Air compressors are known in the art for supplying a flow of pressurized air for a variety of applications. They often use a motor that repetitively drives a piston to compress the air. As the air is compressed, it is often provided to and stored in a tank from which it can then be dispensed. The tank is typically brought up to a particular pressure by the compressor, at which point, a pressure sensor provides a signal that shuts off the motor. When the pressure in the tank drops to a particular pressure, as sensed by the pressure switch, or the compressor is manually turned on again, the motor will turn back on to continue the flow of pressurized air to the tank.
Typical consumer air compressors provide air pressures of about 200 psi or lower. Some applications, however, may require pressures greatly exceeding 200 psi. For example, paintball guns often have tanks that are filled to very high pressures such as 3000 psi-4500 psi. Similarly, scuba tanks are also filled to very high pressures. Thus, most consumer air compressors are not suitable for high pressure applications.
Furthermore, piston assemblies used for common air compressors utilize an interference fit of metallic sealing ring that is attached to and moves with the piston. Due to the number of cycles that the piston is required to undergo during operation, piston failure, and thus compressor failure, is often attributed to wear experienced by the piston components.
An air compressor is disclosed that can take in air at a particular pressure at the input and compress the air such that it exits an output at a much greater pressure until a desired pressure is reached in a piston assembly, at which point, the air compressor can shut off automatically by moving a switch. A tank does not need to be part of the compressor assembly, and thus, the air compressor is capable of determining the pressure and shutting off at the desired pressure regardless of the particular tank that is removeably connected to the air compressor. The switch can be moved to an off position by an arm pivotally connected to a carriage, and thus, an electronic pressure sensor is not required. The air compressor is relatively inexpensive to manufacture, durable, and easy to maintain. In addition, the air compressor can utilize a piston assembly having a plurality of stationary seals, such as o-rings, for receiving a piston.
An air compressor is disclosed including a housing, a motor mounted to the housing, a switch for turning the motor off, a piston assembly disposed within the housing, and a linkage assembly. The switch can be disposed at least partially within the housing. The carriage can be coupled to the piston assembly and can have a pivotally mounted arm. The linkage assembly can be disposed within the housing and can be moveable by the motor. The linkage assembly can be connected to the arm such that when the motor moves the linkage assembly, the linkage assembly can pivot the arm to move the switch.
In addition, an air compressor is disclosed including a housing and a piston assembly disposed within the housing. The piston assembly can include a piston housing, a first o-ring, a second o-ring, and a piston. The piston housing can have a first end and a second end, and can include an air inlet disposed between the first end and the second end. The first o-ring can be disposed within the piston housing between the first end and the air inlet. The second o-ring can be disposed within the piston housing between the second end and the air inlet. The piston can be disposed at least partially within the piston housing. The piston can be moveable with respect to the piston housing. The first o-ring and the second o-ring can be mounted stationary within the piston housing such that the piston is moveable within the first o-ring and the second o-ring.
Further, a piston assembly is disclosed including a piston housing, a first o-ring, a second o-ring, and a piston. The piston housing can have a first end and a second end, and can include an air inlet disposed between the first end and the second end. The first o-ring can be disposed within the piston housing between the first end and the air inlet. The second o-ring can be disposed within the piston housing between the second end and the air inlet. The piston can be disposed at least partially within the piston housing. The piston can be moveable with respect to the piston housing. The first o-ring and the second o-ring can be mounted stationary within the piston housing such that the piston is moveable within the first o-ring and the second o-ring.
With reference to the figures, wherein like reference numbers represent like features, an air compressor is described herein. Referring to
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The cylindrical housing 178 can include a chamber 179 for receiving a portion of the piston 180 at an end 183 and permitting movement of the piston 180 within the cylindrical housing 178. The air inlet 184 can be disposed on the sidewall of the cylindrical housing 178. When the first piston assembly 174 is assembled to the air compressor 100, the air inlet 184 can be disposed within an air block 194. The air block 194 can provide an internal pathway for air from the air input 196 to reach the air inlet 184 of the first piston assembly 174. Seals 198, 200 can be disposed on the outside of the cylindrical housing 178 on each side of the air inlet 184 for contacting the interior of the air block 194.
