KR101956464B1 - High Efficiency Fluid Distributor and Fluid Pump Including Same - Google Patents

Abstract

The present invention relates to a fluid distributor and a fluid pump including the fluid distributor including a disk module in which a plurality of disks having a center hole at the center are stacked at regular intervals, the disk module being rotated by receiving a rotational force; and at least one of an inlet guide provided on an inlet side of the center hole of the disk module for guiding suction of the fluid and a center guide provided in the center hole of the disk module for guiding the flow of the fluid. According to an embodiment of the present invention, a suction capability, a discharge capability, and a distribution capability are greatly improved by applying a feature of a cycloid curve to the inlet guide, the center guide, and a disk guide. In addition, it is possible to increase distribution efficiency by changing the direction of distribution depending on the purpose of use or changing the diameter of the center hole of the disk or the outer diameter of the disk and it is possible to significantly enhance the distribution capability and the discharge efficiency by suctioning the fluid from both sides through distribution module combination and performing uniform distribution in all directions and at 360 degrees. In addition, the present invention can be used for various household and industrial purposes in fans, hair dryers, humidifiers, dehumidifiers, air cleaners, air conditioners, fluid pumps, distributors, fluid mixers, and the like. Also, low noise, which is impossible in existing fans and hair dryers, can be realized and the fluid discharge volume increases, and thus product performance can be improved.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a high-efficiency fluid distributor,

The present invention relates to a high efficiency fluid distributor and a fluid pump including the high efficiency fluid distributor, and more particularly, to a high efficiency fluid distributor and a fluid pump including the high efficiency fluid distributor capable of increasing the suction force, the earth output and the distribution efficiency of the fluid.

As shown in FIGS. 1 and 2, a plurality of donut-like circular disks are stacked on each other at regular intervals, and a fluid is sucked by using the viscous frictional force of fluid generated between the disk and the disk. US patent 1,061,142 and US 1,061,206 filed by Nikola Tesla in 1913 are beginning to be patented. Since then, many patents have been applied to various industrial fields.

In the conventional art, when the disk module 10 rotates, a shear force is generated in a circumferential direction on the surface of the disk 1 between the disk 1 and the disk 1, And thus the fluid is inhaled. When the rotational speed of the disk module 10 is gradually increased, the fluid is further subjected to a tangential force acting on the tangential direction rather than the centrifugal force. As a result, the length of the fluid flowing path ) Is longer, the fluid has a problem that it stays longer between the disk 1 and the disk 1 and has a structure that obstructs the flow of the fluid at the inlet or the central portion where the fluid is sucked. There is a problem that the low suction force, the total discharge power, and the low distribution ability are generally caused by the problem.

US Pat. No. 5,470,197 A is a technique that adjusts the disk gap to increase efficiency according to the rotation speed, but is not used due to the complexity of the apparatus at present. US 20100111720 A1 shows a disk assembly, Is a technique for a ceiling fan that sucks and distributes it in the direction of 360 degrees. However, this technique is a technique for combining a disk assembly and a rotation axis of a motor in a suction passage to a motor and a peripheral device, , Which has a problem of low efficiency because the connecting plate composed of a plurality of holes interferes with suction of the fluid. This patent is based on US Pat. No. 2,632,598 A, filed in 1950, and US Pat. No. 2,632,598 A also has a plurality of holes in the center for sucking fluid, which has the problem of interfering with the suction of the fluid.

US 7,097,416 B2 and US 20050069409 A1 are characterized by a spiral guide or a triangular-pyramidal guide for efficient fluid aspiration, which is advantageous for suction and transfer of viscous fluids, but otherwise It has a problem that it may act as a resistance factor when a fluid is inhaled.

The patent US 5192183 A / US 5192182 A relates to a technique characterized in that the center portion of the disk is formed as a suction port in a shape other than a circular shape and that a guide is not provided at the suction port. However, this technology has a low suction depth, . Also, US 20060291997A1 discloses a structure in which a plurality of water droplets, triangular or trapezoidal suction ports are formed in order to improve the flow of the fluid in the suction port, but this also has a problem that the disk rotates and interrupts the flow of the fluid have.

