High-efficiency double-intake air pump

Abstract

Disclosed is a high-efficiency double-intake air pump, comprising a motor, a connector, a housing and a power assembly, and a lower horseshoe-shaped diaphragm, a lower case of a piston chamber, an upper case of a piston chamber, an upper horseshoe-shaped diaphragm, a disk-shaped air nozzle and an air nozzle protection disk, which are provided in the front end of the housing and are connected in series successively and cooperatively in an axial direction, wherein the front end of the motor is arranged in the rear end of the housing via the connector, the air nozzle protection disk is fixedly connected to the end face of the housing, and the power assembly comprises wave-shaped cam and couples of double-ended pistons. The air pump has an artful and compact design structure, high operation efficiency, and a low noise.

Claims

1. A high-efficiency double-intake air pump, comprising: (i) a motor, a housing and a power assembly, and (ii) a lower valve plate, a lower case of a piston chamber, an upper case of a piston chamber, an upper valve plate, a disk-shaped air nozzle and an air nozzle protection disk, wherein the air nozzle protection disk is fixedly connected to an end face of the housing; wherein an output end of the motor is arranged in a rear end of the housing via a connector; the upper valve plate and the lower valve plate are respectively provided with an air intake control diaphragm and an air outlet control diaphragm corresponding to and in cooperation with air inlets and air outlets in the upper case of the piston chamber and the lower case of the piston chamber; wherein a plurality of air intake grooves are defined in a side wall of the housing; wherein a central cylinder is arranged at a center of an upper end face of the lower case of the piston chamber and at a center of a lower end face of the upper case of the piston chamber respectively, wherein a plurality of piston cylinders are arranged on a circumference centered around the central cylinder; wherein piston chamber air inlets and piston chamber air outlets are defined, corresponding to the piston cylinders, in a lower end face of the lower case of the piston chamber and an upper end face of the upper case of the piston chamber; wherein a hollow pillar is further arranged on the lower case of the piston chamber, wherein a vent of a ventilation duct of the hollow pillar is arranged at the lower end face of the lower case of the piston chamber, wherein the piston chamber air outlet of the lower case of the piston chamber is in communication with a lower-end air path of the ventilation duct; wherein the upper end face of the upper case of the piston chamber is provided with a central air cylinder that works together with the upper valve plate to form a central air chamber; wherein an upper end of the hollow pillar extends upwardly and inserts into a seat hole of the ventilation duct of the hollow pillar corresponding to the upper case of the piston chamber, and wherein an opening of the upper end of the hollow pillar is in communication with the central air chamber via an internal through hole; wherein the piston chamber air outlet of the upper case of the piston chamber is in communication with the central air chamber; wherein the power assembly comprises a wave-shaped cam and a plurality of double-ended pistons, where the double-ended pistons are movably connected to a circumferential wall of the wave-shaped cam through a sliding slot defined in each of the middle of the double-ended pistons; wherein the wave-shaped cam is arranged in a central chamber composed of the central cylinder of the lower case of the piston chamber and the central cylinder of the upper case of the piston chamber, wherein the wave-shaped cam is connected axially to a motor output shaft; wherein the double-ended pistons are arranged in the piston chamber composed of a piston cylinder of the lower case of the piston chamber and a piston cylinder of the upper case of the piston chamber and move up and down in an axial direction inside the piston chamber when the wave-shaped cam rotates; and wherein the central air chamber outputs air through the disk-shaped air nozzle.

2. The high-efficiency double-intake air pump according to claim 1, wherein a plurality of serpentine noise reduction paths are arranged on an upper end face of the disk-shaped air nozzle, wherein an entrance of the serpentine noise reduction paths is in communication with the plurality of air intake grooves defined in the side wall of the housing, and wherein an exit of the serpentine noise reduction paths is in communication with the corresponding piston chamber air inlets in the upper case of the piston chamber and the upper valve plate.

3. The high-efficiency double-intake air pump according to claim 1, wherein the power assembly comprises five double-ended pistons.

4. The high-efficiency double-intake air pump according to claim 1, wherein the air inlets in the upper case of the piston chamber and the lower case of the piston chamber are finger-type channel air inlets.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 illustrates an exploded structural view of the present invention.

(2) FIG. 2 illustrates a perspective view of a driving structure of the present invention.

(3) FIG. 3 illustrates a perspective view of an upper case of a piston chamber of the present invention.

(4) FIG. 4 illustrates a rear view of FIG. 3.

(5) FIG. 5 illustrates a perspective view of the lower case of the piston chamber of the present invention.

