Pneumatic anti-compound on service brake backup line

The invention claimed is: 1. A pneumatic braking system for an axle of a vehicle, comprising: a service brake actuator configured to apply a braking force to the axle of the vehicle, a parking brake actuator, configured to apply a braking force under the action of an elastic spring and a pneumatic chamber, the pneumatic chamber being configured to apply a force opposed to the force applied by the spring, an electro pneumatic modulator unit configured to: receive a first air control pressure representative of a braking request, receive an air supply pressure, and deliver a first modulated air pressure to a service brake chamber to control the braking force applied, the first modulated air pressure being delivered by a regulation unit, the total braking force being a sum of a service brake actuator force and a parking brake actuator force, a parking brake unit, configured to deliver a second air pressure to the parking brake pneumatic chamber to control the braking force applied by the parking brake actuator, and an isolation device configured to: in a first mode in which the isolation device is electrically energized, prevent the delivery of the first air control pressure to the regulation unit, and in a second mode in which the isolation device is not electrically energized: allow the delivery of the first air control pressure to the regulation unit so that a braking force is applied by the service brake actuator when the pressure in the parking brake chamber is higher than a first predetermined threshold, and prevent the delivery of the first air control pressure to the regulation unit when the pressure in the parking brake chamber is lower than or equal to the first predetermined threshold. 2. The pneumatic braking system of claim 1 , in which the isolation device comprises an on-off solenoid valve, the on-off solenoid valve comprising: an inlet port, an outlet port, a control port, a return spring, an electromagnet, and a plunger, configured to move under the joined action of the electromagnet, the return spring, and a pressure in the control port, to selectively allow or prevent fluidic communication between the inlet port and the outlet port, the plunger being configured to: allow fluidic communication between the inlet port and the outlet port when the electromagnet is not electrically energized and the pressure in the control port is higher than the first predetermined threshold, and prevent fluidic communication between inlet port and outlet port: when the electromagnet is electrically energized, or when the electromagnet is not electrically energized and the pressure in the inlet port is higher than a second predetermined threshold and the pressure in the control port is lower than a third predetermined threshold, wherein the first air control pressure is fluidically connected to the inlet port of the on-off solenoid valve, in which the outlet port of the on-off solenoid valve is fluidically connected to the regulation unit, and in which the control port is fluidically connected to the parking brake pneumatic chamber. 3. The pneumatic braking system of claim 1 , in which the isolation device comprises a select low valve and an electromagnetic isolation valve, the electromagnetic isolation valve comprising an inlet port and an outlet port, and being configured for allowing fluidic communication between the inlet port and the outlet port when the electromagnetic isolation valve is not electrically energized and for preventing fluidic communication between the inlet port and the outlet port when the electromagnetic isolation valve is electrically energized, the select low valve comprising a first inlet port connected to the first air control pressure, a second inlet port connected to the parking brake pneumatic chamber having a second air pressure, and an outlet port, and the select low valve being configured so that an outlet port pressure is equal to the lowest of the first air pressure and the second air pressure, wherein the outlet port of the select low valve is connected to the inlet port of the electromagnetic isolation valve, and wherein the outlet port of the electromagnetic isolation valve is configured for being in fluidic communication with the regulation unit. 4. The pneumatic braking system of claim 1 , in which the isolation device comprises a pneumatic isolation valve and an electromagnetic isolation valve, the pneumatic isolation valve comprises a control port, an inlet port, and an outlet port, the first air control pressure being fluidically connected to the inlet port, the control port being fluidically connected to the parking brake pneumatic chamber, the pneumatic isolation valve configured to: allow fluidic communication between the inlet port and the outlet port if pressure in the control port is higher than the first predetermined threshold, prevent fluidic communication between the inlet port and the outlet port if pressure in the control port is lower than or equal to the first predetermined threshold, and allow fluidic communication between the outlet port and atmosphere if pressure in the control port is lower than or equal to the first predetermined threshold, and the electromagnetic isolation valve comprising an inlet port and an outlet port, and is configured to: allow fluidic communication between the inlet port and the outlet port when the electromagnetic isolation valve is not electrically energized, and prevent fluidic communication between inlet port and outlet port when the electromagnetic isolation valve is electrically energized, wherein the outlet port of the pneumatic isolation valve is connected to the inlet port of the electromagnetic isolation valve, and wherein the outlet port of the electromagnetic isolation valve is configured for being in fluidic communication with the regulation unit. 5. The pneumatic braking system of claim 1 , in which the isolation device is included in the electro pneumatic modulator unit. 6. The pneumatic braking of claim 1 , in which the isolation device is included in a foot brake modulator, the foot brake modulator being configured to deliver the first air control pressure and being a separate unit from the electro pneumatic modulator unit. 7. The pneumatic braking system of claim 6 , in which the isolation device is separate from the electro pneumatic modulator unit and separate from the foot brake modulator. 8. The pneumatic braking system of claim 1 , in which the first predetermined parking brake chamber pressure threshold for allowing or preventing the delivery of the first air control pressure to the regulation unit is between 3.5 Bar and 4.5 Bar. 9. The pneumatic braking system of claim 2 , in which the second predetermined threshold is comprised between 3 and 4 Bar, and the third predetermined threshold is comprised between 2 and 2.8 Bar. 10. The pneumatic braking system of claim 3 , in which the parking brake unit comprises an electronic control unit configured for delivering the second modulated air pressure to the parking brake pneumatic chamber. 11. The pneumatic braking system of claim 1 , further comprising: a second service brake actuator configured to apply a braking force to a second axle of the vehicle, and a second electro pneumatic modulator unit configured to: receive the first air control pressure representative of a braking request, receive the air supply pressure, and deliver a second modulated air pressure to a second service brake chamber to control the braking force applied by the second service brake actuator, the second modulated air pressure being delivered by a second regulation unit, wherein the isolation device is furth