The present invention relates to a portable air pump and, more particularly, to a portable air pump having a pivotable pressure gage and easy to be assembled.
Generally, portable air pumps have a compact shape for convenience of carrying, but they are difficult to assembly due to their multiple and small-sized components. In addition, in order to achieve a compact appearance, portable air pumps will inevitably lose the convenience during the pumping operation. For example, they usually do not have a pressure gauge that can read the pressure value. The valve connector of the portable air pump is easily obstructed by external objects such as rim spokes to hard to connect the tire and is difficult to read the pressure value after connecting the tire. The operator can only hold the pump body with one hand and hold the handle with the other hand to laborious pumping due to the compact appearance.
Thus, a need exists for a novel portable air pump that mitigates and/or obviates the above disadvantages.
An objective of the present invention is to provide a portable air pump having a pivotable pressure gage and easy to be assembled
A portable air pump according to the present invention comprises an inflation assembly, a head seat, a pressure gauge, a connection assembly, and an axial member. The inflation assembly includes a cylinder and a piston rod moveable relative to the cylinder to compress the air inside the cylinder. The head seat is pivotally connected to the inflation assembly. One end of the head seat is provided with a containing groove, and another end of the head seat is provided with a pedal portion. The pressure gauge is disposed in the containing groove. The connection assembly is pivotally connected to the inflation assembly and adapted to connect with an air-inflatable object. The axial member is mounted through the inflation assembly and the head seat and is connected to the connection assembly. The axial member is provided with an airflow channel communicating with the cylinder, the containing groove, and the connection assembly.
In an example, the head seat is provided with a guiding hole communicating with the containing groove. The axial member is provided with a first passage communicating with the cylinder and a second passage communicating with the containing groove. The first and second passages are communicated with the airflow channel.
In an example, a check valve assembly is disposed in the airflow channel to cause the first passage to unidirectionally communicate with the second passage.
In an example, the check valve assembly includes a check ball and a limit member abutting against the check ball.
In an example, the connection assembly includes an airflow tube, a joint member, and a valve connector. Two opposite ends of the airflow tube are connected to the joint member and the valve connector. The joint member is provided with a first threaded portion. The valve connector is adapted to connect with the air-inflatable object. The axial member defines a distal end and a proximal end opposite to the distal end. The distal end is provided with a second threaded portion threadedly connected with the first threaded portion.
In an example, the distal end is abutted against a seal ring disposed between the joint member and the distal end.
In an example, the cylinder is provided with a first through-hole. The inflation assembly includes a pivoting seat connected to the cylinder and a connection member disposed in the cylinder. The pivoting seat is provided with a second through-hole. The connection member is provided with a third through-hole. The head seat is provided with a pivoting portion disposed between the containing groove and the pedal portion. The pivoting portion is provided with a fourth through-hole. The axial member is mounted through the first, second, third, and fourth through-holes.
In an example, the cylinder is provided with a first pivoting recess communicating with the first through-hole. The pivoting seat is provided with a second pivoting recess communicating with the second through-hole. The connection member is provided with a third pivoting recess communicating with the third through-hole. The pivoting portion is pivotally connected to the first, second, and third pivoting recesses.
In an example, an outer periphery of the axial member is provided with at least one first airtight ring abutting against an inner periphery of the third through-hole, and at least one second airtight ring abutting against an inner periphery of the fourth through-hole.
In an example, the pivoting seat is provided with a shoulder portion formed around an inner periphery of the second through-hole. The joint member is provided with a first stop portion abutting against an outer periphery of the pivoting seat. The proximal end is provided with a second stop portion abutting against the shoulder portion.
In an example, one end of the piston rod is provided with a piston portion moveable relative to the cylinder, and another end of the piston rod is pivotally connected with a handle detachably abutting against an outer periphery of the cylinder.
In an example, the inflation assembly includes a cover member disposed on the cylinder. The piston rod is movably mounted through the cover member. The cover member is provided with a buckle portion detachably attached with the airflow tube.
The present invention will become clearer in light of the following detailed description of illustrative embodiments of this invention described in connection with the drawings.
