Air and Steam Snow Rake

Abstract

A snow rake used to clear snow or ice from roofs, with air or steam assistance, respectively. A system comprising a rake head, at least one extension tube, a control handle, two pressurized supply lines, wherein the pressurized supply lines carry a fluid, and a fluid source. A rake head comprising a platform, a blade, at least one pressurized transport feed line, at least one nozzle, a tubular connecting column and a quick release connector. When used in air assistance mode, the snow rake lifts snow from the roof prior to clearing the snow with the blade. When used in steam assistance mode, the snow rake melts ice dams on the roof. The system can further comprise a yoke and additional extension tubes, wherein the yoke acts as a fulcrum for the system to facilitate ease of use in air or steam assistance modes.

Description

FIELD OF THE DISCLOSURE

The disclosure generally relates to devices and methods to remove snow or ice from roofs. In particular, the disclosure relates to a snow rake used to clear snow or ice from roofs.

BACKGROUND

Ice dams can form on a roof of a house that has poor insulation. Heat travels through the roof and melts snow over the center of the house. The resulting water can then flow down the roof and eventually freeze near roof overhangs. The water freezes at these overhangs because overhangs are not typically exposed to heat in a poorly insulated house due to the lateral location of the overhangs relative to the house. This can cause an accumulation of ice near the roof overhang and gutter area. When snow accumulates near the center of the house and subsequently melts into water, the water may not be able to drain properly and can collect on the roof. This can ultimately lead to roof damage due to water leaks.

Snow rakes may be used to clear snow from roofs, typically by a person standing on the ground or on a ladder. The snow rake may consist of a rake head coupled to a pole and may be made of aluminum. While holding onto the pole, the person can drag the rake head down the roof to remove the snow.

SUMMARY

In one or more embodiments, the snow rake system may include a rake head, a series of connected extension tubes that may be coupled to the rake head, an insulated heat resistant control handle that may be coupled to the series of connected extension tubes, a primary pressurized supply line that may be coupled to both the rake head and control handle, and a secondary pressurized supply line that may be coupled to the control handle and a fluid source. Both of the pressurized supply lines (primary and secondary) may carry either gas or liquid, such as air, water, or steam. In one or more embodiments, the supply line may carry air to remove snow from roofs or the supply line may carry steam to remove an ice dam from a roof. In one or more embodiments, the system may include the use of a yoke that may be coupled to the series of connected extension tubes and a second series of extension tubes. The yoke may act as a fulcrum for the system. This insulation (plastic, rubber, or otherwise) may be used to protect the operator from the heat of the metallic portions.

The operator may assemble the snow rake system before using it to remove snow from a roof. To assemble the snow rake system, the operator may obtain a plurality of extension tubes (depending on the height of the roof), may connect the plurality of extension tubes in series to achieve the desired length, may obtain a primary pressurized air supply line, may couple one end of the primary pressurized air supply line to the snow rake head, may couple the snow rake head to one end of the series of extension tubes, may couple the remaining end of the primary pressurized air supply line to a control handle, may couple the control handle to the remaining end of the series of extension tubes, may couple one end of a secondary pressurized air supply line to the control handle, and may couple the remaining end of the secondary pressurized air supply line to an air compressor.

The operator may use the snow rake system to clear snow from a roof. The operator may lift the snow rake head above the snow on the roof, may rest the rake head on the snow, may turn on the air compressor, may switch the on/off controller on the control handle to “on,” may wait for the air to loosen the snow, and may pull the snow rake head down the roof, towards the operator, to remove the snow from the roof. In one or more embodiments, a means for lifting the snow rake head above snow on the roof may include a yoke that can act as a fulcrum.

The operator may assemble the snow rake system before using it to remove an ice dam from a roof. To assemble the snow rake system, the operator may obtain a plurality of extension tubes (depending on the height of the roof), may couple the plurality of extension tubes in series to achieve the desired length, may obtain a primary pressurized steam supply line, may couple one end of the primary pressurized steam supply line to the snow rake head, may couple the snow rake head to one end of the series of extension tubes, may couple the remaining end of the primary pressurized steam supply line to a control handle, may couple the control handle to the remaining end of the series of extension tubes, may couple one end of a secondary pressurized steam supply line to the control handle, and may couple the remaining end of the secondary pressurized steam supply line to a steam generator.

