Conventional telescoping straws typically include at least a first pipe and a second pipe received in the first pipe, where a structure of the first pipe directly engages a structure of the second pipe in a sliding relationship between a slid forward position and a slid back position. It is a current problem in conventional telescoping straws to reliably maintain a functional seal between the first pipe and the second pipe at a sliding point of contact between the first pipe and the second pipe.
Because the first pipe and the second pipe of conventional telescoping straws engage each other directly, the material forming each of the first pipe and the second pipe must be sufficiently rigid so as to maintain a structural integrity of the connection between the first pipe and the second pipe. However, employing such sufficiently rigid materials for the first pipe and the second pipe is not advantageous for maintaining an effective seal at the sliding point of contact between the first pipe and the second pipe. Consequently, conventional telescoping straws lack an adaptive structure between the first pipe and the second pipe that would enable incorporating relatively flexible materials in a telescoping straw design for improving the quality of a seal therebetween.
In view of the foregoing, an extendable straw includes a relatively smaller diameter tube, a relatively larger diameter tube, and a collar. The relatively smaller diameter tube includes a radially enlarged section adjacent one end. The relatively larger diameter tube receives the relatively smaller diameter tube and is more flexible than the relatively smaller diameter tube. The radially enlarged section of the relatively smaller diameter tube contacts and seals against an inner surface of the relatively larger diameter tube. The collar is connected at a non-drinking end of the relatively larger diameter tube, the collar being more rigid than the relatively larger diameter tube and receiving the relatively smaller diameter tube. The relatively smaller diameter tube is movable in an axial direction with respect to both the collar and the relatively larger diameter tube. At least one of the collar and the relatively larger diameter tube cooperates with the radially enlarged section of the relatively smaller diameter tube to inhibit further axial movement of the relatively smaller diameter tube with respect to the collar beyond an extended position.
In addition, a method of assembling the extendable straw includes connecting the collar to the non-drinking end of the relatively larger diameter tube. The method further includes inserting the relatively smaller diameter tube through the relatively larger diameter tube and the collar such that the proximal end of the relatively smaller diameter tube is disposed extending axially from the first end of the collar, and the distal end of the relatively smaller diameter tube is disposed extending axially from the second end of the collar. The radially enlarged section is disposed within the relatively larger diameter tube between the collar and the drinking end of the relatively larger diameter tube. The relatively larger diameter tube has the narrowed portion extending from the inner surface adjacent the drinking end of the relatively larger diameter tube through which the radially enlarged section of the relatively smaller diameter tube cannot pass.
It should, of course, be understood that the description and drawings herein are merely illustrative and that various modifications and changes can be made in the structures disclosed without departing from the present disclosure. Referring now to the drawings, wherein like numerals refer to like parts throughout the several views,
The relatively smaller diameter tube 102 includes a proximal end 112 (see
In the illustrated embodiment, the relatively smaller diameter tube 102 is made from a material that is more rigid than the material from which the relatively larger diameter tube 104 is made. In the illustrated embodiment, the relatively smaller diameter tube 102 is made from metal and the relatively larger diameter tube 104 is made from food grade silicone. Alternatively, the relatively smaller diameter tube 102 can be made from a rigid plastic or another material that is more rigid than the material from which the relatively larger diameter tube 104 is made. If desired, the relatively smaller diameter tube 102 and the relatively larger diameter tube 104 can be made from the same material rigid so long as the material is rigid enough so as not to collapse when retracting the relatively smaller diameter tube 102 into the larger diameter tube 104.
With reference to
The relatively larger diameter tube 104 includes a narrowed portion 140, which is formed by at least one protrusion 142 provided near the drinking end 120 in the illustrated embodiment. As shown, the at least one protrusion 142 extends radially inwardly from a main inner surface 144 of the relatively larger diameter tube 104 adjacent the drinking end 120 of the relatively larger diameter tube 104. The at least one protrusion 142 could be provided elsewhere, e.g., offset from the drinking end 120 towards the non-drinking end 122. The at least one protrusion 142 can be a ridge disposed circumferentially and extending radially inwardly from the main inner surface 144 of the relatively larger diameter tube 104. In this manner, the narrowed portion 140 narrows a diameter and a lateral cross section (taken normal to the longitudinal axis 108) of the relatively larger diameter tube 104. The narrowed portion 140 defines a narrowed portion inclined face 150 directed radially inward with respect to a longitudinal axis 108 in a direction going from the non-drinking end 122 toward the drinking end 120.
