EP0158054A1 - Hydraulic drive - Google Patents

Abstract

The invention relates to a hydraulic drive, in particular for actuating electrical high-voltage circuit breakers, which is accommodated together with a hydraulic accumulator with a mechanical pressure-maintaining device in a common pressure housing, into which the delivery element for the hydraulic fluid also integrates a high-pressure pump and a control unit together with the necessary hydraulic connections are, and that is encapsulated with a cover to protect against external influences. In addition, one or more external hydraulic accumulators can be connected to increase the number of operations.

Description

The invention relates to a hydraulic drive, in particular for high-voltage circuit breakers, with a working piston designed as a differential piston, which is guided in a one-sided axial recess in a pressure housing and is constantly under the force of an energy store on one side and the other side optionally with pressure can be acted upon or relieved of pressure.

Such a drive is known from DE-OS 28 28 958, in which a differential piston is acted upon by hydraulic fluid from a separately arranged energy store. Such spatial separation inevitably leads to the laying of pressure lines that are susceptible to interference from external influences, which, depending on their length, adversely affect the efficiency of the system, and which have to be laid taking fire safety into account, which in total together with a considerable installation effort.

It is therefore an object of the invention to provide a device in which both the hydraulic drive and the required energy store, including the associated units, are accommodated without complex laying of pressure lines and protected against external influences.

This object is achieved by the characterizing features of claim 1, according to which in the recess located in the pressure housing, in which the Ar- _D e _l tS piston is guided with a piston rod, a further, so-called storage piston is used, which is symmetrical against one another to its center axis arranged springs supports energy storage, which surrounds it and the piston rod penetrating the pressure housing of the working piston and with this, the wall of the recess and the working piston delimits a storage space which provides pressure energy as a hydraulic accumulator for supplying the hydraulic drive without further supply of external energy , wherein the used hydraulic fluid is fed into a collecting space bounded by the side of the storage piston facing away from the storage space, the wall and the bottom of the recess.

By using the invention there is the possibility at any time, i.e. even in the event of a malfunction or interruption of the power supply, actuate the hydraulic drive as intended, since the drive and energy storage unit form a single unit.

In an advantageous embodiment of the invention introduced the recess as a step-shaped cylinder bore, the working piston being guided in the bore with a smaller diameter, the storage piston in the bore with a larger diameter. This arrangement leads to a very compact design, since the possible storage volume in the storage space is a multiple of the required actuating volume for the working piston. Another advantage is the high positioning force for the working piston that can be achieved with this arrangement.

The recess in the pressure housing is expediently closed with a housing cover, this having a cup-shaped bulge which accommodates the collecting space for the hydraulic fluid.

To reduce the overall length of the hydraulic drive, it is advantageous to arrange the spring arrangement serving as an energy store, or spring store for short, outside concentrically around the pressure housing, the storage piston using transmission rods, which are arranged symmetrically to its central axis and slide out of the pressure housing in a pressure-tight manner, via a thrust piece with the spring storage device is rigidly coupled.

In order to avoid additional holding devices and thus assembly effort and to maintain the compact design, the spring accumulator is supported against a molded-in shoulder on the almost cylindrical pressure housing. The end of the pressure housing facing away from the housing recess has a cylindrical outer contour which serves as a sliding guide for the circular pressure piece.

The spring accumulator is expediently formed from disk spring assemblies. This measure offers the known Advantage that with an appropriate choice of dimensions and preload an almost constant force curve can be adjusted over the spring travel, so that the hydraulic accumulator has an almost constant pressure over its entire operating range.

In a further advantageous embodiment of the invention, the housing cover has an integrally formed switch flange in the extension of the pressure housing, to which a high-voltage circuit breaker can be attached.

A mechanical position indicator, which actuates a limit switch attached to the housing cover in the extension of one of the transmission rods, serves to control the respective memory content of the hydraulic accumulator.

To control the position of the working piston, a mechanical and electrical position indicator is provided, which is connected to a coupling via a lever with a slide for converting the translational movement of the working piston into a rotational movement, which coupling is firmly connected to the piston rod.

In terms of a compact design, a high-pressure pump and a hydraulic control unit are integrated diametrically opposite one another in the pressure housing in the area of the storage space, the control slide belonging to the hydraulic control unit being located in a bore running parallel to the central axis of the storage piston.

