KR100477004B1 - Fluid resistance device and fluid control device using it - Google Patents

Abstract

The present invention relates to a fluid resistance device configured by stacking annular disks, and more particularly, to increase the flow rate of the fluid in the available volume by allowing the fluid to move along the fluid movement path with high head loss on the annular disk, Kinetic energy relates to a fluid resistance device that can be controlled at an appropriate level. The flow module of the fluid resistance device according to the present invention is divided into the inlet portion 101, the fluid is introduced into the annular disk, the fluid introduced into the inlet portion 101 is bent and extends in the circumferential direction having both ends ( 102, the transmission part 104 which communicates perpendicularly at the both ends 103 of the division part 102, the direction change part 105 extended at each end part of the transmission part 104, respectively, The turning part 105 is formed to extend in both sides from the integrated portion 106, the outlet portion 107 is vertically communicated from the integration portion 106, the end portion of the outlet portion 107 is extended and integrated, It characterized in that it comprises an outlet splitting portion 108 which is open in the fluid outflow direction of the annular disk.

Description

Fluid resistance device and fluid control device equipped with the same {fluid resistance device and fluid control device using it}

The present invention relates to a fluid resistance device comprising a stack of annular disks and a fluid processing device equipped with the same. More particularly, the fluid is moved along a fluid movement path having a large head loss on the annular disk even under high pressure. The present invention relates to a fluid resistance device that can be installed within a limited available volume while reducing the speed of the fluid to appropriately control the kinetic energy of the fluid.

Fluid pressure or flow rate Control is essentially a fluid resistance device in the process of flowing the fluid. However, since the fluid resistance device generates various problems such as cavitation, noise, and abrasion, elements such as kinetic energy, flow velocity, and pressure on the outlet side of the fluid are considered when designing the fluid resistance device.

At this time, the correlation between the kinetic energy (KE) and the velocity (V) and the flow rate (w), which are the background of the hydrodynamic theory, is the correlation between the kinetic energy (KE) and the velocity (V) of the fluid. ,

(Where ΔP is the differential pressure acting on the device or the fluid resistance, ρ ₀ is the density of the fluid, A ₀ is the cross-sectional area of the flow path, ξ is the loss factor for the fluid resistance, and V is the velocity)

If the kinetic energy at the trim exit of the valve is less than 480 kPa (30 m / s for water) under normal flow conditions, the problem will hardly occur, but cavitation may occur, so under conditions of two-phase fluids, It has been suggested that this kinetic energy should be limited to below 275 kPa (23 m / s for water) and below 75 kPa (12 m / s for water) in vibration-sensitive systems.

In addition, the flow velocity is directly related to the pressure difference of the fluid added to the front and rear of the device, the total resistance coefficient determined by the shape of the flow path and the Reynolds Number, and the density of the fluid. Since the drop amount is proportional to the total resistance (loss) coefficient, the density of the fluid, and the square of the flow velocity, the local resistance is increased at the flow path changer to increase the total resistance (loss) coefficient, thereby effectively increasing the speed and pressure of the fluid. You can control it.

In addition, the main noise source of the fluid treatment device is aerodynamic noise, and the degree of this acoustic energy is related to the mass flow rate, the pressure ratio due to the upstream absolute pressure and the downstream absolute pressure, the geometry and the physical characteristics of the fluid. It is known that if a pressure ratio is large at a specific part, a sonic flow or choked flow is generated to be a high noise source, thereby controlling or reducing the generation of noise by controlling the pressure ratio.

 Therefore, the kinetic energy of the outlet side of the fluid is kept below that according to the reference degree, and the pressure of the fluid is required to maintain a proper flow rate without causing a sudden change. Various prior arts have been devised to solve this problem. In particular, various inventions have been proposed regarding a fluid resistance device that is formed by stacking annular disks as in the present invention. There are a method of largely changing the cross sectional area of the flow path and a method of switching the direction of the flow path.

One example of the former is the invention of U.S. Patent No. 6,701,957, which forms a spiral flow path from the center of a disk, and the spiral flow path is provided with an orifice-shaped flow resistance part for inducing a rapid change in the cross-sectional area of the flow path. The head was allowed to reduce the head of the fluid.

However, the present invention adopts a method of causing a sudden change in the cross-sectional area of the flow path, such as an orifice, in the flow resistance section, thereby causing a local increase in flow velocity and pressure, causing noise, vibration, and corrosion. Foreign matter is trapped in the area where the area is narrowed has a problem that the device performance is reduced.

One example of the latter is the invention of U.S. Patent No. 6,095,196, which has a flow resistance portion in which the direction of the flow path is simply changed by forming a radial groove from the center of the disk to reduce the head of the fluid. .

