invention is provided in combination with a friction braking system ~or a transit vehicleO The typical transit vehicle includes a car body, axles mounted -to the car body~ Wheels are carried by the axles. A braking system is provided, including friction drum brakes mounted on the axles.
Friction brake actuators are provided for actuating the friction brakes to retard the rotation of the wheels. Friction brake actuator controls are provided for controlling the friction brake actuators.
The friction brake actuators typically comprise a rod member means for connection ko the friction brakes, and an outer chamber enclosing an air-actuated service brake containment portion and also encIosing a spring-activated emergency-parking brake containment portion. The air-actuated service brake containment portion encloses service brake means for moving the rod member means. The spring-activated emergency-parking brake containment por-tion encloses emergency-parking brake means Eor moving the rod member means.
The emergency-parking brake means for moving the rod member means includes a springO The spring-activated emergency-parking brake containment portion includes a first diaphragm affixed to the outer chamber. The interior of the outer chamber proximate the emergency-parking brake containment portion and the first diaphragm define a first air chamber. The first diaphragm9 ~ ~8~
upon air pressure being applied to the ~irst air chamber, causes the spring to be in a compressed condition.
The service brake means for moving the rod member includes a second diaphragm affixed to the outer chamber. The interior o~ the outer chamber proximate the service brake portion and the second diaphragm de~ine a second air chamber. The second diaphragm, upon air pressure being applied to the second chamber, causes the rod member means to operate the ric-tion brakes.
The friction brake actuator control includes a first electro-mechanical air valve connected in fluid co~munication with the first air chamber. An air source is provided for supplying air to the first air valve. A second electro-mechanical air valve is connected in 1uid communication with the second air chamber and the air source. A power source is provided for energizing the first and second air valves.
An emergency brake control switch is connected in circuit between the power source and the first air valve. A
service brake control switch is connected in circuit between the power source and the second air valve~ An accelerometer switch is connected in circuit with a power source and the second electro~
mechanical air valveO
The improvement o the present invention comprises the accelerometer switch being initially connected in circuit to the power source through the emergency brake control switch~ A time-delay switch means is included and is connected in circuit with the accelerometer for switching the accelerometer from being in circuit with the power source through the emergency brake control switch to being in circuit with the power source after a 5a 67880-52 predetermined delay, and by-passing the emergency brake con-trol switch. The service brake con-trol switch prevents the initial onset of the service brake means Eor moving the rod member means until after the spring means Eor moving the rod membe:r thereby preventing undesirable jerks of the vehicle during emergency stopping.
BRIEF DESCRIPTION OF THE PREFERRED EMBODIMENTS
With reference to Fig. 4, there is shown a prior art friction braking system 10 for a transit vehicle 12 such as shown in Figure 1. The transit vehicle 12 includes a car body 14 and the axle means 16 mounted to the car body. Wheel means 18 which may be rubber tired are carried on the axle 16. The braking system 10, such as shown in Fig. 4, includes friction drum brake means 20 mounted on the axle 16 which is conventional and is not shown. Friction brake actuator means 22 is provided for actuating the friction brakes 20 to retard -the rotation of the wheels 18.
~; , ~`21 3~
Friction brake actuator control means 24 is provided for controlling the friction brake actuator 22.
Referring to Figs. 2 and 3, the ricticn brake actuator may be such as manufactured by Anchor Lok, Inc of Culver City, California, Model No. 9-15. The friction braka actuator 2~ comprisss a rod member means 26a, 26b for connectiGn to ths friction drum brakes 20 shown schemat -cally in Figs. 2 and 3. Friction brake actuator also includes outer chamber means 28 enclosing an air-powered service braka containment portion 30 and also enciosing a spring-powered emergency-parking brake containment portion 32. The air-powered service brake containment portion 30 encloses service brake means 34 Ior moving the rod member means 26. The rod member means 26 typically includes a pair of push rods 27~, 27b. The s~ring-ac~ ate~
emergency-parking brake containment portion 32 encloses emergency-parking brake means 36 for moving the rod member means 26 including a spring 38. The spring-activated emergency-par~ing brake containment portion 32 inc'udes a first diaphragm 40 affixed to the outer chamber 28. The inner surface 42 of the outer chamber means 28 proximate the emergency-parking brake containment portion 32 and ths irst diaphragm 40 defining a first air chamber 44. The first diaphragm 40, upon air pressure being supplied to the irst air chamber 44, causing the spring ~8 to be in a compressed condition.
