DD264257A1 - DAMPING DEVICE FOR PRESSURE VIBRATIONS IN PISTON FLOW COMPRESSORS - Google Patents

Abstract

Damping device for pressure oscillations in reciprocating compressors for gaseous and liquid flow media for smoothing the pulsating flows occurring due to the compressor principle. The field of application of the damping device according to the invention is in closed circuits, preferably in hermetic refrigerant compressors for reducing the pulsation of the refrigerant gas flow. In the damper chamber of the damping device, an elastic membrane is gas-impermeably connected to the damper chamber wall or a vibrating piston is mounted gas-impermeable in the damper chamber wall by springs. The elastic membrane or the resilient piston absorb the pressure peaks of the pulsating flow and release it again in the phase of the pulsating flow waste, so that a subsequent slight compression of the flow medium occurs inevitably. The damping device is shown in FIG. 1 with a membrane and in FIG. 2 with a piston. Fig. 1, 2

Description

In the phase of the pulsating flow drop, the membrane or the piston returns to the original position, so that inevitably a subsequent slight compression of the flow medium takes place periodically. The membrane is gas impermeable and rigid, the piston is gas impermeable and movably connected to the damper chamber wall. To improve the pressure balance in the additional chamber, one or more pressure compensation openings may be located in the chamber rear wall.

embodiments

In the drawings, two variants of the application of the invention and its most favorable form of realization

shown.

FIG. 1 shows the damping device with elastic membrane 5

Flow medium is that passes into the damper chamber 4 through an inlet opening 2. The elastic membrane 5 takes on a short time part of the flow of the flow and returns at the outlet of the flow medium from the outlet opening 3 in its original state. A rubber-elastic filler 6, which is located in the additional chamber 7, supports the

Membrane 5 capable of oscillation. In the chamber rear wall 8 pressure equalization openings 9 can be located.

FIG. 2 shows the damping device with pistons 10, d. r is gas-impermeable in the damper chamber 4 and with springs 11 on the chamber rear wall 8 is capable of oscillating ge '' gert. In the chamber rear wall 8 can

Pressure equalization holes 9 are located.

1. Dämpfungse'nrichtung for pressure oscillations in reciprocating compressors for gaseous and liquid flow media, characterized in that in the damper chamber (4) is an elastic membrane (5) which is gas-impermeable connected at a certain location with the damper chamber wall and in the additional chamber (7) one or more pressure equalization holes (9) are located.

2. Damping device according to claim 1, characterized in that, depending on the membrane dimensioning, additionally a rubber-elastic filler (6) in the additional chamber (7) is arranged.

3. damping device according to claim 1, characterized in that the elastic membrane (5) by a piston (10) can be replaced and the piston (10) is gas-impermeable and movably connected to the damper chamber wall.

4. damping device according to claim 3, characterized in that the piston (10) by means of springs (11) is mounted to vibrate.

For this 1 page drawings

Field of application of the invention

Damping device for pressure oscillations in reciprocating compressors for gaseous and liquid flow media for smoothing the occurring by the compressor principle pulsating flows.

The field of application of the damping device according to the invention is in closed circuits, preferably in hermetic refrigerant compressors for reducing the pulsation of the refrigerant gas flow.

Characteristic of the known state of the art

There are several known chamber damper, which operate on the principle of interference, reflection or absorption.

The niichststst the known solution is the PS 2421733 DE, F 01N-1/00, which refers to mufflers for lines of periodically operating machines. The damping is achieved by a Venturi nozzle, which has holes according to the invention at its narrowest cross-sectional area, did open into a gas-tight annular chamber. As the flow velocity increases, the pressure in the gas-tight annular chamber decreases. As the flow velocity increases, the pressure in the gas-tight annular chamber of the elastic venturi decreases. As a result, an enlargement of the minimum nozzle cross-section occurs and thus a change in the nozzle characteristics.

The PS 2514689DE, F 01N-1/16 describes a device for reducing noise caused by pulsating gases. In the process, a partition wall is located between the gas inlet and gas outlet. In this partition, a gas-permeated gap is provided whose length is a multiple of its width. The width of the gap itself is formed variable under the action of the! Flowing gas against the action of a spring element.

Another damper chamber with elastic or resilient damper chamber wall is described in the PS 1553280 DE, F 01 N-1/10.

Disadvantages of these dampers are that they represent fluidically and acoustically a nonlinear resistance, or their constructions are production and material consuming and not always work maintenance-free.

Object of the invention

The aim of the invention is to eliminate the disadvantages of known solutions by the invention ° according to simple and reliable construction of the damping device.

Due to the effect of the additional chamber of the damping device is only an indirect influence on the flow medium ;, so that flow losses are avoided and sets a more continuous flow through the degradation of the flow peaks.

Explanation of the nature of the invention

Based on the object of the invention, the object is to provide a Dämpfungse ¹ .richtung for pressure oscillations in reciprocating compressors ^ υ ig working with no or slight pressure losses. In this case, the pressure peaks of the pulse-generating compressor flow are to be absorbed by an elastic membrane or a single piston or a piston and to be released again in the case of the pulsating flow drop.

