CN114669404A

CN114669404A - Flaky particle water shower head

Info

Publication number: CN114669404A
Application number: CN202210231961.8A
Authority: CN
Inventors: 谢炜; 梁元山; 阎杨; 沈灿
Original assignee: Arrow Home Group Co Ltd
Current assignee: Arrow Home Group Co Ltd
Priority date: 2022-03-09
Filing date: 2022-03-09
Publication date: 2022-06-28

Abstract

The invention discloses a flaky particle water sprinkler which comprises a water inlet shell and a water outlet shell, wherein a water inlet is formed in the water inlet shell, a water outlet and an upper water outlet cavity are formed in the water outlet shell, the flaky particle water sprinkler also comprises a rectifying module, the rectifying module comprises a rectifying piece, the rectifying piece is provided with 2 rectifying cavities, the 2 rectifying cavities are respectively arranged on two opposite sides in the rectifying piece, a plurality of rectifying blocks are arranged in the rectifying cavities, the rectifying blocks protrude out of the inner wall of the rectifying cavities, a plurality of rectifying channels are formed among the rectifying blocks, and when water flows pass through the rectifying channels, the rectifying blocks can disturb the advancing direction of the water flows and enable the water flows to collide. By adopting the invention, the spray can spray fine particle spray, has large spray impact force and wide spray range, and can achieve better massage effect; and the operation is stable and reliable.

Description

Flaky particle water sprinkler

Technical Field

The invention relates to the technical field of bathrooms, in particular to a flaky particle shower head.

Background

The shower head is a common bathroom accessory. Traditional gondola water faucet is only single function of spraying usually, the water flower pattern is fairly simple, current gondola water faucet is on the basis of traditional gondola water faucet, the function that can spray the granule water has been increased, chinese patent with application number CN201720594978.4, it discloses a granule water goes out the water gondola water faucet, this kind of gondola water faucet is equipped with the impeller, rotatory water jacket, go out water core and inclined flow channel, through rivers impact impeller, the impeller drives rotatory water jacket and carries out the circumference swing, thereby make the inclined flow channel in the water core throw away rivers and form rotatory granule water, this kind of rotatory granule water can form slice granule water flower pattern. However, the impact force of the water flow of the flaky particle water spray shower is weakened by parts such as an impeller and the like, the number of the sprayed particle water is insufficient, the spraying range is small, and the massage effect is difficult to achieve. Moreover, the shower head adopts the movable parts to form the flaky spray, once the conditions such as blockage, damage of parts and the like occur, the movable parts can be blocked, and the operation is unstable and unreliable.

Disclosure of Invention

The invention aims to provide a flaky particle water sprinkler which can spray out fine particle water and is stable and reliable in operation.

In order to solve the technical problem, the invention provides a flaky particle water sprinkler which comprises a water inlet shell and a water outlet shell, wherein a water inlet is formed in the water inlet shell, a water outlet and an upper water outlet cavity are formed in the water outlet shell, the water inlet is communicated with the water outlet through the upper water outlet cavity, and water can enter from the water inlet and can be sprayed out from the water outlet.

The slice granule gondola water faucet still includes the rectification module, the rectification module is located go up in the outlet chamber, the rectification module includes the rectification piece, be close to in the rectification piece the one end of water inlet is equipped with the mouth of loosing water, be close to in the rectification piece the one end of delivery port is equipped with the water hole that gathers, the rectification piece is equipped with 2 rectification chambeies, 2 the rectification chamber is located respectively relative both sides in the rectification piece, hydroenergy can follow the mouth of loosing water gets into the rectification chamber, be equipped with a plurality of rectification pieces in the rectification intracavity, the rectification piece protrusion in the inner wall in rectification chamber, it is a plurality of form a plurality of rectification passageways between the rectification piece, rivers pass through during the rectification passageway, the direction of travel that the rectification piece can disturb rivers and make rivers produce the collision.