Service brake means 34 for moving the rGd member 26 includes a second diaphragm 46 affixed to the outsr chamber 28. The i~ner surface a8 of the outer chamber 23 proximate the surface brake portion 30 defining a second air chamber 50. The second diaphragm 46, upon air pressure being applied to the second air chamber 50, causes the rod member ?6, i.e., push rod ~7รข~ to operate the frl-~ion brakes 24. Typically, the service brake means for moving the rod means 26 is used for service brakes where the variation of air pressure in the first chamber controls the amount of braking effort exerted by the friction brakes.
~ 288~
.
Referrin~ to Fig. 4, the friction brake actuator control means 24 includes a first electro-mechanical air valve means 52 connected in fluid communication with the first air chamber 44. An air source 54 is provided for su?plying air to the first air valve 52. A second electro-mQchanica~ air valve msans 56 is connscted in ~ id communication with the sscond air chamber 50 and the air source 54. A power source 58 is provided for energizing the first air valve 52 and the second air valve 56.
Emergensy b~ake control switch means 60 is conne-ted in circuit between the power source 58 and the first air valve 52. Service brake control sw1tch means 62 is connected in circuit between tne power source 58 and the second air valve 55. EmergQncy hrak~ control switch means 60 typical-ly includes emerge~cy brake; control 5~ and emergcncy brakecontact relay 61. Service brake control switch means 62 typlcally includes service braXe control 63 and service brake contact relay 65. The service brake control 63 and emergency brake control 59 maybe microprocessor based controls as disclosed i~ the aforesaid U.S. Patent No.
410,154 issued to Matty. Accelerometer switch means 64, such as manufactursd by Ed Cliff Instruments, a subsidiary of Systxon-Donner Corporation oI Monrovia, California, Model No. 7-600, is desirably connected in circuit with the power source 58 and the second electro-magnetic air valve 56. The Criction braking system described thus far is gen2rally conventionzl.
The improvement o the present invention entails initially connecting accelerometer ~witch 64 in circuit with the power source 58 through the emergency brake control switch 60 as shown in Fig. S. A time-delay switch means 66, such as manufactured by Potter Bromfield, Model CDC38-30G25, may be u~iiized. The Potter Bromfield Switch is a slow-release relay. The time-deLay switch 66 is for switching the accelerometer switch means from being in circuit with the power source 58 through the emergency brake control switch means 60 to being in circuit with the ;
:
~1 2~
power source 58 after a predetermined delay and by~passing the emergency brake switch means 60, whereby upon the emergency brake switch 60 being ener~ized, the service brake switch means 62 can only be activated ~fter a prede-tsr~inG~ dela~, thereby ~reventing undesirabl~ jerks of thetransit vehicla 1' durlng em~rgency stopping.
With rQfsrence to the graph shown in Figs. 6A-6D, it can be seen that utilizing the present invention, the spike 67 which may be caused by the prior art initial air servicQ braXe activation is eliminated by the time-delay of the time-delay switch 66 which can be one second, for example, which permits the spring-activated emergency brake to take eLfect. If the spring brake is insu ficient, ~he accelerometer switch 64 will permit the air service ~rake por_ion 3~ to taXe effect after the time delay. Graphs 63 and 6D indicate that under spring 38 failure the accelerometer switch will successfully close and then open as braking is applied by the air system with an acceptable one-second time deiay, as shown in Fig. 6D, occasioned by the time-delay switch 66 of the present invention.
The present invention relates to braking systems in general and, in particular, to a Eriction braking system or a rubber tire transit vehicle.