The features of the invention are that a damping device is riachgeschaltet after the compression of the refrigerant in the refrigerant circuit. The damping device is arranged so that opposite to the flow direction of the inflow medium in the damper chamber is arranged an elastic membrane or a resilient piston. Between elastic membrane and chamber pressure wall is preferably a rubber-elastic filler to absorb the pressure peaks of the pulsating flow well. When using the spring-loaded piston, the pressure peaks are absorbed by the springs.

In the phase of the pulsating flow drop, the membrane or the piston returns to the original position, so that '

inevitably a subsequent slight compression of the flow medium takes place periodically. The membrane is,

gas impermeable and rigid, the piston is gas impermeable and movably connected to the damper chamber wall. To improve the pressure balance in the additional chamber, one or more pressure compensation openings may be located in the chamber rear wall. ^:

embodiments

In the drawings, two variants of the application of the invention and its most favorable form of realization 'are shown.

FIG. 1 shows the damping device with elastic membrane 5. In this case, 1 represents the flow direction of the i

Flow medium is that passes into the damper chamber 4 through an inlet opening 2. The elastic membrane 5 takes '

while a short time part of the flow and is at the outlet of the flow medium from the outlet opening 3 in |

back to its original state. A rubber-elastic filler 6, which is located in the additional chamber 7, supports the membrane i 5 oscillatory. In the chamber rear wall 8 pressure equalization openings 9 can be located. , |

FIG. 2 shows the damping device with piston 10, which is located in the damper chamber 4 in a gas-impermeable manner and with j

Springs 11 mounted on the rear wall 8 vibratory 'at. In the chamber rear wall 3 can> pressure equalization openings 9 are located.

Claims (4)

-1- 264 257 Claims: 1. Damping device for üruckschwingungen in reciprocating compressors for gaseous and liquid flow media, characterized in that in the damper chamber (4) is an elastic membrane (5), which is gas-impermeable connected at a certain location with the damper chamber wall and in the additional chamber (7 ) One or more pressure equalization openings (9) are located. 2. Damping device according to claim 1, characterized in that, depending on the membrane dimensioning, additionally a rubber-elastic filler (6) in the additional chamber (7) is arranged. 3. damping device according to claim 1, characterized in that the elastic membrane (5) by a piston (10) can be replaced and the piston (10) is gas-impermeable and movably connected to the damper chamber wall. 4. damping device according to claim 3, characterized in that the piston (10) by means of springs (11) is mounted to vibrate. For this 1 page drawings Field of application of the invention Damping device for pressure oscillations in reciprocating compressors for gaseous and liquid flow media for smoothing the occurring by the compressor principle pulsating flows. The field of application of the damping device according to the invention is in closed circuits, preferably in hermetic refrigerant compressors for reducing the pulsation of the refrigerant gas flow. Characteristic of bekannton state of the art There are several known chamber damper, which operate on the principle of interference, reflection or absorption. The closest known solution to the invention is PS 2421733 DE, F 01 N-1/00, which relates to mufflers for lines of periodically operating machines. The damping is achieved by a Venturi nozzle, which according to the invention has at its narrowest cross-sectional area holes, which open into a gas-tight annular chamber. As the flow velocity increases, the pressure in the gas-tight annular chamber decreases. As the flow velocity increases, the pressure in the gas-tight annular chamber of the elastic venturi decreases. As a result, occurs an increase in the minimum nozzle cross-section, and thus a change in the nozzle properties. The PS 2514689DE, F 01 N-1/16 describes a device for reducing noise caused by pulsating gases. There is a partition between gas inlet and gas outlet. In this partition, a gas-permeated gap is provided whose length is a multiple of its width. The width of the gap itself is made variable under the action of the flowing gas against the action of a Federclementes. Another damper chamber with elastic or resilient damper chamber wall is described in the PS 1553280 DE, F 01 N-1/10. Disadvantages of these dampers are that they represent fluidically and acoustically a nonlinear resistance, or their constructions are production and material consuming and not always work maintenance-free. Object of the invention The aim of the invention is to eliminate the disadvantages of known solutions by the invention simple and reliable construction of the damping device. The effect of the additional chamber of the damping device is only an indirect influence on the flow medium, so that flow losses are avoided and sets a more continuous flow through the degradation of the flow peaks. Explanation of the essence of the invention Based on the object of the invention, the object is to provide a damping device for pressure oscillations in reciprocating compressors, which work with no or slight pressure losses in the damping. The pressure peaks of the pulsating compressor flow should be absorbed by an elastic membrane or a spring-loaded piston and released again in the pulsating flow drop. The features of the invention are that a damping device is connected downstream after the compression of the refrigerant in the refrigerant circuit. The damping device is arranged so that opposite to the flow direction of the inflow medium in the damper chamber, an elastic membrane or a resilient piston is arranged. Between elastic membrane and chamber rear wall is preferably a rubber-elastic filler to absorb the pressure peaks of the pulsating flow well. When using the penned pistons, the pressure peaks are absorbed by the springs.