As an improvement of the above scheme, the flow straightener further comprises a flow distribution plate, the flow distribution plate is arranged in the middle of the flow straightener, the flow straightening cavities are respectively arranged on two opposite sides of the flow distribution plate, and the flow distribution plate can divide the water dispersing port into two parts corresponding to 2 flow straightening cavities respectively.

As an improvement of the above scheme, the rectification module includes a plurality of upper rectification blocks, the upper rectification blocks are uniformly arranged on the water dispersing port, a gap between two adjacent upper rectification blocks forms an upper rectification channel, a side wall surface of each upper rectification block is an arc surface, and water can enter the upper rectification channel from the side wall surface of each upper rectification block.

As an improvement of the above scheme, the upper rectification blocks are divided into a plurality of rows, the plurality of rows of upper rectification blocks are arranged in the middle and at the upper part of the rectification chamber, 2 adjacent rows of upper rectification blocks are staggered, a gap between two adjacent upper rectification blocks in each row can form the upper rectification channel, and the upper rectification block in the next row is arranged below the upper rectification channel in the previous row.

As an improvement of the above scheme, the rectification module further includes a left side rectification block and a right side rectification block which are symmetrically arranged, the left side rectification block and the right side rectification block are respectively arranged at two sides of the middle part of the rectification cavity and are located below the upper rectification block, side wall surfaces of the left side rectification block and the right side rectification block are both arc-shaped surfaces, a left side rectification channel is defined by the side wall of the left side rectification block and the side wall of the rectification cavity, a right side rectification channel is defined by the side wall of the right side rectification block and the side wall of the rectification cavity, and a middle side rectification channel is formed by a gap between the left side rectification block and the right side rectification block.

As an improvement of the above scheme, the side left rectifying block and the side right rectifying block gradually approach to the side walls on both sides of the rectifying cavity from top to bottom, the longitudinal section of the combined side left rectifying block and the combined side right rectifying block is in a shape of a Chinese character 'ba', and water flows can be divided into the side left rectifying channel, the side right rectifying channel and the side middle rectifying channel from the upper turbulent rectifying channel after passing through the turbulent flow of the side left rectifying block and the side right rectifying block.

As an improvement of the above scheme, the rectifier module further includes a middle rectifier block, the middle rectifier block is located below the middle rectifier channel in the side portion, 2 side surfaces of the middle rectifier block are symmetrically arranged inclined surfaces and respectively form a middle left rectifier channel and a middle right rectifier channel with the side left rectifier block and the side right rectifier block, and water flows after disturbed flow of the middle rectifier block can be divided into the middle left rectifier channel and the middle right rectifier channel from the side middle rectifier channel.

As an improvement of the above scheme, the rectification module further includes a lower left rectification block and a lower right rectification block, the lower left rectification block and the lower right rectification block are respectively connected to the side walls on both sides of the rectification cavity, the lower left rectification block and the lower right rectification block both protrude toward the direction of the central axis of the rectification cavity, and the side walls of the lower left rectification block and the lower right rectification block respectively enclose a lower left rectification channel and a lower right rectification channel with the side walls of the side left rectification block and the side right rectification block.

As an improvement of the above scheme, the water collecting hole is formed below the middle rectifying block, the rectifying chamber further comprises 2 symmetrically-arranged water collecting areas, the water collecting areas are respectively arranged at two corners of one end of the water collecting hole, which are close to the rectifying chamber, of the lower left rectifying block and one side, which is close to the water collecting hole, of the lower right rectifying block are respectively provided with a lower left side surface and a lower right side surface, the lower left side surface and the lower right side surface are inclined from top to bottom towards the direction far away from the water collecting hole, and the lower left side surface and the lower right side surface respectively form the water collecting areas with the side wall of the rectifying chamber.

As an improvement of the scheme, the water gathering hole is gradually expanded from top to bottom, the outlet cross-sectional area of the water gathering hole is larger than the inlet cross-sectional area of the water gathering hole, and the longitudinal section of the water gathering hole is in a shape like a Chinese character 'ba'.

