KR100800912B1 - Impeller, blower and refrigerator - Google Patents

Abstract

The recessed part (air flow direction conversion means) 8b is provided in the pressure surface 5 side of the blade 8, and the convex part 8a (air flow attachment means) is provided in the trailing edge of the blade 8. The airflow passing through the impeller 9 is converted into the airflow in the axial direction by the concave portion 8b, and flows in the vicinity of the convex portion 8a. This axial airflow acts to suppress peeling of the airflow on the negative pressure surface side, and suppresses the disturbance during the confluence of the airflow on the negative pressure surface side and the airflow on the pressure surface side. Thereby, deterioration of the blowing performance of an impeller and increase of blowing noise can be suppressed.

Description

Impeller, Blower and Freezer {IMPELLER, BLOWER AND REFRIGERATOR}             

1 is a front view of the impeller of the first embodiment of the present invention,

2 is a cross-sectional view taken along the line a-a of FIG.

3 is a front view of main parts showing the action of the impeller of the first embodiment of the present invention,

4 is a cross-sectional view taken along line b-b of FIG. 3 showing the action of the impeller according to the first embodiment of the present invention;

5 is a cross-sectional view taken along line b-b of FIG. 3 showing another action of the impeller according to the first embodiment of the present invention;

6 is a cross-sectional view taken along line c-c of FIG. 3 showing the action of the impeller of the prior art;

7 is a cross-sectional view taken along the line d-d of FIG. 3 showing the action of the impeller according to the first embodiment of the present invention;

8 is a characteristic diagram showing a comparison between the blower of Example 1 of the present invention and the static pressure-air volume (P-Q) characteristics of the impeller of the conventional example;

9 is a front view of main parts of another impeller of the first embodiment of the present invention;

10 is a front view of main parts of another impeller of the first embodiment of the present invention,

11 is a front view of main parts of another impeller of the first embodiment of the present invention,                 

12 is a dimensional view of the impeller of the first embodiment of the present invention,

Fig. 13 is a characteristic diagram showing the relationship between the center position DM of the convex portion 8a of the impeller of the first embodiment of the present invention and the static pressure P of the operation operating point,

14 is a characteristic diagram showing the relationship between the length DT of the bottom side of the convex portion 8a of the impeller of the first embodiment of the present invention and the static pressure P of the driving operation point;

Fig. 15 is a characteristic diagram showing the relationship between the height H of the convex portion 8a of the impeller according to the first embodiment of the present invention and the static pressure P of the driving operation point.

Fig. 16 is a front view of main parts showing the action of the impeller according to the second embodiment of the present invention;

17 is a front view of the blower of the third embodiment of the present invention;

18 is a cross-sectional view taken along the line e-e of FIG. 17;

FIG. 19 is a sectional view taken along the line f-f of FIG. 18 showing the action of the blower according to the third embodiment of the present invention;

20 is a cross-sectional view of the blade of Figure 19 moved in the rotational direction,

21 is a side longitudinal sectional view of the freezer in the fourth embodiment of the present invention;

22 is a front view of an impeller of a conventional example,

FIG. 23 is a cross-sectional view taken along line x-x of FIG. 22;

24 is a front view of principal parts showing the action of the impeller of the conventional example;

25 is a sectional view taken along the line y-y in FIG. 24;

<Explanation of symbols for main parts of drawing>

2: motor 3: hub                 

5: pressure surface 8: blade

8a: convex portion 8b: concave portion

9: impeller 10: first mouse ring

11: second mouse ring 12: outer wall

13: opening 14: swirl flow circulation space

15a, 15b: pillar 16, 16a: blower

101: storage room 105: machine room

150: freezer

The present invention relates to a blower used in refrigerators, air conditioners, OA equipment and the like.

In recent years, axial blowers have been widely used in refrigerators, air conditioners, OA equipment and the like. As a conventional axial blower, what is disclosed in Japanese Patent Laid-Open No. 1999-44432 is known. A conventional axial blower will be described below with reference to the drawings.

22 to 25 are conventional axial flow impellers, FIG. 22 is a front view of the impeller, FIG. 23 is a sectional view taken along line xx of FIG. 22, FIG. 24 is a partially enlarged view showing the action of the impeller, and FIG. 25 is yy of FIG. Line cross section.

