DE102015006812A1 - Apparatus and method for pressure equalization - Google Patents

Abstract

The invention relates to a device and a method for compensating pressure fluctuations of a fluid in a hydraulic system, comprising a container (1) which is separated by a membrane (2) into two regions, wherein a first region (3) is designed to Fluid whose pressure is balanced to absorb, wherein a second region of the container at least partially contains a fluid mixture which is partially liquid (4) and partially gaseous (5). The pressure fluctuations are compensated by the fact that a phase transition between the gaseous and liquid portion of the fluid mixture takes place.

Description

The invention relates to a device for compensating for pressure fluctuations of a fluid in a hydraulic system, comprising a container which is separated by a membrane into two regions, wherein a first region is adapted to receive the fluid whose pressure is balanced. The invention further relates to a method for compensating for pressure fluctuations of a fluid, in a hydraulic system, with a device which is divided by a membrane into two areas, wherein a region is filled with the fluid, the pressure of which is compensated.

Containers to compensate for pressure fluctuations are already known. They are mainly used in heating and hot water circuits to ensure a stable pressure in the piping system. In hydraulic systems, incompressible fluids are often used, so that in addition volume changes, due to different temperature potentials, must be compensated.

By such containers is mainly prevented that subsequent equipment parts are damaged in particular by pressure peaks. As a result of the more even pressure, the following parts of the system can also be designed for a narrower pressure range, which usually goes hand in hand with cost savings. In addition, the error rate of the entire system is lower and thus the failure and maintenance costs. Such devices reduce the risk of pressure surges and attenuate them, for example, when starting and stopping of pumps, they compensate to some extent the loss of fluid through leakage, or can be used on positive displacement pumps as pulsation or vibration.

As a rule, such a surge tank, which is also referred to as expansion vessel or device, designed as a membrane expansion tank. That is, the container has a membrane that divides the container into at least two areas. The membrane is usually a separation membrane, which is not permeable to the fluids on both sides. The membrane can therefore also be understood as a mechanically flexible partition. Also known in the prior art are membranes which are introduced into a steel container, similar to a bladder, rather than covering only the cross-section of a container. The membranes can be made so that they are firmly installed or interchangeable. The membrane is usually made of elastomers or plastics. Metal membranes can be used at particularly low or very high temperatures. As a medium to compensate for pressure fluctuations, nitrogen, another inert gas or air is usually used. The general aim of such devices is to ensure a constant system pressure.

Even when using fluid working machines, in particular reciprocating engines for compressing, dosing and conveying fluids, for example hydraulic fluids, carbon dioxide (CO ₂ ) or hydrogen (H ₂ ), there are inconsistent fluid flows and thus pressure fluctuations on the output side of the fluid working machines.

Known from the prior art devices and methods are usually provided for incompressible fluids. A disadvantage of current systems is that the medium, in order to compensate for the pressure fluctuations, recovers an increase in pressure in the first region in the event of a pressure surge, thus leaving an unstable outlet pressure in the first region. As a rule, pressure peaks can not be completely compensated.

Object of the present invention is preferably fully compensate for pressure peaks.

This object is achieved in that a second region of the container at least partially contains a fluid mixture which is partially liquid and partially gaseous. The pressure peaks are preferably completely compensated by the medium, to compensate for the pressure fluctuations, in the second region of the surge tank, adapted accordingly and a phase transition between the gas and liquid phase takes place. The pressure peaks are thereby compensated less by a pure volume change of the medium in the second region, than by a change in the phase components. Advantageously, the pressure of the fluid in the first region is completely stabilized in this way. By changing the proportion of liquid and gaseous phase, the necessary volume change of the medium in the second area can be better realized.

The surge tank is divided by a membrane into at least two parts. The pressure fluctuations are transmitted via the membrane to the medium in the second area. This must therefore be flexible.

Advantageously, the membrane is made of an elastic, gas-tight material, in particular of nitrile rubber (nitrile-butadiene rubber), polytetrafluoroethylene (Tefon) or fluororubber (Viton). Preferably, the membrane is made of elastomers or plastics. However, membranes made of metals are also possible. Metals are suitable especially at particularly high or extremely low temperature ranges. In a preferred embodiment variant, the device is to compensate for pressure fluctuations with a fluid working machine, in particular a pump or a compressor in connection.