However, even in the above invention, since the flow resistance part is simply formed, the size of the fluid resistance device is relatively increased in order to control the pressure and flow rate of the fluid, thereby increasing the space occupied by the device and increasing the cost. There is a problem.

As described above, both present problems, but there is a problem in that the volume or size of the device is very large in order to control the fluid under conditions of ultra high pressure or high differential pressure. In particular, a method of allowing a fluid to flow through a multi-stage and multi-flow formed of a plurality of disks is preferred.

In this regard, the present invention will be described more clearly by describing the invention of Korean Patent No. 438047, which has been patented by changing the flow path in the prior art, in the prior art.

FIG. 1 is an exploded perspective view of a plurality of disks and two end plates 8 and 9 that form a resistance device for controlling the speed and pressure drop of a fluid.

The disk has an inflow through hole 44 for a T-shaped right-angle flow path having six fluid inlets 43 and a discharge through hole 47 having six fluid outlets 48. In addition, the disk has an inner diameter portion and an outer diameter portion, and the fluid inlet 43 for forming the T-shaped right-angle turning channel 21 is formed in the inner diameter portion on the basis of an angle of the center of the disk, and the radial direction And through holes 45 and 46 for the second and third T-shaped orthogonal direction turning flow paths are formed adjacent to each other, and a discharge through hole 47 having an outlet 48 for fluid is formed adjacent thereto. . Such four disks are repeatedly stacked by a specific angle, causing 18 times of bending to change the flow direction of the fluid to 90 °.

On the other hand, Figure 1 shows that the disk is combined with only six to form a resistance device, the end plates (8, 9) of the resistance device are made to be the same, the size of the center hole and the end plates (8, 9) The outer diameter of is equal to the disk 15. In the end plate 8, bolting holes 83, 84, 85, 86 with four jaws are formed at 90 ° angles at the same positions as bolt fastening holes of the disc for bolting a plurality of disks.

In more detail, the process of connecting the disks and the end plates will be described in more detail, when referring to the bolt fastening holes 89 of the lower end plate 9, the bolt fastening holes 61 of the first disk 71 and the second disk 72. Bolt fastening hole 58 of the third disk 73, bolt fastening hole 59 of the third disk 73, bolt fastening hole 60 of the fourth disk 74, and bolt fastening hole 61 of the fifth disk 75). , The bolt fastening holes 58 of the sixth disk 76, and the bolt fastening holes 86 of the upper end plate are aligned in a straight line to be coupled by bolts, and the remaining three bolt couplings are also the same. It is also possible to join by welding or the like instead of using the bolt.

The prior art thus made has a high performance effect that can be used to drastically lower the pressure of a fluid even under very high pressure. However, the conventional technique has the same channel direction switching angle and the channel cross-sectional area is constant, so that the local resistance is not large. Therefore, the local resistance value has to be increased and the channel cross-sectional area is constant. Once the foreign material passed through the inlet is caught again at the outlet, there was a problem that the noise caused by the fluid flow occurs.

The present invention has been made to solve the above problems, an object of the present invention is to effectively control the kinetic energy, speed and pressure of the fluid by increasing the total resistance coefficient by increasing the local resistance in each direction switching portion of the flow path , There is no sudden change of fluid velocity and pressure throughout the flow path, so that there is no problem of noise, vibration, and erosion, etc. To provide.

In particular, in order to maximize head loss, first, characterize the structure of the flow path to increase the local resistance due to fluid interaction; and second, form a three-dimensional flow path using a plurality of disks to make the local resistance even larger. The present invention provides a fluid resistance device that geometrically arranges flow path switching parts having different flow angle switching angles to increase the local resistance, and fourthly, increases the local resistance by varying the size of the flow path cross-sectional area before and after the flow direction switching.

In the fluid resistance device according to the present invention, a fluid resistance device for stacking annular disks to form a flow path, wherein the flow path is an inflow portion into which the fluid flows into the annular disk, and the fluid introduced into the inflow portion is bent and circumferentially. A splitting part extending and having both ends, a transfer part vertically communicating at both ends of the splitting part, a turning part extending at each end of the delivery part and being bent, and each turning part extending and being integrated A flow module including an integrated part, an outlet part vertically communicating with the integrating part, and an outlet part extending from both ends of the outlet part, the outlet part being open in the fluid outlet direction of the annular disc. It is configured so that the fluid is configured to be divided and integrated, causing a plurality of flow path changes in the flow.

At this time, the fluid flowing into the inlet portion is bent at an angle of more than 90 ° in the divided portion 180-θ ° (0 <θ <90 °), the bent at the angle of θ ° in the direction change section so that the flow path is rapidly switched It is desirable to be configured as possible.

