US20220017266A1

US20220017266A1 - Hand-footholds for buckets, troughs, tubs, containers, redeptacles, and bins

Info

Publication number: US20220017266A1
Application number: US17/353,761
Authority: US
Inventors: Valerie Chandra Hetzel
Original assignee: Individual
Current assignee: Individual
Priority date: 2019-04-22
Filing date: 2021-06-21
Publication date: 2022-01-20

Abstract

A portable container containing internal pairs of foot-handholds located near the bottom of sloped or un-sloped container for the purpose of container stabilization by user/s feet and for bottom of container hand-grab capacity.

Description

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation-in-part of co-pending U.S. patent application Ser. No. 16/390,304 filed on Apr. 22, 2019.

BACKGROUND OF INVENTION

Field of the invention

Portable Containers

Description of Related Art

application Ser. No 16/385,995 and application Ser. No. 16/390,304

BRIEF SUMMARY OF THE INVENTION

Portable containers are often formed of lightweight materials such as plastic, which lacks the ballast needed to stabilize the container when items are added, removed, or when lids are lifted off. In these instances, the container has a tendency to tip over, which is inconvenient, messy, and potentially hazardous. Additionally, most portable containers only have handles at the top of the container, while few are located at the bottom.
The present invention generally relates to sloped, portable container design and, more particularly, to pairs of wall-orifice foot-handholds (different x, y wall planes, accessible to both feet of an individual user or two or more feet of two or more users for the purpose of hold-down capacity of the container via weight transference). For such a container, paired, extracted, or cut-out-of-the-wall orifice foot-handholds can be placed directly above the floor (in said x, y, z configurations) or below the floor of the container if containers sidewalls extend past the final floor of the container to create a base portion upon which the container rests. In this scenario, one or more extracted orifice foot-handholds are cut out of the walls of the base portion, and, in some instances, enclosed internally within the bin to prevent contents from contacting user/s hand/s or feet.
The function of the foot-handholds in the same z plane of a container, either above or below a floor within the different walls of the container, provides the strongest hold-down of the containers when one or more users apply two or more feet to the foot-handholds. The handhold function allows for secure handling and maneuvering of the container, which are not usually found on lower sections of most containers.
The configuration of the pairs being in different wall planes will create a triangular touch point to the ground for a single user employing both feet for weight transference and will prevent tipping of can towards user when removing or adding contents, beings, and lids, or when separating nested containers. This triangular touch-point is akin to a tripod stabilizing a camera, whereby when the user is handling it, there is little to no movement of the device. Two users operating a pair of foot-handholds in opposition or near opposition also creates this triangular touch point to the ground and avoids the tipping of containers towards either user. The added handhold element of a foot-handhold combination becomes invaluable when a single user needs to overturn a bin to pour out contents and needs a lower grab point on the container. This may also function as a tie-down location for when it is upright, flipped, or even on its side.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

FIG. 1 is a sample of a portable, rectangular container, as seen from the bottom orthogonally, with a pair of enclosed foot-handholds. This container is sloped and has no base portion, just a single floor upon which it rests. The wall orifice and floor orifice are enclosed within the container. This enclosure is extruded into the container and is molded to the floor and walls within the container. The pairs are not in the same x or y plane, but are in the same z plane.

FIG. 2A is a portable, translucent, cylindrical container with more than one pair of foot-handholds, as seen from the topside orthogonally. This container is sloped and has no base portion, just a single floor upon which it rests. The wall orifices and floor orifices is enclosed within the container. The enclosure is extruded into the container and is molded to the floor and walls within the container. The pairs are not in the same x or y plane, but are in the same z plane.

FIG. 2B is a blow out of a clay prototype sample of just the foothold.

FIG. 2C is the same design, as seen from the top.

