Patent Grant
10472137
The present case claims the benefit of Canadian patent application No. 2,985,510 filed on 14 Nov. 2017, which application is hereby incorporated by reference in its entirety.
The technical field relates generally to vented spouts for liquid-storage containers.
Many different kinds of spouts have been proposed over the years for use during a gravity transfer of liquids from a container into a receptacle, such receptacle being for instance another container or a tank, to name just a few examples. Some of these spouts include an air vent to admit air inside the container through the spouts when the liquid flows, and also a shutoff valve to control the liquid flow during the transfer. Examples can be found, for instance, in U.S. Pat. Nos. 8,403,185 and 8,561,858.
While most of the prior arrangements have been generally useful and convenient on different aspects, there are still some limitations and challenges remaining in this technical area for which further improvements would be highly desirable.
In one aspect, there is provided a vented pouring spout for a liquid-storage container, the spout including: a first member including: an elongated and generally tubular first main body having a front section and a rear section, the first main body having two segregated and parallel internal passageways, one being an air duct through which an air circuit passes when air enters the container and one being a liquid duct through which a liquid circuit passes when the liquid flows out of the container, the air duct being generally positioned along a top side of the first main body and being smaller in cross section than that of the liquid duct, the liquid duct being substantially straight and substantially unobstructed along the entire first main body, the air duct being substantially straight and substantially unobstructed along the entire first main body up to at least one constricted opening, generally positioned at a rear end of the first main body, from which the air circuit exits the air duct; a valve that is juxtaposed to the rear end of the first main body, the valve having a rear section and a front tapered section extending from the rear section, the rear section of the valve supporting a valve gasket and the front tapered section being made integral with the rear section of the first main body, the front tapered section being adjacent to an inlet of the liquid duct and to the at least one constricted opening; and a protrusion projecting underneath the front section of the first main body; a second member that is shorter in length than the first member, the second member including an elongated second main body, the second main body having a straight tubular inner conduit inside which the rear section of the first main body is slidingly axially movable, the inner conduit having a rear end defining a valve seat that is engaged by the valve gasket when the valve is in a closed position to block the air circuit and the liquid circuit, the valve gasket being out of engagement with the valve seat and being positioned rearward of the valve seat when the valve is in a fully-opened position; an inner gasket provided between the first member and the second member to seal in an air-tight manner an intervening peripheral space between the rear section of the first main body and the inner conduit of the second main body; and a biasing element positioned between the first member and the second member to urge the valve in the closed position.
In another aspect, there is provided a vented spout as shown, described and/or suggested herein.
Further details on these aspects as well as other aspects of the proposed concept will be apparent from the following detailed description and the appended figures.
The spout 100 includes a first member 104 and a second member 106. The first member 104 is longer than the second member 106 and it has a rear section that in a sliding engagement inside the second member 106.
The spout 100 extends mostly in a straight line, between a base 110 and a tip 112, that is parallel to a longitudinal axis 114. The tip 112 corresponds to the front end of the first member 104, thus the end that is away from the base 110. The base 110 is the part of the spout 100 that can be removably attached to the container 102. The base 110 of the illustrated example is circular in shape and is designed to fit over the front edge of the neck of the container 102. The base 110 is slightly larger in diameter than that of the neck. The spout 100 can be secured to the neck, thus to the container 102, using a corresponding collar (not shown) having internal threads matching the external threads on the neck. The collar includes a central opening through which the spout 100 can fit up to the base 110. The collar can then be tightened on the neck of the container 102 until the spout 100 is solidly secured. The spout 100 will extend outside the container 102 and is ready to be used for pouring.
The spout 100 includes a built-in shutoff valve generally positioned at the base 110 and that is normally closed. Hence, the valve remains closed when untouched.
As can be seen, the first member 104 includes a first bottom protrusion 120 projecting underneath the outer wall surface thereof. This first bottom protrusion 120 is only partially visible in
The illustrated first bottom protrusion 120 includes an enlarged front portion, hereafter called the trigger 122, which has a surface at the front that is generally perpendicular to the longitudinal axis 114. It is also slightly curved at the bottom in the example and it is positioned about 1.75 inch (4.5 cm) from the tip 112 in the example. The trigger 122 is where an actuation force can be applied, for instance using a finger, to open the valve inside the spout 100. Other configurations and arrangements are also possible. The valve will open in the illustrated example when the first member 104 axially slides toward the rear with reference to the second member 106.
