The invention relates generally to improved rings and binders using such improved rings. More particularly, the invention relates to adjustable rings, which provide customized capacity for loose-leaf sheets and sheet-like materials, and binders using the same.
Various types of ring binders with rings of fixed capacity have been developed to hold loose-leaf sheet or sheet-like materials. For example, paper, boards, slides, transparencies, photographs, plastic holders for disks, and business cards may be stored in ring binders. The binders come in various sizes, shapes, and configurations.
As exemplified in
Conventional designs of rings are fixed in capacity and size. When more capacity is desired, the user must transfer all the material to a new binder with a larger ring to increase the capacity. When less capacity is desired, the user also must transfer all the material to a new binder with a smaller ring to avoid leaving a significant amount of empty space in the binder.
Having a binder with an adjustable ring would appeal to many users because the entire binder can be utilized in many different size configurations with improved convenience and efficiency. Therefore, there exists a need for a binder, with one or more adjustable rings, that can conform to different amounts of material.
The invention is directed to an adjustable ring, and a binder containing one or more of such adjustable rings.
According to a first embodiment of the invention, an adjustable ring in accordance with the present invention is an upside-down U-shaped ring comprising a pair of telescoping arms with a curved section placed on top of, and connected to, each telescoping arm. Each curved section has a proximal end for connecting to the top of the corresponding telescoping arm, and a distal end for facing and releasably connecting with the distal end of the other curved section. The telescoping arms either share a ground plate, or each is attached to a separate ground plate. The ground plate(s) attach the ring to a backing material of a binder.
In additional embodiments of the invention, an adjustable ring is provided according to the first embodiment, wherein the telescoping arm on each side of the ring is replaced by a telescoping structure that is known in the art, such as ones described in U.S. Pat. No. 2,298,140 titled “Telescopic Extensible Antenna,” U.S. Pat. No. 5,164,739 titled “Antenna Device for an Automobile,” or U.S. Pat. No. 6,830,552 titled “Backscratcher with a Telescopically Adjustable Shaft and with a Plurality of Screw-on Attachment End Pieces.” The disclosure of these three patents is incorporated in this application in their entirety.
In additional embodiments of the invention, a binder constructed in accordance with the present invention comprises a front cover, a rear cover, a spine connecting the both covers, and one or more adjustable rings attached to the rear cover. Other binder constructions can be used in conjunction with one or more of the adjustable rings of the invention, such as the binder designs described in U.S. Pat. No. 5,607,246, the entirety of which is incorporated in this application.
The invention will be understood more readily from the following detailed description of the invention, when taken in conjunction with the accompanying drawings.
The invention is explained in connection with the following exemplary embodiments. They are provided as examples to facilitate the description of the invention and should not be regarded as exclusive embodiments. As discussed below, multiple variations can be made to the design of the ring binder without departing from the spirit or scope of the invention.
The adjustable ring 10 in accordance with the first embodiment of the invention is illustrated in
The curved section 11 preferably has a circular cross section, although other cross sections, such as an oval, a rectangle or a square, are contemplated. The curved section 11 has a proximal end 11a and a distal end 11b. The proximal end 11a of each curved section 11 is attached to the top of the corresponding telescoping tube assembly 12. The distal ends 11b of both curved sections 11 are arranged to face each other with a releasable connection. The curved section 11 can be made as a solid piece, or hollow inside.
The releasable connection is intended to prevent or minimize unwanted motions with the adjustable ring. One unwanted motion is the rotational motion in which the curved section 11 rotates in one or the other direction about the axis 12A of the telescoping tube assembly 12, causing the distal end 11b of the curved section 11 to move out of or into the two-dimensional plane in
For clarity, the surfaces of the distal ends 11b are present as complimentary surfaces to prevent unwanted motion about the axis 12A described in
The telescoping tube assembly 12 has two or more tubes configured in a telescoping relationship so that the telescoping tube assembly 12 can extend or collapse in length as needed. The telescoping tube assembly 12 preferably has a circular cross section, although other cross sections, such as an oval, a rectangle or a square, are contemplated.
In the fully collapsed state, only the outermost tube (14) of the telescoping tube assembly 12 is visible. The top of the outermost tube 14 ends in an edge 14T, which preferably tapers in the direction toward the curved section 11. The bottom of the outermost tube 14 is connected to a base plate 150, which in turn is connected to a ground plate 160.
All tubes in the telescoping tube assembly 12 have the same cross-sectional shape, which is preferably a circle, although other cross sections, such as an oval, a rectangle or a square, are contemplated. The tubes are preferably coaxial, meaning that they share the same central axis.
The tubes are designed to have increasing diameters (or an appropriate cross-sectional dimension in the event that the tubes do not have a circular cross section) going from inside to outside in a radial manner. For example, in
However, if desired, the tubes that construct a telescoping tube assembly 12 may have tubes that have decreasing diameters (or an appropriate cross-sectional dimension in the event that the tubes do not have a circular cross section) going from inside to outside in a radial manner. This design incorporates the same auxiliary features as the described adjustable rings, such as the edges 14F and 15F, except they are oriented in such a fashion that they provide the similar effect of stabilizing a difference in diameters (which is explained in further detail below). This design effectively flips the telescoping tube assembly 12 in
The curved section 11 is attached to the top of the innermost tube, which in the case of
The tubes are designed so that they can glide along the central axis 12A in relation to each other between a fully extended state and a fully collapsed state. Stopping members are provided to prevent the tubes from extending beyond the fully extended state so that the tubes do not become disengaged from each other.
