The invention relates to a cutting tool for cutting openings for register vents in flooring or walls when installing a HAVC system and the like wherein the cutting tool automatically follows a track corresponding to the pattern for the vent opening.
In the installation of heating and air-conditioning systems (HAVC) numerous vent openings must be formed in floors, walls, or ceilings to connect the ductwork to the room. During new home construction, 20 or more vent openings may be needed, and other constructions require even more openings. Previously, the vent openings have been cut manually by using a power sabre saw or sawsall, and much physical labor is exerted on hands or knees. In order to cut the vent opening in the correct space in the floor, one must crawl under the house, locate a space for the vent opening between two floor joists, and drill a pilot hole in the floor while underneath the house to indicate the location. Using the pilot hole, a drawing of the vent opening is marked on the interior floor and the vent opening is manually cut out.
Prior attempts to provide tools and methods for cutting out vent openings for HAVC systems and the like using various floor guides have been made. For example U.S. Pat. No. 7,086,171 B2 discloses a template for cutting out vents of an HVAC system. U.S. Published Application no. 2002/0134213 discloses a cutter guide for guiding the movement of a cutting tool manually. These devices only disclose a guide with which a separate manual cutting tool is used. U.S. Pat. Nos. 4,620,407 and 4,359,302 disclose guides for cutting patterns out of sheet rock and the like. Thus, it can be seen that a power cutting tool is needed in the HAVC industry for cutting vent openings automatically in prescribed pattern.
The above objectives are accomplished according to the present invention by providing a power cutting tool for automatically cutting out a vent opening in a substrate such as a floor and the like in a prescribed pattern. The power cutting tool includes a base assembly adapted for support on a surface of a substrate while the vent opening is cut out. A track assembly is carried by the base assembly for automatically guiding the movement of the cutting tool in the pattern. A power cutting tool assembly is carried on the track assembly having a cutting blade which penetrates the substrate during operation to cut out the pattern. A drive assembly engages the track assembly for automatically moving the cutting tool assembly along the track assembly while simultaneously operating the cutting blade to cut out the vent opening. The cutting blade may include a rotating cutting blade or a reciprocating cutting blade. The drive assembly includes a first drive for operating the cutting tool and a second drive for moving the cutting tool assembly along the track assembly so that the cutting blade cuts out the pattern. In the case of the rotating cutting blade, the first drive includes a drive motor having a rotating driveshaft operatively connected to the cutting blade, and the second drive includes a tractor drive driven by the driveshaft having at least one tractor drive gear which engages the track assembly. Preferably, the tractor drive includes a first tractor drive gear and a second tractor by drive gear, and the track assembly includes a track having an exterior rack gear and an interior rack gear wherein the first tractor drive gear engages the interior rack gear and the second tractor drive gear engaging the exterior rack gear. A reduction gear arrangement is connected between the driveshaft and the tractor drive gears and includes a main output gear carried by the driveshaft. In a preferred form, the reduction gear arrangement includes a planetary gear drive having a first plurality of intermediary gears driven by the main output gear for driving the first tractor drive gear, and a second plurality of intermediary gears driven by the main output gear for driving the second tractor drive gear. The first plurality of intermediary gears may include a first planetary gear engaging a first ring gear for driving the first tractor drive gear, and the second plurality of intermediary gears may include a second planetary gear engaging a second ring gear for driving the second tractor drive gear wherein the first and second tractor drive gears mesh with the exterior and interior rack gears of the track, respectively, and rotate generally at the same speed in opposite directions. Advantageously, the power cutting tool includes a carriage frame that may be two pieces or one piece with the base assembly. The track assembly is carried by the carriage frame. In the case of a two-piece construction, the carriage frame is movable up-and-down. When the carriage frame is movable, the cutting blade cuts out the vent pattern when the carriage frame is in a down position over a pilot hole. For this purpose, a bias mechanism is connected between the base assembly and the carriage frame. The carriage frame may be moved downward to overcome the bias mechanism and reach the down operational position wherein the cutting blade can begin operating.
The invention will be more readily understood from a reading of the following specification and by reference to the accompanying drawings forming a part thereof, wherein an example of the invention is shown and wherein:
Referring now to the drawings, the invention will be described in more detail.
According to the present invention, a vent register cutting tool, designated generally as A, includes a base assembly B, a track assembly C, and a cutting tool assembly D. Base assembly B provides a carriage by which a cutting tool assembly D is carried on track assembly C.
