EP0301116A1 - Submergible electrohydraulic drive unit for hammering and servicing devices in under water operation - Google Patents

Abstract

A submersible electro-hydraulic drive unit is a multi-purpose device for driving various ramming and working equipment designed for underwater use with a casing (M) with a continuous central receiving shaft (1) for a ramming pile (60, 48) or the respective ramming or Tool (55,47,33,66), annular upper and lower support plates (4,5), an outer casing wall (2) and an inner wall (3) enclosing the receiving shaft (1), with this and the casing wall (2nd ) Pump units (10) each with a hydraulic pump (13) and an associated electric motor (12) are individually or jointly cushioned to a limited extent with respect to the casing (M) and a support plate (4 or 5) for the interchangeable fixing of one in the receiving shaft (1 ) protruding piling device (47.55) or working device (33.37.66) is designed.

Description

The invention relates to a submersible electrohydraulic drive unit for piling and working equipment designed for underwater use, with hydraulic pumps to be driven by electric motors in each case and connected to a pressure medium container, which can be connected to a drive device of the piling or working device via flexible connecting lines.

From DE-GS 24 54 521 a ramming device with an impact body displaceably guided in a housing, a drive piston connected to it and sealingly displaceable in a hydraulic cylinder, and a drive unit connected to the hydraulic cylinder via pressure medium lines and a reversing device are known, each by an electric motor Hydraulic pumps to be driven and a pressure medium container and is guided on the projecting at the upper end of the housing pressure medium cylinder via shock absorbers up and down. This well-known construction has proven itself excellently for ramming work under water, but requires a shape that is precisely adapted to the upper end section of the ramming device and a shock-absorbing sliding guidance of the entire drive unit on the ramming device.

Since the work for the exploitation of raw material deposits located on or under the seabed and the devices and constructions to be installed under water penetrate ever deeper water, and various types of work equipment often have to be used at great depths, it is becoming increasingly difficult to find them with an acceptable level Bringing time and effort to the respective workplaces under water and driving them there with economic efficiency. In principle, it would be possible to design a specially adapted, submersible electrohydraulic drive unit for each individual tool to be used at great depths of water, which can be driven from a power source above water via an electrical supply line leading to the tool under water with much less energy loss than if the hydraulic medium itself would have to be supplied by water from a hydraulic pump via correspondingly long lines. However, since the lowering and later catching up of each of the various devices required for an underwater installation and their aligned introduction into the required working position each require a considerable amount of time, even in favorable weather conditions, and also a correspondingly large number of underwater drive units adapted to the respective working device are carried along must, the limit of economy will be reached relatively soon. This is all the more true because the expensive and technically demanding devices and drive units, although essential to carry out the project, often perform only short-term special work, are then no longer required and therefore remain unused for a long time until the next use.

The object of the invention is now a submersible electro To create hydraulic drive unit of the type mentioned, which can be used economically with a simple, uncomplicated construction for piling equipment, as well as for other underwater work equipment, without noticeably limiting their applicability.

To solve this problem, the submersible electro-hydraulic drive unit of the type mentioned is equipped with the features of claim 1.

With a simple, robust design, this drive unit can be used in a practically unlimited depth of water with a single, multiple or jointly driven pump units in a casing with a central receiving shaft, depending on the energy requirement, and can be used to attach a pile hammer or a vibration piling device depending on the requirements or another underwater working device equipped, for example, with rinsing devices or a rotatable tool carrier. The compact design results in a robust construction that is favorable for the harsh off-shore working conditions, by means of which the expensive piling or working equipment is protected against damage on all sides. Due to the preferably both vertically and horizontally elastically sprung mounting of the pump units relative to the casing, the drive unit can also be used for work associated with strong impacts or vibrations. The energy transfer from the drive unit to the attached implement can take place via appropriate plug-in couplings, which facilitates quick replacement of the implement.

Advantageous further configurations of the drive unit are described in the subclaims.

Due to its special design, the drive unit can also stand or stand on the seabed or an underwater structure hanging on a suspension cable to drive one or more implements lowered on separate suspension cables.

