The present invention relates to power tools and, more particularly, to a leveling device that indicates when the power tool is in a horizontal or vertical plane.
In various types of power tools, especially drilling tools, it is desirable to know when the tool is in a horizontal or vertical plane. This is particularly useful when drilling holes for hanging doors or the like when it is desirable to have holes which are in plane with horizontal.
Bubble type of levels have been utilized in power tools. However, these types of leveling devices have various shortcomings. While the bubble level works satisfactorily for horizontal applications, it is still burdensome on the user to view the bubble in between the lines. Ordinarily, these bubble types of levels are not conducive for vertical drilling. Also, due to the vibration of the tool, frothing occurs inside the level, rendering the bubble level useless in many applications.
Another type of measuring device utilizes a simple pendulum with a rigid straight bar connecting the pivot point with a hanging weight together with a cross bar mounted at ninety (90°) degrees to a vertical bar. The cross bar can be disposed on either side of the pivot point when the pivot level is hung and the weight achieves equilibrium, the cross bar will be positioned in a horizontal plane. Accordingly, the ends may be aligned with two notches on a carrier board to align the board to the horizontal and thus measure the horizontal plane.
Both of these devices require the user to get an accurate view during drilling to maintain the plane of the power tool. Also, while these types of devices may be satisfactory for horizontal planes, they are not particularly useful when used in a vertical drilling arrangement.
Accordingly, it is an object of the present invention to provide a user with an easy to use leveling device. The device indicates to the user, usually by an illuminated light, that horizontal or vertical planes have been achieved. The present invention enables the user to readily establish visual contact to indicate that a desired plane has been achieved.
According to a first embodiment of the present invention, a mechanism for determining if a power tool is in a horizontal or vertical plane comprises a housing with a cavity in the housing. A rotating member is positioned within the housing. The rotating member moves in the cavity such that the rotating member seeks an equilibrium position which corresponds to a horizontal or vertical plane. Electrical contacts are coupled with the rotating member such that the electrical contacts only complete an electrical circuit when the rotating member is in the equilibrium position. An indicator is electrically coupled with the electrical contacts to indicate to the user when the mechanism is in an equilibrium position. A power source is electrically coupled with the electrical contacts and the indicator to energize the indicator when the circuit is complete. The rotating member may be fixed for rotation about a central axis in a cylindrical cavity in the housing. Here, the rotating member includes a biased electrical contact. The electrical contacts include a pair of annular members coupled with the housing. Each annular member includes electrical contact portions spaced ninety (90°) degrees from one another. Thus, as the rotating member reaches the equilibrium position, the rotating members biased electrical member contacts the annular ring electrical contact portions to complete the circuit and activating the indicator. Alternatively, the rotating member could be manufactured from an electrical conductive material. Here, the rotating member is cylindrical and has at least one projecting member. The electrical contacts include a biased member to electrically contact the at least one projecting member when the cylindrical rotating member is in the equilibrium position. An axle projects through the cylindrical rotating member to complete the circuit. Alternatively, the cavity may be defined by a pair of opposing conductive conical members acting as the electrical contacts. Here, the rotating member includes a pair of conductive balls. The opposing conductive cylindrical members are separated by a non-conductive membrane. The membrane includes apertures positioned at ninety (90°) degrees apart from one another about a circle. The balls contact one another through the apertures in the membrane when the balls are in the equilibrium position to complete the circuit and activate the indicator.
In accordance with a second embodiment of the present invention, a power tool comprises a housing with a motor within the housing. The motor is coupled with an output. An activation member is coupled with a power source which, in turn, is coupled with the motor. The activation member is activated which, in turn, energizes the motor to drive the output. A leveling mechanism is coupled with the housing. The leveling mechanism comprises a housing with a cavity in the housing. A rotating member is positioned within the housing. The rotating member moves in the cavity such that the rotating member seeks an equilibrium position which corresponds to a horizontal or vertical plane. Electrical contacts are coupled with the rotating member such that the electrical contacts only complete an electrical circuit when the rotating member is in the equilibrium position. An indicator is electrically coupled with the electrical contacts to indicate to the user when the mechanism is in an equilibrium position. A power source is electrically coupled with the electrical contacts and the indicator to energize the indicator when the circuit is complete. The rotating member may be fixed for rotation about a central axis in a cylindrical cavity in the housing. Here, the rotating member includes a biased electrical contact. The electrical contacts include a pair of annular members coupled with the housing. Each annular member includes electrical contact portions spaced ninety (90°) degrees from one another. Thus, as the rotating member reaches the equilibrium position, the rotating member's biased electrical member contacts the annular ring electrical contact portions to complete the circuit and activate the indicator. Alternatively, the rotating member could be manufactured from an electrical conductive material. Here, the rotating member is cylindrical and has at least one projecting member. The electrical contacts include a biased member to electrically contact the at least one projecting member when the cylindrical rotating member is in the equilibrium position. An axle projects through the cylindrical rotating member to complete the circuit. Alternatively, the cavity may be defined by a pair of opposing conductive conical members acting as the electrical contacts. Here, the rotating member includes a pair of conductive balls. The opposing conductive cylindrical members are separated by a non-conductive membrane. The membrane includes apertures positioned at ninety (90°) degrees apart from one another about a circle. The balls contact one another through the apertures in the membrane when the balls are in the equilibrium position to complete the circuit and activate the indicator.