The operator may use the snow rake system to clear an ice dam from a roof. The operator may position the snow rake head above the ice dam, may turn on the steam generator, may switch the on/off controller on the control handle to “on,” may wait for the steam to melt the ice, and may pull the snow rake head towards the edge of the roof, such as towards the operator. In one or more embodiments, a means for positioning the snow rake head above the ice dam may include a yoke that acts as a fulcrum.

BRIEF DESCRIPTION OF THE DRAWINGS

These as well as other objects and advantages of this air or steam snow rake will be more completely understood and appreciated by referring to the following more detailed description of embodiments in conjunction with the accompanying drawings of which:

FIG. 1 is a perspective view of an embodiment of the air or steam snow rake system in use on a house;

FIG. 2 is a perspective front view of an embodiment of the air or steam snow rake head;

FIG. 3 is a perspective side view of an embodiment of the air or steam snow rake head;

FIG. 4 is a perspective side view of an embodiment of the control handle; and

FIG. 5 is a perspective front view of an embodiment of the yoke.

Although the subject matter is amenable to various modifications and alternative forms, specifics thereof have been shown by way of example in the drawings and will be described in detail. It should be understood, however, that the intention is not to limit the disclosure to the particular embodiments described. On the contrary, the invention is to cover all modifications, equivalents, and alternatives.

DETAILED DESCRIPTION

Advantages and embodiments of the disclosed subject matter are illustrated by the following examples, but the particular materials and amounts recited in these examples, as well as other conditions and details, should not be construed to limit this disclosure unduly. For example, with regard to materials, when the composition of a component is described as “metallic material,” the metallic material can include aluminum, steel, copper, stainless steel, etc.

FIG. 1 is a perspective view of an embodiment of the air or steam snow rake system 100 in use on the roof of a house. The air or steam snow rake head 102 may be coupled to a plurality of in-series coupled extension tubes 104 that couple to a control handle 106. A primary operator may grip the extension tubes 104 near the control handle 106 while operating the system. The control handle 106 may be coupled to a secondary pressurized air or steam supply line 108 that may couple to an air compressor or steam generator 110. In one or more embodiments, a yoke 112 may be used to act as a fulcrum for the system. The yoke 112 may attach to a second series of extension tubes 114, and a second operator may grip the extension tubes 114 while operating the fulcrum part of the system. The yoke 112 may attach by using a locking mechanism, such as fitted tubes, a screw and thread, or a spring-ball and hole. The extension tubes 114 can be substantially similar to the extension tubes 104.

To use the snow rake system to clear snow from a roof, the snow rake may first be assembled. An operator may assess the approximate height of the roof when assembling the appropriate number of extension tubes 104. The extension tubes 104 may be of the same or various lengths. An operator may approximate the length of the primary pressurized air supply line that is to run the length of the series of extension tubes and may obtain the appropriate length of primary pressurized supply line. The primary pressurized supply line is the line that runs from the control handle to the blade. The primary pressurized supply line can be a smaller diameter than a secondary pressurized supply line. The primary pressurized supply line can include the extension tubes 114 or consist of the extension tubes 114 and be extendable, such as shown in FIG. 1. The primary pressurized supply line can be integral with the extension tubes 114 or the primary pressurized supply line can be a separate member. The secondary pressurized supply line 108 can run from an air compressor or gas generator 110 to the control handle. An operator may couple the primary pressurized air supply line to the snow rake head 102 and may mount the snow rake head 102 to the extension tubes 104. An operator may then couple the primary pressurized air supply line to the control handle 106 and may mount the control handle 106 to the extension tubes 104. The control handle 106 can be a heat resistant control handle 106. An operator may couple the secondary pressurized air supply line 108 to the control handle 106 and air compressor or steam generator 110.

After the snow rake is assembled, the primary operator may use the snow rake system 100 to remove snow from a roof. The primary operator may lift the snow rake head 102 above the snow on a roof, may then rest the snow rake head 102 on the top of the snow, may then turn on the air compressor, may then switch the on/off controller on the control handle 106 to “on,” may then wait for the air to loosen much of the snow, and may pull the snow rake head 102 down the roof, towards the operator, to remove the snow. This process may be repeated.

