Patent Application
20150147208
The present invention is generally related to air compressor, and more particular to an air compressor capable of conducting outside cool air through the air compressor through multiple air flow paths for effectively and speedily cooling down the motor and cylinder of the air compressor.
An air compressor is a device that can release compressed and pressurized in quick bursts, and is commonly applied to power pneumatic tools, to pump tires, etc. It therefore has become a necessity for home and auto repairmen.
A major issue for air compressor is the heat produced by its motor and cylinder, and the heat is accumulated over time as the air compressor is continuously operated. If the air compressor is overheated, its performance is deteriorated, or its motor or cylinder is burned down, directly or indirectly affecting the applicability and life span of the air compressor.
The overheating problem is conventionally resolved by configuring a fan on the shaft of the motor. As the motor is actuated, the fan spins to draw in cool air and to dissipate the heat. However, the cylinder of the air compressor is usually not located on the air flow path, and its heat is not dissipated satisfactorily. It is often found that the cylinder is at a much higher temperature than the motor. As the cylinder is effectively cooled down, the overheating problem of the air compressor remains.
Therefore, most users have to stop the air compressor, and wait for a while for the cylinder to cool down before resuming the operation of the air compressor.
In other words, both the cylinder and the motor are heat sources of the air compressor. To resolve the overheating problem, both the cylinder and the motor have to be appropriated dissipated, instead of just one of them.
In addition, conventionally, both the cylinder and the motor are housed in a single casing for reducing their noises. The heat produced by the motor and the cylinder is as such accumulated together, and this is also why the overheating problem is resolved only when both the cylinder and the motor are cooled down altogether.
Furthermore, when the cylinder is overheated, the outlet pipe connected to the cylinder would also have a high temperature. On one head, the outlet pipe's material would deteriorate. On the other hand, the user may be scalded by the outlet pipe or its metallic parts. The released air may also have a high temperature, and the inflated object (such as balloons, air-filled toys) may be damaged as well.
Therefore, a major objective is to provide a novel air compressor capable of conducting outside cool air through the air compressor through multiple air flow paths for effectively and speedily cooling down the motor and cylinder of the air compressor. The air compressor contains a casing member, a driving member, a cylinder member, an inlet pipe, and an outlet pipe. Inside the casing member, there is a hollow first accommodation section, a hollow second accommodation section, and a hollow connection section connecting the first and second accommodation sections. The first accommodation section has a number of first inlets and first outlets. The connection section has a number of second outlets. The driving member is located outside the casing member between the first and second accommodation sections, and is adjacent to the first outlets. The cylinder member is located both in the second accommodation section and the connection section. The inlet pipe has a first end connecting the second accommodation section. The outlet pipe has a first end connecting the cylinder member, and a second end extended outside the casing member. The driving member draws outside cool air into the casing member through the first inlets and engages the cylinder member to release compressed air through the outlet pipe. A portion of the drawn air is released outside through the first outlets, thereby forming a first flow path for cooling down the driving member. Another portion of the drawn air is released outside through the second outlets, thereby forming a second flow path for cooling down the cylinder member and the outlet pipe. In other words, the present invention can achieve enhanced heat dissipation by multiple flow paths through the driving and cylinder members.
Another objective of the present invention is provide a novel air compressor having a partition plate configured inside the connection section extended from an inner wall of the connection section towards the second outlets. A second end of the inlet pipe is configured above the partition plate, and is opened towards the same direction of outside air flow. As such, air drawn into the second end of the inlet pipe is in a direction opposite to outside air flow, effectively avoiding dust particles in the air entering and damaging the cylinder member.
The foregoing objectives and summary provide only a brief introduction to the present invention. To fully appreciate these and other objects of the present invention as well as the invention itself, all of which will become apparent to those skilled in the art, the following detailed description of the invention and the claims should be read in conjunction with the accompanying drawings. Throughout the specification and drawings identical reference numerals refer to identical or similar parts.
Many other advantages and features of the present invention will become apparent to those versed in the art upon making reference to the detailed description and the accompanying sheets of drawings in which a preferred structural embodiment incorporating the principles of the present invention is shown by way of illustrative example.
The following descriptions are exemplary embodiments only, and are not intended to limit the scope, applicability or configuration of the invention in any way. Rather, the following description provides a convenient illustration for implementing exemplary embodiments of the invention. Various changes to the described embodiments may be made in the function and arrangement of the elements described without departing from the scope of the invention as set forth in the appended claims.