With reference to
The inflation assembly 10 includes a cylinder 11, a piston rod 12, a pivoting seat 13 connected to the cylinder 11, a connection member 14 disposed in the cylinder 11, and a cover member 15 disposed on the cylinder 11. The piston rod 12 is moveable relative to the cylinder 11 to compress the air inside the cylinder 11. The cylinder 11 is provided with a first through-hole 111 and a first pivoting recess 112 communicating with the first through-hole 111. One end of the piston rod 12 is provided with a piston portion 121 moveable relative to the cylinder 11, and another end of the piston rod 12 is pivotally connected with a handle 122 detachably abutting against an outer periphery of the cylinder 11 to cause the portable air pump being changeable between a compact state and a use state. The pivoting seat 13 is provided with a second through-hole 131, a second pivoting recess 132 communicating with the second through-hole 131, and a shoulder portion 133 formed around an inner periphery of the second through-hole 131. The connection member 14 is provided with a third through-hole 141 and a third pivoting recess 142 communicating with the third through-hole 141. The first, second, and third pivoting recesses 112, 132, and 142 correspond each other. The piston rod 12 is movably mounted through the cover member 15, and the cover member 15 is provided with a buckle portion 151 detachably attached with the connection assembly 40.
One end of the head seat 20 is provided with a containing groove 21, and another end of the head seat 20 is provided with a pedal portion 22. The pressure gauge 30 is disposed in the containing groove 21. The head seat 20 is provided with a guiding hole 23 communicating with the containing groove 21, and a pivoting portion 24 disposed between the containing groove 21 and the pedal portion 22. The pivoting portion 24 is pivotally connected to the first, second, and third pivoting recesses 112, 132, and 142 to cause the head seat 20 being pivotable in relation to the inflation assembly 10. The pivoting portion 24 is provided with a fourth through-hole 241.
The connection assembly 40 includes an airflow tube 41, a joint member 42, and a valve connector 43. Two opposite ends of the airflow tube 41 are respectively connected to the joint member 42 and the valve connector 43, and the airflow tube 41 is detachably attached with the buckle portion 151 of the cover member 15 to cause the portable air pump being changeable between the compact state and the use state. The joint member 42 is pivotally connected to the second through-hole 131 of the pivoting seat 13 and is provided with a first threaded portion 421 and a first stop portion 422 abutting against an outer periphery of the pivoting seat 13. The valve connector 43 is adapted to connect with an air-inflatable object.
The axial member 50 is mounted through the first, second, third, and fourth through-holes 111, 131, 141, and 241 and then is connected to the joint member 42 of the connection assembly 40 to significantly simplify the assembly process. The axial member 50 is provided with an airflow channel 51, a first passage 52 communicating with the cylinder 11, and a second passage 53 communicating with the containing groove 21. The airflow channel 51 communicates with the cylinder 11, the containing groove 21, and the connection assembly 40, and the first and second passages 52 and 53 are communicated with the airflow channel 51. A check valve assembly 54 is disposed in the airflow channel 51 to cause the first passage 52 to unidirectionally communicate with the second passage 53. The check valve assembly 54 includes a check ball 541 and a limit member 542 abutting against the check ball 541. The size of the check ball 541 is configured to fit to block the air airflow channel 51, so that the first passage 52 communicates with the second passage 53 in one direction. The limit member 542 can have a T-shaped cross-sectional shape and be disposed in the airflow channel 51. The axial member 50 defines a distal end 501 and a proximal end 502 opposite to the distal end 501. The distal end 501 is provided with a second threaded portion 55 threadedly connected with the first threaded portion 421 to cause the axial member 50 can be connected to the joint member 42. The distal end 501 is abutted against a seal ring 56 disposed between the joint member 42 and the distal end 501. An outer periphery of the axial member 50 is provided with at least one first airtight ring 57 abutting against an inner periphery of the third through-hole 141, and at least one second airtight ring 58 abutting against an inner periphery of the fourth through-hole 241. In the embodiment, the number of the first airtight ring 57 is one and is adjacent to the first passage 52. The number of the second airtight ring 58 is two, and they are located on two sides of the second passage 53, respectively. The proximal end 502 is provided with a second stop portion 59 abutting against the shoulder portion 133.
Although specific embodiments have been illustrated and described, numerous modifications and variations are still possible without departing from the scope of the invention. The scope of the invention is limited by the accompanying claims.
Number | Date | Country | Kind |
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108215286 | Nov 2019 | TW | national |