Additional objects and advantages of the present invention will become apparent from the detailed description of the preferred embodiment, and the appended claims and accompanying drawings, or may be learned by practice of the invention.
Turning to the figures,
Looking at housing half 14 in
Turning to
Electrical contact rings 66 and 68 are held at the sides of the cavity 52 by non-conductive shells 70 and 72 which enclose the cavity of the housing 50. The conductive rings 66 and 68 are coated with a non-conductive material such that portions 74 of the ring are exposed for conductive purposes. The portions 74 are spaced at ninety (90°) degree intervals about the ring. Also, the rings 66 and 68 are coupled with wires 32 and 34 to complete the electrical circuit.
In use, the rotating pendulum member 54 is capable of rotating about the axle 56 in a three hundred sixty (360°) degree circle in the housing cavity 52. As the drill is manipulated, the pendulum reaches an equilibrium position. When the drill is in a horizontal or vertical plane, the conductive balls 60 and 62 in the rotated pendulum member 54 contact a conductive portion 74 on rings 66 and 68. As this occurs, the LEDs 38 and 40 are illuminated. This indicates to the user that the drill is in a horizontal or vertical plane. Thus, the user may then utilize the drill with the knowledge that it is in a horizontal or vertical plane.
Turning to
The housing 50′ includes a cylindrical cavity 52′ for housing a rotating pendulum 54′. The pendulum 54′ rotates on an axle 56′. The axle projects through a non-conductive shell 72′.
The pendulum 54′ is a cylindrical body with a weighted portion 80 and external projecting members 82. The rotating pendulum member 54′ is made from a conductive material. The weighting member 80 enables the rotating pendulum member 54′ to seek an equilibrium position. The projecting members 82 extend from the cylindrical surface of the rotating pendulum member 54′ to contact an electrical contact pin 84 in housing 50′. The contact pin 84 is coupled with a conductive leaf spring 86 which, in turn, is coupled with wire 32′. Also, the axle 56′ is made from a conductive material which, in turn, has its end coupled with wire 34′.
In use, the rotating pendulum member 54′ rotates about the axle 56′ in a three hundred sixty (360°) degree circle. When the drill is in a horizontal or vertical plane, a projecting member 82 contacts pin 84. Axle 56′, which is already coupled with wire 34′, enables completion of the circuit when the projecting members 82 contact the pin 84. Thus, the circuit is complete when the rotating pendulum member 54′ is in a horizontal or vertical plane. This is the only time that the projections contact the pin which, in turn, complete the circuit, illuminating LEDs 38 and 40 indicating to the user that the drill is in a desired horizontal or vertical plane.
Turning to
The leveling indicator 30″ includes a housing 50″. The housing includes two parts 90 and 92. Inside the non-conductive housing parts 90 and 92 are conductive cones 94 and 96. The conductive cones 94 and 96 are connected with wires 32″ and 34″ which, in turn, lead to the LEDs 38 and 40 as well as to battery 22″. The rotating members 54″ include a pair of conductive balls. A membrane 100 is positioned between the cones 94 and 96. The membrane 100 includes apertures 102 which are positioned about an arc circle, ninety (90°) degrees apart.
When the level indicator 30″ is utilized, the balls 54″ rotate around the cones 94 and 96. The balls 54″ seek an equilibrium position at the bottom of the cones when the drill is in a horizontal or vertical plane. When the drill is in a horizontal or vertical plane, the balls 54″ are positioned in the cone wherein the balls, through apertures 102, contact one another. When the balls 54″ contact one another, the conductive balls 54″ are also in contact with the conductive cones 94 and 96, which complete the circuit, illuminating the LEDs 38 and 40. Thus, when the level indicator is in a horizontal or vertical position, the balls 54″ contact one another through the apertures 102 in the membrane and complete the circuit.
While the above detailed description describes the preferred embodiment of the present invention, the invention is susceptible to modification, variation, and alteration without deviating from the scope and fair meaning of the subjoined claims.
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396 528 | Oct 1993 | AT |
0 578 209 | Sep 1988 | AU |
92 05 302.5 | Aug 1993 | DE |
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2 761 466 | Oct 1998 | FR |