1. Technical Field
The present disclosure relates to cylinders, and particularly to a cylinder for positioning a workpiece.
2. Description of Related Art
A cylinder may be used to push a workpiece, for positioning the workpiece. Many cylinders include a cylinder body defining a receiving chamber, a piston and a push rod received in the receiving chamber. The cylinder body may define two openings at opposite ends communicating with the receiving chamber. The piston may be movably received in the receiving chamber, a first end of the push rod may be fixed to the piston, and a second end of the push rod may extend out of the cylinder body via one opening. The push rod may be used to push a workpiece, for positioning the workpiece. However, the workpiece is just pushed by the push rod along a longitudinal direction of the push rod, which results in the workpiece being not able to be positioned in other directions. Thus the workpiece can slide along other directions, which results in an imprecise positioning of the workpiece and possible damage to the workpiece.
Therefore, there is room for improvement in the art.
The components in the drawings are not necessarily drawn to scale, the emphasis instead placed upon clearly illustrating the principles of the present disclosure. Moreover, in the drawings, like reference numerals designate corresponding parts throughout the several views.
The mounting portion 111 is substantially cubic. The first shoulder portion 1112 is substantially an annular protrusion perpendicularly protruding from the inner sidewall of the mounting portion 111. The mounting portion 111 further defines a pair of fixing holes 1113 at two opposite sidewalls, and a first air inlet hole 1115 at one of the sidewalls thereof. The fixing holes 1113 are circular through holes, and communicate with the first chamber 1151. The first air inlet hole 1115 is a through hole, and communicates with the second chamber 1153. In the illustrated embodiment, the first air inlet hole 1115 and one of the fixing holes 1113 are located at a same sidewall of the mounting portion 111.
The receiving portion 113 is substantially cylindrical. The second shoulder portion 1131 is substantially an annular protrusion perpendicularly protruding from the inner sidewall of the receiving portion 113. The receiving portion 113 defines a second air inlet hole 1133 at a sidewall thereof. The second air inlet hole 1133 is a through hole, and communicates with the third chamber 1155. The second shoulder portion 1131 defines a through groove 1132 parallel to an axis of the receiving portion 113. The through groove 1132 is located below the second air inlet hole 1133, and communicates with the second air inlet hole 1133.
In the illustrated embodiment, a shape of the first air inlet hole 1115 is same as a shape of the second air inlet hole 1133. The second air inlet hole 1133 includes a first end portion 1134, a second end portion 1135, and a connecting portion 1136 interconnecting the first end portion 1134 and the second end portion 1135. The first end portion 1134 is located at a distal end of the second air inlet hole 1133 away from the receiving chamber 115. The second end portion 1135 is located at a distal end of the second air inlet hole 1133 adjacent to the receiving chamber 115. A diameter of the first end portion 1134 is larger than a diameter of the second end portion 1135. The connecting portion 1136 is substantially conic. The shape of the first air inlet hole 1115 and the second air inlet hole 1133 is designed to increase the air pressure when air is flowing in.
The sealing member 13 is substantially annular, and a size of the sealing member 13 matches with a size of the annular groove 1154. The sealing member 13 is made of flexible materials, and is received in the annular groove 1154, for sealing the cylinder body 11. In the illustrated embodiment, the sealing member 13 is made of silicon. The fasteners 15 pass through the corresponding fixing holes 1113, and resist the cylinder rod assembly 30 received in the receiving chamber 115, for stopping the cylinder rod assembly 30 from rotating in the receiving chamber 115. In the illustrated embodiment, the fasteners 15 are jackscrews.
The cylinder rod assembly 30 includes a mounting base 31, a rod 33, and a connecting rod 35, a first sealing member 37, and a second sealing member 39. The mounting base 31 defines a through hole 315, for mounting the rod 33. The mounting base 31 is substantially shaped like two overlapped cylinders, and is received in the receiving chamber 115. The mounting base 31 includes a main body 311 and an extending portion 313 perpendicularly extending from the main body 311 towards the receiving portion 113. The main body 311 and the extending portion 313 are substantially annular, and a diameter of the extending portion 313 is smaller than a diameter of the main body 311. The main body 311 is received in the first chamber 1151, and defines a first through hole 3111 along a radial direction thereof. The extending portion 313 is received in an end of the second chamber 1153 adjacent to the first chamber 1151, and defines an annular first sealing groove 3131 at an outer sidewall thereof. The first sealing member 37 is received in the first sealing groove 3131.
