This application claims the benefit of non-provisional patent application Ser. No. 14/568,128.
The disclosed embodiments relate generally to card, picture, or sign exhibiting devices that use forces to affect a common alignment of independent rotatably mounted display elements to display one or more pictures in upright orientations.
Concrete mixer drums typically sport artwork featuring their company's logos or company names on them for marketing and advertising purposes. That artwork, physically applied to the outside of the drum, is properly displayed and oriented right-side up on one side of the mixing drum but is upside-down on the opposite side of the drum.
The inverted logo and text, repeatedly employed over the years, has always been a Pink Elephant of that industry. Some attempts to work around the restrictions on the mode of display have been to eliminate all recognizable images, trademarks, names, and any text markings from the drum's surface, opting for solid colors or simple graphic designs which have no tops or bottoms. Other approaches have been to provide text located on a circumference of the drum, providing a somewhat readable message. Text on the circumference of the drum was readable and acceptable in that it was never inverted, being readable from both sides, but was used as merely a best-case alternative as there was no way to provide for generally horizontally placed text to be displayed right-side up on both sides of the drum.
Any other placement of text on a concrete mixer drum at any orientation other than around its circumference will inevitably appear in an improper orientation, still somewhat readable, but angled and at some point in its rotation, inverted nonetheless.
A preferred solution to the inverted logo dilemma would be simple in design and simple in operation. The concrete hauling vehicles are heavy enough when empty. A solution should add minimal additional weight to the vehicle. Any solution has to be simple, lightweight, and self-sufficient.
Additionally, in an unrelated arena, point-of-purchase and point-of-sale display manufacturers are continually searching for ways to create attractive, interactive, or dynamic displays that are simple in operation and low in cost. Dynamic displays work because they attract people's attention and communicate more information in the same amount of space as a static display. If a way to create a dynamic display on a vertical surface were to be created which would be simple in construction and operation, it would provide yet another tool for the companies that are involved in the design and manufacture of displays for point-of-sale and point-of-purchase displays.
Accordingly, several objects and advantages of the disclosed embodiments include, but are not limited to:
providing an easily changeable force-orienting display system which provides alignment and display of an image segmented and mounted on receiver substrates on a number of display segments through the application of existing or applied forces;
providing an easily changeable, inexpensive, dynamic advertising device for use in point-of-purchase and point-of-sale displays and others; and
providing an easily changeable, segmented exhibitor display device which through the application of known or applied forces displays multiply sectioned images into their composite images through the employment of a common alignment scheme.
According to one exemplary embodiment, an easily changeable, or semi-permanent, force orienting display system is provided with a number of display segments that are positioned proximally to each other, that are attached rotatably to movable supports, and that are mounted to a moving surface. The materials used in construction of the display segments can include but are not limited to polymers, plastics, metals, or other materials which may be opaque, semi-transparent, or transparent. The weighted characteristic of each of the display segments implies that its center of balance is not colinear with the display segment's axis of rotation, guaranteeing alignment of all display segments due to the effect of gravity, or by similar argument if a force other than gravity is involved. The external surfaces of the multiple display segments have receiver substrate areas determined, and any number of images which are cut into image sections are applied to these receiver substrate areas in a variety of ways, including but not limited to painting, decals, hook and loop, slidable trays, sleeves, and other manners of attachment. As the mounting surface moves, the weighted display segments are acted on by gravity to effect a common alignment of each display segment with respect to each proximal display segment and also with respect to the mounting surface, showing common display faces on all display segments in such a manner as to display one or more pictures properly aligned top to bottom in a plurality of views. This allows for right side up orientation of logos lettering or images on, for example, two sides of a concrete mixer drum. Two images may be displayed, one on each side of the concrete mixer drum.
Further objects and advantages of the disclosed embodiments will become apparent from a consideration of the drawings and ensuing description. In the drawings, closely related figures have the same number but different alphabetic suffixes.
In
The following terms will be used throughout the specification and will have the following meanings unless otherwise indicated.
“Picture” refers to artwork, a physical image, sign, graphic, or the like.
“Picture section” refers to a sub portion of a picture that has been cut into smaller pieces.
“Graphic section” refers to a graphic or a portion of a graphic within a picture.
“Display segment” refers to an elongated display element with defined receiver substrate areas on its exterior whose receiver substrate areas are used to mount picture sections.
The disclosed embodiments include a force-orienting display system for displaying a picture in right side up orientation in multiple viewing orientations. The display system comprises rotatable display segments mounted proximally to each other on a movable drum surface. The display segments each have receiver substrate areas established on their exteriors. Any number of pictures can be displayed where the pictures have been cut into smaller picture sections and mounted onto the receiver substrate areas. These are explained in greater detail in the following detailed description.
In an exemplary embodiment, a force-orienting display system 10 is illustrated in
The display segments 100 are attached to two conventional mounts 101 attached to a surface 104 in such a way that the display segments 100 are able to rotate freely on their longitudinal axis with respect to the surface 104. The mounted display segments 100 are proximally located to each other. Each display segment 100 has sufficient length to define areas on its exterior as a receiver substrate for picture sections to be displayed.
