KR101673951B1 - Separable impeller for turbo blower - Google Patents

Abstract

The present invention relates to a turbo blower detachable type impeller, and it is an object of the present invention to provide a turbine blower detachable type impeller in which the hub and the blades constituting the impeller are separated and assembled from each other, and the blades coupled to the hub have various sizes and shapes So that it is possible to easily change and adjust the air volume and the like of the turbo blower.

Description

[0001] The present invention relates to a separable impeller for a turbo blower,

The present invention relates to a turbo blower detachable impeller.

An impeller is a component used when mixing fluids, and generally comprises a hub, which is connected to a rotary shaft and rotates together with a rotary shaft, and a plurality of blades provided on the hub. The shape of the blade, the angle at which the blade is attached to the hub, and the shape of the blade are classified into a row shape, a propeller shape, a screw shape, and a turbine shape.

On the other hand, a blower refers to a machine for delivering gas through a desired flow path such as a duct or a pipe by applying pressure to the gas. Among them, the turbo blower is a centrifugal blower that uses a centrifugal force of a gas generated by rotation of the impeller, . These turbo blowers have many advantages such as low noise, high efficiency, high strength, high speed rotation, simple structure, and low failure, and are widely used in various fields such as forced ventilation of boilers and gas pressure feeding.

Such a turbo blower is advantageous in that it has a simple structure and less trouble, as described above, and is known to be a drawback that the air volume is changed by the resistance. However, unlike in the past, there is an increasing number of systems that measure various conditions such as air flow and use them for control. Therefore, various studies and researches have been carried out on the system itself or the impeller structure or shape, Therefore, the present invention can overcome the shortcomings of the past by being capable of maintaining a certain amount of airflow that meets the desired design conditions. Meanwhile, since the blower performance such as the airflow blown by the turbo blower can be appropriately controlled, the design of the size and shape of the impeller for achieving the desired performance has become more complicated and subdivided. Accordingly, the design conditions such as the overall shape, the impeller diameter, and the number of blades can be determined to some extent in accordance with the environmental conditions of the impeller used for certain desired environmental conditions.

However, as the design of the impeller becomes more sophisticated, there is a new problem that the impeller must always be produced in accordance with the desired conditions in the actual field. Particularly, in the case of an impeller in which the hub and the blade are integrally formed, since the shape of the impeller is considerably complicated, it is difficult to produce the impeller with a simple process, and the post processing is required even after the impeller is manufactured. In addition, if a small quantity of the impeller is produced in a small quantity according to a specific design order as described above, a problem that the complicated process must be performed for each product greatly increases the production cost and becomes economically disadvantageous have.

In addition, in the case of an impeller in which the hub and the blade are integrally formed as described above, it is impossible to change the structure after once manufactured. Therefore, even if a small damage such as a broken blade occurs, the entire impeller must be replaced, resulting in an additional economic burden.

In order to overcome various problems as described above, there has been disclosed a technique in which a plurality of impellers are assembled into a single shape, rather than a hub and a blade separated type, or the impeller itself is formed as a single body.

In Korean Utility Model Laid-Open Publication No. 1999-0030121 (hereinafter referred to as "separate type impeller ", hereinafter referred to as Prior Art 1), only the wings constituting the impeller are separated and only the damaged wings are replaced when the wings are worn, partially worn, Disclosed is an impeller technique for a seawater pump that reduces cost. 1 (A) is a representative drawing of the prior art 1. As shown in the prior art 1, the hub has a cylindrical shape, a plurality of linear slits are radially formed on the side of the hub, and a plate- And is fitted into the slit. However, in the case of Prior Art 1, the basic impeller shape is the simplest form, and it is difficult to apply the impeller to a complex shape impeller such as a hub having a conical shape and a blade having a curved shape. More specifically, in the case of Prior Art 1, since the hub has a cylindrical shape, the blade can be fixed by closing the upper and lower surfaces after inserting the blade. However, in the case of the conical hub, such a structure can not be applied, New design should be done. In the case of Prior Art 1, since the blade is a flat plate, it can be inserted into a straight slit by a simple sliding. However, the blade may be formed into a curved surface having a very large curvature or inflection point, In the case of a complex shape, it is difficult to design the slit shape or the assembly process.