BRIEF DESCRIPTION OF THE DRAWINGS
For a better understanding of the invention, reference may be had to the accompanying drawings in which:
Figure 1 is a elevational end view of a typical transit vehicle.
Figure 2 is a cross-sectional elevational view of a friction brake actuator showing the air-actuated service brake containment portion in the actuated condition, and the spring-activated emergency parking brake containment portion in a spring-off position.
Figure 3 is a cross-sectional elevational view of the friction brake actuator showing the spring in the parking or emergency position with the service brake containment portion not actuated by air.
Figure ~ is a schematic diagram of the prior art friction braking system.
Figure 5 is a schematic diagram of the riction braking system of the present invention.
Figure 6A is a graph showing the deceleration characteristic utilizing the prior art friction braking system upon application of the emergency brakes.
Figure 6B is a graph of the prior art system showing the - deceleration characteristic upon the system experiencing a broken spring in the emergency brakes.
~28~ 6 1a 67880-52 Figure 6C is a graph of the deceleration characteristic of the present invention upon application of the emergency brakes under normal operation.
Figure 6D is a graph of the deceleration characteristics of the fric-tion brake system of -the present invention with a spring failure.
, ~ 2~38~6 BACKGROUND OF THE INVENTION
Modern transit vehicles such as used in San Francisco's Bart system and the Orlando and Atlanta airports utilize a combination of dynamic or regenerative braking and friction braking to bring the vehicles to a controlled stop. These modern systems have been described in articles such as 'IAtlanta Airport People Mover," by Thomas C. Selis, Manager, in the Conference Record of the 28th IEEE Vehicular Technology Group in Denver, Colorado, on March 22, 1978, and also in an article " Recent Applications of Microprocessor Technology to People Mover Systems," by Michael P. McDonald et al., in the Conference Record of the 29th IEEE Vehicular Technology Group Conference in Chicago, Illinois, March 28, 1979.
U.S. Patent No. 3,398,992 issued to Joseph C. Littmann, dated August 27, 1968, discloses a brake control system for hydraulic brakes on a trailer connected to a towing vehicle. The Littmann patent teaches variation of the pressure o the fluid in the hydraulic system to vary the degree of braking. U.S. Patent ~0 No., 4,384,330 issued to Matsuda et al., dated ~ay 17, 1983, discloses a brake control system for an automotive vehicle for controlliny application release of brake pressure in order to prevent the vehicle from skidding. Another deceleration control system is disclosed in UOS. Patent No. 3,751,116 issued to Thomas H. Engle, dated ~ugust 7, 1983, which discloses a railway brake controller which modulates the train line brake-controlling signal as required to maintain balance between a command force indicative of a desired rate of retardation and a feedback force developed by ~8706 a liquid-filled column subjec-t to the actual rate o~ retardation.
Another brake control apparatus is disclosed in U.S. Patent No.
4,410,154 issued to Thomas C. Matty, dated October 18, 1983, and assigned to the present assignee. The Matty reference discloses a transit vehicle control apparatus which determines a safe brake velocity for a vehicle in relation to a speed control relationship including roadway system design deceleration, the deceleration of the vehicle in relation to inertial space and the deceleration of the vehicle in relation to the roadway. The Matty patent teaches the use of microprocessor-based technology to accomplish braking control.
The typical transit vehicle or "people mover" as part of the braking system includes friction drum brakes of the same kype that are used on tractor trailers and which are well known in the art. The friction brakes are controlled by friction brake actuators which are typically integral units having a fail-safe design such that if the actuators suffers loss of air pressure, a spring causes the friction brakes to engage. Referring to Fig.
6A, there is shown a typical deceleration curve upon the application of the emergency brake spring-activated system. As apparent from graph 6A, there is typically an initial spike or a high deceleration rate which may produce an uncomfortable jerk for passengers on the transit vehicle. This spike occurs as a result of the service brakes which are air-activa-ted being fully applied during an emergency stop having a faster response time than the spring-activated system. An accelerometer which is typically connected in circuit with the service brakes is typically too slow to retard the onset of the service brakes even though sufficient ~.