Extending from the non-drinking end 122 toward the drinking end 120, the relatively larger diameter tube 104 includes a counterbore 152 (
The collar 106 has a first end 162 and a second end 164 located opposite the first end 162. The collar 106 includes an internal surface 166 and an outer surface made up of a proximal outer surface section 170, a distal outer surface section 172, and a shoulder 174 that is normal to the longitudinal axis 108 and connects the proximal outer surface section 170 and the distal outer surface section 172. As shown, the shoulder 174 radially extends from the proximal outer surface section 170 of the collar 106 with respect to a radial direction of the collar 106. In this manner, the shoulder 174 forms and end of a necked down portion 180 of the collar 106 extending from the first end 162 of the collar 106 to the shoulder 174. When assembled, the necked down portion 180 of the collar 106 is received in the counterbore 152 and is retained in the counterbore 152 via a friction fit, weld or adhesive between the counterbore inner surface 156 and the proximal outer surface section 170. Alternatively, the collar 106 can connect to the non-drinking end 122 of the relatively larger tube 104 by overmolding the relatively larger tube 104 onto the collar 106.
The relatively smaller diameter tube 102, the relatively larger diameter tube 104, and the collar 106 are assembled to form the extendable straw 100. When assembled, an outer surface 182 of the relatively larger diameter tube 104 is flush with the distal outer surface section 172 of the collar 106 to provide a smooth and ergonomic hand feeling to a user employing the extendable straw 100. The relatively larger diameter tube 104 receives the relatively smaller diameter tube 102 such that the proximal end 112 of the relatively smaller diameter tube 102 is disposed within the relatively larger diameter tube 104 between the drinking end 120 and the non-drinking end 122 of the relatively larger diameter tube 104, and more particularly between narrowed portion inclined face 150 and the first end 162 of the collar 106. In this manner, the relatively smaller diameter tube 102 is movable between a retracted position (
An apex 184 (e.g., a location offset farthest from the longitudinal axis 108) of the outer surface 130 in the radially enlarged section 124 of the relatively smaller diameter tube 102 contacts and seals against the main inner surface 144 of the relatively larger diameter tube 104. The seal created between the radially enlarged section 124 and the relatively larger diameter tube 104 can be watertight and so as to enable use of the relatively smaller diameter tube 102 and the relatively larger diameter tube 104 together as a drinking straw. Because the main inner surface 144 of the relatively larger diameter tube 104 has a constant diameter between the narrowed portion 140 and the inner surface step 154, the seal is functional for a drinking straw when the relatively smaller diameter tube 102 is positioned at any location along the relatively larger diameter tube 104 between the extended position and the retracted position.
The sealing force causing the seal between the relatively smaller diameter tube 102 and the relatively larger diameter tube 104, and coefficient of friction between the radially enlarged section 124 and the main inner surface 144 of the relatively larger diameter tube 104 provide a static friction force. The static friction force is small enough for a user to comfortably adjust a position of the relatively smaller diameter tube 102 with respect to the relatively larger diameter tube 104 between the extended position and the retracted position. Also, the static friction force is large enough to reliably hold the relatively smaller diameter tube 102 in a position with respect to the relatively larger diameter tube 104 between the extended position and the retracted position.
The collar 106 is received in the counterbore 152 of the relatively larger diameter tube 104 and extends from the non-drinking end 122. The collar 106 also receives the relatively smaller diameter tube 102. With this construction, the relatively smaller diameter tube 102 is movable in an axial direction between the extended position and the retracted position with respect to both the collar 106 and the relatively larger diameter tube 104. The collar 106 cooperates with the radially enlarged section 124 of the relatively smaller diameter tube 102 to inhibit further axial movement of the relatively smaller diameter tube 102 with respect to the collar 106 beyond the extended position.
Notably, the internal surface 166 of the collar 106 has a longitudinal length and radial proximity to the outer surface 130 of the relatively smaller diameter tube 102 sufficient to maintain axial alignment between the collar 106 and the relatively smaller diameter tube 102. As a result, when the relatively smaller diameter tube 102 is inserted in the collar 106, the proximal end 112 of the relatively smaller diameter tube 102 is disposed extending axially from the first end 162 of the collar 106, and the distal end 114 of the relatively smaller diameter tube 102 is disposed extending axially from the second end 164 of the collar 106. Because the collar 106 is more rigid than the relatively larger diameter tube 104, the collar 106 can be better adapted for maintaining axial alignment between the relatively smaller diameter tube 102 and the relatively larger diameter tube 104, and can also be better adapted for maintaining a structural integrity of the extendable straw 100 regarding connecting the relatively smaller diameter tube 102 and the relatively larger diameter tube 104.