Likewise, the sealing structures, shown as two o-rings 186, 188, can be disposed on each side of the air inlet 184 within the chamber 179 and can be mounted such that they are stationary within the chamber 179. The o-rings 186, 188 can be sized to receive the piston 180. The o-rings 186, 188 can be mounted in a stationary position such that they do not move as the piston 180 moves through them. The o-rings 186, 188 can be maintained in a stationary position using one or more spacers 187, 189, which can be tubular or any other suitable shape. For example, spacer 187 can be disposed within the chamber 179 between the o-rings 186, 188 to maintain a desired spacing between the o-rings 186, 188 and to help hold the o-rings 186, 188 in a stationary position. As shown, spacer 187 can hold o-ring 186 against a ledge in the chamber 179 formed by a change in diameter of the chamber 179. The spacer 187 can have one or more apertures 197 for allowing air into the interior of the spacer 187. Another spacer 189 can also be provided near the end 183 to help hold the o-rings 186, 188 in a stationary position. As shown, o-ring 188 can be held in position between the spacers 187, 189. The piston 180 can be disposed within the spacers 187, 189. A threaded nut 185 can be provided at the end 183, which can be tightened to further secure and retain the o-rings 186, 188 and spacers 187, 189 in position. The threaded nut 185 can also be removed to provide access to the chamber 179 for repair or replacement of parts. It will be appreciated that the sealing structures, such as o-rings 186, 188, can be mounted in a stationary position in any suitable manner. In addition, the sealing structures, such as o-rings 186, 188, can have any suitable shape and can be made of any suitable material.
The back check valve 182 can include a spring 202, a plug 204, and a seal 206 to restrict the flow of air to a single direction toward the exit air line 190. The seal 206 can be an o-ring, which can be mounted to the plug 204 within the cylindrical housing 178. When the valve 182 is closed, the seal 206 can abut a ledge formed by a change in diameter of the chamber 179. The spring 202 can bias the plug 204 and seal 206 against the ledge. The valve 182 can open by moving away from the ledge when a particular pressure is reached in the chamber 179. When this occurs, air is permitted to flow through a space between the plug 204 and the chamber 179 and then into the exit air line 190. The exit air line 190 is attached to an end 181 of the piston housing 178 and feeds to an inlet for the second piston assembly 176. As shown in
Referring again to
Likewise, the sealing structures, shown as two o-rings 216, 218, can be disposed on each side of the air inlet 214 within the chamber 209 and can be mounted such that they are stationary within the chamber 179. The o-rings 216, 218 can be sized to receive the piston 210. The o-rings 216, 218 can be mounted in a stationary position such that they do not move as the piston 210 moves through them. The o-rings 216, 218 can be maintained in a stationary position using one or more spacers 217, 219, which can be tubular or any other suitable shape. For example, spacer 217 can be disposed within the chamber 209 between the o-rings 216, 218 to maintain a desired spacing between the o-rings 216, 218 and to help hold the o-rings 216, 218 in a stationary position. As shown, spacer 217 can hold o-ring 216 against a ledge in the chamber 209 formed by a change in diameter of the chamber 209. The spacer 217 can have one or more apertures 227 for allowing air into the interior of the spacer 217. Another spacer 219 can also be provided near the end 213 to help hold the o-rings 216, 218 in a stationary position. As shown, o-ring 218 can be held in position between the spacers 217, 219. The piston 210 can be disposed within the spacers 217, 219. A threaded nut 215 can be provided at the end 213, which can be tightened to further secure and retain the o-rings 216, 218 and spacers 217, 219 in position. The threaded nut 215 can also be removed to provide access to the chamber 209 for repair or replacement of parts. It will be appreciated that the sealing structures, such as o-rings 216, 218, can be mounted in a stationary position in any suitable manner. In addition, the sealing structures, such as o-rings 216, 218, can have any suitable shape and can be made of any suitable material.
The back check valve 212 can include a spring 230, a plug 232, and a seal 234 to restrict the flow of air to a single direction toward the exit air line 220. The seal 234 can be an o-ring, which can be mounted to the plug 232 within the cylindrical housing 208. When the valve 212 is closed, the seal 234 can abut a ledge formed by a change in diameter of the chamber 209. The spring 230 can bias the plug 232 and seal 234 against the ledge. The valve 212 can open by moving away from the ledge when a particular pressure is reached in the chamber 209. When this occurs, air is permitted to flow through a space between the plug 232 and the chamber 209 and then into the exit air line 220. As shown in
It will be appreciated that the second piston chamber 209 can be of a different size than the first piston chamber 179. As shown in
Referring to
During operation, as described further below, the switch 242 can be moved from the on position to the off position by the release arm 148. The switch 242 can include a sleeve in the form of a spring that slides over and extends from the switch 242. The central axis of the spring can align with the central axis of the switch 242. The sleeve can be longer than the switch 242 and can operate as an extension to the length of the switch 242. The sleeve can extend through the aperture 112 for gripping the switch 242 from the exterior of the air compressor 100.