The second member 106 of the illustrated example includes an elongated external conduit 124 that is longitudinally disposed along the undersurface thereof. This external conduit 124, among other things, holds a biasing element to urge the valve into its normally-closed position. It also serves in the example as an abutment for a child resistant closure (CRC) device 130. This CRC device 130 is provided for preventing young children, particularly children up to six years old, from opening the valve inside the spout 100. The CRC device 130 acts as a fail-safe childproof security system that keeps the spout 100 locked unless a release operation is performed. This CRC device 130 can also automatically resets itself back to the locked position once the valve is minimally opened, for instance of about 10%, just enough for some liquid to flow. Further details on the CRC device 130 will be given later in the present detailed description. Variants are possible. The CRC device 130 can be omitted in some implementations.
The spout 100 of
Furthermore, if desired, the spout 100 of the illustrated example can be positioned almost entirely inside the container 102 when not needed for pouring liquid, for instance during storage or transportation of the container 102. To do so, the spout 100 can be inserted through the neck of the container 102, with the tip 112 first, until the base 110 abuts on the front edge of the neck. The collar can then be tightened on the neck of the container 102 to secure the spout 100 and seal the container 102. Putting the spout 100 inside the container 102 could be desirable for minimizing space, among other things. The cap 116 of the illustrated example can then be install over the opening 132 of the base 110 to double close the spout 100, as shown in
The first member 104 includes an elongated and generally tubular first main body 134 that extends over almost the entire length of the spout 100. Variants are possible. For instance, although the first main body 134 has a generally circular cross section, other shapes and configurations are possible in some implementations. The word “tubular” is used in a generic way and does not imply in itself that the first main body 134 must necessarily always be circular in shape on the outside in every possible implementation. Accordingly, noncircular shapes are possible. This remark also applies to other tubular parts of the spout 100 as well.
The first main body 134 has a front section 136 and a rear section 138. The front section 136 is generally positioned outside the second member 106 while the rear section 138 is generally positioned inside the second member 106 in the normally closed position, as shown in
The first main body 134 includes two segregated internal passageways that are entirely enclosed therein. One is an air duct 146 and the other is a liquid duct 148. They are both separated from one another along the entire length of the first member 104 up to the valve 140 at the rear end. The air duct 146 is generally positioned along a top side of the first main body 134 and is smaller in cross section than that of the liquid duct 148. The cross-section area of the air duct 146 is about 30 times smaller than that of the liquid duct 148 in the example. Variants are possible as well.
Portable containers, such as those commonly available for transporting and storing for fuel products, generally include an auxiliary vent opening. This auxiliary vent opening is relatively small in size and is normally closed by a corresponding treaded cap or the like. It is provided for releasing built-in pressure inside the containers or to admit air when pouring liquids using non-vented spouts. Such auxiliary vent opening should remain completely closed when pouring liquid using the vented spout 100. Nevertheless, the spout 100 can still be used even if the auxiliary vent opening is partially or fully opened but the user will then miss a desirable feature thereof. For the sake of simplicity, the rest of the present detailed description will assume that air can only enter the container 102 through the vented spout 100 during pouring.
The valve 140 is an integral part of the first member 104 in the illustrated example. It is juxtaposed to the rear end of the first member 104 and is immediately upstream of the entrance of the liquid duct 148. The valve 140 has a main body. It also includes an enlarged rear section 154 and a front tapered section 156 extending from the rear section 154. The front tapered section 156 has a somewhat conical shape that facilitates the flow of liquid towards the interior of the liquid duct 148 when the valve 140 is opened. Nevertheless, other configurations and arrangements are possible.
The rear side of the valve 140 includes a rear-facing open cavity 158 devoid of passageways to the opposite side thereof. This cavity 158 is only provided to minimize the amount of plastic resin material during manufacturing. Nevertheless, the rear side of the valve 140 can be configured differently and the cavity 158 can even be entirely omitted in some implementations.