To compensate for pressure fluctuations, in comparison to the prior art, when a pure gas phase is used, not only compression of the gas but also a phase transition takes place. In the initial state, the medium, in the second region of the device, consists of a fluid mixture whose composition is chosen such that a liquid phase and a gas phase form. In a preferred embodiment, in the initial state, the liquid phase occupies 10-20% of the volume of the second region, the gas phase correspondingly 80-90%. The filling volume for both areas of the container is one liter. Scales towards smaller or larger filling volumes are however conceivable. Furthermore, it is not absolutely necessary that both areas have an identical filling volume.

The fluid mixture may contain the following constituents: carbon dioxide (CO ₂ ), hydrogen (H ₂ ), carbon monoxide (CO), oxygen (O ₂ ) nitrogen (N ₂ ), and all noble gases, in particular argon, neon, helium or xenon. The fluid mixture preferably contains CO ₂ as the main constituent, since an equilibrium pressure between the gas phase and the liquid phase of about 57 bar is established at a temperature of 20 ° C. Compared to the use of pure CO ₂ , the use of a fluid mixture offers the advantage that, depending on the proportion of CO ₂ in the fluid mixture, an equilibrium pressure can be set to suit the respective operating temperature. In order to achieve a higher pressure in the second region of the container, that is to say a higher pretensioning pressure, a further gas is admixed as minor constituent, which has lower temperature changes during compression or expansion. As a secondary constituent gases with a particularly high isentropic exponent are preferably to be used, so that the influence of the temperature increase due to an isentropic compression shock remains particularly low. Especially noble gases are considered to be particularly suitable here.

In a preferred embodiment variant, the medium in the second region contains, in addition to CO _2, at least one gas from the group of noble gases, in particular xenon or argon. However, it is also possible to use mixtures of noble gases. Argon is preferred for cost reasons. The fluid mixture may also contain oxygen (O ₂ ) or nitrogen (N ₂ ).

For example, to increase the bias pressure to 90 bar, the fluid mixture is formed from CO ₂ and argon, for example. In this case, at least partially liquid CO _{2 is} introduced, which sets at 20 ° C, a pressure of about 57 bar. The residual gas filling at 90 bar is carried out by argon, the partial pressure of CO ₂ thus remains at about 57 bar. Noble gases react to a compression, ie compression, or relaxation with a much lower temperature change than the pure CO ₂ .

The device is also advantageously designed so that the container and the membrane can compensate for pressure fluctuations between 10 and 700 bar. When using CO ₂ as the main component of the medium in the second range, in particular pressure fluctuations between 80 and 120 bar can be compensated. If now a negative pressure of the fluid in the first region, ie a negative pressure change, be compensated, the liquid phase is partly in the gas phase. When compensating for pressure surges, ie positive pressure changes, part of the CO _{2 is} liquefied in the gas phase and passes into the liquid phase. The ratio between the gas and liquid phase of the medium in the second region, as well as the medium itself, must be adapted to the particular application. Thus, for a low-temperature application, at about -150 ° C, in particular nitrogen (N ₂ ) to choose as the main component of the fluid mixture, the biasing pressure must be set to 25 bar. Nitrogen is then partially present in the liquid phase. The bias pressure is then again, preferably by a noble gas, increased to the desired value. The gas used for this purpose must therefore have a boiling temperature below the operating temperature, which is why in this case, for example, neon can be used.

The pressure equalization tank can be tempered by methods known in the art, so that a particularly constant pressure compensation can take place. Thus, the medium in the second area is heated accordingly and the ratio between gas and liquid phase and about the form, can be adjusted accordingly.

In the present invention advantageously pressure fluctuations can be compensated if the fluid is present in the first range at pressures in the range of 70 to 150 bar. That means in other words, if the fluid pressures between 70 and 150 bar, but should be limited to a range between 80 and 120 bar, this is ensured by the pressure equalization vessel. By the presented method and the corresponding device, the pressure fluctuations can be minimized. Preferably, pressure fluctuations of the fluid in the first region, in particular of incompressible media, of +/- 50 bar are compensated for by a respective biasing pressure which is formed by the medium in the second region.

The inventive use of the presented device, pressure surges and pressure changes can be compensated. Subsequent instruments and equipment are thus protected and a constant pressure of the fluid is ensured in the plant components following the surge tank. The pressure changes may have been caused by pumps or mechanical devices in front of the surge tank, but also by volume changes of the fluid, which can be caused for example by temperature fluctuations. The system according to the invention thus also allows the storage of energy in the form of volume change work of the medium in the second area. By the addition of substances, such as noble gases, go with the volume change, ie a compression or relaxation of the medium, only minimal temperature changes.

As a fluid whose pressure is to be balanced, not only gases can be used. The system according to the invention is also suitable for liquids or mixed phases. However, the system is particularly suitable for the pressure stabilization of CO ₂ at room temperature. However, a device according to the invention and such a method can also be used for pressure stabilization of hydraulic fluids, hydrogen or other technical gases.

