RU2496064C2 - Refrigerating device - Google Patents

Abstract

FIELD: heating.

SUBSTANCE: invention refers to refrigerating device, in which there installed is evaporator with anti-icing device (4) intended for elimination of ice accretion on tube (3) for cooling agent and/or heat exchanger (2); with that, the above heat exchanger (2) includes tube (3) for cooling agent with expansion point (3.3) having an increasing diameter; at least one branch pipe (3.1) of small diameter and one branch pipe (3.2) of large diameter is connected to heat exchanger (2). Property of invention is that in comparison to front section of tube (3), the above anti-icing device (4) in section to inlet element (3.2.1) of heat exchanger is approximated to branch pipe (3.2) of large diameter and preferably to expansion point (3.3).

EFFECT: effective elimination of evaporator icing.

8 cl, 3 dwg

Description

Technical field

The invention relates to evaporative devices for refrigerators, designed to eliminate icing.

State of the art

As you know, in the refrigeration circuit of the refrigeration apparatus there is a refrigerant capable of evaporating at a low temperature, which condenses under the pressure developed by the compressor. The heated liquefied gas is directed through the heating element to the evaporator. In general, the evaporator comprises a chamber in which the heat exchanger is located. At the inlet of this heat exchanger, an expansion valve is fixed. The refrigerant entering the expansion valve expands and becomes gaseous. Such a change in the state of aggregation is accompanied by energy absorption, due to which the air surrounding the heat exchanger is cooled. With the help of the evaporator blower, cold air is directed into the cavity of the refrigerator.

Cold air enters the cavity on one side and warm air on the other. The moist warm air contained in the cavity, due to the presence of food products, etc., is sent to the evaporator. This air contains moisture, which results in icing on the evaporator.

Refrigerators, referred to as “No Frost,” use various methods to eliminate icing. In one of the methods, for example, an anti-icer is used, which comprises a heating plate heated by electric current. More specifically, the heating plate is located in the evaporator in such a way that it is optimally connected to the heat exchanger. The control device periodically includes the specified heating plate according to predefined criteria. As a result, icing and freezing are eliminated with sufficient efficiency. Embodiments of such a device are described in patent applications WO 2007031470 and WO 2007115876.

On the other hand, studies have shown that under the influence of the cold point in the evaporator, icing and freezing often occur at the expansion point in the region of the expansion valve. In existing versions, this phenomenon is not technically taken into account, and, due to the very large distance between the de-icing device and the expansion point, it is not always possible to eliminate icing at this point.

Disclosure of invention

The invention relates to a refrigerating apparatus with an evaporator, in which the aforementioned disadvantages can be eliminated and new advantages are realized in the corresponding technical field.

An object of the present invention is to effectively eliminate icing occurring in an evaporator.

Another objective within the framework of the aforementioned main goal is the effective elimination of icing that occurs in the area of transition of the liquid refrigerant to the gaseous state and in neighboring areas (unlike other areas) due to low temperatures.

In addition to these main objectives, the object of the invention is to increase the efficiency of defrosting a refrigeration apparatus while reducing energy consumption.

According to the above and below objectives arising from detailed explanations, it is an object of the present invention to provide a refrigeration apparatus in which an evaporator with an anti-icing device is installed to eliminate icing on a heat exchanger and / or refrigerant pipe, the refrigerant pipe being connected to said heat exchanger, which contains at least one nozzle of small diameter and one nozzle of large diameter, as well as an expansion point with increasing diameter.

According to the invention, the de-icing device, in comparison with the front section of the tube, is close to the large diameter pipe in the section up to the heat exchanger inlet partially or completely, and also, if necessary, close to the expansion point.

In a preferred embodiment of the invention, the longitudinal direction of the de-icing device is changed, so that the large diameter pipe is located closer to the inlet of the heat exchanger.