• Figur 1 einen schematischen Längsschnitt durch eine Antriebs­einheit.
• Figur 2 einen Querschnitt durch die Antriebseinheit gemäß Figur 1,
• Figur 3 eine Pumpeneinheit mit Druckmittelbehälter der An­triebseinheit gemäß Figur 1 in abgewickelter Ansicht,
• Figur 4 einen schematischen Längsschnitt durch eine leicht abgewandelte Antriebseinheit mit angebautem Arbeits­gerät,
• Figur 5 einen schematischen Längsschnitt durch eine Antriebs­einheit gemäß Figur 1 mit einem angebauten Vibrations-­Rammgerät,
• Figur 6 einen Querschnitt durch eine Antriebseinheit gemäß Figur 5,
• Figur 7 einen schematischen Längsschnitt durch eine leicht abgewandelte Antriebseinheit mit angebautem Ramm­hammer,
• Figur 8 eine teilweise geschnitttene schematische Ansicht einer das Hammergehäuse eines Rammhammers umschlie­ßenden Antriebseinheit,
• Figur 9 einen schematischen Längsschnitt durch eine Antriebs­einheit gemäß Figur 1 mit angebautem Spülgerät,
• Figur 10 einen schematischen Längsschnitt durch eine abgewan­delte Antriebseinheit mit angebautem Spülgerät,
• Figur 11 eine Pumpeneinheit der Antriebseinheit gemäß Figur 10 in abgewickelter Ansicht,
• Figur 12 eine andere Ausführungsform einer Pumpeneinheit der Antriebseinheit gemäß Figur 10,
• Figur 13 eine weitere abgewandelte Ausbildung der Pumpenein­heiten einer Antriebseinheit gemäß Figur 10,
• Figur 14 eine schematische Darstellung des Antriebs eines Rammgerätes durch eine auf dem Meeresboden abge­setzte Antriebseinheit,
• Figur 15 einen teilweisen Längsschnitt durch den Drehkopf der Antriebseinheit gemäß Figur 14,
• Figur 16 eine schematische Darstellung einer auf einer Unterwasser-Struktur abgesetzten Antriebseinheit mit Zusatz-Druckmittelbehälter und
• Figur 17 einen schematischen Längsschnitt durch eine An­triebseinheit gemäß der Figuren 1 und 16 mit an­gebautem Zusatz-Druckmittelbehälter.

In the following preferred embodiments of the drive unit are further explained with reference to the accompanying drawings. Show it:

• 1 shows a schematic longitudinal section through a drive unit.
• FIG. 2 shows a cross section through the drive unit according to FIG. 1,
• FIG. 3 shows a pump unit with a pressure medium container of the drive unit according to FIG. 1 in a developed view,
• FIG. 4 shows a schematic longitudinal section through a slightly modified drive unit with an attached implement,
• 5 shows a schematic longitudinal section through a drive unit according to FIG. 1 with an attached vibratory piling device, FIG.
• FIG. 6 shows a cross section through a drive unit according to FIG. 5,
• FIG. 7 shows a schematic longitudinal section through a slightly modified drive unit with a ramming hammer attached,
• FIG. 8 shows a partially sectioned schematic view of a drive unit enclosing the hammer housing of a ramming hammer,
• FIG. 9 shows a schematic longitudinal section through a drive unit according to FIG. 1 with an attached flushing device,
• FIG. 10 shows a schematic longitudinal section through a modified drive unit with an attached flushing device,
• FIG. 11 shows a pump unit of the drive unit according to FIG. 10 in a developed view,
• FIG. 12 shows another embodiment of a pump unit of the drive unit according to FIG. 10,
• FIG. 13 shows a further modified design of the pump units of a drive unit according to FIG. 10,
• FIG. 14 shows a schematic illustration of the drive of a pile driver by a drive unit set down on the seabed,
• FIG. 15 shows a partial longitudinal section through the rotary head of the drive unit according to FIG. 14,
• FIG. 16 shows a schematic illustration of a drive unit with additional pressure medium container and placed on an underwater structure
• 17 shows a schematic longitudinal section through a drive unit according to FIGS. 1 and 16 with an attached additional pressure medium container.

The drive unit shown in FIGS. 1 to 3 has a substantially cylindrical casing M with an annular upper support plate 4 with a lifting eye 44, an annular lower support plate 5, a cylindrical outer casing wall 2 connecting them and a cylindrical inner wall concentric with this 3, which encloses a continuous receiving shaft 1. While the outer jacket wall 2 is rigidly connected to the support plates 4 and 5 by threaded bolts 23 screwed into threaded bores arranged at their ends, the inner wall 3 has through-openings 9 arranged in its upper and lower sections distributed over the circumference and is in the jacket wall 2 Loosely centered by means of annular centering elements 6 in the embodiment shown and by hydraulic cylinders 7 with pistons 8 projecting outwards against the upper support plate 4 or the lower support plate 5 which are arranged on the upper edge or the lower edge and each contain prestressed gas or are connected to a hydraulic accumulator (not shown) supported on both sides. Instead of the hydraulic cylinders 7, spring cylinders acted upon by high gas pressure or appropriately preloaded elastic means can also be used. Similar, prestressed hydraulic cylinders 7 are also attached to the passage openings 9 of the inner wall 3, the pistons 8 of which protrude inwards into the receiving shaft 1 and an elastic support of the inner wall 3 against a ram inserted into the receiving shaft 1 allow pile or a piling or working device arranged in it.