87~
deceleration is being supplied by the spring activated system~ A
typical prior art system producing this response is shown in Fig.
4.
S~MMARY OF_T~IE I~VENTION
The present invention is provided in combination with a friction braking system ~or a transit vehicleO The typical transit vehicle includes a car body, axles mounted -to the car body~ Wheels are carried by the axles. A braking system is provided, including friction drum brakes mounted on the axles.
Friction brake actuators are provided for actuating the friction brakes to retard the rotation of the wheels. Friction brake actuator controls are provided for controlling the friction brake actuators.
The friction brake actuators typically comprise a rod member means for connection ko the friction brakes, and an outer chamber enclosing an air-actuated service brake containment portion and also encIosing a spring-activated emergency-parking brake containment portion. The air-actuated service brake containment portion encloses service brake means for moving the rod member means. The spring-activated emergency-parking brake containment por-tion encloses emergency-parking brake means Eor moving the rod member means.
The emergency-parking brake means for moving the rod member means includes a springO The spring-activated emergency-parking brake containment portion includes a first diaphragm affixed to the outer chamber. The interior of the outer chamber proximate the emergency-parking brake containment portion and the first diaphragm define a first air chamber. The first diaphragm9 ~ ~8~
upon air pressure being applied to the ~irst air chamber, causes the spring to be in a compressed condition.
The service brake means for moving the rod member includes a second diaphragm affixed to the outer chamber. The interior o~ the outer chamber proximate the service brake portion and the second diaphragm de~ine a second air chamber. The second diaphragm, upon air pressure being applied to the second chamber, causes the rod member means to operate the ric-tion brakes.
The friction brake actuator control includes a first electro-mechanical air valve connected in fluid co~munication with the first air chamber. An air source is provided for supplying air to the first air valve. A second electro-mechanical air valve is connected in 1uid communication with the second air chamber and the air source. A power source is provided for energizing the first and second air valves.
An emergency brake control switch is connected in circuit between the power source and the first air valve. A
service brake control switch is connected in circuit between the power source and the second air valve~ An accelerometer switch is connected in circuit with a power source and the second electro~
mechanical air valveO
The improvement o the present invention comprises the accelerometer switch being initially connected in circuit to the power source through the emergency brake control switch~ A time-delay switch means is included and is connected in circuit with the accelerometer for switching the accelerometer from being in circuit with the power source through the emergency brake control switch to being in circuit with the power source after a 5a 67880-52 predetermined delay, and by-passing the emergency brake con-trol switch. The service brake con-trol switch prevents the initial onset of the service brake means Eor moving the rod member means until after the spring means Eor moving the rod membe:r thereby preventing undesirable jerks of the vehicle during emergency stopping.
BRIEF DESCRIPTION OF THE PREFERRED EMBODIMENTS
With reference to Fig. 4, there is shown a prior art friction braking system 10 for a transit vehicle 12 such as shown in Figure 1. The transit vehicle 12 includes a car body 14 and the axle means 16 mounted to the car body. Wheel means 18 which may be rubber tired are carried on the axle 16. The braking system 10, such as shown in Fig. 4, includes friction drum brake means 20 mounted on the axle 16 which is conventional and is not shown. Friction brake actuator means 22 is provided for actuating the friction brakes 20 to retard -the rotation of the wheels 18.
~; , ~`21 3~
Friction brake actuator control means 24 is provided for controlling the friction brake actuator 22.
