Invention for Container and Set for Making the Same

Invented by Nicholas Herling, Marc Heinke

The market for containers and sets for making the same has experienced significant growth in recent years. As people become more conscious of their environmental impact and strive to reduce waste, reusable containers have become increasingly popular. Additionally, the rise of the zero-waste movement and the increasing number of people opting for homemade meals have also contributed to the surge in demand for these products.

Reusable containers offer several advantages over their single-use counterparts. They are not only more sustainable but also more cost-effective in the long run. By investing in a set of containers, individuals can eliminate the need for disposable options, reducing their contribution to landfill waste. Moreover, reusable containers are often made from durable materials such as glass or stainless steel, ensuring they can withstand multiple uses and last for years.

The market for containers and sets for making the same is diverse, catering to various needs and preferences. There are containers specifically designed for storing food, liquids, or even personal care products. These containers come in different sizes, shapes, and materials, allowing consumers to choose the ones that best suit their requirements. Some sets even include specialized compartments or dividers, making it easier to organize and separate different items.

In addition to containers, sets for making the same have also gained popularity. These sets typically include various tools and accessories that enable individuals to prepare their own meals or products from scratch. For instance, a set for making homemade yogurt might include a yogurt maker, containers for storing the yogurt, and a recipe book with instructions. Similarly, a set for making natural beauty products might include essential oils, carrier oils, and containers for storing the final products.

The market for containers and sets for making the same is not limited to individual consumers. Many businesses, particularly in the food and beverage industry, have also recognized the benefits of using reusable containers. Restaurants, cafes, and catering services are increasingly adopting sustainable practices by offering takeout options in reusable containers. This not only reduces waste but also enhances their brand image as environmentally conscious establishments.

As the demand for reusable containers and sets continues to grow, manufacturers have responded by introducing innovative and eco-friendly products. For example, some companies have developed containers made from biodegradable materials, ensuring that even if they do end up in landfills, they will break down over time. Others have incorporated features such as leak-proof lids or stackable designs to enhance convenience and functionality.

In conclusion, the market for containers and sets for making the same has experienced remarkable growth due to increasing environmental awareness and the desire for sustainable alternatives. Reusable containers offer a more sustainable and cost-effective option compared to single-use alternatives. With a wide range of options available, consumers can find containers and sets that cater to their specific needs and preferences. As businesses also recognize the benefits of using reusable containers, the market is expected to continue expanding, providing even more innovative and eco-friendly solutions in the future.

The Nicholas Herling, Marc Heinke invention works as follows

Components as part of a container set are disclosed.” The components of the set can be interchangeably replaced so that different containers can be made. Sets may include an outer container with a first chamber, an inner cavity receivable into the first chamber and having a secondary cavity, a lid attachment removably attached to the outer cavity, an accessory, and a releasable mechanism for attaching the accessory to lid assembly in order to receive the accessory in the first compartment when the lid is attached to outer vessel.

Background for Container and Set for Making the Same

Containers used to store different types of liquids have long been known. Some of these containers are designed to hold beverages. The container can be opened to allow the person to drink the beverage. Some of these beverage containers can be used to store a cold drink or a beverage at the same temperature in the container as the surrounding environment. These containers can be used by athletes or anyone else who is engaged in exercise. A person may use a bottle of beverage during or after a physical activity. These containers are often made from materials like metals or hardplastics, which can withstand moderate impact forces.

Other container types are designed for a specific purpose, such as holding hot drinks. The material that comes into contact with the liquid should be inert even at high temperatures. In the construction of hot beverage containers, glass has been used because it is inert. Many consumers find it desirable to store beverages in glass bottles. Glass is fragile and prone to breaking when it is subjected to impact forces.

It is possible to build a container that can hold hot beverages and is relatively resistant to breakage. In some composite containers, for example, the glass inner vessel may be enclosed within a hard outer casing. The outer hard shell offers some protection to the inner glass vessel. These containers are able to hold both cold and hot beverages in the inner vessel. These containers, due to their construction are good at reducing the rate of loss of heat from hot drinks, and the rate of increase of cold drinks in relation to the ambient temperature. They may be susceptible to breaking, especially when they are used in environments where people are engaged in physical activities.

Also when designing containers to hold liquids, other design considerations may need to be considered. The challenge of providing a container that can be resealed and used more than once is one example. Containers that use materials that are safe for human/animal health may be equally important, especially in the case of beverage containers.

The improvement of known liquid containers is desired.

The present invention provides a container that includes: an outer vessel with an inner chamber, wherein the inner compartment of the vessel has an opening, and an inner vessel with an inner cavity, wherein the cavity of this vessel also has an opening. Both the inner and outer vessels are configured to receive all or substantially the entire inner vessel by way of an opening in the outer cavity into the outer cavity.