As shown in FIG. 22, the impeller 1 has a hub 3 attached to the motor 2, and a plurality of blades 4 provided around the hub 3. The blade 4 has an outer periphery of the projection 6 refracted to the pressure surface 5 side. The blade 4 is inclined so that the leading edge part 4a is located in the front side of the figure rather than the trailing edge part 4b. When the impeller 1 rotates to the left as indicated by the arrow 40, the air is in FIG. Blowing is carried out in the axial direction shown by the arrow 41.

The operation | movement is demonstrated below about the impeller comprised as mentioned above. First, when the impeller 1 is rotated at a predetermined rotation speed by the motor 2, air flows into the impeller 1, and the positive pressure and the dynamic pressure are added by the action of the impeller 4 to discharge the impeller 1. And blowing operation is performed. By providing the projection 6 on the pressure surface 5 side of the blade 4, the flow of leakage from the pressure surface 5 to the negative pressure surface 7 is first increased at the protruding initiation portion, and the blade is circumscribed from the shaft center side to the blade circumference. The noise generation factor is reduced by reducing the fluctuation component included in the mainstream flowing along the pressure surface. That is, by forming a leakage flow from the pressure surface to the negative pressure surface, pressure fluctuations (pressure difference between the pressure surface and the negative pressure surface) at the outer circumferential end are reduced to suppress the noise increase.

However, when the impeller 1 is used under conditions of high wind speed resistance, such as in a refrigerator, the air flow passing through the pressure surface 5 side of the blade 4 has a strong air flow as shown in FIG. It becomes A). The airflow with a strong radial component is blocked by the protrusions 6 provided on the pressure surface 5 side of the blade 4 and converted in the axial direction, and discharged from the trailing edge of the blade 4. Therefore, the discharge air flow velocity in the axial direction from the trailing edge on the pressure surface 5 side increases.
In addition, under conditions of high air flow resistance, a large circulation vortex (not shown) is generated at the tip of the suction side of the blade 4, so that the air flow sucked into the impeller 1 is disturbed and the negative pressure surface 7 is removed. Following air flow causes delamination. In other words, when the airflows on the pressure surface 5 side and the negative pressure surface 7 side join at the trailing edge of the blade 4, the speed difference is large and the airflow is disturbed. Therefore, the turbulence sound generated by deterioration of the blowing performance of the impeller 1 increases. The present invention provides an impeller that solves the above problem.

The impeller of this invention is equipped with the hub attached to the motor, and the some blade provided around the hub. The blade includes airflow direction converting means for converting the air flow sucked into the blade provided on the blade side of the blade in the axial direction, and airflow attaching means for attaching the peeling flow provided in the trailing edge of the blade, and the shaft is formed by the airflow direction converting means. The airflow converted into the direction flows near the airflow attachment means.

At high wind resistance, airflows with large radial velocity components pass through the impeller. The airflow having a large radial velocity component is converted into the axial airflow by the airflow direction converting means and increases the axial airflow speed blown from the pressure surface side. The said axial airflow flows in the vicinity of an airflow attachment means, suppresses the peeling of the airflow on the negative pressure surface side, and acts to suppress the disturbance which arises when the airflow on the negative pressure surface side and the airflow on the pressure surface side merge. In this way, the impeller of the present invention suppresses deterioration of blowing performance and increase of blowing noise.

Hereinafter, an embodiment of the present invention will be described with reference to FIGS. 1 to 21. The same reference numerals are attached to parts having the same configuration as in the prior art, and description thereof is omitted.

(Example 1)

1 to 15 show an impeller of Embodiment 1 of the present invention. 1 and 2, a plurality of blades 8 are provided around the hub 3. The convex part (air flow attachment means) 8a is provided in the trailing edge of the blade 8, and the recessed part (air flow direction conversion means) 8b is provided in the pressure surface 5 side of the blade 8, One end of the recess 8b extends to the vicinity of the trailing edge of the blade 8. Air is blown in the axial direction shown by the arrow 31 of FIG. 2 by the left turn shown by the arrow 30 of FIG. 1 of an impeller. When the impeller 9 is installed under high wind resistance, such as a compartment of a refrigerator, as shown in FIG. 3, the airflow B having a large radial velocity component passing through the blade 8 is formed in the recess 8b. It is blocked and converted to the axial direction as shown in FIG. 4 and FIG. Therefore, the airflow speed in the axial direction discharged from the pressure surface 5 side increases.