At this time, the cross-sectional area of the flow path is kept constant or the cross-sectional area of the flow path is kept constant. It can be configured to gradually increase in the outflow direction of the fluid as a whole. However, it is desirable to form a small cross-sectional area of the flow path in the section between the direction change portion of the fluid and the integrated portion.

In addition, the outlet portion is formed with a protrusion from the base toward the fluid outflow direction, it can be configured so that a plurality of passages branched to the outlet portion.

In addition, it is preferable that a plurality of passages are formed in the stacked annular disks.

Hereinafter, an embodiment according to the present invention will be described with reference to the drawings. However, the configuration of the fluid resistance device according to the present invention can be easily changed according to the dimensions, roughness of the surface of the flow path, the degree of right angle to the flow path, the flow path switching angle, etc. Since variations of the present invention are possible, modifications to the extent that those skilled in the art can easily change the present invention according to fluid characteristics are not excluded from the scope of the present invention.

Figure 2 is a perspective view showing one embodiment of a fluid resistance device according to the present invention installed in the valve. Accordingly, the fluid resistance device 110 includes an annular disk 200 and diaphragm disks 400 (400a, 400b), and the fluid resistance device 110 includes an inlet port 120 and an outlet port in the valve 100. Installed between the 130, it is fixed by the disk coupling bolt 113a and nut 113b passing through the fastening hole formed in the disk (200, 400). On the other hand, the direction of the inlet 120 and the outlet 130 in the valve 100 can be changed according to the characteristics of the valve (100). In addition, the flow rate of the valve 100 is adjusted according to the vertical movement of the plug 150 connected by the stem 140.

As such, the manner in which the fluid resistance device according to the present invention is mounted and operated in the fluid processing device is not limited to the present embodiment, and may be applied and mounted in any known fluid processing device.

3 is a schematic view showing a flow module of the fluid resistance device according to the present invention. As a result, when the flow path of the fluid according to the present invention is described in detail, the fluid introduced from the inlet passes through the inlet 101 and arrives at the partition 102. The fluid is diverted to 180-θ ° (0 <θ <90 °) at an angle of 90 ° or more while passing through the partition 102, and the fluid divided in half flows at the end portions 103 (103a, Go back to 103b, and again turn vertically to reach communicating portions 104 (104a, 104b). The fluid reaching the delivery part 104 again changes direction of θ ° while passing through the redirection parts 105 (105a and 105b) and reaches the integrating part 106.

The fluid in which the flow rate divided in the integrating unit 106 is integrated again arrives in the outflow dividing unit 108 through the communicating outlet 107 while communicating in a vertical direction and finally exits the annular disc.

In this way, the fluid resistance device according to the present invention, the fluid introduced into the divider 102, the delivery unit 104, the turning unit 105, the integrated unit 106, the outlet 107, the outlet divider 108 ), It will have a flow module that can change direction six times. According to the flow module the direction change is made while moving between the disk Since it is six places, the three-dimensional flow path structure is formed through the two disks, and the flow direction of the flow path is configured to be switched, so that the local resistance value is increased by 170% than not being switched. In addition, the fluid is divided and integrated into an interaction process, which results in more localized resistance.

The flow module may be configured to be applied one or more times in the fluid resistance device or, unlike illustrated, the flow path may be configured to be bent vertically down first and then bent upwards again. Let's look at several embodiments according to the present invention.

4 is a plan view showing one embodiment of the annular disk according to the present invention. The annular disk 210 has an inflow through groove 310 through which fluid flows into the fluid resistance device, an outflow through groove 320 through which fluid flows out of the fluid resistance device 110, and a first flow through groove through which fluid flows. 330 and a second flow through groove 340 are formed (for the convenience of description, the columns formed by them are called column A, and the section in which column A is formed is called section A. Meanwhile, the components used in the following description) The names of the first and second terms are used for similarity between components having similar functions, but the names of the components are not unique.

In addition, the one side region of the column A, the first transfer through groove 350 through which the fluid is delivered, the second transfer through groove 360 through which the fluid of the first flow through groove 330 is transferred, and the second flow through groove ( A third transfer through groove 370 through which the fluid of 340 is transferred is formed (for the convenience of description, the rows formed by the column B are referred to as the column B, and the section where the column B is formed is referred to as the section B). At this time, the width of the section B is equal to the width of the section A. A plate section C is formed in one side of the section B in which the column B is formed, in which no groove is formed as much as the width of the section B.

The flow path formed in the present invention is a three-dimensional flow path, and the column A of one annular disk and the column B of another annular disk of the same shape stacked on the upper surface communicate with each other to form a flow path. It is assumed that the rows are in different annular disks, and two annular disks forming one flow path are called adjacent annular disks with respect to each other.

