RU2353817C2 - Blades of fan and modifications - Google Patents

Abstract

FIELD: engines and pumps. ^ SUBSTANCE: group of inventions is related to end wing comprising vertical element and location piece. Location piece simplifies installation of end wing at the end of fan blade. Vertical element passes perpendicular relative to fan blade end. ^ EFFECT: improvement of fan blades aerodynamics, increased fan efficiency. ^ 5 cl, 10 dwg

Description

The present invention relates generally to fan blades and modifications to fan blades and, in particular, to a profile intended for use in a fan blade and an end wing intended for use with a fan blade.

People working in large structures, such as warehouses and manufacturing facilities, can be in working conditions ranging from uncomfortable to dangerous. The same applies to agricultural enterprises, for example, to a structure filled with livestock. On a hot day, the temperature of the internal air can reach a point at which a person or animal cannot maintain a healthy or desired body temperature. In areas where the temperature becomes uncomfortable or unsafe high, it may be necessary to use a device that creates or increases the flow of air within this area. Such air flow can partially contribute to lowering the temperature in the area.

In addition, as a result of some activities that are carried out in this environment, such as welding or the operation of internal combustion engines, airborne pollutants may be formed that may be harmful to the organisms exposed to them. The effect of airborne pollutants can be enhanced if the air flow in this area is less than ideal. In these and similar situations, it may be necessary to use a device that, during operation, creates or improves airflow in the area. Such an air flow can partially help to reduce the harmful effects of pollutants as a result of their dilution and / or disposal.

In some structures and environments, there may be a problem with the accumulation of heat, as well as with the fact that heat remains near the ceiling of the structure. This can be troubling when the area near the floor of the structure is relatively colder. Those skilled in the art will understand the inconvenience that may result from this or other unbalanced distribution of air / temperature. In these and similar situations, it is preferable to use a device that during operation creates or increases the flow of air within the area. Such an air flow can contribute to the partial elimination of delamination and can induce a more ideal air / temperature distribution.

It is also preferable to design a fan to reduce energy consumption. Reducing energy consumption can be achieved using an efficient fan (for example, less energy is required to drive a fan compared to other fans). The reduction in energy consumption can also be affected by the development of a fan that improves air distribution, resulting in lower costs associated with heating or cooling other devices.

The present invention is illustrated by drawings, in which preferred embodiments are presented. It will be appreciated that the present invention is not limited to the exact configurations presented. In the drawings, like reference numerals in several views denote the same elements. The drawings show:

figure 1 is a view in plan of the hub for installing the fan blades;

figure 2 is a cross section of a profile of a fan blade;

figure 3 is a cross section of a preferred embodiment of a profile of a fan blade;

4 is a graph depicting two ellipses;

5 is a plot of the graph of figure 4;

6 is a side view of a fan blade with an end wing;

Fig.7 is a cross section of the end wing of Fig.6;

Fig.8 is a top view of the end wing of Fig.6;

Fig.9 is an end view of the fan blades of Fig.2, modified with the end wing of Fig.6;

figure 10 is a perspective view with an exploded view of the details of the node end wing - the blade of figure 9.

The following describes the presently preferred embodiment of the invention, an example of which is illustrated in the accompanying drawings.

Let us consider in detail the drawings, in which the same reference numbers are used to denote the same elements in all views, while FIG. 1 shows an example of a fan hub 10 that can be used to produce a fan with fan blades 30 or 50. In the present example, the fan hub 10 comprises a plurality of hub mounting elements 12 on which fan blades 30 or 50 can be mounted. In one embodiment, the fan hub 10 is connected to a drive mechanism for rotating the fan hub 10 at a selectable or predetermined speed. The corresponding hub assembly may thus comprise a hub 10 and a drive mechanism coupled to the hub 10. The hub assembly may comprise various other elements, including another hub, and the fan hub 10 may be rotated by any suitable means. In addition, the hub 10 of the fan may have any corresponding element or elements 12 of the installation of the hub.