US 20030086782 A1 discloses a method for assembling a housing, US 4403911 A describes a pump for sucking and transferring a mixture of a liquid and a solid. US Patent Application Publication No. 2002007779 A1 and US 6227795 B1 disclose a method for improving the ruggedness of the disk surface, However, these techniques may be advantageous for sucking and discharging the powder. However, when only the fluid is used, it may cause a problem that it interferes with the flow of the fluid. In addition, Lt; / RTI >

US 4255081 A is characterized by the provision of a plurality of vanes on the disk for the purpose of adjusting the disk spacing and increasing the suction capacity, but it has the problem of increasing the resistance to suction and discharge of fluid, and US 8784035 B2 Is characterized in that the disc combination is equipped with a spiral vortex generator, which is a spiral vortex generator, and US 5388958 A, which incorporates heat transfer technology in the disc combination, But it is not related to the increase in suction power or the ability to distribute and distribute.

Based on the above-mentioned conventional technologies, existing technologies developed based on the Tesla Pump (or a Boundary Layer Pump) have problems such as low suction power, It has limitations to solve.

(Patent Document 1) Korean Patent Registration No. 10-0178546 (registered on Nov. 24, 1998)

(Patent Document 2) Korean Patent Registration No. 10- 1237143 (Registered on Feb. 19, 2013)

SUMMARY OF THE INVENTION The present invention has been made to solve the conventional problems,

It is an object of the present invention to apply a cyclic curve to an inlet guide and a center guide and to a disk guide to allow the flow of fluid to flow through the minimum resistance the fastest and to quickly guide between a plurality of disks to provide suction, Efficiency fluid distributor and a fluid pump including the high-efficiency fluid distributor.

Further, it is possible to provide a high efficiency fluid distributor and a fluid pump including the high efficiency fluid distributor which can change the distribution direction according to the purpose of use, make the center hole diameter of the disk or the outer diameter of the disk different, or greatly increase the distribution efficiency through the combination of the distribution modules There is.

According to an aspect of the present invention, there is provided a high-efficiency fluid distributor comprising: a disk module in which a plurality of disks having center holes formed at a center thereof are stacked at predetermined intervals and rotated by receiving a rotational force; And at least one guide provided on an inlet side of the center hole of the disk module for guiding suction of the fluid and a center guide provided in the center hole of the disk module for guiding the flow of the fluid. .

The inlet guide has a curved guide surface recessed from an outer upper end toward an inner lower end, and the center guide has a curved guide surface recessed from an upper center toward a lower outer side.

The guide surface curve of the inlet guide and the guide surface curve of the center guide are formed of a cycloid curve.

A pair of distribution modules each having a center guide of a cycloid curve in the center hole of the disk module and a center guide of a cyclic curve are provided on the side of the center hole of the disk module are coupled to both ends of the connection rod, And is symmetrically provided.

The center hole of the disk module may have a center hole diameter different from that of the center guide so as to have the same distance from the central guide, thereby forming the same curved line as the cycloid curve of the center guide.

In addition, a pair of distribution modules each having a cyclic curve in-line guide in the center hole of the disk module and a center guide of a cycloid curve in the center hole of the disk module are symmetrically provided with respect to a central connection disk .

The pair of distribution modules may have an outer diameter different from that of each of the disks forming the disk module, and the outer surface of the disk module may be concave. In addition, the pair of distribution modules may have outer surfaces of the discs forming the disc module different from each other, and the outer surface of the disc module is convex. At this time, the pair of pump modules are provided so that the center holes of the disk modules have the same distance from the center guide, and the center holes of the disk modules have the same diameter, so that the same curves as the cycloid curves of the central guides are formed .

In addition, the disk module is characterized in that a fluid distribution guide for distributing fluid at a desired angle is coupled.

The disk has a center guide diameter Cd, a disk outer diameter D, and a disk inner diameter d (g) in a ratio of the outer diameter D of the disk to the gap g between the disk and the disk in a ratio of 8 to 250, (Dd) of the difference between the difference D / (Dd) is 1.2 to 12.

The disc may further include an impeller-shaped disc guide formed radially with respect to a center of the center hole.

The disk guide is formed of a cycloid curve.