As an improvement of the above scheme, the water outlet housing further includes a lower water outlet cavity, the lower water outlet cavity is located below the upper water outlet cavity and is communicated with the upper water outlet cavity, the lower water outlet cavity is cylindrical, the tail end of the lower water outlet cavity is spherical, and the water outlet is arranged at the tail end of the lower water outlet cavity.

As an improvement of the above scheme, the water outlet housing further comprises a water outlet groove, the water outlet groove is provided with a flow guide surface, the flow guide surface is connected with the water outlet, the flow guide surface gradually expands from the water outlet to the outer side of the water outlet, the flow guide surface is an inwards concave arc surface, and the longitudinal section of the water outlet groove is in a shape of a Chinese character 'ba'.

The implementation of the invention has the following beneficial effects:

the flaky particle water shower head is provided with a water inlet shell, a water outlet shell and a rectifying module, water enters from the water inlet shell and is sprayed out from the water outlet shell, the rectifying module is arranged in the water outlet shell and comprises a rectifying part, a rectifying cavity is arranged in the rectifying part, a plurality of rectifying blocks and a plurality of rectifying channels are arranged in the rectifying cavity, water flow can pass through the rectifying cavity after entering from the water outlet shell, the water flow can collide with the rectifying blocks and then is divided by the rectifying channels, particles of the water flow can be more and more dense after multiple collisions, the water flow can be gathered again in a water gathering hole of the rectifying cavity after being divided by the rectifying channels and sprayed out from the water outlet, and the gathered water flow can be pressurized, so that the spraying impact force is improved, and fine particle water spray is combined, can obtain better massage effect.

In addition, the flaky granular water sprinkler is free of moving parts, the bottom of the water outlet shell is also provided with the water outlet groove, the flow guide surface is gradually enlarged from the water outlet to the outer side of the water outlet, the longitudinal section of the water outlet groove is in a shape of Chinese character 'ba', the water outlet groove can effectively avoid blockage, and meanwhile, the cleaning difficulty is reduced, so that the flaky granular water sprinkler can stably and reliably operate.

Drawings

FIG. 1 is a schematic view of a first embodiment of a plate-shaped particle shower head in a disassembled structure at an upper view angle;

FIG. 2 is a schematic side view of the first embodiment of the plate-shaped particle shower head of the present invention;

FIG. 3 is a partial view of A in FIG. 2;

FIG. 4 is a schematic cross-sectional view of a first embodiment of the plate-like particle shower head of the present invention;

FIG. 5 is a schematic structural diagram of a first embodiment of a rectifier module of the present invention;

fig. 6 is a schematic structural diagram of a second embodiment of a rectifier module of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be described in further detail with reference to the accompanying drawings. It is only noted that the invention is intended to be limited to the specific forms set forth herein, including any reference to the drawings, as well as any other specific forms of embodiments of the invention.

Referring to fig. 1, 2 and 3, a first embodiment of the present invention discloses a flaky particle water sprinkler, which includes a water inlet housing 1 and a water outlet housing 2, wherein the water inlet housing 1 is provided with a water inlet 11, the water outlet housing 2 is provided with a water outlet 21 and an upper water outlet cavity 22, the water inlet 11 is communicated with the water outlet 21 through the upper water outlet cavity 22, water enters the water inlet 11 and then continues to enter the upper water outlet cavity 22, the water inlet housing 1 is hermetically connected with the water outlet housing 2, and water can enter the water inlet housing 1 from the water inlet 11 and be sprayed out from the water outlet 21.