Since the annular disk 210 of the present embodiment is installed in a valve in which fluid flows from the inner circumference to the outer circumferential direction, the inflow through groove 310 is formed in the inner circumference of the annular disk 210, and the outflow passage. The groove 320 is formed on the outer circumference of the annular disk 210, the first flow through groove 330 and the second flow through groove 340 is the inlet through groove 310 and the outlet through groove (in the flow order of the fluid) 320).

The inflow through groove 310 has a first inflow portion 311 which is opened to the outside from the inner circumferential surface and has a constant entry section so that external fluid flows in. In addition, in order to increase the local resistance to the fluid, the first inlet 311 is provided with a first partition 313 having end portions 315; 315a, 315b extending in both circumferential directions. The angle formed by the first inflow portion 311 and the end portions 315 (315a, 315b) of the first division portion 313 is formed at an angle of 90 ° or less.

Therefore, the fluid entering the first inlet 311 is steeply turned to 180-θ ° (0 <θ <90 °) that is an angle of more than 90 ° in the first division 313, which is a fluid flow This is to use the characteristic that the local resistance by the turning angle increases exponentially as the turning angle decreases. For example, based on the case where the direction change angle is 90 °, the local resistance value increases by about 190% when switching to 120 ° and decreases about 60% when switching to 60 °. Therefore, in switching the flow path of the fluid, rather than switching twice to 90 °, after switching from the first dividing portion 313 to 120 ° and again from the first turning portions 353; 353a and 353b to 60 °. This is because the total local resistance value is 250%, and the gain is 50%.

The inflow through groove 310 including the first inflow portion 311 and the first division portion 313 is formed by repeating a plurality of circumferential directions of the annular disk 210.

The outflow through groove 320 is provided on the center line in the center of the inlet through the outer circumferential surface and is formed to be spaced apart from the inflow through groove 310 by a predetermined interval. Outflow through groove 320 is in communication with the first integrated portion 355 of the first transfer through groove 350 to be described below so that the fluid flows to the outside and the outlet portion 321 is formed with a constant entry section, the fluid is An outflow dividing portion 323 is opened from the outer circumferential surface to the outside so as to flow out, so that the outflow fluid maintains a separation distance from an adjacent structure or device (eg, a valve body, a plug, etc.) In order to reduce or limit the kinetic energy, the cross section of the flow path is expanded rapidly.

A first flow through groove 330 and a second flow through groove 340 are sequentially formed between the inflow through groove 310 and the outflow through groove 320. The first flow through groove 330 and the second flow through groove 340 are formed in the same shape.

The first flow through groove 330 is in communication with the first transfer through groove 350 of the adjacent annular disk to be described below and the second inlet 331 for introducing fluid from the first transfer through groove 350; The second inflow portion 331 is configured to include a second divided portion 333 extending in both circumferential directions. At this time, it is preferable that the angle bent from the second inflow portion 331 to the end of the second division portion 333 is 90 ° or more.

The second flow through groove 340 is in communication with the second transfer through groove 360 of the adjacent annular disk to be described below and the third inlet portion 341 for introducing the fluid from the second transfer through groove 360 And a third dividing portion 343 which extends from both sides of the third inflow portion 341 in the circumferential direction. At this time, it is preferable that the angle bent from the third inflow portion 341 to the end of the third division portion 343 is also 90 ° or more to increase the resistance.

On the other hand, the inflow through groove 310 formed in the annular disk 210, the first flow through groove 330, the second flow through groove 340, the outlet through groove 320 so that all the center line toward the centripet coincides. It is preferable to form.

In addition, it is preferable that the cross-sectional area of the flow passage is gradually increased toward the outflow through groove 320 from the inflow through groove 310. This is because the velocity of the fluid decreases each time the flow direction is changed by increasing the size of the flow path cross-sectional area gradually each time the flow direction is changed. Therefore, it is possible to control the speed and kinetic energy of the fluid passing through the fluid resistance device 110 in an appropriate state, and when the fluid is gas or vapor, the volume expansion of the fluid through the expansion of the appropriate cross-sectional area as the flow progresses To accommodate.

In addition, in column B of the annular disk 210, a pair of first transfer units 351 formed to communicate with each end 315; 315a, 315b of the first division 313 of the adjacent annular disk 210. 351a, 351b and a pair of first turns to extend in the circumferential direction from the first transfer parts 351; 351a, 351b to change the direction of the fluid at a constant angle θ (0 ° <θ <90 °) 353; 353a and 353b and a first integrating portion 355 extending from the first turning portion 353; 353a and 353b so as to communicate with the second inflow portion 331 of the adjacent annular disk. The first transfer through groove 350 is formed.