According to an aspect of the present invention, there is provided a high-efficiency fluid pump comprising: a disk module in which a plurality of disks having a center hole formed at a center thereof are stacked at predetermined intervals and rotated by receiving a rotational force; And a center guide provided in a center hole of the disk module to guide a flow of the fluid; And a housing which covers an outer side of the disk module of the fluid distributor and includes a discharge port through which fluid is discharged.

The guide of the fluid distributor has a curved guide surface concave from the outer upper end toward the inner lower end, and the guide has a curved guide surface recessed from the upper center toward the lower end outward, and the curve of the inlet guide of the fluid distributor And the curved line of the central guide is formed of a cycloid curve.

The pump module includes a housing having a center guide having a cycloid curve in a center hole of the disk module and having an inlet side guide having a cyclic curve at a center hole entrance side of the disk module, And the pair is connected to both ends of the connecting rod so as to be symmetrical with respect to the connecting rod.

The pump module includes a housing having a center guide having a cycloid curve in a center hole of the disk module and having an inlet side guide having a cyclic curve at a center hole entrance side of the disk module, And the pair is symmetrically provided with respect to the central connecting disk.

Here, the center hole of the disk module has a center hole diameter of each of the disks so as to have the same distance from the center guide, and the same curved line as the cycloid curve of the center guide is formed.

The pump module includes a housing having a center guide having a cycloid curve in a center hole of the disk module and having an inlet side guide having a cyclic curve at a center hole entrance side of the disk module, Wherein the first fluid pump and the second fluid pump are symmetrically disposed symmetrically with respect to the center connecting disk, and the discharge port provided in the housing of the first fluid pump and the second fluid pump has one outlet .

In addition, a fluid suction pipe is connected to an inlet guide of the fluid distributor, and a fluid suction disk for sucking the fluid is connected to the fluid suction pipe.

The disk has a center guide diameter Cd, a disk outer diameter D, and a disk inner diameter d (g) in a ratio of the outer diameter D of the disk to the gap g between the disk and the disk in a ratio of 8 to 250, (Dd) of the difference between the difference D / (Dd) is 1.2 to 12.

The disc may further include an impeller-shaped disc guide formed radially on the center of the center hole. The disk guide is formed of a cycloid curve.

According to the embodiment of the present invention, the suction, discharge, and dispensing capabilities can be greatly improved by applying the features of the inlet guide, the center guide, and the disk guide to the cyclic curves.

In addition, it is possible to increase the distribution efficiency by changing the direction of distribution according to the purpose of use, the diameter of the center hole of the disk or the outer diameter of the disk, and by sucking the fluid from both sides through the combination of the distribution modules, The distribution capability and the discharge efficiency can be greatly increased.

In addition, it can be used in various fields such as an electric fan, a hair dryer, a humidifier, a dehumidifier, an air purifier, an air conditioner, a fluid pump or a distributor, a fluid mixer, The performance of the product is improved.

1 is a conceptual view showing a conventional taughtula pump.
FIG. 2 is a conceptual diagram showing a velocity distribution of a fluid flowing between disks in the prior art. FIG.
3 is a cross-sectional view of a high efficiency fluid distributor in accordance with an embodiment of the present invention.
FIG. 4 is a plan view showing a disk guide for guiding a fluid flowing in a tangential direction of a disk to a disk module in a high-efficiency fluid distributor according to an embodiment of the present invention. FIG.
5 to 8 are sectional views showing various embodiments of a high efficiency fluid distributor according to an embodiment of the present invention.
9 is a cross-sectional view showing a state in which a fluid distribution guide for distributing a fluid at a desired angle to a disk module in a high efficiency fluid distributor according to an embodiment of the present invention is coupled.
10 is a conceptual diagram illustrating the flow distribution and direction of a fluid in a high efficiency fluid distributor according to an embodiment of the present invention.
11 is a cross-sectional view of a fluid pump including a high efficiency fluid distributor in accordance with an embodiment of the present invention.
12 is a side cross-sectional view showing an embodiment for connecting a pair of fluid pumps according to an embodiment of the present invention with a connecting rod to improve fluid absorption and fluid discharge function.
13 is a side cross-sectional view showing an embodiment for connecting a pair of fluid pumps according to an embodiment of the present invention with a connection disk to improve fluid absorption and fluid discharge function.
14 is a side cross-sectional view showing an embodiment in which two pairs of fluid pumps according to an embodiment of the present invention are combined to suck fluid and discharge the fluid through one discharge port.
FIG. 15 is a cross-sectional view of a fluid pump according to an embodiment of the present invention in which a fluid suction pipe and a fluid suction disk are connected to an inlet guide so that fluid can be sucked in 360 ° forward direction and discharged 360 ° in all directions Fig.