In one or more embodiments, the primary operator may use a second operator, a yoke 112, and a second series of extension tubes 114 to lift the snow rake head 102 above the snow. In the assembly instructions herein, before coupling the primary pressurized air supply line to the snow rake head 102 and mounting the snow rake head 102 to the extension tubes 104, the extension tubes 104 may be inserted into the yoke 112. The yoke 112 may then be coupled to the second series of extension tubes 114.

As the primary operator operates the snow rake, the second operator may grip the second series of extension tubes 114 and may lift the extension tubes 104 and snow rake head 102 vertically while walking the yoke 112 toward the control handle 106. The second operator and the primary operator may steer the snow rake head 102 to the location where the snow is to be removed and may lift the snow rake head 102 above the snow.

To use the snow rake system 100 to remove an ice dam from a roof, the snow rake may first be assembled. An operator may assess the approximate height of the roof and may assemble an appropriate number of extension tubes 104. The extension tubes 104 may be of the same length or various lengths. An operator may approximate the length of the primary pressurized steam supply line that runs the length of the series of extension tubes and may obtain the appropriate length of primary pressurized supply line. An operator may couple the primary pressurized steam supply line to the snow rake head 102 and may mount the snow rake head 102 to the extension tubes 104. An operator may couple the primary pressurized steam supply line to the control handle 106 and may mount the control handle 106 to the extension tubes 104. An operator may couple the secondary pressurized steam supply line 108 to the control handle 106 and steam generator 110.

To remove an ice dam, an operator may position the snow rake head 102 above the ice dam, turn on the steam generator, switch the on/off controller on the control handle 106 to “on,” wait for the steam to melt the ice, or may pull the snow rake head 102 towards the edge of the roof, such as towards the operator (not necessarily in that order). These techniques may be repeated.

In one or more embodiments, the primary operator may use a second operator, a yoke 112, and a second series of extension tubes 114 to position the snow rake head 102, such as above the ice dam. In the assembly instructions herein, before coupling the primary pressurized steam supply line to the snow rake head 102 and mounting the snow rake head 102 to the extension tubes 104, the extension tubes 104 may be inserted into the yoke 112. The yoke 112 may then be coupled to the second series of extension tubes 114.

As the primary operator operates the snow rake to remove an ice dam, the second operator may grip the second series of extension tubes 114 and may lift the extension tubes 104 and snow rake head 102 vertically while walking the yoke 112 toward the control handle 106. The second operator or the primary operator may steer the snow rake head 102 to the location at or near where the ice dam is to be removed and may position the snow rake head 102 above the ice dam.

FIG. 2 is a perspective front view of an example embodiment of the air or steam snow rake head 102. The platform 202 may form the base of the rake head and may be fabricated from metallic material. The right wing 204 may extend from the platform 202. The right wing 204 may impede snow from tumbling out laterally during operation of the snow rake. The right wing 204 may be fabricated from metallic material. The left wing 206 may extend from the platform 202. The left wing 206 may impede snow from tumbling out laterally during operation of the snow rake. The left wing 206 may be fabricated from metallic material. A blade 208 may extend from the platform 202. The blade 208 may guide the snow rake head 102 into the snow and may act as a drag scoop for the platform. The blade and air can burble or billow the snow as the snow rake is dragged down the roof. The blade 208 may be fabricated from metallic material. The blade 208 may include a leading edge 220 that may have a square tip. The blade 208 may include a leading edge 220 that may include other configurations, for example angled, v-tipped, etc. The leading edge 220 may help the blade 208 cut into the snow. In one or more embodiments, the snow rake may include a skid plate 218. The skid plate 218 may help to reduce contact between the blade 208 and the roof. The skid plate 218 may include metallic material.