In the first turning units 353 (353a and 353b), the fluid is formed such that the flow path cross-sectional area is reduced based on the first turning unit (353; 353a and 353b) while the direction of the angle is changed. That is, the first integrating portion 355 in the turning portion (353; 353a, 353b) than the flow path cross-sectional area from the first transfer portion (351; 351a, 351b) to the first turning portion (353; 353a, 353b). The passage cross-sectional area up to is formed to be small, which uses the characteristic that the local resistance becomes very large when the size of the cross-sectional area of the passage is reduced after the change of direction. At this time, it should be noted that the size of the cross-sectional area that is reduced after the change direction is maintained larger than the size of the cross-sectional area of the first inlet 311 so that the flow of foreign matter contained in the fluid does not block.

In addition, a second transfer through groove 360 is formed to be spaced apart from the first transfer through groove 350 in the fluid outflow direction, and a third transfer through groove is formed to be spaced apart from the second transfer through groove 360 in the fluid outflow direction ( 370 is formed.

The second transfer through groove 360 includes a first inflow portion 311, a first dividing portion 313 of the adjacent annular disc, and a first transfer portion 351; 351a and 351b of the annular disc 210. The fluid flowing through the turning parts 353 (353a and 353b), the first integrating part 355, the second inlet part 331 of the adjacent annular disk, and the second dividing part 333 in turn is again formed by the first annular disk. A pair of second transfer parts 361 formed to communicate with the end portions 335 (335a, 335b) of the second split part 333 so as to flow into the third inlet part 341 and the third split part 343. 361a and 361b, a pair of second turning portions 363 and 363a and 363b extending from the second transfer portions 361 and 361a and 361b to change the direction of the fluid, and a second turning portion ( 363 and 363a and 363b, and includes a second integration portion 365 formed to communicate with a third inflow portion 341 of the adjacent annular disk 210. Also in the second turning parts 363; 363a and 363b, the fluid is formed so that the direction of the angular angle is changed and the size of the passage cross-sectional area is reduced based on the second turning direction 363; 363a and 363b.

In addition, the third through hole 370 is the first inlet portion 311, the first split portion 313 of the adjacent annular disk, the first transfer portion (351; 351a, 351b), the first of the annular disk 210 The first turning section 353 (353a, 353b), the first integrating section 355, the second inlet section 331, the second split section 333 of the adjacent annular disk 221, of the annular disk 210 The second transfer part 361; 361a, 361b, the second turning part 363; 363a, 363b, the second integration part 365, the third inlet part 341 of the adjacent annular disk 210, It is formed to communicate with the end portion 345 (345a, 345b) of the third split portion 343 so that the fluid flowing through the three split portion 343 in turn flows to the outlet portion 321 of the annular disk 210. A pair of third transfer portions 371a and 371b and a pair of third transfer portions 373a and 373a extending from the third transfer portions 371a and 371b to change the direction of the fluid. 373b and extended from the third turning portions 373a and 373b to communicate with the outlet portion 321 of the annular disk 210. 3 is configured to include an integrator (375). In the third turning portions 373a and 373b, the fluid is formed so that the direction of the angular angle is changed and the size of the passage cross-sectional area is reduced based on the third turning portions 373a and 373b. .

On the other hand, it is preferable that the first transfer through groove 350, the second transfer through groove 360, and the third transfer through groove 370 are all formed to coincide with the center line toward the centripet. In addition, it is preferable that the cross-sectional area of the flow passage becomes larger as the first transfer through groove 350 faces the third transfer through groove 370. This is because the velocity of the fluid is further reduced whenever the flow direction is switched. Therefore, it is possible to control the speed and kinetic energy of the fluid passing through the fluid resistance device in an appropriate state, and if the fluid is gas or vapor, it is possible to accommodate the volume expansion of the fluid by expanding the appropriate cross-sectional area as the flow progresses. To help.

On the other hand, one side of the section (B section) in which the column B is formed is formed with a plate section (C) in which no groove is formed as wide as the width of the B section. The upper and lower portions of the through grooves formed by stacking adjacent annular disks are blocked to allow the through grooves to be formed as flow paths.

In this embodiment, as the fluid resistance device forms a three-dimensional flow path, the introduced fluid not only undergoes a total of 18 turns, but also receives the local resistance maximized through the interaction process divided and integrated.

On the other hand, Figure 4 has been described an embodiment for two flow through grooves, three through the grooves formed in the annular disk, the flow through grooves and the delivery through grooves depending on the nature of the fluid or the need for decompression It is obvious that the present invention is included in the scope of the present invention even if it is not formed or formed in any number of one or more.

