This invention relates to a system for removing accumulated snow and ice that is adapted for use on surfaces such as sidewalks, driveways, roadways, buildings, motor vehicles, and elsewhere. More particularly, this invention relates to a portable system, which uses and recaptures heated air, for initiating the removal of snow and ice from said surfaces.
Snow and ice removal from sidewalks, walkways, driveways, and patios is traditionally carried out by using a shovel and/or a hoe. The problems associated with the use of such traditional devices are many. First, for example, a significant amount of labor is involved with the removal of snow and ice. Second, a shovel may not remove all of the snow from a surface, especially from a textured surface such as cobblestone or brick. Third, on such textured surfaces, it is difficult to shovel at all due to the shovel engaging the corners of the cobblestone, brick, or like surface. Finally, using a hoe or similar device with too much force may damage expensive outdoor surfaces.
To overcome some of the deficiencies associated with a shovel, the snow blower was invented. This device has been around for decades. However, snow blowers also have several deficiencies. For example, snow blowers may use electric power and often are limited by the range of the extension cord and/or the short term or low watt power supply of a portable battery that provides power to the unit. Snow blowers may also use gasoline powered engines that are deficient in that they require the storage of gasoline, may emit harmful and foul odors, and are extremely noisy. Moreover, given the large size of snow blowers, they are often unsuitable for use in tight alley ways and near buildings. They also are unable to remove solid ice from surfaces.
To overcome the deficiencies of the snow blower, several inventions for melting snow and ice have been proposed. These include U.S. Pat. No. 5,948,299, to Scalia, for a Portable Snow Melting Device; United States Publication No. US/2002/0069560 A1, by Smith, for a Snow Melting Device; and U.S. Pat. No. 5,140,762, to Monson, for an Apparatus for Melting Snow and Ice. These known devices may melt snow and ice; however, they are inefficient in their consumption of power in converting electrical/chemical energy into heat energy, and many of them are not versatile in their ability to be used in small spaces or on uneven or non-ground level surfaces.
It therefore would be desirable to provide a system for removing snow and ice from a surface that overcomes the deficiencies of the aforementioned prior art.
It is therefore an object of the present invention to provide a system for removing snow and ice from a surface that overcomes the deficiencies of the prior art.
It is also an object of the present invention to provide a system for removing snow and ice from a surface that uses energy efficiently and recycles the unused heat it produces.
It is another object of the present invention to provide a system for removing snow and ice from a surface that is portable and may be used in narrow or tight areas.
It is yet another object of the present invention to provide a system for removing snow and ice from a surface that is versatile enough to be used on rough surfaces, surfaces made up of loose stones or gravel, surfaces that are not on ground level, or substantially vertical surfaces.
In accordance with the present invention, a system for removing snow and ice from a surface is provided. This system, according to a preferred embodiment of the present invention, may include a housing unit, one or more blower means, a heating element, a heat reclamation means, and a power source means. The power source means may be incorporated within or located externally from the housing unit. The heat reclamation means may be any suitable device for reclaiming at least some of the heated air that is expelled from the blower housing unit for subsequent reuse.
The above and other objects, features, and advantages of the present invention will become apparent upon consideration of the following detailed description, taken in conjunction with the accompanying drawings in which like reference characters refer to like parts throughout.
The present invention is designed to provide heated air in order to remove snow and/or ice from a surface such as a driveway or walkway, including one having a rough surface or one which is made up of loose stones or gravel, a building, or a motor vehicle, and to recapture and recycle expelled but unused heated air.
As shown in
Housing unit 200 may contain a heat production section 205 defined by a lower portion of the hollow cavity of housing unit 200, a duct-like heat reclamation section 230 defined by an upper portion of the hollow cavity of housing unit 200, and a dividing wall 240 disposed between heat production section 205 and heat reclamation section 230. Dividing wall 240 may extend from one side wall 204 to the other side wall 204, and from a front end of housing unit 200 toward, but not reaching, rear wall 203. The space between rear wall 203 and dividing wall 240 may define an air transfer opening 242, which allows recycled heated air to pass from heat reclamation section 230 to heat production section 205, as more fully discussed below. Alternatively, heat production section 205 and heat reclamation section 230 may not share a wall, but instead may each have its own complete and distinct shell, with space in between the two sections, and may only meet at air transfer opening 242.