The stopping members for preventing the outermost tube 14 from disengaging from the intermediate tube 15 are a combination of lips 14T and 15B. The lip 14T originates from the inside surface of the outermost tube 14 at its top, and extends radially inward toward, and eventually abuts, the outside surface of the intermediate tube 15. The lip 14T is in the form of a plate with a hole in its center, wherein the hole matches the outside circumference of the intermediate tube 15, and the outer perimeter of the lip 14T matches the inside circumference of the outermost tube 14. The lip 14T can also have material that extends in a longitudinal manner of the telescoping tube assembly 12 (i.e., along the central axis 12A), imparting a thickness to the plate. In one case, the lip 15B originates from the outside surface of the intermediate tube 15 at its bottom, and extends radially outward toward, and eventually abuts, the inside surface of the outermost tube 14. In this case, the lip 15B is in the form of a plate with a hole in its center, wherein the hole matches the outside circumference of the intermediate tube 15, and the outer perimeter of the lip 15B matches the inside circumference of the outermost tube 14. In another case, the lip 15B can be a plate without a hole, which runs across the entire inside diameter of the outermost tube 14 and attached, at its top surface, to the bottom of the intermediate tube 15. In either case, the lip 15B can also have material that extends in a longitudinal manner of the telescoping tube assembly 12 (i.e., along the central axis 12A), imparting a thickness to the plate.
In a similar fashion, the stopping members for preventing the intermediate tube 15 from disengaging from the innermost tube 16 are a combination of lips 15T and 16B. The lip 15T originates from the inside surface of the intermediate tube 15 at its top, and extends radially inward toward, and eventually abuts, the outside surface of the innermost tube 16. The lip 15T is in the form of a plate with a hole in its center, wherein the hole matches the outside circumference of the innermost tube 16, and the outer perimeter of the lip 15T matches the inner circumference of the intermediate tube 15. The lip 15T can also have material that extends in a longitudinal manner of the telescoping tube assembly 12 (i.e., along the central axis 12A), imparting a thickness to the plate. In one case, the lip 16B originates from the outside surface of the innermost tube 16 at its bottom, and extends radially outward toward, and eventually abuts, the inside surface of the intermediate tube 15. In this case, the lip 16B is in the form of a plate with a hole in its center, wherein the hole matches the outside circumference of the innermost tube 16, and the outer perimeter of the lip 16B matches the inside circumference of the intermediate tube 15. In another case, the lip 16B can be a plate without a hole, which runs across the entire inside diameter of the intermediate tube 15 and attached, at its top surface, to the bottom of the innermost tube 16. In either case, the lip 16B can also have material that extends in a longitudinal manner of the telescoping tube assembly (i.e., along the central axis 12A), imparting a thickness to the plate.
As shown in
Lip 14T is fixedly attached to the inner surface of the outermost tube 14 and/or the under surface of the edge 14F. Similarly, lip 15T is fixedly attached to the inner surface of the intermediate tube 15 and/or the under surface of the edge 15F. Such fixed attachment can be in the form known in the art, such as through the use of a glue or an adhesive. Alternatively, lip 14T can be made as an appendage to, and an integral part of, the outermost tube 14. Similarly, lip 15T can be made as an appendage to, and an integral part of, the intermediate tube 15.
In a fully collapsed state, as shown in
When the telescoping tube assembly 12 moves from a fully collapsed state toward a fully extended state, the lip 15B glides along the inner surface of the outermost tube 14, and/or the lip 16B glides along the inner surface of the intermediate tube 15.
In addition to the fully collapsed state and the fully extended state, the telescoping tube assembly 12 can be in any number of intermediate states. In these intermediate states, such as the one illustrated in
The outermost tube 16 and any intermediate tube, such as 15 in the figures, should be hollow to accommodate internal structures. The innermost tube 16 and the curved section 11 can have a hollow inside or be made as a solid piece.
The tubes 14, 15 and 16 and the curved section 11 can be constructed of any suitable material, including, but not limited to, steel, iron, aluminum, copper, bronze, plastic, etc. The lips 14T, 15T, 15B and 16B can be made using any of the same materials in the preceding sentence, or other materials, such as an elastomeric material (e.g., rubber).
The adjustable ring 10 can be designed such that the tubes 14, 15 and 16 can move up and down in relation to each other with or without friction between two adjacent tubes.
If no friction between the parts of the tube assembly 12 is present, the capacity of the ring is determined by how much material is placed on the ring. The ring will collapse with the force of gravity until it reaches the lowest point, which is the top of material on the ring or the fully closed state, whichever is higher.
Friction allows the tubes to stay in an intermediate state on their own, which facilitates the insertion of papers into the binder. Without friction, the adjustable ring 10 will automatically collapse with the force of gravity to the most collapsed state that is permitted by existing material in the binder.
