A wash equipment assembly for a car wash and method of operating the equipment are described. For example, the assembly includes a cleaning element configured to clean a vehicle, an arm assembly operably attached to the cleaning element and configured to move the cleaning element to a vehicle cleaning position, the arm movably fixed to a support at a first end and the cleaning element mounted on the arm at a second end, a controlled locator for positioning the arm relative to the support such that the cleaning equipment is moved to the vehicle cleaning position, and a sensor for evaluating an actual orientation of the cleaning element relative to a default orientation of the cleaning element. In certain implementations, the controlled locator can modify the position of the arm in response to a signal from the sensor, thereby providing a closed loop control system.

A vehicle wash system includes a vehicle treatment area and an overhead frame portion supporting a pair of side brushes. The side brushes are configured to treat the lateral sides of the vehicle and may also treat the front and back of the vehicle. The side brushes are configured to pivot between a vertical position, an outwardly angled position, and inwardly angled position. The side brushes may travel along the side of the vehicle in both the vertical and pivoted orientations. The side brushes may make multiple passes along the side of the vehicle, and the side brushes may change orientation during or between passes to treat different segments of the vehicle. The side brushes may be actively pivoted or may pivot in response to contacting the vehicle when shifted laterally into contact with the vehicle.

A vehicle sensing and guidance system for a vehicle wash, and a vehicle wash, are provided. The system includes a first vehicle sensing system having at least one sensor configured to detect a vehicle and generate sensor data, a storage storing computer readable instructions, at least one processor that, when executing the computer readable instructions, determines a pose of the first vehicle using the sensor data, and at least one output device configured to present at least one of a first vehicle positioning marker and a vehicle positioning signal at least partially based on the pose of the first vehicle.

A number of dolly assemblies are connected in series with chain linkage sections to form an endless conveyor chain for the dolly assemblies to move objects along a track. Each dolly assembly includes a link attachment and a wheel assembly supported by the link attachment. The link attachment includes a base and a body portion. The body portion presents an open-loop partially surrounding an interior and extending between a pair of ends. The ends are spaced from one another to define an opening to the interior therebetween. The pair of ends are also formed in toward the interior to partially surround a respective pocket. Each pocket is configured to receive a portion of an endlink of a respective chain linkage section therein, and each one of the formed ends functions to prevent the endlink of the respective chain linkage section from becoming unhooked from the body portion.

A system for autonomously moving and aligning a vehicle with respect to an object fixed to a traveling surface in front of the vehicle includes at least one camera packaged within the vehicle to obtain images of the fixed object. A controller packaged within the vehicle receives the images from the camera and processes the images so as to identify and locate the fixed object with respect to the vehicle. A drive system, connected with the controller, is constructed and arranged to cause autonomous movement, steering and braking of the vehicle. A user input device is constructed and arranged to activate the controller 1) to identify and locate the fixed object relative to the vehicle, and 2) to command the drive system to autonomously move the vehicle towards the fixed object and to stop the vehicle so as to be aligned relative to the fixed object.

A vehicle washing installation includes at least one side washing brush which is mounted on a crossbar of the vehicle washing installation by a suspension to be rotatable about first and second pivot axes. The suspension has a first actuator for pivoting the side washing brush about the first pivot axis. The problem of providing a vehicle washing installation which, with little constructional outlay, permits a good washing result even in the case of inclined side surfaces and rear surfaces of the vehicle and the inclined transitions between said surfaces is addressed in that the suspension has a second actuator for pivoting the side washing brush about the second pivot axis, and by a method with the steps of: detecting and/or determining the inclination of a first vehicle surface running transversely with respect to the longitudinal direction; pivoting the side washing brush from a basic position about the second pivot axis in a manner corresponding to the inclination of the first vehicle surface; and moving the side washing brush along the first vehicle surface.

A vehicle washing system includes a frame disposed above a vehicle treatment area, and a reciprocal guide system coupled to the frame. The guide system is configured to move vertically relative to the frame, and supports a vehicle treatment component such as a rotatable brush. The brush may be lowered and raised relative to the vehicle treatment area by extending or retracting the guide track. When the guide system is retracted upward, there are no downwardly extending guides or rails that extend downward from the bottom of the guide system. The guide system is collapsible in a vertical direction, and may be a scissors mechanism or a telescoping mechanism or other collapsible mechanism. The guide system may be actuated directly or may be actuated dependent on a separate vertical drive mechanism, such as a windable belt.

A vehicle wash system includes a frame suspended above a vehicle treatment area. A pivotable frame is pivotally coupled to the frame, and an extendable and retractable linear frame is coupled to the pivotable frame and configured to extend downward from the pivotable frame and retract upward toward the pivotable frame. A top brush is coupled to a lower end of the linearly frame, and is extendable toward engagement with a vehicle. The top brush is also pivotable relative to a vertical position via pivoting of the pivotable frame, and the top brush is pivotable at different degrees of extension of the linear frame. The linear frame and the top brush may pivot in response to contact from the vehicle.

A vehicle wash system includes a vehicle treatment area and an overhead frame portion supporting a pair of side brushes. The side brushes are configured to treat the lateral sides of the vehicle and may also treat the front and back of the vehicle. The side brushes are configured to pivot between a vertical position and an outwardly angled position, in which the side brushes are generally aligned with the side glass of the vehicle windows. The side brushes may travel along the side of the vehicle in both the vertical and pivoted orientations. The side brushes may make multiple passes along the side of the vehicle, and the side brushes may change orientation during or between passes to treat different segments of the vehicle.

This Invention, a virtually waterless, soapless and brushless, tunnel car wash system improves traditional professional car washing methods by using less water, no soap and no brushes. The waterless cleaning formula that is used in this system is presently only available for hand use in spray bottles. The “Prep-Tunnel” prepares the car for formula application through an automated, quick and convenient process. Together the car wash tunnel equipment and the formula work to “prep” the car by pre-rinsing, drying and cooling the car so that the formula is best applied for optimal cleaning, waxing and shining results. This new system will save on water, chemical and labor cost while delivering a car that is cleaned, waxed, coated, sealed and protected.