DE102016200479A1 - Arrangement for conducting refrigerant in a heat exchanger - Google Patents

Abstract

The invention relates to an arrangement (1, 1 ') for conducting a refrigerant in a heat exchanger. The arrangement (1, 1 ') has an expansion element (3, 3') and a pipeline (5, 8) with a central axis (2, 10). The refrigerant flows from the expansion element (3, 3 ') into the pipeline (5, 8). The expansion element (3, 3 ') encloses a flow path for the refrigerant, which ends at an opening (4, 4'). The opening (4, 4 ') is arranged within the pipeline (5, 8). The flow path is inclined in the region of the opening (4, 4 ') to a plane oriented perpendicular to the central axis (2, 10) in a main flow direction (6) of the refrigerant through the pipeline (5, 8) and to the central axis (2, 10). arranged spaced such that the refrigerant flows through a tangential inlet section into the pipe (5, 8). The invention also relates to the use of the arrangement for conducting the refrigerant in a refrigerant circuit.

Description

The invention relates to an arrangement for conducting a refrigerant in a heat exchanger. The arrangement comprises an expansion element and a pipeline with a central axis. The refrigerant flows out of the expander and into the pipeline. The invention also relates to the use of the arrangement for conducting the refrigerant in a refrigerant circuit.

In known from the prior art refrigerant circuits of refrigerators or heat pump systems capillary tubes are often used as expansion organs or throttle bodies. By an unsteady operating behavior, the vapor content of the refrigerant can change periodically within the refrigerant circuit at the inlet into the Drosselkapillarrohr. Among other things, with the periodically changing vapor content of the refrigerant at the inlet into the Drosselkapillarrohr also changes the phase composition of the refrigerant at the outlet of the Drosselkapillarrohres periodically. In this case, periodically and at high speed changing amounts of fluid with a larger proportion of liquid from the Drosselkapillarrohr from which are interrupted by fluid quantities with a lower proportion of liquid.

The liquid-rich fluid quantities of the refrigerant, after emerging from the throttle capillary tube, strike an inner wall of an evaporator, which is arranged downstream of the throttle capillary tube, in particular an evaporator tube. The evaporator tube has a larger diameter than the Drosselkapillarrohr. The sudden impact of the liquid-rich refrigerant on the inner wall of the evaporator generated due to the high liquid density and the high velocity of the refrigerant, a high impulse to the inner wall and thus the wall of the evaporator. The impact of the liquid-rich refrigerant stimulates the wall of the evaporator to mechanical vibrations. The structure-borne noise excited by the impact of the liquid-rich refrigerant on the wall is radiated as airborne sound at corresponding points in the refrigerant circuit of the refrigerating machine. As an external effect arise so periodically occurring noise, which can be perceived by the operator of the refrigerator or the heat pump system as disturbing.

In the conventional refrigerant circuits of refrigerators and heat pump systems, the Drosselkapillarrohr is just led into the evaporator tube and connected to the evaporator tube. The Drosselkapillarrohr and the evaporator tube are arranged coaxially aligned with each other. The refrigerant flows freely from the Drosselkapillarrohr in the inner volume of the surrounding the Drosselkapillarrohr evaporator tube and hits unhindered and unrestrained on the inner wall of the Drosselkapillarrohr subsequently arranged evaporator, that is on the inner surface of the evaporator tube. In the known coaxial arrangement of the Drosselkapillarrohres and the evaporator tube, it is not accurate to predict at which location the refrigerant impinges as a two-phase mixture of liquid and vapor or gas on the wall of the evaporator tube. So occur in a variety of refrigerant circuits of refrigerators or heat pump systems clearly perceptible flow noise.