As shown in FIGS. 1-3, each hub mounting element 12 has an upper surface 14 and a lower surface 16 that end with a leading edge 18 and an end edge 20. In addition, an opening 22 is formed in each hub mounting element 12 extending from the upper surface 14 and to the bottom surface 16. In the present exemplary embodiment, the opening 22 is dimensioned so that a mount 26 can be installed in it. Each mounting element 12 of the hub is configured to install fan blades 30 or 50 on it. For specialists in the art it is obvious that the mounting elements 12 of the hub can be provided in various alternative configurations.

In one preferred embodiment, fan blades 30 or 50 are mounted on a hub assembly disclosed in US Pat. No. 6,244,821. It should be noted that the fan blades 30 or 50 can be mounted on any other hub and / or hub assembly. The corresponding hub assembly during operation can rotate the hub 10 at any desired angular velocity. Just as an example, such an angular velocity can be somewhere in the range from, mainly, 7 to 108 rpm.

Figure 2 shows a cross section of a fan blade 30 having a curved trailing edge 38 mounted on a hub 10. A cross section is made along a transverse plane located in the center of the fan blade 30 facing the hub 10. The fan blade 30 has an upper surface 32 and a lower a surface 34, each of which ends with a leading edge 36 and a trailing edge 38. As shown in the drawing, the trailing edge 38 has an inclination of substantially 45 ° with respect to the portion of the upper surface 32 that is closest to the rear s edge 38 and the bottom surface portion 34 which is the closest to the trailing edge 38. However, the trailing edge 38 may have any other suitable slope, such as 0 °, up to the case when it is a simple flat surface. Other suitable trailing edge configurations 38 are apparent to those skilled in the art.

In the illustrated embodiment, the fan blade 30 is substantially hollow. Many ribs or protrusions 40 are located inside the fan blade 30. As shown in the drawing, when the hub mounting member 12 is inserted into the fan blade 30, the ribs or protrusions 40 are set to come into contact with the upper surface 14, the bottom surface 16, the leading edge 18 and the trailing edge 20 of the hub mounting member 12. The protrusions 40 thus provide a sliding fit between the fan blade 30 and the hub mounting member 12. Alternative configurations for the fan blade 30, including, without limitation, affecting the relationship between the fan blade 30 and the hub mounting member 12, are apparent to those skilled in the art.

Terms used here, such as "chord", "chord length," "maximum thickness," "maximum bend," "angle of attack", etc., should be understood in the same meaning in which these terms are used for an airplane wing or other profile design. In one embodiment, the fan blade 30 has a chord length of generally 6.44 inches. The fan blade 30 has a maximum thickness of mainly 16.2% chord; and the maximum bulge, mainly 12.7% of the chord. The radius of the leading edge 36 is mainly 3.9% of the chord. The radius of the trailing edge 38 for a quarter of the bottom surface 34 is mainly 6.8% of the chord. In a preferred embodiment, the fan blade 30 has a chord of substantially 7 inches. In another embodiment, the fan blade 30 has a chord of generally 6.6875 inches. Any other appropriate sizes and / or proportions may be used.

By way of example only, the fan blade 30 can have an aerodynamic drag value in the range of, basically, 39.8, under conditions where the Reynolds number is basically 120,000, and basically 93.3 when the Reynolds number is mostly 250,000. However, other aerodynamic drag values can be obtained for the fan blades 30.

In one embodiment, the fan blade 30 has a drag coefficient in the range from mainly 0.027, under conditions where the Reynolds number is basically 75000 to basically 0.127 when the Reynolds number is basically 112,500 However, other drag values can be obtained for the fan blades 30.

For example, under conditions where the Reynolds number is basically 200,000, the fan blade 30 moves air so that there is a speed factor of mainly 1.6 on the bottom surface 34, on the trailing edge 38 of the fan blade 30. Other speed factor values may be obtained using the fan blade 30.

In one embodiment, the fan blade 30 provides aerodynamics without stalling the flow for angles of attack from basically -1 ° to 7 °, under conditions where the Reynolds number is basically 112,000; and angles of attack from mainly -2 ° to 10 ° when the Reynolds number is basically equal to 250,000. These values are given as an example.

