ES2942180T3 - Fan unit for refrigeration systems - Google Patents

Abstract

The invention relates to a ventilation unit (1) designed for use and arrangement in a refrigeration system, with a fan and a heat exchanger (3) arranged in series with the fan, the fan being designed and arranged in front of the heat exchanger (3).) during operation to drive a volumetric flow of air through the heat exchanger (3) and out of the ventilation unit, characterized in that the fan is designed as a diagonal fan (2) and sucks the volumetric flow of air axially during operation and blows it diagonally at an angle to its axis of rotation (RA). (Automatic translation with Google Translate, without legal value)

Description

DESCRIPTION

Fan unit for refrigeration systems

The invention relates to a ventilation unit designed for use and installation in a refrigeration plant.

A problem with the use of ventilation units having fans and heat transfer units, often called heat exchangers, in refrigeration plants is the fact that the heat exchanger continually freezes during operation and therefore increases its resistance to flow. The downstream fan must work against the increasing resistance to flow, so that its operating state is altered. Traditionally, axial fans or axial ventilation systems are used in such ventilation units, which are designed for heat exchanger flow resistance without freezing. As a result, the fan only runs for a short time in the optimal efficiency range, but with increasing freezing of the heat exchanger and its increasing resistance to flow, the fan's working state moves away from the efficiency range. optimal. Furthermore, due to the increased resistance to flow, the direction of the outflow changes from an axial direction to an increasingly radial direction.

Apart from the worse efficiency of the plant in economic terms, it is also a disadvantage from the point of view of fluidics, since the draft of the fan is considerably reduced, which results in an uneven temperature distribution in the cold room. adjacent to the fan. In addition, the radially exhausted air is partly supplied around the increasingly frozen heat exchanger and back to its intake zone, passing through the heat exchanger again and producing a thermal short circuit.

A protective grill is usually located on the exhaust side of the fan. In this area, with the increased radial outflow of the axial fan, the very cold air mixes with the air from the adjoining cold room (return flow in the hub region). In high humidity applications, ice or snow can be deposited on the fan blades or on the protective grill, which also impairs efficiency and flow characteristics. Also, when the heat exchanger is defrosting and the fan is stopped, ice can fall on the fan wall ring and prevent the fan from restarting due to freezing.

Necessary defrosting is generally a disadvantageous and costly interruption of proper operation, which should be avoided as far as possible.

Documented prior art is disclosed in JP 2003 106742 A and EP 2679 920 A2, for example.

The problem that the invention proposes to solve is, therefore, to provide a ventilation unit that overcomes the above drawbacks and can operate more efficiently, as well as defrost less frequently.

This problem is solved by the combination of features according to claim 1 of the patent.

According to the invention, a ventilation unit is designed for use and installation in a refrigeration plant, with a fan and a heat exchanger arranged in series with the fan, wherein the fan is designed and positioned with respect to the heat exchanger to supply in operation a volumetric flow of air through the heat exchanger and out of the ventilation unit. The fan is designed according to the invention as a diagonal fan. In the diagonal fan, the volumetric air flow during operation is sucked in axially and exhausted diagonally at an angle to the axis of rotation of the diagonal fan.

The diagonal fan is advantageously distinguished by a large air outlet even with a large back pressure. This ensures that the exhaust direction of the diagonal fan is always diagonal and not radial, even for the maximum back pressures that occur during operation. Its draft also remains substantially unchanged, even with a continuously increasingly frozen heat exchanger, and a thermal short circuit due to reflow at the outlet to the inlet area of the heat exchanger is avoided. Also, this prevents the heat exchanger from further freezing as a result of this. Heat exchanger defrost cycles become longer.

In an advantageous embodiment variant, the diagonal fan is designed to axially suck in the volumetric air flow and expel it diagonally at an angle of 10 - 80°, more preferably an angle of 25 - 60° with respect to its axis of rotation. Compared with a 0° exhaust angle of an axial fan and a 90° exhaust angle of a radial fan, the exhaust angle of the diagonal fan it offers an average value from the beginning, which can be maintained throughout the operation.

In a favorable embodiment of the ventilation unit it is proposed that the diagonal fan is designed to suck in the volumetric air flow axially through the heat exchanger and exhaust it from the ventilation unit to the free environment, for example in a cold room. Therefore, the bias fan is fluidly connected downstream of the heat exchanger.

The heat exchanger generates by progressive freezing for the diagonal fan during operation a resistance to flow that increases from an initial resistance to flow with a first resistance characteristic (A) to a resistance to freezing with a second characteristic (B) of endurance. An embodiment of the ventilation unit according to the invention is characterized in that the bias fan is designed to have its highest efficiency range in an area of a third resistance characteristic (C) of the heat exchanger, wherein the third resistance characteristic lies between the first and second characteristics (A, B) of resistance. The resistance characteristics (A, B, C) are characterized by an increasing back pressure, psf [Pa], plotted against a quantity, qv [m3/h], of supplied air. The exhaust flow, even with maximum back pressures, also always remains diagonal and does not change in the radial direction, as it does with axial fans.