In order to pressurize the water flow and spray the granular water with large granules, the flaky granular water sprinkler further comprises a rectification module 3, the rectification module 3 is disposed in the upper water outlet cavity 22, in this embodiment, the rectification module 3 is plural, the plural rectification modules 3 are circumferentially distributed in the water outlet housing 2, the rectification module 3 comprises a rectification member 31, a water dispersion opening 311 is disposed at one end of the rectification member 31 close to the water inlet 11, the water flow can enter the rectification member 31 from the water dispersion opening 311, a water collection hole 312 is disposed at one end of the rectification member 31 close to the water outlet 21, the water flow can be sprayed out from the water collection hole 312 and reach the water outlet 21, the rectification member 31 is provided with 2

rectification cavities

313, 2 rectification cavities 313 are respectively disposed at two opposite sides of the rectification member 31, and water can enter the rectification cavity 313 from the water dispersion opening 311, the water dispersion opening 311 can divide water into two parts, which enter the rectification cavities 313 on both sides of the rectification member 31, where the water flow is divided by the upper part.

Be equipped with a plurality of rectification pieces 32 in rectification chamber 313, rectification piece 32 protrusion in the inner wall of rectification chamber 313 is a plurality of form a plurality of rectification passageways 33 between the rectification piece 32, rivers pass through during rectification passageway 33, rectification piece 32 can disturb the advancing direction of rivers and make rivers produce the collision, rivers and a plurality of the collision of rectification piece 32 and along the wall of rectification piece 32 carries out reposition of redundant personnel many times, and rivers after the reposition of redundant personnel get into each among the rectification passageway 33, and last rivers are in gather and produce the collision again in the water hole 312. In the multiple collision, the more the granules of water divide more and more, at last when water hole 312 gathers assembles, because the cross section size of water scattering mouth 311 is greater than the cross section size of water hole 312 gathers, water hole 312 with delivery port 21 intercommunication is followed water scattering mouth 311 gets into water hole 312 gathers is equivalent to the feedwater stream pressurization to improve impact range and impact distance when rivers spout, finally form the granule water that the granule is more, the impact force is stronger, have better massage effect.

The first embodiment of the invention has the following beneficial effects:

the flake particle water sprinkler in the first embodiment of the invention is provided with a water inlet shell 1, a water outlet shell 2 and a rectification module 3, water enters from the water inlet shell 1 and is sprayed out from the water outlet shell 2, the rectification module 3 is arranged in the water outlet shell 2, the rectification module 3 comprises a rectification piece 31, a rectification cavity 313 is arranged in the rectification piece 31, a plurality of rectification blocks 32 and a plurality of rectification channels 33 are arranged in the rectification cavity 313, the water flow can pass through the rectification cavity 313 after entering from the water outlet shell 2, the water flow can collide with the rectification blocks 32 and then is divided by the rectification channels 33, after multiple collisions, particles of the water flow can be more and more dense, the water flow can be gathered in the water gathering holes 312 of the rectification cavity 313 again after being divided by the rectification channels 33 and sprayed out from the water outlet 21, and the gathered water flow can be pressurized, therefore, the jet impact force is improved, the jet range is expanded, and a better massage effect can be obtained.

Referring to fig. 4, in order to form the sheet-shaped splash, the water outlet housing 2 further includes a water outlet groove 24, the water outlet groove 24 is provided with a flow guide surface 241, the flow guide surface 241 is connected to the water outlet 21, when the water is sprayed out from the water outlet 21, a part of the water flow is sprayed out along the flow guide surface 241 due to the action of surface tension, the flow guide surface 241 is gradually enlarged from the water outlet 21 to the outer side of the water outlet 21, the flow guide surface 241 is an inwardly concave arc surface, and the longitudinal section of the water outlet groove 24 is in a shape of "eight", so that the water flow is sprayed out along the flow guide surface 241 to form the sheet-shaped splash which is gradually enlarged from the water outlet 21, which not only forms a better visual effect, but also enlarges the spraying range, and can achieve a better water flow massage effect by matching with the splash with higher granularity.