Figure 3 shows a cross section of another preferred embodiment of a fan blade 50 having a generally elliptical upper surface 52 and lower surface 54, each of which ends at a leading edge 56 and a trailing edge 58 mounted on the hub 10. The cross section passes along the transverse plane located in the center of the fan blade 50, when viewed from the hub 10. In this embodiment, the fan blade 50 is hollow. A plurality of bulges 60 are located inside the fan blade 50. As shown in the drawing, when the hub mounting member 12 is inserted into the fan blade 50, the protrusions 60 are arranged so that they come into contact with the upper surface 14, the bottom surface 16, the leading edge 18 and the trailing edge 20 of the hub mounting member 12. The protrusions 60 thus provide a sliding fit between the fan blade 50 and the hub mounting member 12. Alternative configurations for the fan blade 50, including, but not limited to, configurations that affect the interdependence between the fan blade 50 and the hub mounting element 12, are obvious to those skilled in the art.

As shown, the fan blade 50 has a smaller radius of curvature in the direction of its leading edge 56, compared with a larger radius of curvature in the direction of its trailing edge 58. Such values of the curvature of the fan blade 50 can be obtained, at least in part, by generating two ellipses using the following formulas. For specialists in the art it is clear that the first ellipse, which was obtained at the intersection of the Cartesian axes x and y, can be generated using the following equations:

[1] x = a (COS (t)), and

[2] y = b (SIN (t)),

Where

a = length of the primary radius,

b = length of the secondary radius, and

t = angle of rotation of the radius around the origin (for example, in radians).

Accordingly, the first ellipse can be generated using the above equations. Similarly, the coordinate set for the first ellipse can be obtained using equations [1] and [2]. An example of the first ellipse 200 is illustrated in the graph presented in figure 4, where a = 3 and b = 2.

The coordinates for the second ellipse can be obtained using the following equations:

[3] x ₂ = x (COS (θ)) - y (SIN (θ)), and

[4] y ₂ = y (COS (θ)) - x (SIN (θ)),

Where

x ₂ = second x coordinate after turning the first ellipse counterclockwise by θ radian around the origin, and

y ₂ = second coordinate "y" after turning the first ellipse counterclockwise by θ radian around the origin.

Thus, the dimensions of the second ellipse depend on the dimensions of the first ellipse. An example of a second ellipse 300 is shown in the graph shown in FIG. 4, where θ = 0.525 radians. It should be noted that in the case when the first and second ellipses are drawn in accordance with equations [1] - [4], these two ellipses can intersect at four points (“intersection of ellipses”). 4 shows four intersections 400 of ellipses between the first ellipse 200 and the second ellipse 300.

The curvature of the upper surface 52 and the lower surface 54 can be based, at least in part, on the curvature of the first and second ellipses between two successive intersections of the ellipses. An example of such a segment of the first ellipse 200 and the second ellipse 300 is shown in FIG. 5, which shows the portion of the ellipses 200 and 300 between successive intersections of the ellipse 400. Accordingly, equations [1] - [4] can be used to generate surface coordinates, at least for a portion of the upper surface 52 and the lower surface 54 of the fan blade 50.

It should be noted that the ratio of the chord length to the thickness of the fan blade 50 can vary with the rotation θ with respect to two ellipses.

The sections of the fan blade 50 may deviate from the curvature of the first and second ellipses. By way of example only, and as shown in FIG. 3, the leading edge 56 may be modified and may have a generally circular surface. Other deviations will be apparent to those skilled in the art.

In one embodiment, a fan blade 50 is created using equations [1] to [4], where a = 3 units, b = 2 units, and θ = 0.525 radians. In this embodiment, the fan blade 50 is formed with a circular leading edge 56 having a diameter of 3.5% of the chord length. Such a curvature of the leading edge 56 tangentially corresponds to the upper surface 52 and the lower surface 54. Such a correspondence can be represented by comparing FIGS. 3 and 5. Of course, other sizes can be used.

In a preferred embodiment, the fan blade 50 has a chord length of substantially 7.67 inches. In another embodiment, the fan blade has a chord length of substantially 7.687 inches. However, the fan blade 50 may have any other suitable chord length.

In this embodiment, the radius of the leading edge 56 is generally 3.5% of the chord. The maximum thickness of the fan blade 50 is generally 14.2% chord. The maximum convexity of the fan blade 50 is generally 15.6% of the chord. However, any other appropriate sizes and / or proportions may be used.