In the illustrated embodiment, five pump units 10, each arranged at the same circumferential spacing, each consisting of a vertically oriented, submersible electric motor 12 and a hydraulic pump 13 connected coaxially with its lower end are arranged in the annular space 22 between the jacket wall 2 and the inner wall 3. Each pump unit 10 is supported on a supporting projection of the inner wall 3 via elastic support elements 11. The pump units 10 each have associated, essentially cylindrical pressure medium containers 14, which are each attached to the inner wall 3 in a vertically aligned manner between adjacent pump units 10. Each hydraulic pump 13 is connected on the one hand via a connecting line 21 with a built-in vibration-damping expansion compensator 24 to the lower part of the associated pressure medium container 14 and, on the other hand, via a hose-like connecting line 18 with a collecting connection 19, from which the pressure medium via further hose lines, not shown, to the ramming or driven Tool is fed. The return flow of the pressure medium from the ramming or working device also takes place via the collecting connection 19, which communicates via a connecting line 20 with the upper part of the associated pressure medium container 14. Since each pump unit 10 has its own elongated cylindrical pressure medium container 14, effective cooling of the pressure medium by the surrounding water is achieved at the same time. The electric motors 12 are each connected via a separate electrical line 17 to a watertight junction box 16, to which an umbilical 15 which is led down from an energy source over water and can be connected in a watertight manner with a number of separate electrical power lines corresponding to at least the number of electric motors 12. At its upper end, each pressure medium container 14 contains, on the one hand, an opening 27 with the interior the pressure medium container 14 and on the other hand via an outer opening 28 with the environment communicating cylinder 25 with a displaceable floating piston 26. Through this arrangement, the pressure in the pressure medium container 14 is always automatically adjusted to the pressure of the surrounding water via the floating piston 26, so that on the one hand the container wall 29 is not exposed to any external overpressure and, on the other hand, the pressure medium of the hydraulic pump 13 in each case runs in quickly. Since the connecting lines 20 running from the collecting connections 19 to the associated pressure medium containers 14 are connected to one another by a ring line 30, even in the event that a floating piston 26 is stuck in the pressure medium container 14 concerned, pressure equalization is nevertheless produced via the floating holes 26 of the remaining pressure medium containers, so that the system remains functional.

In operation, the hydraulic pump 13 sucks pressure medium from the pressure medium container 14 via the connecting line 21 and leads it via the hose line 18 and the collecting connection 19 to the ramming or working device to be driven, while the returning pressure medium runs back from the collecting connection 19 via the connecting line 20 into the pressure medium container 14 .

Since the pump units 10 and the pressure medium containers 14 are attached in a uniformly distributed manner over the circumference of the cylindrical casing M, the drive unit causes practically no tilting of the same when connected to a ramming or working device.

The drive unit shown in FIG. 4 according to FIG. 1 carries a working device detachably connected to the upper support plate 4 by threaded bolts 23 with a work spindle 33 which can be driven by hydraulic motors 31 and a gear 32, which extends through the receiving shaft 1 and on the lower support plate 5 concentrically attached guide tube 34 extends coaxially and is connected at its free lower end to a replaceable tool carrier 37 in a rotationally fixed manner. The working Spindle 33 is rotatably supported by radial bearings 35 arranged in the support plates 4 and 5 and in the guide tube 34, and is additionally secured against vertical displacements by axial bearings 36 which cooperate with a support plate 4 and 5, respectively.

The hydraulic motors 31 are driven by pressure medium supplied by the hydraulic pumps 13 via the hose line 18, the collecting connection 19 and a connecting line 41, which then flows back to the pressure medium container 14 via the connecting line 42, the collecting connection 19 and the connecting line 20. In addition, the implement is supplied with power via the connection box 16 connected to the umbilical 15 and a supply line led via a connection 43. To support the umbilical 15, an essentially semicircular support element 46 is attached to the upper support plate 4, on which the loop-like sagging umbilical 15 is placed. The working device connected to the drive unit is suspended by means of a lifting eye 44 pivotably articulated at its upper end on a suspension cable 45 of a crane arranged on a workshop ship, not shown, and is lowered and raised to the desired water depth together with the drive unit. If necessary, the working device connected to the drive unit can also be used in an inclined to horizontal orientation by means of additional devices (not shown), for example, additional support elements which engage the guide tube 34 or the lower support plate 5.