Japanese Unexamined Patent Publication No. 2013-213441 ("Impeller and its Production Method ", hereinafter referred to as Prior Art 2) discloses an impeller in which a hub is coupled to a hub. Fig. 1B shows a representative view thereof. The impeller of the prior art 2 is formed by combining the blades having complex curved surfaces in the conical hub (base portion), so that it is difficult to make the impeller capable of being assembled by simple application of the structure of the prior art 1. In the prior art 2, unlike the assembly method of the prior art 1, the blade assemblies in which the blades are combined are fixedly coupled to the base portion, and the blades are fixed by engaging the protrusions at the end portions of the blades and the grooves formed at the base portion (Totally different from the prior art 1) structure. However, as shown in Fig. 1 (B), it can be easily deduced that the fixing force of the fixing structure of the prior art 2 is not so strong. In addition, since the blade coupling and the base are adapted to be coupled with each other, it is necessary to replace the entire blade assembly when the individual blades are damaged.

Japanese Laid-Open Patent Application No. 2013-213442 ("Impeller and its Manufacturing Method ", hereinafter referred to as Prior Art 3) discloses a technique in which an impeller having a complicated shape is assembled. In the prior art 3, in order to solve problems of difficulty in fabrication (such as described above) occurring in such a complicated shape impeller, a problem of replacing the entire part when some damage occurs, and the like, Discloses a structure in which a divided piece unit is formed by combining a part of a hub and a blade, and these units are radially arranged and joined to form an impeller. In this case, even if a blade breaks, only the corresponding divided piece unit can be replaced, so that the above-described problems can be solved. However, in the case of the impeller of Prior Art 3, there is only one shape that can be formed by joining the divided piece units. As described above, there is still a problem of economic inefficiency in the problem of producing and changing various air flow conditions .

1. Korean Utility Model Publication No. 1999-0030121 ("Separate Impeller") 2. Japanese Patent Laid-Open Publication No. 2013-213441 ("Impeller and its manufacturing method") 3. Japanese Patent Laid-Open Publication No. 2013-213442 ("Impeller and its manufacturing method")

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide an impeller having a hub and a blade that can be separated and assembled from each other, The present invention provides a turbo blower detachable type impeller that allows the blades to have various sizes and shapes so that the air volume and the like can be easily changed and adjusted.

In order to achieve the above object, the present invention provides a turbo blower detachable type impeller having a conical shape including a circular upper surface 111 and a circular lower surface 112 having a larger area than the upper surface 111, (110) having a plurality of recesses (114) formed in a groove shape extending from the lower surface (111) to the lower surface (112) and being formed radially in the side surface (113); A blade wind pressure surface 121 formed to have a predetermined curved surface shape and converting the kinetic energy of wind into mechanical energy and a blade wind pressure surface 121 formed along one side end of the blade wind pressure surface 121 and corresponding to the cross- A plurality of blades 120 including a blade engaging portion 122 having a cross-sectional shape that is a cross-sectional shape; And an auxiliary blade wind pressure surface (131) having an area smaller than the blade wind pressure surface (121), and an auxiliary blade wind pressure surface (131) which is formed in a curved shape of a predetermined shape to convert kinetic energy of wind into mechanical energy, And a plurality of auxiliary blades (130) formed along the cross-sectional shape of the insert portion (114) and having an auxiliary blade engagement portion (132) having a cross-sectional shape corresponding to the cross-sectional shape of the insert portion (114). And the blade 120 and the auxiliary blade 130 are fitted to the hub 110 by fitting the blade engaging portion 122 or the auxiliary blade engaging portion 132 into the fitting portion 114, 130 may be combined.

At this time, the blade catching portion 122 or the auxiliary blade catching portion 132 may have a shape in which the cross-sectional shape becomes wider toward the end.

