JP2008527271A - Axial direction driven piston cylinder unit - Google Patents

Abstract

  The present invention is an axially driven piston cylinder unit comprising a cylinder (2) and a piston (3), the piston (3) being defined by the piston (3) and the cylinder (2). Reciprocating in the axial direction of the cylinder (2) between the first piston position where the cylinder chamber (18) is maximum and the second piston position where the cylinder chamber is minimum; Further, a drive member (50) reciprocated in the axial direction of the cylinder is provided, and the drive member is of a type mechanically coupled via the piston (3) and the piston rod (4). As a result, the piston rod (4) can be made elastic by using an elastic device (6) at the first end (4 ′) and / or the second end (4 ″) of the piston rod. 6) The piston (3) or the drive member (50) is coupled to the piston (3) or the drive member (50) so as to be able to move in an axial direction relative to the piston (3) or the drive member (50) against the stress. When the piston bottom (16) comes into contact with the end wall (12) on the cylinder head side during the movement of the piston (3) to the second piston position adjacent to the end wall (12) on the cylinder head side, the drive member (50) continues to move against the force of the elastic device (6) and the drive member (50) is braked by the elastic device.

Description

  The present invention is an axially driven piston / cylinder unit comprising a cylinder and a piston, the piston having a cylinder chamber (cylinder volume) defined by the piston and the cylinder having a maximum capacity. A drive capable of reciprocating in the axial direction of the cylinder between a piston position of 1 and a second piston position having the smallest cylinder chamber, and further capable of reciprocating in the axial direction of the cylinder A member (drive element) is provided, and the drive member is of a type mechanically coupled via the piston and the piston rod.

  A piston cylinder unit of this type is known, for example, from US Pat. No. 5,525,845. In this case, the piston rod is rigidly connected to the piston and the drive member that can move in the axial direction of the linear drive unit or the linear drive unit, that is, rigidly, that is, incapable of relative movement. In the operation of the piston driven by the linear motor, the axial vibration produced by the linear motor of the unit consisting of the movable drive member, the piston rod and the piston increases the vibration amplitude, so that the piston bottom of the piston Will hit the bottom of the cylinder hole, which leads to damage to the piston bottom or to the end face wall (bottom) of the head side of the cylinder hole.

  An object of the present invention is to improve the axially driven piston cylinder unit described at the beginning and to reduce the possibility of damage to the piston or cylinder.

  In a configuration according to the present invention to solve the above-described problem, the piston rod uses an elastic device or an elastic device on at least one of the first end and the second end of the piston rod. , Coupled to the piston or drive member so as to be axially movable relative to the piston or drive member against the stress or clamping force of the elastic device or elastic device, whereby the cylinder of the cylinder When the piston bottom part comes into contact with the end surface wall on the head side of the cylinder hole during the movement (movement) of the piston to the second piston position adjacent to the end surface wall on the head side of the hole, the drive member is In this case, the elastic device or the elastic device is moved (moved) against the force of the general device or the elastic device. It is adapted to brake the serial drive member. That is, the drive member moves while being braked or damped by an elastic device or an elastic device.

  In the normal operating state of the piston-cylinder unit, the piston rod is precisely defined relative to the piston and to the drive member, i.e. is held substantially stationary relative to the piston and drive member, There is no relative movement between the drive member, the piston rod and the piston. Relative motion between the drive member and the piston rod or between the piston rod and the piston in the event of overloading, ie when the force generated from the drive member exceeds the stress or clamping force of the elastic device Is supposed to occur.

  Since the mass of the drive member is cut off from the piston by an elastic device, the drive member comes into contact with the end face wall on the head side of the cylinder hole when the piston moves (moves) to the compression position. In some cases, it is braked by an elastic device, ie the subsequent inertial movement of the drive member is damped by the elastic device. As a result, only the mass of the piston collides with the end face wall on the head side of the cylinder hole. The collision pulse generated when the mass of the piston hits the end wall on the head side of the cylinder hole is significantly smaller than that of the rigid unit consisting of the piston, piston rod and drive member. The risk of damage or damage to the end face wall on the head side of the cylinder bore is greatly reduced.