The object of the invention is to provide an arrangement for selectively discharging a fluid, in particular a refrigerant, from an expansion element into a subsequently formed line or for introducing the fluid into a heat exchanger, in particular an evaporator, of a refrigerant circuit. In this case, a mass flow of the fluid present in particular as a two-phase mixture of liquid and vapor from the outlet of the expansion device should be specifically directed to the outlet enclosing surfaces of a wall to minimize or avoid the emission of disturbing perceptible flow noise. The arrangement should also be structurally easy to implement in order to minimize the cost of manufacturing and maintenance.

The object is achieved by the subject matters with the features of the independent claims. Further developments are specified in the dependent claims.

The object is achieved by an inventive arrangement for conducting a refrigerant in a heat exchanger. The arrangement comprises an expansion element and a pipeline with a central axis. The refrigerant flows out of the expander and into the pipeline. The pipeline is advantageously cylindrical, in particular circular-cylindrical and thus formed with a circular cross-section. However, the pipeline may also have other cross-sectional geometries.

According to the concept of the invention, the expansion device encloses a flow path for the refrigerant, wherein the flow path terminates at an opening which is arranged within the pipeline. The flow path is inclined in the region of the opening to a plane oriented perpendicular to the central axis of the pipeline in a main flow direction of the refrigerant through the pipeline and to the central axis of the pipeline arranged spaced such that the refrigerant flows through a tangential inlet section into the pipeline.

According to a preferred embodiment of the invention, the heat exchanger is designed as an evaporator of the refrigerant, so that the refrigerant flows as a two-phase mixture of liquid phase and vapor phase in the pipe of the heat exchanger.

By means of the inclined orientation according to the invention of the opening of the flow path as the exit of the expansion element, the refrigerant expanded on passing through the expansion element into a two-phase region of vapor and liquid flows in a tangentially targeted manner to an inner wall of the pipeline surrounding the opening. The tangential orientation of the opening of the flow path as the exit from the expansion element with respect to the downstream in the flow direction of the refrigerant pipe causes a selective application of the subject to different impulses liquid-vapor mixture of the refrigerant to a wall of the pipeline. In this case, the refrigerant is compared to conventional coaxial arrangements of the flow path or the exit of the expansion device in the pipeline much slower and slower slowed down or decelerated, so that a force occurring is introduced gently and smoothly into the pipeline. This also vibration excitations are reduced or avoided by force surges due to periodically changing fluid densities of liquid and vapor. In addition, pressure pulsations in the fluid caused by the periodically changing fluid densities of fluid and vapor at the throttle exit are reduced or avoided in the fluid downstream along the main flow direction. With the targeted influencing of the flow of the refrigerant according to the invention at the outlet of the expansion element, the structure-borne noise-inducing impulse effect of the refrigerant impinging on the wall of the pipeline is reduced or even avoided. In addition, the mechanical loads on the mechanically coupled with the arrangement components are minimized.

A development of the invention consists in that the expansion element is designed as a capillary tube.

According to a first alternative embodiment of the invention, the expansion element and the pipeline are arranged aligned on a common central axis. The expansion element designed as a capillary tube has a first, straight section and a second section designed as a cylindrical spiral. The axis of the first section of the expansion element corresponds to the central axis and the second section of the expansion element is wound uniformly around the central axis. The second section of the capillary tube, which is wound uniformly around the central axis, is advantageously arranged with an outer side adjacent to an inner side of a wall of the pipeline such that the flow direction of the refrigerant exiting from the capillary tube is aligned parallel to the inner side of the wall of the pipeline in the region of the opening , This ensures that the refrigerant flows through a tangential inlet section into the pipeline.

According to a development of the invention, the pipeline is designed as a transition element made of areas with different diameters. In this case, the inner diameter of the pipeline in a region corresponds to the outer diameter of the first region of the capillary tube, so that an outer side of the wall of the capillary tube rests against an inner side of the pipeline. The portion of the abutment of the first region of the capillary tube and the pipeline is advantageously formed as a fluid-tight connection.

