CS215863B1 - Fluid pressure distribution arrangement for dynamic tests - Google Patents

Abstract

The invention relates to the arrangement of the pressure fluid distribution of a dynamic test facility for testing structural units and structures, which is equipped with electrohydraulic loading systems and a central hydraulic engine room. Each of a large number of separate hydraulic lines to which the loading electrohydraulic systems are connected is connected to one working hydraulic unit. The output pressure pipes of individual hydraulic units, the pressure pipes of individual lines* the return pipes of hydraulic units and the return pipes of hydraulic lines on the side of the units are provided with valves. The pressure and return pipes are interconnected and provided with valves on the connecting pipe. In the event of a failure of any of the hydraulic units, the failed unit can be replaced by an adjacent hydraulic unit by the appropriate adjustment of the valves. Similarly, a hydraulic unit can be used to strengthen the supply to the hydraulic line of an adjacent unit. If, in addition, a backup hydraulic unit is arranged that can be connected to individual hydraulic units and lines, it can similarly be used both to replace one of the hydraulic units and to reinforce one of the hydraulic lines.

Description

BACKGROUND OF THE INVENTION The present invention relates to the arrangement of a pressure fluid distribution system for a dynamic test facility for assemblies and structures equipped with electrohydraulic load systems and a central hydraulic engine room with a plurality of hydraulic units.

Large dynamic test laboratories for assemblies and whole structures are usually equipped with electrohydraulic loading systems. The pressurized oil sources for these load systems are often concentrated in the central hydraulic engine room, from where the oil is fed to the individual load systems by hydraulic distribution. The different pressure oil consumption for individual tests, the requirement for fail-safe backup and the design limitation of the power output of the pumps make it necessary to install several hydraulic units in the hydraulic engine room to ensure the required hydraulic output. The hydraulic units are connected in parallel to the hydraulic distribution system, which forms a uniform network, to which the offtakes for the individual test load devices are again connected in parallel.

The nature of the pressure oil withdrawal for the individual electrohydraulic servo load systems is characterized by a large diversity of dynamic courses, so that it is not possible to determine a typical operating mode in terms of both the amplitude of the offsets and the frequency. However, the required dynamic test runs produce periodic system oscillations, which are transmitted as hydraulic network pressure oscillations. These dynamic phenomena in the hydraulic system cause interactions between individual load systems, make control difficult and impair the accuracy of the required load curves. The parallel operation of a series of hydraulic power units equipped with autonomous automatic constant-pressure controls does not allow optimum adjustment of the operation of the individual power units to the total consumption, resulting in energy losses.

. These disadvantages are confronted with the arrangement according to the invention, which is based on the fact that the manifold is formed as a plurality of separate hydraulic lines, each connected to one hydraulic unit and to at least one separate load system. Each hydraulic power unit is provided with a shutter on its outlet pressure line and another shutter on its return line, each hydraulic assembly is provided on its side of the hydraulic power unit with a shutter on the pressure line and another shutter on the return line. The pressure lines of the adjacent hydraulic power units are interconnected and a shutter is provided in each interconnection line and the return lines of the adjacent hydraulic power units ^J are interconnected and a shutter is provided in each interconnection line.

If the hydraulic engine room is equipped with a standby hydraulic power unit, the hydraulic power outlet piping is connected to the standby power outlet piping and these interconnecting pipelines are provided with shutters and the hydraulic unit return piping is connected to the backing pipeline of the backup aggregate and provided with shutters. All shutters and interconnecting piping are located on the hydraulic board.

The arrangement according to the invention allows autonomous feeding of individual dynamic tests or individual load servo systems with one or two hydraulic units. By means of hydraulic pipes and closures a number of variants of connection of individual hydraulic units to hydraulic systems are possible. In the arrangement according to the invention, all the shutters are concentrated on an accessible and well arranged plate hydraulic distributor which is located in the hydraulic machine room immediately next to the hydraulic aggregates and allows the operator to easily and transparently select the most suitable variant of the aggregates to the hydraulic systems and thus to the electrohydraulic loading systems of the dynamic test facility.