The impeller 100 further includes a fixing groove 141 formed in a shape of a recessed groove on the fitting portion 114 and a fixing groove 141 formed in the fixing groove 141 of the blade fixing portion 122 or the auxiliary blade fixing portion 132 And the coupling groove 142 is formed at a position corresponding to the coupling groove 142. The coupling groove 142 is formed in the space formed by the coupling groove 142, A fixing part 140 including a fixing pin 143 movable toward the groove 142; As shown in FIG. The fixing unit 140 may further include elastic means 144 having both ends connected to the fixing groove 141 and the fixing pin 143, respectively.

The fixing portion 140 may be disposed closer to the upper surface 111 than the lower surface 112. In addition, the side surface 113 may be formed so that the inclination degree decreases from the upper surface 111 to the lower surface 112.

In addition, the impeller 100 may be formed by alternately arranging the blade 120 and the auxiliary blade 130.

In addition, the hub 110 may have a cavity 115 therein.

According to the present invention, the hub and the blades constituting the impeller can be separated and assembled to each other. Therefore, even if a part of the blades is damaged, only the damaged blades can be replaced without replacing the entire impeller, There is a great economic effect that can save a lot of the operation cost into the back.

In addition, the impeller of the present invention has the following great advantages in manufacturing. When manufacturing an impeller in which the hub and the blade are integrally formed, a casting is made to form a casting, and then a final shape is finely processed through a post-processing, or a process of cutting a single mass of material into a desired shape is used. The impeller of the present invention is an impeller used in a turbo blower and comprises a conical hub and a plurality of blades having a complex curved surface. When such a complicated impeller is made into the process as described above, difficulty in process design and realization Lt; / RTI > However, since the impeller of the present invention basically has a hub having a conical shape and the respective blades are separately manufactured, the process design and realization difficulty in making each component are greatly lowered. In other words, it is possible to enhance productivity and economical efficiency because of the effect of enhancing the easiness of fabrication and the possibility of occurrence of defects during manufacturing to be much lowered. In addition, in the case of such a manufacturing method, a considerable amount of material is wasted by being cut off during the manufacturing process. However, in the present invention, the waste of such material can be much reduced, and the economic effect is further improved.

Above all, the present invention has a great effect in that the blades coupled to the hub have various sizes and shapes, so that the air volume and the like can be easily changed and adjusted. In the case of a product with a complex shape such as an impeller in actual production sites, resources such as manpower, time, and cost are wasted in operations such as changing the shape and changing the process in accordance with changing requirements, . However, the impeller of the present invention is not made by assembling only the same blades to the hub, but it is possible to easily manufacture the blades and the auxiliary blades alternately. Accordingly, even if the requirements according to the impeller performance (air flow rate, etc.) are changed, it is possible to easily meet the requirements by assembling the appropriate blades and the auxiliary blades according to the requirements, It is possible to dramatically reduce the resources used in the design compared with the conventional one.

Figure 1 is an illustration of a conventional detachable impeller.
2 is a perspective view of one embodiment of a turbo blower detachable impeller of the present invention.
3 is a top view of an embodiment of a turbo blower detachable impeller of the present invention.
4 is a cross-sectional view of one embodiment of a turbo blower detachable impeller of the present invention.
5 is a process of assembling the turbo blower detachable impeller of the present invention.
6 is a perspective view of a turbo blower detachment type impeller according to another embodiment of the present invention;

Hereinafter, a turbo blower detachable impeller according to the present invention will be described in detail with reference to the accompanying drawings.

2 to 5 show an embodiment of the turbo blower detachable impeller of the present invention, wherein FIG. 2 is a perspective view, FIG. 3 is a top view, and FIG. 4 is a sectional view. 5 shows a process of assembling the turbo blower detachable impeller of the present invention, and FIG. 6 shows various embodiments of the fitting portion, the engaging portion and the fixing portion of the turbo blower detachable impeller of the present invention. As shown in the drawing, the turbo blower detachable impeller 100 of the present invention basically includes a hub 110, a blade 120, and an auxiliary blade 130, and additionally, And may further comprise a fixing portion 140. Hereinafter, each part will be described in more detail.