These and other objects, features and other advantages of the present invention will become more apparent by describing in detail preferred embodiments of the present invention with reference to the accompanying drawings. Hereinafter, a high-efficiency fluid distributor and a fluid pump including the same according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings. For purposes of this specification, like reference numerals in the drawings denote like elements unless otherwise indicated.

FIG. 3 illustrates a side view of a fluid distributor for collecting and accelerating surrounding fluids to uniformly distribute the fluid at 360.degree. Instead of the discharge port, in order to increase the suction efficiency, according to an embodiment of the present invention.

FIG. 4 shows a disk guide for guiding the fluid flowing in the tangential direction of the disk out of the disk module in the fluid distributor.

5 is a side view of the disk in which the center holes of the disks have the same distance from the center guide so that the center holes of the disks have different diameters and the curves are the same as the cyclic curves of the central guides Giving.

Figure 6 shows a side view of a pair of highly efficient fluid dispensers in which fluid dispensers are combined in two using connecting rods to absorb and accelerate fluids on both sides to enhance the fluid dispensing function .

Figure 7 shows a side view of a paired high efficiency fluid distributor in which fluid distributors are combined in two using a common connecting disk to absorb and accelerate fluids on both sides to improve the fluid distribution function Giving.

Figure 8 is a side view of a fluid dispenser that improves the ability to diffuse or gather fluid dispense by adjusting the length of the disc by combining two fluid dispensers using a common connecting disc, Respectively.

FIG. 9 shows a state in which a fluid distribution guide is coupled to a disk module in a fluid distributor to distribute the fluid at a desired angle.

Figure 10 is a schematic representation of the flow distribution and direction of the fluid from a fluid distributor that distributes the fluid.

3 to 10, a high-efficiency fluid distributor 100 according to an embodiment of the present invention includes a disk module 110 (see FIG. 3), a plurality of disks having a center hole formed at a center thereof, And an inlet guide 120 provided at the inlet of the center hole of the disk module for guiding the suction of the fluid. Alternatively, a plurality of disks having center holes formed at the center thereof are stacked at predetermined intervals, A disk module 110 and a center guide 130 provided in the center hole of the disk module for guiding the flow of the fluid or a plurality of disks having a center hole formed at the center thereof are stacked at predetermined intervals, An inlet guide 120 provided at a center hole inlet side of the disk module for guiding suction of the fluid, Is provided in the center hole of the module is configured to include a central guide 130 for guiding the flow of the fluid.

3, the disc module 110 includes a plurality of discs 112 stacked at regular intervals on a connection disc 111 which receives a rotational force of a driving unit (not shown) Is rotated by receiving the rotational force of a driving unit (not shown). Since each disk 112 is formed in a donut shape and stacked in a plurality of layers, a center hole 113 is formed at the center of the disk module 110.

The inlet side of the center hole 113 of the disk module 110 is provided with an inlet guide 120 for guiding the suction of the fluid. The inlet guide 120 has a curved guide surface 121 concaved from the outer upper end toward the inner lower end to guide the fluid to be sucked into the center hole 113 of the disk module.

At this time, it is preferable that the curved line of the guide surface 121 formed on the inlet guide 120 is formed of a cycloid curve.

A center guide 130 for guiding the flow of the fluid is provided in the center hole 113 of the disk module 110. The central guide 130 has a curved guide surface 131 concaved from the upper center toward the lower outer side to guide the fluid sucked into the center hole 113 to be distributed among the plurality of disks 112 with a minimum resistance.

At this time, it is preferable that the curved line of the guide surface 131 formed in the central guide 130 is formed of a cycloid curve.

Here, the center guide 130 has a sharp-pointed shape, which is one example, and the center guide 130 may have a cycloid curve and have a finer end or may have various shapes do.

The cycloid curve is the trajectory of a point on the circumference of a rotating circle. The equation of the curve is expressed as x = radius (t - sint (t)) and y = radius (1 - cos (t)).