Figure 5a is a perspective view of a fluid resistance device according to an embodiment of the present invention laminated to an annular disk, Figure 5b is a partial perspective plan view showing the laminated annular disk, Figure 5c is an incision showing the stacked annular disk Perspective view. Accordingly, the method in which the annular disks 210 are stacked in detail will be provided with a diaphragm disk 400a at the lowermost layer. The annular disk 210 is stacked on the upper portion, and the section B on which the other column of the annular disk 210 is formed is formed on the upper portion of the section A on which the column A of the annular disk 210 is formed so that the fluid can flow in three dimensions. B) is stacked so as to be positioned, the plate section (C) is formed so as to be located on top of the other space of the annular disk again stacked, the annular disk 210 to suit the size or flow rate of the valve in the lamination method Lay in multiples. When the lamination is completed, the disc disk 400b is finally stacked to complete the annular disk stack 270.

According to the lamination method as described above, a plurality of fluid passages 280 having a plurality of inlets 281 and outlets 283 are formed. In this embodiment, eight fluid channels are formed, and the inlets 281 are formed. Fluid introduced through) has a structure that is discharged through the outlet 283 formed in the other disk.

At this time, in order to bind the annular disk stack 270, a fastening hole 271 is formed in each disk, so that a valve (pressure control valve, flow control valve, pressure reducing valve), back pressure device, silencer, diffuser, or similar fluid may be formed. Being able to be mounted on any fluid treatment device that increases or decreases the flow rate is within the ordinary scope of the skilled artisan and can be mounted in many ways.

FIG. 5B illustrates in more detail that the grooves of the annular disc communicate with each other while the grooves of the adjacent annular disc overlap each other up and down. That is, both ends 315; 315a and 315b of the first division part 313 of the inflow through groove 310 overlap with the first transfer parts 351; 351a and 351b of the first transfer through groove 350. In communication, the first integration portion 355 of the first transfer through groove 350 is communicated while overlapping the second inlet portion 331 of the first flow through groove 330, the first flow through groove 330 Both ends 335; 335a and 335b of the second division part 333 of the second communication part 333 communicate with each other while overlapping with the second delivery part 361; 361a and 361b of the second delivery through hole 360. The second integrating portion 365 of the groove 360 is communicated while overlapping with the third inlet portion 341 of the second flow through groove 340, and the third dividing portion 343 of the second flow through groove 340. End portions 345 (345a, 345b) are communicated while overlapping with the third transfer portion (371; 371a, 371b) of the third transfer through groove 370, the third integrated portion of the third transfer through groove (370) 375 is communicated while overlapping the outlet portion 321 of the outflow through groove 320.

In FIG. 5C, the adjacent annular disks are stacked to show a three-dimensional shape in which columns A or B formed on each annular disk are connected while overlapping to form a flow path. At this time, it can be seen more clearly that the fluid passing through the flow path changes 18 times in total.

6 is a partial plan view showing another embodiment of the annular disc according to the present invention. In the present embodiment, the outflow portion 321 of the outflow groove 320 of the annular disk 210 is formed with a protrusion 325 extending from the base in the fluid outflow direction, resulting in the outflow portion 321 Two flow paths are formed. Two protrusions 325 are formed in this embodiment, but since the flow passage cross-sectional area of the outlet portion 321 to be formed is not larger than the cross-sectional area of the flow passage formed in the fluid inlet portion 311, there is a fear that foreign substances introduced therein may be blocked. If not, it is also possible to form a plurality.

When a plurality of flow paths of the outlet portion 321 are formed, the peak frequency of the noise is transferred to the higher side, and thus the human body exceeds the audible frequency range of the person, thereby reducing the noise in the apparatus.

On the other hand, according to the physical properties of the fluid mounted on the fluid resistance device or the valve structure according to the present invention, the inlet and outlet of the fluid can be arranged as opposed to the embodiment of FIG. Fig. 7 is a plan view showing one embodiment of the annular disc in this case. In contrast to the inflow through-groove 310 in FIG. 4, the inflow through-groove 310 of the annular disk 210 has a first inflow section 311 and a first inflow section in which a constant entry section is opened to the outside from the outer circumferential surface thereof. A first flow through groove 330 and a second flow through groove, having a first split portion 313 having end portions 315 and 315a and 315b extending in both circumferential directions at 311. 340, the first through-hole 320 is formed in the manner described in Figure 4 to form a column A, the first communication with each end (315; 315a, 315b) of the first partition 313 of the adjacent annular disk A second transfer through groove 360 and a third transfer through groove 370 are formed in the manner described with reference to FIG. Form a fever. In addition, at one side of the section in which the column B is formed, a plate section C in which no groove is formed by the width of each section is formed.