  In a preferred embodiment of the invention, the piston bottom of the piston is provided with an opening or a through hole, and the first end of the piston rod passes through the opening or through hole of the piston bottom of the piston. In this case, the piston rod is moved (moved) relative to the piston in the axial direction of the piston, and an elastic device is provided between the piston rod and the piston. The piston rod is adapted to generate (act) a stress or a pressing force directed from the piston toward the drive member, or the piston rod is tightened from the piston toward the drive member. In this case, the piston rod is provided with an end stopper or a mushroom-shaped head. Mushroom-shaped head, the piston rod is adapted to prevent the break out of the opening. Based on this embodiment, the mass hitting the end wall on the head side is further reduced because the mass of the piston rod is also cut off from the piston.

  In a particularly advantageous embodiment, the piston rod is guided in a sealed manner in the opening in the piston bottom, and for this purpose is advantageously provided with a seal surrounding the piston rod, i.e. an opening in the piston bottom. A seal is provided between the part and the piston rod. Based on this embodiment, the compression efficiency is improved because the medium compressed by the piston is not allowed to escape through the annular gap around the piston rod.

  In another advantageous embodiment, the drive member is provided with an opening or a through hole, in which case the second end of the piston rod enters the drive member into the opening or the through hole, or It penetrates the opening or through hole of the drive member, and the piston rod is moved (moved) relative to the drive member in the axial direction of the drive member, and is elastic. The device is provided between the piston rod and the drive member, and causes the piston rod to generate stress or pressing force directed from the drive member to the piston, or the piston rod Is tightened from the drive member toward the piston, and in this case, the piston rod is provided with an end stopper, and the end stopper is Piston rod is adapted to prevent the break out of the opening. In this embodiment, the blocking using the elastic device is performed on the side of the drive member, so that the piston rod and the piston can be firmly connected to each other, and the complicated seal at the opening at the bottom of the piston is omitted. can do.

  In an advantageous embodiment, the elastic device (flexure device or telescopic device) comprises a spring or is formed by a spring. In a particularly advantageous embodiment, a Belleville spring device is provided, or a compression or tension coil spring (compression coil spring or tension coil spring) is provided.

The present invention is effectively implemented using a linear drive, such as a linear motor, in which the piston is loaded or driven by a movable drive member of the linear drive for reciprocating drive. It has become so.

  The axially driven piston-cylinder unit according to the invention is advantageously used in a compressor or compressor for the formation of pressure fluid.

The present invention will be described in detail below based on the embodiments shown in the drawings. In the drawing
FIG. 1 is a diagram showing an embodiment of the present invention provided with a shut-off device in the region of a piston,
FIG. 2 is an enlarged view of the piston rod penetration guide at the piston bottom of the embodiment of FIG.

  FIG. 1 shows a longitudinal section of a piston cylinder unit 1 composed of cylinders 2 and 3. The cylinder 2 of the piston cylinder unit (piston cylinder unit) 1 has a cylinder hole 10 which receives the piston 3 so as to be able to reciprocate in the direction of the longitudinal axis X of the cylinder hole 10. The piston 3 is freely guided in the cylinder hole so as to be able to reciprocate. The piston 3 is gas-supported in the cylinder 2. The end surface wall 12 on the head side formed in the cylinder head 23 of the cylinder hole 10, the inner peripheral wall 14 of the cylinder hole 10, and the piston bottom portion 16 define a cylinder chamber (cylinder volume) 18. An inflow passage 22 is opened in the end surface wall 12 on the head side of the cylinder hole 10, and the inflow passage 22 includes a valve 20. Further, an outflow passage 24 is provided in the end wall 12 on the head side, and the outflow passage is provided with a suitable valve 26 and is also open to the cylinder hole 10.

  When the piston 3 moves to the left in FIG. 1, the fluid is sucked into the cylinder chamber 18 through the inflow passage 22 and the inflow valve 20, and the sucked fluid is compressed in the right direction of the piston 3. The gas is discharged through the outflow valve 26 and the outflow passage 24. The illustrated piston cylinder unit 1 is a component part of a piston type work machine, and the fluid discharged by the piston type work machine is, for example, a gas, that is, gas or air in the case of a compressor or a compressor. The invention is in principle also used for other piston-type work machines, for example pumps.