Referring to Figs. 2 and 3, the ricticn brake actuator may be such as manufactured by Anchor Lok, Inc of Culver City, California, Model No. 9-15. The friction braka actuator 2~ comprisss a rod member means 26a, 26b for connectiGn to ths friction drum brakes 20 shown schemat -cally in Figs. 2 and 3. Friction brake actuator also includes outer chamber means 28 enclosing an air-powered service braka containment portion 30 and also enciosing a spring-powered emergency-parking brake containment portion 32. The air-powered service brake containment portion 30 encloses service brake means 34 Ior moving the rod member means 26. The rod member means 26 typically includes a pair of push rods 27~, 27b. The s~ring-ac~ ate~
emergency-parking brake containment portion 32 encloses emergency-parking brake means 36 for moving the rod member means 26 including a spring 38. The spring-activated emergency-par~ing brake containment portion 32 inc'udes a first diaphragm 40 affixed to the outer chamber 28. The inner surface 42 of the outer chamber means 28 proximate the emergency-parking brake containment portion 32 and ths irst diaphragm 40 defining a first air chamber 44. The first diaphragm 40, upon air pressure being supplied to the irst air chamber 44, causing the spring ~8 to be in a compressed condition.
Service brake means 34 for moving the rGd member 26 includes a second diaphragm 46 affixed to the outsr chamber 28. The i~ner surface a8 of the outer chamber 23 proximate the surface brake portion 30 defining a second air chamber 50. The second diaphragm 46, upon air pressure being applied to the second air chamber 50, causes the rod member ?6, i.e., push rod ~7รข~ to operate the frl-~ion brakes 24. Typically, the service brake means for moving the rod means 26 is used for service brakes where the variation of air pressure in the first chamber controls the amount of braking effort exerted by the friction brakes.
~ 288~
.
Referrin~ to Fig. 4, the friction brake actuator control means 24 includes a first electro-mechanical air valve means 52 connected in fluid communication with the first air chamber 44. An air source 54 is provided for su?plying air to the first air valve 52. A second electro-mQchanica~ air valve msans 56 is connscted in ~ id communication with the sscond air chamber 50 and the air source 54. A power source 58 is provided for energizing the first air valve 52 and the second air valve 56.
Emergensy b~ake control switch means 60 is conne-ted in circuit between the power source 58 and the first air valve 52. Service brake control sw1tch means 62 is connected in circuit between tne power source 58 and the second air valve 55. EmergQncy hrak~ control switch means 60 typical-ly includes emerge~cy brake; control 5~ and emergcncy brakecontact relay 61. Service brake control switch means 62 typlcally includes service braXe control 63 and service brake contact relay 65. The service brake control 63 and emergency brake control 59 maybe microprocessor based controls as disclosed i~ the aforesaid U.S. Patent No.
410,154 issued to Matty. Accelerometer switch means 64, such as manufactursd by Ed Cliff Instruments, a subsidiary of Systxon-Donner Corporation oI Monrovia, California, Model No. 7-600, is desirably connected in circuit with the power source 58 and the second electro-magnetic air valve 56. The Criction braking system described thus far is gen2rally conventionzl.
The improvement o the present invention entails initially connecting accelerometer ~witch 64 in circuit with the power source 58 through the emergency brake control switch 60 as shown in Fig. S. A time-delay switch means 66, such as manufactured by Potter Bromfield, Model CDC38-30G25, may be u~iiized. The Potter Bromfield Switch is a slow-release relay. The time-deLay switch 66 is for switching the accelerometer switch means from being in circuit with the power source 58 through the emergency brake control switch means 60 to being in circuit with the ;
:
~1 2~
power source 58 after a predetermined delay and by~passing the emergency brake switch means 60, whereby upon the emergency brake switch 60 being ener~ized, the service brake switch means 62 can only be activated ~fter a prede-tsr~inG~ dela~, thereby ~reventing undesirabl~ jerks of thetransit vehicla 1' durlng em~rgency stopping.
With rQfsrence to the graph shown in Figs. 6A-6D, it can be seen that utilizing the present invention, the spike 67 which may be caused by the prior art initial air servicQ braXe activation is eliminated by the time-delay of the time-delay switch 66 which can be one second, for example, which permits the spring-activated emergency brake to take eLfect. If the spring brake is insu ficient, ~he accelerometer switch 64 will permit the air service ~rake por_ion 3~ to taXe effect after the time delay. Graphs 63 and 6D indicate that under spring 38 failure the accelerometer switch will successfully close and then open as braking is applied by the air system with an acceptable one-second time deiay, as shown in Fig. 6D, occasioned by the time-delay switch 66 of the present invention.
