EP2821737A1 - Refrigeration and/or freezer device - Google Patents

Abstract

The present invention relates to a refrigerator and / or freezer with at least one refrigerant circuit comprising at least one refrigerant line and in which at least one condenser and at least one downstream of the condenser evaporator is arranged, wherein upstream of the evaporator, at least one expansion unit is arranged, in the the refrigerant is depressurized, wherein in the refrigerant line between the outlet of the condenser and the inlet of the expansion unit is at least one liquid refrigerant permeable porous body or wherein the expansion unit is partially or completely formed by a permeable for liquid refrigerant porous body.

Description

The present invention relates to a refrigerator and / or freezer with at least one refrigerant circuit comprising at least one refrigerant line and in which at least one condenser and at least one downstream of the condenser befindlicher evaporator is arranged, wherein upstream of the evaporator, at least one expansion unit is arranged, in which the refrigerant is released when flowing through.

Conventional refrigerant circuits of known refrigerators or freezers include a condenser, an evaporator and an expansion unit in the form of a capillary arranged between condenser and evaporator. After flowing through the evaporator, the refrigerant passes to the compressor where it is compressed and returned to the condenser by means of the compressor.

In the operation of such refrigerators or freezers, the problem may arise that noises caused by the refrigerant flow in the refrigerant circuit occur. To counteract this, for example, in so-called Rollbond or Z-Bond evaporators, the channels are designed so that as possible set low flow noises. This can be achieved by bypass channels, parallel channel structures, different or adapted pipe cross sections, etc. Furthermore, it is known to avoid noise by a suitable injection geometry, such as a trumpet-shaped embodiment of the transition region between the capillary and evaporator in this area as possible.

It is also known to design the outlet opening of the capillary in such a way that a possible rounded outlet opening results without burrs.

The present invention has the object of developing a refrigerator or freezer of the type mentioned in such a way that the noise caused in the context of the flow of the refrigerant can be further reduced.

This object is achieved by a refrigerator and / or freezer with the features of claim 1. Thereafter, it is provided that there is at least one permeable for liquid refrigerant porous body in the refrigerant line between the outlet of the condenser and the inlet of the expansion unit.

It is also conceivable that the expansion unit, which is arranged upstream of the evaporator, is partially or completely formed by a porous body permeable to liquid refrigerant. In this case, the function of the expansion element, which is usually designed as a capillary, partially or completely taken over by said porous shaped body. In this case, the porous shaped body is preferably designed with respect to its porosity so that the pressure loss for the refrigerant flowing through is equal to or less than with a commonly used expansion element. Its function can thus be completely or partially taken over by the porous body. In the case of complete adoption of the function no pressure-reducing capillary is necessary. If the function is partially taken over, a pressure-reducing capillary is still used.

Preferably, this porous body is formed so that the flow resistance generated by the body for liquid refrigerant is lower than for vapor refrigerant. The porous body is thus preferably designed so that it can pass liquid refrigerant with low flow resistance and represents a larger (considerable) flow resistance for vaporous refrigerant.

According to the invention, at least one built-in part is thus provided in the refrigerant circuit, which is in direct contact with the refrigerant and which directly influences the noise behavior in a reducing manner.

Said body has the task of preventing the formation of vapor bubbles and / or their backflow against the main flow direction of the refrigerant as far as possible. The formation of vapor bubbles may be due to cavitation or insufficient undercooling of the refrigerant.

In a preferred embodiment of the invention, the porous body has the task of preventing the formation of bubbles on the thermodynamic / fluid dynamic level.

It is preferably provided that the body is attached to the inlet of the refrigerant in the expansion unit or in the expansion device.

By using this body, the location of the phase transition is e.g. stabilized within the expansion unit or inside the capillary, by preventing or reducing the backflow through the pulse at the bubble formation. The backwards, d. H. refrigerant accelerated against the main flow direction can not pass through the body due to the high pulse velocity.

Through the body, both such a backward flow of the liquid Käl- temittels and the return flow of vapor refrigerant, for example in the area the entry into the expansion unit prevents or at least reduced. As a result, irregular flow noise or cavitation noise can be largely or completely prevented.

In a preferred embodiment of the invention, it is provided that at least one filter drier is located in the outlet of the condenser or between the outlet of the condenser and the inlet of the expansion unit and that the body is in or at the end of the filter drier facing the expansion unit.

It should be noted at this point that the terms "upstream", "downstream", "inlet" or "inlet" and "outlet" etc. refer to the direction of flow of the refrigerant in which it flows through the refrigerant circuit during operation of the compressor ,

The body may be located in or at the end of the filter drier. The filter dryer can be arranged directly in the inlet area of the expansion unit or else be mounted inside the tube of the condenser outlet.

It is also possible that the porous body partially or completely takes over the function of the dryer or the desiccant therein. By a corresponding materiality of the porous molding of a material in which a dryer is usually constructed, this task can be fulfilled.