The left flat angle long brace 210 may support the platform 202 to a rake head tubular connecting column 224 (FIG. 3 provides additional detail related to the rake head tubular connecting column 224). The flat angle short brace 212 may support the platform 202 to the rake head tubular connecting column 224. The right flat angle long brace 214 may further support the platform 202 to the rake head tubular connecting column 224. The left flat angle long brace 210, flat angle short brace 212, or right flat angle long brace 214 may include metallic material.

The air or steam pressure transport feed line 216 may carry air to allow the snow rake to be used to clear snow, or may carry steam to allow the snow rake to be used to clear ice dams from a roof. A purpose of the air is to at least partially lift the snow when raking. A purpose of the steam is to at least partially melt the ice dams. The air or steam snow rake head 102 can have several air or steam pressure transport feed lines 216. In one or more embodiments of the air or steam pressure transport feed line 216, the outer diameter may be about ⅜ inches (9.525 mm) and inner diameter may be a ¼ of an inch (6.35 mm). The air or steam pressure transport feed line 216 may include metallic material. The air or steam pressure transport feed line 216 may be subject to less pressure than the pressurized air or steam supply line 108 (FIG. 3 further describes the pressurized air or steam supply line 340).

A nozzle 222 may be connected to each air or steam pressure transport feed line 216. In one or more embodiments, nozzle 222 may have an opening that can be of various sizes or diameters, such as a jet opening, of an appropriate size to create backpressure in the air or steam pressure transport feed line 216. The size of the opening may be adjusted. In one or more embodiments that utilize pressurized air, the paths of the jets may cross about 4 to 6 inches (10.16 to 15.24 cm) from the leading edge 220. In one or more embodiments that utilize steam, nozzle 222 may extend substantially down to the leading edge 220.

FIG. 3 is a perspective side view of an example embodiment of the air or steam snow rake head 102. The platform 202 may form the base of the rake head and may include metallic material. The right wing 204 may extend from the platform 202. The right wing 204 may impede snow from tumbling out laterally during operation of the snow rake. The right wing 204 may include metallic material. The blade 208 may extend from the platform 202. The blade 208 may guide the snow rake head 102 into the snow and may act as a drag scoop for the platform. The blade 208 may include metallic material. The blade 208 may have a leading edge 220 that may have a square tip. Alternatively, the blade 208 may have a leading edge 220 that has other shapes, such as a curved or angled shape or a v-tipped shape, etc. The leading edge 220 may help the blade 208 cut into the snow.

The flat angle short brace 212 may support the platform 202 to the rake head tubular connecting column 224. The flat angle short brace 212 may include metallic material. At an end portion of the rake head tubular connecting column 224 the tube may be tapered into the extension handle receiver 318. This may allow the extension handle receiver 318 to be coupled to a tubular connecting column. The rake head tubular connecting column 224 may protect the air or steam pressure transport feed line 216, manifold 320, extension nipple 322, flexible connector union 324, lower connector clamp 326, upper connector clamp 328, and/or union 330. The rake head tubular connecting column 224 and extension handle receiver 318 may include metallic material. The air or steam pressure transport feed line 216 may carry air if the snow rake is being used to clear snow from a roof or may carry steam if the snow rake is being used to clear an ice dam from a roof.

The manifold 320 may split the air or steam into multiple streams so that each air or steam pressure transport feed line 216 may be serviced. One end of the manifold 320, which is distal to the operator, may be welded or adhered to the air or steam pressure transport feed line 216, such as by using an epoxy or other such structural adhesive. The other end of the manifold 320, which is proximal to the operator, may have a female thread to couple to the male portion of an extension nipple 322. In some embodiments, this coupling may be secured with a thread-locking fluid. The manifold 320 may include metallic material.

The end of the extension nipple 322 proximal to the operator and opposite to that connected to the manifold 320, may be coupled with the flexible connector union 324. In one or more embodiments, this connection may be tightened by using the lower connector clamp 326. The extension nipple 322 may be fabricated from metallic material. The lower connector clamp 326 may be fabricated from chrome plated steel, stainless steel, etc.

