EP1030065A1 - Fluid power cylinder with fluid locking - Google Patents

Abstract

The cylinder consists of a double-wall cylinder tube (1) with flow grooves, a guide part (2), a bottom closing part (3) and a piston rod (6) with piston (7) between a piston cavity (31) and an annular piston cavity (32). The bottom closing part contains a control cylinder cavity (8) with a control piston (15) kept in the blocking middle position by springs (13, 14) on either side.The unpressurized fluid in the piston cavities blocks the movement of the piston and its rod. When pressure is applied, the system is unblocked.

Description

The invention relates to a pressure-operated working cylinder for use as a differential working cylinder in hydraulically or pneumatically operated mechanisms, their movement is blocked if the pressure energy fails have to be.

Pressure medium-operated devices for adjusting a gear member from one position to another are known from the prior art. For certain applications, it is necessary for functional or safety reasons to fix the position of a link in a given or current position using path blocking systems.
These blocking systems can be divided into mechanically or fluidically acting.

Known mechanical locking systems are mostly based on the Principle of positive or non-positive coupling of the piston rod with the working cylinder tube. Locking body that arranged between the working cylinder tube and the piston rod are, by spring forces on their inner or pressed outer jacket and cause the clamping, being also systems with a clamp on the inner surface of the piston rod are known. In addition to these arranged in the working cylinder Locking systems are also used as additional Work component in connection with a working cylinder used. The necessary fittings and their circuitry are outside the cylinder, also mounted directly on this. Unlocking is done by directly loading the locking device with the Working pressure of the fluid or via separate controls.

The publication is an example of this principle of action DE 33 07 644 A1 cited, in which a pressure medium operated Working cylinder with locking in any Positions is described of a hollow piston rod has in any position with one in the Fixed piston rod protruding from the cylinder base Support tube, the free end of a radially movable mechanical clamping element carries, braked and lockable is. The mechanical clamping device is via a control cylinder in combination with a double unlockable check valve arranged outside the cylinder controlled. It is unlocked by the operating pressure of the fluid and the blocking if the pressure fails mechanical jamming.

The disadvantages of the mechanical locking devices exist always in complex production. Stiction related Clamping systems are subject to heavy wear and tear relatively short lifespan and high maintenance requirements depending on the intended use. External clamping devices on the working cylinder require radially protruding dimensions. An exact Positioning is in systems with high dynamic forces not guaranteed.

In fluidic blocking systems, which are known from the prior art, single or double-acting blocking valves, which can also be designed to be unblocked, are installed in the fluid circuit for operating the working cylinder. Their arrangement is such that the movement of the main piston of the working cylinder is prevented in the event of pressure loss by the outflow of the fluid from the two working spaces of the cylinder being blocked and this acting as a blocking means between the piston surfaces and the blocking valves. Unlocking can be done using the operating pressure or a separate control line. The disadvantage of these solutions is the need for additional components outside the working cylinder.
With direct attachment, there is a bulky, bulky design that makes it difficult to adapt to the mechanism technology. If the installation is removed, there is a risk of the pressure lines bursting and thus the necessary pathway not being achieved. This makes additional mechanical support devices necessary.

A fluid operated blocking device to limit a specified relative speed is in the publication DE 44 06 186 C2 disclosed. This is made with one Fluid-filled tube as a cylinder with end pieces on both sides educated. One end piece is with a sealed piston rod bushing Mistake. The piston has flow Connections with valves between the two cylinder chambers separated by the piston. The valve closure member becomes resilient at a distance by spring force held to the valve seat. When a certain one is exceeded Insertion speed of the piston rod increased the pressure in the respective cylinder chamber, so that the valve closes, the fluid stops draining and the blockage he follows. Unlocking is done by reversing movement or at least temporary relief.

The field of application of this fluid operated locking device is to block the path when a relative speed is exceeded or a pressure limit. At a conceivable use as a pressure-operated working cylinder would not be possible to block the path if the pressure failed.

The object of the invention is a pressure medium operated Differential working cylinder with fluidic Roadblock to develop in the event of loss of pressure energy prevents the outflow of the fluid, no expensive mechanical Has locking devices, no external clamping devices required, is maintenance-free, a compact Design has a sufficiently precise positioning enables and preferably in moving systems with large dynamic forces is used as well as inexpensive can be produced.

The task is performed by those listed in protection claim 1 Features resolved. Preferred further developments result from the subclaims.

