DE20021297U1 - Memory connector block - Google Patents

Description

Memory connection block

The invention relates to an accumulator connection block for a hydraulic pressure accumulator with connections for connecting a storage vessel, a hydraulic pump and a tank and with a 3-way valve for shutting off and relieving the storage vessel.

Storage connection blocks for hydraulic pressure accumulators are used to quickly provide the required amount of energy in hydraulic systems without the use of large pumps. For example,

&iacgr;&ogr; such hydraulic pressure accumulators are used in presses. Such a hydraulic pressure accumulator is a closed vessel divided in two by a membrane with an inlet in order to be able to introduce the hydraulic medium into one chamber of the vessel. The other chamber of the pressure accumulator is filled with a gas, for example nitrogen. With a relatively small pump, the pneumatic medium in the pressure accumulator can be pressurized by introducing the hydraulic medium, which can then be made available directly to operate a specific consumer by relieving the accumulator. In larger hydraulic systems, several such pressure accumulators can also be arranged parallel to one another.

In previously known storage connection blocks, 3-way valves are used, which are designed as ball valves with a floating ball.

In such valves, the shut-off element - the ball - is sealed against the seals of the individual outlets by the pressure acting on the shut-off element in the pressurized line, through which the shut-off element is pressed into its sealed seat in the respective sealing shell opposite the pressurized side. The prerequisite is that one line is pressurized and the other line is depressurized or at least has a lower pressure. For this reason, the shut-off element is coupled to the rotary movement of the control shaft with a certain amount of play, so that depending on the

&iacgr;&ogr; switching position of the valve the shut-off device can rest on the corresponding sealing shell.

The hole in the shut-off device is usually L-shaped, but T-holes are also known.

In the case of storage connection blocks with such a 3-way valve, the storage connection block can basically be switched to two different states, one of which corresponds to the operating position in which the 3-way valve is switched to a position in which there is a fluid connection between the pump and the storage vessel. The second position of the valve of such a storage connection block is the relief position in which there is a fluid connection between the storage vessel and the tank for the hydraulic medium. In this position, the storage vessel is shut off from the pump.

In order to ensure that such a storage connection block operates properly without leakage, the pump connection and the connection of the connection block associated with the pressure accumulator are arranged at an angle of 90° to each other. However, this diversion has the disadvantage of a pressure loss. The advantage of such a storage connection block with a 3-way valve compared to a storage connection block with a 2-way valve is that the storage vessel is automatically relieved when the pump is shut off. Nevertheless, with a storage connection block with a 2-way valve, which is also designed as a ball valve with a floating ball, it is possible to arrange the connections for the storage vessel and the pump opposite each other with respect to the valve, so that for switching reasons a

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Redirection of the fluid flow and thus the associated pressure loss as with a 3-way valve is avoided.

The storage tank of such a hydraulic system must be serviced at regular intervals. During such maintenance, the hydraulic pump must be switched off to prevent leakage in the accumulator connection block. This is particularly undesirable if several pressure accumulators are connected in parallel in a hydraulic system and the hydraulic pump should not be switched off during maintenance of a single storage tank in order to continue operating the system.

Based on this discussed prior art, the invention is therefore based on the object of developing a storage connection block of the generic type mentioned at the outset in such a way that it not only combines the advantages of previously known storage connection blocks with a 2-way valve or with a 3-way valve, but also allows maintenance of the storage vessel to be carried out without the hydraulic pump having to be switched off for this purpose.

This object is achieved according to the invention in that the shut-off element of the 3-way valve is designed in the manner of a ball, the control shaft of which is centrally mounted for the stationary arrangement of the shut-off element and the peripheral surface of which has the bore openings rests against a sealing arrangement assigned to each outlet.