According to the invention, the heat exchanger is designed to cool the volumetric air flow to an average supply temperature of less than or equal to 15°C, especially 5°C, to form a volume of cold air, and the diagonal fan can suck and directly expel the volumetric flow of cold air. Between the heat exchanger and the diagonal fan there are no components that thermally influence the volumetric flow of cold air, and the entrance through the diagonal fan occurs immediately downstream of the heat exchanger.

The ventilation unit in one embodiment is characterized in that the diagonal fan and the heat exchanger are connected to each other by a casing, which forms a closed flow duct for the volumetric air flow or the volumetric flow of cold air.

On the other hand, it is also advantageous if the ventilation unit is designed as an integrated structural unit for complete arrangement and fixing in the refrigeration plant. The integrated component can be pre-assembled as a whole and supplied. In the cold room, all that remains is to make the electrical connection. This reduces the chance of errors during the installation process.

In an advantageous embodiment, the heat exchanger is designed as an evaporator.

In an embodiment according to the invention, the ventilation unit furthermore comprises a guide (flow) device, which is arranged in an exhaust section of the diagonal fan and is designed to deflect the volumetric flow of air exhausted by the fan. diagonal in a diagonal direction towards an axial direction. In this way, the diagonal exhaust direction of the diagonal fan can be shifted to an axial exhaust direction, and thus the draft of the diagonal fan is increased. The guide device can be embodied by housing parts or by additionally secured guide bodies on the diagonal fan, such as air deflectors or the like. In a variant embodiment, the guide device is designed in one piece on the diagonal fan, so that the number of parts is minimized.

Furthermore, a protective grill or access barrier can be arranged on the diagonal fan on the discharge side.

On the other hand, it can be provided in the ventilation unit that the guide device converts the rotation of the volumetric air flow produced by the diagonal fan partly into static pressure and thus increases the pressure rise, the efficiency and diagonal fan throw.

According to the invention, the diagonal fan has a co-rotating cover disk that covers the fan blades. The ventilation unit in an exemplary embodiment can additionally be designed in such a way that the flow guidance occurs in the stationary housing and the diagonal fan has a fan-shaped axial wingtip. Then, a gap is formed between the impeller and the fan blades.

Other advantageous modifications of the invention are characterized in the dependent claims and are presented in detail below together with the description of the preferred embodiment of the invention with the aid of the figures. These are:

Figure 1 a non-inventive ventilation unit with a prior art axial fan to illustrate flow behavior in the frozen state;

figure 2 the fan unit from figure 1 in a non-frost state;

figure 3 a ventilation unit according to the invention in a frozen state;

figure 4 a diagram to show the design of the ventilation unit according to the invention.

Figure 1 shows the basic schematic arrangement of the ventilation unit according to the invention, but with an axial fan 11 connected to a heat exchanger 10, to illustrate fluidic problems. This shows a frozen state of the heat exchanger 10 and a resulting substantially radial exhaust flow from the axial fan 11. A thermal short circuit occurs in the flow path 8 represented by the arrows, whereby the air expelled by the axial fan 11 returns again to the inlet area of the heat exchanger. In addition, an intake flow 9 occurs on the exhaust side in the region of the hub of the axial fan 11, on which the exhaust flow is superimposed. In the frozen state of the heat exchanger, little or none of the actual purely axial outflow provided in the unfrozen state remains, as shown, for example, in Figure 2.

Figure 3 schematically shows a ventilation unit 1 according to the invention in a frozen state with a diagonal fan 2 and a heat exchanger 3, designed as an evaporator, arranged in series with it. The heat exchanger 3 and the diagonal fan are connected to each other by a casing 5, forming a flow duct. Both the diagonal fan 2 and the heat exchanger 3 are installed and secured in the casing 5, so that the ventilation unit is an integrated structural unit. A protective grill 19 is arranged in the exhaust section of the diagonal fan 2 . The ventilation unit 1 in its schematically represented form is designed for use and installation in a refrigeration plant.

In operation, the diagonal fan 2 draws in a volumetric flow of air from the axial direction through the heat exchanger 3 and then exhausts it, despite freezing, from the ventilation unit 1 diagonally at an angle a = 30° with respect to the axis of rotation, RA, of the fan 2 diagonal in the open environment, such as a cold room. The diagonal path 7 of the outlet flow is indicated by arrows.

