FI106399B - Pressure - Google Patents

Abstract

A multifunction pressure accumulator (21) comprised of a pressure-proof reservoir having at least two pressure connections (4, 10) and at least two leak-proof partition walls (2, 5) moving or flexing due to pressures conveyed to the reservoir and a pressure chamber formed by means of said partition walls and filled with gas. For filling of pressure chamber (13) the gas filling channel (14) is taken to the pressure chamber side at least through one partition wall.

Description

PRESSURE BATTERY 1 106399

The invention relates to a pressure accumulator for hydraulic systems.

5 Hydraulic systems used in vehicles, forestry machines, saws, and many other mechanical devices are subject to pressure shocks, which causes heavy stress on the components, structures and piping of the system. These pressure shocks are mainly due to impact loads on the mechanisms used in hydraulics. Since the compressibility of the hydraulic oils is very low and there are no other elasticities in the other system, it is advantageous to use a pressure accumulator in the pressure system which, when properly dimensioned, receives pressure peaks and does not allow the system pressure to rise too high Hydraulic systems than mechanisms equipped with a hydraulic system can be dimensioned lighter when the hydraulic system is equipped with a pressure accumulator.

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The biggest disadvantage of current pressure accumulators is that the hydraulic system requires multiple batteries, which tends to raise the price of the system. Especially when using double-acting cylinders and hydraulic pivoting devices, two batteries, one for both directions of travel, must be provided. The development of dual-action pressure accumulators has been hampered by technical problems in filling the pressure chamber. In particular, the use of mass-produced pre-machined tubes has been problematic since the conventional solution has required the cylinder casing to be machined or welded to obtain the overpressure gas required between the pistons of the double-acting accumulator, resulting in a risk of deformation of the casing and consequently sealing problems.

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The method of the invention provides a decisive improvement in the above disadvantages. To accomplish this, the method according to the invention is characterized by what is set forth in the characterizing part of claim 1.

The main advantage of the invention is that when using the battery according to the invention only one battery is needed for the double-acting slave cylinder and the swinging systems instead of the previous two. As a result, the system's acquisition cost is lower than before, and space requirement is also reduced, as space is needed for only one battery, requiring only half the size of the previous one. The system also has fewer maintenance locations. In addition, the total weight of the system is lower, which is particularly important for hydraulic systems in timber trucks, for example, since the weight saved in this way increases the load-bearing capacity of the vehicle. A particularly important advantage is that the pressure accumulator according to the invention can be used. · 1 ··. prefabricated prefabricated, high-quality, low-cost cylindrical tube, '· / · 2 that does not need to be machined or welded to eliminate the risk of tube deformation:' · · 40 tubes when machining or welding to avoid pressure battery leakage.

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In the following, the invention will be explained in detail with reference to the accompanying drawing.

: ***: Figure 1 schematically illustrates a double-acting hydraulic cylinder 20 with a ^ *** .45 double-acting pressure accumulator 21.

· »», ···. Figure 2 shows the battery 21 in a rest position.

Fig. 3 shows a pressure accumulator 21 opened for gas filling .150 «· · 1 · ·>» 2 · 106399

Figure 4 shows the battery 21 in the working position so that the battery is subjected to working pressure from the left side of the battery shown in the figure.

Figure 5 shows the battery 21 in the working position so that the battery is subjected to working pressure from the right side of the battery shown in the figure.

Figure 6 shows the battery 21 in the working position so that the battery is subjected to working pressure on both sides of the battery shown in the figure.

10

Fig. 1 shows a double-acting hydraulic cylinder 20 having two-way working movements corresponding to pressure ports 22 and 23 connected to the pressure ports 4 and 10 of the double-acting pressure accumulator 21. When one of the pressure ports 22 or 23 of the hydraulic cylinder 4 or 10 and therewith to a pressure accumulator in the pressure chamber 11 or 12. In the event of pressure strikes on either side of the hydraulic cylinder, the pressure accumulator 21 receives it by damping the shock due to the spring action of the battery. The spring action of the battery is achieved by filling the pressure chamber 13 with high pressure gas.