Another advantage that results from this design is that all hydraulic connections between the pressure chambers and the high pressure pump and the hydraulic control unit in the form of fluid channels embedded in the pressure housing. are, so that externally installed pressure lines are not required. The fluid channels are designed so that hydraulic fluid is conveyed from the collecting space into the storage space and from there via the three-way control unit can get from the storage space into a working space for the working piston and from the working space into the collecting space. The working area is on the side of the working piston facing away from the storage area.

In order to rule out accidental switching operations of the drive in the event of a pressure drop in the storage space due to a fault, a spring-loaded locking pin inserted in the pressure housing engages in an annular groove provided for this purpose on the working piston jacket when the working piston is in its working position. The spring force of the compression spring is to be set so that the locking pin slides back into its bore at operating pressure in the hydraulic fluid storage space as a result of the force acting on its excellent end face.

With regard to its switching capacity, the hydraulic drive according to the invention is designed in such a way that it meets the standards, regulations or legal regulations (e.g. ANSI, ICE / VDE) and reliably maintains the switching times or switching intervals required there.

To increase the storage capacity, one or more additional, externally arranged and independent of external energy supply, similarly constructed hydraulic accumulators, ie units without a work, pump and control unit, can be provided, which have corresponding Hydraulic lines and valves are connected to the hydraulic drive. With this, the drive capacity can be increased practically as desired and adapted to the application requirements, the additional space requirement being small due to the compact design.

The connecting lines can be rigid, i.e. firm or flexible, e.g. be laid as an armored hose. The valves are designed according to the invention as a multi-way valve and expediently arranged on the hydraulic drive in order to prevent the pressure drop in the storage space in the case of damaged connections. The location of the or the additional storage can be determined according to the respective local conditions.

On the basis of a schematic sketch and an exemplary embodiment, the idea of the invention and its design possibilities are to be explained again and illustrated more specifically in the figures and description of the figures.

• Fig. 1 Prinzipskizze der Anordnung,
• Fig. 2 Schnitt durch einen hydraulischen Antrieb mit Hydraulikspeicher in Ruhestellung (z.B. Schalter geöffnet),
• Fig. 3 Schnitt durch einen hydraulischen Antrieb mit Hydraulikspeicher in Arbeitsstellung (z.B. Schalter geschlossen),
• Fig. 4 Seitenansicht der Anschlußseite (Schalterseite),
• Fig. 5 Prinzipskizze der Anordnung mit einem externen Hydraulikspeicher.

Show it:

• 1 is a schematic diagram of the arrangement,
• 2 section through a hydraulic drive with hydraulic accumulator in the rest position (eg switch open),
• 3 section through a hydraulic drive with hydraulic accumulator in the working position (eg switch closed),
• 4 side view of the connection side (switch side),
• Fig. 5 schematic diagram of the arrangement with an external hydraulic accumulator.

Figure 1 shows the schematic structure of the arrangement formed from the storage unit and hydraulic actuator. Within a common pressure housing 10 there is a storage piston 16, which delimits a collecting space 34 which is subjected to low pressure and in which the storage piston 16 is supported against the pressure housing via a spring arrangement which is symmetrical with respect to its central axis, against a storage space 30 which is subjected to high pressure is also a working piston 18, which has a piston rod 28, which centrally axially penetrates the storage piston 16 and the pressure housing 10 for the purpose of actuating an electrical switch 100, and which separates the storage space from a working space 38, which can be selected by means of a control unit 22 optionally via fluid channels 54 , 56 connected to the storage space 30 can be pressurized, or connected to the collecting space 34 via fluid channels 54, 58 can be relieved of the pressure. A high-pressure pump 20 delivers pressure fluid from the collecting space 34 into the storage space 30 via fluid channels 50, 52.

The hydraulic drive shown in FIGS. 2 to 4 has a pressure housing 10 with an almost cylindrical stepped outer contour, into which a step-shaped cylinder bore is formed starting from an end face in the axial direction. This bore has a first area with a large diameter, which serves as storage cylinder 12, and a second area with a smaller diameter, which serves as working cylinder 14, at a depth of approximately 1/3. The pressure housing 10 is closed off from the outside with a flanged housing cover 32.

