A tire pressure management system includes at least an axle, which houses pressurized fluid, and is supported by a tire. A vehicle frame supported by the axle, by way of a suspension is disposed between frame and the axle. Also included is a pressure management controller (PMC) supported by the frame, which communicates with the tire. A load detection device (LDD) interacting with the suspension determines a value for a load supported by the suspension. The PMC provides at least a central processing unit (CPU) programmed with a lookup table that associates the value determined by the LDD with a predetermined pressure for the tire. The CPU directs an inflation, else a deflation of of the tire based on the determined value.

A rotary union having a housing, a shaft rotatably disposed within the housing, and a tube having a first end sealingly disposed within the shaft and a second end sealingly coupled to the housing. A tire inflation system may comprise a rotary union externally mounted to a vehicle wheel end or mounted to a vehicle fairing.

Various systems and methods are provided for a central tire inflation system with a wheel hub including an integrated sealing surface. In one embodiment, a system comprises: a vehicle wheel hub including a gas passage and a sealing surface shaped to engage directly with a seal to fluidly couple the gas passage to a counterpart gas passage of a stationary vehicle component. The sealing surface may be formed integrally with the vehicle wheel hub and shaped to engage directly with the seal with no other components disposed between the sealing surface and the seal.

A rotary joint assembly for a tire inflation system for a vehicle includes a stationary portion defining a first fluid passage. The stationary portion includes a support portion and having a first annular sealing face. The first fluid passage ending in the first annular sealing face. The assembly also includes at least one bearing and a rotatable portion rotatably mounted on the support portion by way of the at least one bearing. The rotatable portion defines a second fluid passage and has a second annular sealing face, the second fluid passage ending in the second annular sealing face. The rotatable portion defines an axis of rotation of the rotatable portion and a radial direction oriented perpendicular to the axis of rotation. The at least one bearing supporting an inner face of the rotatable portion, wherein the inner face of the rotatable portion faces toward the axis of rotation. An annular seal chamber is radially disposed between the first annular sealing face and the second annular sealing face and provides fluid communication between the first fluid passage and the second fluid passage. The at least one bearing and the annular seal chamber at least partially overlap along an axial direction oriented in parallel to the axis of rotation.

A rotary union having a housing, a shaft rotatably disposed within the housing, and a tube having a first end sealingly disposed within the shaft and a second end sealingly coupled to the housing. A tire inflation system may comprise a rotary union externally mounted to a vehicle wheel end or mounted to a vehicle fairing.

An assembly for a tire inflation system including a spindle having a fluid conduit. The spindle is coupled with a rotary joint spindle, and the rotary joint spindle includes a fluid conduit in fluid communication with the spindle fluid conduit. A fluid collector ring is located about the rotary joint spindle such that the fluid collector ring may rotate. The fluid collector ring is also in fluid communication with the rotary joint spindle fluid conduit.

A wheel end assembly includes a spindle having a passage formed therein. The wheel end assembly also includes a hub cap assembly. The hub cap assembly has an inner housing and an outer housing. The inner housing and outer housing are in fluid communication via an air passage. An air spindle has an inboard portion and an outboard portion. The inboard portion is disposed in the spindle and the outboard portion is disposed in the inner housing. Also, the air spindle has a fluid passage. The fluid passage is in fluid communication with the passage formed in the spindle and the air passage formed in the hub cap assembly. A rotary air seal is disposed around the air spindle. A rotary oil seal is disposed around the air spindle and is spaced apart from the rotary air seal.

A vehicle operational diagnostics and condition response system includes at least an axle supporting a vehicle frame, a suspension disposed between and secured to each the vehicle frame and the axle, a load detection device interacting with the suspension and communicating with a system controller, wherein the system controller is supported by the vehicle frame, and a vehicle operational lighting system supported by the frame and communicating with the system controller. The vehicle operational lighting system is activated by the system controller in response to load detection data received by the system controller from the load detection device.

A wheel end assembly for a tire pressure management system including an axle having an axle end portion and a rotary joint assembly disposed outboard of the axle end portion. The rotary joint has a rotary hub, a non-rotating tube spindle at least partially disposed within the rotary hub, the tube spindle having a tube spindle hollow central chamber, an air seal provided between the rotary hub and the tube spindle, and a bearing assembly provided between the rotary hub and the tube spindle. The bearing assembly is positioned outboard of the air seal.

In one aspect, a rotary union for a wheel end system including a wheel hub having a passageway. The rotary union includes a pressurized air receiver configured to be mounted to a vehicle spindle, an air inlet of the pressurized air receiver, a pressurized air distributor rotatable around an axis relative to the pressurized air receiver, and an air outlet of the pressurized air distributor. The pressurized air distributor is configured to be mounted to the wheel hub and rotate therewith. The rotary union further includes a seal axially spaced from the air inlet so that the seal and the air inlet are offset from one another along with the vehicle spindle. The seal is shiftable from a disengaged configuration to an engaged configuration to permit pressurized air received at the air inlet of the pressurized air receiver to flow to the air outlet of the pressurized air distributor.