An apparatus (100) for applying product to the skin of a person in a booth (10), comprising: an applicator (57) configured to apply the product to the person; a first guide (40) configured to guide movement of an applicator in a first dimension, in order to enable the applicator to apply the product to the person at a plurality of different heights; and a second guide (20) configured to guide movement of the applicator in a second dimension, in order to enable the applicator to apply the product across the width of the person. The apparatus may comprise control circuitry for controlling the applicator in dependence upon the weight of the person.

An applicator making it possible to apply a coating product on a surface to be coated, including at least one row of nozzles, among which at least the first nozzle in the row includes a valve, the applicator further including at least one distance sensor, to measure an application distance of the first nozzle from a point in front of the latter on a path of the applicator, and an electronic control unit of the valve, which is programmed to collect the distance measured by the distance sensor and, based on the collected distance value, to open or close the valve.

A dispensing device comprising a body with an attachment mechanism configured to connect to a subject, a reservoir disposed inside the body, a removable selected fragrance disposed inside the reservoir, a dispenser coupled to the reservoir, a controller coupled to the dispenser and configured to dispense the selected fragrance, and a plurality of sensors on the body configured to provide data streams to a smart device.

Disclosed are a pesticide spraying control method, a device, and a storage medium. The method includes: planning, by a controller, a spraying route matching an area to be sprayed, and mapping the spraying route to a crop prescription map matching the area to be sprayed; and determining, by the controller, a spraying control point in the spraying route and a spraying amount matching the spraying control point based on crop state information in at least two areas included in the crop prescription map. The spraying control point is associated with an actual spraying point of an operation unmanned aerial vehicle. The actual spraying point is spaced from the spraying control point associated with the actual spraying point by a set distance on the spraying route and is located before the spraying control point associated with the actual spraying point in a forward direction of the operation unmanned aerial vehicle.

A system for repairing a paint defect of a part can have means for identifying the paint defect of the part, a robotic applicator, and a computer module. The robotic applicator can include a dispenser and a pad. The robotic applicator can be configured to position the dispenser and the pad adjacent to the paint defect of the part. The dispenser can be configured to atomize a composition into an atomized composition. The dispenser can be also configured to dispose a predetermined amount of the atomized composition on the paint defect. The pad can be configured to work the predetermined amount of the atomized composition on the paint defect. The computer module can be in communication with the robotic applicator. The computer module can be configured to control functions of the robotic applicator.

A disinfectant dispensing system for automatically cleaning a high-traffic surface. The automatic disinfectant dispensing system is configured to spray a disinfecting or sanitizing solution on a high-traffic surface for a predetermined time long enough to clean the surface after the surface has been touched and potentially contaminated. A liquid disinfecting or sanitizing solution is retained in a fluid storage component. The solution is dispensed to a plurality of fluid dispensing components via distribution tubing in fluid communication with the fluid storage component. Each of the fluid dispensing components is positioned near a high-traffic surface, such as a doorknob. A motion sensing element in each fluid dispensing components detects the presence of an external object, such as a hand, and activates a fluid dispersal element to dispense the disinfecting or sanitizing solution a period of time after the motion is no longer detected.

An pet spray training system is provided. The system includes a sound, vibration or motion sensor that is configured to generate electrical signals in response to an occurrence. The system may include a filter, which is tuned to recognize a dog barking event, and generate an electrical signal in response to recognizing an input signal indicative of a dog's bark. The system further includes a removably pressurized gas reservoir that holds a deterrent fluid under pressure. The system additionally comprises a motor module configured to rotate a shaft in response to the electrical signal from the filter. The canister has a spray nozzle for releasing fluid that affects the dog's senses. In response to rotating the shaft, the spray nozzle is depressed.

A soap dispenser can be configured to dispense an amount of liquid soap, for example, upon detecting the presence of an object. Certain embodiments of the dispenser include a housing, reservoir, pump, motor, sensor, electronic processor, and nozzle. In certain embodiments, the sensor can be configured to generate a signal based on a distance between an object and the sensor. In certain embodiments, the electronic processor can be configured to receive the signal from the sensor and to determine a dispensation volume of the liquid. The dispensation volume can vary as a function of the distance between the object and the sensor. The processor can be configured to control the motor to dispense approximately the dispensation volume of the liquid.

The disclosure relates to a coating method for coating a component with a coating agent, comprising the following steps: moving an application device over a component surface of the component to be coated, delivering a coating agent jet (9) from the application device to the component surface that is to be coated, defining switching points on the component surface for initiating a switching action, in particular for switching on or switching off a coating agent jet, and performing the switching action when one of the switching points is reached. The disclosure provides the following steps: marking the switching points on the component surface by generating a switching marking on the component surface at the individual switching points, detecting the switching markings corresponding to the individual switching points during movement of the application device, and performing the switching actions when the switching markings are detected on the component surface. The disclosure further includes a corresponding coating installation.

A system for the in situ production of a liner suitable to shield active surfaces of apparatus for the processing of liquids and/or solids from coming into contact with, and being fouled by, the processed materials, comprises: 1) a spray head, adapted to spray a layer of curable polymeric material onto a surface; 2) circuitry adapted to direct the movement of said spray head according to data pertaining to the surface to be sprayed; and 3) curing apparatus, suitable to cure the layer of material sprayed onto said surface, thereby to produce a shielding liner in situ.