DE102014001886A1 - Optimized intermediate injection point - Google Patents

Abstract

Refrigerating and / or freezing appliance with at least one refrigerant circuit, wherein the refrigerant circuit comprises at least one condenser and at least two evaporator or evaporator sections, wherein at least one connecting line for the refrigerant is located between at least the evaporators or evaporator sections and wherein at least one Zwischeneinspritzstelle is provided in this connecting line by means of which refrigerant can be injected into the connecting line, wherein the intermediate injection point has at least one expansion tube which is connected to the connecting line and whose cross-sectional area increases in the flow direction of the refrigerant.

Description

The present invention relates to a refrigerator and / or freezer with at least one refrigerant circuit, wherein the refrigerant circuit comprises at least one condenser and at least two evaporators or at least two evaporator sections, wherein between the evaporators or between the evaporator sections at least one connecting line for the refrigerant is and in this connection line at least one intermediate injection point is provided, by means of which refrigerant can be injected into the connecting line.

Cooling or freezing devices are known from the prior art, the refrigerant circuit comprises at least one condenser and at least two evaporators, wherein at least one connecting line is provided, through which the liquid refrigerant flows from one evaporator to the other evaporator. Furthermore, it is known to provide an intermediate injection point in this connection line, at which a line is brought together with the connection line, this line being controlled by a control element, e.g. B. from a valve upstream of the evaporator leads to the intermediate injection point. This arrangement serves to adjust the amount of the refrigerant supplied to the evaporators in the desired manner.

Such, known from the prior art refrigerant circuit is in 4 shown.

The reference number 10 indicates the compressor of the refrigerant circuit from which the refrigerant to the condenser 20 flows. From the liquefier 20 the refrigerant flows to the multiway valve 30 , From there leads a first line 40 to the first evaporator 50 , which may be, for example, a refrigerator part evaporator.

This evaporator 50 Downstream is the evaporator 60 which may be, for example, a freezer evaporator.

The reference number 70 denotes throttle bodies.

Between the two evaporators 50 . 60 is the connection line or main connection line according to the invention 4 , How out 4 can be seen, is located in this main connection line 4 an intermediate injection site 1 on which a line 2 in the main line 4 opens, the other end with the regulatory body, z. B. valve 30 connected is. At the pipe 2 it is a bypass line of the evaporator 50 , Depending on the position of the valve 30 the refrigerant gets into the pipe 40 or in the line 2 or at the same time in both lines.

Instead of a multi-way valve, it is also conceivable that in each of the lines 40 or 2 ever any other control organ, z. B. a valve is used.

As this continues in 4 indicated by dashed lines, instead of exactly one intermediate injection point, a plurality of intermediate injection points and more than two evaporators or more than two evaporator sections may be provided.

5 shows the intermediate injection point according to the prior art. Like this 5 shows, the line becomes 2 formed by a capillary, which is in the pipe 4 is inserted. After the refrigerant has left the end area of the capillary 2 this mixes with the in the pipe 4 located main stream 5 of the refrigerant.

A disadvantage of the known arrangement is that, due to the abrupt expansion of the refrigerant in the outlet region of the capillary, swirls can arise, which can lead to a development of noise and to an increase in the flow resistance. Through the free, unfixed end of the capillary, into the connecting line 4 protrudes, can also cause vibrations, which can also cause unwanted noise.

The present invention has the object of developing a refrigerator and / or freezer of the type mentioned in such a way that the noise in the region of the intermediate injection is reduced or eliminated altogether.

This object is achieved by a refrigerator and / or freezer with the features of claim 1.

Thereafter, it is provided that the intermediate injection point has at least one expansion tube which is connected to the connecting line and whose cross-sectional area increases in the flow direction of the refrigerant.

This configuration of an expansion tube ensures that the injected refrigerant is continuous, d. H. gently brought to expansion. The known from the prior art vortex, which can lead to a noise, can be largely or completely avoided.

Due to this configuration of the expansion tube also the advantage is achieved that in the intermediate injection point freshly injected refrigerant is optimally admixed to the main flow of refrigerant flowing in said connecting line. Depending on the operating point, the intermediate injection point can also act as the sole injection point. In this case, it is also ensured by the design of the expansion tube according to the invention that in comparison to known embodiments, a reduced noise during injection is present or noise is completely prevented.

In a preferred embodiment of the invention, at least one capillary tube is provided, the end of which is accommodated without play in the expansion tube. By this complete encompassing of the end of the capillary through the expansion tube, vibrations of the end of the capillary are prevented, whereby with regard to the noise development a further improvement over known embodiments occurs. A swinging of the free capillary end, as in the embodiment according to 5 is possible from the prior art, is excluded.

