DE3033685A1 - Axial inflow cooling air impeller for air conditioner - has blades with specified contour to produce outflow component in radial direction - Google Patents

Abstract

The impeller (60) is intended for moving the cooling air through the heat exchanger of an air-conditioning unit. It comprises a hub (10) with a number of blades (71) each having a segment (75) near its tip edge (72), a leading edge (73), and a trailing edge (74). The tip segment region (75) has an S-shaped cross-section along a circular arc (between 0.7 and 0.9D) about the impeller centre (O). This cross-section has a point of inflexion or a flat portion between leading (73) and trailing (74) edges. The blade surface from this point or portion to the leading edge is concave and to the trailing edge convex.

Description

HITACHI, LTD.

5-1, Marunouchi 1-chome, Chiyoda-ku,

Tokyo, Japan

Pipe blower for air conditioning

The invention relates to an air conditioning system, in particular for use in the external unit of an air conditioning system.

There is known a two-part air conditioner which has an indoor unit arranged in a room and a Outdoor unit, which is arranged in the open air, comprises, both units by ducts for heating or cooling the room air are connected to each other. Usually the indoor unit includes a heat exchanger for heating or cooling the room air and a fan that conveys the room air to the heat exchanger, and comprises the outdoor unit a heat exchanger that either extracts heat from the outside air or heats it, a fan for conveying the Outside air to the heat exchanger, and a compressor for conveying a coolant in the circuit to the heat exchangers the outdoor and indoor units. In both units, the heat transfer capacity is increased by a The volume of air supplied to the heat exchangers is improved. On the other hand, an increase in the number of heat exchangers required The amount of air supplied by the blower increases the size of the blower motors, which in turn increases the

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Fan power consumption increased. Furthermore, there is an increase in the volume of air conveyed by the fans an increased noise development. The amount of air supplied to a fan is thus chosen so that a heat exchanger can perform satisfactorily while reducing noise can be kept small by the fan motor and the power consumption of the fan motor. In the case of the outdoor unit however, in a two-part air conditioner, there is often an obstacle nearby, which is the passage of air can obstruct, and the presence of an obstruction can reduce the flow of the fan to the heat exchanger cause the conveyed amount of air, whereby the performance of the heat exchanger is reduced.

Fig. 1 is a horizontal sectional view through the outdoor unit, a known air conditioning system, with a compressor 2, a heat exchanger 4-, a fan motor 7 and a fan 6 secured to the fan motor 7 by means of a hub 10. The compressor 2, the heat exchanger 4- and the fan motor 7 are housed in a case 1, and the fan 6 is driven by the fan motor 7. The compressor 2 in the housing 1 is enclosed by a sound-absorbing wall 3 so that the noise it generates does not penetrate to the outside. In a section facing the heat exchanger 4, the housing 1 has a suction air grille 5 through which air is sucked in. An annular fan guide 8 is arranged in the housing 1 and encloses the fan 6, and an outlet grille 9 is provided on the front side of the fan 6 , through which air is conveyed. In the outdoor unit constructed in this way, the air is sucked in the direction of the arrows A, through the intake grille 5 into the unit, where it flows through the heat exchanger Ί , the fan in the direction of the arrows A _? is penetrated and conveyed to the outside through the outlet grille 9 of the unit.

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When the air flows through the heat exchanger A-, occurs a heat transfer between the air and the coolant flowing in the heat exchanger A-. With this well-known Outside unit, the air flows parallel to the axis of rotation of the fan, as indicated by the arrows A and A ».