The hub 110 is formed in a conical shape including a circular upper face 111 and a circular lower face 112 having an area wider than the upper face 111. [ The side surface 113 is formed so as to smoothly connect the upper surface 111 having a relatively narrow area and the lower surface 112 having a relatively large area. At this time, the impeller used in the turbo blower generally has various theories and experiences, and as shown in the drawing, the inclination of the side surface 113 is smaller as it goes from the upper surface 111 to the lower surface 112 And it is preferable that the hub 110 of the present invention is applied to such a shape. The hub 110 may also be designed to eliminate unnecessary weight gain by having cavities 115 formed therein as shown in the cross-sectional view of FIG.

In the impeller 100 of the present invention, the hub 110 has a plurality of recesses 114 formed in a groove shape extending from the upper surface 111 to the lower surface 112, . 3, the fitting portion 114 has a curved shape corresponding to one end of the blade 120 or the auxiliary blade 130, as can be seen clearly from the top view of FIG.

The blade 120 includes a wind pressure surface 121 for receiving wind and a blade catching part 122 fitted to the fitting part 114 to be fixed to the hub 110. More specifically, the wind pressure surface 121 is formed in a predetermined curved shape to convert the kinetic energy of wind into mechanical energy. FIGS. 2 to 5 show an embodiment of the shape of the blade 120, which is only illustratively shown to correspond to the shape of a blade of a generally used turbo blower. In other words, Of course not limited. The blade catching portion 122 is formed on one end of the blade wind pressure surface 121 and is fitted to the fitting portion 114 formed on the hub 110. The fitting portion 114 Sectional shape corresponding to the cross-sectional shape of the fitting portion 114 so as to be smoothly fitted and fixed to the fitting portion 114. [ (A specific example of the shape of the blade engagement portion 122 will be described later in detail)

The configuration of the auxiliary blade 130 is substantially the same as the configuration of the blade 120 except that the auxiliary blade wind pressure surface 131 of the auxiliary blade 130 has a smaller area than the blade wind pressure surface 121 But it is different.

The impeller 100 of the present invention is basically composed of the hub 110, the blade 120 and the auxiliary blade 130 as described above, The coupling between the hub 110 and the blade 120 and the auxiliary blade 130 can be achieved by fitting the blade coupling part 122 or the auxiliary blade coupling part 132 into the hub 110. [ As described above, since the sectional shape of the blade catching portion 122 or the auxiliary blade catching portion 132 corresponds to the sectional shape of the fitting portion 114, The coupling can be done well. In the present invention, the hub 110 is formed in a conical shape and the shape of the fitting portion 114 (i.e., the shape of the hub 110, the shape of the coupling between the blade 120 and the auxiliary blades 130) The centrifugal force acting on the joint portion is completely different from the direction of the centrifugal force so that the product safety can be inspected sufficiently. .

Here, the auxiliary blade 130 is used to control the air volume, wind pressure, wind speed, etc. generated by the impeller 100, which is finally manufactured. Specifically, it is as follows. The blades 120 are formed on the other hub 110 such that only one of the blades 120 having the same area of the wind pressure surface is coupled to one hub 110, And the auxiliary blades 130 are appropriately mixed and joined together to constitute an impeller. At this time, the total area of the wind pressure of the impeller of the former and the total area of the wind pressure of the latter impulse are different from each other, and thus, the generated air volume and the like in the former impeller and the latter impeller are different.

As described above, there has been an inconvenience in designing and manufacturing an impeller suitable for the turbo blower manufacturer whenever the impeller air condition conditions desired by the customer are changed. However, in the case of the present invention, the generated air volume of the impeller can be adjusted by appropriately mixing the blades and the auxiliary blades as described above. In other words, conventionally, when the impeller air condition conditions desired by the customer are changed, waste of resources such as time, manpower, and cost is very large in the process of designing a new impeller and performing a new process in accordance therewith. However, according to the present invention, It is possible to easily change the air flow rate and the like by appropriately adjusting the blending degree of the blades, thereby greatly reducing the waste of resources as described above. In the embodiment of FIGS. 2 to 4, the blade 120 and the auxiliary blade 130 are alternately arranged. However, the present invention is not limited thereto. For example, one auxiliary blade across two blades or one auxiliary blade across three blades), the degree of blending can be changed as desired to suit user needs.