FIG. 3A is a translucent, cylindrical container with more than one pair of foot-handholds, as seen from the topside orthogonally. This enclosure is sloped and has no base portion, just a single floor upon which it rests. The wall orifices and upward floor indent is enclosed within the container. This enclosure is extruded into the container and is molded to the floor and walls within the container. The pairs are not in the same x or y plane, but are in the same z plane.

FIG. 3B is the same design, as seen from the top.

FIG. 3C is a blow out of a clay prototype sample of just the foothold.

FIG. 4A is a translucent, cylindrical container with more than one pair of foot-handholds, as seen from the topside orthogonally. This container is sloped and has no base portion, just a single floor upon which it rests. The extruded enclosure is modified to accommodate bars or handles placed at the intersection of the floor and wall in the enclosure running parallel to the ground where the orifices are otherwise located with visible, optional grips that wrap around the handles or bars. The pairs of foot-handholds are not in the same x or y plane, but are in the same z plane.

FIG. 4B is the same design, as seen from side directly.

FIG. 4C is the same design, as seen from the top.

FIG. 5A is a translucent, cylindrical, mesh container with more than one pair of foot-handholds, as seen from the topside orthogonally. This container is sloped and has no base portion, just a single floor upon which it rests. The wall and floor orifices have no enclosure to contain the orifices within the container. The pairs of foot-handholds are not in the same x or y plane, but are in the same z plane.

FIG. 5B is a translucent, cylindrical, mesh container with a corrugated floor more than one pair of foot-handholds, as seen from the topside orthogonally. This container is sloped and has no base portion, just a single floor upon which it rests. The wall and floor orifices have no enclosure to contain the orifices within the container. The pairs of foot-handholds are not in the same x or y plane, but are in the same z plane.

FIG. 6A is a square, sloped container with more than one pair of foot-handholds, as seen from the topside orthogonally. This container is sloped and has a base portion upon which the container rests. The wall orifice foot-handhold is below a single-planed floor. The pairs are not in the same x or y wall plane. One wall is removed.

FIG. 6B is the same square container as FIG. 6A but viewed from the top.

FIG. 6C is a top view only of a round non-sloped container with paired footholds and concave enclosure.

FIG. 6D is a top view only of a triangular non-sloped container with paired footholds, and concave enclosure in a triangular configuration.

FIG. 6E is a top view only of a rectangular non-sloped container with paired footholds, and concave enclosure in a rectangular configuration.

FIG. 6F is a blow out of a clay prototype sample of just the foothold.

FIG. 7A is a translucent, round container with more than one pair of foot-handholds, as seen from the topside orthogonally. This container is sloped and has a base portion upon which the container rests. The wall orifice foot-handhold is below a corrugated floor. This floor rises above the foothold and curves over the foot-handhold and falls towards the ground, providing potential contact points with the ground and continuing around the inside walls over each foothold. The pairs are not in the same x or y wall plane in the base portion, but are in the same z plane in the base portion. They are configured to receive the front portion of two feet of one person or more than two feet of two or more people for the purpose of stability via weight transference to the container, as well as functional handholds for lifting practicality.

FIG. 7B is another side view of FIG. 7A.

FIG. 7C is a top view of FIGS. 7A and 7B.

FIG. 7D is a square container with more than one pair of foot-handholds, as seen from the topside orthogonally. This container is sloped and has a base portion upon which the container rests. The wall orifice foot-handhold is below a corrugated floor. The floor rises above the foothold and curves over the foot-handhold and falls towards the ground, providing potential contact points with the ground and continuing around the inside walls over each foothold. The pairs are not in the same x or y wall plane in the base portion, but are in the same z plane in the base portion. They are configured to receive the front portion of two feet of one person or more than two feet of two or more people for the purpose of stability via weight transference to the container, as well as functional handholds for lifting practicality.