According to FIG. 2, the fan of the known external unit comprises the hub 10 and four identically shaped blades 61. The blades 61 are inclined towards the cylindrical hub 10 (cf. FIG. 3), namely via a blade section 65 near the outer edge 6A Blade 61. Each blade is arcuate in cross-section. According to the sectional view of FIG. 3, the blade 61 is cut in the form of an arc of an imaginary circle, the center of which lies on the central axis 0 of the hub 10 and which is developed in a straight line. Thus, when the fan 6 rotates in the direction of an arrow R in Fig. 2, a leading edge 63 of each blade 61 traps air, and the air trapped by the blade 61 flows along the surface of the blade to a trailing edge 6A- from which the air in the direction of arrows A _? is promoted. In each blade 61, a present near the front edge 63 of portion 66 and a present near the trailing edge 6A portion 61 is shaped so that (see. The cross-sections of FIG. A · and Fig. 5), the portions 66 and 67 in the outer edge portion 62 are inclined upward in the course of the hub 10 to the outer edge 62. Each blade 61 is curved and has a concave top side 68 and a convex bottom side 69 . The sectional views of FIGS. A and 5 each show the blade 61 cut along a plane which runs perpendicular to the center axis 0 of the hub 10. The surface of each blade 61 serves to convey air, and the lower surface 69 faces the heat exchanger A-. With this configuration of the blade 61, the air entrained by the leading edge 63 is prevented from flowing to the outer edge 62. As a result, the air exiting the fan 6 flows

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essentially completely parallel to the axis of rotation of the fan 6, see arrows A _? in Fig. 1). It is known that an air conditioning system employing this fan 6 has a high degree of efficiency.

Nevertheless, the known fan 6 has a disadvantage. If the outdoor unit of the two-part air conditioning system is fastened in a position in which an obstacle 12 lies in front of the fan 6 (cf. the dashed lines in FIG. 1), the amount of air conveyed by the fan 6 is greatly reduced. That is to say, if the fan has an increased pressure loss, the amount of air conveyed by the fan is greatly reduced. A reduction in the amount of air conveyed causes a reduction in the amount of air passing through the heat exchanger 4, so that the heat transfer capability of the heat exchanger 4 is reduced. Furthermore, since the air flow discharged from the blower 6 hits the obstacle 12, a loud noise is generated. It has therefore hitherto been customary to select a position in which there is no obstacle when the outdoor unit of a known air conditioner is mounted.

The present invention has been developed in order to eliminate the aforementioned problem of the known blower. task The invention is therefore to provide an improved tubular blower for use in the outdoor unit of a two-part Air conditioning, whereby the amount of air delivered by the fan is not reduced when in the flow path an air flow emerging from the fan is an obstacle, and the noise caused by impact the conveyed air on the obstacle is very low.

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This object is achieved in a tubular blower according to the invention in that the blower has blades, wherein a portion of each vane near an outer edge of the vane is substantially S-shaped or undulating in cross-section is trained; this section is arcuately cut so that the center axis of the hub is the center an imaginary circle of which the arc is a part. That is, the section near the outer edge of each The blade is shaped in cross section so that its upper side is convex and its lower side towards the leading edge concave and to the rear edge its top is concave and its bottom is convex. Thus between the convex and concave surface portions are a turning point or straight portion. With every shovel is a section close to the trailing edge running from the hub to the outer edge in an arc shape. Compared to that corresponding section of a known blade, however, the direction of the arc is reversed, and this section has a convex top and a concave bottom. A section of each blade near the leading edge has a concave top and a convex bottom, like that of the corresponding section of the known Shovel is the case.

Due to the specified construction of the blades promotes the fan according to the invention air parallel to the axis of rotation of the fan and also in a direction in which the Air flows away from the axis of rotation of the fan. That is to say, in that the one located near the outer edge of each blade Section is S-shaped or undulating in cross-section and the section of each blade near the trailing edge is a Has a convex surface, the air is carried away by the blade through the outer edge and flows from the axis of rotation the blower gone. As a result, the volume of air flowing away from the direction of rotation also increases if there is an obstacle in front of the fan,

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and the flow of air parallel to the direction of rotation of the fan is prevented. Thus, through the presence an obstacle causes at most a slight change in the volume of air conveyed away by the fan .