The end of the flexible connector union 324 that is proximal to the operator may be connected to the union 330. The male portion of the union 330 may be coupled with the flexible connector union 324. In one or more embodiments, this connection may be tightened, such as by using the upper connector clamp 328. The upper connector clamp 328 may include chrome plated steel or stainless steel, among other metallic materials. The flexible connector union 324 may be used to eliminate shock on the manifold 320 to air or steam pressure transport feed line 216 weld or epoxy connection; the flexible connector union 324 may absorb vibrational energy. The flexible connector union 324 may be fabricated from a high-pressure hose that may be steam rated to allow it to carry both steam and air.

An end portion of the union 330 proximal to the operator may be coupled to a rake head quick release connector 332. One end portion of the quick release connector 332 may have a female thread, which may couple to the standard threaded male portion of the union 330. The union 330 may include metallic material. A rake head collar cup 338 may have a hole through its center, and may be used as a washer between the union 330 and rake head quick release connector 332. The rake head collar cup 338 may be inserted into the extension handle receiver 318 and the male threads of the union 330 may be inserted into the hole in the rake head collar cup 338. The rake head quick release connector 332 may be threaded onto the threaded male portion of the union 330. In one or more embodiments, rake head collar cup 338 may provide support for the air or steam pressure transport feed line 216, manifold 320, extension nipple 322, flexible connector union 324, lower connector clamp 326, upper connector clamp 328 and union 330. The rake head collar cup 338 may include metallic material.

The distal end of the rake head quick release connector 332 may be coupled to the union 330, and the proximal end of the rake head quick release connector 332 may be coupled to the male portion of a rake head air supply connector 334. The sleeve portion of the rake head quick release connector 332 may be pulled back, the male portion, such as a barbed or knobbed male portion, of the rake head air supply connector 334 may be inserted into the rake head quick release connector 332, and the sleeve portion may be released to make the connection. The rake head quick release connector 332 may couple the pressurized air or steam supply line 340 to the flexible connector union 324. The rake head quick release connector 332 may include metallic material.

The end of the rake head air supply connector 334 proximal to the operator may be connected to the pressurized air or steam supply line 340. The barbed male portion, such as a barbed or knobbed male portion, of the rake head air supply connector 334 may be coupled to the pressurized air or steam supply line 340. In one or more embodiments, this coupling may be tightened by using the distal upper connector clamp 336. The distal upper connector clamp 336 may include chrome plated steel or stainless steel, among other materials. The rake head air supply connector 334 may include metallic material.

FIG. 4 is a perspective side view of an example embodiment of the air supply connector 402, control handle 106, and extension tube 104. The control handle 420 may be fabricated from material that provides insulating characteristics and has integrity to form a handle. The control handle 420 can be heat resistant. The extension tube 104 proximal to the operator, such as an extension tube 104 most proximal to the operator, may include a tapered proximal end, a male, or tail end, thus forming a tail end extension tube 418. The proximal male end of the extension tube 418 proximal to the operator, such as a proximal male end of the extension tube 418 most proximal to the operator, may be coupled to the distal female end of the control handle 420. The control handle 420 may protect the standard ball cock valve 408 and may facilitate coupling to the tail end extension tube 418 and pressurized air or steam supply line 340 (shown in FIG. 3). The extension tube 418 distal to the operator may mechanically couple to other extension tubes, which can ultimately couple to the rake head extension handle receiver 318 in FIG. 3. The tail end extension tube 418, as well as other extension tubes, may include metallic material.

The control handle air supply connector 402 may mechanically couple the control handle 420 to a pressurized air or steam supply line. In one or more embodiments, an attachment mechanism 422, such as an attachment nut, quick release, spring-ball, or other attachment mechanism, may be included at the distal end of the control handle air supply connector 402. In such embodiments, the proximal threaded end of the lower extension nipple 404 may be inserted into the attachment mechanism 422 and the attachment mechanism may be tightened to make the coupling. The proximal end of the control handle air supply connector 402 may be attached to a quick disconnect that may be coupled to the pressurized air or steam supply line. The control handle air supply connector 402 may be fabricated from metallic material. The control handle collar cup 406 may include a hole through its center, and may be used as a washer between the lower extension nipple 404 and control handle air supply connector 402. The control handle collar cup 406 may also be used to stabilize the control handle air supply connector 402. The control handle collar cup 406 may be inserted into the control handle 420, and the outer most circumference of the control handle collar cup 406 may allow for a friction fit with the internal surface of the control handle 420. The male threads of the lower extension nipple 404 may be inserted into the hole in the control handle collar cup 406, and the attachment nut on the control handle air supply connector 402 may be threaded onto the threaded male portion of the lower extension nipple 404. The control handle collar cup 406 may include plastic or other such structural material.

