The present disclosure relates to an individual gear dryer system. In particular, the present disclosure relates to a firefighter turnout gear or protective ensemble drying application.
Firefighting is a highly dangerous task that subjects firefighters to many hazards. An important asset to the firefighters is the turnout gear he wears while performing his duties. The turnout gear typically includes a coat, bunker pants, gloves, and boots, which are constructed of protective and fire-resistant materials. Because of the heavy materials and construction used, turnout gear that gets damp or wet while a firefighter is on duty is not easily ventilated and dried before the gear is needed again.
Perpetually damp and wet gear leads to many problems. Damp and wet gear promotes the growth of mildew and bacteria, which may lead to skin irritation, fungus, odor, and other more serious skin conditions. Moisture retained in the fabric may also cause premature wear, shorten the life expectancy, and compromise the thermal protective capability of the gear.
The National Fire Protection Association, Inc. (NFPA) has promulgated the standards for the selection, care, and maintenance of firefighting protective ensembles in publication NFPA 1851. Although NFPA 1851 specifies that air drying is the most appropriate method of drying firefighting ensemble elements, it does provide for the use of drying rooms in which the air is heated to no more than 100 degrees Fahrenheit. Conventional gear dryer systems employ rigid tubular racks onto which the gear may be hung. The tubular racks conduct and ventilate air into the gear to speed drying. Other conventional systems use a specially-outfitted cabinet that circulates air using ductwork and racks inside the cabinet. However, these conventional rack and cabinet systems are bulky, take up valuable space in the firehouse, and are expensive.
An individual gear dryer system for firefighting gear and equipment and other applications is envisioned and described herein.
A dryer system for a firefighting ensemble comprising a housing having an air intake port and an air outlet port, a forced air assembly including a heater and a blower accommodated within the housing, a plurality of flexible porous hose segments coupled to the air outlet port operable to receive and conduct forced air therefrom, and the plurality of flexible porous hose segments are operable to conduct forced heated air into elements of the firefighting ensemble to speed drying.
A dryer system for an ensemble comprising a housing having an air intake port and an air outlet port, a forced air assembly accommodated within the housing, a plurality of flexible porous conducting elements coupled to the air outlet port operable to receive and conduct forced air therefrom, and the plurality of flexible porous conducting elements are operable to conduct forced air into elements of the ensemble to speed drying.
A portable dryer system comprising a forced air assembly including a heater and a blower, a plurality of flexible porous hose segments coupled to an air outlet of the forced air assembly and operable to receive and conduct forced air therefrom, and the plurality of flexible porous hose segments are operable to conduct forced heated air into articles of equipment to speed drying.
In a preferred embodiment, the housing of system 10 additionally includes an electrical outlet 22 that enables another individual gear dryer system or device to obtain power in situations where wall-mounted electrical outlets are scarce.
Coupled to the housing air outlet port is a plurality of interconnected porous flexible hose segments 24-29 that are operable to conduct the heated forced air from the blower and to release it along its lengths. One possible candidate for the porous flexible hose segments 24-29 may be the soaker hose used in gardening applications, for example. Conventional soaker hoses are made from rubber, polyethylene, and like materials. The porous flexible hose segments 24-29 are used to be threaded into the torso, sleeves, waist, pant legs, and boots of the turnout coat and pants to circulate heated air into the elements of the ensemble to speed drying. Hose segments 24-29 are coupled to an air outlet in the housing to receive and conduct forced heated air. The porosity of the hose segments enables the forced air to be distributed internally within the firefighting ensemble.
It should be noted that the individual dryer system described herein is not limited to the firefighting application. For example, this system may be used with scuba gear (e.g., wetsuit), waterskiing gear (e.g., swimwear and life jacket), snow sport gear (e.g., snowsuit, jacket, pants, boots, and gloves), boating gear, kayaking gear, and many other equipment and clothing that benefit from quicker drying time. Because a bulky specialized or custom rack system is not required, the individual dryer system may be easily ported and deployed anywhere.
The features of the present invention which are believed to be novel are set forth below with particularity in the appended claims. However, modifications, variations, and changes to the exemplary embodiments described above will be apparent to those skilled in the art, and the individual gear dryer system described herein thus encompasses such modifications, variations, and changes and are not limited to the specific embodiments described herein.
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Number | Date | Country | |
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Child | 13288220 | US |