NO149319B - PROCEDURE AND DEVICE FOR APPLICATION AND REMOVAL OF A OFFSHORE CONSTRUCTION - Google Patents

Description

Device with a cylinder and a movable piston in it.

The invention relates to a device with

a cylinder and a piston movable in this, connected to a drive mechanism, which separates two chambers, where the seal between the piston and the cylinder consists of a rolling membrane which is arranged between one of the aforementioned chambers and an auxiliary chamber filled with liquid, and where the restriction of the auxiliary chamber does not only consists of the rolling diaphragm, but also of wall parts of the piston and the cylinder which are designed in such a way that, by their shape alone, they keep the volume of the auxiliary space at least approximately constant during the movement of the piston in the cylinder, and where in the space sealed by the rolling diaphragm is located a gas.

In the case of devices of this nature consist

the connection between the piston and the drive of a mechanism with many individual parts and the pivot point which is subject to wear e.

The purpose of the invention is to provide a simpler connection between

the piston and the drive mechanism, and this is achieved according to the invention by the fact that in the second chamber there is a movable column of liquid which, in a manner known per se, forms the connection between the piston and the drive mechanism.

The coupling between the drive mechanism and the piston by means of a movable liquid column has the advantage that one has a great deal of freedom with regard to the arrangement of the piston and the drive mechanism in relation to each other. In order for the roller membrane to work in the best way, it is desirable that it is constantly stretched during the device's operation. This means that there must be so much liquid in the auxiliary space that the membrane is always kept in a stretched state with the help of the gas pressure in the space above the roller membrane and the pressure against the liquid in the auxiliary space, so that the liquid in this auxiliary space serves as a repulsion for the roller membrane. As the liquid in the auxiliary space is almost incompressible, it is clear that the membrane always remains constant in radial section.

According to a further advantageous feature of the invention, the auxiliary space and the space in which the movable liquid column is located are connected to each other, and this connection is formed by a gap between the piston and the cylinder wall.

Such a constructionally very simple embodiment has the further advantage that the piston simultaneously runs in an oil bath.

By the fact that the space filled with the liquid under the roller membrane and the space in which the movable column of liquid is located are connected to each other, the advantage is achieved that only one kind of liquid is sufficient.

A further advantage consists in the fact that, in contrast to the known devices which are provided with a rolling membrane supported by liquid, no additional device for the supply of liquid is required here. As a result of the prevailing constant pressure difference between the liquid-filled space under the roller membrane and the space in which the movable column of liquid is located, a constant quantity of liquid per time unit.

A further advantageous embodiment according to the invention is that the connection between the auxiliary space and the space in which the movable column of liquid is located is dimensioned so that at least so much liquid flows through the connection to the auxiliary space that the concentration of the gas that diff passes through the membrane and dissolves in the liquid of the auxiliary space at the prevailing pressures in this space, stays below the saturation concentration of the gas in this liquid.

An embodiment of the invention will be explained in more detail with reference to the drawing which shows a longitudinal section through a compressor where the seal between the piston and the cylinder is formed by a rolling membrane and the connection between the piston and the drive mechanism consists of a movable liquid column.

In the drawing, a cylinder 1 is provided with a reciprocating piston 2. The piston 2 consists of two parts of different diameters, so that an annular surface 3 is formed, and the cylinder 1 likewise consists of two parts of different diameters, so that it forms an annular surface 4. The space 5 that is formed in this way between the piston and the cylinder wall is closed at the top by means of a rolling membrane 6. As the piston and cylinder are designed so that the surfaces 3 and 4 are equal, the volume does not change of the space 5 by the movement of the piston in relation to the cylinder, provided that the rolling diaphragm is not subjected to a change in length. The piston 2 rests on a liquid column 7 which is movable in such a way that its other side is limited by a piston 8 to be driven. The piston 2 delimits on the upper side a space 9 in which there is a gas to be compressed. The space under the rolling membrane is completely filled with liquid.

The room 9 is through an inlet valve 10 in connection with a gas supply line 11 and through an outlet valve 12 in connection with a drain line 13. The cylinder 11 is fixed on a chassis 14 in which there is a crankshaft 15 with a crankshaft 16 which is connected to a piston rod 17 which in turn is connected to a piston 8. The crankshaft 15 is connected to a drive device not shown.

The compressor also has a regulation mechanism 18. This regulation mechanism consists of a housing 19 which is divided by means of a membrane 20 into two parts 21 and 22. The room 5 below the rolling membrane 6 is through a line 23 in open connection with the room 21 The space 9 above the piston 1 is through a line 24 in open connection with the space 22. The same pressure difference prevails above the membrane 20 as above the roller membrane 6. The membrane 20 also has a valve body 25 which, depending on the position of the membrane, closes or opens for a liquid supply line 26. Furthermore, the regulation mechanism 18 contains a pressure spring 27 which attacks the membrane 20 and with the help of which a desired pressure difference can be set across the membrane 20 or 6. In order to prevent the membrane 20 starting to oscillate in the event of rapid pressure changes, narrowings 23' and 24' are arranged in the connection lines 23 and 24 which dampen any pressure changes. The liquid drain line 26 opens into a liquid container 28. The liquid container 28 is further connected to a line 29 in which a liquid pump 30 is arranged. The other end of the line 29 opens into the cylinder 1.