The rod 33 includes a rod body 331, a fixing end 333 and a pushing end 335, in which the fixing end 333 and the pushing end 335 are located at two opposite ends of the rod body 331. A diameter of the rod body 331 is smaller than a diameter of the fixing end 333, and is greater than a diameter of the pushing end 335. The fixing end 333 is mounted and received in the through hole 315. The rod body 331 and the pushing end 335 are received in the receiving chamber 115. The fixing end 333 defines an annular second sealing groove 3331 at an outer sidewall thereof, and defines a second through hole 3332 corresponding to the first through hole 3111 of the main body 311. The second sealing member 39 is received in the second sealing groove 3331. The second through hole 3332 is aligned with the first through hole 3111, and communicates with the first through hole 3111. The connecting rod 35 passes through the first through hole 3111 and the second through hole 3332, for fixing the rod 33 with the mounting base 31. The pushing end 335 includes a first section 3351 and a second section 3353. The first section 3351 interconnects with the rod body 331 and the second section 3353. The second section 3353 is located at a distal end of the first section 3351 away from the rod body 331. The first section 3351 is substantially a frustum of a cone, and a diameter of a distal end thereof adjacent to the rod body 331 is greater than a diameter of a distal end thereof adjacent to the second section 3353. The first section 3351 includes a resisting surface 3355 at an outer sidewall thereof. The resisting surface 3355 is an inclined surface, and inclines from the distal end thereof adjacent to the rod body 331 to the other distal end adjacent to the second section 3353 towards an axis of the rod body 331. The second section 3353 is substantially cylindrical, and protrudes from the distal end of the first section 3351, outwardly.
The piston assembly 50 is sleeved on the rod body 331 and the pushing end 335, and includes a piston 51, a first sealing ring 53, a wear ring 55, a second sealing ring 56, a piston rod 57, a dust cover 58, and six resisting members 59. The piston 51 is substantially cylindrical, and is sleeved on the rod body 331 and is received in the second chamber 1153 besides the extending portion 313. An outer sidewall of the piston 51 resists against the inner sidewall of the second chamber 1153. The piston 51 defines a third sealing groove 511 and a containing groove 513 at an outer sidewall, and defines a fourth sealing groove 515 at an inner sidewall thereof. The third sealing groove 511, the containing groove 513, and the fourth sealing groove 515 are substantially annular. The first sealing ring 53 is received in the third sealing groove 511. The wear ring 55 is received in the containing groove 513. The second sealing ring 56 is received in the fourth sealing groove 515. The first sealing ring 53 and the second sealing ring 56 are made of flexible materials. The wear ring 55 is made of wearable materials.
The piston rod 57 is substantially cylindrical, and protrudes from a distal end of the piston 51 away from the extending portion 313, outwardly. An end portion of the piston rod 57 adjacent to the piston 51 is received in the second chamber 1153, and a middle portion of the piston rod 57 is received in the third chamber 1155, and another end portion of the piston rod 57 away from the piston 51 extends out from the receiving portion 113. An outer sidewall of the piston rod 57 resists against an inner sidewall of the third chamber 1155. The piston rod 57 defines six through holes 571 at the end away from the piston 51 along a circumference of the piston rod 57. The through holes 571 are adjacent to the resisting surface 3355. The sealing member 13 is received in the annular groove 1154, and is sleeved on the piston rod 57. The dust cover 58 is substantially cap-shaped, and is mounted on a distal end of the piston rod 57, for prevent dust from entering or dropping into the piston rod 57. The resisting members 59 are bearing balls, and are positioned between the corresponding through holes 571 and the pushing end 335. A diameter of the resisting member 59 is greater than a diameter of the through hole 571, thus the resisting members 59 can not be pushed out from the through holes 571. In other embodiments, the number of the through hole 571 and the resisting member 59 can be one or more than one. In other embodiments, the resisting members 59 can be in other shapes, such as ellipsoidal.
In assembly, the second sealing member 39 is received in the second sealing groove 3331. The fixing end 333 of the rod 33 is mounted in the mounting base 31. The connecting rod 35 fixes the rod 33 and the mounting base 31. The first sealing member 37 is received in the first sealing groove 3131. Therefore, the sub-assemblies of the cylinder rod assembly 30 are assembled together. Then, the resisting members 59 are mounted in the corresponding through holes 571. The dust cover 58 is detachably mounted on the piston rod 57. The first sealing ring 53, the wear ring 55, and the second sealing ring 56 are respectively mounted into the third sealing groove 511, the containing groove 513, and the fourth sealing groove 515. Therefore, the sub-assemblies of the piston assembly 50 are assembled together. Next, the piston assembly 50 is sleeved on the rod body 331. Finally, the sealing member 13 is received in the annular groove 1154, and the piston assembly 50 and the cylinder rod assembly 30 are inserted into the cylinder body 11. The fasteners 15 fasten the cylinder rod assembly 30 with the cylinder body 11.
In use, a workpiece (not shown) needed to be positioned is sleeved on the piston rod 57, and covers the through holes 571. Air is inputted into the second chamber 1153 of the receiving chamber 115 from the second air inlet hole 1133 and the through groove 1132. The piston 51 is forced to slide along the inner sidewall of the second chamber 1153 towards the mounting base 31. The air between the receiving portion 113 and the piston 51 flows out from the first air inlet hole 1115. The piston rod 57 slides along the inner sidewall of the third chamber 1155 towards the mounting base 31. The resisting surface 3355 resists the resisting members 59, and enable the resisting members 59 to be partially exposed from the through holes 571, thus the resisting members 59 resists and positions the workpiece as shown in
Finally, while various embodiments have been described and illustrated, the disclosure is not to be construed as being restricted thereto. Various modifications can be made to the embodiments by those skilled in the art without departing from the true spirit and scope of the disclosure as defined by the appended claims.
Number | Date | Country | Kind |
---|---|---|---|
201210035951.3 | Feb 2012 | CN | national |