In the fluid resistance device according to the embodiment described with reference to FIG. 7, the flow path resistance device is formed by stacking as shown in FIG. 5, and at least one protrusion (not shown in FIG. 6 toward the fluid outflow direction from the base of the outlet part 321). Forming the 325 to form a plurality of flow paths formed by the outlet portion 321 can be obviously derived by the description of the present specification, so a detailed description thereof will be omitted.

At this time, it is within the ordinary creative scope of those skilled in the art to form a fastening hole 271 in each disk to bind the annular disk stack 270 so that it can be mounted on the valve with bolts and nuts, for example, welding Or a pin or the like.

Effects of the fluid resistance device and the fluid treatment device equipped with the same according to the present invention described above are as follows.

First, by forming a three-dimensional flow path structure to increase the head loss of the fluid without a sudden change in pressure in the annular disk in the fluid resistance device, the flow rate of the fluid is increased in a constant volume, so that the fluid can be easily The flow can be controlled, and the damage caused by cavitation, abrasion, and erosion can be suppressed, and the fluid resistance device can be miniaturized.

Second, the cross sectional area of the flow path is larger than that of the prior art, and thus the flow path blockage caused by foreign matter is eliminated.

Third, the grooves formed in the annular disk are formed to gradually increase in the fluid outflow direction, and by forming a section to be reduced again in a certain section, local resistance is maximized.

Fourth, the noise can be reduced by forming a plurality of flow paths of the outlet portion to make the frequency generated when the fluid flow is above the audible frequency.

Although the invention has been described with reference to the preferred embodiments mentioned above, many other possible modifications and variations can be made without departing from the spirit and scope of the invention. Accordingly, the appended claims are intended to cover such modifications and variations as fall within the true scope of the invention.

1 is an exploded perspective view of a fluid resistance device according to the prior art.

Figure 2 is a cross-sectional view showing one embodiment of a valve in which a fluid resistance device according to the present invention is used.

3 is a schematic view showing a flow module of the fluid resistance device according to the present invention.

Figure 4 is a plan view showing one embodiment of the annular disk of the fluid resistance device according to the present invention.

Figure 5a is a plan view showing one embodiment of the annular disk stack of the fluid resistance device according to the present invention.

Figure 5b is a partial perspective plan view showing an embodiment of a laminate of the annular disk of the fluid resistance device according to the present invention.

Figure 5c is a perspective view showing an embodiment of the annular disk of the fluid resistance device according to the present invention.

Figure 6 is a partial plan view showing another embodiment of the annular disk of the fluid resistance device according to the present invention.

Figure 7 is a plan view showing another embodiment of the annular disk of the fluid resistance device according to the present invention.

<Description of the symbols for the main parts of the drawings>

       101: inlet 102: dividing unit

       103 (103a, 103b): division end 104 (104a, 104b): transmission part

       105 (105a, 105b): direction change unit 106: integrated unit

       107: outlet 108: outlet splitting section

200, 210: annular disk 310: inflow through groove

311: first inlet 313: first division

315: first split end 320: outflow groove

321: outflow part 323: outflow splitting part

330: first flow through groove 331: second inlet

333: second division part 335: second division part end

340: second flow through groove 341: third inlet

343: third division 345: end of third division

350: first delivery through groove 351: first delivery

353: first direction switching unit 355: first integration unit

360: second delivery through groove 361: second delivery through

363: second direction switching unit 365: second integration unit

370: third delivery through groove 371: third delivery through

373: third direction switching unit 375: third integration unit

400a, 400b: plate disc

Claims (17)