However, in the case of the impeller according to the present invention, the hub 110, the blade 120, and the blade 120, which are conventionally manufactured, are required to be discarded when the requirements of the customer are changed as described above. And the auxiliary blade 130 can be always recycled, the problem of inventory processing and the like are also essentially excluded. In addition, since the manufacturing process is free from the problem of the stock process, it is possible to design the process in consideration of mass production in producing the products such as the hub 110, the blade 120, the auxiliary blade 130, As is generally well known, the production cost per unit of product tends to be reduced in mass production compared to small quantity production, and it is of course economically advantageous in this respect as well.

The fitting portion 114 in which the blade 120 is inserted and the fitting portion 114 in which the auxiliary blade 130 are fitted may have different shapes. However, in this case, the position where the blade 120 is inserted and the position where the auxiliary blade 130 is fitted are fixed, so that the degree of freedom in changing the air volume is reduced, It is preferable that the blade catching portion 122 and the auxiliary blade catching portion 132 have the same shape.

In addition, although it has been described above that the blade 120 and the auxiliary blade 130 (of a smaller area than the blade) are of two types, the blades 120 and the auxiliary blades 130 themselves may be produced in various types , It is natural that the degree of freedom for design change can be further improved.

Hereinafter, a structure for fixing the blade 120 or the auxiliary blade 130 to the hub 110 will be described in detail.

The impeller for the turbo blower rotates at a fairly high speed in most cases, so if the blades are not firmly secured to the hub, the risk of product damage and human accidents increases. Therefore, if the blade and the hub are separated, the joint structure must have a firm fixing force.

6 (A), 6 (B) and 6 (C), the blade engagement portion 122 or the auxiliary blade engagement portion 132 has a width So as to be widened. By doing so, even if the blade 120 or the auxiliary blade 130 receives a force to outward due to a centrifugal force, the blade engagement portion 122 or the auxiliary blade engagement portion 132, which is relatively wide, The end of the auxiliary blade 130 is caught by the entrance of the fitting portion 114 having a relatively narrow width to prevent the blade 120 or the auxiliary blade 130 from being separated from the hub 110. 6 (A), 6 (B) and 6 (C) are cross-sectional views taken along the AA 'direction shown in the sectional view of FIG. 4 and show various exemplary examples of the engaging portions 122 and 132 and the fitting portion 114 . 6A may be a simple cross-sectional shape in which the end is protruded, a trapezoidal shape as shown in FIG. 6B, or the like as shown in FIG. 6B, as long as the width of the engaging portions 122, And a more complicated shape in which an end portion is protruded as shown in Fig. 6 (C), and an auxiliary protrusion is further formed in the other direction, as shown in Fig. 6 (C). FIG. 6D is an enlarged view of the S portion in the sectional view of FIG.

In addition, the impeller 100 of the present invention includes the fixing portion 140 as shown in the sectional view of FIG. 4 and the embodiment of FIG. 6, so that the fixing force can be further enhanced. The fixing portion 140 basically includes a fixing groove 141, a coupling groove 142, and a fixing pin 143 as shown in FIG.

The fixing groove 141 is formed in the shape of a recessed groove on the fitting portion 114 and the fitting groove 142 is formed in the blade fixing portion 122 or the fixing groove 132 of the auxiliary blade fixing portion 132. [ (Not shown). Therefore, when the blade 120 or the auxiliary blade 130 is coupled to the hub 110, the space formed by the fixing groove 141 and the space formed by the coupling groove 142 are communicated with each other, .

The fixing pin 143 is provided in the space defined by the fixing groove 141 and the coupling groove 142 as described above. The fixing pin 143 is movably provided in the space formed by the fixing groove 141 and the coupling groove 142 so that the coupling groove 142 is formed by the centrifugal force when the impeller 100 rotates, . As the fixing pin 143 moves toward the coupling groove 142, the fixing pin 143 applies a pressing force to the coupling groove 142. As a result, 122 or the outer side surface of the auxiliary blade catching part 132 is pressed against the inner side surface of the fitting part 114 more strongly. Accordingly, as the impeller 100 rotates at a high speed, the engaging portions 122 and 132 and the fitting portion 114 are more firmly engaged with each other.