The essence of the invention is that a pressure medium-operated differential working cylinder in one of the two closure parts, preferably in the bottom closure part, a locking and directional valve combination controlled by the operating pressure of the fluid from a control piston held in the non-pressurized state by springs in the central position with channels through radial and axial introduced bores are formed, which shuts off the supply and discharge channels to the pressure chambers of the working cylinder via its outer surface in this position, with an appropriate fit pairing or additional seals between the control cylinder chamber and the control piston preventing an outflow of the fluid. The outflow of the fluid from the pressure chambers of the working cylinder is prevented in the unpressurized state or if the operating pressure fails and the piston is blocked off by the fluid enclosed in the pressure chambers.
The connections for the supply and discharge of the fluid open directly into the respective control cylinder chamber of the control piston. With this arrangement, the unlocking is ensured by the introduction of the fluid. Depending on the application, the spring force for the control piston that determines the release pressure can be selected. The release pressure should not be below 10% of the operating pressure in order to avoid displacements of the control piston due to back pressure in the drain or in the event of decompensations when the pressure in the pressure chamber is released.
In the case of differential working cylinders, the cylinder tube is expediently designed with double walls with suitable flow grooves between the tube walls in order to enable the fluid inlets and outlets from the piston chambers via the blocking and directional valve combination preferably arranged in the bottom closure part of the working cylinder.

A variant of the pressure-operated working cylinder with fluidic path blocking, as additional security to block the path, inside the bottom locking part Check valves in the supply lines of the fluid from the control piston to the pressure rooms by additional valve spools can be controlled via tappets when fluid is applied.

The advantages of the invention compared to known solutions are the use of the fluid as an enclosed barrier medium in the unpressurized state, in particular in the absence of complex, wear-prone mechanical clamping devices. External supports to secure mechanisms in the event of pressure failure are not required.
The leakage of the differential working cylinder with respect to the fluid is achieved.
A fluid-operated working cylinder with the path lock according to the invention is maintenance-free, has a compact design with a radial expansion that is technically customary for the respective application, and ensures a sufficiently precise positioning. Use in moving systems with large dynamic forces is easily guaranteed.

Fig. 1 als Schnitt eines doppelwandigen Differentialarbeitszylinders mit Wegsperrsystem im drucklosen Zustand

Fig. 2 als Schnitt im Bodenverschlußteil nach Fig. 1 zur Darstellung der Zu- und Ablaufanschlüsse sowie der Fluidzuführungsbohrungen im drucklosen Zustand

Fig. 3 als Schnitt des Bodenverschlußteils mit dem in diesem integrierten Wegsperrsystem im entsperrten Zustand bei Druckbeaufschlagung im Kolbenraum des Arbeitszylinders

Fig. 4 als Schnitt des Bodenverschlußteils mit dem in diesem integrierten Wegsperrsystem mit zusätzlichen über Stößel angesteuerten Ventilen im entsperrten Zustand bei Druckbeaufschlagung im Kolbenraum des Arbeitszylinders

Fig. 5 als Schnitt im Bodenverschlußteil nach Fig.4 zur Darstellung der Zu- und Ablaufanschlüsse sowie der Fluidzuführungsbohrungen im drucklosen Zustand

Fig. 6 als Schnitt durch das Bodenverschlußteil nach Fig.4 zur Darstellung der Stößel und Ventile

näher erläutert.The invention is based on an embodiment of

Fig. 1 as a section of a double-walled differential working cylinder with a locking system in the depressurized state

Fig. 2 as a section in the bottom closure part of FIG. 1 to show the inlet and outlet connections and the fluid supply holes in the depressurized state

Fig. 3 as a section of the bottom closure part with the integrated locking system in the unlocked state when pressurized in the piston chamber of the working cylinder

Fig. 4 as a section of the bottom closure part with the integrated in this way blocking system with additional valves controlled by tappets in the unlocked state when pressurized in the piston chamber of the working cylinder

Fig. 5 as a section in the bottom closure part of Figure 4 to illustrate the inlet and outlet connections and the fluid supply holes in the unpressurized state

Fig. 6 as a section through the bottom closure part of Figure 4 to show the plunger and valves

explained in more detail.

