Embodiments of the present invention generally relate to air pumps, and, more particularly, to air pumps for inflating bicycle tires.
In order for a bicycle to operate effectively, the air pressure in the tires of the bicycle should be maintained at a certain level. Over time and over the course of use, bicycle tires leak air such that the air pressure in the tire decreases to an undesirable level. Therefore, bicycle users frequently need to refill the air in the tires of their bicycles with an air pump. Such bike pumps include a piston rod positioned in a tube body with a hose extending from the tube body. A handle is connected to the piston rod, and the hose has a head with a nozzle that is configured to engage the air valve on a bike tire. The bike user uses the handle to push the piston rod up and down in the tube body, and, as the piston rod moves down, the piston pushes air from the tube body through the hose to the hose nozzle. The hose nozzle delivers the air to the bike tire valve and inflates the bicycle tire with air.
While many bicyclists have their own portable bike pump which they keep at home or take with them on rides, “public” bicycle pumps exist that are configured to be secured to the ground outdoors along bike paths or at parks, bike stations, or shops so that many different bicyclists can use the pump.
Conventional bicycle pumps typically are lightweight and not made of particularly robust materials. The handle, piston rod, and tube body are typically made of plastic, and the hose is typically made of rubber. Therefore, bicycle pumps, especially public pumps mounted outdoors, can wear out and break quickly from use and the elements. For example, the bike pump handle often breaks easily, and the hose can easily be detached from the tube body or perforated. In addition, the hose is typically connected to the body of the pump by pressure fittings, so it is easy to detach from the pump. Moreover, because many of the parts of a conventional bicycle pump are integrally formed together as a single plastic piece, it is not easy to disassemble the bike pump or remove or replace individual parts of the bike pump. For example, the piston rod and the handle may be integrally formed as a single plastic piece, but if only the handle becomes damaged, both the piston rod and the handle need to be replaced. In fact, sometimes when an individual bike pump component does break or wear out, the whole pump must be replaced with a new pump because the component cannot be easily replaced.
Certain embodiments of the present invention provide a pump for inflating tires with air. The pump includes a body having a base and a top portion. The base is configured to be anchored to the ground, and the top portion is detachably connected to an upper plate in the body by fasteners. The pump includes a handle assembly that includes a piston rod, handle bar, and cap that are detachably connected to each other by a fastener. The pump includes a tube positioned in the body and that extends through the upper plate. The tube slidably receives the piston rod and is connected to an air line. The pump includes a hose that is connected to the air line and that extends from the body. The hose has a head configured to engage the nozzle of a tire. When the piston rod is moved downward within the tube, air is displaced from the tube and through the air line to the hose such that the head dispenses air.
The pump may further include a pressure gauge that is threadably mounted to the upper plate and that is positioned beneath the top portion. The top portion includes a transparent portion positioned over the gauge. The gauge has a face and a cover that define a chamber therebetween, and oil is located in the chamber.
The air line may include (a) a first air line that is connected at a first end to a barbed fitting extending from the tube and that is connected at a second end to a check valve, and (2) a second air line that is connected at a first end to the check valve and that is connected at a second end to an adaptor connected to the hose.
The pump hose may be threadably connected to an adapter that is connected to the air line. The pump hose may be made in part of threaded metal.
The piston rod may include a piston head on which is mounted two flexible gaskets that each form a seal with an interior wall of the tube.
The pump handle assembly may include rubber grips that are slidably mounted to the handle bar.
The head of the hose may magnetically connect to the body.
Certain embodiments of the present invention provide a pump for inflating tires with air. The pump includes a body having a base and a top portion. The base has a hole configured to receive an anchor to secure the base to the ground, and the top portion is detachably connected to an upper plate in the body by fasteners. The pump includes a handle assembly including a piston rod, handle bar, and handle cap that are detachably connected to each other by a fastener. The pump includes a tube positioned in the body and extending through the upper plate. The tube slidably receives the piston rod and is connected to an air line. A hose is connected to the air line and extends from the body. The hose has a head configured to engage the nozzle of a tire. The pump includes a pressure gauge that is detachably mounted to the upper plate and positioned beneath the top portion. The pressure gauge is connected to the air line. When the piston rod is moved downward within the tube, air is displaced from the tube and through the air line to the hose such that the head dispenses air and the pressure gauge displays the pressure of the air in the air line.
Certain embodiments of the present invention provide a pump for inflating tires with air. The pump includes a body having an upper portion and a lower portion, wherein the lower portion includes a base plate that is configured to be secured to the ground by an anchor. The lower portion of the body has a greater outer diameter than the upper portion. The pump includes a handle assembly having a piston rod, handle bar, and handle cap that are detachably connected to each other by a fastener. The pump includes a tube positioned in the upper portion of the body. The tube is slidably received in the piston rod. The pump includes an air line positioned in the lower portion of the body. The air line is connected to the tube at one end and connected to an adapter at another end. The pump includes a hose that is connected to the adapter and that extends from the lower portion of the body. The hose has a head configured to engage the nozzle of a tire. When the piston rod is moved downward within the tube, air is displaced from the tube and through the air line to the hose such that the head dispenses air.