A third region of the pipeline is preferably formed with an extension of the diameter as a transition to a tube, wherein the inner diameter of the third region of the pipeline corresponds to the outer diameter of the tube, so that an outer side of the wall of the tube rests against an inner side of the third region of the pipeline. The portion of the abutment of the third region of the pipeline and the pipe is advantageously formed as a fluid-tight connection.

According to a second alternative embodiment of the invention, the expansion element and the pipe have two axes aligned differently with respect to each other. In this case, the axis of the expansion element and the axis of the pipeline are arranged at different levels and at an angle inclined to each other.

Another advantage of the invention is that the expansion member encloses a rectilinear flow path and the conduit has a region of tapered diameter at a junction with a connection to the expansion member. The tapered diameter portion is formed with an opening inclined to a center axis. The expansion member designed as a capillary tube is inserted into the pipeline in a region having a smallest diameter, wherein the inner diameter of the pipeline corresponds to the outer diameter of the expansion element, such that an outer side of the wall of the expansion element abuts on an inner side of the pipeline in such a way, in that the flow direction of the refrigerant exiting from the expansion element is aligned in the region of the opening parallel to the inside of the pipeline. This ensures that the refrigerant flows through a tangential inlet section into the pipeline. The portion of the abutment of the expansion member and the pipe are formed as a fluid-tight connection.

The arrangement for conducting the refrigerant into a heat exchanger is advantageously used in a refrigerant circuit in which the refrigerant circulates in a flow direction. In the flow direction of the refrigerant, the refrigerant circuit preferably has at least one compressor and a heat exchanger for cooling and / or liquefying the refrigerant, the arrangement according to the invention and a heat exchanger for evaporating the refrigerant.

Further details, features and advantages of embodiments of the invention will become apparent from the following description of exemplary embodiments with reference to the accompanying drawings. Each show an arrangement for conducting refrigerant, especially for discharging refrigerant from an expansion element and for introducing the refrigerant into a pipeline, in particular a circular cylindrical pipe and a pipe operated as an evaporator heat exchanger, with a tangential inlet path of the refrigerant into the pipeline , generated by:

1 a tubular piece formed as a cylindrical spiral, and

2 : a targeted inclination of the inlet of the pipeline.

In 1 is an arrangement 1 for conducting refrigerant, especially for discharging the refrigerant from an expansion device 3 and for introducing the refrigerant into a pipeline 5 shown. The order 1 in particular has a pipeline 5 a operated as an evaporator heat exchanger with a tangential inlet path of the refrigerant in the pipeline 5 on.

The designed as a capillary expansion device 3 , Also referred to as Drosselkapillarrohr due to the function of throttling or expanding the refrigerant, and the pipeline 5 are on a common central axis 2 arranged aligned. The capillary tube 3 has a first, straight section 3a and a second section formed as a cylindrical spiral or as a cylindrical screw 3b on. The one from the capillary tube 3 enclosed flow path is thus within the first section 3a straight and within the second section 3b spirally wound and extends to an opening 4 , The helically wound second section 3b of the capillary tube 3 lies with the outside on the inside of the wall of the pipeline 5 at. The opening 4 of the capillary tube 3 is to one perpendicular to the central axis 2 aligned plane in the main flow direction 6 of the refrigerant through the pipeline 5 arranged inclined. The main flow direction 6 is in the direction of the central axis 2 aligned.

That from the opening 4 effluent two-phase mixture of liquid and vapor is thus tangential in the pipeline 5 introduced, so that the refrigerant via a tangential inlet section into the pipeline 5 flows in and in the main flow direction 6 is forwarded. By means of the tangential to the inside of the wall of the pipeline 5 and in relation to the perpendicular to the central axis 2 aligned plane inclined arrangement of the opening 4 as outlet of the capillary tube 3 the refrigerant flows deliberately led into the pipeline 5 one. The refrigerant becomes the central axis 2 inclined and tangentially introduced into the pipeline. The refrigerant passing through the opening 4 into the pipeline 5 enters, flows predominantly along the inside of the wall. A centrifugal force acts on the pipe 5 inflowing, different pulses having two-phase mixture of the refrigerant with a vaporous and a liquid phase, which is deliberately applied to the wall. By the targeted application of the flowing refrigerant to the wall of the pipeline 5 slow flow is achieved with gentle and even force transfer to the surrounding surfaces. The targeted guidance of the flow of the refrigerant at the outlet of the capillary tube 3 reduces or eliminates the structure-borne noise-inducing impulse action of the refrigerant impinging on the wall and reduces or prevents the propagation of pressure pulsations downstream along the main flow direction of the fluid.