For example purposes only, the operation of an embodiment of the air compressor 100 will be described herein. Referring again to
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The motor 106 can continue to drive the pistons 180, 210 until the switch 242 is turned off. The air compressor 100 can be equipped with an automatic shut-off mechanism to turn off the air compressor 100 when a desired pressure has been reached in a piston assembly. The automatic shut-off mechanism can be a mechanical structure incorporated into the carriage 144. Referring to
The amount of pivot force is related to the amount of pressure in the piston assemblies 174, 176. When the connecting arm 142 is pulling the carriage 144 and second piston 210 toward the back check valve 212, the pressure in the piston assemblies 174, 176 exerts a force against the piston 210 and carriage 144. The connecting arm 142 works against this force in order to pull the carriage 144 toward the switch 242, but the pivot force about the pivot connection at 158 between the release arm 148 and shaft block 146 increases with the increase in pressure in the piston assemblies 174, 176. Thus, when a certain piston assembly pressure threshold is reached, the pivot force will be great enough to overcome the spring force of the spring, which permits the release arm 148 to rotate with respect to the shaft block 146 as shown in
It will be appreciated that the shut-off pressure can be adjusted by using a spring 168 capable of asserting a different spring force, and/or by altering various connection positions on the release arm 148. For example, the shut-off pressure can be affected by modifying the chosen positions of the connecting arm/release arm pivot connection at 170, the release arm/drive block pivot connection at 158, and/or the position of the spring aperture 160. It will be appreciated that the automatic shut-off mechanism can include any suitable structure to shut off the air compressor 100 at any desired pressure.
Thus, the air compressor 100 can operate as a two-stage compressor that takes in air at particular pressure, compresses that air to a higher pressure in the first piston assembly 174, and then further compresses the air to an even higher pressure with the second piston assembly 176. The pressure of the compressed air at each stage can be any suitable amount. By way of example and not limitation, in certain embodiments, the air compressor can take in air at approximately 85 psi and further compress the air to approximately 800 psi with the first piston assembly 174. This higher pressure air can then be fed into the second piston assembly 176 for further compression to approximately 4500 psi. In addition, once a certain pressure in a piston assembly has been reached, the air compressor 100 can include a mechanical structure for shutting off the air compressor 100. The particular piston assemblies utilized can help determine the amount of compression through the air compressor 100.
The air compressor is capable of providing compressed air at a high pressure suitable for filling paintball gun tanks, scuba tanks, and any other suitable applications.
All references, including publications, patent applications, and patents, cited herein are hereby incorporated by reference to the same extent as if each reference were individually and specifically indicated to be incorporated by reference and were set forth in its entirety herein.
The use of the terms “a” and “an” and “the” and similar referents in the context of describing the invention (especially in the context of the following claims) are to be construed to cover both the singular and the plural, unless otherwise indicated herein or clearly contradicted by context. The terms “comprising,” “having,” “including,” and “containing” are to be construed as open-ended terms (i.e., meaning “including, but not limited to,”) unless otherwise noted. Recitation of ranges of values herein are merely intended to serve as a shorthand method of referring individually to each separate value falling within the range, unless otherwise indicated herein, and each separate value is incorporated into the specification as if it were individually recited herein. All methods described herein can be performed in any suitable order unless otherwise indicated herein or otherwise clearly contradicted by context. The use of any and all examples, or exemplary language (e.g., “such as”) provided herein, is intended merely to better illuminate the invention and does not pose a limitation on the scope of the invention unless otherwise claimed. No language in the specification should be construed as indicating any non-claimed element as essential to the practice of the invention.
Preferred embodiments of this invention are described herein, including the best mode known to the inventors for carrying out the invention. Variations of those preferred embodiments may become apparent to those of ordinary skill in the art upon reading the foregoing description. The inventors expect skilled artisans to employ such variations as appropriate, and the inventors intend for the invention to be practiced otherwise than as specifically described herein. Accordingly, this invention includes all modifications and equivalents of the subject matter recited in the claims appended hereto as permitted by applicable law. Moreover, any combination of the above-described elements in all possible variations thereof is encompassed by the invention unless otherwise indicated herein or otherwise clearly contradicted by context.
This patent application claims the benefit of U.S. Provisional Patent Application No. 60/441,909, filed Feb. 11, 2011, which is incorporated by reference in its entirety herein.
Number | Date | Country | |
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61441909 | Feb 2011 | US |