KR200499660Y1 - Faucet head with water splash prevention function - Google Patents

Abstract

The present disclosure relates to a water faucet head having a water splash prevention function, comprising: a head body; a guide body installed inside the head body, wherein a first flow space for spraying water and a second flow space for direct water spraying are formed, and wherein a plurality of water passage holes are provided to communicate with each of the first flow space and the second flow space; a flow control cover disposed in the first flow space to slow down the linear motion in the direction of fluid flow; and an air trap disposed outside the flow control cover in the first flow space to form a water film to suppress air mixing.

Description

Faucet head with water splash prevention function

Embodiments of the present invention relate to a water jet head, which can selectively perform spray jetting and direct jetting, and has a structure that effectively controls the flow of fluid so as to prevent water splashing during spray jetting.

Typically, faucet heads are designed to allow users to choose between direct or spray jets, depending on their needs, in kitchens, bathrooms, and other locations. These faucet heads essentially include a nozzle section through which fluid is ejected. Direct jets discharge fluid at a constant flow rate and pressure, while spray jets spray multiple small jets to clean a wide area.

However, when using a spray nozzle with a conventional faucet head, problems can arise, such as irregular water droplet formation due to air mixing within the fluid, or excessive water splashing due to high flow rates. This is particularly true when users are washing dishes at a sink or washbasin, where excessive water splashing can create an uncomfortable work environment and potentially contaminate the surrounding area.

Embodiments of the present disclosure are intended to provide a deep learning-based water head that improves the problems of the aforementioned water head, and to provide a water head that can effectively prevent water splashing when spraying water.

The technical problems to be achieved in the embodiments of the present disclosure are not limited to those mentioned above, and other technical problems not mentioned can be considered by a person having ordinary skill in the art from the various embodiments described below.

According to one embodiment of the present disclosure, a water faucet head having a water splash prevention function is provided, comprising: a head body; a guide body installed inside the head body, wherein a first flow space for spraying water and a second flow space for direct water jetting are formed, and wherein a plurality of water passage holes are provided to communicate with each of the first flow space and the second flow space; a flow control cover disposed in the first flow space to slow down the linear motion in the direction of fluid flow; and an air trap disposed outside the flow control cover in the first flow space to form a water film to suppress air mixing.

The above air trap has at least one water passage opening formed along the central axis of the air trap, and a mesh net forming a water film may be arranged in each of the at least one water passage openings.

The surface of the flow control cover is provided with at least one supporting protrusion that is inserted corresponding to each of the at least one water passage openings, and each of the at least one supporting protrusion includes a first protrusion member and a second protrusion member that are spaced apart from each other, and the first protrusion member can be inserted so as to face one side of the water passage opening, and the second protrusion member can be inserted so as to face the other side of the water passage opening.

The at least one water passage opening may be composed of a plurality of water passage openings spaced apart along the circumferential direction of the air trap, and the at least one supporting protrusion may be composed of a plurality of supporting protrusions spaced apart along the circumferential direction of the flow control cover, and on the surface of the flow control cover, the first protrusion member of each of the supporting protrusions may be arranged to face the inner surface of the corresponding water passage opening, and the second protrusion member of each of the supporting protrusions may be arranged to face the outer surface of the corresponding water passage opening.

The above flow control cover is arranged to be movable along the central axis direction within the guide body, and when fluid flows in the first flow space, the flow control cover can pressurize the air trap by coming into close contact with it.

The first flow space is formed as a hollow double-wall structure having an inner wall and an outer wall, and among the plurality of passage holes, a first passage hole communicating with the first flow space is eccentrically arranged radially outward from the central axis of the guide body, and when fluid flows into the first flow space through the first passage hole, a vortex flow of the fluid can be induced within the first flow space.

According to an embodiment of the present invention, a technical effect can be provided that can effectively prevent water splashing when spraying water.

In addition, according to an embodiment of the present invention, by applying a structure including a flow control cover and an air trap, mixing with air is minimized when the fluid is sprayed in a spray manner, thereby maintaining the size and flow rate of the water droplets constant and suppressing the occurrence of irregular water splashing.

In addition, according to an embodiment of the present invention, when spraying water, the flow control cover is configured to be pressed against the air trap by the pressure of the fluid, thereby maintaining the formation of a water film in the air trap more stably, and the quality of the spray water can be improved by inducing the water to flow in a certain direction.