DETAILED DESCRIPTION OF THE INVENTION

The use of paired foot-handholds in portable containers of all types has significance for the following reasons:
For a trash bag which is vacuumed sealed to the inside of a trash receptacle;
For two or more containers which are nested together and cannot be separated;
For the removal a tight fitting lid from portable buckets and trash receptacles;
For the removal of living beings from portable tubs, such as a dog or cat, farm animal, or a bathing, slippery baby;
For the addition or removal of slippery food items, such as live seafood, from large food safe containers;
For having only one available hand to use when engaging with container contents;
For placing long or top-heavy objects into containers, while trying to balance said objects;
To avoid touching an unsanitary container;
To avoid touching an extremely hot or extremely cold container;
To avoid touching a hazardous or reactive container;
For tying down the container when it is top-heavy;
For having a lower grab-point of the container when flipping a heavy container over;
For two or more people needing to lift a container on their shoulders;
For needing general tie down locations, beyond possible handles on container rims at the top of a container;
For adding poles or through-bars to foot-handhold orifices;
For hanging a container upside down to dry or to remove contents.
To have clamp locations at the bottom of a container and other uses not currently thought of or expressed.
Without foot-handholds that allow a single user to hold the bottom bucket in place with foot or feet, or two users to hold a container down, or one or two users to grip the foot-handholds, a single user is left to stabilized container by placing said container between the user's knees or feet, bang container against other objects to loosen contents or lid, flip container on its side and sit on the container to hold it in place while extracting contents, lids, or beings, or to call upon a second user to help with operation. Needless to say, this can be unsanitary, messy and unsafe, potentially resulting in container damage. For example, a user may be working with hot potash container and may not be able to remove the lid without the aid of her feet to hold down container. Often, when such above scenario exists, a user is forced to place the bucket between her knees and squeeze her knees together in hopes of securing the bucket while removing the lid. The jostling of this activity creates micro movements, which, when lid is lifted, spews a plume of ash rising into the user's face. If done while hot, legs can get burned while squeezing or when embers spill out due to the forceful nature of removing such a tight fitting lid. A user in a very cold climate will not be able to manipulate a container, such a metal bucket, without severe pain to the hands as there may not be enough friction to hold the container if there are no foot-handholds. A user may have to sit on a container to remove a second nested container. In all scenarios, a spill-out potential of contents often occurs, which can be messy and potentially hazardous. Two feet in different x and y planes are the best solution to steadying a container, and the additional benefit of handholds provide a more functional container overall.
For disabled persons, having footholds will prove useful if the disability is related to one or both arms. For users carrying a bag to the outdoor trash bin, being able to step into the footholds to lift the lid with one hand while holding the trash bag with the other becomes integral. In some instances, having footholds frees up both hands for easier use. Nestable containers are the most common shape of portable containers since shipping and storing of two or more container frees up floor or shelf space in trucks, warehouses, homes, and businesses. Because of this, nestable containers are the preferred embodiment that contains foot-handholds. The foot-handhold combination near, directly above, or directly below a container's floor solves the nesting-separation issues created by the friction between two or more nested containers. A single user employing foot-handholds with his feet can separate the containers alone or with a second person employing the foot-handhold the containers with his or her hands. While this is addressed in the original application Ser. No. 16/390,304 Hetzel, the ideal configuration or preferred embodiment is in the foot-handhold pairing being in the same z-axis but in different x- and y-axis in a sloped, portable container. While footholds are shown in x or y planes in the original Hetzel drawings, it was not explicitly stated in the claims or in the specifications, but rather implied. By foot-handholds being in separate wall planes when two feet of a single user are engaged, the user avoids the tipping effect toward the user that occurs when using only a single foot or when using two footholds in the same plane. Additionally, while some footholds can act as handholds, they don't always solve the problem of tipping as in Boover U.S. Pat. No. 5,690247. The addition of various grips, like an upward indent, a two-orifice through-grab, or a handle bar grip, give current Hetzel footholds more function with the addition of hand utility.