In the area of the storage cylinder 12, a high-pressure pump 20 is fitted outside in a pressure-tight manner by means of a circumferential seal into a housing opening arranged radially to the cylinder axis. A hydraulic control unit 22 is also positively integrated diametrically opposite in the pressure housing 10.

The storage cylinder 12 serves to receive a storage piston 1b, which separates the storage space 30, which is under high pressure, from the collecting space 34, which is acted upon by low pressure and is arranged in the cup-shaped, arched housing cover 32. If the operating pressure in the storage space 30 is exceeded, this is connected to the collecting space 34 via a bore 86 which extends axially eccentrically in the storage piston 16 and leads to an overpressure valve 84 located in the storage piston 16. On the side facing the collecting space 34, the storage piston 16 has a collar 90, through which a fluid channel 58, which is formed in the pressure housing 10 and is extended by means of a pressed-in piece of pipe, is eccentrically guided in a bore 92 with sufficient play and ends in the collecting space 34. Further bores are arranged symmetrically to the central axis, each receiving a transmission rod 60.

On the end of the storage piston 16 opposite the collar there is a sliding seal 102 which is embedded in the outer surface of the storage piston 16 and which seals the storage space 30 against the wall of the storage cylinder 12. In its center, the storage piston 16 is penetrated by a piston rod 28 in an axially extending guide bore 82. To seal the storage space 30, at least one is in the guide bore '82 inserted sliding seal 104 is provided. Two slide rings 106 serve for the exact guidance of the piston rod 28 in the guide bore 82.

Free access for the hydraulic fluid from the storage space 30 to a work space R 36 is limited to a defined cross section by a fitted insert and an inserted impact bushing 110. The piston rod 28 is inseparably connected to a working piston 18, which, designed as a differential piston, has annularly tapering shoulders 88 on both piston surfaces, which act as impact dampers, and which merge into the piston rod 28 on one side. On the end opposite the piston rod 28, the working piston 18 carries a piston ring, a sliding seal 42 is also embedded in the piston jacket at an approximately medium piston height. On the side facing the piston rod, an annular groove 44 is provided in the jacket of the working piston 18, the contour of which is adapted to a spring-loaded locking pin 46. A fluid channel 54 opens into the bottom 48 of the working cylinder 14 and establishes the connection to the hydraulic control unit 22 running axially parallel to the working cylinder 14. The hydraulic control unit is connected to the storage space 30 via a fluid duct 56, and to the collecting space 34 via a fluid duct 58.

The high-pressure pump 20 is connected to the collecting space 34 via a fluid channel 50 and to the storage space 30 via a fluid channel 52.

Immediately next to the impact sleeve 110 is the spring-loaded locking pin 46 as a pressure-controlled lock in the radial direction in the working cylinder 14 arranged, which is aligned with the intended annular groove 44 when the working piston 18 is in the working position.

The transmission rods 60 are led out of the pressure housing 10 in a bushing with a sliding seal and connect the accumulator piston 16 to a spring arrangement 26 via a pressure piece 62. The stepped and threaded ends of the transmission rod 60 are bores in the collar 90 of the thread adapted to the thread diameter Storage piston 16 and bores in the pressure piece 62 inserted so that the collar and the pressure piece 62 are supported on the transmission rod 60 and are each non-positively fixed.

The pressure piece 62 is guided by the cylindrical end of the pressure housing 10 so that it slides on the slide guide 74 with its inner bore 70, which has a slide piece 72 for reducing friction.

The spring arrangement 26 is layered in alternating directions and arranged and preloaded in accordance with its geometry in such a way that an almost constant force curve results over the entire working path. The spring assemblies 26 are supported on the one hand against the pressure piece 62 and on the other hand against an abutment 78 incorporated on the circumference of the pressure housing 10.

The housing cover 32 is penetrated by the piston rod 28 in a central bore 108 with an inserted sliding seal. Eccentrically arranged, in the extension of a transmission rod 60, a mechanical actuating display 120 for the accumulator piston, which penetrates the housing cover in a slide-tight bore 109, is led out of the pressure building 10, one on the housing cover 32 attached limit switch 122 actuated. The further configuration of the housing cover 32 provides that an electrical switch 100 to be actuated via the piston rod 28 can be flanged to the switch flange 124 in the extension of the pressure housing 10. Furthermore, the housing cover 32 is guided radially outwards so that it serves as a hood base 116 for receiving a cover 114, which is detachably connected to the hood base 116 with a closure. At the level of the mechanical setting indicator 120, an optical reading device 126 can be attached to the hood base. Furthermore, an electrical setting indicator 128 is provided for the working piston, which is connected to a coupling 132 via a lever with a sliding piece 130. The coupling serves to connect the piston rod 28 to the electrical switch 100 to be actuated. On the side facing away from the switch flange there is a threaded bore 134 in the pressure housing 10, which receives a cylinder screw 136 for fixing a holding device 138.