An end portion of the lower extension nipple 404 distal to the operator may be coupled to the standard ball cock valve 408 by threading it into the female end of the standard ball cock valve 408. In one or more embodiments, this joint may be soldered. An end of the lower extension nipple 404 may be male threaded. The lower extension nipple 404 may be used to position the control handle air supply connector 402 beyond the control handle 420. The lower extension nipple 404 may include metallic material.

The end of the standard ball cock valve 408 distal to the operator may be coupled to the upper extension nipple 414 by inserting one of the threaded ends of the upper extension nipple 414 into the female end of the standard ball cock valve 408. In one or more embodiments, this joint may be soldered. Both end portions of the standard ball cock valve 408 may be female threaded. The standard ball cock valve 408 may be fabricated from brass, among other materials. One purpose of the standard ball cock valve 408 is to allow fully open, partial restriction, and/or full restriction modes for the air or steam. Switching between modes may be accomplished via the on/off controller 412. The on/off controller 412 may be coupled to the standard ball cock valve 408 with a fastener, such as a screw, and the on/off controller 412 may include steel and include a nonmetallic covering. The covering may be made of plastic or any other thermally insulating material that can prevent user burn, such as when the snow rake system is operating in steam mode. An internal valve clip 410 may slide over each end of the standard ball cock valve 408, and the outer most circumferences of the clips may allow for a friction fit with the internal surface of the control handle 420. Each internal valve clip 410 may include a hole through its center. The internal valve clips 410 may keep the standard ball cock valve 408 centered and in place, and may include rubber or plastic.

An end portion of the upper extension nipple 414 distal to the operator may be coupled to the control handle quick release connector 416 by threading it into the female end of the control handle quick release connector 416. Both ends of the upper extension nipple 414 may be male threaded. The upper extension nipple 414 may be used to position the control handle quick release connector 416 beyond the control handle 420 and into the tail end extension tube 418. The upper extension nipple 414 may include metallic material.

The end of the control handle quick release connector 416 distal to the operator may be coupled to a male air supply connector, which may be coupled to the pressurized air or steam supply line. This connection may be substantially similar to the connection shown in FIG. 3. The sleeve portion of the quick release connector 416 may be pulled back, the male portion of a male air supply connector may be inserted into the quick release connector 416, and the sleeve portion may be released to complete the coupling. The control handle quick release connector 416 may mechanically couple the upper extension nipple 414 to the pressurized air or steam supply line in the tail end extension tube 418. The control handle quick release connector 416 may include metallic material.

FIG. 5 is a perspective front view of an embodiment of the yoke 112. The yoke base 502 may be inserted into the female end of the support tubular connecting column 528. A setscrew 526 may be inserted through the wall of the support tubular connecting column 528 and into the wall of the yoke base 502. The setscrew 526 may keep the yoke base 502 stable with the female end of the support tubular connecting column 528. The setscrew 526 may include metallic material. The support tubular connecting column 528 may support the yoke mast 506 and may offset the weight of the snow rake system, such as by acting as a fulcrum (e.g., see FIG. 1). The support tubular connecting column 528 may include metallic material. The yoke extension handle receiver 530 may facilitate coupling to the female end of additional extension tubes 114, which may be gripped by a second operator (e.g., see FIG. 1).

The yoke base 502 may hold the yoke base shaft 518. The yoke base 502 may include metallic material. The yoke stop 504 may be part of the yoke base 502 and may include metallic material as well. The yoke stop 504 may surround, stabilize, or retain a yoke wishbone 508. The yoke base shaft 518 may be inserted into the yoke base 502, and the yoke shaft collar stop 516 may be coupled with the yoke stop 504. Upon insertion of the yoke base shaft 518 into the yoke base 502, the yoke base shaft 518 may hold the yoke wishbone 508, and may allow for 360° rotation of the yoke wishbone 508, such as by creating a loose fit between the yoke base shaft 518 and the yoke base 502. The yoke mast 506 may couple the yoke wishbone 508 to the yoke base shaft 518. The yoke base shaft 518 may include metallic material. The yoke shaft collar stop 516 may be part of the yoke base shaft 518, and may include metallic material.