The cycloid curve is the "shortest descent curve" that descends the fastest when the same object descends at any given position, and the "asymptotic curve" that falls simultaneously at the bottom when an object in a stationary state is dropped on the cycloid curve Curve "(Toutochrone). That is, when an object slides from any arbitrary point to another arbitrary point, the curve that can move most quickly with the lowest resistance is the cycloid curve.

4, the disc 112 may further include an impeller-shaped disc guide 114 formed radially with respect to the center of the center hole 113. The disk guide 114 may be configured not only in the direction shown in FIG. 4 but also in the opposite direction, that is, on the back surface of the disk, The disk guide 114 is preferably formed of a cycloid curve.

In general, when the disk module rotates rapidly, the fluid has a larger tangential force than the centrifugal force, which results in a longer length of the fluid path. And the fluid has a problem of staying longer between the disk and the disk, causing problems in the suction, discharge, and distribution efficiency of the fluid. Therefore, in the present invention, as shown in FIG. 4, the disk guide 114 is mounted on the donut-shaped disk 112 to enhance the suction, discharge, and distribution efficiency of the fluid.

The disk guide 114 guides the fluid to be held in the disk module 110 due to a force acting in a tangential direction and guides the fluid to the disk module 110, thereby performing the discharge or distribution of the fluid more quickly.

4 (a), r = 0.2685.r _O and r _O are the radius of the donut-shaped disk 102. In this case, the disk guide 114 is formed of a cyclic curve, Of the radius. Then, y = r (1 - cos (t)) is expressed as x = r - r (t - sin (t)) in the xy coordinate system and t is between 0 and 2π. A section where the left side of the thus-depicted cycloid donut-shaped disk 112 is used, that is, a section for using the disk guide 114 is used.

As shown in FIG. 4 (b), the number of the disk guides 114 is eight. In practice, however, the number of the disk guides 114 may be at least two, and the disk guides 114 must be formed at a constant angle.

The disc guide 114 is also used to maintain a constant distance between the disc 112 and the disc 112. For convenience of explanation, r = 0.2685.r _O is described here, but it can be changed according to the size of the disk.

The ratio D / g of the outer diameter D of the disk 112 to the gap g between the disk 112 and the disk 112 is a ratio of the central guide diameter Cd and the disk outer diameter D / Dd of the difference between the inner diameter D of the disc and the inner diameter d of the disc is preferably 1.2 to 12.

Although the disk module 110 is discharged in a direction perpendicular to the fluid inlet of the inlet guide 120, this is only an example, and the disk module may be configured at an angle other than a right angle with the inlet.

The high-efficiency fluid distributor constructed as described above may be provided in various embodiments as shown in FIG. 5 to FIG.

5, the fluid distributor 100 has a center hole 113 of the disk module 110, that is, a center hole of each of the disks is equally spaced from the center guide 130 having the guide surface 131 of the cycloid curve, The diameter of the center hole 113 of each of the disks 112 is varied so as to have a distance to form the same curve A as the cycloid curve of the center guide 130. [ When the center hole 113 of the disk module has the same distance from the center guide 130, the fluid guided by the center guide 130 is similarly sucked into the disk module 110 and discharged in the same manner The suction force and the discharge power can be increased.

6, the fluid distributor 100 includes an inlet guide 120 having a cyclic curve on the inlet side of the center hole 113 of the disk module 110, A pair of distribution modules 140 provided with curved center guides 130 may be coupled to both ends of the connection rod 150 so as to be symmetrical with respect to the connection rod 150. [ As described above, when the distribution module 140 is combined with the two connection rods 150, the fluid can be absorbed and accelerated from both sides to improve the fluid distribution function. In addition, the fluid can be sucked from both sides and uniformly distributed .

6 (b), the center hole 113 of the disk module, that is, the center hole of each disk has the same distance from the center guide 130 having the cyclic curve, as shown in FIG. 6 (b) The diameter of the hole 113 may be varied to form the same curve as the cycloid curve of the central guide 130.

7, the fluid distributor 100 is provided with an inlet guide 120 having a cyclic curve on the inlet side of the center hole 113 of the disk module, and the center of the cycloid curve in the center hole 113 of the disk module, A pair of the distribution modules 140 provided with the guide 130 may be provided symmetrically with respect to the center connection disk 111. [ Combining the fluid dispensers in two with a common connection disc 111 allows the fluid dispensing function to be improved by absorbing and accelerating the fluid from both sides and by uniformly distributing the fluid in all directions 360 ° .