For example, a fan having a diameter of 24 feet and containing ten blades 50 mounted at an angle of attack of 10 ° produces a traction force of mainly 5.2 pounds, rotating at a speed of mainly 7 revolutions per minute, moving approximately 87.302 cubic feet per minute. When rotated at a speed of basically 14 revolutions per minute, the fan generates a traction force of basically 10.52 pounds and moves 124,174 cubic feet per minute. When rotated at a speed of mainly 42 revolutions per minute, the fan generates a traction force of mainly 71.01 pounds and moves mainly 322613 cubic feet per minute. Other values of traction and / or volumes of transported air can be obtained using a fan having fan blades 50.

For example, a fan blade 50 having an angle of attack of substantially 10 ° can exhibit aerodynamic drag in the range of mainly 39, under conditions where the Reynolds number is basically 120,000 to basically 60. when the Reynolds number is basically 250,000. Other aerodynamic drag values can be obtained using the fan blade 50.

In one embodiment, the fan blade 50 provides aerodynamics without stalling the flow for angles of attack from basically 1 ° to 11 °, under conditions where the Reynolds number is basically 112,000; for angles of attack from about 0 ° to 13 ° when the Reynolds number is approximately 200,000; and for angles of attack from basically 1 ° to 13 °, when the Reynolds number is basically equal to 250,000. Of course, these values are examples.

A fan having a diameter of 14 feet and containing ten fan blades 50 rotates at a speed of substantially 25 revolutions per minute. This fan consumes approximately 54 watts and generates a torque of mainly 78.80 inch-pounds and a flow rate of basically 34169 cubic feet per minute. The fan thus has an efficiency of mainly 632.76 cubic feet per minute / watt.

In another example, a fan having a diameter of 14 feet and containing ten fan blades 50 rotates at a speed of approximately 37.5 revolutions per minute. This fan consumes mainly 82 watts and develops a torque of mainly 187.53 inch-pounds and a flow rate of basically 62,421 cubic feet per minute. This fan thus has an efficiency of mainly 761.23 cubic feet per minute / watt.

A fan having a diameter of 14 feet and containing ten fan blades 50 rotates at a speed of generally 50 revolutions per minute. This fan consumes basically 263 watts and develops a torque of mainly 376.59 inch-pounds and a speed of basically 96,816 cubic feet per minute. The fan thus has an efficiency of mainly 368.12 cubic feet per minute / watt.

The following can be applied to any fan blade, including, by way of example only, the fan blade (30) or the fan blade (50).

In one embodiment, each fan blade 30 or 50 is made of a uniform solid material. By way of example only, fan blades 30 and 50 may be made of extruded aluminum. However, it should be noted that the fan blades 30 and / or 50 can be made of any other suitable material or materials, including, without limitation, any metal and / or plastic. In addition, the fan blades 30 and / or 50 can be manufactured using any suitable manufacturing method, including, without limitation, stamping, bending, welding and / or molding. Other suitable materials and manufacturing methods will be apparent to those skilled in the art.

When the fan blade 30 or 50 is mounted on the hub 10, the hub mounting elements 12 extend into the fan blade 30 or 50, generally 6 inches, for example. Alternatively, the hub mounting elements 12 extend into the fan blade 30 or 50 to any appropriate length. It should be noted that the hub 10 may have mounting elements 12 that are installed outside the fan blades 30 or 50, and not from the inside. Alternatively, the hub mounting elements 12 can be installed both partially inside and partially outside of the fan blades 30 or 50.

The blade 30 or 50 of the fan may also contain one or more holes made with the possibility of alignment with the holes 22 in the mounting element 12 of the hub. In this embodiment, when the holes in the fan blades 30 or 50 are aligned with the holes 22 in the hub mounting member 12, a mount 26 can be installed through the holes to secure the fan blades 30 or 50 to the hub mounting member 12. In one embodiment, mount 26 is a bolt. Other suitable alternatives for fastening (s) 26 will be apparent to those skilled in the art, including but not limited to adhesives. Accordingly, it should be appreciated that openings 22 are optional.

A fan blade 30 or 50 may be approximately 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, or 14 feet long. Alternatively, the fan blade 30 or 50 may have any other suitable length. In one embodiment, the fan blade 30 or 50 and the hub 10 are sized such that the fan comprising the fan blades 30 or 50 and the hub 10 has a diameter of substantially 24 feet. In another preferred embodiment, the fan blade 30 or 50 and the hub 10 are sized such that the fan comprising the fan blades 30 or 50 and the hub 10 has a diameter of substantially 14 feet. Other appropriate sizes are apparent to those skilled in the art.