The center of mass of each display segment 100 is not colinear with its axis of rotation.
Receiver substrate areas for mounting picture sections are determined by examining a display segment 100 at rest. Its orientation will have its center of balance below the axis of rotation. A plane through the axis of rotation and the resting center of balance defines a left and right receiver substrate area. Display segments 100 displaying image segments mounted on their receiver substrate areas on the display segments are shown in
Pictures selected and cut into smaller picture sections are calculated to fit the physical dimensions of and are attached to the right-side half and left side half receiver substrate areas defined.
In one embodiment, the picture sections are printed onto the surface of curved, removable display sleds with semicircular cross sections extending the length of the display segments 100 and slidably attached to a plurality of tongues 320 as illustrated in
Whereas the picture sections 232, 234, 236, 238, 242, 244, 246, 248 from
In one embodiment, a display system 10 as illustrated in
Referring to
As the rotating, generally vertical surface is rotated 180°, the picture displayed will change from displaying the picture on its “1” right side to displaying the picture on its “2” left side. As the rotating, generally vertical surface is rotated through another 180°, the picture displayed will alternate from displaying the picture on its “2” left side to displaying the picture on its “1” right side. The picture displaying cycle then repeats.
Of course, the display system 20 described above may be implemented on non-flat surfaces.
Still another embodiment incorporates the application of one or more known different forces to act on the display segments, such as magnetism, acting on an internal, ferrous mass, which is used simultaneously as a mass to alter its overall center of mass.
In another embodiment, the number of receiver substrate may be more than two, such as defining four receiver substrate locations around the display segments 100 instead of two. Gravity and magnetism could then be used in conjunction to display one of four images.
An alternate embodiment for affecting the center of mass of the display segments 100 is noted by designing a portion of the display segment 100 to comprise materials of differing densities, such as a relatively light density material 105 and a relatively low density material 106 as shown in
The placement of the rotational mechanism 110 may be varied in some embodiments. For example, the rotational mechanism 110 may be integral to the display segment 100, or it may be integral to its mount 101.
In some embodiments, the display segments 100 may have different diameters. In another exemplary embodiment, transparent tubing is slid over the display segments 100 to attach, secure, and retain the picture sections to the display segments 100.
In another exemplary embodiment, mounts which conduct electricity or incorporate electrical conductors for conducting electricity may be provided for light generating elements 310, such as a light emitting diode as shown within the cutaway section 103 in
In some embodiments, picture sections can be removably secured to by any appropriate attachment expedient, such as magnetic backed picture sections and a magnetically attractive surface, by the use of hook and loop material on the backs of the picture sections and on the receiver substrate areas.
An alternate embodiment for attaching the graphic sections is evident in that some picture sections will bear a convenient adhesive layer on their obverse, protected by a strippable liner, where the liner can be pulled away from the picture section, exposing an adhesive surface.
Yet another alternate embodiment is for pictures which are painted or printed onto the receiver substrate areas.
Referring again to
Explained herein is a system for displaying one or more pictures mounted on one or more independent, freely rotatable, elongated display segments which are attached proximally to each other on a movable surface. The movable surface acts to change the position and orientations of the different display segments with respect to the surface and to nearby display segments, causing a coordinated change of display between one of two different pictures in non-inverted orientations. For example, it correctly displays logos in proper top to bottom orientation on both sides of a concrete mixer drum.
A mounting surface need not be completely flat, but the display segments rotate freely with respect to the mounting surface, taking into account all possible movements of the mounting surface. Each display segment attached to a rotating surface must have free, unobstructed rotation throughout the entire range of motion of the surface.
The display segments remain generally parallel to each other. They will properly align to display pictures while their axes of rotation are synchronized left sides to left sides, and in a primarily non-vertical orientation. They are not required to be confined to horizontal orientations only, as gravity continues to act on the horizontal component of the center of mass acting on the center of rotation of the display segment to provide a rotational moment when the display segment is not in a true horizontal orientation. However, as the axes of rotation of the display segments approach a vertical orientation, the centers of mass of the display segments become more closely aligned with the axes of rotation, the rotational moment of the horizontal component of gravity on the center of mass acting along the center of rotation approaches zero, and gravity begins to have less effect in providing its novel, desired alignment force on the display segments, and the display coordination breaks down.
While the above description contains many embodiments, these should not be construed as limitations on the scope of the invention, but as exemplary implementations thereof. Many other ramifications and variations are possible within the teachings of the invention.
Thus, the scope of the invention should be determined by the appended claims and their legal equivalents, and not by the examples given.
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Number | Date | Country | |
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20190066547 A1 | Feb 2019 | US |
Number | Date | Country | |
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Parent | 14568128 | Dec 2014 | US |
Child | 16151189 | US |