7 (b), each of the pair of distribution modules 140 has a different outer diameter of each of the disks 112 forming the disk module 110, so that the outer surface of the disk module 110 is concave It can be provided in a recessed shape.

 7A is a view showing a state in which the fluid sucked as a basic structure is transferred to the disk module 110 through the inlet guide 120 and the center guide 130 and then the viscous resistance between the disk 112 and the disk 112 7 (b) shows a state in which the outer disc 112 has a different diameter as a concave lens, while the fluid is distributed at the same pressure and speed between the disc 112 and the disc 112 while flowing outwardly through the outer disc 112 Which is designed for the purpose of diffusing the fluid, so that the fluid near to the common connection disc 111 is later distributed, because the fluid is low in speed and pushes out the fluid from the surroundings due to the high pressure.

As shown in FIG. 7C, the pair of distribution modules 140 may be configured such that the outer diameter of each of the disks 112 forming the disk module 110 is different, and the outer surface of the disk module 110 is convex So as to have a protruded shape. This is designed for the purpose of focusing the fluid by configuring the outer disc 112 to have different diameters like a convex lens so that the fluid that is farthest from the common connection disc 111 is firstly distributed, Because it is low, the pressure is so high that it pushes the fluid out of the surrounding area.

The fluid distributor 100 shown in Figs. 8A, 8B and 8C is different from the fluid distributor 100 shown in Figs. 7A, 7B, The diameter of the center hole 113 of each disk is made different so that the center hole 113 of the center guide 130 has the same distance from the guide surface 131 of the center guide 130, Is formed. That is, in addition to the features of the embodiment shown in FIG. 7, the fluid guided by the center guide 130 is added to the disk module 110 as a whole.

FIG. 9 shows a fluid distribution guide 150 coupled to the disk module 110 of the fluid distributor 100 shown in FIG.

The fluid dispensing guide 150 serves to distribute the fluid sucked through the inlet guide 120 and the center guide 130 to a desired angle. In FIG. 9, the fluid dispensing guide 150 ) Is formed in a curved shape or a curved shape and is distributed in the direction of 180 degrees from the suction port.

10, when the disk module 110 is rotated as shown in FIG. 10, the fluid is sucked on the cycloid curve of the inlet side guide 120 to form a center hole 113 And the fluid introduced into the center hole 113 is guided by the cycloid curve of the center guide 130 and sucked into the space between the disks 112. And. The fluid sucked into the space between the disks 112 is radially uniformly discharged through the disk guide 114 provided on the disk 112. [ In this case, the input guide 120, the center guide 130, and the disk guide 114 have a characteristic of a cycloid curve, that is, a "shortest drop curve" that falls most rapidly when the same object descends at an arbitrary same position, Because the feature of "Toutochrone", which drops simultaneously at the bottom when an object in a stationary state is dropped at different positions on the Lloyd's curve, is applied, the flow of fluid is made to flow fastest with minimum resistance, The disk guide 114 is guided the soonest between the disks 112, and the disk guide 114 induces a quick discharge of the fluid, thereby greatly improving the suction ability, the discharge ability, and the distribution ability of the fluid.

In addition, it is possible to increase the distribution efficiency by changing the direction of distribution according to the purpose of use, the diameter of the center hole of the disk or the outer diameter of the disk, and by sucking the fluid from both sides through the combination of the distribution modules, Distribution efficiency can be greatly increased.

Hereinafter, the fluid pump 200 including the high efficiency fluid distributor 100 of the present invention will be described.

11 shows a fluid pump including a high efficiency fluid distributor according to an embodiment of the present invention.

FIG. 12 shows a side view of a pair of highly efficient fluid pumps in which the fluid pumps of FIG. 11 are combined using two connecting rods to absorb and accelerate fluid from both sides to improve the fluid discharge function.

Figure 13 shows a side view of a paired high efficiency fluid pump in which the fluid pumps of Figure 11 are combined in two using a common connection disc to enhance the fluid delivery function by absorbing and accelerating fluid from both sides.