In a further preferred embodiment, the de-icing device extends beneath the large diameter pipe and under the inlet of the heat exchanger to a predetermined point on the base plate. In addition, the de-icing device bends upward and is oriented in the direction of the inlet element of the heat exchanger. The approximate element of the heating plate is parallel to the base plate at a constant distance from the large diameter pipe.

In a further preferred embodiment of the invention, stabilizing connecting elements are provided on an approximate element of the heating plate in the evaporator.

In a further preferred embodiment of the invention, the inlet element of the heat exchanger is approximately proportional to the de-icing device from the side of the large diameter pipe by proportionally changing the longitudinal direction.

In a further preferred embodiment of the invention, the large-diameter pipe is close to the anti-icing device by changing the input element of the heat exchanger in the part of the large-diameter pipe and the shape of the anti-icing device.

In a further preferred embodiment, the de-icing device extends on one side along the base plate. For an approximate element of the heating plate parallel to the existing heating plate, a heating plate bracket is provided.

In a further preferred embodiment, the de-icing device is in the form of a heating tube.

The design and additional elements of the invention, as well as all its advantages are explained using the detailed description on the example of the attached figures. Therefore, it is necessary to take into account the figures and explanations to them.

Brief Description of the Drawings

The figures depict:

Figure 1: perspective view of the evaporator according to the invention, inside view.

Figure 2: close-up of the tube for the refrigerant and de-icing device, close-up.

Figure 3: anti-icing device of a different design.

The implementation of the invention

Below the invention is described in detail on the example of the attached figures without any restrictions, which allows you to expand on the topic.

The figure 1 presents a variant embodiment of the invention, according to which the evaporator comprises a housing 1 of the evaporator and a heat exchanger 2, placed in the housing 1 of the evaporator. The heat exchanger 2 comprises a plurality of heat-conducting plates 2.1 arranged parallel to each other. The liquid refrigerant compressed by the compressor (not shown in the figure) and passed through the heating element (not shown in the figure) is supplied to the evaporator in the same way, through the refrigerant pipe 3.

In figures 1 and 2, a refrigerant pipe 3 is shown in which liquid refrigerant is located and on which a small diameter pipe 3.1 is installed, designated in the relevant field of technology as a capillary pipe. In addition, in the same area there is a large diameter branch pipe 3.2 (designated in the corresponding field of technology as a capillary connection) in which gaseous refrigerant is located. These two pipes 3.1 and 3.2 are connected to each other by the extension point 3.3, which is a section of a tube of increasing diameter. The specified pipe 3.2 large diameter with one end connected to the inlet 2.2 of the heat exchanger, and the other end to the release 2.3 of the heat exchanger. Tubes 3.2.1 and 3.2.2 are laid in rows above and below the heat exchanger 2 and are parallel to each other. Seam 3.4 of the exhaust part 3.2.3 is located on the heat-conducting plates 2.1. It is known from the technical field that a liquid refrigerant located in a small diameter pipe 3.1, after passing through the expansion point 3.3, due to the increase in diameter, goes into a gaseous state and moves along the large diameter pipe 3.2 to the heat exchanger 2 in the form of gas.

Figures 2 and 3 show an anti-icing device 4 (hereinafter referred to as a heating apparatus) in the form of a heating tube, which is controlled by a control device 4.3 located outside the evaporator body 1, is located between the lower part of the heat exchanger 2 and the evaporator base plate 1.1 and extends over the base plate 1.1 in the form of S. On the other hand, the heating apparatus 4 in the area of the inlet 2 of the heat exchanger extends over the base plate 1.1 in a certain area parallel to the heat exchanger 2. Noviz on the present invention lies in the fact that the heating apparatus preferably extends from the deepest point of the expansion point 3.3 upwards towards the expansion point 3.3, forming a bend 4.1, and, preferably, is directed to the outlet at the same or approximately the same height. The elevation angle is as close as possible to the right angle. After that, the approximate element 4.2 of the heating plate extends parallel to the base at a constant distance from the large diameter pipe 3.2 and ends, preferably, on the control device 4.3. Preferably, said approximate heating plate element 4.2 is connected via cable ties 5 to the heat exchanger inlet element 3.2.1, thereby stabilizing the heating plate element 4.2 in the evaporator body 1. However, in preferred embodiments of the invention, said stabilization is provided by other elements as well, for example, in one embodiment, an approximate element 4.2 of the heating plate is attached to a point on the evaporator body with a support element.