Specifically, referring to fig. 5, the flow straightener 31 further includes a dividing plate 314, the dividing plate 314 is disposed in the middle of the flow straightener 31, and the flow straightening cavities 313 are disposed on two opposite sides of the dividing plate 314, so that the dividing plate 314 can divide the water dispersing opening 311 into two parts corresponding to the 2 flow straightening cavities 313, when water enters from the water dispersing opening 311, the water is divided into two parts by the dividing plate 314, and the two parts of water enter the two flow straightening cavities 313, so as to achieve a primary dividing effect. The rectifying module 3 includes a plurality of upper rectifying blocks 321, in one rectifying cavity 313, the plurality of upper rectifying blocks 321 are uniformly arranged on the water dispersion opening 311, an upper rectifying passage 331 is formed by a gap between two adjacent upper rectifying blocks 321, and because a side wall surface of the upper rectifying block 321 is a circular arc surface, water can enter the upper rectifying passage 331 from the side wall surface of the upper rectifying block 321, and water flow continues to flow into the rectifying cavity 313 from the upper rectifying passage 331. Since the number of the upper rectifying blocks 321 is plural and the number of the upper rectifying passages 331 is also plural, after the water flow is divided by the dividing plate 314, the water flow is divided into a plurality of water flows by the plural upper rectifying blocks 321 again, and the water flow is further dispersed. In addition, in the sidewall of the upper rectifying block 321, the water flow passes through to generate sharp point separation, and the separated water flow generates a vortex downstream of the upper rectifying block 321, so that the water flow can generate violent collision in a downstream region to further break up the water flow passing through the upper rectifying passage 331.

The rectifying module 3 further comprises a left side rectifying block 322 and a right side rectifying block 323 which are symmetrically arranged, the left side rectifying block 322 and the right side rectifying block 323 are respectively arranged at two sides of the middle part of the rectifying cavity 313 and are located below the upper rectifying block 321, the side wall surfaces of the left side rectifying block 322 and the right side rectifying block 323 are both arc surfaces, the side wall of the left side rectifying block 322 and the side wall of the rectifying cavity 313 form a left side rectifying channel 332, the side wall of the right side rectifying block 323 and the side wall of the rectifying cavity 313 form a right side rectifying channel 333, a gap between the left side rectifying block 322 and the right side rectifying block 323 forms a middle side rectifying channel 334, the left side rectifying block 322 and the right side rectifying block 323 can form 3 channels, and water flows through a plurality of parts of the upper rectifying block 321 to be divided, a part of the water flow is converged and collided at the side left rectifying passage 332, a part of the water flow is converged and collided at the side right rectifying passage 333, and the remaining water flow is converged and collided at the side middle rectifying passage 334, and the collided water flow generates more particles. The side left rectifying block 322 and the side right rectifying block 323 gradually approach to the side walls on two sides of the rectifying cavity 313 from top to bottom respectively, the combined longitudinal section of the side left rectifying block 322 and the side right rectifying block 323 is in a shape of Chinese character 'ba', and the arc-shaped side wall surfaces of the side left rectifying block 322 and the side right rectifying block 323 are matched, so that the water flow can be further guided to the middle lower part of the rectifying cavity 313. The water flow passes through the lateral left rectifying block 322 and the turbulent flow of the lateral right rectifying block 323, and then can enter the lateral left rectifying channel 332, the lateral right rectifying channel 333 and the lateral middle rectifying channel 334 by being divided by the upper turbulent flow rectifying channel 33.

The rectifier module 3 further comprises a middle rectifier block 324, the middle rectifier block 324 is located below the rectifier channels 334 in the side portions, the water flow coming out of the rectifier channels 334 in the side portions will flow through the

middle rectifier block

324, 2 side surfaces of the middle rectifying block 324 are inclined surfaces which are symmetrically arranged and respectively form a middle left rectifying channel 335 and a middle right rectifying channel 336 with the side left rectifying block 322 and the side right rectifying block 323, after water flows through the disturbed flow of the middle rectifying block 324, can follow rectifying channel 334 reposition of redundant personnel gets into middle part left rectifying channel 335 with middle part right rectifying channel 336, up to this point the water current of flowing through rectifying chamber 313 middle part can with middle part rectifying block 324 bumps once more and produces the granule, and the water current is shunted by middle part left rectifying channel 335 and middle part right rectifying channel 336, further breaks up the water current after the collision.