Various methods can be used to impart desirable friction between the tubes. In one method, the tubes and/or lips are dimensioned such that an inner part fits tightly within an outer part, creating friction through compressive forces between the mating surfaces of the parts. In another method, one or both of the mating surfaces (i.e., the inner surface of an outer tube and the outer surface of an inner lip) are provided with a coating or surface layer that imparts or adjusts friction. Examples of suitable coating includes a polymeric coating, such as those described in U.S. Pat. No. 3,893,496, which is incorporated in its entirety into the instant specification. Examples of suitable surface layer includes a rubber, a suede, or another material with a coarse surface. In yet another method, one or more lips (especially those made of rubber or another elastomeric material) can be dimensioned such that they are wider than the internal voids of the corresponding outer tubes when they are in their natural, uncompressed state, but can fit inside such internal voids under compression. The compression required to insert the lips into the corresponding outer tubes leads to the creation of friction between these parts.
Other known mechanisms can be provided to releasably lock two adjacent tubes in a specific position. For example, a ball retention mechanism as described in U.S. Patent Application Publication No. US20030170074 can be used to releasably lock the outermost tube 14 in relation to the intermediate tube 15, and/or the intermediate tube 15 in relation to the innermost tube 16. The disclosure of U.S. Patent Application Publication No. US20030170074 is incorporated in its entirety in the instant application. Such lock allows a user to add or remove materials to the ring without worrying about the telescoping arm(s) collapsing under the effect of gravity, and the lock can be readily broken once the addition or removal has been accomplished.
In additional embodiments, telescoping assemblies with known designs can be used for purposes of this invention. For example, in these additional embodiments, the telescoping arm 12 is replaced by a telescoping structure that is described in U.S. Pat. No. 2,298,140 titled “Telescopic Extensible Antenna,” U.S. Pat. No. 5,164,739 titled “Antenna Device for an Automobile,” or U.S. Pat. No. 6,830,552 titled “Backscratcher with a Telescopically Adjustable Shaft and with a Plurality of Screw-on Attachment End Pieces.” The disclosure of these three patents is incorporated in this application in their entirety. The design illustrated in FIG. 5 of U.S. Pat. No. 6,830,552 is particularly advantageous because it reduces or eliminates the unwanted rotation between the tubes.
Stiffener panels 105-1, 105-2 and 105-3 are preferably made from a rigid material, such as chipboard, cardboard, paperboard, plasticized polyvinyl chloride, low density polyethylene, thermoplastic rubber, ethylene-ethyl acrylate, ethylene-butylene copolymer, polybutylene and copolymers thereof, ethylene-propylene copolymers, chlorinated propylene, chlorinated polybutylene or mixtures of those, polyurethane elastomeric materials, polyester elastomeric materials, polyamide elastomeric materials, copolymers of isobutylene and isoprene, aluminum, steel, copper, iron, brass, and other materials of the like.
In other embodiments, the adjustable ring 10 of the invention is used in conjunction with a binder that is known in the art, such as any of the various embodiments of binders described in U.S. Pat. No. 5,607,246, which is incorporated in its entirety into the instant specification. Embodiments reflecting such use are considered embodiments of this invention. For example, a binder constructed according to the disclosure of U.S. Pat. No. 5,607,246 comprises (i) a front cover stiffener panel, said front cover stiffener panel preferably having an inside and outside sheet, and preferably being secured between said inside and said outside surface sheets, (ii) a rear cover stiffener panel, said rear cover stiffener panel being spaced apart from said front cover stiffener panel in opposing relation thereto and preferably having an inside and outside sheet, and preferably being secured between said inside and said outside surface sheets, (iii) one or more adjustable rings secured to said front cover stiffener panel and said rear cover stiffener panel, whereby said adjustable rings are in accordance with the first embodiment, (iv) a plurality of stiffener strips which are secured to each other, wherein said stiffener strips form a flexible spine which is connected to the front cover stiffener panel at one end, and connected to the rear cover stiffener panel at the opposing end, (v) whereby said front and said rear cover stiffener panels, and said stiffener strips cooperatively define a binder cover having front and rear covers interconnected by a flexible spine, said flexible spine being conformable about said one or more adjustable rings. The use of flexible backing is advantageous because it conforms to a larger or smaller range of material, in terms of thickness.
Although the invention has been described in conjunction with examples thereof, it will be appreciated by those skilled in the art, that additions, modifications, substitutions, and deletions may be made without departing from the spirit or scope of the invention as defined in the appended claims.
Number | Name | Date | Kind |
---|---|---|---|
917773 | Leach | Apr 1909 | A |
2099472 | Emery | Nov 1937 | A |
2163856 | Schade | Jun 1939 | A |
2855935 | Ham | Oct 1958 | A |
4172675 | Lacourt | Oct 1979 | A |
20030170074 | Mills | Sep 2003 | A1 |
20080095572 | Frankeny | Apr 2008 | A1 |
Number | Date | Country |
---|---|---|
783954 | Jul 1935 | FR |
214276 | Feb 1925 | GB |