Finally, the foot-handhold orifices in the perimeter walls of the base portion of a container, as defined in Hetzel's claims 17-20 FIGS. 6A-6F, 7A-7D, creates a base portion that is a bit higher than current base portions designed on the market today. This increased height in the base portion is needed to accommodate a plurality of footholds. A wider or higher container would have to be made to make up for volume loss created by the additional height in the base portion. A change to the floor shape will mitigate this problem and provides structural integrity to the floor as byproduct. Depending on floor corrugation, the container's base portion and floor can support the container together.
The current patents are known to provide a plurality of recesses around the rim of the bottom wall of a container to receive the forward part of the foot or feet of a user above a floor. For example, U.S. Pat. No. 4,666,054 to Jaicks issued May 19, 1987, where bottom recesses allow a user to hold the container with one or both feet while screwing the lid. However, Jaikes and all other cited patents do not have walls adjacent to the final floor, which extend past the floor to make a base portion below said floor. This appears only in Hetzel's application (pending 6-1016/390,304) figures and claims. Furthermore, Jaikes does not include the handhold element described herein. While Jaicks' design solves this issue, Jaick's patent does not address or detail this issue specifically.
Timm's U.S. Pat. No. 5,803,303 is useful for two users but does not avoid the tipping effect caused by a single operator, as a single user cannot use both feet in this configuration. Hetzel's application (pending 16/16/390,304) addresses two feet of a single user in the claim and all previous figures, and if not obvious, is claimed again. In addition to what was claimed in the previous application, these continuation-in-part footholds now double as handholds in all embodiments. Finally, since Hetzel's application (FIGS. 6-10 of pending 16/16/390,304) already work as a handhold, these foot-handhold features will be an improvement by a new feature of a corrugated floor in which the higher corrugated sections of the floor will wrap over the foothold and return towards the ground, keeping the foot-handhold outside of the containers content space. This results in a structural improvement to the base portion as well, if the lower portion of the corrugated floor is in contact with the ground.
What is needed to improve upon Hetzel's above the floor wall foothold design is to add a smaller bottom orifice (7) into the enclosed foot-handholds' floor. This will result is a foothold that doubles as a handle, wherein fingers can go through the foothold's orifice in the sidewall and bend downwards, extending through the smaller enclosed floor orifice which has been cut out of the floor in this region. The fingers and thumb would be able to interlace, wrapping securely around the foot-handhold.
In the case of an upward indent design 7, such as FIG. 3A, the floor of the footholds in the enclosed orifice below the bin becomes a grab-point. The indent can be slight as to just receive the users fingertips.
Thirdly, a bar can be added to a foot-handhold enclosure in lieu of side and floor wall. By removing the sidewall and floor in just the enclosure area, there is now place for a bar to be inserted. The enclosure cavity will contain a bar at the intersection of the floor and wall, in the plane as the floor. This handle can have a grip that can spin around the bar for rotational purposes of the bin. This handle is similar to Ulfner and Bitsch, but for the dual purpose of a hold down and to use as a handle, and not for garbage truck mechanical purposes.
The purpose of the first three new embodiments is to provide a container with foot-handholds that allows a user to stabilize the container with one foot or the preferred embodiment of both feet to avoid container tipping, and at the same time providing a handhold all while not obstructing the nesting of containers.
In the last embodiment offered, the floor of the container is molded above the orifice foot-handholds in such a manner so as to reduce height of the container and not reduce volume within.
When the foot-handholds are simple orifices, they can go below the floor in a base portion upon which a container rests or directly above the floor upon which a container rests. When above a solid container, the wall orifices must be enclosed within the container to avoid spill-out of contents since the orifice is directly above the floor of the container.
In all cases, a plurality of wall orifice foot-handholds are spaced in pairs around the bottom sidewalls of the container as a function of container shape, such that at least two footholds present themselves for use at the same time for both feet of a single operator or two or more feet or two or more operators, located directly above the floor of the container.

