A thermal monitor control system for a refuse vehicle includes a plurality of onboard devices including a first onboard device and a second onboard device, a plurality of sensors including a first sensor configured to collect a first data set and a second sensor configured to collect a second data, and a processing circuit configured to receive the first data set from the first sensor and the second data set from the second sensor, define a normal operating profile, receive a third data set from the first senor and a fourth data set from the second sensor, compare the third data set and the fourth data set to the normal operating profile, and cause the onboard messaging system to display the alert to the operator in response to determining that the third data set or the fourth data set differs from the normal operating profile.

A method for controlling a vehicle (1) assembled from a set of modules (20). The vehicle (1) includes: at least one drive module (30); and at least one functional module (40). The at least one drive module (30) has a pair of wheels (32) and is configured to autonomously operate and drive the assembled vehicle (1) wherein the modules (30, 40, 70, 80) of the vehicle (1) are configured to communicate with the control device (100). The method includes: receiving (s101) data from the modules (30, 40, 70, 80) of the vehicle (1), wherein the data includes a value of at least one parameter associated with a current condition of the modules (30, 40, 70, 80); evaluating (s102) the received data by comparing the value of the at least one parameter with a predetermined value or value interval for the at least one parameter; and controlling (s103) the vehicle (1) based on the evaluation.

A refuse vehicle has a tailgate. The tailgate has a framework to secure CNG tanks. A cover overlays the frame work to provide an aesthetic appearance to the vehicle.

A fluid system for a vehicle is provided. The fluid system is configured to couple to a chassis of the vehicle. A frame assembly of the fluid system is configured to couple with the chassis directly or with another component that is coupled, directly or indirectly, with the chassis. A cowling of the fluid system can enclose a fuel pressure vessel and an auxiliary fluid vessel. The auxiliary fluid vessel is configured to be placed in fluid communication with the component powered or operated by the fluid therein.

A joystick control system for a refuse vehicle includes multiple joystick input devices, and a single controller. The single controller is configured to receive a user input from one or more of the multiple joystick input devices. The controller is also configured to identify which of the joystick input devices provide the user input. The controller is also configured to generate control signals, in response to receiving the user input, for one or more controllable elements of the refuse vehicle based on which of the joystick input devices provides the user input and the user input. The controller is also configured to provide the control signals to the one or more controllable elements of the refuse vehicle to operate the one or more controllable elements of the refuse vehicle according to the user input.

A refuse vehicle includes a chassis, a first energy storage device, a body, an electric power take-off system, and a subsystem coupled to the body and moveable using hydraulic power from the electric power take-off system. The first energy storage device (e.g., a battery) is supported by the chassis and is configured to provide electrical power to a prime mover. Activation of the prime mover selectively drives the refuse vehicle. The body is configured for storing refuse, and is supported by the chassis. The electric power take-off system is positioned on the body and includes an electric motor, a second energy storage device configured to provide electric power to the electric motor, and a hydraulic pump that is drive by the electric motor. The electric motor drives the hydraulic pump to convert the electrical power into hydraulic power.

An air intake assembly for a vehicle includes an air intake configured to intake ambient air and a heater box configured to be positioned adjacent a component of an exhaust assembly of the vehicle. The heater box is configured to intake ambient air and heat the air by heat absorption from the component of the exhaust assembly. The air intake assembly is configured to selectively permit passage of ambient air from the air intake and heated air from the heater box toward the engine assembly. The air intake assembly may selectively permit passage of ambient air and heated air by use of a valve in communication with the air intake and the heater box and further in connection with an engine assembly of the vehicle, the valve configured to selectively permit passage of ambient air from the air intake and heated air from the heater box toward the engine assembly.

A refuse collection vehicle body having a receiving hopper with a pendulum packer device mounted for arcuate movement therewithin, a tapered storage compartment for receiving refuse material from the receiving hopper, a tailgate assembly having a pneumatic mechanism for controlling the tailgate latch mechanism, and an ejection system for dumping the refuse material collected within the storage compartment, the storage compartment having a trough or channel associated with its top portion for housing the hydraulic cylinders associated with the pendulum packer device and the tailgate assembly. The hydraulic cylinder associated with the ejection system as well as the hydraulic tank and hydraulic fluid cooler associated with the vehicle body are all positioned over hazmat containment devices to contain any leakage from these components during normal operation. The tapered storage compartment is formed by joining two rectangular sheets of material to a pair of wedge shaped members.

A fuel management module for use with a CNG fuel system for a vehicle includes a housing configured to be connected to the vehicle and a number of connections, receptacles, and controls associated with the module. A defueling receptacle may be positioned on the front panel of the housing, for defueling a fuel tank of the vehicle. A defueling control valve may be positioned on the front panel of the housing for controlling operation of the defueling receptacle, allowing for selective defueling. One or more high pressure connections may be accessible on the housing and configured for connection to one or more separate fuel tanks in a plug and play configuration. A plurality of filling connections may be accessible on the housing for filling the fuel tank(s). A low pressure fuel output connection may be positioned on the back panel of the housing to provide fuel output from the high pressure connections to the engine.

A refuse collection vehicle body having a receiving hopper with a pendulum packer device mounted for arcuate movement therewithin, a tapered storage compartment for receiving refuse material from the receiving hopper, a tailgate assembly having a pneumatic mechanism for controlling the tailgate latch mechanism, and an ejection system for dumping the refuse material collected within the storage compartment, the storage compartment having a trough or channel associated with its top portion for housing the hydraulic cylinders associated with the pendulum packer device and the tailgate assembly. The hydraulic cylinder associated with the ejection system as well as the hydraulic tank and hydraulic fluid cooler associated with the vehicle body are all positioned over hazmat containment devices to contain any leakage from these components during normal operation. The tapered storage compartment is formed by joining two rectangular sheets of material to a pair of wedge shaped members.