The tool holder 37, which is snapped on at the lower end of the work spindle 33, is provided with conventional devices for the interchangeable mounting of work tools, not shown, for carrying out cutting, machining, grinding, sawing and drilling work and / or flushing, pressure jet or burning work. As far as these work tools can be supplied with pressure media, gases or electrical current these are supplied through supply lines, not shown, which run inside the hollow work spindle 33, at the upper end of which, via a conventional rotary feedthrough 39, only shown schematically, with a pump or corresponding supply lines in the umbilical 15, and through an outlet opening 40 adjacent to the tool carrier 37 with the are connected to work tools to be supplied.

5 and 6, a drive unit which is modified only with regard to the cross-section of the jacket wall 2, the inner wall 3 and the receiving shaft 1, which is rectangular here, is shown with a vibration piling device 47 detachably fastened to its upper support plate 4 by means of threaded bolts 23. The lower support plate 5 is provided with an insertion cone 53 for a ram pile 48 which is essentially rectangular in cross section. Otherwise, the drive unit corresponds to the explanations given above in connection with FIGS. 1 to 3.

The vibratory pile driver 47 is provided in the usual manner with unbalance motors 49, which are only indicated schematically, and rests on the pile pile 48 which extends through the receiving shaft 1 and whose upper end edge engages in a recess 50 on the underside of the vibratory pile driver 47. For optimal transmission of the vibrations to the ramming pile 48, the vibrating ramming device is provided with horizontally oriented press cylinders 51, the pistons 52 of which are pressed firmly against the outer wall of the ramming pile 48 by supply of pressure medium from the drive unit, which results in a firm, frictional connection which is favorable for the transmission of the vibrations will be produced. The connection lines to at least one hydraulic pump 13 of the drive unit required for supplying the pressure cylinders 51 with pressure medium and the corresponding switching elements are not shown in FIG. 5 for reasons of clarity. The signal transmission to the vibration piling device 47 takes place via a signal line 54. This with the drive unit The connected vibratory piling device 47 is lowered via a lifting eye 44 pivotably articulated at the upper end and a carrying rope 45 guided through it so that the driving pile 48 is inserted into the receiving shaft 1 through the insertion cone 53 until the recess 50 of the vibrating piling device 47 on the upper edge of the pile. In operation, the vibratory pile driver 47 is supplied with pressure medium from the drive unit via the connecting lines 18 and 20, which drives the unbalance motors 49 in a conventional manner to generate a vibration with a frequency and amplitude suitable for driving the pile driver 48, via corresponding hydraulic motors.

In the drive unit shown in FIG. 7, the lower support plate 5 is provided on the one hand with an integrally machined insertion cone 59 and on the other hand with a guide tube 61 extending upwards through the receiving shaft 1 for a cylindrical ramming pile 60. The upper support plate 4 is detachably connected to a fastening flange 62 attached to the outer circumference of the hammer housing 63 of a ramming hammer 55 by means of threaded bolts. In the hammer housing 63, an impacting body (not shown) is usually displaceably guided upwards and downwards, which is connected via a piston rod to a piston which can be displaceably sealed in a hydraulic cylinder. The chambers of the hydraulic cylinder, not shown, are connected to the common connection 19 of the drive unit via a conventional reversing device, not shown, a connection 64 and two hose lines 56 and 57. The pressure medium conveyed by the hydraulic pumps 13 flows via the hose line 18, the collecting connection 19 and the hose line 56 to the connection 64, while the pressure medium displaced from the hydraulic cylinder flows back via the hose line 57, the collecting connection 19 and the connecting line 20 to the pressure medium containers 14. The electrical control and monitoring signals required for the operation of the ramming hammer are transmitted via a signal line 58 transfer.

In this embodiment, the inner wall 3 of the drive unit, which carries the pump units 10 and the pressure medium containers 14, is resiliently supported at the top and bottom via the pistons 8 of the hydraulic cylinders 7 against the outer surface of the guide tube 61, so that the pump units 10 and the pressure medium containers 14 are driven by the ramming of the ramming hammer 55 are not affected. This is all the more true since the hammer housing 63 is expediently also resiliently supported on the striking plate S resting on the driven pile 60 by prestressed spring devices, in particular hydraulic cylinders connected to hydraulic accumulators, with outwardly projecting support pistons.