The accompanying drawings, which are included as part of the detailed description to aid understanding of the embodiments, provide various embodiments and, together with the detailed description, describe technical features of the various embodiments.
FIG. 1 is a schematic drawing of a faucet equipped with a faucet head according to one embodiment of the present disclosure.
Figure 2 is an exploded perspective view of a water head according to one embodiment of the present disclosure.
Fig. 3 is a bottom perspective view of the guide body included in the water head illustrated in Fig. 2.
Fig. 4 is a drawing showing the internal structure of the head body included in the water head illustrated in Fig. 2.
Figure 5 is an enlarged exploded perspective view of the guide body, flow control cover, and air trap included in the water head illustrated in Figure 2.
FIG. 6 is a cross-sectional view showing the fluid flow pattern of the first discharge mode of the water head according to one embodiment of the present disclosure.
Figure 7 is a drawing showing a state in which the second discharge mode water hole of the guide body is blocked in the first discharge mode illustrated in Figure 6.
FIG. 8 is a cross-sectional view showing the fluid flow pattern of the second discharge mode of the water head according to one embodiment of the present disclosure.
Figure 9 is a photograph showing the water splashing phenomenon when using a conventional water head.
FIG. 10 is a photograph showing the water splash prevention effect when using a water head according to one embodiment of the present disclosure.

Hereinafter, specific embodiments of the present disclosure will be described with reference to the drawings. However, these are merely examples, and the present disclosure is not limited thereto.

In describing this disclosure, detailed descriptions of known technologies related to this disclosure will be omitted if they are deemed to unnecessarily obscure the gist of this disclosure. Furthermore, the terms described below are defined based on their functions in this disclosure and may vary depending on the intent or custom of the user or operator. Therefore, their definitions should be based on the overall content of this specification.

The technical idea of the present disclosure is determined by the claims, and the following examples are merely a means for efficiently explaining the technical idea of the present disclosure to a person having ordinary skill in the art to which the present disclosure belongs.

FIG. 1 is a schematic diagram showing a faucet equipped with a faucet head (10) according to one embodiment of the present disclosure, FIG. 2 is an exploded perspective view of a faucet head (10) according to one embodiment of the present disclosure, FIG. 3 is a bottom perspective view of a guide body (200) included in the faucet head (10) shown in FIG. 2, FIG. 4 is a diagram showing the internal structure of a head body (100) included in the faucet head (10) shown in FIG. 2, FIG. 5 is an enlarged exploded perspective view of a guide body (200), a flow control cover (300), and an air trap (400) included in the faucet head (10) shown in FIG. 2, FIG. 6 is a cross-sectional view showing a fluid flow state of a first discharge mode of a faucet head (10) according to one embodiment of the present disclosure, and FIG. 7 is a cross-sectional view showing a second discharge mode of a guide body (200) in the first discharge mode shown in FIG. 6. This is a drawing showing a state in which a water hole (232) is blocked, and FIG. 8 is a cross-sectional view showing a fluid flow state of a second discharge mode of a water head (10) according to one embodiment of the present disclosure.

Referring to FIGS. 1 to 8, a water head (10) according to one embodiment of the present invention can be connected to a conventional water body and used, and a mixed water of hot water and/or cold water supplied to the water body can be supplied to the water head (10) and discharged to the outside.

A water head (10) according to one embodiment of the present invention may be configured to be capable of discharging water in either a first discharging mode of a spray-type discharging method or a second discharging mode of a direct discharging method via an aerator (700). To this end, the water head (10) may include a head body (100), a guide body (200), a flow control cover (300), an air trap (400), and a nozzle switching unit (610) installed therein.

The head body (100) may include a receiving housing (110) and a switching switch (120). The receiving housing (110) may be formed hollow so that the guide body (200), the flow control cover (300), the air trap (400), and the nozzle switching unit (610) can be accommodated therein, and a switching switch (120) may be coupled to one side of the receiving housing (110). The switching switch (120) may perform a function of switching between the first spray mode and the second spray mode according to a user's operation.

The changeover switch (120) may include a changeover projection (121) that protrudes inwardly through the side wall of the receiving housing (110), and may be rotated at a preset angle as the user operates the changeover switch (120). Preferably, the changeover switch (120) may be positioned in a first position where one end is pressed and inserted or in a second position where the other end is pressed and inserted as the user presses and applies pressure.

A switching ball (620) that selectively blocks one of the plurality of water passage holes (231, 232) of the guide body (200), a spring member (630) that presses the switching ball (620) toward the guide body (200), and a nozzle switching unit (610) that accommodates and supports the switching ball (620) and the spring member (630) may be arranged within the receiving housing (110). The nozzle switching unit (610) may be configured to rotate within a preset angle range when the position of the switching switch (120) is changed, thereby changing the position of the switching ball (620) that blocks the water passage holes (231, 232).

The nozzle switching unit (610) may include a rotation shaft (611) coupled to the switching protrusion (121) of the switching switch (120), a ball receiving portion (612) that receives a spring member (630) and a switching ball (620), and a rotation connection portion (613) that connects the rotation shaft (611) and the ball receiving portion (612). The ball receiving portion (612) may be formed in a hollow cylindrical shape with one end open, and the spring member (630) may be received in the ball receiving portion (612) and supported on the other end of the ball receiving portion (612). The switching ball (620) may be arranged so that a portion is exposed through the open end of the ball receiving portion (612), and may be supported by being pressed outwardly from the ball receiving portion (612) by the spring member (630).