In contrast to the prior art, the storage connection block according to the invention ensures that the ball-shaped shut-off device is sealed in any position of the valve. This is achieved by the switching shaft being rigidly connected to the shut-off device or being molded onto the shut-off device and mounted centrally. The peripheral surface of the shut-off device, which has the bore openings, rests on a sealing arrangement assigned to each outlet, whereby a telescopic seal is expediently provided with a sealing shell resting on the peripheral surface with a conically inwardly inclined surface and with an elastic sealing ring supported on the connection side. By using such a 3-way valve, the storage connection block can be

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different switching positions without the problem of leakage occurring. Consequently, for example, the connections for the storage vessel and the pump can be arranged opposite each other in relation to the tap in order to avoid a pressure loss due to circuitry. By using such a 3-way tap, however, the hydraulic pump can also be shut off from the storage vessel without leakage, so that the storage vessel can be relieved even when the hydraulic pump is running. It is also possible to put the storage connection block into other suitable switching positions, for example one in which there is a fluid connection between the pump and the storage vessel and the tank connection, for example for flushing or venting the system. Furthermore, the pump can be operated without pressure if there is a fluid connection between the pump and the tank and the connection to the storage vessel is shut off.

The invention is described below using an embodiment with reference to the attached figures. They show:

Fig. 1: A longitudinal section through a storage connection module with

schematically shown further hydraulic elements,

Fig. 2. A cross section through the memory connection block of the

Figure 1,

Fig. 3a-e: A schematic representation of the 3-way valve of the storage connection block of Figures 1 and 2 in different switching positions.

Part of a hydraulic system not shown in detail is a hydraulic pressure accumulator 1 consisting of a pressure-resistant storage vessel 2 and a storage connection block 3. The storage vessel 2 is chambered by a membrane 4, with gas being provided in the upper chamber 5 in Figure 1 and the hydraulic medium used to operate the hydraulic system being provided in the lower chamber 6. The storage vessel 2 is pressurized in its design shown in Figure 1.

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so that the gas in the chamber 5 - nitrogen - is under pressure. The chamber 6 has a connection 7 which is connected to a connection S of the connection storage block 3 assigned to the storage vessel 2.

The storage connection block 3 comprises a 3-way ball valve 8 with a guided control shaft, the shut-off device 9 of which has a T-bore 10. The storage connection block 3 also comprises several connections, on the one hand the connection S for the storage vessel 2, and on the other hand a

Î Connection P, to which the hydraulic pump 11 of the system is connected, and a connection T, which is in fluid communication with the tank 12 of the hydraulic system. The connections P and S are arranged diametrically opposite one another with respect to the 3-way ball valve 8, so that the pressure provided by the hydraulic pump 11 can be introduced into the storage vessel 2 without pressure loss. In the storage connection block 3, a pressure relief valve (not shown in detail) is also inserted into a bore 13, which in turn is connected to the connection S and the connection T via corresponding channels, bridging the 3-way ball valve.

The shut-off element 9 of the 3-way ball valve 8 rests on a sealing arrangement D ₁ - D ₃ , of which a section of the sealing arrangement D ₁ is shown in the enlarged view. The sealing arrangement D ₁ and accordingly also the other two sealing assemblies D ₂ and D ₃ each consist of a sealing shell 14 with an inwardly inclined conical surface 15 and an elastic sealing ring 16. The sealing ring 16 and the rear part of the sealing shell 14 are inserted into a receiving groove of the connection P. With the peripheral surface having the bore openings, the shut-off element 9 rests on the side of the sealing shell 14 facing the shut-off element 9 under constant contact pressure conditions. The seal D ₁ can be referred to as a telescopic sealing arrangement due to the combination of the sealing shell 14 and the elastic sealing ring 16.

A control shaft 17 is formed on the shut-off device 9 - as can be seen in Figure 2. The control shaft 17 is in turn mounted centrally in the storage and shut-off block 3 so as to be rotatable about its longitudinal axis. The end of the control shaft 17 protruding from the storage connection block 3 has a

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a square head 18 for attaching a gear lever not shown in the figures.