A motor 210 may be disposed within heat production section 205, and may be mounted to housing unit 200 by a motor mounting means 212. Motor mounting means 212 may be one or more rigid posts made of metal or another rigid material. Motor mounting means 212 may be mounted to rear wall 203, as shown in
A heating element 220 may also be disposed within heat production section 205, toward the front end of housing unit 200 relative to fan 214, and may be mounted to bottom wall 202, dividing wall 240, and/or side walls 204. Heating element 220 may consist of one or more heating coils or any other electrically powered heat source capable of fitting within heat production section 205 between fan 214 and the front end of housing unit 200.
An internal hose or cord 222 may be disposed within heat production section 205 so that one end of internal hose or cord 222 is attached to motor 210 and the other end of internal hose or cord 222 is attached to a port 226. Port 226 may be made of rubber or a like material and may be snugly fit within a hole in rear wall 203, as shown in
An electrical wire 224 also may be disposed within heat production section 205. One end of electrical wire 224 may be connected to motor 210, and the other end of electrical wire 224 may be connected to heating element 220, to allow the flow of electricity from motor 210 to heating element 220. Alternatively, if power source means 110 is electrical power provided by a wall socket, electrical wire 224 may be directly connected at one end to cord 120 at port 226, with the other end still connected to heating element 220.
As shown in
A retractable wheel apparatus 250 may be disposed on an exterior side of bottom wall 202, toward the front end of housing unit 200. Retractable wheel apparatus 250 may consist of a wheel mount 252, a wheel attachment means 254, and a wheel 256. Wheel mount 252 may be permanently mounted to housing unit 200. Wheel attachment means 254 may be rotatably attached to wheel mount 252 so that wheel attachment means 254 may rotate from a lowered position where wheel attachment means 254 is substantially perpendicular to bottom wall 202, as shown in
One or more feet 260 may be disposed on bottom wall 202, at or near the edge where bottom wall 202 meets rear wall 203. For example, as shown in
One or more handles 270 may be disposed on the outside of housing unit 200. Handles 270 may be attached to top wall 201, rear wall 203, or, as shown in
In operation, fan 214, powered by motor 210, generates high velocity wind as it blows air through heat production section 205 and toward the front end of housing unit 200. Said air is heated to a temperature sufficient to melt snow and ice from a surface as it is blown past heating element 220. The heated air is blown through the open front end of heat production section 205 and, when blower device 130 is aimed at it, makes contact with snow and/or ice on a surface and acts to melt said snow and/or ice. At least some of the heated air that does not reach the snow and/or ice rises toward the open front end of heat reclamation section 230. To maximize the amount of unused heated air that reaches the open front end of heat reclamation section 230, it may be concavely curved or angled with respect to the open front end of heat production section 205, as shown in
A detailed sectional side view of a second preferred embodiment of a snow and ice removal system 300 according to the present invention is shown in
Heat reclamation section 430 may be defined by a top wall 431, two side walls 432, and dividing wall 440 serving as its bottom. Heat reclamation section top wall 431 may slope upwards from the open back end of heat reclamation section 430 to an open front end of heat reclamation section 430. Heat reclamation section side walls 432 may be substantially triangular in shape. Dividing wall 440 may extend from one side wall 432 to the other side wall 432, and from the open front end of heat reclamation section 430 toward, but not reaching, the top of duct section 401. The space between dividing wall 440 and the top of duct section 401 may define an air transfer opening 442, which allows recycled heated air to pass from heat reclamation section 430 to duct section 401 and heat production section 402, as more fully discussed below. All walls of main housing unit 400 may be made of plastic or another durable material.
System 300 also may include a fan housing unit 403 defined by a top wall 406, a bottom wall 407, a rear wall 408, and two side walls 409. An open front end of fan housing unit 403 may coincide with an open back end of duct section 401. Fan housing unit 403 may have the same general cross-sectional shape as duct section 401, or their shapes may differ and only the open front end of fan housing unit 403 and the open back end of duct section 401 may have the same shape. The walls of fan housing unit 403 may be made of plastic or another durable material.
A primary motor 410 may be disposed within fan housing unit 403, and may be mounted to fan housing unit 403 by a primary motor mounting means 412. Primary motor mounting means 412 may be one or more rigid posts made of metal or another rigid material. Primary motor mounting means 412 may be mounted to rear wall 408 of fan housing unit 403, as shown in
A heating element 420 may be disposed within, and mounted to the walls of, heat production section 402. Heating element 420 may consist of one or more heating coils or any other electrically powered heat source capable of fitting within heat production section 402.