The container of another aspect of this invention comprises: An outer vessel with a bottom surface for supporting the outer vessels, an interior cavity defined by at least a part by the inner surface on a sidewall, and an internal cavity in the inner chamber of the vessel. Both the outer and inner vessel are configured to receive all or substantially the entire inner vessel by the top of the vessel, and both the inner and outer vessels can be positioned in a manner that allows the lid of the outer and inner vessel to be easily removed.

The lid has an internal cavity and is used to enclose the interior cavity of outer vessels when the vessel is not inside the outer one.

The method includes: “(i) filling up the interior vessel with hot or cold beverages; (ii), inserting the inside vessel into outer vessel through opening into inner cavity; and (iii); securing lid to hold inner vessel in inner cavity.

A container kit is provided by another aspect of this invention. It includes: an outer vessel with a first opening and a cavity; an inner vessel with a second opening and cavity; an inner accessory configured to fit into the first opening so that the second opening is located near the first opening. The lid assembly can be attached to the outer surface of the vessel using a removable attachment mechanism. This allows for a selected one from the many interchangeable inner vessels to be attached to the lid. A container kit is provided by another aspect of this invention. It includes: an outer vessel with a first opening and a cavity; an inner vessel with a second opening and a cavity; an interchangeable accessory set that can be attached to the lid; an interchangeable accessory that has an opening in its second cavity; an interchangeable accessory that is releasably attached to the lid; an interchangeable accessory that is releasably attached to the lid; an interchangeable accessory that is releasable

The container kit is another aspect of this invention. It comprises: an outer vessel with a first cavity, an outer opening; and an infusion device having a wall that defines a second opening and a second chamber, the infusion device configured to be received and supported through the opening of the outer vessels, and the wall having a plurality holes in fluid communications with the second cavity. A lid assembly, which includes an accessory retainer, is designed to be removable attached to the outer opening to seal it; and an accessory, which has a retention element, a retainer, a

The container is designed to have an outer vessel with a first cavity, an outer vessel’s opening and an inner-vessel opening. It also has a pad that includes a wall that defines a pocket for the bottom of the inner-vessel, as well as at least one shock-absorbing element beneath the inner-vessel when it is inserted in the pocket.

The container kit includes: a lid that is removable from the outer vessel and an accessory. A releasable mechanism is used to attach the accessory to lid assembly so that it is received into the first opening when the lid is attached to outer vessel.

The following description and accompanying figures of embodiments of this invention will reveal other aspects and features to those with ordinary skill in the arts.

Referring first to FIG. In FIG. In FIG. In FIG. Container 100 can consist of an outer vessel 101 and an inner vessel 200, as well as a lid, a lid grip, band, tea strainer, base pad, seal spout, 700, cap, 800, etc.

The container 100 disclosed herein has several important features, including: (a), an outer vessel that can provide a level of protection to the inner vessel from impact forces; (b), the ability to choose materials for both the inner and outer vessels according to different design parameters or at least ones which do not overlap completely. While the materials used for the inner and outer vessels can be selected to be safe for liquids intended for human or animal consumption, an outer vessel may be chosen that is more resistant to impact than the inner vessel.

Inner vessel 201 can be selected as safe and suitable for storing liquids that are at temperatures significantly higher or lower than the typical ambient temperature (e.g. For storing hot or iced beverages, outer vessel 101 is suitable for both.

Referring to FIGS. Outer vessel 101, which is shown in FIGS. 2A-2D will provide a strong and durable protective shell for container. The outer vessel 101 may be constructed from any material that is suitable for the function described in this document.

Suitable outer vessel materials may be selected based on one or more, or a combination of other additional physical and chemical properties including, for example, odour resistance, heat and chemical resistance including hydrolytic stability, transparency/translucency and visual clarity, touch feel (flexibility), weight, durability, costs, availability and ease of processing and handling. The potential for toxicity or danger to users or the environment during use or disposal may also be considered.

Polymers such as polyesters and polyolefins, including copolymers are suitable outer vessel materials. The outer vessel can contain polyolefins, copolyesters (such as high-density and low-density LDPE), polypropylenes, polycarbonates, polyacrylates, such as poly(methylmethacrylate), polystyrenes, polyvinylchloride (PVC), polybutylene terephthalate, and derivatives thereof.

A suitable copolyester material may contain terephthalic acid (TA), naphthalenedicarboxylic acid and ethylene glycol, and a catalyst metal, as described in U.S. Pat. No. The entire content of Patent No. 5,851,612 is hereby incorporated by reference. Co-polyesters may be formed from monomers such as dimethyl terephthalate (DMT), tetramethyl cyclobutanediol, and cyclohexanedimethanol. See, for example, the teachings in U.S. No. No.

Click here to view the patent on Google Patents.


Comments

Leave a Reply

Your email address will not be published. Required fields are marked *