It should be noted that the cross section along the length of the fan blade 30 or 50 need not be identical. Those. the configuration of the fan blade 30 or 50 does not have to be uniform along the entire length of the fan blade 30 or 50. By way of example only, the “at the tip of the hub installation” portion of the fan blade 30 or 50 (that is, the tip of the fan blade 30 or 50 that is mounted on the hub 10) can be removed. For example, on the leading edge 56 of the fan blade 50, an oblique cut is made to install another blade 50 on the hub 10.

Alternatively, a fan blade 30 or 50 may be formed or may be configured such that a tip portion for mounting on a hub or other portion is removed, lightened, or may otherwise be "missing." It should be noted that due to the absence of such a section (regardless of whether it was removed or absent from the very beginning), problems associated with the fact that the blades 30 or 50 interfere with each other on the hub 10. Such mutual interference can be caused various factors, including, without limitation, the length of the chord of the blades 30 or 50 fans. Other factors, in addition to mutual interference, may affect the removal or other absence of a portion of the fan blade 30 or 50. The missing portion may include a leading edge 36 or 56, a trailing 38 or 58, or both.

Alternatively, to solve the problem of mutual interference between the fan blades 30 or 50 in the hub 10, the diameter of the hub can be increased (for example, without increasing the number of mounting elements 12 of the hub). Alternatively, the chord of the fan blades 30 or 50 can be reduced. However, other alternatives and variations of the hub 10 and / or the fan blades 30 or 50 will be apparent to those skilled in the art.

The fan blade 30 or 50 may have a zero or non-zero angle of attack. By way of example only, when the hub is mounted on the mounting member 12, the fan blade 30 or 50 may have an angle of attack in the range of from about -1 ° to about 7 °, inclusive; between -2 ° and 10 °, inclusive; or, mainly, 7 °, 8 °, 10 ° or 13 °, only as an example. However, the fan blade 30 or 50 may have any other appropriate angle of attack. The fan blade 30 or 50 can be substantially straight along its length, and the angle of attack can be set by using the hub mounting element 12 with the desired angle of attack.

Alternatively, the angle of attack of the mounting member 12 may be zero, and the angle of attack for the fan blade 30 or 50 may be set by turning the fan blade 30 or 50. Thus, the fan blade 30 or 50 can be made substantially straight along the length along which the blade mounting element 12 extends into the fan blade 30 or 50, and rotation can be provided to obtain an angle of attack in the rest of the fan blade 30 or 50 . Such a rotation can be performed at any appropriate length of the fan blade 30 or 50 (for example, the entire remaining length of the fan blade 30 or 50 has a “rotation”; or this rotation is made short, as a result of which almost the entire remaining part of the fan blade 30 or 50 essentially made direct; etc.). Other appropriate configurations and methods for setting the angle of attack for all or part of the fan blade 30 will be apparent to those skilled in the art. In addition, it should be noted that all or some sections of the fan blade 30 or 50 can have one or more turns for any purpose.

A blade for example a 30 or 50 fan can be modified using a variety of approaches. Such modifications may alter the performance of the fan. As shown by way of example in FIGS. 6-10, one such modification may include an end wing 70. Although the end wing 70 will be described in the context of the fan blades 30 and 50, it should be appreciated that the end wings 70 can be used with any other appropriate fan blades.

The end wing 70 according to this embodiment comprises a vertical element 72. The vertical element 72 has a flat inner surface 74 and a rounded outer surface 76. Other suitable configurations for the inner surface 74 and the outer surface 76 will be apparent to those skilled in the art. In this example, the perimeter of the vertical element 72 is defined by the lower edge 78, the upper edge 80 and the trailing edge 82. Each edge 78, 80 and 82 converges, in general, in a corresponding angle 84. Thus, in the present example, the vertical element 72 has three angles 84 As shown, each corner 84 is rounded. Accordingly, the term “angle,” as the term used here, should not be construed as a term requiring an acute angle. The angle does not have to be limited to the point or area in which a pair of straight lines meet or intersect. Although in the present example, the vertical element 72 is described as having three angles, it should be noted that the vertical element 72 may have any corresponding number of angles 84.