Claims
1. In combination with a friction braking system for a transit vehicle, said transit vehicle including a car body, axle means mounted to said car body, wheel means carried by said axle means, said braking system including friction brake means mounted on said axle means, friction brake actuator means for actuating said friction brakes to retard the rotation of said wheel means, friction brake actuator control means for controlling said friction brake actuator means, said friction brake actuator means compris-ing rod member means for connection to said friction brake means, outer chamber means enclosing an air powered service brake containment portion and enclosing a spring powered emergency-parking brake containment portion, said air powered service brake containment portion enclosing service brake means for moving said rod member means, said spring activated emergency-parking brake containment portion enclosing emergency-parking brake means for moving said rod member means, said emergency parking brake means for moving said rod member means including a spring, said spring activated emergency-parking brake containment portion including a first diaphragm means affixed to said outer chamber, the inner surface of said outer chamber means proximate said emergency-parking brake containment portion and said first diaphragm defining a first air chamber, said first diaphragm upon air pressure being applied to said first air chamber causing said spring to be in a compressed condition, said first means for moving said rod member including a second diaphragm means affixed to said outer chamber means inner surface, the interior surface of said outer chamber means proximate said service brake portion and said second diaphragm means defining a second air chamber, said second diaphragm means upon air pressure being applied to said second air chamber causing said rod member means to operate said friction brake means, said friction brake actuator control means including a first electro-mechanical air valve means connected in fluid communication with said first air chamber, an air sourc-for supplying air to said first air valve means, a second electro-mechanical air valve means connected in fluid communication with said second air chamber and said air source, a power source for energizing said first air valve means and said second air-valve means, an emergency brake control switch means connected in circuit between said power source and said first air valve means, a service brake control switch means connected in circuit between said power source and said second air valve means, accelerometer switch means connected in circuit with said power source and said second electro-mechanical air valve means, the improvement which comprises:
said accelerometer switch means initially con-nected in circuit with said power source through said emergency switch means, a time delay switch means connected in circuit with said accelerometer switch means for switch-ing said accelerometer switch means from being in circuit with said power source through said emergency brake control switch means to being in circuit with said power source after a predetermined delay and by-passing said emergency brake switch means, whereby upon said emergency-parking brake means for moving said rod member means being activat-ed, said service brake means for moving said rod member means can only be activated after a predetermined delay thereby preventing undesirable jerks of said transit vehicle during emergency stopping.
said accelerometer switch means initially con-nected in circuit with said power source through said emergency switch means, a time delay switch means connected in circuit with said accelerometer switch means for switch-ing said accelerometer switch means from being in circuit with said power source through said emergency brake control switch means to being in circuit with said power source after a predetermined delay and by-passing said emergency brake switch means, whereby upon said emergency-parking brake means for moving said rod member means being activat-ed, said service brake means for moving said rod member means can only be activated after a predetermined delay thereby preventing undesirable jerks of said transit vehicle during emergency stopping.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CA000546088A CA1288706C (en) | 1987-09-03 | 1987-09-03 | Transit vehicle friction brake deceleration control system |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CA000546088A CA1288706C (en) | 1987-09-03 | 1987-09-03 | Transit vehicle friction brake deceleration control system |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CA1288706C true CA1288706C (en) | 1991-09-10 |
Family
ID=4136383
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CA000546088A Expired - Lifetime CA1288706C (en) | 1987-09-03 | 1987-09-03 | Transit vehicle friction brake deceleration control system |
Country Status (1)
| Country | Link |
|---|---|
| CA (1) | CA1288706C (en) |
-
1987
- 1987-09-03 CA CA000546088A patent/CA1288706C/en not_active Expired - Lifetime
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| Date | Code | Title | Description |
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| MKLA | Lapsed |