The heat exchanger 3 cools the volumetric air flow to an average supply temperature of less than or equal to 15 °C, in particular less than or equal to 5 °C, to form the volumetric flow of cold air, which is directly taken in by the fan. 2 diagonal.

The ventilation unit 1 according to the invention in Fig. 3 with diagonal fan 2 can be interpreted, in comparison with the embodiment with an axial fan 10 shown in Fig. 1, in the manner shown in Fig. 4 with the help of a plot of the volume, qv [m3/h], of supplied air plotted against the pressure, psf [Pa]. Here, the fan characteristics 11', 2' of the axial fan 11 of FIG. 1 and of the diagonal fan 2 of FIG. 3 are graphically represented, as well as three resistance curves A, B, C due to different freezing states of the heat exchanger 3.

The flow resistance of the heat exchanger 3 increases during operation by progressive freezing from an initial flow resistance with a first resistance characteristic A for the diagonal fan to a freezing resistance with a second resistance characteristic B. In the state of the second resistance characteristic, a defrost process is started for the heat exchanger 3. The diagonal fan 2, on the other hand, is designed in such a way by its diagonal exhaust direction that it has its greatest range of efficiency in a region of the third resistance characteristic C of the heat exchanger 3, the third resistance characteristic C being between the first and second characteristics A, B of resistance. The resistance characteristics A, B, C are characterized by an increasing back pressure, psf [Pa], plotted against the volume, qv [m3/h], of supplied air.

The ventilation unit 1 according to the invention with diagonal fan 2 can operate longer and more efficiently in the region of resistance characteristic C for the same corresponding scope of delivery, compared to an arrangement with axial fan 11, which by design only works in the region of characteristic A of resistance. The absolute difference is indicated in the diagram by the characteristic curves 11', 2' of the fan of the axial fan 11 and the diagonal fan 2.

Claims (9)

1. A ventilation unit (1) designed for use and installation in a refrigeration plant, with a fan and a heat exchanger (3) arranged in series with the fan, wherein the fan is designed and positioned with respect to the exchanger (3) heat to supply in operation a volumetric flow of air through the heat exchanger (3) and out of the ventilation unit, where the fan is designed as a diagonal fan (2) and sucks the volumetric flow axially of air during operation and expels it diagonally at an angle to its axis of rotation (RA), where the heat exchanger (3) is designed to cool the volumetric air flow to an average supply temperature of < 15 °C to form a volume of cold air, wherein the diagonal fan (2) can directly suck in and exhaust the volumetric flow of cold air, and the ventilation unit further comprises a guide device, which is arranged in an exhaust section of the diagonal fan (2) and is designed to divert the volumetric flow of air exhausted by the diagonal fan (2) in a diagonal direction in an axial direction, characterized in that the diagonal fan (2) has a disc of corotative cover, and because the heat exchanger (3) for the diagonal fan (2) generates by progressive freezing during operation a resistance to flow increasing from an initial resistance to flow with a first resistance characteristic (A) up to a resistance to freezing with a second resistance characteristic (B) and the diagonal fan (2) is designed to have its greatest range of efficiency in an area of a third resistance characteristic (C) of the heat exchanger (3), where the third strength feature (C) is between the first and second strength features (A,B), and where the strength features (A,B,C) are characterized by an increase in back pressure, psf [Pa ], plotted against a quantity, qv [m3/h], of air supplied. The ventilation unit according to claim 1, characterized in that the diagonal fan (2) is designed to suck in the volumetric air flow axially and exhaust it diagonally at an angle of 10 - 80°, especially an angle of 25 - 60° about its axis of rotation (RA). The ventilation unit according to one of the preceding claims, characterized in that the diagonal fan (2) is designed and arranged in the ventilation unit (1) to suck the axial volumetric flow of air through the heat exchanger (3). heat and to expel it from the ventilation unit (1) to the free environment. The ventilation unit according to one of the preceding claims, characterized in that the diagonal fan (2) and the heat exchanger (3) are connected to one another by a casing (5) which forms a closed flow duct for the flow air volumetric. The ventilation unit according to one of the preceding claims, characterized in that it is designed as an integrated structural unit for complete arrangement and fixing in the refrigeration plant. The ventilation unit according to one of the preceding claims, characterized in that the heat exchanger (3) is designed as an evaporator. The ventilation unit according to claim 1, characterized in that the guide device is designed in one piece on the diagonal fan (2). The ventilation unit according to one of the claims 1 or 7, characterized in that the guide device is designed to transform a rotation of the volumetric air flow produced by the diagonal fan (2) partly into static pressure. The ventilation unit according to one of the preceding claims 4 to 8, characterized in that the housing (5) forms an air guide for the volumetric air flow produced by the diagonal fan (2).