The invention is explained in more detail, for example, with the aid of the drawing. Show it:

1 shows a sectional view through an external unit of a known two-part air conditioning system;

FIG. 2 is a front view of the fan of the outdoor unit according to FIG. 1 in the direction of an arrow B;

Fig. 3 is a sectional view III-III according to FIG. 2, wherein a blade of the fan of Fig. 2 in the form of an arcuate portion of an imaginary Circle, with the center on the center axis of the hub and developed in the form of a straight line, cut-is;

FIG. K shows a sectional view IV-IV according to FIG. 2, the blade being cut along a plane perpendicular to the center axis of the hub;

5 shows a sectional view V-V according to FIG. 2, with the blade along a central axis the hub vertical plane is cut;

6 is a sectional view through the external unit of a two-part air conditioning system in which the Pipe blower according to the invention is provided;

Fig. 7 is a side view of the tubular blower according to the invention;

Fig. 8 is a front view of the pipe blower according to Invention, seen in the direction of an arrow K in Fig. 6;

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9 shows a sectional view IX-IX according to FIG. 8, with the fan blade in the form of a Arc section of an imaginary circle, the center of which is on the center axis of the hub lies, developed as a straight line, is cut;

Fig. 10 is a sectional view X-X according to Fig. 8, the fan blade along a to Center axis of the hub vertical plane is cut; and

11 shows a sectional view XI-XI according to FIG. 8, with the fan blade along a central axis the hub vertical plane is cut and developed as a straight line.

Fig. 6 shows the external unit of a two-part air conditioning system, which uses the pipe blower according to the invention. Just like the known fan, the fan 60 is on the Fan motor 7 secured by the hub 10, and the compressor 2, the heat exchanger 4 and the fan motor 7 are arranged in the housing 1. In the case of an outdoor unit with the tubular fan 60, the air flows according to the arrows A through the intake grille 5 into the outdoor unit and passes through the "heat exchanger A-. The Air through the fan 60 (see. Arrows A- and A.,) and is conveyed out of the unit through the outlet grille 9 to the outside. According to Fig. 6, the air is out of the fan 60 in an air stream which runs parallel to the axis of rotation of the fan 60 (cf. arrows A ~), and in an air stream which runs away from the axis of rotation of the fan 60 (cf. arrows A,).

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According to FIGS. 7 and 8, the fan 60 comprises the hub 10 and four blades 71 of identical design. The blades 71 are fastened at an angle with respect to the hub 10. 9 shows in cross section a section 75 near an outer edge 72 of each blade 71, which is cut in the form of an arc of an imaginary circle, the center of which lies on the center axis 0 of the hub and which is developed in the form of a straight line. Thus, the vane 71 has a substantially S-shaped or undulating shape in cross-section, with a portion of the vane near the leading edge 73 having a convex top 78 and a concave bottom 79 and a portion near a trailing edge 7A- having a concave top 78 and a convex bottom 79 . A turning point 11 or straight section lies in the middle between the front edge 73 and the rear edge 74. The air is conveyed away from the upper side 78, and the lower side 79 faces the heat exchanger A-. Thus, while the fan 60 rotates in the direction of arrow R in Fig. 8, the leading edge 73 of each vane 71 traps air, and the air so trapped flows along the top of the vane 71 to the trailing edge 74, from which it is directed in the direction of the arrow A _? is promoted. The air reaching the rear edge 7A- is conveyed away in the direction of arrow A.

If a section 77 of each blade 71 is close to the trailing edge 7A - along a perpendicular to the central axis 0 of the hub 10 extending plane is intersected and the turning point 11 or an arbitrarily chosen point on the straight section interspersed, the section 77 has an arc shape in cross section with the convex upper side 78 and the concave Bottom 79.

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Part of the air entrained by each blade 71 thus flows to the outer edge 72 and is from there in Direction of the arrow A ^ or from the center axis 0 of the Hub 10 carried away. A section 76 of each blade near the leading edge 73 has (see. Fig. 11, section line XI-XI) the convex upper side 78 and the concave lower side 79, which are also used in the case of the blade 61 according to the state the technology are available. The air conveyed away through the section 76 of each blade 71 thus flows in parallel to the axis of rotation of the fan 60 as in the case of the blade 61 of the known fan.

The results of experiments carried out on the blade 71 of the fan 60 will now be explained. The radius from the center axis 0 of the hub 10 to the outer edge 72 of the blade 71 is denoted by D. The test results show that the vane 71 should be shaped to be in a vane area between 0.7 D and 0.9 D is S-shaped (undulating) in cross section as in FIG. 9. When a section of the shovel 71 did not have an S-shaped or undulating cross-section between 0.7 D and 0.9 D, the volume of the air flowing out was reduced.