6 shows the air flow C peeling off from the negative pressure surface 7 side. 7 shows the airflow D attached on the negative pressure surface 7 side. As shown in FIG. 7, by providing the convex portion 8a at the trailing edge of the blade 8 to partially lengthen the blade string length, the airflow D is attached near the trailing edge of the blade 8, Peeling of airflow is suppressed. Thereby, the disturbance which arises when the airflow D blown from the negative pressure surface 7 side and the airflow E discharged from the pressure surface 5 side can be suppressed, and the blowing performance of the impeller 9 By suppressing deterioration, an increase in blowing noise can be suppressed.

Fig. 8 shows a comparison of the static pressure-air volume (P-Q) characteristics of the impeller of this embodiment and a conventional impeller. The impeller of this embodiment prevents a decrease in the amount of air flow at high static pressure conditions as compared with the conventional impeller. It is also considered to extend the entire trailing edge of the blade 8 in order to suppress the separation of the airflow, in which case the weight of the entire impeller increases and the load to the motor also increases, which increases the input. However, if the convex part 8a is provided in a part of the trailing edge part of a blade like this invention, peeling of airflow can be suppressed without increasing the weight of an impeller and the load to a motor.

In addition, although the negative pressure surface 7 side is flat in FIG. 4, as shown in FIG. 5, in order to make the thickness of the blade 8 uniform, the negative pressure surface was matched with the recessed part 8b provided in the pressure surface 5 side. The same effect can be acquired even if the convex part 8d is provided in (7) side.

In addition, although the shape of the convex part 8a provided in the trailing edge part of the blade 8 in FIGS. 1-3 is substantially circular arc shape, the triangle shape shown in FIGS. 9-11, the triangle shape whose vertex is arc shape, 2 The same effect can be obtained also in the shape of a peak formed of two circular arcs.

FIG. 12: shows the dimension of the convex part 8a, and FIG. 13 shows the relationship of the position DM of the center of the convex part 8a, and static pressure P. As shown in FIG. The airflow velocity in the axial direction in which the DM is converted by the concave portion 8b between 0.5DZ and 0.9DZ is large, and the velocity of the airflow D adhering to the vicinity of the convex portion 8a is also large. Get Where DZ is the distance between the outer circumferential end of the hub 3 and the outer circumferential end of the blade 8. 14 shows the relationship between the length DT of the base of the convex portion 8a and the positive pressure P. As shown in FIG. If the DT is in the range from about 0.1DZ to about 0.9DZ, a large effect is obtained. 15 shows the relationship between the height H and the positive pressure P of the convex portion 8a. A large effect can be obtained when H is in a range from around 0.2DZ to around DZ. In addition, it is confirmed that the greatest effect can be obtained when DM is in the range of from about 0.7DZ to about 0.8DZ, in the range of DT from about 0.4DZ to about 0.8DZ, and when H is about 0.1 to about 0.35. In addition, when DM is in a different range, the same effect can be obtained by designing considering DT and H appropriately.

(Second embodiment)

Figure 16 shows an impeller of a second embodiment of the present invention. The same reference numerals are given to parts of the same configuration as the above-described embodiment, and description thereof is omitted.

In Fig. 16, one end of the concave portion 8b extends to the tip of the convex portion 8a. By this structure, the airflow F with a large radial velocity component passing through the impeller 9 is blocked by the recess 8b provided on the pressure surface 5 side, and converted into an axial airflow, so that the pressure surface 5 It is discharged from the side. The convex part 8a is provided in the trailing edge of the blade 8, and the blade chord length is partially extended, and peeling of the airflow D on the negative pressure surface 7 side is suppressed, and it blows from the negative pressure surface 7 side. The confluence which arises at the time of confluence at the time of confluence is suppressed by joining the airflow and the said axial airflow which become the same position. Thereby, deterioration of the blowing performance of the impeller 9 can be suppressed, and the increase of blowing noise can be suppressed.

(Third embodiment)

17 to 20 show the blower 16 of the third embodiment of the present invention. The same reference numerals are given to parts of the same configuration as the above-described embodiment, and description thereof is omitted.