As illustrated in
Inside the casing member 1, there is a hollow first accommodation section 11, a hollow second accommodation section 12, and a hollow connection section 13 connecting the first and second accommodation sections 11 and 12. In the present embodiment, the connection section 13 is located above the first and second accommodation sections 11 and 12, and a space is formed outside the casing member 1 beneath the connection section 13 and between the first and second accommodation sections 11 and 12. The casing member 1 has a number of first inlets 14 on a front side of the first accommodation section 11 and a number of first outlets 15 on an opposite bask side of the first accommodation section 11, both connecting the first accommodation section 11 with the outside of the casing member 1. In the present embodiment, the first outlets 15 are positioned adjacent to a bottom edge of the back side of the first accommodation section 11 so that they are distant from the connection section 13. The connection section 13 has a number of second outlets 16 adjacent to the second accommodation section 12. A partition plate 17 is configured inside the connection section 13 adjacent to the first accommodation section 11, and is extended from an inner wall of the connection section 13 towards the second outlets 16.
The driving member 2 contains a motor 21 and a fan 22. The motor 21 is located outside the casing member 1 in the above-mentioned space between the first and second accommodation sections 11 and 12. The motor 21 has a shaft 211. A first end 212 of the shaft 211 is extended into the first accommodation section 11, and a second end 213 of the shaft 211 is extended into the second accommodation section 12. The fan is joined to the first end 212 of the shaft 211 and is housed in the first accommodation section 11.
The cylinder member 3 is located both in the second accommodation section 12 and the connection section 13, and contains a cylinder 31, a connecting rod 32, and a tube 33. The cylinder 31 is located inside the connection section 13 above the second accommodation section 12. The connecting rod 32 has one end joined to a piston 321 and the other end joined to a crank shaft 322. The piston 321 is housed inside the cylinder 31. The crankshaft 322 is housed in the second accommodation section 12 and joined to the second end 213 of the shaft 211. The tube 33 is inside a top cover 30 and connects the cylinder 31. The tube 33 has an outlet 331.
The inlet pipe 4 is located inside the connection section 13. The inlet pipe 4 has a first end 41 connecting the second accommodation section 12, and a second end 42 located above the partition plate 17. The inlet pipe 4 has a curved section as it runs towards the second end 42 and, as such, the send end 42 opens towards the second outlets 16.
The outlet pipe 5 is located inside the connection section 13. The outlet pipe 5 has a first end 51 connecting the outlet 331 of the tube 33, and a second end 52 extended outside the casing member 1.
The air compressor further contains a control member 6 configured on the casing member 1. The control member 6 contains a control circuit 61 electrically connecting the driving member 2, and a control switch 62 for turning the driving member 2 on or off.
The motor 21 of the driving member 2 drives the fan 22 to spin so as to draw outside cool air into the casing member 1. In the meantime, the crankshaft 322 of the motor 21 is rotated and the connecting rod 32 is engaged into an up-down reciprocal motion, thereby actuating the cylinder member 3. As the cylinder member 3 operates, the compressed air produced by the cylinder member 3 is released to outside the casing member 1 through the tube 33, the outlet 331, and the outlet pipe 5.
More specifically, when the fan 22 of the driving member 2 spins as shown in
In other words, the present invention can effectively conduct outside air through the driving member 2 and the cylinder member 3 by multiple flow paths for enhanced heat dissipation so as to avoid problems such as performance drop due to overheating, burning down parts, etc. In addition, as air flow through the connection section 13, the outlet pipe 5 is also cooled.
Please note that the second end 42 of the inlet pipe 4 is positioned above the partition plate 17, and is opened towards the same direction of outside air flow, as shown in
An air compressor according to another embodiment of the present invention is shown in
The cylinder member 3 is located both in the second accommodation section 12 and the connection section 13. The cylinder 31 of the cylinder member 3 is tightly joined to a top portion of the second accommodation section 12, the tube 33 is tightly joined to the connection section 13. In addition, heat dissipating fin channels 311 are configured on the surface of the cylinder 31. Therefore outside cool air flows towards the cylinder member 3 through the connection section 13, and then flows outside the casing member 1 through the heat dissipating fin channels 311, thereby cooling down the cylinder member 3.
While certain novel features of this invention have been shown and described and are pointed out in the annexed claim, it is not intended to be limited to the details above, since it will be understood that various omissions, modifications, substitutions and changes in the forms and details of the device illustrated and in its operation can be made by those skilled in the art without departing in any way from the spirit of the present invention.
