This disclosure relates to window blinds, particularly window blinds that are automated and cordless.
Standard window blinds typically include cords. Even the so-called cordless blinds often include tilt strings which provide support for the slats and provide a mechanism for tilting the slats to close the window blinds. Exposed cords in blinds detract from the aesthetics of the window treatment and, more importantly, represent a safety hazard for children who may become entangled in the cords and strangle. A blind that is devoid of exposed cords is needed.
Window blinds which require manual adjustment of the slats to lift, lower, or tilt the slats represent a level of inconvenience. A window blind which is powered by electricity, for example, by battery power is desirable. While window blinds which perform some functions using battery power are known in the art, a more convenient window blind which may raise, lower, and tilt the slats while being truly devoid of exposed cords is needed.
We disclose a window blind which may be battery-controlled and may have no exposed cords. The window blind may include a headrail and multiple slats. The slats may include one or more electromagnets. The core of the electromagnets may be inserted into channels that may connect a top surface to a bottom surface of the slat. The electromagnets may each include a core and a wire wrapped around the core with one of the two ends of the wire extending from each end of the core. The ends of the wire may be in electrical connection with a battery. The window blinds may further include switches which may either complete or break a circuit including at least one battery and at least one electromagnet. A controller may modulate the switches to actuate or inactivate the electromagnets.
The ends of the slats may be inserted into orifices within each of a plurality of rotatable slat mounting members. The rotatable slat mounting members may be located between two guide rails. The guide rails may be mounted on each of two side panels which extend downward from the ends of the headrail. The orifices may include electrical connections which may electrically connect the ends of the wires which extend from the electromagnets to the one or more batteries. The rotatable mounting members may rotate when the slats tilt providing the slats with freedom of movement. The rotatable mounting members may slide vertically between the two guide rails on each side panel to enable the slats to raise and lower.
The electromagnets may, at least in part, control the tilting, raising, and lowering of the slats. For example, when all the electromagnets are actuated and have the same polarity, the slats may be attracted to each other and stack up. The top slat may be vertically immobile so that the lower slats stack below the top slat. The slats may be raised in this way.
Alternatively, the electromagnets on a longitudinal edge of each of the slats may be actuated while the electromagnets on the opposite longitudinal edge of each of the slats may be inactivated. A metal member may be attached to each slat. In some embodiments, the metal member may be on the bottom surfaces of the slats and along the longitudinal edges which have the inactive electromagnets. Instead of the electromagnets being attracted to each other, the electromagnets of one slat may be attracted to the metal member of the slat above it. The longitudinal edge of the lower slat and the opposite longitudinal edge of the upper slat may move toward each other causing the slats to tilt.
Window blind, as used herein, means a blind that covers an opening in a building, including a window or door.
While this invention is susceptible of embodiment in many different forms, there are shown in the drawings, which will herein be described in detail, several specific embodiments with the understanding that the present disclosure is to be considered as an exemplification of the principals of the invention and is not intended to limit the invention to the illustrated embodiments.
We disclose a window blind that has no exposed cords to present a safety hazard or detract from the aesthetic pleasure of the window blind. The window blind may include a headrail with two ends. A side panel may extend downward from each of the two ends of the headrail. The window blind may include one or more batteries. In some embodiments, the one or more batteries may be housed within the headrail.
Each of the side panels may include a guide rail assembly. Each guide rail assembly may include two guide rails which may be parallel to each other and which may be approximately perpendicular to the headrail and approximately parallel to the side panels. The side panels may include a plurality of rotatable slat mounting members. The rotatable slide mounting members may be mounted between the guide rails in each side panels. Each rotatable slat mounting member may include an orifice for inserting an end of a slat and each orifice may include a plurality of electrical connections. Each end of a slat may be inserted into a rotatable slat mounting member that is mounted within a different side panel.
Each window blind may include multiple slats each of which may include a top surface, a bottom surface, two transverse edges, and both a front and a rear longitudinal edge. Each slat may include multiple electromagnets which may be in electrical connection with the one or more batteries. Each of the electromagnets may have identical polarity.
The window blinds may include at least one switch which may be located between the one or more batteries and the electromagnets. The switches may control the currents flowing between the one or more batteries and the electromagnets. Consequently, the switches may actuate or inactivate the electromagnets.
The electromagnets may include a core and a wire wrapped around the core with each end of the wire extending from a different end of the core. In some embodiments, the electromagnets may be inserted into channels that extend through the thickness of the slat connecting the top surface with the bottom surface of the slat. There be at least two channels and an electromagnet may be inserted through each channel.