The pipeline 5 is as a transitional element 5 to the flow direction of the refrigerant to the expansion device 3 subsequent, operated as an evaporator heat exchanger of the refrigerant circuit to view. The expansion organ 3 and the heat exchanger are thus components of a refrigerant circuit, not shown, which also has at least one compressor and a heat exchanger for cooling and / or liquefying the refrigerant in the flow direction of the refrigerant.

The transition element 5 is from different areas 5a . 5b . 5c formed with different diameters. In the area of the smallest diameter of the transition element 5 is the capillary tube 3 introduced, wherein the inner diameter of the transition element 5 essentially the outer diameter of the first area 3a of the capillary tube 3 corresponds to the outside of the wall of the capillary tube 3 on the inside of the transition element 5 is applied. Between the capillary tube 3 and the area of the smallest diameter of the transition element 5 is a fluid-tight connection 7 educated. The fluid-tight connection is preferably produced by soldering or welding or compression. The trained as a cylindrical screw second section 3b of the capillary tube 3 is within a second range 5b of the transition element 5 arranged. The second area 5b of the transition element 5 has a larger diameter than the area with the smallest diameter, wherein both the area with the smallest diameter and the second area 5b are each formed with a constant diameter and both areas over a first area 5a connected to each other. The first area consequently has a steadily increasing diameter. The largest diameter corresponds to the diameter of the second area 5b and the smallest diameter the diameter of the area of the fluid-tight connection 7 with the capillary tube 3 , A third area 5c of the transition element 5 is designed as an extension and transition to a tube of the operated as an evaporator heat exchanger. The tube of the heat exchanger is in the third area 5c of the transition element 5 introduced, wherein the inner diameter of the third area 5c of the transition element 5 substantially corresponds to the outer diameter of the tube of the heat exchanger, so that the outside of the wall of the tube of the heat exchanger on the inside of the third region 5c of the transition element 5 is applied. Between the tube of the heat exchanger and the third area 5c with the largest diameter of the transition element 5 In turn, a fluid-tight connection is formed, which is preferably produced by soldering or welding or compression. The third area 5c is expanded with the diameter such that the inserted tube of the heat exchanger has the same value of the inner diameter as the second region 5b of the transition element 5 to ensure an aligned and formed wall for the refrigerant flowing therethrough.

2 shows an arrangement 1' for conducting refrigerant, especially for discharging the refrigerant from an expansion device 3 ' and for introducing the refrigerant into a pipeline 8th , The order 1' in particular has a pipeline 8th a operated as an evaporator heat exchanger with a tangential inlet path of the refrigerant in the pipeline 8th or the heat exchanger.

The likewise designed as a capillary expansion device 3 ' encloses compared to the embodiment according to 1 , in particular in the area of the transition to the pipeline 8th , a straight-line flow path. The flow path ends at the opening 4 ' inside the pipeline 8th ,

The pipeline 8th is at the junction and at the junction with the capillary tube 3 ' with a region of tapered diameter and one to the central axis 10 inclined arranged opening formed. In a region of the smallest diameter is the capillary tube 3 ' into the pipeline 8th introduced, with the inner diameter of the pipeline 8th essentially the outer diameter of the capillary tube 3 ' corresponds to the outside of the wall of the capillary tube 3 ' on the inside of the pipeline 8th is applied. Between the capillary tube 3 ' and the pipeline 8th is a fluid-tight connection 7 ' educated.