20

Figure 2 schematically shows a pressure accumulator 21 having two separate end chambers 11 and 12. These end chambers are supplied with pressure from the hydraulic system from two different points in the system. The pressure chamber 13 contains high pressure gas. The pressure chamber 13 is separated from the end chambers 11 and 12 by the pistons 2 and 5 provided with pressure seals 3 and 6, the piston 5 being provided with a through hole 14 connecting the pressure chamber 13 and the end chamber 12. A gas filling pipe 9 and a valve 8 are the pressure chamber 13 is filled with pressurized gas. For filling, the end piece 7 of the pressure accumulator 21 must be removed.

Figure 3 schematically illustrates a pressure accumulator 21 having the end piece shown in Figure 2 removed for filling the pressure chamber 13 with a pressurized gas. For filling the gas, the gas hose of the filling apparatus is connected to the filling pipe 9. The valve 8 is then opened and a suitable amount of pressurized gas is released into the pressure chamber 13. This one. thereafter the valve 8 is closed and the end piece 7 according to Fig. 2 is inserted.

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Figure 4 schematically illustrates a pressure accumulator 21 with a pressure in the hydraulic system provided with a pressure accumulator 21 in the portion of the system connected to the end chamber 12 of the pressure accumulator 21 by pressure causing the piston 5 to move in the direction of gas and further increase in pressure. The pressure fluctuations in the hydraulic fluid become due to the spring action of the compressed gas contained in the pressure chamber 13: received in an advantageous manner so that the effects of shocks are effectively softened and dampened.

Figure 5 schematically illustrates a pressure accumulator 21 such that a pressure system 21 ** ** t «hydraulic system has a pressure in the portion of the system connected to the pressure accumulator 21 end chamber 11. As a result of the pressure, the piston 2 is displaced. - · in the direction of chamber 13, causing further compression of the gas in the pressure chamber and further increase in pressure. Due to the spring action of the compressed gas contained in the pressure chamber 13, the pressure fluctuations of the hydraulic fluid are received in an advantageous manner so that the effects of shocks are effectively softened and dampened.

3, 106399

Figure 6 schematically illustrates a pressure accumulator 21 such that a pressure accumulator 21 has a pressure in both parts of the system which are connected to the pressure accumulator 21 end chamber 11 and 12. Under pressure, the piston 2 and piston raising even more. Due to the spring action of the compressed gas contained in the pressure chamber 13, the pressure fluctuations of the hydraulic fluid are received in an advantageous manner so that the effects of shocks are effectively softened and dampened.

In particular, it should be noted that the pressure accumulator according to the invention can be implemented as a piston battery as well as a diaphragm battery. Instead of the dual-mode battery described in the specification, the battery may be more multi-functional. Otherwise, it should be noted that the invention has been described above with reference to only one preferred embodiment. However, this is in no way intended to limit the invention to this example only, but many modifications are possible within the scope of the inventive idea defined in the following claims.

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Claims (4)

1. Multifunctional pressure accumulator (21) soi consists of a pressure-resistant container, belonging to at least two pressure connections (4,10) and at least two tight walls (2), (5) which move or spring due to the container. conduction pressure and a pressure chamber (13) formed by means of said partitions and filled with compressible gas, characterized in that for filling the pressure chamber (13), the gas filling channel (14) is provided with a valve and said duct passed through at least one intermediate wall to the side of the pressure chamber (13). Pressure accumulator according to claim 1, characterized in that in the container casing of the pressure accumulator (21), most preferably in a gable part (7), a connection (10) through which the gas filling to the container (13) can be carried out can be used. channel (14) guided through the partition 3. A pressure accumulator according to claim 1 or 2, characterized in that the end portion (7) can be detached from the container sheath (15). I <(I I ( 4. I • <I t I 4 4 4 • I 4 I 4 4 • 4 4 4 4 • · · • · • · • · · 9 9 · · • 4 I • · «• ·« • · • · • »· • · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · 4 ·