Fig. 14 shows a structure in which four fluid pumps (two pairs) of Fig. 11 are combined to collect the fluid from both sides and then discharge the fluid to one place.

Fig. 15 shows an embodiment in which a fluid suction pipe is coupled to a fluid suctioning pipe to suck fluid in all directions at 360 占 and discharge it in all directions 360 占 or discharge in a desired direction.

11 to 15, a fluid pump 200 according to an embodiment of the present invention includes a disk module in which a plurality of disks having a center hole formed at the center thereof are stacked at regular intervals and rotated by receiving a rotational force, A fluid dispenser provided on an inlet side of the center hole of the disk module and including at least one of an inlet guide for guiding suction of the fluid and a center guide provided in a center hole of the disk module for guiding the flow of the fluid, 100); And a housing 210 covering the outer side of the disk module of the fluid distributor and having a discharge port through which fluid is discharged.

Here, since the fluid distributor 100 includes all of the contents described above, the description thereof will be omitted.

As shown in FIG. 11, the housing 210 covers the outer side of the disk module 110 of the fluid distributor 100 and has a discharge port 211 through which fluid is discharged to one side. The housing 210 guides the sucked fluid in one direction to be discharged to the discharge port 211. That is, the fluid sucked into the center hole 113 of the disk module passes through the discharge port 211 while passing the fluid in the direction indicated by the dotted line in FIG. 11 (c) due to the viscous resistance force to the disk module 110 . 11 (c) shows the direction in which the fluid is sucked due to the inlet guide 120 and the center guide 130. In this case, as shown in FIG. Here, the disk module 110 indicates that the disk module 110 is discharged in a direction perpendicular to the suction direction of the fluid, but the disk module 110 may be formed at an angle other than a perpendicular direction to the suction direction.

12, the fluid pump 200 includes an inlet guide 120 having a cyclic curve at the inlet side of the center hole 113 of the disk module, and a center guide 113 of a cycloid curve in the center hole 113 of the disk module. A pair of pump modules 220 including a housing 210 covering the outer side of the disk module 110 are coupled to both ends of the connecting rod 230 so as to be symmetrical with respect to the connecting rod 230 .

13, the fluid pump 200 includes an inlet guide 120 having a cyclic curve on the inlet side of the center hole 113 of the disk module, A pair of pump modules 220 including a central guide 130 and a housing 210 covering an outer side of the disk module may be symmetrically provided with respect to a central connecting disk.

The center holes 113 of the disk modules shown in FIGS. 11 to 13 have different diameters of the center holes 113 of the disks so as to have the same distance from the center guides 130, The same curve can be formed.

14, the fluid pump 200 includes an inlet guide 120 having a cyclic curve at the inlet side of the center hole 113 of the disk module, and a center guide 130 of a cycloid curve in the center hole of the disk module. A pair of pump modules 220 including a housing 210 covering the outer side of the disk module is symmetrically provided with a first fluid pump and a second fluid pump symmetrically provided with respect to a central connecting disk And the discharge ports 211 provided in the housing 210 may be integrated into a single outlet.

15, the fluid pump 200 is connected to the fluid inlet pipe 240 to the inlet guide 120 of the fluid distributor and the fluid inlet pipe 240 is connected to the fluid inlet disk 250 May be connected to be capable of sucking fluid from a 360 ° radial direction.

The fluid suction disk 250 and the fluid suction pipe 240 may be installed at a rear end of the fluid distributor 100 or the fluid pump 200 for distributing the fluid. 15 (a), when the fluid is connected to the fluid distributor 100, the fluid sucked in can be distributed in a radial direction of 360 ° as shown in FIG. 15 (a). When connected to the fluid pump 200, Can be discharged to a desired position.

As described above, the fluid pump according to the present invention greatly improves the pump performance by using the fluid distributor having excellent suction, discharge, and dispensing capabilities by using the features of the inlet guide, the center guide, and the disk guide curves do.

In addition, the combination of pump modules can greatly enhance suction and discharge capabilities. The fluid can be sucked from the 360 ° radial direction and discharged in a desired direction, so that it can be applied to various technologies. Particularly, it can be used in various fields such as an electric fan, a hair dryer, a humidifier, a dehumidifier, an air purifier, an air conditioner, a fluid pump or a distributor,

In addition, since the noise is small, it is possible to realize low noise that can not be attained in a conventional fan or a hair dryer, and the performance of the product is improved because the discharge amount of the fluid is increased.

