The invention is related to mechanical engineering and can be used in fluid power systems for transfer of fluid power between working fluids with different temperatures at reduced heat exchange between them.
There are devices for transfer of fluid power between working fluids isolated from one another (hydraulic buffers) in the form of hydropneumatic accumulators (hereinafter—the accumulators), their housing containing at least two variable-volume reservoirs filled with fluids via respective ports, while said variable-volume reservoirs are separated from one another by a separator movable relative to the housing.
Used as hydraulic buffers are generally accumulators with elastic separators, for example, in the form of elastic polymeric membranes or bladders [1].
In case of the use of accumulators for transfer of fluid power between working fluids with different temperatures their disadvantage is the high level of heat losses caused by heat exchange between the fluids through the separator and the walls of the housing of the accumulator.
The system proposed in [1] for separation of two fluid mediums in petrochemical compressors chosen as the closest analog includes an accumulator connected via one of its ports with the sealing fluid rail and via another port with a tank with fluid neutral to gas at the compressor discharge. This application of the accumulator allows efficient isolation of two fluids with different properties from one another and pressure transfer between them. However, in the applications with different temperatures of the two fluids such an application of a standard accumulator as a buffer between the fluids will result in intensive heat exchange between the fluids through the separator of the accumulator, in undesirable cooling of the hotter fluid and heating of the colder fluid as well as in general heat losses in the system.
The objective of the present invention is creation of a hydraulic buffer for fluid power transfer between working fluids with different temperatures at reduced heat exchange between them.
The objective is achieved by the proposed hydraulic buffer (hereinafter—the buffer) comprising a housing with at least two variable-volume reservoirs separated from one another, each of them communicating with its port in the housing. The variable-volume reservoirs are separated from one another by at least two separators with at least one buffer reservoir made between them filled with working fluid preferably with low heat conductivity, i.e. not exceeding 0.2 W/m/K.
Thus, during transfer of the fluid power between the working fluids with different temperatures the heat exchange between them occurs through at least one buffer reservoir and two separators separating the buffer reservoir from the reservoirs with working fluids of different temperatures.
The movable separators can be made in the form of pistons. To reduce the heat losses of cyclic heating and cooling of the massive walls of the buffer housing the separators are preferably made elastic, for example, in the form of elastic membranes or in the form of bladders inserted into one another. Such embodiment of the separators allows avoiding contact of working fluids of different temperatures with the same section of the walls of the housing and, thus, losses for thermo-cycling this section of the housing. In the embodiment of the buffer with bladder-type separators only one of the fluids is in contact with the housing, i.e. the temperature of the housing does not change when power is transferred between the fluids. When using bladders as separators it is expedient to make them spherical ensuring the minimum ratio between the surface area and the internal volume. In the embodiment of the buffer with membrane separators the volumes of the variable-volume reservoirs change only due to deformation of the separators but not due to the changed ratio of the areas of the housing surfaces being in contact with the fluids, which also allows avoiding thermo-cycling the housing.
To increase the working range of the temperatures at least one of the elastic separators should be preferably made from the material capable of being used at increased temperatures, preferably of 200° C. or higher, for example, from polyamide or organosilicone polymers. At least one elastic membrane can be also made from metal.
To reduce heat exchange through convective flows of fluids in the buffer reservoir means of convection suppression are made in it.
In the embodiment of the buffer with separators in the form of bladders inserted into one another the means of convection suppression are made in the form of a flexible porous filler (for example, foamed polyurethane with open pores) filling the volume of the buffer reservoir.
In the embodiment of the buffer with separators in the form of elastic membranes the means of convection suppression can be also made as an aggregate of elements inserted into one another, preferably cylindrical ones, located inside the buffer reservoir along its axis. The cylindrical elements are made with the possibility of axial movement relative to one another similar to a telescopic structure. Without preventing the synchronous motion of the membranes they reduce considerably convection of the fluid inside the buffer.
For further reduction of convective heat losses the buffer volume is preferably filled with the fluid with reduced heat conductivity (not more than 0.2 W/m/K) and increased viscosity (not less than 50 cSt at the working temperature of 100° C. or higher.
For still greater reduction of heat transfer along the walls of the buffer housing the housing includes at least one heat-insulating element made so as its heat conductivity in at least one direction does not exceed 20 W/m/K; the said heat-insulating element forms the external walls of at least one buffer reservoir.
The parts of the invention are described in more detail in the example given below and illustrated by the drawings presenting:
FIG. 1—Schematic view of the hydraulic buffer with one buffer reservoir and two separators in the form of bladders inserted into one another.
FIG. 2—Schematic view of the hydraulic buffer with two separators in the form of elastic membranes and one buffer reservoir and the aggregate of coaxial cylinders inserted into it.
The hydraulic buffer according to
When fluid power is transferred from the first working fluid with the first temperature filling the variable-volume reservoir 2 through the port 4 (
The buffer reservoir 8 of the hydraulic buffer with bladder-type separators according to
The embodiments described above are examples of the embodiment of the main idea of the present invention that also supposes variety of other embodiments that are not described here in detail, for example, the embodiments differ by the choice of materials for separators, heat-insulting insert, type of fluid in the buffer reservoir, embodiments of the means of convection suppression and materials used in them as well as the number of successively placed buffer reservoirs.
Thus, the proposed solutions allow creating a hydraulic buffer for fluid power transfer between the working fluids with different temperatures with the following properties:
1—H. Exner, R. Freitag, Dr. H. Gais, R. Lang, Y. Oppoltser, P. Shwab, E. Zumpf, U. Ostendorff, M. Ryke. Hydraulic drive. Fundamentals and components. 2nd Russian edition. Bosch Rexport AG Service Automation Didactics Erbach Germany, 2003, p. 156c
Number | Date | Country | Kind |
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2011112504 | Mar 2011 | RU | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/RU11/00852 | 10/27/2011 | WO | 00 | 9/17/2013 |