As can best be seen in
Track assembly C includes a continuous track 20 carried by base B and carriage frame 12. There are typically two standard register vent sizes, 4″×8″ and 4″×10″. Track 20 provides a pattern for the 4″×8″ vent opening. Track 20 provides a pattern for cutting out a 4″×10″ opening by shifting the base 2 inches to the left or right and so that one continues cutting until another 2 inches is removed. Alternately two tracks may be replaceably used on carriage 12. Track 20 includes a rack gear 24 formed around the outside of the track and a second rack gear 26 formed around the inside of the track. Tractor drive gears 28 and 30 engage the outside and inside rack gears 24 and 26, respectively, to move the tool cutting assembly around the pattern of the track, as will be explained in more detail below.
Cutting tool assembly D travels on track 20 to cut out vent opening 16. The assembly includes a housing 32 for a drive motor 34 and a reduction gear drive, designated generally as E, driven by the motor. The cutting tool 16 requires a high speed, while the cutting tool assembly requires a relatively low speed. As can best be seen in
For this purpose, planetary gear drive 44 may include a rotary driveshaft 40 driven by motor 34. A sun or input gear 42 is affixed to rotary shaft 40 to drive the planetary gear drive. Gear 42 engages planetary gears 46. Only one planetary gear 46 is needed for kinematic purposes, however, using redundant gears permits load sharing and the transmission of high power by using smaller gears. Planetary gears 46 engage both input drive gear 42 and a first ring gear 48 integral with drive gear 50. Gear 50 is a first output of the planetary gear drive. Planetary gears 46 and 52 rotate as a unit and are the planet gears of the system. Shafts 54 pass through a planet gear carrier arm 56, and are connected to opposing planetary gears 46 and 52. Gears 52 engage a second ring gear 60 which is integral with tractor drive gear 30 which is a second output of the planetary drive. Second ring gear 60 is integral with tractor drive gear 30. Tractor drive gear 30 engages inside gear rack 26 of track 20 as part of the tractor drive moving the power cutting tool around the track. Gear 50, through intermediate gears 62, 64, drives tractor drive gear 28 which engages the outside rack gear 24 of track 20. Synthetic guide rollers 70 are sandwiched under opposing flanges 25 of the “T” shaped track for stability and wear. As can best be seen in
The different gears described above may be selected in a conventional manner having been taught the aspects of the invention. For example, gear 42 may have 30 teeth. The ratio of gear 42 to gear 48 is 2094. The difference between the speeds of gears 28 and 30 is constant for a router operating at the speeds of 20,000 RPM; this difference will be about 9.5 RPM. Gears 28 and 30 turn in opposite directions therefore on a straight section of the track each will turn at about 4.75 RPM. The actual linear speed of the cutting tool assembly can be governed by selecting the size and teeth of the gears in a conventional manner. For example, gear 42 may have 30 teeth, gear 46 may have 39, gear 53 may have 38 teeth, ring gear 48 (internal gear) may have 108 teeth, ring gear 60 (internal gear) may have 105 teeth, gears 50 and 64 may be any suitable gears with the same number of teeth, gears 28 and 30 may be any suitable gears with the same number of teeth, and gear 62 may be selected to suit the remaining gear selection.
As can best be seen in
Referring now to
While the preferred embodiment of the invention has been described using specific terms, such description is for illustrative purposed only, and it is to be understood that changes and variations may be made without departing from the spirit or scope of the following claims.
Number | Name | Date | Kind |
---|---|---|---|
2679269 | Waszak | May 1954 | A |
2735455 | Forsberg | Feb 1956 | A |
3908510 | Koskolos et al. | Sep 1975 | A |
4306479 | Eberhardt | Dec 1981 | A |
4359302 | Payne | Nov 1982 | A |
4620407 | Schmid | Nov 1986 | A |
4947910 | Reneau | Aug 1990 | A |
5148730 | McCaw | Sep 1992 | A |
5647420 | Michell | Jul 1997 | A |
6694635 | Sidebottom | Feb 2004 | B1 |
6926477 | Allemann | Aug 2005 | B2 |
6966122 | Smith | Nov 2005 | B2 |
7086171 | Lawson | Aug 2006 | B2 |
7367131 | Hordis | May 2008 | B1 |
7454844 | Ruby | Nov 2008 | B1 |
7958641 | Ende | Jun 2011 | B1 |
9140435 | Yaphe | Sep 2015 | B2 |
20020134213 | Causse et al. | Sep 2002 | A1 |
20050081954 | Wielechowski | Apr 2005 | A1 |
20140366386 | Brisson | Dec 2014 | A1 |
Number | Date | Country | |
---|---|---|---|
20140366386 A1 | Dec 2014 | US |
Number | Date | Country | |
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61834070 | Jun 2013 | US |