A temperature-regulating apparatus is provided to rapidly cool a beverage to a desired temperature. In some variations, the geometry of the temperature-regulating apparatus is configured to rapidly cool a beverage incorporating one or more inner portions that contain a temperature regulating material, such as a phase change material having a high heat capacity. The geometry of the interior of the container may be configured to aid in rapid heat transfer between the beverage therein and the outer shell of the inner portion and may have a length to width aspect ratio of at least 4:1. The inner portion may be formed between the exterior wall of the container and by a single piece of formed metal that extends along the length, width and base walls to form the interior for receiving a beverage. The cavity formed between the outer shell and the exterior wall may be at least 15 mm deep.

An insulating container can be configured to retain a volume of liquid, and include a canister having a first inner wall having a first end having an opening extending into an internal reservoir, and a second outer wall forming an outer shell. The opening can be sealed by a spout adapter, the spout adapter having a spout channel extending between the internal reservoir and a spout opening, smaller than the opening of the canister. The spout opening may be sealed with a cap having a magnetic top surface, and the spout adapter may be further removably coupled to a lid that may be used as a cup into which a volume of the liquid can be poured.

An insulating container can be configured to retain a volume of liquid, and include a canister having a first inner wall having a first end having an opening extending into an internal reservoir, and a second outer wall forming an outer shell. The opening can be sealed by a spout adapter, the spout adapter having a spout channel extending between the internal reservoir and a spout opening, smaller than the opening of the canister. The spout opening may be sealed with a cap having a magnetic top surface, and the spout adapter may be further removably coupled to a lid that may be used as a cup into which a volume of the liquid can be poured. In addition, spout adapter assembly with an adapter that releasably attaches to the canister and a plug that is received within the adapter that moves to place the spout adapter assembly into an open and a closed orientation. The plug may have a means to provide tactile feedback to a user that the spout adapter assembly is in an optimal pouring condition.

In a vacuum insulating container, an outer cylinder has a first annular wall that extends radially inward so as to be inclined with respect to an aperture plane of the outer cylinder at an open end of the outer cylinder and has a tip end part spaced apart from an outer peripheral surface of the inner cylinder; an inner cylinder has a second annular wall that extends radially outward so as to be inclined with respect to the aperture plane of the inner cylinder at an open end of the inner cylinder and faces the first annular wall; and an annular sealing member formed of an elastic body having a low thermal conductivity is compressed between the first annular wall and the second annular wall.

An insulating container can be configured to retain a volume of liquid, and include a first inner wall having a first end having an opening extending into an internal reservoir, and a second outer wall forming an outer shell. The second outer wall can include a second end configured to support the container on a surface. The second outer wall can include a dimple, and the dimple can include a circular base and an inner portion converging to an hole extending into the second outer wall. The hole can be sealed by a resin, and the circular base can be covered by disc formed of the material. Alternatively, a cap can cover the dimple, and a weld can connect the cap to the second outer wall. The container can also include a sealed vacuum cavity forming an insulated double-wall structure between the first inner wall and the second outer wall.

A shock-proof mineral container and mounting structure thereof, which provides a heat insulation container with a liner formed using mineral material. The liner is provided with shock-proof protection and a mounted assembly structure. During the process of assembling the single ended suspended configuration, a blocking member having an elastic effect is inter-connected between an annular neck configured on the mineral liner and an upper link opening joined to an outer cylinder, and the elastic strain of the blocking member is used to absorb shock waves occasionally produced by an external force when carrying the container, thereby safeguarding the structural safety of the hard and brittle mineral liner. In addition, the structure is supplemented with a cylinder liner, which adds to the heat insulation capacity of the container and maintains the stability of the mineral liner.

Methods and equipment to apply a decorative surface on a building panel wherein the surface includes a mix of fibres, binders, wear resistant particles and pigments. Layers may be applied as separate layers with equipment that applies essentially only one of the materials in the surface mix. A method of forming a surface layer on a substrate, the method including forming a first layer of a first material, applying a second layer of a second material on the first layer, mixing the first and second layers into a mix comprising the first and the second material, and applying the mix on a substrate for forming a surface layer.

A primary beverage container includes a container body (102) and a container end (230). The container body includes an outer wall (104) and an inner wall (106). The outer wall defines an outer cavity (116), and the inner wall defines an inner cavity (122) with an opening (124) at a top end (108) of the container body. The inner wall is positioned within the outer cavity such that between the top end and a bottom end of the container body, the inner wall is spaced apart from the outer wall within the outer cavity. The container end is joined to the top end of the container body and covers the opening of the inner cavity.

A 128 oz. stainless steel/glass/plastic water bottle novel assembly where the bottle consists of a standard mouth lid including a container, a cap mounted to an upper end of the container and has holes therein connected to a straw leading to the lower end of the bottle, and a handle which is attached to the bottle assembly. A double-walled insulation mechanism with gel within the walls to maintain the temperature of liquid for a longer period of time.

A smart infusion water bottle is disclosed. The infusion water bottle comprising a body comprising an open end at a top portion for allowing a liquid to flow in and out therethrough and an infusion chamber configured to be removably secured to the top portion of the body, and receive a flavoring material, wherein the infusion chamber comprises a plurality of openings at a bottom portion of the infusion chamber, to allow the liquid to flow in and out of the infusion chamber. The infusion water bottle further comprises a lid removably secured to a top portion of the infusion chamber, wherein the lid comprises a temperature sensor coupled to the infusion chamber and downwardly extending therefrom to the body, a display positioned on a surface of the lid and a controller operatively connected to the temperature sensor and the display, wherein the controller is configured to receive signals from the temperature sensor indicative of the temperature inside the infusion chamber and the body, and output temperature information on the display.