In Fig. 9, the length between the leading edge 73 and the trailing edge 74 · is denoted by -C and the length between the trailing edge 74 · and the turning point 11 or straight section is denoted by Δ-C. The test results show that the ratio _s &> t. / -Z should be between 0.2 and 0.5. D ₀ hp the turning point 11 is advantageously chosen so that the ratio <& «€ / • £ is between 0.2 and 0.5. When the ratio was less than 0.2, the volume of the air flowing in the direction of arrow A, was decreased. If it was greater than 0.5, the air entrained by the leading edge 73 was not in the direction of arrow A-,

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but in the direction of arrow A-, conveyed away. This air meets the fan guide 8 and can be removed from the Unit cannot be conveyed to the outside, which reduces the volume of air given off by the fan and result in increased noise development.

The position of the highest point of the section 77 of the blade 71, the arcuate along a to the central axis 0 or Hub 10 is cut in the vertical plane and runs through the turning point 11, is denoted by P (see. Fig. 10), and the distance between P and the center axis 0 is denoted by d. The test results show that the The ratio of the distance d to the radius D of the fan 60 or the ratio d / D should be between 0.3 and 0.6. The position of P is advantageously chosen so that d / D is between 0.3 and 0.6. When the location of the highest Point P was chosen so that d / D was between 0.3 and 0.6, the air flow was in that of the axis of rotation of the fan 60 leading away direction or in the direction of the arrow A- supports and increases its volume. Even if there was an obstruction in front of the fan 60, there was none The volume of the air discharged from the fan 60 decreased and the noise level did not increase.

The height of the highest point X in FIG. 10 is assumed to be X. The test results show that the height X or the highest point P should be chosen so that the ratio of the height X to the radius D, that is X / D, is between 0.04 and 0.16. That is to say, the height X of the highest point P is advantageously chosen such that X / D is between 0.04 and 0.16. When X / D was greater than 0.16, an eddy current was generated between the highest point P and the outer edge 72, thereby reducing the volume of air discharged from the blade 71 and increasing the noise level. When X / D was less than 0.04, there was a decrease in air volume in the direction of A _1,.

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From the above explanation it can be seen that the specified pipe blower for use in an air conditioning system give over the prior art has differently designed blades. Dede shovel embraced a portion near the outer edge of the S-shaped or undulating blade with a concave surface near the leading edge and a convex surface near the trailing edge of the blade, and a portion near the Trailing edge that is arcuate with a convex surface. By these design features of the fan blades it is achieved that the air released by the fan is not only parallel to the axis of rotation of the Blower, but also flows in a direction leading away from this axis of rotation. So even if before the The outdoor unit of the air conditioner is obstructed or the outdoor unit is mounted in a position in which there is an obstacle in front of the fan, there is no reduction in the volume of the conveyed by the fan Air and no increase in the noise level.

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Claims (3)

Expectations .) Pipe blower for use in the external unit of a two-part air conditioning system, with a plurality of identically designed blades secured to a hub, each blade having: - a section near its outer edge, - a section near its leading edge, and - a section near its trailing edge, and - wherein the portion located near the front edge has a concave surface, characterized, - That the section (75) located near the outer edge (72) of the blade (71) is substantially in cross-section The S-shape is cut through an arc of an imaginary circle, the center of which is on the central axis (0) of the Hub (10) lies, and a reversal point (11) or straight section between the leading edge (73) and the trailing edge (74 ·) of the blade (71), and - That the surface (78) of the blade (71) between the Reversal point (11) or straight section and the leading edge (73) concave and between the reversal point (11) or straight section and the trailing edge (7A-) is convex. 81- (A 4981-01) -Schö 130012/08 2. Pipe blower according to claim 1,
characterized, - That the section (77) near the rear edge (74) of the blade (71) is arcuately cut in cross section along a plane perpendicular to the central axis (0) of the hub (10) and the reversal point (11)
interspersed, and that its surface (78) is convexly shaped. 3. Pipe blower according to claim 1,
characterized, - That the section (77) near the rear edge (74) of the blade (71) is cut arcuately in cross section along a plane which is to the central axis (0) of the
Hub (10) runs vertically, and one arbitrarily
selected point at the straight section of the S-shaped section (75) penetrated, and that its surface (78) is convexly shaped. 130012/0870