Depending on the fluid used, a suitable membrane must be selected which is chemically stable to the fluid, gas tight, and has sufficient flexibility. The device and method can be used at operating temperatures between -269 ° C and 150 ° C. The operating temperature is usually limited by the choice of a suitable membrane.

Another advantage, when a device according to the invention is integrated into a system, results from the fact that the electronic regulation of the fluid pressure can be simplified by the mechanical pressure compensation.

Together with the effect that the following system components can be designed for a lower pressure range, this results in a cost reduction in the design and construction of the system. In addition, reducing the pressure drops reduces the susceptibility to failure of the entire system and thus the maintenance and repair or downtime costs.

In the following, an embodiment of the invention is shown schematically.

1 schematically shows a surge tank.

The in 1 shown pressure equalization tank 1 is made of metal. However, other pressure and temperature stable materials are conceivable. The container usually has a cylindrical shape, but may also be formed almost spherical or rather cuboid. As a rule, it is made of two parts between which the membrane 2 is clamped, which divides the container into two areas. The membrane in this case is made of nitrile butadiene rubber. Both areas of the container each have at least one opening for the inlet or outlet of the fluid or the compensation medium. An area is connected via this opening with the remaining system components, for example via a pipe in connection. This area is therefore with the fluid 3 filled, the pressure to be balanced and stabilized. In the embodiment shown here, the container is designed so that CO ₂ can be stabilized as a fluid. The pressure range varies between 10 and 700 bar. The operating temperature is in the application example shown between 2 and 30 ° C, but in particular between 18 and 24 ° C. The surge tank is usually mounted after a fluid work machine in the system. However, there may be other plant components in between.

In the second area is the medium for pressure equalization, which is a liquid phase 4 and a gaseous phase 5 having. It is filled in the production of the surge tank on the existing opening. The opening can then be tightly closed or carried out, for example via a valve, that the medium can be replaced for maintenance purposes or during maintenance work, the form can be adjusted, in particular by deliberate draining or supplying medium or to control the pressure. It is also conceivable to provide the container with means for controlling the pressure, for example a pressure gauge, or with safety devices, in particular a bursting device, or a safety valve.

The pressure equalization tank can be integrated in any direction in the system. Horizontal or vertical mounting is preferable, but not mandatory.

Claims (10)

Device for compensating pressure fluctuations of a fluid in a hydraulic system, comprising a container ( 1 ) passing through a membrane ( 2 ) is separated into two regions, a first region ( 3 ) is adapted to receive the fluid whose pressure is balanced, characterized in that a second region of the container at least partially contains a fluid mixture which is partly liquid ( 4 ) and partially gaseous ( 5 ). Device according to claim 1, characterized in that the membrane ( 2 ) is made of an elastic, gas-tight material, in particular of nitrile rubber, polytetrafluoroethylene or fluororubber. Apparatus according to claim 1 or 2, characterized in that the device for compensating for pressure fluctuations with a fluid working machine, in particular a pump or a compressor is in communication. Device according to at least one of claims 1 to 3, characterized in that the fluid mixture in the second region contains carbon dioxide and contains at least one gas from the group of noble gases, in particular xenon or argon. Device according to at least one of claims 1 to 4, characterized in that the container and the membrane are designed so that pressure fluctuations between 10 and 700 bar can be compensated. Method for compensating for pressure fluctuations of a fluid in a hydraulic system with a device that passes through a membrane ( 2 ) is divided into two areas, a first area ( 3 ) is filled with the fluid whose pressure is balanced, characterized in that the second region of the container for pressure equalization contains a fluid mixture which is partly liquid ( 4 ) and partially gaseous ( 5 ). A method according to claim 6, characterized in that the fluid is present in the first region at pressures in the range of 10 to 700 bar. Method according to one of claims 6 or 7, characterized in that pressure fluctuations are passed through the membrane to the fluid mixture in the second region and that this fluid mixture contains carbon dioxide, which is liquid and gaseous and the pressure fluctuations are compensated by the fact that the proportion of liquid and gaseous carbon dioxide changes. Method according to at least one of claims 6 to 8, characterized in that the fluid mixture in addition to the carbon dioxide at least one gas from the group of noble gases, in particular xenon or argon. Method according to at least one of claims 6 to 9, characterized in that pressure fluctuations of the fluid in the first region, in particular of incompressible media, of +/- 50 bar are compensated by a respective biasing pressure which is formed by the fluid mixture in the second region.

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