As shown, the relatively larger diameter tube 104 receives the necked down portion 180 of the collar 106 and the shoulder 174 abuts the non-drinking end 122 of the relatively larger diameter tube 104. A longitudinal distance between the non-drinking end 122 and the inner surface step 154 coincides with a longitudinal length of the necked down portion 180 such that the relatively larger diameter tube 104 also receives the necked down portion 180 of the collar 106 with the inner surface step 154 of the relatively larger diameter tube 104 abutting the first end 162 of the collar 106.
The collar 106 and the relatively larger diameter tube 104 may be reconfigured such that the collar 106 receives the relatively larger diameter tube 104 therein, without departing from the scope of the present disclosure. Also, either or both the inner surface step 154 and the shoulder 174 may be reconfigured to obstruct relative axial movement between the relatively larger diameter tube 104 and the collar 106 beyond an assembled position of the relatively larger diameter tube 104 and the collar 106.
A portion of the first end 162 of the collar 106 extends radially inward beyond the main inner surface 144 of the relatively larger diameter tube 104 at the inner surface step 154. The relatively larger diameter tube 104 engages the collar 106 such that the main inner surface 144 of the relatively larger diameter tube 104, the first end 162 of the collar 106, and the internal surface 166 of the collar 106 together form a narrowed section, which is opposite to the narrowed portion 140, that is configured to inhibit further axial movement in the direction of arrow E of the relatively smaller diameter tube 102 with respect to the relatively larger diameter tube 104 and the collar 106 beyond the extended position.
With reference to
The radially enlarged section 124 is configured to form an interference fit with the main inner surface 144 of the relatively larger diameter tube 104. Because the relatively larger diameter tube 104 is also more flexible than the relatively smaller diameter tube 102, the radially enlarged section 124 deforms the main inner surface 144 of the relatively larger diameter tube 104 where the radially enlarged section 124 contacts the relatively larger diameter tube 104, improving the seal between the relatively smaller diameter tube 102 and the relatively larger diameter tube 104.
A method of assembling the extendable straw 100 will be described next. The order of steps can differ from the order that each step is described below. The method includes connecting the collar 106 to the non-drinking end 122 of the relatively larger diameter tube 104. The method further includes inserting the relatively smaller diameter tube 102 through the relatively larger diameter tube 104 and the collar 106 such that the proximal end 112 of the relatively smaller diameter tube 102 is disposed extending axially from the first end 162 of the collar 106, and the distal end 114 of the relatively smaller diameter tube 102 is disposed extending axially from the second end 164 of the collar 106. The radially enlarged section 124 is disposed within the relatively larger diameter tube 104 between the collar 106 and the drinking end 120 of the relatively larger diameter tube 104. As mentioned above, the relatively larger diameter tube 104 has the narrowed portion 140 extending from the main inner surface 144 adjacent the drinking end 120 of the relatively larger diameter tube 104 through which the radially enlarged section 124 of the relatively smaller diameter tube 102 cannot pass.
The collar 106 can be permanently affixed, e.g., glued to the relatively larger diameter tube 104. Connecting the collar 106 to the non-drinking end 122 of the relatively larger diameter tube 104 can include inserting the necked down portion 180 of the collar 106 into the relatively larger diameter tube 104 until the first end 162 of the collar 106 abuts the inner surface step 154 of the relatively larger diameter tube 104, or the non-drinking end 122 of the relatively larger diameter tube 104 abuts the shoulder 174 of the collar 106. Connecting the collar 106 to the non-drinking end 122 of the relatively larger diameter tube 104 could also be accomplished by overmolding the relatively larger tube 104 onto the collar 106.
It will be appreciated that variations of the above-disclosed embodiments and other features and functions, or alternatives or varieties thereof, may be desirably combined into many other different systems or applications. Also that various presently unforeseen or unanticipated alternatives, modifications, variations or improvements therein may be subsequently made by those skilled in the art which are also intended to be encompassed by the following claims.
Number | Name | Date | Kind |
---|---|---|---|
4340175 | Danek | Jul 1982 | A |
4657182 | Hoshi | Apr 1987 | A |
4736887 | Inaba | Apr 1988 | A |
4850533 | Hoshi | Jul 1989 | A |
6585170 | Katsukawa | Jul 2003 | B2 |
7997509 | Karklins | Aug 2011 | B2 |
10123641 | Pepper | Nov 2018 | B1 |
20020166990 | Yang | Nov 2002 | A1 |
20060255169 | Gieson | Nov 2006 | A1 |
20120160928 | Jo | Jun 2012 | A1 |
20200008599 | Price | Jan 2020 | A1 |
20210045558 | Aveles, Jr. | Feb 2021 | A1 |
Number | Date | Country | |
---|---|---|---|
20210244217 A1 | Aug 2021 | US |