Dual Air Chamber Structure & Method For Using

Abstract

A dual air chamber structure having two independent and air impervious chambers, with each chamber being inflated and deflated by a separate air valve. The inner chamber, except for its air valve, is completely contained by the outer chamber and is comprised of primary horizontal conduit and a plurality of inflatable intermittent vertical posts made of small diameter tubing which are connected by a corresponding plurality of horizontal conduit made of small diameter tubing, such that the inner chamber as a whole is comprised of a repeating series of inflatable vertical posts followed by inflatable horizontal connectors. The outer chamber forms an air impervious bladder around the inner chamber, except for the air valve of the inner chamber.

Claims

1. A dual air chamber device, comprising: An inner chamber comprised of an air valve and a primary horizontal conduit connected to a plurality of intermittent vertical posts having a top and a bottom; An outer chamber comprised of an air valve and an inner surface, wherein the outer chamber forms an air impervious bladder around the inner chamber, except for the air valve of the inner chamber.

2. The dual air chamber device of claim 1, wherein the top and bottom of the plurality of intermittent vertical posts are sealed by the inner surface of the outer chamber.

3. The dual air chamber device of claim 1, wherein the top and bottom of the plurality of intermittent vertical posts are sealed independently of the inner surface of the outer chamber.

4. A dual air chamber device, comprising: a. An inner chamber comprised of an air valve, a primary horizontal conduit, and a secondary horizontal conduit, and a plurality of intermittent vertical posts; b. An outer chamber comprised of an air valve, wherein the outer chamber forms an air impervious bladder around the inner chamber, except for the air valve of the inner chamber.

5. A method for inflating a dual air chamber device, comprising the steps of: a. Opening an air valve on an outer chamber; c. Inflating the inner chamber; d. Closing the air valve of the inner chamber; e. Inflating the outer chamber; f. Closing the air valve of the outer chamber.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0006] FIG. 1 is an external perspective view of the dual air chamber device.

[0007] FIG. 2 is an internal perspective view of the dual air chamber device.

[0008] FIG. 3 is a top view of the dual air chamber device.

[0009] FIG. 4 is a detailed top view of the dual air chamber device.

[0010] FIG. 5 is an internal side view of the dual air chamber device.

[0011] FIG. 6 is a top view of an alternate embodiment of the dual air chamber device.

[0012] FIG. 7 is a top view of an alternate embodiment of the dual air chamber device.

LISTING OF COMPONENTS

[0013] 101Inner Chamber [0014] 103Inner Chamber Air Valve [0015] 104Primary Horizontal Conduit [0016] 105Vertical Post [0017] 105(a)Top of Vertical Post [0018] 105(b)Bottom of Vertical Post [0019] 107Secondary Horizontal Conduit [0020] 109Outer Chamber [0021] 111Outer Chamber Air Valve [0022] 113Outer Chamber Upper Layer [0023] 115Outer Chamber Lower Layer [0024] 117Outer Chamber Single Outer Layer [0025] 119Outer Chamber Inner Surface

DETAILED DESCRIPTION OF THE INVENTION

[0026] Disclosed is a dual air chamber device having two independent and air impervious chambers.

[0027] The inner chamber 101, except for its air valve 103, is completely contained by the outer chamber 109. The inner chamber 101 may be comprised of a primary horizontal conduit 104 and a plurality of inflatable intermittent vertical posts 105 made of small diameter tubing which are connected by a corresponding plurality of inflatable horizontal connectors 107 made of small diameter tubing, such that air is free to flow between the primary conduit 104, vertical posts 105, and secondary horizontal conduits 107. As shown in FIG. 2, the inner chamber 101 as a whole (101, 104, 105, 107) represents a continuous unit such that air may flow freely between the primary horizontal conduit 104, 107. The vertical posts 105 and horizontal conduits (104, 107) may be cylindrical in shape, although other shapes may be used. The angle between the vertical posts 105 and horizontal conduits (104, 107) may vary in alternative embodiments. The diameter and overall size, as well as the density of the vertical posts 105 and horizontal conduits (104, 107) may also vary depending on the particular application of the dual air chamber structure.

[0028] In one preferred embodiment, as shown in FIG. 2, the inner chamber 101 may be comprised of a primary horizontal conduit 104 having a plurality of secondary horizontal conduits 107, each secondary horizontal conduit 107 having a plurality of intermittent vertical posts 105. In another preferred embodiment, as shown in FIG. 6, the inner chamber 101 may be comprised of a snaking fence structure, wherein a primary horizontal conduit 104 contains a plurality of intermittent vertical posts 105. In other preferred embodiments, the structure and or shape of the inner chamber 101 may vary such that each embodiment is defined by a primary and/or secondary horizontal conduits (104, 107) having a plurality of intermittent vertical posts 105.

[0029] The outer chamber 109 is comprised of an upper layer 113 and lower 115 layer, such that the two layers (113, 115) are fused together to form an air impervious bladder. In other preferred embodiments, the outer chamber may be comprised of a single outer layer, sealed to form an air impervious bladder. The outer chamber 109 contains an air valve 111.

[0030] In one preferred embodiment, the inner surface 119 of the outer chamber 109 contacts the top 105(a) and bottom 105(b) of each vertical post 105 of the inner chamber preferred embodiments, the vertical posts 105 of the inner chamber 101 may be sealed independently of the inner surface 119 of the outer chamber 109, such that although the top 105(a) and bottom 105(b) of each vertical post 105 may still come into contact with the inner surface 119 of the outer chamber 109, the inner surface 119 of the outer chamber 109 does not seal the top 105(a) or bottom 105(b) of the vertical posts 105.

[0031] In each preferred embodiment, as the inner chamber 101 inflates, the vertical posts 105 stand up (inflate), thereby providing a mechanism to force the inner surfaces 119 of the outer chamber 109 away from each other. This creates a vacuum effect in the outer chamber 109, which allows air to be drawn into the outer chamber's air valve 111 thereby inflating the outer chamber 109. This allows a user to quickly and easily inflate the dual air chamber structure, without relying on self-inflating means such as open cell foam.

[0032] The inner 101 and outer 109 chambers may be made of any material typical to the industry such as rip-stop nylon, polyester, or a polyurethane material. The air valves (103, 111) for each chamber (101, 109) may be of a type typical to the industry, such as a screw type valve.

[0033] To inflate the device, a user first opens both air valves (103, 111). As the user pushes air into the inner chamber 101, the vertical posts 105 inflate, thereby pushing the walls of the outer chamber 109 away from each other. This creates a vacuum effect in the outer chamber 109 causing air to be drawn through the outer chamber's air valve 111. When the inner chamber 101 is inflated to the user's preference, the user closes the inner A user may add additional air to the outer chamber 109 if desired. Finally, the user should close the outer chamber's air valve 111.

[0034] Those in the art will appreciate that the disclosed technology has a number of possible applications. For example, the inventor envisions the device being incorporated into lightweight sleeping pads and mattresses, other inflatable outdoor items such as kayaks and rafts, and other products with a need for such a technology.