A protective helmet includes a plurality of fluid filled bladders, impact sensors, valves, and pumps wherein the helmet absorbs energy from an impact to protect a person wearing the helmet from traumatic brain injury. The bladders expel fluid in response to a triggering event such as energy from an
A protective helmet includes a plurality of fluid filled bladders, impact sensors, valves, and pumps wherein the helmet absorbs energy from an impact to protect a person wearing the helmet from traumatic brain injury. The bladders expel fluid in response to a triggering event such as energy from an impact detected as a pressure spike event and/or detected as an acceleration event. A selected bladder may expel fluid to other bladders, to a reservoir, to the environment outside of the protective helmet, or combinations thereof. In embodiments where the bladders need additional fluid after an impact, one or more pumps may refill selected deflated bladders. When a bladder is underinflated, an indicator light may emit light on an outer surface of the protective helmet to warn that the bladder is not yet ready to be placed in operation to absorb another impact.
대표청구항▼
1. A protective helmet, comprising: a structural support band defining a perimeter edge of the protective helmet;a plurality of bladders interconnected to the structural support band, each bladder in the plurality of bladders having a volume configured to store fluid;a valve positioned on each bladd
1. A protective helmet, comprising: a structural support band defining a perimeter edge of the protective helmet;a plurality of bladders interconnected to the structural support band, each bladder in the plurality of bladders having a volume configured to store fluid;a valve positioned on each bladder in the plurality of bladders, each valve being in fluid communication with the corresponding volume of each bladder in the plurality of bladders;a sensor positioned on each bladder in the plurality bladders, each sensor being in operable communication with the corresponding valve of each bladder in the plurality of bladders, wherein each valve is configured to open and release at least some of the fluid stored in the corresponding volume when the corresponding sensor detects a triggering event; andat least one pump in fluid communication with the volumes of the plurality of bladders, the at least one pump configured to increase the pressure of the fluid stored in the volumes of the plurality of bladders to a fill pressure after deflation of one or more bladders; andwherein a plurality of fluid lines that provide fluid communication between bladders in the plurality of bladders such that a pressure change in one bladder is transmitted to at least one other bladder. 2. The protective helmet of claim 1, wherein: the sensors are one of: pressure sensors configured to detect a triggering event that is a pressure increase beyond a predetermined pressure threshold; oraccelerometers configured to detect a triggering event defined as an acceleration exceeding a predetermined acceleration threshold. 3. The protective helmet of claim 1, wherein: each valve is configured to close when the corresponding sensor detects a second triggering event, wherein the second triggering event is one of:a pressure decrease below a second predetermined pressure threshold; ora delay period after the first triggering event. 4. The protective helmet of claim 1, further comprising: a centralized controller operably interconnected to at least one sensor and at least one valve in the plurality of bladders, the controller configured to receive an input signal from the at least one sensor and transmit an output signal to the at least one valve, depending on a predetermined logic. 5. The protective helmet of claim 1, further comprising: a decentralized controller positioned on each bladder in the plurality of bladders, each controller configured to receive an input signal from a corresponding sensor and transmit an output signal to a corresponding valve, depending on a predetermined logic. 6. The protective helmet of claim 1, wherein: the sensors are in operable communication with each other, wherein the sensor that detects the triggering event is configured to open more than one valve. 7. The protective helmet of claim 1, further comprising: a first check valve positioned in a first tube of each fluid line in the plurality of fluid lines, the first check valve oriented to allow fluid flow in a first direction; anda second check valve positioned in a second tube of each fluid line in the plurality of fluid lines, the second check valve oriented to allow fluid in a second direction. 8. The protective helmet of claim 7, wherein: the first check valve has a first cracking pressure, and the second check valve has a second cracking pressure, wherein the first cracking pressure is set to the fill pressure of the fluid in the volumes of the plurality of bladders. 9. The protective helmet of claim 1, further comprising: an indicator light positioned on an outer surface of the plurality of bladders, the indicator light configured to emit light after deflation of one or more bladders. 10. The protective helmet of claim 1, wherein: the plurality of bladders comprises a right front bladder, a right rear bladder, a left rear bladder, a left front bladder, a top left bladder, and a top right bladder. 11. The protective helmet of claim 5, wherein: the predetermined logic includes at least one of: a) activation to open a valve based on detected pressure of a sensor being above a predetermined threshold;b) activation to open a valve based on detected acceleration of the helmet above a predetermined threshold; orc) a selected combination of a) and b). 12. A protective helmet, comprising: a structural support band defining a perimeter edge of the protective helmet;a plurality of bladders interconnected to the structural support band, each bladder in the plurality of bladders having a volume configured to store fluid;a valve positioned on each bladder in the plurality of bladders, each valve being in fluid communication with the corresponding volume of each bladder in the plurality of bladders;a sensor positioned on each bladder in the plurality bladders, each sensor being in operable communication with the corresponding valve of each bladder in the plurality of bladders, wherein each valve is configured to open and release at least some of the fluid stored in the corresponding volume when the corresponding sensor detects a triggering event; andat least one pump in fluid communication with the volumes of the plurality of bladders, the at least one pump configured to increase the pressure of the fluid stored in the volumes of the plurality of bladders to a fill pressure after deflation of one or more bladders; andwherein the at least one pump is an individual pump positioned on each bladder in the plurality bladders, each individual pump being in operable communication with the corresponding sensor of each bladder in the plurality of bladders. 13. A protective helmet, comprising: a structural support band defining a perimeter edge of the protective helmet;a plurality of bladders interconnected to the structural support band, each bladder in the plurality of bladders having a volume configured to store fluid;a valve positioned on each bladder in the plurality of bladders, each valve being in fluid communication with the corresponding volume of each bladder in the plurality of bladders;a sensor positioned on each bladder in the plurality bladders, each sensor being in operable communication with the corresponding valve of each bladder in the plurality of bladders, wherein each valve is configured to open and release at least some of the fluid stored in the corresponding volume when the corresponding sensor detects a triggering event; andat least one pump in fluid communication with the volumes of the plurality of bladders, the at least one pump configured to increase the pressure of the fluid stored in the volumes of the plurality of bladders to a fill pressure after deflation of one or more bladders; andwherein a padding layer disposed on an inner surface of the plurality of bladders, the padding layer having an inner surface that is distinct from the inner surface of the plurality of bladders.
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