A secondary motor 434 may be disposed within heat reclamation section 430, and may be mounted to heat reclamation section 430 by a secondary motor mounting means 435. Secondary motor mounting means 435 may be one or more rigid posts made of metal or another rigid material. Secondary motor mounting means 435 may be mounted to heat reclamation section top wall 431 and dividing wall 440, as shown in
As shown in
A retractable wheel apparatus 450 may be disposed on the bottom of main housing unit 400, toward the front end of heat production section 402. Retractable wheel apparatus 450 may consist of a wheel mount 452, a wheel attachment means 454, and a wheel 456. Wheel mount 452 may be permanently mounted to main housing unit 400. Wheel attachment means 454 may be rotatably attached to wheel mount 452 so that wheel attachment means 454 may rotate from a lowered position, where wheel attachment means 454 is substantially perpendicular to the bottom of main housing unit 400, to a raised position, where wheel attachment means 454 is pointed away from the front end of heat production section 402, as shown in
A rear handle 470 may be disposed on the outside of fan housing unit 403, and a front handle 475 may be disposed on the outside of main housing unit 400. Rear handle 470 may be attached to fan housing unit top wall 406, as shown in
System 300 also may include, as a power source means, a rechargeable battery 480. Battery 480 may be detachably mounted to a battery terminal 485 located on bottom wall 407 of fan housing unit 403, or at another location outside either fan housing unit 403 or main housing unit 400. A series of electrical wires 490 may be connected at one end to battery terminal 485 and at their respective other ends to primary motor 410, secondary motor 434, and heating element 420 to allow the flow of electricity to each of those respective elements. Alternatively, system 300 may utilize an external power source means such as those described above in connection with the first preferred embodiment of the present invention.
In operation, primary fan 414, powered by primary motor 410, generates high velocity wind as it blows air through duct section 401 and heat production section 402. Said air is heated to a temperature sufficient to melt snow and ice from a surface as it is blown past heating element 420. The heated air is blown through the open front end of heat production section 402 and, when system 300 is aimed at it, makes contact with snow and/or ice on a surface and acts to melt said snow and/or ice. At least some of the heated air that does not reach the snow and/or ice rises toward the open front end of heat reclamation section 430. To maximize the amount of unused heated air that reaches the open front end of heat reclamation section 430, it may be concavely curved or angled with respect to the open front end of heat production section 402, as shown in
Thus, a system for removing snow and/or ice from a surface and for recapturing and reusing expelled but unused heated air is provided. Persons skilled in the art will appreciate that the described embodiments are presented for the purpose of illustration rather than limitation and the present invention is limited only by the claims that follow.
This application claims the benefit, pursuant to 35 U.S.C. §119(e)(1), of U.S. Provisional Application Ser. No. 60/619,316, filed Oct. 15, 2004.
Number | Name | Date | Kind |
---|---|---|---|
2476543 | Geissler et al. | Jul 1949 | A |
2779856 | Fahner | Jan 1957 | A |
2820450 | Zimmerman | Jan 1958 | A |
3174477 | Wilson | Mar 1965 | A |
3311104 | Wollner et al. | Mar 1967 | A |
3411174 | Jordan | Nov 1968 | A |
3524044 | Liardi | Aug 1970 | A |
3603507 | Devlin | Sep 1971 | A |
3964183 | Mouat | Jun 1976 | A |
4033055 | Lazarecky | Jul 1977 | A |
4918844 | Marsh | Apr 1990 | A |
5140762 | Monson | Aug 1992 | A |
5146695 | Yang | Sep 1992 | A |
5189756 | Sprunger | Mar 1993 | A |
5282264 | Reeves et al. | Jan 1994 | A |
5867926 | Schmitt | Feb 1999 | A |
5948299 | Scalia | Sep 1999 | A |
20020069560 | Smith | Jun 2002 | A1 |
Number | Date | Country |
---|---|---|
2613066 | Sep 1977 | DE |
2376028 | Sep 1978 | FR |
987946 | Mar 1965 | GB |
Number | Date | Country | |
---|---|---|---|
20060083493 A1 | Apr 2006 | US |
Number | Date | Country | |
---|---|---|---|
60619316 | Oct 2004 | US |