17 and 18, the outer wall 12 of the blower 16 has two plate-shaped mouth rings that define the suction side and the discharge side of the blade 8, namely the first mouth ring 10 and the second mouth ring. It surrounds the outer periphery of (11). The swirl flow circulation space 14 between the first mouse ring 10 and the second mouse ring 11 has an opening 13 opposite the blade 8. The plurality of pillars 15a and 15b provided in the swirl flow circulation space 14 extend substantially in the radial direction of the blade 8 from the opening edges of the first and second mouth rings 10 and 11.

When the blower 16 is installed under conditions of high wind path resistance, such as in a compartment of a refrigerator, as shown in FIG. 18, a part of the airflow G having a large radial velocity component passing through the blade 8 is opened in the opening 13. Flows into the swirl flow circulation space (14).

As shown in FIG. 19, as it turns left from the pillar 15a of the blade 8 to the pillar 15b, the airflow H to the left side of the pillar 15a of the pillar 15a and the pillar 15b is carried out. Airflow I near the middle and airflow J to the right of the column 15b flow into the swirl flow circulation space 14 from the pressure face 5 side of the blade 8, respectively. The introduced airflows H, I, and J become swirl flows flowing in the circumferential direction of the blades 8 by the rotation of the blades 8 and flow in the swirl flow circulation space 14.

As shown in FIG. 20, the blade 8 continues to rotate to pass through the column 15b, but the air flows H, I, and J are blocked by the column 15b, and the flow direction is changed to negative pressure. It is discharged to the surface 7 side.

As described above, the air flows H, I, and J are discharged to the low pressure portion of the negative pressure surface 7 side of the blade 8 in the swirl flow circulation space 14, thereby flowing the air flow flowing along the negative pressure surface 7 side. In order to increase speed, the disturbance which arises when it merges with the discharge airflow from the pressure surface 5 can be suppressed, and also the deterioration of the blowing performance of an impeller can be suppressed, and the increase of blowing noise can be suppressed.

(Example 4)

21 shows a freezer 150 of a fourth embodiment of the present invention. The same reference numerals are given to parts of the same configuration as the above-described embodiment, and description thereof is omitted.

In FIG. 21, the freezer 150 includes a storage compartment 101. The air sucked from the storage compartment air intake port 102 by the blower 16 passes through the air path, heat exchanges in the evaporator 103, is discharged from the storage compartment air outlet port 104, and supplies cooled air to the storage compartment 101. The blower 16 is used in the passage for supplying cooling air to the storage compartment 101 in the refrigerator. In this embodiment they are respectively configured at the top and bottom.

In addition, the machine room 105 is composed of a compressor 106, an evaporating dish 107, and a condenser 108. The air sucked from the machine room air inlet 109 by the blower 16a passes through the air path, heat exchanges in the condenser 108, and is discharged from the machine room air outlet 110. The blower 16a is used in the passage for supplying air into the machine room 105 of the refrigerator.

By this structure, deterioration of the blowing performance of the blowers 16 and 16a can be suppressed on the conditions with high passage resistance like the refrigerator refrigerator 150. As shown in FIG.

Therefore, since the amount of air passing through the evaporator 103 increases, the efficiency of heat exchange becomes good, and the cooling ability as the freezer 150 is improved. In addition, since the amount of air passing through the condenser 108 and the compressor 106 increases, the compressor 106 can be cooled and heat exchange of the condenser 108 becomes efficient, so that the condensation capacity of the freezer 150 is increased. This is improved.

According to the present invention, when the air path resistance is high, an airflow having a large radial velocity component passes through the impeller. The airflow having a large radial velocity component is converted into the axial airflow by the airflow direction converting means and increases the axial airflow speed blown from the pressure surface side. This axial airflow flows in the vicinity of the airflow attachment means and suppresses the separation of the airflow on the negative pressure surface side, and acts to suppress the disturbance generated when the airflow on the negative pressure surface side and the airflow on the pressure surface side merge. Thereby, the impeller of this invention has the effect which suppresses deterioration of blowing performance, and the increase of blowing noise.