Other embodiments of the vertical member 72 are clear to those skilled in the art.

The end wing 70 in accordance with the present embodiment further comprises an end wing mounting element 90 that extends substantially perpendicularly from the inner surface 74 of the vertical element 72. As shown in the drawing, the end wing mounting element 90 is made similar to the mounting element 12 of the hub. The end wing mounting member 90 has an upper surface 92 and a lower surface 94, each of which ends at a front 96 and a trailing edge 98. In addition, each end wing mounting member 92 has holes 100 formed through the upper surface 92 and the lower surface 94. B In this example, each hole 100 is dimensioned to allow mounting 26 therein. Mounting element 90 of the end wing is configured to insert a fan 30 or 50 into one tip of the blade pa. For specialists in the art it is obvious that the mounting element 90 of the end wing can be made in various alternative configurations.

Figure 9 shows a cross-sectional view of a fan blade 30 with an end wing 70 mounted on it. The cross section extends along a transverse plane located in the center of the fan blade 30 when viewed in the direction of the end wing 70 (i.e., from the side of the hub 10). In this example, and as shown in FIGS. 9 and 10, the mounting element 90 of the end wing is designed so that it can be installed on the tip of the fan blade 30 or 50. As well as the mounting element 12 of the hub, the mounting element 90 of the end wing is mounted with sliding relative to the protrusions 40 or 60 in the blades 30 or 50 of the fan. In the present example, the upper edge 80 of the end wing 70 extends above the upper surface 32 or 52 of the fan blade 30 or 50 and extends beyond the front edge 36 or 56. Similarly, the lower edge 78 of the end wing 70 extends beyond the bottom surface 34 or 54 of the blade 30 or 50 fans. The trailing edge 82 of the end wing 70 extends beyond the trailing edge 38 or 58 of the fan blade 30 or 50. The end wings 70 and fan blades 30 or 50 may have any other relative sizes and / or configuration.

The fan blade 30 or 50 may comprise one or more holes formed near the tip of the fan blade 30 or 50 through the upper surface 32 or 52 and / or the lower surface 34 or 54, which / which are located so that they coincide with the hole (s) 100 in the end wing mounting element 90, when the end wing mounting element 90 is inserted into the fan blade 30 or 50, and the dimensions of which are selected so that it can be fitted with a mount 26. The end wings 70 can thus be closed are replicated on the fan blades 30 or 50 by means of one or more fasteners 26. In one embodiment, the fastener 26 is a bolt. In another embodiment, fastener 26 comprises a complementary pair of slender head locking screws, such as screw racks, sometimes used to connect a large number of sheets of paper to each other (for example, a “male” screw with a threaded outer surface so that it matches “threaded” screw with threaded inner surface). However, any other suitable fastener (s) may be used, including but not limited to adhesives. In accordance with this, it should be noted that the holes 100 are used if necessary.

It should also be noted that the mounting element 90 of the end wing does not have to be inserted from the end side of the fan blade 30 or 50. Thus, similarly to the mounting elements 12 of the hub, the mounting element 90 of the end wing can be made so that it can be installed on the outside of the fan blades 30 or 50, and not from the inside. Alternatively, the end wing mounting elements 90 can be installed simultaneously partially partially inside and partially outside the fan blades 30 or 50. However, other configurations will be apparent to those skilled in the art.

In an alternative embodiment, there is no mounting element 90 in the end wing 70, and instead it is formed with a recess formed on the inner surface 74 of the vertical element 72. In this embodiment, the tip of the fan blade 30 or 50 is inserted into the end wing 70 to secure the end wing 70 on the blades 30 or 50 of the fan. In yet another embodiment, the fan blade 30 or 50 is formed as a unit with the end wing 70. Accordingly, it will be apparent to those skilled in the art that there are many configurations that include the fan blade 30 or 50 with the end wing 70.

