DE102018200368A1 - Chiller with adaptive throttle - Google Patents

Abstract

The present invention relates to a refrigerating machine comprising a compressor (1), a condenser (2), an evaporator (4) and an adaptive throttle (3). Through the individual components circulates a coolant. At least one pipe of the adaptive throttle (3) comprises an adaptive material, wherein when the ambient temperature changes, the flow through the at least one pipe of the adaptive throttle (3) changes.

Description

The present invention relates to a refrigeration machine having a throttle with a tube comprising an adaptive material. Due to the adaptive material, the flow through the throttle changes depending on the ambient temperature.

State of the art

In a refrigerating machine, in a cyclic process, a gaseous refrigerant is compressed by a compressor to increase the pressure. In a downstream condenser, the refrigerant condenses, giving off heat to the environment of the refrigerator. Following this, the now liquid coolant is directed to a throttle where the pressure is reduced again. In an evaporator, the coolant then absorbs heat from the inner walls of an adjacent refrigerator and evaporates. The gaseous coolant is then in turn compressed by the compressor and the cycle closed.

The evaporation temperature in a chiller is optimized for a certain ambient temperature, so that the cooling of the chiller achieves the highest possible efficiency. The prerequisite for high efficiency is the optimal filling of the evaporator, in which the area for the heat transfer in the evaporator is maximized. The heat transfer through the wall of the cold room depends on the surface and the temperature difference. The larger the heat exchange surface area, the smaller the temperature difference between the cooling point and the coolant required for a desired cooling capacity. If a lower temperature difference is required, the evaporation temperature can be selected to be correspondingly higher. A higher evaporation temperature is equivalent to a higher evaporation pressure, which in turn means that the compressor has less compaction work to do. The actuator for the control of the level of the evaporator is the throttle. If this is opened further, pressure and temperature rise in the evaporator. If the throttle is closed again, the temperature and pressure in the evaporator will drop. The mass flow of the coolant depends largely on the cross section and the length and shape of the throttle.

By using electrically controlled expansion valves or thermal expansion valves, the flow can be adjusted to the ambient temperature, thereby increasing the efficiency of the chiller. Furthermore, a bi-stable solenoid valve with two different chokes can be used to reduce the loss of efficiency. These two chokes are optimized for two different ambient temperatures, each switching to the choke whose flow is most efficient at the actual ambient temperature.

Disclosure of the invention

The invention relates to a refrigeration machine comprising a compressor, a condenser, an evaporator and an adaptive throttle. The individual components are flowed through by a liquid or gaseous coolant, which serves for heat transport. The adaptive throttle has at least one tube comprising an adaptive material. The mass flow of the coolant through the adaptive throttle thus significantly depends on the cross section or the length and shape of the at least one tube of the adaptive throttle at the respective ambient temperature. A change in ambient temperature results in a change in the shape of the adaptive material, which changes the mass flow of the coolant through the adaptive throttle. The ambient temperature is the temperature that prevails outside of an insulated refrigerator of the refrigerator. The optimal filling of the evaporator with the coolant is thus ensured even with an increase or decrease in the ambient temperature, whereby the highest possible evaporation temperatures and thus a high efficiency of the chiller are guaranteed. The at least one tube of the adaptive throttle may comprise further materials in addition to the adaptive material. When selecting these materials, it should be remembered that their material properties do not cancel out the shape memory effect of the adaptive material - the temperature-dependent transformation of the crystal structure into an "embossed" shape - and as a result the throttle loses its function.

In accordance with one aspect of the invention, a falling or rising ambient temperature may result in a change in the diameter, length, and / or shape of the at least one adaptive throttle tube. As already explained, the mass flow of the coolant can be controlled as a function of the respectively prevailing ambient temperature of the chiller.

In one aspect, the adaptive material used in the refrigerator is a shape memory material. In shape memory materials are usually metal alloys. While most metals always have the same crystal structures up to their melting point, shape memory materials have two different crystal structures depending on their temperature. If a shape memory material is deformed, At first, its crystal structure changes. By heating the shape memory material to a phase transition temperature, the atoms in the crystal lattice regain their original arrangement and the original shape returns without any further external application of force. The phase transformation is independent of the rate at which the temperature changes. Shape memory materials and the associated temperature-dependent high restoring forces can be used particularly advantageously in refrigerators and chokes used there. In this way, a change in shape of the at least one tube of the adaptive throttle can be effected by a conversion of the crystal structure of the shape memory material as a function of the ambient temperature and thus optimally adapt the flow of the cooling material through the adaptive throttle into the evaporator. Advantageously, the fact that shape memory materials show low fatigue, whereby they reliably assume their original shape even with a very high number of phase transformation.