When the high-pressure pump 20 is switched on, hydraulic fluid is conveyed from the collecting space 34 via the fluid channel 52 into the storage space 30 via the fluid channel 50. As a result of the pressure in the storage rim 30 which rises as further conveyance occurs, the storage piston 16 moves in the direction of the housing cover 32 against the force resulting from the compression of the spring arrangement 26 and transmitted by means of the transmission rods 60 until it has reached its predetermined end position. When the pressure rises further, the pressure relief valve 84 opens and hydraulic fluid passes through the bore 86 from the storage space 30 into the collecting space 34.

The fluid in the hydraulic control unit 22 channels 54 and 56 connected to each other, hydraulic fluid from the storage space 30 reaches the bottom 48 of the working cylinder 14, so that the same pressure is present on both piston surfaces. However, since the piston area of the working piston 18 facing the working space A 38 is larger by the cross section of the piston rod 28 than the opposite piston area, the working piston 18 is moved into the working position. In accordance with this piston stroke, the piston rod 28 moves in the direction of the switch flange 124, as a result of which the flanged electrical switch 100 is actuated. In order to bring the working piston 18 out of the working position into its rest position, the fluid channels 54 and 58 are connected to one another in the hydraulic control unit 22. In this way, the hydraulic fluid in the working space A 38 reaches the collecting space 34 via the fluid channels 54 and 58. As a result of the pressure relief in the working space A 38, the working piston 18 is displaced into its rest position at high speed by the storage pressure prevailing in the working space R 3b. Correspondingly, the piston rod 28 moves back and actuates the electrical switch 100 and, via the lever with the slider 130, the electrical setting indicator.

With each switching operation on / off, a volume unit of hydraulic fluid corresponding to the volume of the working space 38 is consumed from the storage space 30. The required number of switching operations to be made possible without the supply of external energy determines the size of the storage volume which, as explained at the beginning, is stored under almost constant force corresponding to almost constant pressure. The respective available storage volume in the storage space 30 can be read on the mechanical control display 120. With the help of the provided end scarf ters 122, the actuation of the high pressure pump 20 can be controlled.

To avoid mechanical damage to the working piston 18 as a result of its rapid movement from the rest position into the working position and vice versa, the impact dampers 88 mentioned at the outset are provided.

Their effect is based thereon that the A-running cross-section _b for the pressure fluid from the working cylinder 14 depending on the position of the working piston decreases 18th This has the consequence that the pressure fluid runs more slowly, so that the working piston 18 is braked in its movement.

FIG. 5 schematically shows how an external hydraulic accumulator 10 # connects via a connecting line either as a rigid pipeline 40 or as a flexible hose line 40 # to a multi-way valve 24, which, located on the hydraulic drive, connects the high-pressure pump 20 either with the storage space 34 or with the external one Hydraulic accumulator 10 # connects. This hydraulic accumulator 10 # consists of a pressure housing 10 #, which is designed in the same way as the pressure housing 10 of the hydraulic drive.

The cylindrical interior is subdivided by a storage piston 16 # into a storage space 30 # and into a second area which accommodates the spring arrangement 26 # provided as a storage element.

In the example, the supply of pressurized fluid via the connecting line (40, 40 #) through the high-pressure pump 20 is provided, with the intermediate multi-way valve secures the storage space 30 against a drop in pressure.

In terms of circuitry, it is provided that, if necessary, the pressure fluid in the external hydraulic accumulator flows into the storage space 30 due to the stored force emanating from the spring arrangement 26 #, so that an additional number of switching operations is ensured.