When the spout 100 of the illustrated example is closed, as shown in
Furthermore,
When a liquid must be poured from the container 102 and this container is, for instance a portable container, the container 102 will tilted by a user up to a point where the liquid contacts the rear face of the spout 100 if the valve 140 is still closed. The user can also open the valve 140 beforehand so that the liquid reaches the valve 140 while it is already opened. The liquid will then start flowing out of the spout 100 passing through an internal liquid circuit extending from the valve 140 to the tip 112 of the spout 100. However, many users will generally prefer tilting the container 102 first and opening the valve 140 afterwards, particularly if the liquid level inside the container 102 is high. Among other things, the tip 112 of the spout 100 must often be positioned at a specific location to prevent spillage, for instance be in the immediate proximity or be inside an opening of a receptacle in which the liquid is transferred. An example of such receptacle includes a reservoir or tank located on a machine or on a vehicle. The receptacle can also be another container. Many other situations and contexts exist.
When liquid is present on the rear side of the spout 100 while the valve 140 is still closed, the user must eventually open the valve 140, either partially or fully, for the liquid to flow. Liquid will start flowing around the valve 140, between the valve gasket 160 and the valve seat 162 when the valve 140 is moved rearwards over a sufficient distance relative to the valve seat 162. The liquid will then enter the liquid duct 148 but will not enter the air duct 146 because, among other things, the air will come out of the constricted opening 180 at an increased velocity.
It should be noted that the valve seat 162 can be designed to prevent the valve 140 from opening below a certain minimum distance, for instance 0.1 inch (2.5 mm). This will prevent some liquid to enter the liquid duct 148 if the tip 112 simply hits an object, such as when the container 102 is tilted and the user is now positioning the tip 112 prior to the liquid transfer. Variants are possible.
The front tapered surface 156 of the valve 140 in the illustrated example includes a slanted and/or curved surface 184 generally positioned at the top part, immediately in front of the outlet of the constricted opening 180. This surface 184 differs from the other parts of the front tapered surface 156 in that it is provided specifically for guiding the air and facilitating the flow of air during pouring when the container 102 is tilted. The other parts are rather designed to funnel the liquid at the inlet of the liquid circuit when the liquid enters the liquid duct 148 during pouring. Furthermore, it was found that having a very smooth finish on the surface 184 can improve the air flow at the end of the air circuit during pouring and, as a result, improves the liquid flow. Smaller bubbles will form in the liquid when the surface 184 has a smoother finish compared to a regular standard finish. When the first member 104 is made of plastic, the surface in the mold forming the surface 184 can be specifically machined so as to have a surface finish with an extremely high (mirror-like) smoothness, such as A-1 (grade #3 diamond buff) or A-2 (grade #6 diamond buff) on the SPI (Society of the Plastic Industry) finish guide. This enhanced finish will only be provided for the surface 184 to keep the costs down and it is not a finish routinely used in such context. Nevertheless, other configurations and arrangements are possible as well. It can also be omitted in some implementations.
In use, the position of the constricted opening 180, because it is part of the first member 104, will always follow the position of the valve 140. Hence, when the valve 140 is fully opened, the constricted opening 180 of the illustrated example will be positioned beyond the rear edge of the opening 132 of the base 110.
It should be noted that the exact configuration and arrangement of the parts can be different in some implementations from what is shown in the figures.
As can be seen in
There are two spaced-apart annular guiding elements 192, 194 in the illustrated example. They will remain inside the second member 106 regardless the position of the valve 140 is opened. The annular guiding element 194 is positioned closer to the rear end than the annular guiding element 192. They both have a relatively large and smooth outer surface, as well as somewhat rounded lateral edges to facilitate the relative axial sliding motion between the first member 104 and the second member 106. The illustrated first member 104 further includes a longitudinally-disposed guiding element 196 extending along a given length towards the front of the spout 100 along the top of the first main body 134. The rear end of this longitudinally-disposed guiding element 196 merges with the annular guiding element 192 in the illustrated example. The longitudinally-disposed guiding element 196 has a relatively large and smooth outer surface that is slightly curved in cross section to match the curvature of the inner wall surface inside the second member 106. The front end of the longitudinally-disposed guiding element 196 can extend beyond the front edge of the second member 106, as can be seen for instance in
The illustrated first member 104 further includes an annular groove 198 located between the annular guiding element 194 and the valve 140. This groove 198 is made within the outer wall surface of the first main body 134 to receive a corresponding inner gasket. This inner gasket is provided to seal the intervening peripheral space between the first member 104 and the second member 106 in an air-tight manner. Further details on this arrangement will be given later in the present detailed description. Other configurations and arrangements are possible as well.