Referring to fig. 6, the present invention further discloses a second embodiment, which is different from the first embodiment in that, in the second embodiment, a plurality of rows of the upper baffle blocks 321 are provided on the rectifying member 31, the upper baffle blocks 321 in the first row are transversely arranged on the water dispersing port 311 in the same manner as the upper baffle blocks 321 in the first embodiment, water can enter the rectifying member 31 from the upper baffle blocks 321, while in the second embodiment, the upper baffle blocks 321 are not provided with the side left baffle blocks 322, the side right baffle blocks 323 and the middle baffle blocks 324, but instead, a plurality of rows of the upper baffle blocks 321 are arranged sequentially downward along the upper baffle blocks 321 in the first row, and a gap between two adjacent upper baffle blocks 321 in each row can form the upper baffle channel 331, so that the upper baffle channel 331 also has a plurality of rows, a plurality of rows of the upper baffle blocks 321 are arranged in the middle and the upper part of the rectifying

chamber

313, and 2 adjacent rows of the upper baffle blocks 321 are staggered, that is, the upper baffle block 321 in the next row is arranged below the upper baffle channel 331 in the previous row. Set up the multirow upper portion vortex piece 321 also has better rectification, vortex effect, and water is from first line upper portion vortex passageway 331 gets into after down can with the second line upper portion vortex piece 321 bumps, by the second line upper portion vortex passageway 331 divides, and rivers after dividing continue down can with the third line upper portion vortex piece 321 bumps, and by the third line upper portion vortex passageway 331 divides … … so on, rivers are in the multirow upper portion vortex piece 321 with can obtain more abundant collision effect in the upper portion vortex passageway 331, and rivers after the collision help producing more granule to further break up rivers, increase the rivers granule.

In order to continuously break up the water flow on both sides of the rectifying cavity 313, the rectifying module 3 further includes a lower left rectifying block 325 and a lower right rectifying block 326, the lower left rectifying block 325 and the lower right rectifying block 326 are respectively connected to the side walls on both sides of the rectifying cavity 313, the lower left rectifying block 325 and the lower right rectifying block 326 are respectively located below the side left rectifying block 322 and the side right rectifying block 323, the lower left rectifying block 325 and the lower right rectifying block 326 are both protruded toward the central axis of the rectifying cavity 313, and the side walls of the lower left rectifying block 325 and the lower right rectifying block 326 and the side walls of the side left rectifying block 322 and the side right rectifying block 323 respectively enclose a lower left rectifying channel 337 and a lower right rectifying channel 338. The water flow rushing out of the side left rectifying channel 332 and the side right rectifying channel 333 collides with the side walls of the lower left rectifying block 325 and the lower right rectifying block 326, respectively, and the collided water flow generates more particles, and then the water flow enters the lower left rectifying channel 337 and the lower right rectifying channel 338 along the convex side walls of the lower left rectifying block 325 and the lower right rectifying block 326, respectively. The lower left rectifying channel 337 and the lower right rectifying channel 338 are perpendicular to the side walls of the two sides of the rectifying cavity 313, and can guide water flow to gather towards the middle.