A washer 520 may fit over the yoke base shaft 518 and may mechanically couple with the yoke base 502. In one or more embodiments, the washer 520 may include plastic. A snap ring 522 may then be coupled with the plastic washer 520. In one or more embodiments, the snap ring 522 may be a 270° semi-circle that may snap into the snap ring rill 524. The snap ring rill 524 may be a portion of material removed by a lathing technique from the yoke base shaft 518, for example. The snap ring rill 524 may facilitate attachment of the snap ring 522. The snap ring 522 may keep the yoke base shaft 518 tight in its socket. The snap ring 522 may include metallic material. The washer 520 may provide a buffer between the metallic material yoke base 502 and metallic material snap ring 522.

The yoke wishbone 508 may attach to the yoke swivel 510 and may allow for 360° rotation of the yoke swivel 510. The yoke wishbone 508 may include metallic material. The yoke swivel 510 may retain the extension tube 514 and may include two swivel attachment posts 512. The swivel attachment posts 512 may be inserted into the yoke wishbone 508 via a loose fitting, such as to allow for 360° rotation of the yoke swivel 510. In one or more embodiments, these junctions may be greased. The yoke swivel 510 and the two swivel attachment posts 512 may be fabricated from metallic material. The extension tube 514 may be used to extend the rake head (e.g., see FIG. 1) and may house the pressurized air or steam supply line.

The air or steam snow rake system 100 can allow an operator to stay on the ground while removing snow or ice. Such a system can be more efficient, safe, cheaper per operation, or cheaper for those purchasing the air or steam snow rake system 100. Also, when a snow drift is being removed there can be a lot of repetitive arm motion that can be above the operators heart. For some, this can be life threatening due to the fact that this can cause a heart attack. By using the air or steam snow rake system 100 it can be faster or less physically demanding. Further, the air or steam snow rake system 100 may cause less damage to a roof surface, due to reduced scraping on the roof.

Various embodiments of systems, devices, and methods have been described herein. These embodiments are given only by way of example and are not intended to limit the scope of the disclosure. It should be appreciated, moreover, that the various features of the embodiments that have been described may be combined in various ways to produce numerous additional embodiments. Moreover, while various materials, dimensions, shapes, feature locations, etc. have been described for use with disclosed embodiments, others besides those disclosed may be utilized without exceeding the scope of this disclosure.

Persons of ordinary skill in the relevant arts will recognize that the subject matter may comprise fewer features than illustrated in any individual embodiment described above. The embodiments described herein are not meant to be an exhaustive presentation of the ways in which the various features of the subject matter may be combined. Accordingly, the embodiments are not mutually exclusive combinations of features; rather, the subject matter may comprise a combination of different individual features selected from different individual embodiments, as understood by persons of ordinary skill in the art, and are within the scope of the following claims.

Claims

1. A snow rake system, comprising:

a rake head,

a plurality of serially-coupled extension tubes, wherein the rake head is coupled to a first end of the extension tubes;

a control handle, coupled to a second end of the extension tubes;

a primary pressurized supply line configured to transport fluid, a first end of the primary pressurized supply line coupled to the rake head and a second end of the primary pressurized supply line coupled to the control handle; and

a secondary pressurized supply line configured to transport a fluid, a first end of the secondary pressurized supply line coupled to the control handle and a second end of the secondary pressurized supply line coupled to a fluid source.

2. The snow rake system of claim 1, further comprising:

a yoke, wherein the yoke is coupled to the extension tubes; and

a second series of extension tubes, wherein the yoke is coupled to the second series of extension tubes.

3. The snow rake system of claim 1, wherein the rake head comprises:

a platform;

a blade coupled to the platform;

a tubular connecting column coupled to the platform;

at least one pressurized transport feed line coupled to the platform; and

at least one nozzle coupled to the pressurized transport feed line.