It is thus conceivable, for example, that the porous molded body partially or completely takes over the function of the component dryer and / or the component expansion element with appropriate geometric and material design, so that partially or completely the previous elements dryer and / or expansion element and in particular the capillary can be omitted ,

Furthermore, it can be provided that the body is located in or at the entrance of the expansion unit.

Thus, it is possible for the body to be arranged in or at the entrance area of the capillary leading to the evaporator or another expansion unit, such as, for example, an expansion valve or an expansion machine.

It is conceivable that a hollow shaped body is provided between the filter drier or condenser outlet and the inlet of the capillary or another expansion unit, and that the body according to the invention is arranged at any position on this shaped body or in front of or behind this shaped body.

In a further embodiment of the invention, it is provided that the body is designed as a modular component or is part of a modular component and / or that the body or the modular component is mounted between two pipe sections of the refrigerant circuit.

Considered, for example, a mounting by soldering, welding, gluing, by a clamping ring connection (Lokring or Swagelog) or a combination of two or more of the aforementioned types of fastening.

It is also conceivable to carry out the body in the form of a modular component or as part of a modular component which is inserted at a suitable point in the refrigerant circuit at the end or at the beginning of a pipe section. Again, a solder joint, welded joint, a connection by gluing, a clamping ring connection (eg Lokring or Swagelog), by positive locking, by adhesion or even by a combination of at least two of the aforementioned measures is conceivable.

The body itself may, for example, be cylindrical, round, spherical, disc-shaped, rod-shaped, bulk material in any desired form or as a shaped body, or it may also occupy several of the abovementioned forms.

This shaped body can be adapted, for example, to the inner shape of the filter dryer. Consider, for example, a conical shape of the body with a centrally located receiving cavity for the entrance of the capillary.

In a preferred embodiment of the invention it is provided that the body in addition to the above-mentioned influencing the location of the phase transition has a sound-insulating function.

In a further embodiment of the invention, it is provided that the degradation of the supercooling produced by the pressure loss during the flow is <3K and preferably <1K.

The body is designed as a porous structure, which includes all bodies having a plurality of passages for the liquid refrigerant, such as e.g. Pores, meshes, holes etc ..

The porous body is preferably compatible with the refrigerants R600a, R134a, R290, R744, R1234, with mineral oil, silicone oil, synthetic oils, copper, aluminum and steel.

Preferably, the body is heat-resistant, which is required for mounting the body during soldering and also adhesive-resistant.

The body may be formed as a molecular sieve (eg silica gel), activated alumina, as a sintered material of metal, plastic (eg polyester mat) or on an inorganic basis.

A foam or foam-like body made of metal, plastic or inorganic base is also considered.

The body can also be designed as a sieve or filter, wherein these can each be made either of metal, of plastic (eg polyester mat) or of inorganic base.

A preferred pore size or opening size of the body is in the range between 1 .mu.m and 50 .mu.m.

In a further embodiment of the invention, it is provided that the body is an active or passive material which is designed such that, depending on the phase state and / or the noise behavior of the refrigerant, its free flow cross-section, in particular its mesh size or Adjusts pore size.

Also, a combination of two or more of the aforementioned forms and materials of the body is conceivable and mitumfasst of the invention.

If, for example, it is an active component or a passive component which is able to adapt its mesh size or pore size, this adaptation can take place electrically, electronically, magnetoresistively, thermally or by pressure or also by electroresistance.

A particularly preferred embodiment of the invention is that the body is designed as a metal sintered body and has a mesh size / pore size between 1 .mu.m and 50 .mu.m.

This body can be arranged in a filter drier which, for example, is located directly in the inlet area of a capillary, which in turn leads to the evaporator.

It is preferably provided that the porous structure of the body over the length of the porous body in the flow direction of the refrigerant is not constructed homogeneously. In a preferred embodiment, it is provided that its pore size decreases in the flow direction. This decrease can be realized continuously or else in stages or by means of different porous shaped bodies which are installed one behind the other. Also, this succession of several moldings and generally the arrangement of several moldings is understood as "moldings" within the meaning of the invention. It is also conceivable that the pore size in the end region of the molding increases again.

Comparatively coarse pores at the flow inlet serve to filter impurities, finer pores are used for throttling or pressure reduction in the central region of the molding and coarse pores or medium or fine or very fine at the outlet serve to cause a low exit noise of the refrigerant, which due to reduced flow rates is the case.

If the shaped body replaces the expansion element or if the expansion element is formed by the shaped body, an expansion element in the form of a pressure-reducing capillary can be dispensed with. The spatial distance from the condenser outlet to the evaporator can then be bridged, for example, via a capillary which does not reduce or only slightly reduces pressure. The injection point of the refrigerant into the evaporator corresponds to the exit from the shaped body, which ends in the evaporator inlet.

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

The single FIGURE shows a schematic representation of a filter dryer and a capillary with a arranged in the filter dryer flow stabilizer in the form of the porous body according to the invention.

The sole FIGURE shows by reference numeral 1 a throttle capillary or a connection capillary to a throttle body, such as a valve, which is not shown in the figure.