Still, the illustrated first member 104 further includes a second bottom protrusion 200 projecting from the outer wall surface underneath the first main body 134. The second bottom protrusion 200 is only partially visible in
As best shown in
Still,
As can be appreciated, the restrictions to the flow of liquid are also very low in the illustrated example, thereby maximizing the liquid output when the valve 140 is fully opened.
When the first member 104 is manufactured using an injection molding process of a plastic resin material, a pin is provided within the mold to form the sidewall 222 and the rear end of the air duct 146. This pin, however, is generally too small having for internal liquid channels in which a cooling liquid flows during molding. The slender pin, instead, uses one or more internal gas channels in which a pressurized gas, such as air, can continuously flow. It is also supported at both ends to obtain the desired tolerances. It is supported at the rear through the constricted opening 180. Pressurized air can enter at the front end of the pin and be vented out of the mold through rear venting channels. Cooling the pin can significantly decrease the molding cycle time, among other things. Other configurations and arrangements are also possible.
In use, once the container 102 is tilted, or even set up-side down, to pour liquid through the spout 100, the user will open the valve 140 for the liquid to flow by gravity and will maintain it open, for instance until the receptacle is full or when a sufficient amount of liquid was transferred. The user can control and adjust the flow when pouring by actuating the position of the trigger 122 to set the position of the valve 140. The user may, for instance, progressively reduce the flow of liquid when the receptacle is almost full. This is often desirable to prevent spillage. However, it is sometimes difficult to see when the receptacle is full or almost full. Different factors can be involved, such as an insufficient illumination, the opening of the receptacle being hidden by the container 102, by the spout 100 or by other objects, etc. These factors may force the user to pour the liquid at a slower rate or to interrupt the flow frequently to check the level, thereby increasing the time and effort required for completing the transfer and increasing the likelihood of experiencing an undesirable spillage. Still, the user may be distracted for some reason and not realize that the receptacle is now almost full, or may have overestimated the amount of liquid to be added. This also increases the likelihood of experiencing an undesirable spillage. The illustrated spout 100 can mitigate these difficulties.
As aforesaid, some air must enter the container 102 through the air duct 146 during pouring to replace the proportional volume of liquid flowing out of the liquid duct 148. Air will stop entering the container 102 when the flow of liquid stops. However, interrupting the incoming air flow can also cut off the liquid flow shortly thereafter because of the increased negative pressure, relative to the ambient air pressure, above the liquid level inside the container 102. This negative pressure is what causes the air to enter but if no more air is admitted, the increased negative pressure will decrease the flow and eventually stop it.
Now, since the tip 112 of the illustrated spout 100 is where both the liquid outlet and the air inlet are located, the flow of liquid through the spout 100 will automatically decrease and then stop soon after air is prevented from entering the air duct 146. This highly desirable and convenient feature is only possible because of the air-tight seal provided between the first and second members 104, 106. Furthermore, the fact that the valve 140 is located at the base 110 of the spout 100 allow the user to close the valve 140 after the flow stopped by itself and then move the tip 112 upwards without experiencing any spillage, even if the liquid level in the receptacle was at the very maximum limit, since the spout 100 has no residual liquid therein once closed.
In the illustrated example, the biasing element is a single helical compression spring 240 positioned inside the external conduit 124.
All parts of the second member 106 can be molded together using an injection molding process and form a monolithic unitary piece. The illustrated second member 106 is an example of an implementation that can be made using an injection molding process of a plastic resin material. It includes a lateral opening 242 on each side of the external conduit 124, near the rear end thereof, which can be useful when retrieving the second member 106 out of its mold. This feature can be omitted in some implementations.
