A hydraulic system that activates and operates a built-in jack system to enable a driver to change their tires without needing to set up a manual jack system, especially in inclement weather or in a poorly known location. The system is made up of four hydraulic jacks located closely to each tire. A hydraulic pump activated and operated from a control panel will enable one or more of the jacks to actuate due to the hydraulic fluid, lifting the vehicle off of the ground high enough to change a tire.

A stabilizer for a vehicle includes an actuator assembly configured to be coupled to a chassis of the vehicle and a ground pad coupled to the actuator assembly. The actuator assembly is selectively repositionable between an extended position and a retracted position to reconfigure the stabilizer between a lifting configuration and a storage configuration. The ground pad has a bottom surface configured to engage a support surface below the chassis. When the stabilizer is in the lifting configuration, the bottom surface of the ground pad engages the support surface. When the stabilizer is in the storage configuration, the ground pad is not in contact with the support surface.

A stabilizer for a vehicle includes an actuator assembly configured to be coupled to a chassis of the vehicle and a ground pad coupled to the actuator assembly. The actuator assembly is selectively repositionable between an extended position and a retracted position to reconfigure the stabilizer between a lifting configuration and a storage configuration. The ground pad has a bottom surface configured to engage a support surface below the chassis. When the stabilizer is in the lifting configuration, the bottom surface of the ground pad engages the support surface. When the stabilizer is in the storage configuration, the ground pad is not in contact with the support surface.

A stabilizing system includes a plurality of jacks, each operated by a corresponding hydraulic actuator. A hydraulic fluid transfer pump supplies hydraulic fluid to and receives hydraulic fluid from one or more pressure chambers of the actuator. A pilot-operated check or directional valve may be provided in fluid communication with one or more of the pressure chambers and configured to regulate the flow of hydraulic fluid to and from the pressure chamber. A directional control valve may connect the pump output with the jacks via respective pilot-operated directional valves. The directional control valve may include a plurality of switch positions respectively connecting the pump output with pairs of the jacks.

A stabilizing system includes a plurality of jacks, each operated by a corresponding hydraulic actuator. A hydraulic fluid transfer pump supplies hydraulic fluid to and receives hydraulic fluid from one or more pressure chambers of the actuator. A pilot-operated check or directional valve may be provided in fluid communication with one or more of the pressure chambers and configured to regulate the flow of hydraulic fluid to and from the pressure chamber. A directional control valve may connect the pump output with the jacks via respective pilot-operated directional valves. The directional control valve may include a plurality of switch positions respectively connecting the pump output with pairs of the jacks.

The present invention relates to a support structure for a vehicle provided with a cargo crane having a crane base, said support structure comprising a support beam connectable to said crane base and a support leg, wherein a proximal end of said support leg is connected to said support beam at a pivoting point, such that, said support leg is pivotable around said pivoting point relative to said support beam. The support structure further comprises an actuating device connected to the support leg for pivoting said support leg relative to said support beam, wherein said actuating device is configured to arrange said support structure in at least a tunnel mode and a diagonal mode, by adjusting an extension of said actuating device, such that in the tunnel mode, a distal end of said support leg is positioned to abut against a supporting surface on which the vehicle stands and in the diagonal mode, a knee of the support structure or at least a part of a lateral side of said support leg is positioned to abut against the supporting surface on which the vehicle stands.

The present invention relates to a support structure for a vehicle provided with a cargo crane having a crane base, said support structure comprising a support beam connectable to said crane base and a support leg, wherein a proximal end of said support leg is connected to said support beam at a pivoting point, such that, said support leg is pivotable around said pivoting point relative to said support beam. The support structure further comprises an actuating device connected to the support leg for pivoting said support leg relative to said support beam, wherein said actuating device is configured to arrange said support structure in at least a tunnel mode and a diagonal mode, by adjusting an extension of said actuating device, such that in the tunnel mode, a distal end of said support leg is positioned to abut against a supporting surface on which the vehicle stands and in the diagonal mode, a knee of the support structure or at least a part of a lateral side of said support leg is positioned to abut against the supporting surface on which the vehicle stands.

A high load pivoting caster with integral jack preferably includes a wheel mounting base, a pair of wheels, a high load jack, a slewing ring, an wheel axle and an attachment cube. The wheel mounting base includes a base plate, and first and second pairs of wheel support plates. The first wheel is retained between the first pair of wheel support plates. The second wheel is retained between the second pair of wheel support plates. The wheel axle is inserted through the pair of wheels and the first and second pair of wheel support plates. The slewing ring preferably includes a stator ring, a rotor ring, an indexing plate and a set of rotary bearings. An opening is formed through the indexing plate to receive an outer perimeter of the high load jack. The attachment cube is preferably attached to a top of the indexing plate with welding.

A support apparatus is equipped with a support foot of hydraulic type that comprises: a cylinder equipped with a cavity axially shaped that has a longitudinal axis, a piston slidably received in a sealed manner in the cavity so as to divide said cavity into a first chamber and a second chamber, a stem provided with a first end fixedly connected to the piston and a second end that protrudes from the cylinder, a base fixed to the second end of the stem, and an actuation group of the support foot configured to selectively send a pressurised work fluid to the first chamber or to the second chamber so as to change the relative position of the base with respect to the cylinder. Where said support apparatus comprises: a position sensor configured to monitor the value of a parameter indicative of the position of the base with respect to a reference element fixedly connected to the cylinder, and an electronic control unit, electrically connected to said position sensor, which is configured to transmit the value of the indicative parameter monitored by the position sensor to a remote device and to control the activation of the actuation group of the support foot as a function of an activation signal and the value of the indicative parameter.

A support apparatus is equipped with a support foot of hydraulic type that comprises: a cylinder equipped with a cavity axially shaped that has a longitudinal axis, a piston slidably received in a sealed manner in the cavity so as to divide said cavity into a first chamber and a second chamber, a stem provided with a first end fixedly connected to the piston and a second end that protrudes from the cylinder, a base fixed to the second end of the stem, and an actuation group of the support foot configured to selectively send a pressurised work fluid to the first chamber or to the second chamber so as to change the relative position of the base with respect to the cylinder. Where said support apparatus comprises: a position sensor configured to monitor the value of a parameter indicative of the position of the base with respect to a reference element fixedly connected to the cylinder, and an electronic control unit, electrically connected to said position sensor, which is configured to transmit the value of the indicative parameter monitored by the position sensor to a remote device and to control the activation of the actuation group of the support foot as a function of an activation signal and the value of the indicative parameter.