Although the preferred embodiments of the present invention have been described, the present invention is not limited to the specific embodiments described above. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the appended claims, And equivalents may be resorted to as falling within the scope of the invention.

100: fluid distributor
110: Disk module 111: Connection disk
112: Disk 113: Center hole
114: Disk guide 120: Inlet guide
121: guide surface 130: central guide
131: guide surface 140: distribution module
150: fluid dispensing guide 200: fluid pump
210: housing 211: discharge port
220: pump module 230: connecting rod
240: Fluid suction pipe 250: Fluid suction disk

Claims (23)

A disk module including a plurality of disks having a center hole formed on a connection disk rotated by receiving a rotational force and stacked at regular intervals;
An inlet guide provided at a center hole inlet side of the disk module and having a guide surface of a cyclic curve from an outer upper end toward an inner lower end to guide suction of fluid;
And a center guide provided in a center hole of the disk module and guiding a flow of fluid by forming a guide surface of a cyclic curve from an upper center to a lower outer side,
Wherein the central hole of the disk module has a center hole diameter of each of the disks different from the center guide to have the same distance as the cyclic curve of the central guide. delete delete The method according to claim 1,
And a pair of fluid distributors are coupled to both ends of the connecting rod so as to be symmetrical with respect to the connecting rod. delete The method according to claim 1,
Wherein the pair of fluid distributors are symmetrically disposed with respect to a central connecting disc. The method according to claim 4 or 6,
Wherein the outer surfaces of the pair of disk modules are concaved with different outer diameters of the disks forming the disk module. The method according to claim 4 or 6,
Wherein the outer surface of each of the disks forming the disk module is different in outer diameter, and the outer surfaces of the pair of disk modules are convex. delete The method according to claim 1,
Wherein the disk module is coupled to a fluid distribution guide for distributing fluid at a desired angle. The method according to claim 1,
The disk has a center guide diameter Cd, a disk outer diameter D, and a disk inner diameter d (g) in a ratio of the outer diameter D of the disk to the gap g between the disk and the disk in a ratio of 8 to 250, ) Of the difference between the D / (Dd) and the D / (Dd) is 1.2 to 12. The method according to claim 1,
Further comprising: an impeller-shaped disk guide formed radially on the disk with respect to a center of the center hole. 13. The method of claim 12,
Wherein the disk guide is formed of a cycloid curve. A disk module having a plurality of discs having center holes formed on a connecting disc rotating on receiving rotation of the disc, the disc modules being stacked at predetermined intervals; And a central guide provided in the center hole of the disk module and guiding the flow of the fluid, wherein a guiding surface of a cyclic curve is formed from the upper center to the lower outer side of the center guide, And a center hole of the disk module has a center hole having a center hole diameter different from that of the center guide so as to have the same distance as the cyclic curve of the center guide. And
And a housing which covers an outer side of the disk module of the fluid distributor and has a discharge port through which fluid is discharged. delete 15. The method of claim 14,
And a pair of the fluid pumps are coupled to both ends of the connecting rod so as to be symmetrical with respect to the connecting rod. 15. The method of claim 14,
Said pair of fluid pumps being symmetrically disposed with respect to a central connecting disc. delete 18. The method of claim 17,
Wherein the pair of fluid pumps symmetrically provided with respect to the connection disk are integrated so that the discharge ports provided in the housing have one outlet. 15. The method of claim 14,
A fluid suction pipe is connected to an inlet guide of the fluid distributor, and a fluid suction disk for sucking the fluid is connected to the fluid suction pipe. 15. The method of claim 14,
The disk has a center guide diameter Cd, a disk outer diameter D, and a disk inner diameter d (g) in a ratio of the outer diameter D of the disk to the gap g between the disk and the disk in a ratio of 8 to 250, ) Of the difference between the D / (Dd) and the D / (Dd) is 1.2 to 12. 15. The method of claim 14,
Further comprising an impeller-shaped disk guide formed radially on the disk with respect to a center of the center hole. 23. The method of claim 22,
Wherein the disk guide is formed of a cycloid curve.

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