The arrangement according to the invention avoids dynamic interactions while carrying out various tests in a dynamic test facility, which greatly facilitates the control of the individual electrohydraulic load servomechanisms and improves the load accuracy. Separate assignment of one or two hydraulic units to the hydraulic system eliminates the possibility of interacting with the autonomous pressure controls, which occurs when the pressure pipes of multiple units are connected in parallel and which can lead to disturbance of stability and energy losses. The arrangement according to the invention allows for a variety of fail-over modes on one or more aggregates, thus avoiding longer test interruptions

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-from dynamic testing room. At the same time, even in the case of a standstill, the principle of separate feeding of hydraulic orders is not violated. Further, the arrangement according to the invention makes it possible, if such a variant is provided for in the dimensioning of the individual lines of piping, to use one of the aggregates to enhance the supply of oil to the hydraulic line, i.e.. parallel connection of two units can double the hydraulic power of one order for particularly demanding dynamic tests.

If preferred, the arrangement according to the invention does not exclude the formation of a central pressure network or several separate partial pressure networks. Separate connection of hydraulic units to hydraulic lines or the creation of several mutually separate pressure networks allows optimum selection of source power and working pressure individually for each test in the dynamic test room, which brings significant energy savings especially in long-term tests.

An exemplary embodiment of the invention is further explained by means of a general arrangement diagram.

The diagram shown in the figure shows the connection of a large dynamic test facility, the hydraulic engine room of which is equipped with four working hydraulic units, a first hydraulic unit 1, a second hydraulic unit 2, a third hydraulic unit 3 and a fourth hydraulic unit 4 and a backup hydraulic unit 5. The oil for the test halls is realized by four separate hydraulic orders, the first hydraulic order 6, the second hydraulic order 2, the third hydraulic order 8 and the fourth hydraulic order 2 · Electrohydraulic load servo systems (not shown) are connected to individual hydraulic orders. Each of the working hydraulic power units has a cap on its outlet pressure line. The first hydraulic power pack closes 10. The second hydraulic power pack closes 11. The third hydraulic power pack closes 12 and the fourth hydraulic power pack closes 13. Each hydraulic assembly is provided with a shut-off on the pressure line on the side of the power pack. The first hydraulic order 6 by the shutter 14. The second hydraulic order 2 by the shutter 15. The third hydraulic order 8 by the shutter 16 and the fourth hydraulic order 9 by the shutter 17. There are closures on the connecting pressure line of the neighboring hydraulic power units. a closure 18, between the second hydraulic power unit 2 and the third hydraulic power unit 2, the closure 19, and between the third hydraulic power unit 3 and the fourth hydraulic power unit 6, the closure 20. Similarly to the outlet pressure line, each hydraulic power unit is provided with the first hydraulic power unit 1 by the closure 25. the second hydraulic power unit 2 by the closure 26, the third hydraulic power unit 3 by the closure 27 and the fourth hydraulic power unit 4 by the closure 28. Likewise, each hydraulic system on the return line on the aggregate side is provided with a closure. The first hydraulic order 6 by the shutter 29. The second hydraulic order 7 by the shutter 30. The third hydraulic order 8 by the shutter 31 and the fourth hydraulic order 2 by the shutter 32.

There are also closures on the interconnecting return line of adjacent hydraulic units between the first hydraulic unit 1 and the second hydraulic unit 2 of the closure 33, between the second hydraulic unit 2 and the third hydraulic unit 3 of the closure 34 and between the third hydraulic unit 3 and the fourth hydraulic unit. 35.

The back-up pressure line of the back-up unit 5 is connected to the outlet pressure line of all four working hydraulic units 1, 2, 2 and 4, through the first shutter 21 with the fourth hydraulic unit 6, through the second shutter 22 with the third hydraulic unit 3, through the third shutter 23 with the second hydraulic power unit 2 and through the fourth cap 24 with the first hydraulic power unit 1.