In addition, the fixing portion 140 may further include elastic means 144 having both ends connected to the fixing groove 141 and the fixing pin 143, respectively. The elastic means 144 prevents the fixing pin 143 from escaping from the fixing groove 141 in a state before the blade 120 or the auxiliary blade 130 is coupled to the hub 110 Can play a role. In addition, when the blade 120 or the auxiliary blade 130 is coupled to the hub 110, the elastic means 144 is compressed so that the restoring force of the elastic means 144 acts in the same direction as the centrifugal force The coupling force between the hub 110 and the blade 120 or the auxiliary blade 130 can be further increased.

It is general that the shape of the side surface 113 of the hub 110 is formed so as to have a smaller inclination from the upper surface 111 to the lower surface 112 as described above. In this case, it is preferable that the fixing portion 140 is disposed at a position closer to the upper surface 111 than the lower surface 112, as in the example shown in the sectional view of FIG. As a result, the direction of action of the centrifugal force and the direction of the fixed engagement force are shifted as much as possible, and the coupling force can be further improved.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. It goes without saying that various modifications can be made.

100: Impeller (of the present invention)
110: hub 111: upper surface
112: side 113: side
114: fit portion 115: joint
120: blade
121: blade wind pressure surface 122: blade catching portion
130: secondary blade
131: auxiliary blade wind pressure surface 132: auxiliary blade catching portion
140:
141: fixing groove 142: engaging groove
143: fixing pin 144: elastic means

Claims (8)

And a circular bottom surface 112 having a circular upper surface 111 and an area larger than the upper surface 111. The lower surface 112 is formed in a groove shape extending from the upper surface 111 to the lower surface 112 A hub (110) having a plurality of fitting portions (114) radially formed on a side surface (113);
A blade wind pressure surface 121 formed to have a predetermined curved surface shape and converting the kinetic energy of wind into mechanical energy and a blade wind pressure surface 121 formed along one side end of the blade wind pressure surface 121 and corresponding to the cross- A plurality of blades 120 including a blade engaging portion 122 having a cross-sectional shape that is a cross-sectional shape;
And an auxiliary blade wind pressure surface (131) having an area smaller than the blade wind pressure surface (121), and an auxiliary blade wind pressure surface (131) which is formed in a curved shape of a predetermined shape to convert kinetic energy of wind into mechanical energy, And a plurality of auxiliary blades (130) formed along the cross-sectional shape of the insert portion (114) and having an auxiliary blade engagement portion (132) having a cross-sectional shape corresponding to the cross-sectional shape of the insert portion (114).
A fixing groove 141 formed in the shape of a recessed groove on the fitting portion 114 and a fixing groove 141 formed at a position corresponding to the fixing groove 141 of the blade fixing portion 122 or the auxiliary blade fixing portion 132. [ And is movable toward the coupling groove 142 by a centrifugal force when the impeller 100 is rotated in the space formed by the fixing groove 141 and the coupling groove 142. [ A fixing part 140 comprising a fixing pin 143 which is fixed to the fixing part 143;
And,
The blade 120 and the auxiliary blade engaging portion 132 are fixed to the hub 110 by the fitting of the blade engaging portion 122 or the auxiliary blade engaging portion 132 to the fitting portion 114 and the fixing portion 140, Wherein the auxiliary blades (130) are detachably and assemblably coupled to each other.
The apparatus according to claim 1, wherein the blade catching portion (122) or the auxiliary blade catching portion (132)
Wherein the cross-sectional shape of the impeller is such that the cross-sectional shape becomes wider toward the end.
delete 2. The apparatus of claim 1, wherein the fixing portion (140)
Further comprising elastic means (144) having opposite ends connected to the fixing groove (141) and the fixing pin (143), respectively.
2. The apparatus of claim 1, wherein the fixing portion (140)
Is disposed closer to the upper surface (111) than the lower surface (112).
2. The device of claim 1, wherein the side surface (113)
And the inclination degree decreases from the upper surface (111) to the lower surface (112).
2. The apparatus of claim 1, wherein the impeller (100)
Wherein the blades (120) and the auxiliary blades (130) are alternately arranged.
2. The apparatus of claim 1, wherein the hub (110)
Wherein a cavity (115) is formed in the inside of the impeller.

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