(6) FIG. 6 illustrates a rear view of FIG. 5.

(7) FIG. 7 illustrates an assembly view of the lower case of the piston chamber and the upper case of the piston chamber of the present invention.

(8) FIG. 8 illustrates a perspective view of a lower horseshoe-shaped diaphragm of the present invention.

(9) FIG. 9 illustrates a perspective view of a disk-shaped air nozzle in the present invention.

(10) FIG. 10 illustrates a schematic structural view of air paths of the present invention.

(11) FIG. 11 illustrates an assembly view of the present invention.

LIST OF REFERENCE NUMERALS IN THE FIGURES

(12) Motor 1 Connector 2 Housing 3 Air intake groove 31 Lower case of a piston chamber 4 Hollow pillar 41 Lower piston chamber air inlet 42 Lower piston chamber air outlet 43 Lower piston cylinder 44 Ventilation duct vent of the hollow pillar 45 Lower central cylinder 46 Lower horseshoe-shaped diaphragm 5 Air outlet control diaphragm 51 Air intake control diaphragm 52 Upper case of the piston chamber 6 Seat hole of the ventilation duct of the hollow pillar 61 Upper piston chamber air outlet 62 Upper piston chamber air inlet 63 Internal through hole 64 Central air cylinder 65 Upper piston cylinder 66 Upper central cylinder 67 Upper horseshoe-shaped diaphragm 7 Double-ended piston 8 Sliding slot 81 Wave-shaped cam 9 Disk-shaped air nozzle 10 Serpentine noise reduction paths 101 Noise reduction paths entrance 102 Noise reduction paths exit 103 Air nozzle 104 Air nozzle protection disk 11 Intake air flow 12

DETAILED DESCRIPTION OF THE INVENTION

(13) Reference will now be made in detail to the present embodiments of the invention, examples of which are illustrated in the accompanying drawings. It will be apparent to those skilled in the art that various modifications and variations can be made to the structure of the present invention without departing from the scope or spirit of the invention. In view of the foregoing, it is intended that the present invention cover modifications and variations of this invention provided they fall within the scope of the following claims and their equivalents.

(14) To make the objectives and characteristics of the present invention comprehensive, the embodiments of the present invention are described in details with reference to the drawings. It should be explained that the drawings are simplified and are not in precise proportion, for facilitating the convenient and clear illustration purpose only.

(15) According to the first embodiment, referring to FIG. 1, the present invention relates to a high-efficiency double-intake air pump, which includes a motor 1, a connector 2, a housing 3 and a power assembly, and a lower valve plate 5, a lower case of a piston chamber 4, an upper case of a piston chamber 6, an upper valve plate 7, a disk-shaped air nozzle 10 and an air nozzle protection disk 11, which are provided in the front end of the housing 3 and are connected in series successively and cooperatively in an axial direction, in which the front end of the motor 1 is arranged at the rear end of the housing via the connector 2, and the air nozzle protection disk 11 is fixedly connected to the end face of the housing 3.

(16) Referring to FIG. 2, the power assembly of the present invention includes a wave-shaped cam 9 and five double-ended pistons 8, in which the output shaft of the motor 1 is connected to the wave-shaped cam 9, a middle portion of the double-ended piston 8 is provided with a sliding slot 81, and while implementing connection, the double-ended pistons are hanging on the circumferential wall of the wave-shaped cam 9 with the sliding slots 81 and swing in the axial direction along with the rotation of the wave-shaped cam 9.

(17) Referring to FIG. 3, an upper central cylinder 67 is arranged at the center of the lower end face of the upper case of a piston chamber 6, and five upper piston cylinders 66 are arranged on circumference with the above axis as the center, a seat hole of the ventilation duct of the hollow pillar 61 is arranged between two neighbouring upper piston cylinders 66, and an upper piston chamber air outlet 62 and an upper piston chamber air inlet 63 are arranged at the bottom of the respective upper piston cylinder 66. Referring to FIG. 4, an upper end face of the upper case of the piston chamber 6 is illustrated, in which a central air cylinder 65 is arranged at the center of the upper end face, and the central air cylinder 65 is not in communication with the central cylinder 67 at the back side, the central air cylinder 65 fits with the upper horseshoe-shaped diaphragm 7 to form a central air chamber; an internal through hole 64 is arranged in the side wall of the central air cylinder 65, and the internal through hole 64 is communicated with the upper piston chamber air outlet 62.