To drive ram piles 60 of large diameter, the drive unit can also be modified by omitting the guide tube 61, so that the pistons 8 of the horizontal hydraulic cylinders 7 are resiliently supported directly against the ram pile 60. In both cases, the drive unit expediently simultaneously forms the pile collar which is anyway required for guiding the driven pile 60.

In the arrangement shown in FIG. 8, the drive unit with the lower support plate 5 is lowered from above over the outer circumference of the hammer housing 63 to an attachment flange 62 projecting outward thereon, the lower support plate 5 advantageously being releasably secured to the attachment flange. In this arrangement, since the drive unit encloses the main part of the hammer housing 63, there is in some cases an advantageously shorter overall length of the device to be lowered. In the embodiment shown, the hammer housing 63 is, however, provided with a pile collar 65 attached to the underside of the fastening flange 62, which ensures a secure, free-running fit on the driven pile 60. This arrangement also enables driving of ram piles 60 with a very large diameter can no longer be accommodated in the receiving shaft 1 of the drive unit.

In the arrangement shown in FIG. 9, the lower support plate 5 is detachably connected via threaded bolts 23 to the mounting flange 74 of a flushing device 66, which has a flushing pipe 72 passing through the receiving shaft 1 with a built-in check valve 73 and a plurality of pump units 67 arranged at the upper end of the flushing pipe 72 Each has a water pump 68 driven by a hydraulic motor 70, which sucks in sea water surrounding a suction opening 69 and conveys it into the rinsing pipe 72 via assigned inlet openings 71. In the arrangement shown, the flushing device 66 is fixed in a liquid-tight manner by means of a coupling part 76 acting in the manner of a bayonet lock on a lockable oil delivery device 75 arranged on the seabed. The hydraulic motors 70 are supplied with pressure medium from the hydraulic pumps 13 of the drive unit via the hose line 18, the collecting connection 19 and the connecting line 41, which then flows back via the connecting line 42, the collecting connection 19 and the connecting line 20 to the pressure medium container 14. The check valve 73 allows the pressurized water flow conveyed by the water pumps 68 to pass to the oil delivery device 75 and the borehole below it, but conversely prevents any leakage in the direction of the flushing pipe 72.

In this way, by means of the universally applicable drive unit with the simple flushing device attached to it, pressurized water can be pressed in economically through a borehole into an oil deposit in order to squeeze out otherwise unavailable amounts of oil elsewhere in the deposit and thus make it more productive. A major advantage is that there is no need to use an expensive, long, high-pressure hose of large diameter from the ship to the borehole that is at risk of damage.

This advantage is greater the higher the water pressure required and the greater the depth of the water.

In the embodiment shown in FIGS. 10 and 11, the drive unit has pump units 67 installed in the annular space 22 between the casing wall 2 and the inner wall 3, each with a hydraulic motor 70 connected to an associated hydraulic pump via a connecting line 80 and a water pump 68 connected to this which communicates with the flushing pipe 72 via an inlet opening 71 passing through the inner wall 3. This results in an even shorter and more compact design. In the arrangement shown, the flushing device 66 is connected by means of a coupling part 76 acting in the manner of a bayonet lock to a connecting piece 83 which is fixed to an inspection flange 77 of a pipeline 78 laid on the seabed. The flushing device 66 connected to the drive unit is lowered and raised by means of a lifting eye 44 which is pivotably articulated at its upper end and a carrying rope 45 which is guided through it.

In the modified embodiment shown in FIG. 11, the pump units 10 and 67 are each elastically supported on support supports 79 attached to the pressure medium container 14 via elastic support elements 11. The pressure medium containers 14 are in turn releasably attached to a bracket 85 on the inner wall 3 of the drive unit. In this way, each pressure medium container 14 together with the associated electric motor 12, the hydraulic pump 13 driven by it, the hydraulic motor 70 and the water pump 68 driven by it can be quickly and easily installed and removed in the annular space 22 accessible after detachable segments of the jacket wall 2 will. The pressure medium conveyed by the hydraulic pump 13 via the connecting line 80 to the hydraulic motor 70 flows back via a connecting line 81 to the connection 82 of the pressure medium container 14. For this the pressure medium is sucked in by the hydraulic pump 13 via a connection 84 and the connecting line 21.

In the modified arrangement shown in FIG. 12, the electric motor 12 fastened to the inner wall 3 via support elements 88 and 89 drives the water pump 68 connected to it via a support plate 87 directly via a gear 86.