Still,
The CRC device 130 in
The CRC device 130 of the illustrated example generally includes a front end section 272, a first intermediary section 274, a second intermediary section 276 and a rear end section 278. All sections can be molded together to form a monolithic unitary part. Other configurations and arrangements are possible.
The front end section 272 includes two spaced-apart members 280 that are configured and disposed to fit over the rear supporting element 214 of the first bottom protrusion 120 in a retaining engagement, where they are prevented from moving and pivoting. They allow the CRC device 130 to be set in a cantilevered manner. The exact configuration and arrangement may be different in some implementations.
The first intermediary section 274 is a relatively thinner part compared to the others. It allows the CRC device 130 to bend slightly so that the second intermediary section 276 and the rear end section 278 can be displaced relative to the front end section 272. The first intermediary section 274 acts as a spring. It is made of a highly resistant material, such as a plastic material. Other materials, configurations and arrangements can be used as well.
The second intermediary section 276 is larger in size that the others. It includes a slightly-concave surface 282 at the location where a user must apply the force 270 to set the CRC device 130 to the unlocked position, thus to enable the possibility of moving the valve 140. It is also the part that prevents the valve 140 from being opened when it is in the locked position, for instance as shown in
The rear end section 278 includes a flanged-like element 284 that is attached at one end to the second intermediary section 276. The other end of the flanged-like element 284 is a free end. The rear end section 278 further includes a small projecting portion 286 that is configured and disposed to latch with the front notch 220 (
At the position shown in
Upon releasing the actuation force of the trigger 122, the spring 240 urges the valve 140 back to its normally-closed position and the CRC device 130 will then come out of the external conduit 124. The second intermediary section 276 will be pushed out in front of the cut-out portion 252 and its rear side will abut against the front edge of the cut-out portion 252 exactly at the position where the valve 140 is fully closed. The rear end section 278 also remains hidden inside the external conduit 124. The valve 140 is blocked in its closed position for as long as the user does not press again on the second intermediary section 276 of the CRC device 130 at unlock it once again.
It should be noted that in use, the weight of the container 102 can be supported on the receptacle, for instance by engaging the trigger 122 over the rim of the opening of the receptacle. The weight of the container 102 will compensate, at least partially, the force required to keep the valve 140 opened while pouring. Furthermore, this can be done without touching the CRC device 130 after the spout 100 was unlocked since the actuation force is applied on the trigger 122. This mitigates the risks of inadvertently damaging the CRC device 130. The trigger 122 as configured and disposed in the illustrated example greatly facilitates handling since the container 102 can be held using only one hand. The same hand can be used to unlock the CRC device 130 and to control the position of the valve 140. The user can take the other hand to hold the recipient or for gripping a fixed object while pouring.
As can be seen, the cap 116 of the illustrated example includes a main body 290 having a central section over which a knob 292 is provided. The central section of the main body 290 defines a cavity 294 opened on the bottom side. This bottom cavity 294 is configured and shaped to receive the tip 112 of the spout 100, as shown for instance in
As can be appreciated, the spout 100 as proposed herein can have, among other things, one or more the following advantages:
The present detailed description and the appended figures are meant to be exemplary only, and a skilled person will recognize that variants can be made in light of a review of the present disclosure without departing from the proposed concept.