(18) Referring to FIG. 5, a lower central cylinder 46 is arranged at the center of the upper end face of the lower case of the piston chamber 4, and five lower piston cylinders 44 are configured, corresponding to the upper piston cylinders 66, on the circumference with the above axis as the center, a hollow pillar 41 is arranged, corresponding to the seat hole of the ventilation duct of the hollow pillar 61, between two neighbouring lower piston cylinders 44, and the front end of the hollow pillar 41 has a notch; a lower piston chamber air outlet 62 and a lower piston chamber air inlet 63 are arranged at the bottom of the respective lower piston cylinder 44. Referring to FIG. 6, the lower end face of the lower case of the piston chamber 4 is provided with a ventilation duct vent of the hollow pillar 45, which is communicated with the air path of the lower piston chamber air outlet 62.

(19) Referring to FIG. 8, the lower horseshoe-shaped diaphragm 5 has five sets of air outlet control diaphragms 51 and air intake control diaphragms 52 corresponding to the lower piston chamber air outlets 62 and the lower piston chamber air inlets 63; the upper horseshoe-shaped diaphragm 7 has five sets of air outlet control diaphragms 51 and air intake control diaphragms 52, which is identical to FIG. 8.

(20) Referring to FIG. 9, an air nozzle 104 is arranged at the center of the upper end face of the disk-shaped air nozzle 10 and is communicated with the central air chamber, a plurality of serpentine noise reduction paths 101 is arranged around the air nozzle 104, the entrance of the noise reduction paths 102 is communicated with the air intake groove 31 of the side wall of the housing, and the exit of the noise reduction paths 103 is communicated with the corresponding piston chamber air inlets 63 in the upper case of the piston chamber and the upper horseshoe-shaped diaphragm.

(21) Referring to FIG. 7, during the installation of the lower case of the piston chamber 4 and the upper case of the piston chamber 6, the hollow pillar 41 of the lower case of the piston chamber inserts into the seat hole of the ventilation duct of the hollow pillar 61 of the lower case of the piston chamber, and the notch of the front end of the hollow pillar 41 is communicated with the central air cylinder 65 of the upper case of the piston chamber through the internal through hole 64; the lower case of the piston chamber 4 after assembled with the upper case of the piston chamber 6, the corresponding lower piston cylinder 44 and upper piston cylinder 66 are assembled to form the piston chamber for installation of the double-ended piston 8; the lower central cylinder 46 and the upper central cylinder 67 are assembled to form the central chamber for installation of the wave-shaped cam 9, the wave-shaped cam 9 rotates inside the central chamber, and the double-ended piston 8 moves up and down inside the piston chamber along with the motion of the wave-shaped cam to compress air.

(22) Referring to FIG. 11, the housing 3 fits with the connector 2 and is formed with five air intake grooves 31 on the side wall of the housing, the air intake grooves 31 are respectively communicated with the air intake control diaphragms 51 of the upper horseshoe-shaped diaphragm 7 and the lower horseshoe-shaped diaphragm 5 through the corresponding serpentine noise reduction paths. Referring to FIG. 10 and FIG. 11, the details of the working processes of the present invention are described as follows. The motor 1 drives the wave-shaped cam 9 to rotates, drives the double-ended piston 8 to move up and down repetitively, so as to carry out the air intake and discharge working processes; when intake the air, the atmospheric air is taken in through the air intake groove 31 defined in the side wall from the bottom of the pump so as to form an intake air flow 12, the air flow after entering the pump is diverged into two paths of air flows, in which one path of air flow enters the corresponding lower piston cylinder 44 via the corresponding air inlet in the lower case of the piston chamber of the air pump, and the other path of air flow enters the corresponding upper piston cylinder 66 via the corresponding air inlet in the upper case of the piston chamber of the air pump; when discharging the air, the air in the upper piston cylinders 66 is pressurized by the double-ended piston 8, then the pressurized air flows are transported through the internal through hole 64 to the central chamber via the air outlet and are jetted through the air nozzles 104; the air in the lower piston cylinders 44 is pressurized by the double-ended piston, and the pressurized air flows enter the ventilation duct vent of the hollow pillar 45, the hollow pillar 41, the notch of the hollow pillar via the air outlet, and eventually, the pressurized air flows are transported to the central chamber via the air outlet through the internal through hole 64 in the upper case of the piston chamber and are jetted through the air nozzles.

(23) In this embodiment, the air inlets in the upper case of the piston chamber and the lower case of the piston chamber are finger-type channel air inlets, which can further reduce the noise.

(24) The air pump has an artful and compact design structure, high operation efficiency, and a low noise, and based on testing, the noise from the air pump disclosed in the present invention does not exceed 55 dBA maximally.