Claims

1. A portable container configured to hold material, comprising of;

a floor upon which said container rests;

at least one wall having a lower portion attached to the circumference of said floor,

so as to establish an enclosed area for holding material above said floor, and;

at least two wall orifice footholds, cut out of said wall directly above the floor in the same z plane, spaced around a periphery of said wall at different x and y axis of said container, each configured to receive the distal ends of at least two feet of one person for full or partial weight transference from the operator, for the purpose of container stabilization and;

each said wall orifice has a corresponding concave enclosure encapsulating said orifice, projecting within said container holding material area, attached to interior side of said wall above and along sides of the said orifice and dropping vertically to said floor and attaching to said interior floor for the purpose of covering the distal end of the users foot.

2. The container of claim 1 wherein at least one wall comprises a plurality of walls.

3. The container of claim 1 wherein a plurality of orifice footholds are oppositionally placed in said wall locations for the purpose of two or more operators' feet.

4. wherein the container of claim 2 has a secondary, smaller and narrower floor orifice cut out from the floor within the container orifice enclosure for the purpose of creating a grab-through for a user hand of both orifices within the orifice enclosure, creating a foot-handhold.

5. wherein the container of claim 3 has a secondary, smaller and narrower floor orifice cut out from the floor within the container orifice enclosure for the purpose of creating a grab-through for a user hand of both orifices within the orifice enclosure, creating a foot-handhold.

6. wherein container of claim 2 has an upwards indent in said enclosures' floor for the purpose of a fingertip friction grab, creating a foot-handhold.

7. wherein container of claim 3 has an upwards indent in said orifice enclosures' floor for the purpose of a fingertip friction grab, creating a foot-handhold.

8. wherein the container of claim 2 has said foothold enclosures within the container with the removal of the exterior floor and wall material in the foothold enclosures, resulting in a cavity within each foothold enclosure with an added bar running parallel and in contact with the ground connected at the most exterior left and right floor and wall intersections, creating a foot-handhold.

9. wherein the container of claim 3 has said foothold enclosures within the container with the removal the exterior floor and wall material in the foothold enclosures, resulting in a cavity within each foothold enclosure with an added bar running parallel and in contact with the ground connected at the most exterior left and right floor and wall intersections, creating a foot-handhold.

10. wherein the container of claim 8 has grip material encapsulating said bar.

11. wherein the container of claim 9 has grip material encapsulating said bar.

12. A portable container configured to hold material, comprising of;

a floor;

at least one wall having a lower portion attached to the circumference of the said floor, so as to establish an enclosed area for holding material above said floor, wherein at least one wall extends below the floor establishing a base portion upon which the container rests, and;

at least two wall orifice footholds, cut out of said wall below the floor, in the same z plane, spaced around a periphery of said wall at different x and y axis of said container, each configured to receive the distal ends of at least two feet of one person for full or partial weight transference from the operator, for the purpose of container stabilization.

13. The container of claim 12, wherein at least one wall comprises a plurality of walls.

14. The container of claim 12, wherein a plurality of orifice footholds are oppositionally placed in said wall locations for the purpose of two or more operators' feet.

15. The container of claim 13, has a corrugated floor which rises and falls around said wall orifice foot-handholds to keep said orifice below and not within content area of container.

16. The container of claim 14 has a corrugated floor which rises and falls around said wall orifice foot-handholds to keep said orifice below and not within content area of container.

17. A portable mesh container configured to hold material, comprising of;

a floor upon which container rests;

at least one wall having a lower portion attached to the circumference of said floor, so as to establish an enclosed area for holding material above said floor, and;

at least two wall orifice footholds, cut out of said wall directly above the floor, in the same z plane, spaced around a periphery of the said wall, at different x and y axis of said container, each configured to receive the distal ends of at least two feet of one person for full or partial weight transference from the operator, for the purpose of container stabilization.

18. The container of claim 17, wherein at least one wall comprises a plurality of walls.

19. The containers of claim 17, wherein a plurality of orifice footholds are oppositionally placed in said wall locations for the purpose of two or more operators' feet.