According to Fig. 1, Fig. 2 and Fig. 3, the differential working cylinder with integrated locking system consists of a double-walled cylinder tube 1 with flow grooves, a guide part 2 and a bottom closure part 3, which has a cylinder base plate 4 with a bore 5 and a piston rod 6 with a piston 7. The bottom closure part 3 has an axial bore as a control cylinder chamber 8 with an upper bore 9, which in an upper channel 10 and a lower bore 11, which opens into a lower channel 12, in which one by means of a left spring 13 and a right Spring 14 control piston 15 held in the blocking central position with a left axial bore 16 which is arranged in a lower radial bore 17 and a right axial bore 18 which opens into an upper radial bore 19. The control piston 15 is provided in the area of the lower radial bore 17 with a left circulation channel 20 and in the area of the upper radial bore 19 with a right circulation channel 21 via which the flow of the fluid depending on the switching position through the radial bores 17; 19 is ensured in any radial position of the control piston 15. The control piston 15 is sealed in the control cylinder chamber 8 by fits, but can also have additional seals.
The springs 13; 14 are guided by a left extension 22 and a right extension 23 of the control piston 15, the ends of the extensions 22; 23 serve simultaneously as a left stop 24 and as a right stop 25.
The bottom closure part 3 has an end plate 26 which is fastened and sealed in the usual manner for easier assembly of the integrated path blocking system.
The differential working cylinder is connected to a fluid circuit via a left connection opening 27, which opens into a left control cylinder chamber 28 and a right connection opening 29, which opens into a right control cylinder chamber 30. To extend the piston rod 6, a fluid is supplied via the left connection opening 27, which flows into the left control cylinder chamber 28 and displaces the control piston 15 through the pressure build-up against the bias of the right spring 14 from the locking central position to the right stop 25. The connection from the left control cylinder chamber 28 to the lower channel 12 via the lower bore 11 is released, at the same time the connection of the upper channel 10 via the upper bore 9 and the right circulation channel 21 to the upper radial bore 19, which is connected to the right axial bore 18 in Connection is established. The fluid flows from the left control cylinder chamber 28 through the lower bore 11, the lower channel 12 and the bore 5 in the cylinder base plate 4 to a piston chamber 31 of the differential power cylinder. The working pressure of the fluid acts on the piston 7 and causes the piston rod 6 to extend. The fluid, which is located in an annular piston chamber 32, flows through an opening 33 in the double-walled cylinder tube 1 with flow grooves into a left-hand annular channel 34 in the bottom closure part 3, which for upper channel 10 is open. From the upper channel 10, the fluid continues to flow through the upper bore 9, via the right circulation channel 21, the upper radial bore 19 and the right axial bore 18 in the control piston 15, outflow grooves 35 on the right stop 25 into the right control cylinder chamber 30 and further through the right port 29 back into the external fluid circuit.

According to FIGS. 4, 5 and 6, a variant of the fluidic blocking system in the bottom closure part 3 in the upper channel 10 has a polygonal upper tappet 36, which is moved by an upper valve slide 37 in an upper cylinder chamber 38 and an upper blocking valve 39 controls. The upper plunger 36 is moved in the depressurized state by a plunger spring A 40 so that the upper shut-off valve 39 is closed.
The upper shut-off valve 39 has a valve chamber A 41 with valve seat A 42, in which a valve body A 44 preloaded with a valve spring A 43 with grooves A 45, a sealing cone A 46 and a valve stem A 47 is arranged.
A lower check valve 51, which is actuated by a polygonal lower plunger 48 and is moved in a lower cylinder chamber 50 by a lower valve slide 49, is arranged in the lower channel 12. The lower plunger 48 is moved in the depressurized state by a plunger spring B 52 so that the lower shut-off valve 51 is closed.

The lower shut-off valve 51 has a valve chamber B 53 with valve seat B 54, in which a valve body B 56 preloaded with a valve spring B 55 with grooves B 57, a sealing cone B 58 and a valve stem B 59 is arranged.
To extend the piston rod 6, the working cylinder is acted upon via the left connection opening 27 with a fluid which flows into the left control cylinder chamber 28 and moves the control piston 15 against the bias of the right spring 14 from the locking central position to the right stop 25. The connection from the left control cylinder chamber 28 to the lower channel 12 is released, at the same time the connection of the upper channel 10 via the upper bore 9 and the right circulation channel 21 to the upper radial bore 19, which is connected to the right axial bore 18, is established.
The fluid flows from the left control cylinder chamber 28 through the lower bore 11 into the lower channel 12 and presses the lower valve slide 49 up to a stop 60, the residual fluid being displaced from the lower cylinder chamber 50 into the right control cylinder chamber 30 through a connecting bore 61. At the same time via a channel 62, which is connected to the left control cylinder chamber 28 and a right ring channel 63 in the end plate 26, the fluid is guided to the upper cylinder chamber 38 and moves the upper valve spool 37 to a slide stop 64, the pressure increasing Upper shut-off valve 39 is opened by the upper tappet 36 via the valve stem A 47. The pressure in the channel 12 also simultaneously opens the sealing cone B 58 of the valve body B 56 in the lower shut-off valve 51 against the pressure of the valve spring B 55, lifts it out of its valve seat B 54 and fluid flows through the bore 5 in the cylinder base plate 4 into the piston chamber 31 and moves the piston 7.
The fluid flowing out of the annular piston chamber 32 through the opening 33 via the flow grooves in the double-walled cylinder tube 1 into the left annular channel 34 is through the opened upper check valve 39 into the upper channel 10 and further through the upper bore 9 via the right circulation channel 21, the upper radial bore 19 and the associated right axial bore 18 in the control piston 15, the outflow grooves 35 in the right control cylinder chamber 30 via the right opening 29 opening into the outer fluid circuit.

