A ball collection apparatus constituted of: a control circuitry; a body; motors; wheels arranged to rotate responsive to the motors, the body arranged to move along a surface responsive to the rotation of the plurality of wheels; a collection compartment arranged to maintain a ball within a predetermined area in relation to the body; a ball input port in communication with the collection compartment; and a ball ejector arranged to eject the ball from the collection compartment, wherein the control circuitry is arranged to: receive information regarding the location of the ball; responsive to the received information, control the at least one motor to advance the body towards the location of the ball, the collection compartment arranged to collect the ball through the ball input port; and control the ball ejector to eject the ball from the collection compartment and propel the ejected ball towards a predetermined target area.

A main body of a ball collecting and discharging machine includes a traveling portion and a ball collecting and discharging portion to collect and discharge balls. A controller causes the ball collecting and discharging portion to collect the balls scattered in a ball scattered area while causing the traveling portion to cause the main body to travel along a ball collecting route in the ball scattered area. When the ball collecting and discharging portion reaches a state of being ready to discharge balls during or after ball collecting work, the controller causes the traveling portion to cause the main body to travel along the ball discharging route and causes the ball collecting and discharging portion to discharge balls at the ball discharging site.

An assembly for conveying sports equipment includes a first pulley, a second pulley, and a belt extending between and movable around the pulleys. A plurality of engagement members are coupled to the belt such that they travel along a path extending from the first pulley to the second pulley and back. The second pulley is spaced apart from the first pulley along a first axis, and along a second axis that is perpendicular to the first axis such that the belt is inclined toward the second pulley, and such that sports equipment engaged with an engagement member beneath the first pulley will advance toward the second pulley. A stop member is offset from the path of the engagement members such that empty engagement members can proceed beyond the stop member, and the stop member is configured to stop motion of the belt upon contacting sports equipment conveyed by engagement members.

A lacrosse teaching device includes a body, a ball receptacle, and a valve. The body includes a first leg, a second leg, and an archway interconnecting the first and second legs. The body defines a tunnel and the archway defines an opening. A ball receptacle defines a cavity and an opening. The cavity is dimensioned to hold at least one lacrosse ball. The ball receptacle communicates with the opening in the archway such that a lacrosse ball can travel from the cavity of the ball receptacle through the opening in the archway and into the tunnel. The valve is positioned between the cavity of the ball receptacle and the opening in the archway and is actuable to control movement of the at least one lacrosse ball from the cavity of the ball receptacle into the opening in the archway.

An inverted dunk tank including a frame attached to a trailer. The frame supports a plurality of water tanks in an upper section of the frame. The plurality of water tanks is each connected to a water release valve respectively. At least one sidewall is attached to the frame. The at least one sidewall has a plurality of holes located therein. Each of the plurality of holes has a sensor therein. The sensors detect when an item passes through the hole. The sensor will send a signal to the water release valve and dump water from the tank.

A non-transitory storage medium having stored thereon logic is disclosed. The logic is executable by one or more processors to perform operations including receiving information associated with a selection of a first training drill, responsive to receiving the information associated with the selection of the first training drill and based on the first training drill, causing a first light to be placed in an activated state, wherein the first light is coupled to a first goal apparatus, and responsive to a triggering event, causing the first light to be placed in a deactivated state and causing a second light to be placed in an activated state. The goal apparatus includes posts that form a goal plane, wherein a first sensor pair is coupled to the goal, and wherein the triggering event is a detection of an object passing through the posts and across the goal plane.

An inverted dunk tank including a frame attached to a trailer. The frame supports a plurality of water tanks in an upper section of the frame. The plurality of water tanks is each connected to a water release valve respectively. At least one sidewall is attached to the frame. The at least one sidewall has a plurality of holes located therein. Each of the plurality of holes has a sensor therein. The sensors detect when an item passes through the hole. The sensor will send a signal to the water release valve and dump water from the tank.

An intelligent ball passing system is provided, including: a ball passing robot configured for carrying out a ball passing action according to human body postures, including: a video capture device (1) configured for acquiring human body posture data, a movement mechanism (2) configured for driving the ball passing robot to move according to a ball passing instruction, and a central processing module (3) connected to the movement mechanism (2) and the video capture device (1) respectively; and a software system configured for controlling the ball passing robot to carry out the ball passing action, the central processing module recognizing and classifying the human body postures by using the software system that uses a BP neural network.

A sports projectile delivery system may control the operation of a launcher to cause an American football or other sports projectile to be delivered to a target location on a field. In some aspects, the system can track player movements on the field, e.g., through the use of a tracking device mounted on the player, enabling the ball etc. to be launched to a player in anticipation of where the player will go. The system may include additional customization and/or logging options, e.g., permitting a player to designate a body position (e.g., above the head or near the knees) for delivery of the ball, designate a speed or hang time for delivery, or provide player data and analytics to an online or otherwise connected database.

A light charger charges a plurality of luminescent balls to emit light for use in dim lighting. The charger is a housing subdivided into a hopper section, a transport and light charging section, and a base section. The transport and light charging section includes a transport assembly integrated with a light charging assembly, with the transport assembly configured to receive and transport luminescent balls from the hopper into and through the light charging assembly, which comprises at least one light source. The light source comprises at least one LED and an illuminating light panel interposed between the LED and the luminescent ball when operating. The base section comprises an ejection exit point for the charged luminescent ball to exit the light charging assembly and a sensor for activating the system to eject at least one luminescent ball.