4. The snow rake system of claim 3, further comprising:

a left wing coupled to the platform;

a right wing coupled to the platform; and

at least one skid plate coupled to the blade.

5. The snow rake system of claim 3, further comprising a manifold coupled to the pressurized transport feed line.

6. The snow rake system of claim 5, further comprising:

an extension nipple coupled to the manifold;

a flexible connector union coupled to the extension nipple;

a union coupled to the flexible connector union;

a quick release connector coupled to the union; and

a collar cup, wherein the collar cup mates with the union, the collar cup mates with the quick release connector, and the collar cup mates with the tubular connecting column.

7. The snow rake system of claim 1, wherein the control handle comprises:

a control handle;

a supply connector;

a lower extension nipple coupled to the supply connector;

a ball cock valve coupled to the lower extension nipple;

an on/off controller coupled to both the ball cock valve and the control handle;

an upper extension nipple coupled to the ball cock valve; and

a quick release connector coupled to the upper extension nipple.

8. The snow rake system of claim 7, further comprising:

two internal valve clips, connected to the ball cock valve and mated with the control handle.

9. The snow rake system of claim 7, further comprising:

a collar cup mated with the lower extension nipple and the control handle.

10. The snow rake system of claim 2, wherein the yoke comprises:

a wishbone;

a swivel coupled to the wishbone;

a mast coupled to the wishbone;

a base shaft coupled to the mast; and

a base coupled to the base shaft.

11. The snow rake system of claim 10, further comprising a washer coupled to the base shaft and mated with the base.

12. The snow rake system of claim 10, further comprising a snap ring, wherein the snap ring is coupled to the base shaft and is mated with the washer, and wherein the base shaft has a rill to facilitate attachment of the snap ring.

13. The snow rake system of claim 10, further comprising a set screw coupled to the base, wherein the set screw connects to a support tubular connecting column.

14. The snow rake system of claim 1, wherein the fluid is air or steam.

15. A method for removing snow from a roof, comprising:

lifting a snow rake head above snow on a roof;

resting a rake head of the snow rake on the snow;

turning on an air compressor coupled to the snow rake;

switching an on/off controller to on, wherein the on/off controller is located on a control handle of the snow rake;

allowing air from the air compressor to loosen the snow; and

pulling the snow rake head down the roof to remove the snow from the roof.

16. The method of claim 15, comprising lifting the snow rake head above snow on the roof using a yoke.

17. The method of claim 15, wherein the method comprises:

obtaining a series of extension tubes, wherein the number of extension tubes is obtained as a function of a height of the roof;

connecting the series of extension tubes, wherein the length of the series of extension tubes depends on the height of the roof;

obtaining a primary pressurized air supply line;

connecting the one end of the primary pressurized air supply line to the snow rake head;

mounting the snow rake head to one end of the series of extension tubes;

connecting the remaining end of the primary pressurized air supply line to the control handle;

mounting the control handle to the remaining end of the series of extension tubes;

connecting one end of a secondary pressurized air supply line to the control handle; and

connecting the remaining end of the secondary pressurized air supply line to the air compressor.

18. A method for removing an ice dam off a roof, comprising:

positioning a snow rake head above an ice dam;

turning on a steam generator coupled to the snow rake head;

switching an on/off controller to on, wherein the on/off controller is located on a control handle of the snow rake head;

allowing the steam to melt the ice; and,

pulling the snow rake head towards the edge of a roof of a house.

19. The method of claim 18, comprising:

obtaining a series of extension tubes;

connecting the series of extension tubes, wherein the length of the series of extension tubes is a function of a height of a roof;

obtaining a primary pressurized steam supply line;

connecting the one end of the primary pressurized steam supply line to the snow rake head;

mounting the snow rake head to one end of the series of extension tubes;

connecting the remaining end of the primary pressurized steam supply line to the control handle;

mounting the control handle to the remaining end of the series of extension tubes;

connecting one end of a secondary pressurized steam supply line to the control handle;

connecting the remaining end of the secondary pressurized steam supply line to the steam generator;

20. A method as in claim 18, comprising positioning the snow rake head above the ice dam using a yoke.