In a fluid resistance device for laminating an annular disk to form a flow path, The flow path includes an inflow portion through which the fluid flows into the annular disk, a partition portion in which the fluid flows into the inflow portion is bent and extends in a circumferential direction and has both ends, and as long as the flow passage communicates vertically at both ends of the partition portion. A pair of transmission parts, a pair of turning parts extending from each end of the transmission part and being bent, an integrated part extending and integrating the pair of turning parts, respectively, and an outflow communicating vertically in the integration part And a flow module that extends from both ends of the outlet portion to both sides, and includes an outlet splitter configured to open in the fluid outlet direction of the annular disc. And the fluid is configured to be repeatedly divided and integrated while sequentially passing through the at least one or more flow modules. The method according to claim 1, The fluid introduced into the inlet is bent at an angle of 180-θ ° (0 <θ <90 °) in the traveling direction at each of the divided parts, and at each of the turning parts, the fluid is bent at an angle of θ in the traveling direction. Fluid resistance device, characterized in that configured to be switched quickly. The method according to claim 1, Fluid resistance device, characterized in that the size of the cross-sectional area of the flow path is kept constant. The method according to claim 1, And the size of the cross-sectional area of the flow passage gradually increases in the outflow direction of the fluid. The method according to any one of claims 1 to 2, The flow path is formed such that the size of the cross-sectional area in the section between the turning section and the integrated section is smaller than the size of the cross-sectional area in the section from the transmission section to the turning section. Fluid resistance device, characterized in that. The method according to any one of claims 1 to 4, The outlet portion is formed with at least one protruding portion from the base toward the fluid outflow direction, the fluid resistance device characterized in that the outlet is divided into a plurality of passages. The method according to any one of claims 1 to 4, And a plurality of passages are formed in the stacked annular disks. In a fluid resistance device for laminating an annular disk to form a flow path, The annular disk, An inlet through-hole including a first inlet which opens in the direction in which the fluid flows into the annular disk, a first divider having both ends extending from the first inlet and bent circumferentially; It has an outlet portion of a predetermined length formed radially spaced apart from the one divided portion, and both ends extending from the outlet portion and bent in the circumferential direction, and includes an outlet split portion that is open in the fluid outflow direction of the annular disk A section in which the outflow through grooves are formed symmetrically on the center line direction of the inflow through grooves; A pair of first transfer parts extending radially in a predetermined length at one side of the section A, a pair of first turning parts extending from each of the pair of first transfer parts and bent; A first section configured to include a first integration part which extends and extends in one direction, respectively, and includes a first transmission through groove formed at a side of the section in which the inflow through groove is formed; And And a plate section having a width equal to the section B on one side of the section B, in which no groove is formed. The annular disks are stacked such that segment B of the second annular disk is positioned below section A of the first annular disk, and plate section of the third annular disk is located below section B of the second annular disk, An end of the first division portion of the first transfer through groove and the first transfer portion of the second annular disk communicate with each other, and a flow path in which the first integration portion of the second annular disc communicates with the outlet of the first annular disk. Fluid resistance device, characterized in that forming. The method according to claim 8, A, B and diaphragm section is a fluid resistance device, characterized in that formed repeatedly in the circumferential direction in the laminated annular disk. The method according to claim 9, The annular disk, A second dividing part disposed between the inflow through groove and the outflow through groove, the second inflow part extending in a radial direction at a predetermined length and having both ends extending from the second inflow part to be bent in a circular direction; A first flow through groove configured to include and be formed to be symmetrical on the center line of the inflow through groove; And A pair of second transfer portions positioned radially spaced apart from the first transfer through groove at a predetermined interval in a radial direction and extending at a predetermined length in the radial direction, and extending from the second transfer portion to change the direction of the fluid; A second transfer through groove configured to include a pair of second turning portions and a second integration portion extending from the second turning portion, the left and right symmetry being formed on the center line of the first transfer through groove; Is equipped with more, An end portion of the first dividing portion of the first annular disc and a first transfer portion of the second annular disc are in communication, the first integration portion of the second annular disc is in communication with a second inlet portion of the first annular disc, An end portion of the second annular disk and the second transfer portion of the second annular disk communicate with each other, and the second integrated portion of the second annular disk communicates with the outlet of the first annular disk to form a flow path. Fluid resistance device, characterized in that. The method according to claim 10, The annular disk further comprises one or more flow through grooves in a manner in which the first flow through groove is formed, and further comprises one or more transfer through grooves in a manner in which the second transfer through groove is formed. Fluid resistance device. The method according to any one of claims 8 to 11, The fluid introduced into the inlet is bent at an angle of 180-θ ° (0 <θ <90 °) in the traveling direction at each of the divided parts, and at each of the turning parts, the fluid is bent at an angle of θ in the traveling direction. Fluid resistance device, characterized in that configured to be switched quickly. The method according to any one of claims 8 to 11, Fluid resistance device, characterized in that the size of the cross-sectional area of the flow path is kept constant. The method according to any one of claims 8 to 11, The size of the cross sectional area of the flow passage gradually increases in the outflow direction of the fluid. Fluid resistance device, characterized in that enlarged. The method according to any one of claims 8 to 11, The outlet portion is formed with at least one protrusion from the base toward the fluid outflow direction, the fluid resistance device characterized in that the outlet is formed by branching a plurality of passages. The method according to any one of claims 8 to 11, The flow path is a fluid resistance device characterized in that the cross-sectional area in the section from each of the turning section to the integrated section is smaller than the size of the cross-sectional area in the section from the respective transmission section to each of the turning section. . A fluid treatment device equipped with the fluid resistance device of any one of claims 8 to 11.