A magnetic mechanical latching attachment for connecting goggles to a helmet includes a goggle attachment portion configured to mechanically and magnetically attach to a helmet attachment portion. The goggle attachment portion and helmet attachment portion include complimentary interlocking features that mechanically lock the portions together when attached and magnetic features that assist engagement of the complimentary interlocking features in a locked position. A related method of coupling goggles to a helmet, as well as a helmet-goggle attachment system, is provided.

A system is provided for use by athletes and their coaches during practice. The system includes an electronic system configured for inclusion in a helmet. The electronic system includes a transparent display screen coupled to the helmet, a processor coupled to the transparent display screen, a camera coupled to the processor and a first wireless transceiver coupled to the processor. The system also includes a handheld processing device. The handheld processing device includes a second wireless transceiver configured to communicate video content with the first wireless transceiver, an interactive display screen configured to display the first video and a video editing application configured to edit the first video to generate a second video including a simulated player technique superimposed in the first video. The second video is communicated from the handheld processing device to the electronic system for display to the athlete via the transparent display screen.

An improvement of current lens roll-off systems is provided. The improvement embodies a goggle module operatively associated with a remote module by way of a wireless signal transmitted by a user engaging a remote button of the remote module, wherein the remote module may be removably connected along handlebars of the vehicle. The goggle module has an upper arm and lower arm, wherein the upper arm confirms the presence of the supply canister of the lens roll-off system, and wherein the lower arm engages a pull cord of the lens roll-off systems. The wireless signal urges the pull cord by way of the lower arm, thereby the rider can automatically operate the lens roll-off system hands-free.

Headwear includes a storage region formed in a headwear portion with the storage region having an opening. An accessory is configured to cover a portion of a wearer's face and includes first and second opposing ends. The first end of the accessory is manually removable from the storage region through the opening. A retainer is attached to the second end of the accessory for limiting movement of the accessory within the storage region. The retainer locks the second end of the accessory within the storage region.

An adjustable looped-cord goggle attachable to a helmet is provided. The goggle includes a goggle frame having a first side and a second side, one or more channels formed along an internal periphery of frame, and an elastic cord adapted to form a first loop and a second loop. A first end of the cord fastened to a first position on the first side of the frame and a second end exits through a second position on the first side of the frame forming the first loop. A remaining portion of cord is passed through the channels to reach the second side of the frame. Further, the second end of the cord is passed through a third position and exits at a fourth position on the second side of the frame forming the second loop. The first loop and second loop fasten the goggle frame to the helmet.

A pair of electric goggles is disclosed. The goggles include a conductive lens mounted onto a frame adapted to be electrically connected to an electric socket in order to raise the temperature of the lens, when powered. The goggles are provided with a strap for attaching to a helmet, the strap has a strap clip designed to have the electric socket attached thereto. The electric socket is meant to be electrically connected to a power supply via a power cable. With the combination of a strain relief clip located below the electric socket, the power cable can be positioned in a predetermined configuration, which unencumbers the user from the power cable when detaching or removing the goggles.

A protective helmet for use with motorsports and cycling activities has a head receiving helmet body that includes a head receiving interior, and an exterior having a front surface, a rear surface, and a perimetral lip for defining a forward-facing aperture. A transparent shield member is engageable with the helmet body and is configured to be placeable adjacent to the forward-facing aperture of the helmet body. The shield member includes a perimetral edge that is sized and configured for engaging the perimetral lip of the helmet body. A strap is coupled to the shield and is configured to engage the rear surface of the helmet body. The engagement of the perimetral edge of the shield member with the perimetral lip of the helmet body enables an increasing force exerted against the shield to be exerted against the helmet, rather than directly against the user's face, and resists the intrusion of dust into the interior of the helmet.

A bicycle helmet adapted to be used with eyewear includes an impact-absorbing body, a resilient wiper, and an alignment feature. The impact-absorbing body has a convex exterior surface and a concave interior surface adapted to be positioned on a user's head. The impact-absorbing body further includes an aperture formed in the exterior surface and dimensioned to permit insertion of a portion of the eyewear into the aperture along an insertion axis. The resilient wiper is positioned at least partially in the aperture and arranged to engage the portion of the eyewear upon insertion into the aperture. The alignment feature defines at least a portion of the aperture and is oriented to guide the portion of the eyewear toward the resilient wiper.

Systems and methods for coupling a clip to a wearable item with a receiver. The methods involve: receiving the clip's latch structure in the receiver's channel; sliding the latch structure's side members against a channel surface; sliding the latch structure's latch body against the channel's opening edge; bending the latch body by biasing the latch body towards the latch structure's common body portion as the latch body slides against the edge; inserting the latch body and the side members through the channel until at least the free end of the latch body no longer resides in the channel, the latch body automatically unbending when the free end of the latch body no longer resides in the channel; and preventing at least the free end of the latch body from re-entering the channel such that the clip is coupled to the wearable item.

Example implementations relate to a display and strap with sensors. In some examples, an apparatus may comprise a strap, a pressure sensor coupled to the strap, and a display coupled to the strap. In some examples, the apparatus may include a tensioner mechanism coupled to the strap and a motor coupled to the tensioner mechanism. The motor may actuate the tensioner mechanism to adjust the strap to a particular amount of tension, and the particular amount of tension may be based on an amount of pressure detected by the pressure sensor.