A third line 31 is also connected to the liquid container 28, the other end 32 of which opens into the cylinder 1. The mouth 32 is chosen so that it is only free when the piston 2 takes its top position and the position of the mouth 32 determines the top position of the piston.

The compressor works on the following

manner:

When the crankshaft 15 is driven, the piston 8 will move and its movement is transferred to the piston 2 by means of the moving column of liquid 7. As a result, the gas in the space 9 is compressed. In order to achieve a good effect of the rolling diaphragm 6, it is desirable that the this maintains an approximately constant pressure difference. The regulation mechanism 18 ensures this and it works as follows. With the correct pressure difference across the roller membrane 6, the membrane 20 under the influence of the forces exerted by the liquid in the space 21, the pressure spring 27 and the gas pressure in the space 22, assumes such a position that the mouth of the liquid drain line 26 in the space 21 is closed by means of the valve body 25. If the pressure difference across the roller membrane decreases, because the same pressure difference prevails above the membrane 20, the membrane 20 and thereby also the valve body 25 will be pushed upwards by means of the spring 27 so that the drain line 26 is opened and liquid from room 5 passes through the line 23 and the space 21 can flow away until the correct pressure difference is again created over the roller membrane 6.

As the roller membrane 6 is completely impermeable to liquid, the gas in the space 9 will be completely free of liquid. This is a very big advantage for systems with gas chambers that must not contain liquid, e.g. air compressors. Even if the roller membrane is completely liquid-tight, the gas can still penetrate. This has the disadvantage that some gas can penetrate into the space 5 so that the liquid is no longer incompressible, which has the effect that the roller membrane 6 does not have a massive but somewhat yielding support and a stretching of the roller membrane by pressure fluctuations in the space 9 can therefore occur.

In order to avoid this disadvantage, according to the invention, the compartment 5 is connected to the liquid column 7 so that liquid from the compartment in which the liquid column 7 is located can flow to the compartment 5 so that an excess of liquid is carried away through the regulation mechanism 18 from the compartment 5. This prevents the concentration of the gas that diffuses into room 5 becomes so large that this manifests itself in the form of gas bubbles in room 5.

In the compressor shown, this connection between the movable liquid column 7 and the chamber 5 consists of a gap 33 between the piston 2 and the cylinder wall 1. It is obvious that this connection can also consist of a very narrow line. The use of the gap between the piston and the cylinder has the additional advantage that there is always sufficient liquid between the piston and the cylinder so that the lubrication of the piston is excellent.

The liquid which according to leakage flows away through the gap 33, the space 5, the line 23, the regulation mechanism 18 and the liquid drain line 26, from the space 7 in which the movable column of liquid is located, and the liquid which flows through the line 31 from the space 7 with each stroke of the piston , is taken back again to the room 7 by means of the pump 30.

Although in this embodiment the cylinder 1 is connected directly to the undercarriage 14, it is obvious that the cylinder 1 with accessories and the undercarriage 14 can be arranged separately as the space below the piston 2 and the space above the piston 8 are connected to each other by a wire.

According to the invention, in addition to a very simple and compact structure, the advantage is also achieved that, despite hydraulic operation of the piston, the gas space remains completely free of liquid, while the occurrence of gas bubbles in the rolling diaphragm's support liquid is completely avoided.

A further advantage is that by using a rolling diaphragm for machines of this type, a larger stroke volume is made possible than with the known diaphragm compressors.

Claims (3)

1. Device with a cylinder and a movable in it, with a drive mechanism connected piston that separates two chambers, where the seal between piston and cylinder consists of a rolling membrane that is arranged between one of the aforementioned chambers and an auxiliary chamber filled with liquid, and where the limitation of the auxiliary space consists not only of the rolling diaphragm, but also of wall parts of the piston and the cylinder which are designed in such a way that they keep the volume of the auxiliary space at least approximately constant during the movement of the piston in the cylinder, and where in the space that is sealed of the roller membrane there is a gas, characterized by the fact that in the second chamber there is a movable column of liquid (7) which, in a manner known per se, forms the connection between the piston (2) and the drive mechanism (8, 15, 16, 17). 2. Device according to claim 1, characterized in that the auxiliary space (5) and the space in which the movable liquid column (7) is located are connected to each other and this connection consists of a gap (33) between the piston (2) and the cylinder wall (1). 3. The device according to claim 2, characterized in that the connection between the auxiliary space (5) and the space in which the movable liquid column (7) is located is dimensioned so that at least as much liquid flows through the connection to the auxiliary space (5) that the concentration of the gas that diffuses through the membrane (6) and dissolves in the liquid of the auxiliary space (5) at the prevailing pressures in this space, remains below the saturation concentration of the gas in this liquid.