Figure 1 and, correspondingly, Figure 3a show the 3-way ball valve 8 in the operating position of the hydraulic pressure accumulator 1, in which the hydraulic medium is continuously pumped from the pump 11 via the pump connection P into the storage vessel 2 via the storage connection S. Due to the opposing arrangement between the pump connection P and the storage connection S, there is no pressure loss due to circuitry. Pressure relief of the storage vessel 2 for operating a corresponding actuator or for maintaining a predetermined pressure is not discussed in this explanation.

In a second position of the 3-way valve (see Figure 3b), the storage vessel 2 is manually relieved, since the storage connection S is now connected to the tank connection T via the bore 10. The pump connection P is shut off. As the shut-off device 9 seals off each connection S, P or T in each position of the 3-way ball valve 8, there is no risk of leakage in this position. This means that the pump 11 can continue to operate even in the position of the 3-way ball valve 8 shown in Figure 3b.

Figure 3c shows a schematic position of the 3-way ball valve 8 in which the system can be vented or flushed. In this position, all three connections S, P and T are in fluid communication with one another through the T-bore 10.

Figure 3d shows the 3-way ball valve 8 in a position in which the pump 11 can be operated without pressure. In this position, the pump connection P and the tank connection T are in fluid communication, while the storage connection S is shut off.

Figure 3e shows the 3-way ball valve 8 in a position in which all connections P, T, S are blocked. In this way, the system can be shut off while the pressure remains in the accumulator.

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From the illustration and description of the invention it is clear that the storage connection block according to the invention has considerable advantages over the previously known prior art, in particular also due to the fact that additional switching positions are now permitted, in that pressure can be built up in the storage vessel when using a 3-way valve without a pressure loss due to the circuitry and in that automatic storage vessel emptying can take place when the pump connection is shut off from the other connections.

-8-Reference symbol list

1 Hydraulic pressure accumulator 2 Storage vessel 3 Memory connection block 4 membrane 5 chamber 6 chamber 7 Connection 8th 3-way ball valve 9 Shut-off device 10 T-hole 11 pump 12 tank 13 drilling 14 Sealing shell 15 Surface, conical 16 Sealing ring 17 Shift shaft 18 Square head _{D1 -D3} Seal arrangement P Connection pump S Connection storage vessel T Connection tank

Claims (6)

1. Accumulator connection block for a hydraulic pressure accumulator (1) with connections (S, P, T) for connecting a storage vessel (2), a hydraulic pump (11) and a tank (12) and with a 3-way valve (8) for shutting off and relieving the storage vessel (2), characterized in that the shut-off element (9) of the 3-way valve (8) is designed in the manner of a ball, the switching shaft (17) of which is centrally mounted for the stationary arrangement of the shut-off element (9) and whose peripheral surface having the bore openings rests against a sealing arrangement (D ₁ -D ₃ ) assigned to each outlet. 2. Storage connection block according to claim 1, characterized in that each sealing arrangement (D ₁ -D ₃ ) consists of a sealing shell (14) resting on the peripheral surface of the shut-off element (9) with a conically inwardly inclined surface (15) and of an elastic sealing ring (16). 3. Storage connection block according to claim 1 or 2, characterized in that the bore of the 3-way valve (8) is designed as a T-bore (10). 4. Storage connection block according to claim 3, characterized in that the connection (S) assigned to the storage vessel (2) and the connection (P) of the storage connection block (3) assigned to the pump (11) are arranged diametrically opposite one another with respect to the 3-way valve (8), so that a pressure loss-free fluid connection can be established between the two. 5. Storage connection block according to one of claims 1 to 4, characterized in that a pressure relief valve is arranged in a line bridging the 3-way valve (8) between the storage vessel (2) and the tank (12) in the storage connection block (3). 6. Storage connection block according to one of claims 1 to 5, characterized in that an electromagnetic relief element is associated with the storage connection block.