The expansion tube may be formed in regions or over its entire length conical. It may comprise straight walls and / or curved wall sections.

The cross-sectional area of the expansion tube preferably increases in the flow direction of the refrigerant over its entire length or over a substantial part of the length of the expansion tube. However, the invention also includes the case that such an increase in the cross-sectional area over the length of the expansion tube is present only in regions, d. H. that there are also areas in which the cross-sectional area does not change along the length of the expansion tube.

Furthermore, it can be provided that the expansion tube is directly connected to the connecting line or is also connected via an intermediate piece indirectly with the connecting line.

It is conceivable, for example, that the intermediate injection point is designed in the form of a Y-piece. In this case, the refrigerant flowing through the connecting pipe flows through one leg of the Y-shaped piece and the refrigerant flowing through the expansion pipe through the other leg of the Y-piece. There, both streams are merged into a common stream and then get into the evaporator.

In a preferred embodiment of the invention it is provided that the connection between the expansion tube and the connecting line is formed by one or more solder joints. It is conceivable that the expansion tube is soldered to the connecting line or, conversely, the connecting line is soldered to the expansion tube.

As stated above, it is also conceivable, by means of a Y-piece merge the refrigerant flows from the connecting line and the expansion tube and provide corresponding solder joints, which join the connecting line and the expansion tube in the form of a Y-piece.

In a further embodiment of the invention, it is provided that the expansion tube and the line section located downstream of the intermediate injection point lie on a line or are aligned with one another. In this way, the injected into the expansion tube refrigerant can be introduced largely without turbulence and deflections in the line section, which eventually leads to the evaporator.

However, the invention also includes the case that the expansion tube is curved and in particular has a curvature in its end region in which it communicates with the connecting line. This is the case, for example, when a Y-piece is used, by means of which the expansion tube and connecting line are in communication.

In a further embodiment of the invention, it is provided that the refrigerant circuit has at least two evaporator or at least two evaporator sections, one of which is assigned to the refrigerator part and a freezer part of the device and that the intermediate injection point in a line section, d. H. located in the connecting line between these two evaporators or evaporator sections.

Further details and advantages of the invention will be explained in more detail with reference to an embodiment shown in the drawing.

Show it:

1 FIG. 2 is a schematic view of the connection line and the expansion tube soldered to the connection line. FIG.

2 FIG. 2 is a schematic view of the connection pipe and the expansion pipe, wherein the connection pipe is soldered to the expansion pipe, FIG.

3 FIG. 2 is a schematic view of the connecting pipe and the expansion pipe, which are designed as Y-pieces. FIG.

4 a schematic view of a possible refrigerant circuit according to the present invention and

5 an intermediate injection site according to the prior art.

In 1 is with the reference numeral 4 a connecting line or a main connecting line, which extends between two evaporators of a refrigerant circuit.

For example, reference is made to the in 1 illustrated refrigerant circuit, which is also an embodiment of the present invention.

Like this 1 shows, is located between the evaporators 50 and 60 the main connection line 4 ,

Like this further 1 is found in this main interconnector 4 the intermediate injection point 1 , in the two pipes, namely on the one hand, the connecting line 4 and on the other hand, the expansion tube 3 be merged according to the invention.

Notwithstanding the in 5 illustrated embodiment of the prior art, the expansion tube with the connecting line 4 connected and the capillary 2 coming from the valve 30 according to 1 extends to the intermediate injection point is located in an end portion of the expansion tube 3 , The capillary is thus not according to the invention directly with the connecting line 4 in connection, but indirectly via the expansion tube 3 ,

Instead of a valve, any other adjusting or regulating member can be used, by means of which the refrigerant flow can be controlled or regulated.

That from the capillary 2 leaking liquid refrigerant is in the expansion tube 3 injected and expanded there evenly. Through the trumpet-shaped expanding expansion tube 3 can swirl around the injection point, ie the end of the capillary 2 , be largely or completely avoided.

The expansion tube 3 is connected to the connecting line so that freshly injected refrigerant from the capillary 2 optimally to the main stream 5 , ie with the refrigerant flow in the connecting line 4 is mixed. In certain operating points, ie if in the connecting line 4 no refrigerant flows, the intermediate injection point 1 also be used as the sole injection point.

Like this 1 and also from the other embodiments according to the 2 and 3 As can be seen, the capillary end is not loose in the expansion tube 3 but is completely covered by this, and preferably without play, so that vibrations are reduced or avoided.