Due to this design, the heating apparatus 4 in the evaporator housing 1 is close to the coldest region corresponding to the expansion point 3.3, and, therefore, to the heat exchanger inlet element 3.2.1. Thus, icing and freezing are effectively eliminated. On the other hand, reducing the operating time of the heating apparatus 4 can save energy.

In a further embodiment of the invention, instead of approaching the heating apparatus 4, the inlet element 3.2.1 of the heat exchanger is approached to the heating apparatus 4, implemented in the form of a bend (not shown in the figure). Due to this, the inlet element 3.2.1 of the heat exchanger acquires sufficient rigidity and does not need additional stabilizing elements, cable ties or other elements.

In the following embodiment, the heating apparatus 4 and the inlet element 3.2.1 of the heat exchanger can be approached to each other in the form of bends.

In the next embodiment, the heating apparatus 4 is made in the form of an approximate element 4.2 of the heating plate, which extends on one side along the base plate 1.1, and in parallel with the existing heating plate 4 is the bracket of the heating plate.

The protected scope of the invention is disclosed in the claims and in no case can be limited by the description, which serves to explain the invention. It should be assumed that a person skilled in the art, taking into account the detailed explanations and figures, can develop similar embodiments without deviating from the main idea of the invention.

Claims (8)

1. A refrigeration apparatus comprising an evaporator with an anti-icing device (4) designed to eliminate icing on the refrigerant pipe (3) and / or heat exchanger (2), the refrigerant pipe (3) containing an expansion point (3.3) with increasing diameter, which is located on the specified heat exchanger (2), and with the heat exchanger (2) connected at least one pipe (3.1) of small diameter and one pipe (3.2) of large diameter, characterized in that the de-icing device (4), in comparison with front tube and (3), close to the large diameter pipe (3.2) in the section up to the inlet (3.2.1) of the heat exchanger and, preferably, to the expansion point (3.3). 2. The refrigeration apparatus according to claim 1, characterized in that the longitudinal direction of the anti-icing device (4) is changed so that said large diameter pipe (3.2) is located closer to the heat exchanger inlet element (3.2.1). 3. The refrigerator according to claim 1 or 2, characterized in that the de-icing device (4) extends under the inlet element (3.2.1) of the heat exchanger above the base plate to a predetermined height mark on the large diameter pipe (3.2), after which it is directed upward in the form of a bend (4.1) and is close to the inlet element (3.2.1) of the heat exchanger, and the approximate element (4.2) of the heating plate is parallel to the base plate at a constant distance from the large diameter pipe (3.2). 4. The refrigerator according to claim 3, characterized in that stabilizing fasteners are provided on the approximate element (4.2) of the heating plate in the evaporator body. 5. The refrigeration apparatus according to claim 1, characterized in that the longitudinal direction of the specified pipe (3.2) of large diameter is changed in the region of the inlet element (3.2.1) of the heat exchanger so that this pipe is close to the de-icing device (4). 6. The refrigeration apparatus according to claim 1, characterized in that the de-icing device (4) and the inlet element 3.2.1 of the heat exchanger are close to each other in the form of bends. 7. The refrigerator according to claim 1, characterized in that the de-icing device (4) extends on one side along the base plate (1.1), and for the approximate element (4.2) of the heating plate parallel to the existing heating plate (4), a heating plate bracket is provided. 8. The refrigeration apparatus according to claim 1, characterized in that said anti-icing device (4) is made in the form of a heating tube.

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