diameter is to hold the knot. This method offers a greater strength than the sewing process because any force is applied directly to the material of the webbing/ribbon and not to the thread used in the sewing process. For the melted-solidified-end, the method uses a double-dimension point of connection. For spheric shape melted-solidified-end, the double diameter as the one for the knot method is used. However, for a linear shape melted-solidified-end, a channel is used to guide the webbing or ribbon to the linear double-dimension point of connection.
The quick release buckle disclosed as part of this invention has been invented using the disclosed methods and it can be made of any size taking into consideration the width and thickness of the webbing or ribbon.
An advantage of the disclosed methods when compared to the standard sewing process, is that the method does not need a sewing machine. This is very convenient especially in remote areas or in an emergency when a sewing machine will not be available.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 shows the front view (on the left), the back view (at the center), and the cross section (on the right) of the double-diameter point of connection (100), identifying the large diameter (110) and the small diameter (120).
FIG. 2 shows the front view (on the left), the back view (at the center), and the cross section (on the right) of the double-diameter point of connection (100) with the melted-solidified-end (510) of the webbing or ribbon (500).
FIG. 3 shows the front view (on the left), the back view (at the center), and the cross section (on the right) of the double-dimension point of connection (200), identifying the large dimension (210) and the small dimension (220).
FIG. 4 shows the front view (on the left), the back view (at the center), and the cross section (on the right) of the double dimension-point of connection (200) with the melted-solidified-end (520) of the webbing or ribbon (500).
FIG. 5 shows the top, bottom, and lateral views of the assembled quick release buckle as the preferred embodiment.
FIG. 6 shows isometric views of the front of the male of the quick release buckle with a double-diameter point of connection.
FIG. 7 shows isometric views of the back of the male of the quick release buckle with a double-diameter point of connection.
FIG. 8 shows isometric views of the front of the female of the quick release buckle with a double-diameter point of connection.
FIG. 9 shows isometric views of the back of the female of the quick release buckle with a double-diameter point of connection.
FIG. 10 shows an isometric view (on the right) of the double-dimension point of connection of the two ends of the quick release (on the left) for the use of a linear melted-solidified-end, identifying the large dimension (210) and the small dimension (220).
DETAILED DESCRIPTION
The quick release buckle, as the preferred embodiment for this invention, has been invented to be used with two methods for attaching a webbing or ribbon to the quick release buckle without the need of sewing the webbing or ribbon.
As in any quick release buckle, the quick release buckle of the present invention has two connecting ends where the webbing or ribbon can be attached to the quick release buckle. For the quick release buckle as the preferred embodiment of this invention, the two connecting ends can accommodate the two attaching methods disclosed. The first method uses a knot which is hold by the double-diameter point of connection (100) as shown in FIG. 1. The small diameter (120) is of such size that allows the webbing or ribbon (500) to pass through it but not the knot (510), while the larger diameter (110) is of such size that allows to hold the knot (510) as shown in FIG. 2. The second method takes advantage that generally webbings and ribbons are made of materials that can be melted, such as nylon, polypropylene, or polyester. Using a flame or a hot iron or ultrasonic welder the end of a webbing or ribbon (500) can be melted to create a linear melted-solidified-end (520) that is thick enough to pass the larger dimension (210) of the double-dimension point of connection (200) but not the small dimension (220). The double-diameter point of connection (100) can also be used with a melted-solidified-end that instead of being linear it is round like a knot. FIGS. 5 through 9 shows the quick release of the present invention with a double-diameter point of connection (100). FIG. 5 shows the top, bottom, and lateral views of the assembled quick release buckle. FIG. 6 shows three different isometric views of the front of the male of the quick release buckle. FIG. 7 shows three different isometric views of the back of the male of the quick release buckle. FIG. 8 shows three different isometric views of the front of the female of the quick release buckle. FIG. 7 shows three different isometric views of the back of the female of the quick release buckle. FIG. 10 shows the same quick release illustrating, within the dash lines, the ends of the male and female that can be substituted by a double-dimension point of connection (200). On the isometric view (on the right) of the double-dimension point of connection (200), the large dimension (210) and the small dimension (220) are identified.
Operation of the Presently Preferred Embodiment
For the first attaching method, the double-diameter point of connection (100) (see FIG. 1) using a knot (510) as shown in FIG. 2, an end of the webbing or ribbon (500) is folded or rolled so that the webbing or ribbon (500) can pass through the small diameter. Once the webbing or ribbon (500) has passed, a knot (510) is made, and the webbing or ribbon (500) is pulled to fit the knot (510) into the large diameter (110) as shown in FIG. 2. When the webbing or ribbon is pulled, the knot (510) cannot pass through the small diameter (120) and the webbing or ribbon (500) is secured to the quick release buckle.
For the second attaching method, the double-dimension point of connection (200) (see FIG. 3) using a thick linear melted-solidified-end (520) as shown in FIG. 4, an end of the webbing or ribbon (500) is passed through the channel made between the large dimension (210) and the small dimension (220). The end of the webbing or ribbon (500) enters the groove of the small dimension (220) and leaves through the groove of the large dimension (210). Once the webbing or ribbon (500) has passed the channel, a thick linear melted-solidified-end is made by melting the material with a flame or a hot iron or ultrasonic welder. Then, the webbing or ribbon (500) is pulled to fit the thick end in the cavity of the channel. When the webbing or ribbon is pulled, the thick melted-solidified-end cannot pass through the small dimension (220) groove and the webbing or ribbon (500) is secured to the quick release buckle.
Patent Application
20220256978