  The piston 3 is driven by a drive member 50 capable of moving in an axial direction that vibrates along an axis Y of a linear motion drive unit (linear drive unit) 5 schematically shown in FIG. An axially movable drive member 50 is mechanically coupled to the piston 3 via the piston rod 4. The piston rod 4 is inelastic in the axial direction, that is, rigid, and therefore transmits the axial force of the driving member 50 to the piston 3.

  The piston rod 4 is firmly coupled to the drive member 50. The piston rod 4 is guided in the piston 3 so as to be movable in the direction of the longitudinal axis X of the cylinder 2 or in the direction of the longitudinal axis X ′ of the piston 3 coaxial with the longitudinal axis of the cylinder. For this purpose, the piston rod 4 is supported inside the piston 3 by a ring-shaped radial support 31, which is rigidly connected to the piston 3 on the outer periphery and has an opening in the center. The opening receives the piston rod 4 in a slidable manner, that is, the piston rod 4 is guided through the central opening of the piston so as to be movable in the axial direction, that is, is guided through.

  The piston bottom 16 is provided with a through-opening 16 '(FIG. 2) in the center, and a first end 4' on the piston side of the piston rod 4 is guided through the through-hole. The first end 4 ′ on the piston side is provided with a mushroom-shaped head 41 on the end face, and the curved surface of the head faces the cylinder head 23. The mushroom-shaped head 41 forms an annular support surface 41 ′ on the back side facing the piston bottom 16, and the outer diameter of the support surface is larger than the diameter of the opening 16 ′ of the piston bottom 16. As a result, the piston rod 4 is prevented from coming out to the left in the drawing.

  The first end 4 ′ on the piston side of the piston rod 4 has a reduced diameter with respect to the other part of the piston rod 4, ie the remaining part. A seal 43 may be disposed around the diameter portion, and the seal may connect the first end section 4 ′ on the piston side of the piston rod 4 to the inner peripheral surface of the opening 16 ′ of the piston bottom 16. And sealed.

  An annular curved disc spring 44 is provided as an elastic device 6 in the region of the radial support 31 inside the piston 3, which is fixed to the piston 3 on the outer periphery, and in the center. A hole is received in the piston rod 4, i.e. the piston rod is guided through a central hole in the disc spring, in which case the inner circumference of the annular disc spring 44 is the piston It is fixed to the rod 4. The disc spring 44 is curved in a convex shape toward the left side in FIG. 1, that is, toward the drive member 50, thereby causing the disc spring 44 to exert stress on the piston rod 4 to the left side in FIG. The mushroom-shaped head 41 at the first end 4 ′ of the piston rod 4 is brought into contact with the piston bottom 16 by the stress of the spring 44 with the annular surface 41 ′ of the head.

  When the piston 3 is moved or moved to the right side in the drawing, that is, to the compression position where the volume of the cylinder chamber 18 is minimized, the piston bottom 16 comes into contact with the end face wall 12 on the head side of the cylinder head 23. Based on the mass inertia of the movable drive member 50 and the piston rod 4, the drive member 50 and the piston rod 4 further move to the right against the force of the disc spring 44, and are braked by the spring force of the disc spring 44. Will come to be. In this case, the mushroom-shaped head 41 at the end of the piston rod 4 on the piston side is formed away from the piston bottom 16 in the region of the opening of the outflow passage 24 on the cylinder chamber 18 side of the cylinder head 23. It moves into the recessed portion (notch portion) 25. As a result, the impact at the time of the collision of the piston bottom portion 16 with the end surface wall 12 on the head side is limited to the mass of the piston 3, and the masses of the drive member 50 and the piston rod 4 are temporally transferred to the end surface wall 12 on the head side. Is damped by the spring 44 after the piston bottom 16 impact.

  In another embodiment, the piston rod 4 may be rigidly connected to the piston 3, i.e. non-relatively connected, in which case the relatively axially movable bearing of the piston rod 4 is connected to the drive member 50. The elastic component provided by the spring 44 is provided between the piston rod 4 and the drive member 50.