While the vertical element 72 is shown as being substantially perpendicular to the mounting element 90, it should be appreciated that the two elements can be positioned at any suitable angle with respect to each other. Thus, and by way of example only, the vertical member 72 can be tilted inward or outward by attaching the end wing 70 to the fan blades 30 or 50. Alternatively, the vertical member 72 may comprise more than one corner. Thus, the vertical member 72 may be configured such that each of the upper portion of the vertical member and the lower portion of the vertical member are inclined inward when the end wing is attached to the fan blade 30 or 50. Other end wing options 70, including, without limitation, angled options, will be apparent to those skilled in the art.

Although the end wing 70 has been specifically described as a modification of the fan blades 30 or 50, it should be noted that the end wing 70 can be used to modify any other fan blades.

In one embodiment, the end wing 70 is formed of a uniform, continuous molded plastic material. However, it should be noted that the end wing 70 can be made of a wide variety of materials, including, without limitation, any suitable metal and / or plastic, and may contain many parts. In addition, the end wing can be manufactured using any suitable manufacturing method.

The rear vortices, which are formed at or near the ends of the fan blades 30 or 50, can increase the lifting force near the ends of the fan blades 30 or 50. The end wings 70 may impede the radial flow of air above the upper surface 32 or 52 and / or the lower surface 34 or 54 near the ends of the fan blades 30 or 50. Such a delay can cause air to flow more normally from the leading edge 36 or 56 to the trailing edge 38 or 58, thereby improving the efficiency of a fan having fan blades 30 or 50 with end wings 70 at least at some rotational speeds.

In one embodiment, the end wings 70 are attached to the ends of the blades 30 or 50 on a fan having a diameter of 6 feet. Thanks to the addition of end wings 70, the air flow rate in the fan increases by 4.8% at 171 revolutions per minute.

In another embodiment, the end wings 70 are attached to the ends of the blades 30 or 50 on a fan having a diameter of 14 feet. Thanks to the addition of end wings 70, the air flow rate in the fan increases by 4.4% at 75 rpm.

The two tables below illustrate the efficiency that can be achieved by adding end wings 70 to a fan having a diameter of 14 feet:

Table 1 Fan without end wings 70 Speed (rpm) Maximum power (watts) Average power (watts) Torque (inch-pounds of force) Flow rate (cubic feet per minute) Efficiency (cubic feet per minute) / watt) 12.5 54 fifty 17.86 0 0 25 66 54 78.80 34,169 632.76 37.5 125 82 187.53 62,421 761.23 fifty 339 263 376.59 96,816 368.12 62.5 700 660 564.01 110,784 167.85 75 1170 1140 839.75 129,983 114.02

table 2 End Fan 70 Speed (rpm) Maximum power (watts) Average power (watts) Torque (inch-pounds of force) Flow rate (cubic feet per minute) Efficiency (cubic feet per minute) / watt) 12.5 fifty 42 18.56 26,815 638.45 25 58 43 18.39 46,547 1082.49 37.5 68 49 186.00 61,661 1258.39 fifty 241 198 354.61 87,552 442.18 62.5 591 528 582.78 120,859 228.90 75 980 950 847.41 136,560 143.75

Of course, other values may be realized using end wings 70. In addition, acceptable wing options, including, without limitation, alternative wing configurations, will be apparent to those skilled in the art.

In conclusion, it should be noted that the various advantages that have been obtained as a result of introducing the concepts of the invention have been described above. The above description of one or more embodiments of the invention has been presented for purposes of illustration and description. It is assumed that it is not exhaustive or does not limit the invention to the exact form disclosed. Obvious modifications or variations are possible given the above description. One or more embodiments have been selected and described to best illustrate the principles of the invention and its practical application, so as to enable those skilled in the art to make the best use of the invention in various embodiments and with various modifications that correspond to the particular ones considered. use cases. The scope of the invention is intended to be determined by the appended claims.