Before the embodiments of the invention are explained in detail, it is to be understood that the invention is not limited in its application to the details of construction and the arrangement of the components set forth in the following description or illustrated in the drawings. The invention is capable of other embodiments and of being practiced or being carried out in various ways. Also, it is to be understood that the phraseology and terminology used herein are for the purpose of description and should not be regarded as limiting. The use of “including” and “comprising” and variations thereof is meant to encompass the items listed thereafter and equivalents thereof as well as additional items and equivalents thereof.
The pump 10 includes a handle assembly 58. The handle assembly 58 includes a handle bar 62 having two grips 66 attached thereto. The grips 66 can be slidably attached with adhesive to and removed from the handle bar 62 by maintenance staff. The handle bar 62 extends through, and is detachably connected to, a cylindrical handle cap 70. The handle bar 62 is detachably connected to the cap 70 by a tamper resistant fastener 74 such as a bolt or screw. The handle assembly 58 is shown in the “down” position wherein the cap 70 is pushed down to the top portion 22 of the pump 10. By way of example only, the handle bar 62 and handle cap 70 are both made of steel, aluminum, or some other metal, and the grips 66 are made of a hard polymer or rubber material.
A flexible hose 26 is connected to a first adapter 28 that extends from the body 14 of the pump 10 through a gap 36. A head 30 with a nozzle 34 is connected to the hose 26 by a second adaptor 38. By way of example only, the hose 26 may be 36 or 48 inches long and made of rubber covered with stainless steel braiding. The adapters 28 and 38 may be made of brass or another kind of metal. The nozzle 34 is configured to be used with a bicycle tire valve to fill the tire with air; however, the nozzle 34 can also be configured to fill other inflatable objects with air. The head 30 may be made of or include a magnetic material such that the head 30 can be magnetically connected to the metal pump body 14.
A barbed fitting 118 extends from the bottom of the tube 90. A first air line 122 extends from the fitting 118 to a check valve 126 that extends from the interior wall 98 of the body 14. A second air line 130 extends from the check valve 126 to a three way barbed fitting 134 that extends from the interior wall 98 of the body 14. A third air line 138 extends from the three way barbed fitting 134 to a barbed fitting 142 connected to the pressure gauge 50, which is mounted to the top plate 92. A fourth air line 146 extends from the three way barbed fitting 134 to a barbed fitting 150 that is connected to the first adapter 28. The air lines 122, 130, 138, and 146 may be made of rubber, and the fittings 118, 134, 142, and 150 may be made of steel or aluminum or some other metal.
The top plate 92 also includes a hole 166 that receives the tube 90 when the tube 90 is placed in the body 14. The top plate 92 also supports the pressure gauge 50, which is connected to the barbed fitting 142 that is connected to the third air line 138 (
With respect to the piston rod 78, the piston 102 has grooves 178 on the circumference thereof to receive the gaskets 110. Silicone grease may be applied to the gaskets 110 once the gaskets 110 are attached to piston 102. Another O-ring 182 is placed between the piston 102 and the rod 78 when the piston 102 is connected to the rod 78 to form a seal between the piston 102 and rod 78. The piston 102 is secured to the rod 78 by the shoulder screw 106, which is secured by a set screw 186 that extends through the body of the rod 78.
With respect to the handle assembly 58, the cap 70 includes horizontal holes 190 for receiving the handle bar 62 and a vertical hole 194 for receiving the screw 74. The handle bar 62 also includes a vertical hole 202, and the rod 78 includes a threaded bore 206 hole.
With reference to
The third air line 138 is connected to the barbed fitting 142 and the three way barbed fitting 134, and the fourth air line 146 is connected to the three way barbed fitting 134 and the barbed fitting 150. The second air line 130 is connected to the check valve 126 and the three way barbed fitting 134, and the first air line 122 is connected to the barbed fitting 118 and the check valve 126. Sealant and/or hose clamps may be used to attach the air lines to the barbed fittings. The hose 26 is threadably connected to the head 30 by the adapter 38, and the adapter 28 of the hose 26 is threadably connected to the barbed fitting 150 in the body 14. The adapter 38 can extend through the gap 36 into the body 14 of the pump 10 so that a person cannot reach the adapter 38 to unscrew it from the barbed fitting 150. Sealant may be used to threadably connect the adapters 28 and 38 to the hose 26.
The piston rod 78 with the piston 102 attached thereto is inserted into the tube 90 and then the bushing 96 is slid down along the piston rod 78 until the bushing 96 is positioned inside of and on top of the tube 90. The bushing 96 is then secured to the tube 90 by the screw and washer assembly 174. The gasket 54 is positioned on the gauge 50, and the top portion 22 and top plate 24 are then secured to the top plate 92 by the connectors 16.