Return line backup unit 2 J® connected with the return line of the four working hydraulic units 1, 2, £ 2 ^and, via the first cap 36, a fourth hydraulic aggregate £ through the second shutter 37 ae third hydraulic aggregate 3 via a third seal 38 with the second hydraulic power unit 2 and through the fourth shutter 39 with the first hydraulic power unit 1. The tanks of all hydraulic power units are connected by the unpressurized ροί · Ί 'through the first line 40 between the hydraulic unit 1 and 2, the second line 41 and the street aggregate 2 and 3. through a third line 42 between the hydraulic power unit 2 ^{and the} pipe 43 between the hydraulic power unit 5 and the reserve hydraulic power unit 5 '.

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All shutters, including their respective interconnecting lines, are located on a well arranged plate hydraulic distributor 44 as shown in FIG.

The basic connection for the separate supply of the balances of hydraulic lines 6, 2, 8 and 2 by four working-hydraulic units 1, 2, 2, 5 assumes opening of shutters 10, 11, 12, output pressure piping of hydraulic units 1,2., 2,1 just as well as the shutters 22, 26, 27, 28 on their return line and the shutters 14, 15, 16, 17 of the hydraulic lines 6, 7, 8 on the outlet pressure line, as well as the shutters 29.30.31.32 ^on their return line. All shutters 18, 19, 20, 22, 21 »35 on the interconnecting piping of pressure and return lines of hydraulic units 1, 2, 2, A and shutters 21, 22, 22, 21, 36, 22, 38, 39 on the outlet are closed. and the return line of the backup hydraulic power unit 2, which remains out of operation.

In the event of a failure of any of the working hydraulic power units, the failing power unit can be replaced by an adjacent working power unit or a back-up power unit 2 · For example, in the event of a failure on the hydraulic power unit 2 replaced by the hydraulic power unit 2. 2, A, closures 14. 12, 17 hydraulic lines 6, 2, 2 ^{on the} pressure line, closure 19 on the connecting pressure line between the second hydraulic unit 2 and the third hydraulic unit 2, the valves 25. 27, 26 on the return line of the hydraulic units 1 , 2, 1, shutters 29, 22, 22 on the return line of hydraulic lines 6, 2, 2 ^and shutter 24 on the connecting return line between the second hydraulic power unit 2 and the third hydraulic power unit 2 · The shutter is closed. 11 of the second hydraulic power outlet pressure line, the third hydraulic power line shut-off 16, the shut-off pressure line 18 between the first hydraulic power unit 1 and the second hydraulic power unit 2, the shutter 20 between the third hydraulic power unit 3 and the fourth hydraulic power unit 2 piping of second hydraulic power unit 2, closure 31 on return line of third hydraulic order 8, interconnecting return line closure 22 between first hydraulic unit 1 and second hydraulic unit 2, and closure 35 on interconnecting return line between third hydraulic unit 2 ^and fourth hydraulic unit 2 · Hydraulic system 8 is disconnected. Backup hydraulic unit 2 J ^e inoperative as in the previous case. The second hydraulic unit 2 is out of operation and the standby power supply for the hydraulic lines 6, 2, 2 is maintained during standby. · If the failed hydraulic unit 2 is replaced by the backup hydraulic unit 2, the shutters 10, 12, 13 of the hydraulic units 1, 2 will be opened. 4, the shutters 14, 12, 16, 12 of the hydraulic lines 6, 2, 8, 2, the outlet pressure line cap 23 of the backup hydraulic power unit 2, the shutters 25 '. 27. 28 on the return line of hydraulic power units 1, 2, 4, closures 29. 22, 21, 32 on the return line of hydraulic power lines 6, 11, 8, 2 ^and backflow stopper 38 of the reserve hydraulic power unit 2 · hydraulic power line 2, shutters 18, 12, 20 on the interconnecting pressure line between individual hydraulic units 1 to 4, shutters 21. 22, 24 back-up hydraulic power line 2, shut-off 26 on the second hydraulic unit 2 return line, shutters 33 , 24, 35 on the connecting return line between the individual hydraulic units 1 to 4 and the shut-offs 36. 22, 39 return line of the backup hydraulic unit 2 · Failed hydraulic unit 2 is out of order. Even during this standby, the separate power supply of the hydraulic systems is maintained.