100 spout
102 liquid-storage container
104 first member
106 second member
110 base (of the spout)
112 tip (of the spout)
114 longitudinal axis
116 cap
120 first bottom protrusion
122 trigger
124 external conduit
130 child resistant closure (CRC) device
132 opening (of the spout base)
134 first main body (of the first member)
136 front section (of the first main body)
138 rear section (of the first main body)
140 valve
142 recess
144 peg
146 air duct
148 liquid duct
150 second main body (of the second member)
152 inner conduit (of the second main body)
154 rear section (of the valve)
156 front tapered section (of the valve)
158 rear-facing open cavity (of the valve)
160 valve gasket (O-ring)
162 valve seat
164 mounting groove (for valve gasket)
170 outer gasket (U-ring)
172 outer peripheral flange
180 constricted opening
182 plenum
184 slanted and/or curved top surface
192 annular guiding element
194 annular guiding element
196 longitudinally-extending guiding element
198 groove (for the inner gasket)
200 second bottom protrusion
202 base portion (of the second bottom protrusion)
204 mounting member
210 opening (adjacent the valve)
212 supporting member
214 rear supporting element (of the first bottom protrusion)
220 front notch
222 V-shaped sidewall
224 front curved surface (under the second bottom protrusion)
230 inner gasket (T-ring)
232 gap
234 projecting part (on the inner gasket)
240 biasing element/spring
242 lateral opening
244 longitudinally-extending lateral wall
246 bottom wall
250 rib
252 cut-out portion
254 slot
260 upper wall section
270 force (to unlock)
272 front end section (of latch member)
274 first intermediary section (of latch member)
276 second intermediary section (of latch member)
278 rear end section (of latch member)
280 spaced-apart member
282 concave surface
284 flanged-like element
286 projecting portion
288 actuation force
290 main body (of the cap)
292 knob (of the cap)
294 cavity (of the cap)
296 bottom annular portion (of the cap)
298 upper annular portion (of the cap)
| Number | Date | Country | Kind |
|---|---|---|---|
| 2985510 | Nov 2017 | CA | national |
| Number | Name | Date | Kind |
|---|---|---|---|
| 886237 | Murtha | Apr 1908 | A |
| 4478242 | Bond | Oct 1984 | A |
| 4564132 | Lloyd-Davies | Jan 1986 | A |
| 4746036 | Messner | May 1988 | A |
| D303634 | Vachon | Sep 1989 | S |
| 4958668 | Vachon | Sep 1990 | A |
| 5107909 | Donovan | Apr 1992 | A |
| 5228487 | Thiermann et al. | Jul 1993 | A |
| 5255713 | Scholle et al. | Oct 1993 | A |
| 5406994 | Mitchell et al. | Apr 1995 | A |
| 5507328 | Donovan | Apr 1996 | A |
| 5560522 | Clark | Oct 1996 | A |
| 5628352 | Gracyalny et al. | May 1997 | A |
| 5711355 | Kowalczyk | Jan 1998 | A |
| 5961001 | Davis et al. | Oct 1999 | A |
| 6155464 | Vachon | Dec 2000 | A |
| 6227419 | Raboin | May 2001 | B1 |
| 6401752 | Blackbourn et al. | Jun 2002 | B1 |
| 6435380 | Raboin | Aug 2002 | B1 |
| 6722535 | Flach | Apr 2004 | B1 |
| 6742680 | Friedman | Jun 2004 | B2 |
| 6968875 | Nielsen | Nov 2005 | B2 |
| 7013936 | Schliemann et al. | Mar 2006 | B2 |
| 7513395 | Labinski et al. | Apr 2009 | B2 |
| 7543723 | Wilford et al. | Jun 2009 | B2 |
| 7621304 | Nielsen | Nov 2009 | B2 |
| 8038035 | Forbis | Oct 2011 | B2 |
| 8113239 | Richards et al. | Feb 2012 | B2 |
| 8201595 | Trippi, Jr. | Jun 2012 | B2 |
| 8403185 | Vachon | Mar 2013 | B2 |
| 8561858 | Vachon | Oct 2013 | B2 |
| 8567646 | Cray | Oct 2013 | B1 |
| 8616419 | Slack | Dec 2013 | B2 |
| 8800826 | Forbis et al. | Aug 2014 | B2 |
| 9493280 | Wilkinson | Nov 2016 | B2 |
| 10308405 | Gaikwad | Jun 2019 | B2 |
| 20120118431 | Dickie | May 2012 | A1 |
| 20140097210 | Wright | Apr 2014 | A1 |
| 20150053725 | Hingorani | Feb 2015 | A1 |
| 20170327281 | Cross | Nov 2017 | A1 |
| 20180037379 | Adam et al. | Feb 2018 | A1 |
| Number | Date | Country |
|---|---|---|
| 00112938 | Jul 1984 | EP |
| 2015052507 | Apr 2015 | WO |
| Number | Date | Country | |
|---|---|---|---|
| 20190144172 A1 | May 2019 | US |