In some embodiments, the slats each include multiple tabs. The tabs may extend from each of the two transverse edges of each slat. For example, a tab may extend laterally from each corner of the slat. Consequently, two tabs may extend from each transverse edge of each slat, the tabs being parallel to the longitudinal edges of the slat. The tabs on each end of each slat may be inserted into a rotatable slat mounting member.
The ends of the wire extending from each end of the core of each electromagnet may extend out onto a tab. For example, because the core may be inserted into a channel that extends from the top surface to the bottom surface of the slat, one end of the wire may extend from the core out onto a bottom surface of a tab and the other end of the wire may extend out onto a top surface of the same tab. In some embodiments, at least one of the multiple electromagnets on each slat may be positioned at or near a corner of the slat. Some embodiments may include an electromagnet at each corner of the slat. In some embodiments, electromagnets may be positioned along each of the front and the rear longitudinal edges of a slat.
When the tab is inserted into the orifice within the rotatable slat mounting member, the ends of the wires may each come in contact with an electrical connection within the orifice. The connection may provide current from the at least one battery to the electromagnet.
Each of the slats may further include at least one metal member. In some embodiments, the metal members may include steel, iron, or a combination of both steel and iron. In some embodiments, the at least one metal member may be located on the bottom surface of each slat. In some embodiments, a metal member may further be located along on the bottom surface of a slat along the front longitudinal edge, the rear longitudinal edge, or both the front and rear longitudinal edges.
Referring again to the at least one switch, each of the at least one switch may complete a circuit between one or more electromagnet and at least one battery when in a closed position. Furthermore, the switch each of the at least one switch may break a circuit between one or more electromagnet and at least one battery when in an open position. In some embodiments, the window blind may include multiple switches and each switch may be a designated switch which is designated to control a single, specific electromagnet.
The disclosed window blind does not include tilt strings although the slats may be tilted to block incoming light. In some embodiments, the window bind includes a controller. In some embodiments, the controller may be located within the headrail. The controller may be connected to and modulate the at least one switch. In one embodiment, the slats may tilt to at least partially block light passing through the blinds as follows. The controller may close the switches that control the current flow to electromagnets which are positioned along the rear longitudinal edge of the slats. The controller may also open the switches that control the current flow to the electromagnets which are positioned along the front longitudinal edge of the slats. Consequently, the electromagnets that are positioned along the rear longitudinal edges of the slats may be actuated and the electromagnets that are positioned along the front longitudinal edges of the slats may be inactivated.
The electromagnets that are positioned along the rear longitudinal edge of a first slat may be attracted to the one or more metal members on the bottom surface of a second slat. The first slat may be adjacent to and may be the slat immediately below the second slat. The one or more metal members on the second slat may be located along the front longitudinal edge of the second slat on its bottom surface. Consequently, the rear longitudinal edge of the first slat may move toward the metal member of the second slat. This may cause the first and second slats to tilt towards each other. The rotatable slat mounting members into which the first and second slats are inserted may rotate as the slats tilt allowing the indicated longitudinal edges of the slats to move freely towards each other. The indicated longitudinal edges of the first and second slats may come into contact with each other causing the slats to close and block light from entering through the window blind.
The slats of the disclosed window blind may be raised and lowered as follows. The electromagnets on both longitudinal edges of each slat may be actuated. In some embodiments, the controller may close the switches causing the electromagnets to actuate. The electromagnets from adjacent slats may be attracted to each other through the magnetic forces. The slats may move vertically toward each other by moving vertically along the guide rail assembly. In some embodiments, the top slat may be vertically immobile so that the slats below it may stack below the top slat and completely open the window blind.
Referring now to the drawings,
While specific embodiments have been illustrated and described above, it is to be understood that the disclosure provided is not limited to the precise configuration, steps, and components disclosed. Various modifications, changes, and variations apparent to those of skill in the art may be made in the arrangement, operation, and details of the methods and systems disclosed, with the aid of the present disclosure.
Without further elaboration, it is believed that one skilled in the art can use the preceding description to utilize the present disclosure to its fullest extent. The examples and embodiments disclosed herein are to be construed as merely illustrative and exemplary and not a limitation of the scope of the present disclosure in any way. It will be apparent to those having skill in the art that changes may be made to the details of the above-described embodiments without departing from the underlying principles of the disclosure herein.