If the direction of movement of the piston 7 is reversed, the pressure is applied via the right connection opening 29, the fluid flowing into the right control cylinder chamber 30, displacing the control piston 15 to the left stop 24 and thus the inflow to the annular piston chamber 32, via the upper bore 9, the channel 10, the upper shut-off valve 39 and the left ring channel 34, to the double-walled cylinder tube 1 with flow grooves, via opening 33.
By displacing the control piston 15, the valve slide 49 is simultaneously pressurized via the connecting bore 61, which is displaced up to a stop A 65 and thereby displaces the lower tappet 48, which displaces the valve body B 58 from its sealing position via the valve stem B 59 and so the lower check valve 51 opens.
The outflow of the fluid from the piston chamber 31 takes place via the bore 5, the grooves B 57 of the opened lower shut-off valve 51, the lower channel 12, the lower bore 11, the left circulation channel 20, the lower radial bore 17, the left axial bore 16 , the left control cylinder chamber 28 and the left port 27 back into the external fluid circuit.

Reference symbols used

1

double-walled cylinder tube

2nd

Guide part

3rd

Bottom closure part

4th

Cylinder base plate

5

drilling

6

Piston rod

7

piston

8th

Control cylinder room

9

upper hole

10th

upper channel

11

lower hole

12th

lower channel

13

left feather

14

right feather

15

Control piston

16

left axial bore

17th

lower radial bore

18th

right axial bore

19th

upper radial bore

20th

left circulation channel

21

right circulation channel

22

left extension

23

right extension

24th

left stop

25th

right stop

26

End plate

27

left connection opening

28

left control cylinder room

29

right connection opening

30th

right control cylinder room

31

Piston chamber

32

Piston chamber

33

opening

34

left ring channel

35

Outflow grooves

36

upper plunger

37

upper valve spool

38

upper cylinder space

39

upper shut-off valve

40

Tappet spring A

41

Valve room A

42

Valve seat A

43

Valve spring A

44

Valve body A

45

Grooves A

46

Sealing cone A

47

Valve stem A

48

lower plunger

49

lower valve spool

50

lower cylinder space

51

lower shut-off valve

52

Tappet spring B

53

Valve room B

54

Valve seat B

55

Valve spring B

56

Valve body B

57

Grooves B

58

Sealing cone B

59

Valve stem B

60

attack

61

Connecting hole

62

channel

63

right ring channel

64

Slide stop

65

Slider stop A

Claims (5)

Pressure-operated differential working cylinder with fluidic path lock, consisting of a double-walled cylinder tube (1) with flow grooves, a guide part (2), a bottom closure part (3) and a piston rod (6) with one arranged between a piston chamber (31) and an annular piston chamber (32) Piston (7),
characterized, that a control cylinder space (8) with a control piston (15), which is held in the blocking central position by means of a left spring (13) and a right spring (14), is preferably integrated in the bottom closure part (3) as a way blocking system, that the fluid enclosed in the unpressurized state in the piston chamber (31) and the annular piston chamber (32) blocks the movement of the piston rod (6) with the piston (7) and that the lock-out system is unlocked when pressure is applied. Pressure-operated differential working cylinder with fluidic path lock, consisting of a double-walled cylinder tube (1) with flow grooves, a guide part (2), a bottom closure part (3) and a piston rod (6) with one arranged between a piston chamber (31) and an annular piston chamber (32) Piston (7),
according to claim 1, characterized in that valve slides (37; 49) with plungers (36; 48) and check valves (39; 51) are arranged in channels (10; 12) in the bottom closure part (3). Pressure-operated differential working cylinder with fluidic path lock, consisting of a double-walled cylinder tube (1) with flow grooves, a guide part (2), a bottom closure part (3) and a piston rod (6) with one arranged between a piston chamber (31) and an annular piston chamber (32) Piston (7), according to claims 1 and 2, characterized in that that the supply channels of the fluid to the pressure chambers (31; 32) in the form of radial bores (17; 19) in connection with axial bores (16; 18) are guided onto the outer jacket of the control piston (15). Pressure-operated differential working cylinder with fluidic path lock, consisting of a double-walled cylinder tube (1) with flow grooves, a guide part (2), a bottom closure part (3) and a piston rod (6) with one arranged between a piston chamber (31) and an annular piston chamber (32) Piston (7), according to claims 1 to 3, characterized in that that the control piston (15) has circulation channels (20; 21) in the region of the radial bores (17; 19). Pressure-operated differential working cylinder with fluidic path lock, consisting of a double-walled cylinder tube (1) with flow grooves, a guide part (2), a bottom closure part (3) and a piston rod (6) with one arranged between a piston chamber (31) and an annular piston chamber (32) Piston (7), according to claims 1 to 4, characterized in that that the bottom closure part (3) has an end plate (26) in which a right ring channel (63) is arranged.

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