Claims (12)

In the impeller, A hub mounted to the motor, a plurality of blades provided around the hub, and airflow direction converting means for converting the airflow sucked by the blade provided on the pressure surface side of the blade in the axial direction, and provided at the trailing edge of the blade. And an airflow attachment means for attaching the peeling flows, wherein the airflow converted in the axial direction by the airflow direction converting means flows in the vicinity of the airflow attachment means. Impeller. The method of claim 1, The said airflow direction conversion means is comprised by the recessed part provided in the pressure surface side of a blade, The said airflow attachment means is comprised as the convex part provided in the trailing edge part of a blade, The one end of the said recessed part extends to the vicinity of the trailing edge part of a blade, It is characterized by the above-mentioned. By Impeller. The method of claim 2, One end of the concave portion extends to the tip of the convex portion. Impeller. In the blower, A hub mounted to the motor, a plurality of blades provided around the hub, and airflow direction converting means for converting the airflow sucked by the blade provided on the pressure surface side of the blade in the axial direction, and provided at the trailing edge of the blade. It has a airflow attachment means for attaching peeling flow, The airflow converted into the axial direction by the said airflow direction conversion means flows in the vicinity of an airflow attachment means, and the structure of an orifice surrounding the outer periphery of the said impeller is a suction side. Blades of the impeller between the first and second plate-shaped mouth rings partitioning the discharge side and the outer wall surrounding the outer circumference of the first and second plate-shaped mouth rings, and the first and second plate-shaped mouth rings. A swirl flow circulation space having an opening opposite the; And a plurality of pillars provided extending from the opening edges of the first and second plate-shaped mouth rings in a substantially radial direction of the impeller. air blower. The method of claim 4, wherein The airflow direction converting means provided in the impeller is constituted by a concave portion provided on the pressure surface side of the blade, and the airflow attachment means is configured as a convex portion provided in the trailing edge of the blade, and one end of the recess extends near the trailing edge of the blade. Characterized in that air blower. The method of claim 5, wherein One end of the concave portion of the air flow direction conversion means provided on the blade of the impeller extends to the tip of the convex portion. air blower. In the freezer, A hub mounted to the motor, a plurality of blades provided around the hub, and airflow direction converting means for converting the airflow sucked by the blade provided on the pressure surface side of the blade in the axial direction, and provided at the trailing edge of the blade. It has a airflow attachment means for attaching peeling flow, The airflow converted into the axial direction by the said airflow direction conversion means flows in the vicinity of an airflow attachment means, and the structure of an orifice surrounding the outer periphery of the said impeller is a suction side. Blades of the impeller between the first and second plate-shaped mouth rings partitioning the discharge side and the outer wall surrounding the outer circumference of the first and second plate-shaped mouth rings, and the first and second plate-shaped mouth rings. A swirl flow circulation space having an opening opposite the; And using a blower in the air passage for supplying cooling air to the storage compartment in the refrigerator, further comprising a plurality of pillars provided extending from the opening edges of the first and second plate-shaped mouth rings in a substantially radial direction of the impeller. Freezer The method of claim 7, wherein The airflow direction converting means provided in the impeller is constituted by a concave portion provided on the pressure surface side of the blade, and the airflow attachment means is configured as a convex portion provided in the trailing edge of the blade, and one end of the recess extends near the trailing edge of the blade. Characterized in that Freezer The method of claim 8, One end of the concave portion of the air flow direction conversion means provided on the blade of the impeller extends to the tip of the convex portion. Freezer In the freezer, A hub mounted to the motor, a plurality of blades provided around the hub, and airflow direction converting means for converting the airflow sucked by the blade provided on the pressure surface side of the blade in the axial direction, and provided at the trailing edge of the blade. It has a airflow attachment means for attaching peeling flow, The airflow converted into the axial direction by the said airflow direction conversion means flows in the vicinity of an airflow attachment means, and the structure of an orifice surrounding the outer periphery of the said impeller is a suction side. Blades of the impeller between the first and second plate-shaped mouth rings partitioning the discharge side and the outer wall surrounding the outer circumference of the first and second plate-shaped mouth rings, and the first and second plate-shaped mouth rings. A swirl flow circulation space having an opening opposite the; And using a blower in the air passage for supplying air into the machine room of the refrigerator, further comprising a plurality of pillars provided extending from the opening edges of the first and second plate-shaped mouth rings in a substantially radial direction of the impeller. Freezer The method of claim 10, The airflow direction converting means provided in the impeller is constituted by a concave portion provided on the pressure surface side of the blade, and the airflow attachment means is configured as a convex portion provided in the trailing edge of the blade, and one end of the recess extends near the trailing edge of the blade. Characterized in that Freezer. The method of claim 11, One end of the concave portion of the air flow direction conversion means provided on the blade of the impeller extends to the tip of the convex portion. Freezer

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