  The present invention is not limited to the above-described embodiments, and the embodiments are used for explaining the basic idea of the present invention. Within the framework of the present invention, the apparatus according to the present invention can be implemented in various ways with configurations different from those of the previous embodiments. In this case, the apparatus may be implemented by combining various configurations described in the claims. The reference numerals used in the claims, the description, and the drawings are used for understanding the invention and do not limit the invention.

The longitudinal cross-sectional view of the Example which provided the interruption | blocking apparatus in the area | region of piston of this invention The expanded sectional view of the penetration guide part of the piston rod in the piston bottom part of the Example of FIG.

Explanation of symbols

  1 piston cylinder unit, 2 cylinder, 3 piston, 4 piston rod, 4 ', 4 "end, 5 linear drive, 10 cylinder hole, 12 end wall, 16 piston bottom, 16' opening, 18 cylinder chamber, 20 valve, 22 inflow passage, 23 cylinder head, 24 outflow passage, 26 outflow valve, 31 radial support, 41 head, 41 'support surface, 44 disc spring, 50 drive member

Claims (7)

An axially driven piston / cylinder unit,
Cylinder (2),
And a piston (3), said piston (3) having a first piston position in which a cylinder chamber (18) defined by said piston (3) and said cylinder (2) is maximum; Reciprocating in the axial direction of the cylinder (2) between the second piston position where the cylinder chamber is the smallest,
Further, a drive member (50) reciprocated in the axial direction of the cylinder is provided, and the drive member is mechanically coupled via the piston (3) and the piston rod (4). ,
The piston rod (4) is made of the elastic device (6) using an elastic device (6) at the first end (4 ') and / or the second end (4 ") of the piston rod. 6) is coupled to the piston (3) or the drive member (50) so as to be able to move in the axial direction relative to the piston (3) or the drive member (50) against the stress of 6). In the movement of the piston (3) to the position of the second piston adjacent to the end face wall (12) on the cylinder head side of (10), the piston bottom (16) abuts on the end face wall (12) on the cylinder head side. In this case, the drive member (50) is adapted to continue to move against the force of the elastic device (6), so that the elastic device brakes the drive member (50). Axial direction drive, characterized by Expression of the piston cylinder unit.   The first end (4 ') of the piston rod (4) passes through an opening (16') provided in the piston bottom (16) of the piston, and the piston rod (4) is connected to the piston. It is adapted to move relative to the piston (3) in the axial direction, and an elastic device (6) is provided between the piston rod (4) and the piston (3). The piston rod (4) is subjected to stress directed from the piston (3) to the drive member (50), and the piston rod (4) has an end stopper (41 '). 2. An axially driven piston cylinder unit according to claim 1, wherein the end stopper is adapted to prevent the piston rod (4) from coming out of the opening (16 ').   3. The axially driven piston cylinder unit according to claim 2, wherein the piston rod (4) is guided in a sealed state in an opening (16 ') at the bottom of the piston.   The second end (4 ″) of the piston rod (4) passes through an opening provided in the drive member (50), and the piston rod (4) is in the axial direction of the drive member (50). The elastic member is provided between the piston rod (4) and the driving member (50), and is moved relative to the driving member (50). The piston rod (4) is adapted to generate stress directed from the drive member (50) to the piston (3), and the piston rod (4) includes an end stopper (41 '). The axial stopper type piston cylinder unit according to claim 1, wherein the end stopper prevents the piston rod (4) from coming out of the opening.   5. An axially driven piston / cylinder unit according to claim 1, wherein the elastic device (6) comprises a spring (60).   The piston (3) according to any one of claims 1 to 5, wherein the piston (3) is loaded by a movable drive member (50) of the linear drive (5) for reciprocating drive. Axis drive type piston cylinder unit.   A compressor for the formation of a pressure fluid, characterized in that the compressor comprises at least one piston-cylinder unit (1) of axial drive according to any one of claims 1 to 6. A compressor for the formation of pressure fluid.

Images