An aquatic exercise apparatus for applying a resistive force to an exercising swimmer, the apparatus includes a bracket mounted to a vertically oriented surface located above a pool of water, a container, an operational assembly comprising at least one upper pulley attached to the bracket and at least one lower pulley attached to the container, a cord passing through the at least one upper pulley and the at least one lower pulley, and a fastener configured to attach to an exercising swimmer, where the fastener is attached to a free end of the cord, and where pulling the free end of the cord moves the container upward against gravity.

According to a first embodiment of the present application, Applicant discloses an aquatic exercise device for assisting a swimmer to practice swimming in place. The device comprises: a pair of tines, each tine comprising an upper end and a lower end; a fork root attached to the upper ends of the pair of tines; and a suspension element attached to and suspending the fork root. The suspension element suspends the fork root and the upper ends of the tines above water comprising a practice area, the lower ends of the tines are submerged in the water of the practice area, and the pair of tines operative to maintaining a position of the swimmer in the practice area.

The ability for a non-swimmer or unskilled swimmer to float horizontally in the water can be lifesaving and can reduce the incidence of drowning deaths. Swim training devices to facilitate teaching of basic flotation techniques to non-swimmers, unskilled swimmers, and for use in rehabilitation therapy and general aqua therapy are disclosed herein. The devices and methods are designed to encourage, facilitate, and increase psychological comfort with floating in a horizontal position, versus a vertical position. The swim trainer device includes a body and a float which may be mounted coplanar with the body, and may be adjustable. Multiple uses and configurations are discussed for use by swim instructors and others working with infants, toddlers, children, and adults.

A timing device is provided herein. The timing device includes a housing defining an aperture. An elongated member is extendable from the housing through the aperture. A reel assembly includes a spool rotatable about a spool axle. A portion of the elongated member is wound about the spool. An encoder assembly includes a first wheel and an encoder operably coupled with the first wheel. The encoder is configured to detect a rotational velocity of the first wheel. A controller is configured to calculate a linear velocity of the elongated member based on the rotational velocity of the first wheel, wherein the elongated member is configured to move with the swimmer as the swimmer moves away from the housing.

An apparatus for remote controlled physical activity monitoring, the apparatus comprising: at least one orientation measurer, wearable on at least one body part of a user, configured to measure orientation of a body part wearing the orientation measurer during a physical activity of the user, at least one pressure meter, wearable on at least one body part of the user, configured to measure pressure applied by muscle of a body part wearing the pressure meter during the physical activity of the user, a computer processor, associated with the orientation measurer and pressure meter, configured to derive monitoring control data from the measured orientation and pressure, and a data transmitter, associated with the computer processor, configured to transmit the monitoring control data to a physical activity monitoring device, and thereby to remotely control a monitoring of the physical activity of the user by the physical activity monitoring device.

The present invention relates to a floatable breathing device. The floatable breathing device provides includes a head unit, a snorkel, a plurality of receiving passageways, and an internal pathway. The head unit has buoyant properties and includes an ornamental shaped buoyant outer material and an inner shell positioned within the buoyant outer material. The inner shell forms a head receiving section and a protruding section. The head receiving section is received internal to the buoyant outer material and is configured to be contoured to a human head, the protruding section extending from the head receiving section to a vent opening in the outer buoyant material. The snorkel is connected to and extending through the head unit, while the plurality of receiving passageways are disposed about the inner shell and receiving the snorkel such that the snorkel extends through and exits a portion of the head unit at the vent opening. The internal pathway is positioned along a base of the outer buoyant material and extends between the internal shell and the buoyant outer material, passing to the interior of the interior shell through a cutout in a protruding portion thereof and terminating adjacent to the vent opening.

An aquatic game apparatus includes a target that is buoyant and configured to float on water. The target has a target portion that has a plurality of target openings for receiving a water skipping article. The target openings may have different opening sizes and different point values. The target portion may be rotated up a target angle from a base portion. The base portion contains floatation units that may be detachable to the target. One or more anchors, which may be fillable weight bags may be coupled to the target by straps and configured to retain the target in a position. The aquatic game apparatus may also contain a backstop having a net to capture water skipping articles that have missed the target. The target and/or the backstop may comprise inflatable floatation units. The target and/or the skipping article may glow in the dark.

Systems and methods of analyzing a user's motion during a swimming session are described. One or more motions sensors can collect motion data of the user. A processor circuit can make motion analysis based on the motion data. The processor circuit can determine if the user's arm swing is a genuine swim stroke. The processor circuit can also determine whether the user is swimming or turning. The processor circuit can also classify the user's swim stroke style. The processor circuit can also determine the user's swim stroke phase. The processor circuit can also determine the user's stroke orbit consistency.

In one aspect, a swim system may include a reverse thrust system worn by a swimmer proximate the frontal upper torso. The system provides a variable amount of reverse thrust such that the user can swim-in-place or make gradual forward progress. Importantly, this may enable a user to effectively “extend” a small residential pool to serve the same function as a twenty-five meter pool typically found at commercial or government facilities. The system also provides laminar current under the user while swimming, which solves the problems of “leg drop,” the need to “out-kick” the arm stroke, and turbulence and wave action around the head associated with conventional swim-in-place devices. Still further, in certain embodiments the system provides a relatively strong current in the region of the arm stroke moving away from the swimmer which provides enhanced “resistance” for proficient swimmers.

An adaptable exercise system enables the portable and adaptable placement of exercise equipment that can be adjusted to suit the intended exercises to be performed. The system provides a cross bar and legs that can be used in water, sand, gravel, sod or any location. The legs are height adjustable and allow for a variety of configurations and thus exercises.