Through the trumpet-shaped or starting from the capillary 2 conically expanding shape of the expansion tube 3 is the refrigerant that comes out of the capillary 2 exits, gently and steadily brought to expansion and can in this state with the main stream 5 in the connection line 4 be mixed at the junction of both lines.

Like this from the embodiment according to 2 indicates the connection line 4 in the area of the intermediate injection point 1 a substantially S-shaped course. In this area becomes the expansion tube 3 with the connection line 4 connected and preferably by a circumferential solder joint L with the connecting line 4 connected. Instead of a solder joint, a welded joint is also considered.

2 shows an embodiment according to the invention, in which the connecting line 4 in her to the expansion tube 3 directed end portion has a curvature. In this end area becomes the connecting line 4 to the substantially straight expansion tube 3 soldered or welded.

The respective peripheral solder joint or weld is in the embodiment according to 1 and 2 as well as in the embodiment described below 3 denoted by the reference L.

Out 1 and 2 shows that the expansion tube 3 and the conduit section extending downstream of the intermediate injection site 100 are essentially on a line, ie aligned with each other, so that through the capillary 2 injected and in the expansion tube 3 relaxed refrigerant largely linear in this pipeline 100 can occur.

3 shows an embodiment in which the connecting line 4 and the expansion tube 3 Y-shaped to a common line 100 be merged. In each case, there is a leg of this Y-shaped intermediate piece on the one hand with the connecting line 4 and on the other hand with the expansion tube 3 in connection. Both the refrigerant flowing through the connecting pipe 4 flows as well as the refrigerant flowing through the expansion tube 3 flows through, thus traversing a curved area, before they are then merged and together through the pipe 100 be led to the evaporator.

The solder joints or welds in this embodiment are also marked with the reference symbol L.

As is the case from the embodiment according to FIG 1 As can be seen, not just an intermediate injection point 1 be provided, but there may be a plurality of intermediate injection points in one and the same refrigerant circuit. Accordingly, not only two but also more than two evaporators or evaporator sections may be provided.

By the present invention, it is possible to provide an optimized injection of the refrigerant in an intermediate injection point, in which the noise in the region of the intermediate injection point is reduced. The free capillary end, which is located within the connecting line, as known from the prior art, and which may for example have a length of 10 mm, is preferably avoided by the capillary end being completely enclosed by the expansion tube.

The present invention results in a flow-mechanically optimized mixing of the two refrigerant streams. The absence or reduction of turbulence results in lower pressure drops and less noise. Apart from that results in an optimal expansion of the refrigerant when the evaporator 60 is operated alone.

Claims (10)

Cooling and / or freezer with at least one refrigerant circuit, wherein the refrigerant circuit comprises at least one condenser and at least two evaporator or evaporator sections, wherein between the evaporators or between the evaporator sections is at least one connecting line for the refrigerant and wherein at least one Zwischeneinspritzstelle provided in this connecting line is, by means of which refrigerant can be injected into the connecting line, characterized in that the intermediate injection point has at least one expansion tube which is connected to the connecting line and whose cross-sectional area increases in the flow direction of the refrigerant. Cooling and / or freezing appliance according to claim 1, characterized in that at least one capillary tube is provided, the end of which is preferably received without play in the expansion tube. Cooling and / or freezing appliance according to claim 1 or 2, characterized in that the expansion tube is formed in regions or over its entire length conical. Cooling and / or freezing appliance according to one of the preceding claims, characterized in that the cross-sectional area of the expansion tube increases in regions or over the entire length of the expansion tube. Cooling and / or freezing appliance according to one of the preceding claims, characterized in that the expansion tube is directly connected to the connecting line in communication or is indirectly connected via an intermediate piece with the connecting line. Cooling and / or freezing appliance according to one of the preceding claims, characterized in that the intermediate injection point is designed in the form of a Y-piece. Cooling and / or freezing appliance according to one of the preceding claims, characterized in that the connection between the expansion tube and the connecting line is formed by one or more solder joints or welds. The refrigerator and / or freezer according to any one of the preceding claims, characterized in that the expansion tube and the lying downstream of the intermediate injection line line section lie on a line. The refrigerator and / or freezer according to one of claims 1 to 7, characterized in that the expansion tube is formed curved in its end region, in which it communicates with the connecting tube. The refrigerator and / or freezer according to one of the preceding claims, characterized in that the refrigerant circuit comprises at least two evaporator or at least two evaporator sections, at least one of which is assigned to a cooling part and at least one freezer part of the device and that the connecting line between the two Evaporators or evaporator sections is located.

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