The capillary tube 3 ' and the pipeline 8th have two different axes 9 . 10 on. The axis 9 of the capillary tube 3 ' and the axis 10 the pipeline 8th are in different planes and at an angle inclined to each other arranged such that a targeted inclination of the inlet of the refrigerant in the pipeline 8th is guaranteed. The opening 4 ' of the capillary tube 3 ' is also perpendicular to the axis 10 aligned plane in the main flow direction 6 of the refrigerant through the pipeline 8th arranged inclined. The main flow direction 6 is in the direction of the axis 10 aligned.

That through the opening 4 ' from the capillary tube 3 ' effluent two-phase mixture of liquid and vapor is tangential into the pipeline 8th introduced, so that the refrigerant via a tangential inlet section into the pipeline 8th the heat exchanger flows in and in the main flow direction 6 is forwarded. By means of the tangential to the inside of the wall of the pipeline 8th and in relation to the perpendicular to the axis 10 aligned plane suitable arrangement of the opening 4 ' as outlet of the capillary tube 3 ' the refrigerant flows deliberately led into the pipeline 8th one. The refrigerant becomes an axis 10 inclined and tangential in the pipeline 8th initiated. The refrigerant passing through the opening 4 ' into the pipeline 8th is introduced, flows predominantly along the inside of the wall along. A centrifugal force acts on the pipe 8th inflowing, different pulses having two-phase mixture of the refrigerant with a vaporous and a liquid phase, which is deliberately applied to the wall. By the targeted application of the flowing refrigerant to the wall of the pipeline 8th slow flow is achieved with gentle and even force transfer to the surrounding surfaces. The targeted guidance of the flow of the refrigerant at the outlet of the capillary tube 3 ' reduces or eliminates the structure-borne noise-inducing impulse action of the refrigerant impinging on the wall and reduces or prevents the propagation of pressure pulsations downstream along the main flow direction of the fluid.

The expansion organ 3 ' and the heat exchanger are components of a refrigerant circuit, not shown, which also has at least one compressor and a heat exchanger for cooling and / or liquefying the refrigerant in the flow direction of the refrigerant.

LIST OF REFERENCE NUMBERS

1, 1 '

 Arrangement for conducting refrigerant

2

 central axis

3, 3 '

 Expansion organ, capillary tube

3a, 3a '

 first section - straight

3b

 second section - cylindrical screw

4, 4 '

 opening

5

 Pipe, transition element

5a

 first area

5b

 second area

5c

 third area

6

 Haupströmungsrichtung

7, 7 '

 fluid-tight connection

8th

 Pipeline, heat exchanger

9

Axial capillary tube 3 '

10

Central axis, axis pipeline 8th

Claims (10)