In the embodiment shown in FIG. 13, the water pump 68 and the electric motor 12 are connected coaxially to a unit which is fastened to the inner wall 3 via support plates 90 and 91. This embodiment is suitable for cases in which a direct drive of the water pump 68 is permitted without speed transmission.

The embodiments described above with reference to FIGS. 1 to 13 can of course be modified in a variety of ways depending on the requirements of the intended use, in order to use a complete drive unit by optional modular assembly of the ramming or working equipment required for the respective working purpose Few fastening parts and plug connections or at most certain modifications of individual parts to achieve the universal use of the drive unit for different devices. In this connection, the drive unit can also be designed such that it drives a ramming or working device, which is spaced apart from it on its own support element, on its own connecting lines in a position set down on the seabed or an underwater structure or hanging on a support element.

For this purpose, the drive unit shown in FIGS. 14 and 15, which is set down on the sea floor, can be released on the one hand to increase its stability with a base plate 96 which may be fastened to the lower support plate 5 and on the other hand with a threaded bolt 97 with the upper support plate 4 connected turret 92 provided. This has a pivot 102, which is rotatably mounted in a housing 103, with a central through-channel 107 for the umbilical 15 and two through-channels 104 and 105, each of which lead to an annular groove recessed in the peripheral surface of the pivot 102 and via this irrespective of the rotational position of the pivot 102 communicate with an associated connecting line 41 or 42 and are each connected at their other end to an associated, longer connecting hose 100 or 101. To avoid kinks, these are guided over a toroidally curved support surface of an annular collar 106. Since the rotary head 92 can be freely rotated through 360 °, the hose lines 100 and 101 can run without difficulty to a ramming hammer 94, which sits freely on a ramming pile 93 pre-installed in a guide device 95 at a greater lateral distance from the drive unit. The umbilical 15 is carried by a plurality of buoyancy containers 98, the buoyancy of the bottom buoyancy container 98 being dimensioned such that it holds the section of the umbilical 15 above the drive unit tautly vertically, while the other buoyancy containers 98 the umbilical 15 each step-like, forming sagging loops 99 lead to the water surface.

In this way, several ram piles 93 pre-installed in the vicinity of the drive unit set down on the sea floor can be driven in succession with the same ram hammer 94 without the drive unit having to be displaced for this purpose. In the arrangement shown in FIG. 14, the ram pile 93 shown on the right was first rammed in and the ram hammer 94 was then transferred to the preinstalled ram pile 93 shown on the left. For example, several driven piles pre-installed on an offshore platform can be driven in to save time and labor.

In the arrangement shown in FIG. 16, the drive unit is arranged on an underwater structure 115 or also on a ship's deck above water and connected to a hydraulically driven vibration piling device 47 via longer hose lines 100 and 101. The vibration piling device 47 is intended to shake a larger number of anchor piles 108 with anchor chains 116 attached to them to hold an underwater structure (not shown) in the seabed. The required electrical energy is in turn supplied to the drive unit via an umbilical 15. Since the longer hose lines 100 and 101 leading from the drive unit to the vibratory ramming device 47 accommodate a pressure medium filling quantity which is dependent on their diameter, the quantity of pressure medium remaining in the pressure medium containers 14 can be so small that the supply of the hydraulic pumps 13 with pressure medium does not occur more is guaranteed. In order to avoid this, the drive unit is provided in the manner shown in FIG. 17 with an additional pressure medium container 109 inserted into the receiving shaft 1, which is held on the upper support plate 4 and communicates with the pressure medium containers 14 via a connecting line 110. If the drive unit is not set up under water but on a ship's deck, the floating piston 26 in the cylinder 25 is no longer pressed so strongly against the pressure medium in the pressure medium container 14 because of the lack of water pressure on its outer surface and the friction of its seal. Although due to the difference in height between the drive unit and the working device arranged at a greater depth, the pressure medium should still flow rapidly via the hose line 100, the oscillating mode of operation can nevertheless cause the pressure medium supply to be cut off briefly, which is damaging to the hydraulic motors in the long run. For this reason, the drive unit for use over water is provided with an air line 111 running parallel to the umbilical 15 via the support element 106 to the upper side of the additional pressure medium container 109 to generate a prestress promoting the inflow by slight overpressure. The compressed air space 112 created by the removal of pressure medium in the additional pressure medium container 109 serves at the same time as a buffer space which receives the pressure medium quantities flowing back in an oscillating manner via the hose line 100 without undesired pressure peaks.