The handle assembly 58 is assembled by inserting the handle bar 62 through the horizontal holes 190 in the cap 70 such that the hole 202 in the handle bar 62 is vertically aligned with the hole 194 in the cap 70. The screw 74 is inserted into the aligned holes 194 and 202 and then the cap is positioned on the rod 78 such the screw 74 can be threaded into the bore hole 206 of the rod 78 to fasten the cap 70 to the rod 78. The grips 66 are then slid on to the handle bar 62 and held in place on the handle bar 62 by glue or other adhesive.
Once the pump 10 is assembled, the pump 10 can be secured to a ground or floor surface by anchors, such as bolts, that are inserted through the holes 42 of the base 18 into the ground. By way of example only, the pump 10 can be secured to the ground at a park, bike station, or store or along a trail.
With respect to
In particular, the bicyclist places at least one hand on the grips 66 of the handle assembly 58 and moves the piston rod 78 up and down in the direction of Arrows A and B (
The displaced air then travels through the first air line 122 and the check valve 126 into the second air line 130. Once the air has passed through the check valve 126, the air cannot go back through the check valve 126 into the first air line 122. Therefore, the air pressure in the second, third, and fourth air lines 130, 138, and 146 increases and, because the air cannot go back through the check valve 126 or through the gauge 50, the air travels through the fourth air line 146 into the hose 26 and into the bicycle tire. The air pressure in the bicycle tire increases, as does the pressure in the second, third, and fourth air lines 130, 138, and 146, and this increase in air pressure is shown by the gauge 50. The user continues to move the piston rod 78 up and down in this manner until the gauge 50 shows that the pressure in the system, and thus the tire, has reached a desirable level. The user then disengages the nozzle 34 form the bicycle tire valve and magnetically connects the head 30 to the body 14 of the pump 10.
The pump 300 has a tube 340 that is similar to the tube 90 of
With reference to
In operation, a bicyclist connects the head 332 of the pump 300 to the valve of a bike tire. The bicyclist then uses at least one hand to grip the handle assembly 324 and move the handle assembly 324 up and down in the direction of Arrows A and B. As the bicyclist pulls the handle assembly 324 up in the direction of Arrow A, air is drawn into the tube 340 below the piston (
The various pump embodiments 10, 300, and 400 may be configured to be used to inflate any number of other inflatable objects besides bicycle tires and can be used in any number of different locations. The pump embodiments of the present invention are made of robust and durable materials and components that provide for greater component lifespans even though the pumps are located outside and are exposed to the elements and repeated use by numerous different bicyclists. For example, many of the components are made of steel or aluminum and the hose includes metal braiding and is threadably connected to metal adapters to prevent the hose from easily being detached or damaged. Moreover, the pumps are easy to disassemble, and many of the components are removable. Therefore, if an individual component does wear out or break, the component can easily be removed and replaced without the need to replace the entire pump. For example, the hose, air lines, handle, and air gauge can all easily be removed and replaced by maintenance staff with special tools for tamper resistant hardware. The pumps may also include user friendly features such as an oil-filled pressure gauge that does not fog up and a pump head that can be magnetically connected to the pump body.
While various spatial and directional terms, such as top, bottom, lower, mid, lateral, horizontal, vertical, front and the like may used to describe embodiments of the present invention, it is understood that such terms are merely used with respect to the orientations shown in the drawings. The orientations may be inverted, rotated, or otherwise changed, such that an upper portion is a lower portion, and vice versa, horizontal becomes vertical, and the like.
Variations and modifications of the foregoing are within the scope of the present invention. It is understood that the invention disclosed and defined herein extends to all alternative combinations of two or more of the individual features mentioned or evident from the text and/or drawings. All of these different combinations constitute various alternative aspects of the present invention. The embodiments described herein explain the best modes known for practicing the invention and will enable others skilled in the art to utilize the invention. The claims are to be construed to include alternative embodiments to the extent permitted by the prior art.
Various features of the invention are set forth in the following claims.
This application is a Continuation of, and claims priority to, U.S. patent application Ser. No. 16/404,403, filed on May 6, 2019, which is a Continuation of, and claims priority to, U.S. patent application Ser. No. 15/683,174, filed on Aug. 22, 2017, which is a Continuation of, and claims priority to, U.S. patent application Ser. No. 14/485,311, filed on Sep. 12, 2014. U.S. patent application Ser. Nos. 14/485,311, 15/683,174, and 16/404,403 are incorporated herein by reference and made a part hereof.
Number | Date | Country | |
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Parent | 16404403 | May 2019 | US |
Child | 17547699 | US | |
Parent | 15683174 | Aug 2017 | US |
Child | 16404403 | US | |
Parent | 14485311 | Sep 2014 | US |
Child | 15683174 | US |