Claims (25)

1. The end wing for the fan blade, comprising a vertical element and a mounting element, in which at least a portion of the mounting element is located essentially perpendicular to at least a portion of the vertical element, and the mounting element is made to be installed on the first the tip of the fan blade, and the fan blade is configured to be mounted on the hub of the fan, on the second tip of the fan blade, the second tip being opposite the first ok numbness. 2. The end wing according to claim 1, in which the vertical element is made with a rounded outer surface. 3. The end wing according to claim 2, in which the vertical element is made with a substantially flat inner surface. 4. The end wing according to claim 1, in which the perimeter of the vertical element is defined by the lower edge, upper edge and trailing edge. 5. The end wing according to claim 4, in which each of the edges converges, in General, in the corresponding angle. 6. The end wing according to claim 5, in which each of the corners is made mainly rounded. 7. The end wing according to claim 1, in which at least a portion of the mounting element is configured to be installed inside the first tip of the fan blade. 8. The end wing according to claim 1, in which the vertical element is configured to restrain the radial air flow over at least a portion of the fan blade located near the first end of the fan blade. 9. The end wing according to claim 1, in which the mounting element has an inner surface in which at least a portion is not perpendicular to the mounting element. 10. The end wing according to claim 1, in which the mounting element is made with the possibility of essentially fixing on the first end of the fan blades, at least one mount. 11. The end wing according to claim 1, in which the vertical element has a top edge, and the mounting element has a leading edge, and when installing at the first end of the fan blade, which has a leading edge, the distance from the leading edge of the mounting element to a point on the upper edge of the vertical the element is greater than the distance from the leading edge of the mounting element to the leading edge of the fan blade at the first end. 12. The end wing according to claim 1, in which the vertical element has a trailing edge, and the mounting element has a trailing edge, and when installing at the first end of the fan blade having a trailing edge, the distance from the trailing edge of the mounting element to a point on the trailing edge of the vertical element greater than the distance from the trailing edge of the mounting element to the trailing edge of the fan blade at the first end. 13. The end wing according to claim 1, in which the vertical element has a lower edge, and the mounting element has a lower surface, and when installing on the first end of the fan blade having a lower surface, the distance from the lower surface of the mounting element to a point on the lower edge of the vertical element more than the distance from the bottom surface of the mounting element to any point on the bottom surface of the fan blade, at the first end of the fan blade. 14. The end wing according to claim 1, in which the vertical element has a top edge, and the mounting element has a top surface, and when installing on the first end of the fan blade having a top surface, the distance from the upper surface of the mounting element to a point on the upper edge of the vertical element more than the distance from the upper part of the mounting surface of the element to any point on the upper surface of the fan blade, at the first end of the fan blade. 15. A kit for modifying a fan blade, comprising a vertical element, as well as a mounting element, in which the mounting element is located essentially perpendicular to at least a portion of the vertical element, and the mounting element is configured to be installed on the first end of the fan blade, and the fan blade is configured to be mounted on the fan hub, on the second end of the fan blade, the second end being opposite the first end, and also e at least one mount made with the possibility of fixing the mounting element on the first end. 16. A fan comprising a hub configured to rotate during operation, as well as a plurality of fan blades, each fan blade having a first end and a second end, in which each fan blade is mounted on the hub, at a corresponding first end; and an end wing mounted on the second end of each fan blade. 17. The fan according to clause 16, in which each end wing contains a vertical element and a mounting element. 18. The fan of claim 17, wherein the mounting member extends substantially perpendicular to the vertical member. 19. The fan of claim 17, wherein at least a portion of each mounting element is configured to install a corresponding fan blade in the second extremity. 20. The fan of claim 16, wherein the distance between the first extremity and the second extremity of each fan blade is at least substantially 4 feet. 21. A method of manufacturing a fan blade, in which the end wing is fixed at the tip of the fan blade, said wing comprising a vertical element and a mounting element, wherein at least a portion of the mounting element is arranged substantially perpendicularly to at least a portion of the vertical element in which the mounting element is made with the possibility of connection with the tip of the fan blade. 22. A fan blade configured to be mounted on a rotating fan hub, comprising an upper surface having substantially elliptical curvature, a lower surface having substantially elliptical curvature, and a leading edge, each of which has an upper surface and a lower surface ends at the leading edge and trailing edge, with each of the upper surface and lower surface ending at the trailing edge. 23. The fan blade according to item 22, in which the first radius of curvature is made near the front edge, and the second radius of curvature is near the trailing edge, and the first radius of curvature is less than the second radius of curvature. 24. The fan blade according to item 22, in which the curvature of the upper surface is formed on the first ellipse, and the curvature of the lower surface is formed on the second ellipse. 25. The fan blade according to paragraph 24, in which the curvature of the second ellipse is made dependent on the curvature of the second ellipse.

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