In order to achieve the cooling of the electric motors 12 and the hydraulic pumps 13 that occurs during underwater use due to the surrounding water even when the drive unit is installed above water, a cooling water line 113 is introduced into the interior of the drive unit, which is delimited by the jacket wall 2 which is sealingly connected to the base plate 96 is. The cooling water then flows out of the interior via a drain line 114. In this way, the pump units 10 and the hydraulic oil in the pressure medium containers 14 and 109 are cooled in the same way as when used under water.

The drive unit explained above with reference to preferred embodiments can be modified by the person skilled in the art in various ways depending on the requirements of the individual case, provided that it is designed as a multipurpose drive unit for various ramming or working devices to be optionally installed and a jacket housing with a central receiving shaft and ring-shaped upper and lower support plates for fixing the device to be operated in each case and between the receiving shaft and an outer jacket wall, which are arranged in a spring-loaded manner by pump units and pressure medium containers.

Claims (28)

1. Submersible electrohydraulic drive unit for ramming and working equipment designed for underwater use, with hydraulic pumps to be driven by electric motors in each case and connected to a pressure medium container, which can be connected via flexible connecting lines to a driving device of the ramming or working device, characterized in that a) the drive unit as a multi-purpose device for driving various pile driving and working devices with a jacket housing (M) which can be lowered under water on a support element (45) with a continuous, central receiving shaft (1) for a pile driver (60, 48) or the respectively required Ramming or working device (55,47,33,66) is formed, b) the casing (M) has ring-shaped upper and lower support plates (4 and 5), an outer casing wall (2) connected to them, and an inner wall (3) surrounding the receiving shaft (1), c) the hydraulic pumps (13), each with an associated electric motor (12), preferably parallel to one another at circumferential intervals between the inner wall (3) and the jacket wall (2) pump units (10) arranged to the receiving shaft (1) are connected, d) the pump units (10) are cushioned individually or together with respect to the casing (M) at least in the direction parallel to the receiving shaft (1) and can be moved to a limited extent and e) the upper support plate (4) and / or the lower support plate (5) for the optional, exchangeable fixing of a ramming hammer (55) or working device (33, 37; 66) or a vibrating ramming device (47) protruding into the receiving shaft (1) are designed. 2. Drive unit according to claim 1, characterized in that the pump units (10) on the inner wall (3) of the casing (M) are fixedly or preferably elastically supported and the inner wall (3) against the upper and lower support plate (4, 5) is resiliently supported on both sides. 3. Drive unit according to claim 1 or 2, characterized in that the pump units (10) or the inner wall (3) carrying them are cushioned by prestressed spring devices, preferably with a prestressed hydraulic accumulator hydraulic cylinder (7) with pistons (8) projecting therefrom are. 4. Drive unit according to one of claims 1 to 3, characterized in that the inner wall (3) of the casing (M) is guided by centering elements (6) in the outer casing wall (2) to a limited extent and with circumferentially spaced spring devices, in particular prestressed Hydraulic cylinders (7) with radially inwardly projecting pistons (8) for resilient support against an implement (55, 33, 66, 47) located in the receiving shaft (1) or a ram pile (48; 60) is provided. 5. Drive unit according to one of claims 1 to 4, characterized in that the pump units (10) each in substantially cylindrical pressure medium containers (14) with a longitudinal axis coaxial or parallel to the longitudinal axis of the electric motor (12) are assigned. 6. Drive unit according to one of claims 1 to 5, characterized in that the pump units (10) and the pressure medium container (14) between the outer casing wall (2) and the inner wall (3) are alternately attached to each other in the circumferential direction. 7. Drive unit according to one of claims 1 to 6, characterized in that the outer casing wall (2) and the inner wall (3) of the casing housing (M) are each concentric and substantially cylindrical. 8. Drive unit according to one of claims 1 to 7, characterized in that the outer casing wall (2) of the casing housing (M) is completely or partially removable. 9. Drive unit according to one of claims 1 to 8, characterized in that the upper and lower support plate (4,5) are designed to be interchangeable. 10. Drive unit according to one of claims 1 to 9, characterized in that the pump units (10) are individually operable and are each connected via separate electrical lines (17) to a watertight connection box (16), to which one with a corresponding number of separate Umbilical (15) provided with electrical lines can be connected in a watertight manner. 11. Drive unit according to one of claims 1 to 10, characterized in that the pressure medium containers (14) are communicatively connected to each other and their interior for automatic pressure adjustment to the ambient pressure in each case via a floating piston (26) or a flexible partition sealingly closed pressure compensation opening ( 27,28) is connected to the environment. 