My be used if one of the units to strengthen 1,2,2,4,2 supply to one of the hydraulic systems of 6 second, 8, 2, ^r ° P ^can this purpose, use either adjacent the hydraulic power unit or the backup hydraulic power unit 2 · for example, for strengthening the third hydraulic Procedure 8 hydraulic unit 2 will be opened cap 10, 12, 13 the outlet pipe of the pressure of hydraulic units 1, 2, 2, 4, stoppers 14 th, 16, 17 of hydraulic systems 6, 8, ^2, their pressure lines, the shut-off 19 on the connecting pressure line between the second hydraulic power unit 2 and the third hydraulic power unit 3, the shutters 22, 26, 22, 28 on the return line of the hydraulic power units 1, 2, 2, 4, hydraulic lines 6, 8, 2 and interconnecting return line 34 between the second hydraulic unit 2 and the third hydraulic unit 2 · The second valve 15 is closed

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- řádu of the hydraulic system na on the pressure line, closures 18 and 20 on the connecting pressure line between the first hydraulic unit 1 and the second hydraulic unit 2 and the third hydraulic unit 2 and the fourth hydraulic unit 4 respectively. the first hydraulic power unit 1 and the second hydraulic power unit 2, respectively between the third hydraulic power unit 3 and the fourth hydraulic power unit 6 and the shutter 30 of the hydraulic line 2 on the return line. The backup hydraulic power unit 2 is again out of operation, all of its shutters 21, 22, 23, 23, 36, 17.

18, 32 are closed. Second hydraulic order 2 <3® disconnected.

In order to strengthen the hydraulic system 8 with the backup hydraulic unit 2, the shutters 10, 11, 12, 12, 14 will be opened. 12 3.6. iZ thus all the shutters on both the outlet pressure line of hydraulic units 1, 2, 2 »1» ^{and on the} pressure line of hydraulic lines 6,

Druhý »θ» 2 second pressure outlet pipe 22 of the back-up hydraulic power unit 2 »valves 22, 26, 24, 28, 29, 2θ» 14, J2, ie all the valves on both the return lines of hydraulic power units 1, 2, 2, 4 , on the hydraulic lines 6, 8, 8,2 ^{and the} second back-up pipe 37 of the backup hydraulic power unit 2 · The shut-off valves 18, 19, 20 of the connecting pressure line between the hydraulic units 1, 2, 2, 4 and 21 are closed. 23. 24 backup hydraulic power outlet pressure line 2 »closures 33» 14 »3? connecting piping between hydraulic units 1, 2,3,4 ^and shutters 22 »38. 39 back-up hydraulic power unit 2 return line ·

In all connections, the levels in the tanks of all the units are leveled with the unpressurised interconnecting pipe 40. 41 »42.» 41 ·

Claims (4)

Pressure fluid distribution arrangement for dynamic tests with electrohydraulic load systems with a plurality of hydraulic power units, characterized in that the manifold is formed as a plurality of separate hydraulic lines (6,7,6,9), each connected to one a hydraulic power unit (1,2,3,4) and at least one separate electrohydraulic load system. Arrangement according to Claim 1, characterized in that each hydraulic power unit (1, 2, 3, 4) is provided with a closure (10, 11, 12, 13) on its outlet pressure line and another closure (25, 26, 27). 28) on its return line, each hydraulic system is provided on its side at the hydraulic power unit (1, 2, 3, 4) with a cap (14, 15, 16, 17) on the pressure line, pressure lines of adjacent hydraulic units (1, 2,3, 4) are interconnected and a shutter (18, 19, 20) is provided in each interconnecting line, and return pipes of adjacent hydraulic units (1, 2, 3, 4) are interconnected and a shutter (33) is provided in each interconnecting line. , 34) Arrangement according to Claims 1 and 2, characterized in that the outlet pressure line of the hydraulic power units (1, 2, 3, 4) is connected to the outlet pressure line of the backup unit (5) and these interconnecting lines are provided with shutters (21, 22). 23, 24) and the return line of the hydraulic units (1, 2, 3, 4) is connected to the return line of the backup unit (5) and these interconnecting lines are provided with shutters (36, 37, 38, 39). Arrangement according to Claims 1 and 2, characterized in that all shutters and interconnecting pipes are located on the plate-type hydraulic distributor (44).