Arrangement ( 1 . 1' ) for conducting a refrigerant in a heat exchanger, comprising an expansion element ( 3 . 3 ' ) and a pipeline ( 5 . 8th ) with a central axis ( 2 . 10 ), whereby the refrigerant from the expansion organ ( 3 . 3 ' ) into the pipeline ( 5 . 8th ) flows in, characterized in that the expansion organ ( 3 . 3 ' ) encloses a flow path for the refrigerant, which at an opening ( 4 . 4 ' ), where - the opening ( 4 . 4 ' ) within the pipeline ( 5 . 8th ) and - the flow path in the region of the opening ( 4 . 4 ' ) to a perpendicular to the central axis ( 2 . 10 ) aligned plane in a main flow direction ( 6 ) of the refrigerant through the pipeline ( 5 . 8th ) inclined and to the central axis ( 2 . 10 ) are arranged such that the refrigerant through a tangential inlet section into the pipeline ( 5 . 8th ) flows in. Arrangement ( 1 . 1' ) according to claim 1, characterized in that the heat exchanger is formed as an evaporator of the refrigerant, so that the refrigerant as a two-phase mixture of liquid phase and vapor phase in the pipeline ( 5 . 8th ) flows in. Arrangement ( 1 . 1' ) according to claim 1 or 2, characterized in that the expansion organ ( 3 . 3 ' ) is formed as a capillary tube. Arrangement ( 1 ) according to claim 3, characterized in that the expansion organ ( 3 ) and the pipeline ( 5 ) on a common central axis ( 2 ), wherein the expansion element ( 3 ) a first, straight section ( 3a ) and formed as a cylindrical spiral second section ( 3b ), wherein the axis of the first section ( 3a ) of the expansion organ ( 3 ) of the central axis ( 2 ) and the second section ( 3b ) of the expansion organ ( 3 ) evenly around the central axis ( 2 ) is wound around. Arrangement ( 1 ) according to claim 4, characterized in that the wound second section ( 3b ) of the capillary tube ( 3 ) with an outside on an inner side of a wall of the pipeline ( 5 ) is arranged in such a way that the flow direction of the capillary tube ( 3 ) leaking refrigerant in the region of the opening ( 4 ) parallel to the inside of the wall of the pipeline ( 5 ) is aligned. Arrangement ( 1 ) according to claim 4 or 5, characterized in that the pipeline ( 5 ) as a transitional element with areas ( 5a . 5b . 5c ) is formed with different diameters, wherein the inner diameter of the pipeline ( 5 ) in a region of the outer diameter of the first region ( 3a ) of the capillary tube ( 3 ) and an outer side of the wall of the capillary tube ( 3 ) on an inner side of the pipeline ( 5 ), wherein the portion of the concern of the first area ( 3a ) of the capillary tube ( 3 ) and the pipeline ( 5 ) as a fluid-tight connection ( 7 ) is trained. Arrangement ( 1 ) according to claim 6, characterized in that a third area ( 5c ) of the pipeline ( 5 ) is formed with an extension of the diameter as a transition to a tube, wherein the inner diameter of the third region ( 5c ) of the pipeline ( 5 ) corresponds to the outer diameter of the tube and an outer side of the wall of the tube at an inner side of the third region ( 5c ) of the pipeline ( 5 ), the section of the concern of the third area ( 5c ) of the pipeline ( 5 ) and the tube is formed as a fluid-tight connection. Arrangement ( 1' ) according to claim 3, characterized in that the expansion organ ( 3 ' ) and the pipeline ( 8th ) two different from each other aligned axes ( 9 . 10 ), wherein the axis ( 9 ) of the expansion organ ( 3 ' ) and the axis ( 10 ) of the pipeline ( 8th ) are arranged at different levels and at an angle inclined to each other. Arrangement ( 1' ) according to claim 3 or 8, characterized in that the expansion organ ( 3 ' ) encloses a rectilinear flow path and the pipeline ( 8th ) at a transition to a connection to the expansion organ ( 3 ' ) has a region with a tapered diameter, which with a to a central axis ( 9 ) is arranged inclined, wherein in an area with a smallest diameter, the expansion organ ( 3 ' ) into the pipeline ( 8th ) and the inner diameter of the pipeline ( 8th ) the outer diameter of the expansion element ( 3 ' ), so that an outer side of the wall of the expansion organ ( 3 ' ) on an inner side of the pipeline ( 8th ) is applied in such a way that the flow direction of the expander ( 3 ' ) leaking refrigerant in the region of the opening ( 4 ' ) parallel to the inside of the pipeline ( 8th ), the section of the concern of the expansion organ ( 3 ' ) and the pipeline ( 8th ) is formed as a fluid-tight connection. Use of an arrangement ( 1 . 1' ) according to one of the preceding claims in a refrigerant circuit, wherein the refrigerant circuit in the flow direction of the refrigerant at least one compressor and a heat exchanger for cooling and / or liquefying the refrigerant, the arrangement ( 1 . 1' ) and a heat exchanger for vaporizing the refrigerant.

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