12. Drive unit according to one of claims 1 to 11, characterized in that the lower support plate (5) additionally carries a guide tube (61) enclosed by the inner wall (3) of the casing (M) for a ram pile (60) and the inner wall ( 3) is resiliently supported on the outer circumference of the guide tube (61). 13. Drive unit according to one of claims 1 to 11, characterized in that the receiving shaft (1) has an insertion of the hammer housing (63) of a ramming hammer (55) permitting clearance and at least one support plate (4,5) for optionally sprung attachment is designed on and / or releasable fixed positions on at least one projection (62) on the outer circumference of the hammer housing (63). 14. Drive unit according to one of claims 1 to 11, characterized in that the upper support plate (4) for releasably fixing a working device with at least one with the hydraulic pumps (13) or the pressure medium containers (14) each via connecting lines (41 and 42 ) Connectable hydraulic motor (31), a drive spindle (33) which can be driven thereby and is rotatably mounted in the support plates (4, 5) is designed for at least one tool carrier (37) which can be preferably exchangeably attached to the end protruding from the receiving shaft (1). 15. Drive unit according to claim 14, characterized in that at least one of a pump via a rotary leadthrough (39) through the hollow work spindle (33) to the tool carrier (37) extending supply line is provided for an associated tool. 16. Drive unit according to claim 14 or 15, characterized in that on the lower support plate (5) to the receiving shaft (1) coaxially projecting down guide tube (34) with at least one pivot bearing (35,36) for the work spindle (33) detachably attached is. 17. Drive unit according to one of claims 1 to 11, characterized in that the upper support plate (4) is designed for releasable fixing with a ramming pile (48) inserted into the receiving shaft (1) non-positively connectable vibration piling device (47). 18. Drive unit according to one of claims 1 to 11, characterized in that at least one support plate (4,5) for releasably fixing a flushing device (66) lying in the receiving shaft (1) with at least one, preferably by connecting lines (41, 42) with the Hydraulic pumps (13) or the hydraulic motor (70) that can be connected to the pressure medium containers (14), at least one water pump (68) that can be driven thereby, a flushing pipe (72) connected to its pressure side and running through the receiving shaft (1), and a coupling part that surrounds its mouth ( 76) is designed for releasable attachment to an underwater device (75) to be rinsed. 19. Drive unit according to claim 18, characterized in that at least one pump unit (10) in the space between the outer casing wall (2) and the inner wall (3) attached water pump (68) is assigned, which by a via connecting lines (80,81 ) with a hydraulic pump (13) or a pressure medium container (14) connected hydraulic motor (70) can be driven. 20. Drive unit according to claim 19, characterized in that at least one water pump (68) by an electric motor (12) can be driven directly or via a gear (86). 21. Drive unit according to one of claims 1 to 20, characterized in that the upper support plate (4) for releasably fixing a protruding into the receiving shaft (1), via a connecting line (110) with the pressure medium container (14) connected additional pressure medium container (109) is designed. 22. Drive unit according to one of claims 1 to 21, characterized in that the upper support plate (4) for optional fixing of a rotary head (92) communicating with the connecting lines (41, 42) with guide devices (106) for connecting lines (100, 101) from the Drive unit is designed for at least one laterally offset ramming or working device (94). 23. Drive unit according to one of claims 1 to 22, characterized in that the upper support plate (4) has devices for hanging attachment to a flexible support element (45). 24. Drive unit according to one of claims 1 to 23, characterized in that the hydraulic pumps (13) and the pressure medium container (14) each via a flexible connecting line (18, 20) with a collecting connection (19) and from this via detachable hose lines (41 , 42; 56, 57) are connected to a hydraulic cylinder or hydraulic motor (31, 70) of the piling or working device to be connected in each case. 25. Output unit according to one of claims 1 to 24, characterized in that switching devices for the divisible supply of the pressure medium flow generated by the hydraulic pumps (13) via assigned hose lines (56, 57) to a number of pile driving or working devices (55, 47, 33, 66) ) are provided. 26. Drive unit according to claim 25, characterized in that the switching devices for supplying volume-adjustable partial pressure flows to ramming or working devices are designed. 27. Drive unit according to one of claims 1 to 26, characterized in that in the mental housing and / or one of the lower support plate (5) projecting downward guide jacket (65) for the ramming part (48, 60) arranged at least one buoyancy container for receiving gas is. 28. Drive unit according to one of claims 1 to 27, characterized by at least one positioning device with a driven propeller or another device for generating a substantially horizontal thrust jet.

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