In particular, the size of the shape memory material of the refrigerator can be changed by at least 3% in at least one direction during the phase transformation. The phase transformation thus leads to a not inconsiderable change in size of the shape memory material and thus to a reduction or enlargement of the cross section and / or to a shortening or lengthening of the at least one tube of the adaptive throttle. By the associated temperature-dependent regulation of the coolant mass flow, an optimal filling of the evaporator and thus a high efficiency of the cooling machine can be achieved.

Advantageously, the tube of the adaptive throttle of the refrigerator on its inside a coating for the thermal decoupling of the tube of the adaptive throttle of the coolant used. Thus, it is achieved that the temperature of the coolant has no or at least only a negligible influence on the size change of the at least one tube of the adaptive throttle and thus on the circulating through the adaptive throttle in the evaporator mass flow of the coolant. For the flow through the at least one pipe of the adaptive throttle thus only the ambient temperature of the refrigerator is the relevant size, whereby the optimal filling of the evaporator is unaffected by the temperature of the coolant.

The chiller described above, which comprises an adaptive throttle, can be used particularly advantageously for cooling refrigerators.

Furthermore, shape memory materials are used as a tube for a throttle for temperature-dependent change in the flow of the coolant. Such adaptive chokes can be used wherever the flow is to be adjusted to the ambient temperature. Possible applications include heat pumps. The advantages of adaptive chokes described above can be transferred.

list of figures

• 1 zeigt eine schematische Darstellung einer Kältemaschine mit einer Ausführungsform der adaptiven Drossel.

Embodiments of the invention are illustrated in the drawings and explained in more detail in the following description.

• 1 shows a schematic representation of a refrigerator with an embodiment of the adaptive throttle.

Embodiments of the invention

1 shows a schematic representation of a refrigerator with an embodiment of the adaptive throttle 3 in a refrigerator, not shown. This has a compressor 1 , a liquefier 2 , an adaptive throttle 3 and an evaporator 4 on. An adaptive throttle tube 3 here comprises a shape memory material. The evaporator 4 is next to a cold room to be cooled 6 arranged using a refrigerator insulation 5 is shielded from temperature influences of the environment. In the chiller circulates a coolant as a heat transfer medium. This is in a compressor 1 compacted and heated. In a liquefier 2 the heat is released to the environment of the chiller. Following this, the coolant flows through the tube of the adaptive throttle 3 , in this case, the pressure of the coolant is reduced. The diameter, length and / or shape of adaptive restrictor tube 3 are due to the properties of the shape memory materials depending on the ambient temperature. Exceeds the temperature of the shape memory material of the adaptive throttle tube 3 a phase change temperature of the shape memory material, the crystal structure of the adaptive reactor tube changes 3 , From this phase transformation results in a change in the diameter, the length and / or the shape of the tube of the adaptive throttle 3 , Depending on the prevailing ambient temperature of the chiller thus the mass flow of the coolant through the pipe of the adaptive throttle 3 reduced or increased. From the adaptive throttle 3 from the coolant flows into the evaporator 4 , By adapting the mass flow through the adaptive throttle 3 will be an optimal filling of the evaporator 4 achieved with the coolant. In the evaporator 4 The coolant takes heat from the inner wall of the refrigerator 6 on, evaporates and then flows to the compressor 1 whereupon the cycle begins again.

Claims (7)

Refrigerating machine, comprising a compressor (1), a condenser (2), an evaporator (4) and a throttle through which flows a coolant for heat transport, characterized in that the throttle is an adaptive throttle (3), wherein at least one Pipe, through which the coolant flows, comprises an adaptive material, which leads to a change in the ambient temperature to a change in the flow through the pipe of the adaptive throttle (3). Chiller according to one of the preceding claims, characterized in that the adaptive material leads to a change in the ambient temperature to a change in the diameter, the length and / or the shape of the tube of the adaptive throttle (3). Chiller according to one of the preceding claims, characterized in that the adaptive material is a shape memory material. Chiller after Claim 3 , characterized in that the size of the shape memory material changes at least in one direction at a phase transformation by at least 3%. Cooling machine according to one of the preceding claims, characterized in that the adaptive throttle (3) has on its inner side a coating for the thermal decoupling of the adaptive throttle (3) from the coolant. Use of a refrigerator according to one of the preceding claims in a refrigerator. Use of shape memory materials as a tube for an adaptive throttle (3).

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