The figure shows the inlet end of the capillary 1, in which the liquid refrigerant from the filter drier, whose housing bears the reference numeral 4, enters.

The reference numeral 5 indicates a desiccant in the filter drier, such as silica gel.

Reference numeral 6 denotes the cavity of the filter drier which is filled with the desiccant 5 except for the space occupied by the porous structure 3.

The reference numeral 3 denotes the porous body, d. H. the flow stabilizer according to the present invention.

As can be seen from the figure, this body has a cavity 2 which extends in the end region of the capillary 1.

Instead of the illustrated arrangement, it is also possible that the porous body 3 encloses the capillary 1 in a form-fitting manner.

The reference numeral 7 finally indicates the main flow direction of the refrigerant. This passes from a condenser, not shown, according to the figure from above into the filter drier and then into the capillary 1 shown.

In the figure, the dryer is arranged upright. Of course, the invention also includes the case that the dryer can be mounted in the refrigeration cycle horizontally or in any other orientation.

If no porous body 3 is used, there is a risk that within the capillary, in which the liquid refrigerant changes into vaporous refrigerant, a vaporous backflow in the region of the inlet into the capillary 1 can occur opposite to the main flow direction 7. As a result, irregular flow noise or cavitation noise can occur.

The presence of the porous body 3 in the inlet region of the capillary 1 stabilizes the location of the phase transition and prevents or reduces said backflow. The accelerated by the vapor refrigerant backwards, d. H. Because of its high pulse speed, liquid refrigerant moving counter to the direction 7 is decelerated on the porous body 3 and can not pass through it, or only to a minor extent.

However, passage of the liquid refrigerant according to the figure from the top to the bottom (i.e., in the main flow direction) through the body 3 is possible. However, a passage of the vaporous refrigerant is comparatively difficult, so that it can not emerge upwards or out of the capillary 1 in a subordinate extent against the main flow direction 7.

As a result, the uncontrolled vapor bubble formation is largely or completely suppressed by cavitation or by backflow of vapor bubbles or due to insufficient supercooling of the refrigerant. The energy consumption can also be reduced by the positive effect on the noise generation. As stated above, the supercooling degradation caused by the pressure loss is <3K and preferably <1K.

Instead of or in addition to the position of the porous body shown in the figure, this can for example be arranged within the capillary 1.

Claims (11)

Refrigerating and / or freezing appliance with at least one refrigerant circuit, which comprises at least one refrigerant line and in which at least one condenser and at least one downstream of the condenser befindlicher evaporator is arranged, wherein upstream of the evaporator, at least one expansion unit is arranged, in which the refrigerant is expanded, characterized in that in the refrigerant line between the outlet of the condenser and the inlet of the expansion unit is at least one liquid refrigerant permeable porous body or that the expansion unit is partially or completely formed by a liquid refrigerant permeable porous body. The refrigerator and / or freezer according to claim 1, characterized in that the body is formed such that the flow resistance generated by the body for liquid refrigerant is lower than for vapor refrigerant. Refrigerating and / or freezing appliance according to claim 1 or 2, characterized in that at least one filter drier is located in the outlet of the condenser or between the outlet of the condenser and the inlet of the expansion unit and that the body is in or at the end of the expansion unit Filter drier is located and / or characterized in that the body is located in or at the entrance of the expansion unit and / or characterized in that the refrigerant circuit comprises at least one filter drier which is partially or completely formed by the porous body. Cooling and / or freezing appliance according to one of the preceding claims, characterized in that the body is designed as a modular component or is part of a modular component and / or that the body or the modular component is mounted between two pipe sections of the refrigerant circuit or in the end region or inserted or inserted into another section of a pipe of the refrigerant circuit. Cooling and / or freezing appliance according to one of the preceding claims, characterized in that the body is cylindrical, round, spherical, disc-shaped, rod-shaped, formed as bulk material or as a molded body, which is adapted in its outer shape to at least one immediately adjacent or adjacent component , The refrigerator and / or freezer according to any one of the preceding claims, characterized in that the body has sound insulating properties and / or that the degradation of the supercooling caused by the pressure loss during the flow is <3 K and preferably <1 K. Cooling and / or freezing appliance according to one of the preceding claims, characterized in that the body is formed as a molecular sieve. Refrigerator and / or freezer according to one of the preceding claims, characterized in that it is the body is a sintered body, which preferably consists of metal, plastic or an inorganic material or one or more of the aforementioned materials, wherein it is preferably provided in that the mesh size or the pore size is between 1 and 50 μm. Cooling and / or freezing appliance according to one of the preceding claims, characterized in that the body consists of a foam, sieve or filter or has one or more of these components. The refrigerator and / or freezer according to one of the preceding claims, characterized in that it is the body is an active or passive material, which is designed such that it depending on the phase state and / or noise behavior of the refrigerant its free flow cross-section , in particular its mesh size or pore size changes. Cooling and / or freezing appliance according to one of the preceding claims, characterized in that the pore size of the porous body decreases in the flow direction of the refrigerant or initially decreases and then increases.

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