The water gathering hole 312 is arranged below the middle rectifying block 324, the rectifying cavity 313 further comprises 2 symmetrically arranged water gathering areas 3131, the water gathering areas 3131 are respectively arranged at two corners of one end of the rectifying cavity 313 close to the water gathering hole 312, one sides of the lower left rectifying block 325 and the lower right rectifying block 326 close to the water gathering hole 312 are respectively provided with a lower left side surface 3251 and a lower right side surface 3261, the lower left side surface 3251 and the lower right side surface 3261 are inclined towards the direction far away from the water gathering hole 312 from top to bottom, and the lower left side surface 3251 and the lower right side surface 3261 respectively form the water gathering area 3131 with the side wall of the rectifying cavity 313. The water rushing out of the lower left rectifying channel 337 and the lower right rectifying channel 338 is guided into the water collection zone 3131 by the lower left side face 3251 and the lower right side face 3261, and the water flow is easily swirled in the water collection zone 3131 due to the separation of the water flow by the sharp points in the lower left rectifying block 325 and the lower right rectifying block 326, thereby further breaking up the water flow of the lower left side face 3251 and the lower right side face 3261, while the water flow from the middle left rectifying channel 335 and the middle right rectifying channel 336 collides with the water flow rushing out of the lower left rectifying channel 337 and the lower right rectifying channel 338, further exacerbating the collision of the water flow in the water collection zone 3131, and further increasing the particle splash.

The water flow collided after being converged finally flows out from the water gathering holes 312, and the water flow rushes out from the water gathering holes 312 because the water gathering holes 312 are smaller, which is equivalent to pressurizing the water flow. And as the water gathering hole 312 gradually expands from top to bottom, the outlet cross-sectional area of the water gathering hole 312 is larger than the inlet cross-sectional area of the water gathering hole 312, the longitudinal section of the water gathering hole 312 is in a shape of a Chinese character 'ba', and under the action of surface tension, water flow can expand along the side wall of the water gathering hole 312 and diffuse from two sides. The water outlet housing 2 further comprises a lower water outlet cavity 23, and the lower water outlet cavity 23 is located below the upper water outlet cavity 22 and is communicated with the upper water outlet cavity 22. Before entering the lower water outlet cavity 23, because the rectifying cavity 313 is arranged on two sides of the rectifying block 32, and the water collecting holes 312 are arranged at the bottoms of the rectifying cavity 313 on two sides, the water is finally concentrated in the water collecting holes 312, and is converged with the water flushed from the water collecting holes 312 on the other side, and is diffused and sprayed out to the lower water outlet cavity 23 from two sides. Go out the water cavity 23 down and be the cylinder, the end that goes out the water cavity 23 down is spherical, delivery port 21 is located go out the end of water cavity 23 down, rivers finally can go out to take place rotation, collision once more in the water cavity 23 down, further improved the granularity of rivers, later rivers are followed delivery port 21 blowout, delivery port 21 further pressurizes rivers, has improved the impact force of rivers, makes impact distance and impact range enlarge to use experience has been promoted and has been experienced the sense.

The foregoing is a preferred embodiment of the present invention, and it should be noted that modifications and embellishments could be made by those skilled in the art without departing from the principle of the present invention, and these modifications and embellishments are also regarded as the scope of the present invention.

Claims

1. The flaky particle water shower head is characterized by comprising a water inlet shell and a water outlet shell, wherein the water inlet shell is provided with a water inlet, the water outlet shell is internally provided with a water outlet and an upper water outlet cavity, the water inlet is communicated with the water outlet through the upper water outlet cavity, and water can enter from the water inlet and is sprayed out from the water outlet;

2. The flaky particle water sprinkler as claimed in claim 1, wherein the flow straightener further comprises a flow distribution plate, the flow distribution plate is disposed in the middle of the flow straightener, the flow straightening cavities are respectively disposed on two opposite sides of the flow distribution plate, and the flow distribution plate can divide the water dispersing port into two parts corresponding to 2 flow straightening cavities respectively.

3. The plate-like granular sprinkler according to claim 1, wherein the rectifying module comprises a plurality of upper rectifying blocks, the upper rectifying blocks are uniformly arranged on the water dispersing port, a gap between two adjacent upper rectifying blocks forms an upper rectifying channel, the side wall surface of each upper rectifying block is a circular arc surface, and water can enter the upper rectifying channel from the side wall surface of each upper rectifying block.