Claims (14)

1.Hydraulic drive, in particular for high-voltage circuit breakers, with a working piston (18) designed as a differential piston, which is funneled in a one-sided axial recess (12, 14) located in a pressure housing (10) and constantly under the force on one side of an energy store (2b) and the other side of which can optionally be pressurized or relieved of pressure, characterized in that the recess (12, 14) in the pressure housing (10), which receives the working piston (18) and is provided with a piston rod. a storage piston (16) is used, which is supported against an energy store (26) formed from springs (26) arranged symmetrically to its central axis, which (16) and the pressure housing (10) penetrate the piston rod (28) of the working piston (18 ) engages and with this, the wall of the recess (12) and the working piston (18) delimits a storage space (30) which acts as a hydraulic accumulator on the reverse The hydraulic drive without further supply of external energy provides pressure energy that the used hydraulic fluid can be supplied to a collection chamber (34) which is at low pressure and is delimited from the side of the accumulator piston (16) facing away from the accumulator chamber (30), the wall and the bottom of the recess, and the storage space (30) is separated from the collection space (34) by the storage piston (16). 2. Hydraulic drive according to claim 1, characterized characterized in that the recess (12, 14) in the pressure housing (10) is a stepped tapered cylinder bore (12, 14), the working piston (18) having the smaller diameter, serving as the working cylinder (14) and Accumulator pistons are guided in the bore which has the larger diameter and serves as an accumulator cylinder (12), and is tightly closed by means of a housing cover (32). 3. Hydraulic drive according to at least one of the preceding claims, characterized in that the working cylinder (14) at its end facing the storage cylinder (12) has a locking device (46) which holds the working piston (18) in the working position, i.e. in its end position of the working piston (18) closest to the storage piston (16). 4. Hydraulic drive according to at least one of the preceding claims, characterized in that in the pressure housing (10) a high pressure pump (20) for filling the storage space (30) and a hydraulic control unit (22) for controlling the movement of the working piston (18) in a form-fitting manner are integrated. 5. Hydraulic drive according to at least one of the preceding claims, characterized in that in the pressure housing fluid channels (50, 52, 54, 56, 58) for connecting the high pressure pump (20) with the storage space (30) and with the collecting space (34) and for connecting the storage space (30) to the control unit (22) and for connecting the control unit (22) to the work space (A 38) and the collecting space (34). b. Hydraulic drive according to at least one of the Previous claims, characterized in that the storage piston (16) and the energy store (26) are rigidly coupled to one another. 7. Hydraulic drive according to at least one of the preceding claims, characterized in that the energy storage (26) designed as a spring arrangement (26) is on the one hand connected to a pressure piece (60) which is connected to the storage piston (16) by means of transmission rods (62) and by The cylindrically shaped end of the pressure housing (10) facing away from the recess (12, 14) is guided, and on the other hand is supported on the pressure housing (10) on the side facing away from the recess (12, 14). 8. Hydraulic drive according to at least one of the preceding claims, characterized in that the energy store (26) is arranged concentrically to the central axis of the storage piston (16) and is preferably formed from plate spring assemblies (80). 9. Hydraulic drive according to at least one of the preceding claims, characterized in that a switch flange (124) is integrally formed on the housing cover (32) on the side facing away from the pressure housing (10), which can be flanged to an electrical high-voltage circuit breaker (100) . 10. Hydraulic drive according to at least one of the preceding claims, characterized in that a mechanical control indicator (120) of the storage piston (16) corresponding to the available amount of pressurized fluid in the storage space (30) is provided. 11. Hydraulic drive according to at least one of the preceding claims, characterized in that on the housing cover (32) an electrical control indicator (128) for the working piston (18) is fastened mechanically via a lever with a slider (130) to implement the translatory movement of the working piston (18) in a rotational movement connects to a coupling (132) which is rigidly connected to the working piston (18) and at the same time actuates an optical setting indicator (126). 12. Hydraulic drive according to at least one of the preceding claims, characterized in that at least one external hydraulic accumulator (10 ') for the additional provision of pressure fluid with the storage space (30) via a pipe (40) or a hose line (40') is connected. 13. Hydraulic drive according to at least one of the preceding claims, characterized in that the connecting line (40, 40 ') connects to a valve (24) arranged on the storage space (30), so that it is secured against a drop in pressure. 14. Hydraulic drive according to at least one of the preceding claims, characterized in that the external hydraulic accumulator (10 ') via the connecting line (40, 40') by the high pressure pump (20) of the hydraulic drive (10) can be fed with pressurized fluid.

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