4. The plate-like particle water sprinkler of claim 3, wherein the upper rectification blocks are divided into a plurality of rows, the upper rectification blocks are arranged in the middle and upper portions of the rectification chamber, the upper rectification blocks of adjacent 2 rows are staggered, a gap between two adjacent upper rectification blocks in each row can form the upper rectification channel, and the upper rectification block of a next row is disposed below the upper rectification channel of a previous row.

5. The flaky grain water sprinkler of claim 3, wherein the rectification module further comprises a left side rectification block and a right side rectification block which are symmetrically arranged, the left side rectification block and the right side rectification block are respectively arranged at two sides of the middle part of the rectification cavity and are positioned below the upper rectification block, the side wall surfaces of the left side rectification block and the right side rectification block are both arc surfaces, the side wall of the left side rectification block and the side wall of the rectification cavity form a left side rectification channel, the side wall of the right side rectification block and the side wall of the rectification cavity form a right side rectification channel, and a gap between the left side rectification block and the right side rectification block forms a middle side rectification channel.

6. The flaky particle shower head as claimed in claim 5, wherein the left and right side rectifying blocks are gradually close to the side walls of the rectifying cavity from top to bottom, the combined longitudinal section of the left and right side rectifying blocks is splayed, and water can be divided into the left and right side rectifying channels and the middle rectifying channel from the upper rectifying channel after passing through the turbulent flow of the left and right side rectifying blocks.

7. The flaky particle shower head as claimed in claim 3, wherein the rectification module further comprises a middle rectification block, the middle rectification block is located below the rectification channel in the side part, 2 sides of the middle rectification block are symmetrically arranged inclined planes and respectively enclose a left rectification channel and a right rectification channel with the left rectification block and the right rectification block, and water can be shunted into the left rectification channel and the right rectification channel from the middle rectification channel after passing through the disturbed flow of the middle rectification block.

8. The flaky grain shower head as claimed in claim 1, wherein the rectification module further comprises a left lower rectification block and a right lower rectification block, the left lower rectification block and the right lower rectification block are respectively connected with the side walls at two sides of the rectification cavity, the left lower rectification block and the right lower rectification block are both protruded towards the direction of the central axis of the rectification cavity, and the side walls of the left lower rectification block and the right lower rectification block respectively enclose a left lower rectification channel and a right lower rectification channel with the side walls of the left side rectification block and the right side rectification block.

9. The flaky particle water sprinkler as claimed in claim 8, wherein the water gathering hole is formed below the middle rectifying block, the rectifying chamber further comprises 2 symmetrically arranged water gathering regions, the water gathering regions are respectively formed in two corners of one end of the water gathering hole, the lower left rectifying block and one side of the lower right rectifying block close to the water gathering hole are respectively provided with a lower left side surface and a lower right side surface, the lower left side surface and the lower right side surface are inclined from top to bottom towards the direction far away from the water gathering hole, and the lower left side surface and the lower right side surface respectively form the water gathering regions with the side wall of the rectifying chamber.

10. The flaky particle water sprinkler as claimed in claim 1, wherein the water collecting hole is gradually expanded from top to bottom, the outlet cross-sectional area of the water collecting hole is larger than the inlet cross-sectional area of the water collecting hole, and the longitudinal section of the water collecting hole is in a shape of a Chinese character 'ba'.

11. The flaky particle water sprinkler as claimed in claim 1, wherein the water outlet housing further comprises a lower water outlet cavity, the lower water outlet cavity is located below the upper water outlet cavity and is communicated with the upper water outlet cavity, the lower water outlet cavity is cylindrical, the tail end of the lower water outlet cavity is spherical, and the water outlet is arranged at the tail end of the lower water outlet cavity.

12. The flaky particle water sprinkler as claimed in claim 1, wherein the water outlet housing further comprises a water outlet groove, the water outlet groove is provided with a flow guiding surface, the flow guiding surface is connected with the water outlet, the flow guiding surface gradually enlarges from the water outlet to the outer side of the water outlet, the flow guiding surface is an inwards concave arc surface, and the longitudinal section of the water outlet groove is in a shape of Chinese character 'ba'.