The rotation shaft (611) and the ball receiving portion (612) can be formed to have a predetermined length along the height direction of the receiving housing (110), and the rotation connecting portion (613) can connect the upper portions of the rotation shaft (611) and the ball receiving portion (612). The rotation shaft (611) can be inserted or fitted into the switching protrusion (121) so that the two parts interfere with each other and operate as one unit.

A cylindrical rotation guide (111) extending along the height direction of the rotation housing (110) (the direction of the central axis of the guide body (200)) may be arranged within the receiving housing (110). A rotation shaft (611) may be inserted into and supported by the rotation guide (111), and a rotation connection part (613) may be arranged in contact with the upper end of the rotation guide (111).

When the position of the switching switch (120) is changed by external manipulation, the nozzle switching unit (610) can be rotated by a predetermined angle around the rotation shaft (611) or the rotation guide (111), and accordingly, the water receiving unit (612) and the switching ball (620) can be moved in position to selectively shield the water passage holes (231, 232) formed in the guide body (200). That is, the plurality of water passage holes (231, 232) formed in the guide body (200) can be spaced apart along the rotation radius of the water receiving unit (612) or the switching ball (620).

For example, when the water head (10) operates in the first discharge mode, as illustrated in FIG. 6, the first discharge hole (231) can be opened to be in fluid communication with the inside of the receiving housing (110), and the fluid passing through the first discharge hole (231) can flow into the first flow port (251) and the first flow space (200a), pass through the guide body (200) and the air trap (400), and then be discharged in a spray manner. Meanwhile, as illustrated in FIG. 7, in the first discharge mode, the second discharge hole (232) can be shielded by the switching ball (620), and the fluid flow into the second flow space (200b) can be blocked.

When the water head (10) operates in the second discharge mode, as illustrated in Fig. 8, the first discharge hole (231) is shielded by the switching ball (620) and the second discharge hole (232) can be opened to be in fluid communication with the inside of the receiving housing (110). The fluid passing through the second discharge hole (232) can flow into the second flow port (261) and the second flow space (200b) and be discharged in a direct manner through the aerator (700).

Meanwhile, a fixing support wall (112) formed at a preset height along the height direction may be provided on the central side of the receiving housing (110), and a viewing portion (612) may be fixed on the fixing support wall (112). By being supported by the fixing support wall (112), the viewing portion (612) can be stably rotated and moved at a preset height inside the receiving housing (110).

According to one embodiment of the present invention, the water head (10) has a structure as described above, so that the user can conveniently switch between the first water spray mode (spray spray) and the second water spray mode (direct water spray) simply by operating the changeover switch (120).

As described above, a water head (10) according to one embodiment of the present invention may include a head body (100) and a guide body (200) installed therein. The guide body (200) forms a first flow space (200a) for spraying water and a second flow space (200b) for direct water jetting, and a plurality of water passage holes (231, 232) communicating with each of the first flow space (200a) and the second flow space (200b) may be provided in the guide body (200). A flow control cover (300) may be arranged in the first flow space (200a) within the guide body (200), and this may be configured to slow down the linear motion in the fluid flow direction. In addition, an air trap (400) may be placed on the outside of the flow control cover (300) within the first flow space (200a), which suppresses air mixing to form a water film, thereby preventing water splashing.

The guide body (200) may be formed to have a preset height along the central axis, and may be formed to have a structure having a partitioned double space. More specifically, the guide body (200) may include a first body part (210) arranged radially outer with respect to the central axis, and a second body part (220) arranged radially inner. Each of the first body part (210) and the second body part (220) may be formed to extend in the circumferential direction with respect to the central axis of the guide body (200), and the first body part (210) and the second body part (220) may be arranged coaxially.

The first flow space (200a) may be formed between the first body part (210) and the second body part (220), and the second flow space (200b) may be formed inside the second body part (220). That is, the first flow space (200a) may be formed in a hollow column shape having an inner wall (the second body part (220)) and an outer wall (the first body part (210)).

On the outer surface of the first body part (210), a plurality of sealing members (241, 242) spaced apart from each other along the direction of the central axis may be arranged. The plurality of sealing members (241, 242) may include a first sealing member (241) and a second sealing member (242), and a watertight structure between the guide body (200) mounted in the receiving housing (110) and the receiving housing (110) may be formed by the plurality of sealing members (241, 242).

The guide body (200) may further include a bottom member (230) facing the innermost bottom surface of the receiving housing (110), and the first body part (210) and the second body part (220) may be formed to extend perpendicularly from the bottom member (230). The bottom member (230) of the guide body (200) may be formed with a plurality of water passage holes (231, 232) described above. The plurality of water passage holes (231, 232) may be composed of a first water passage hole (231) in fluid communication with the first flow space (200a) and a second water passage hole (232) in fluid communication with the second flow space (200b).

In addition, a first water passage guide (250) protruding toward the radially outer side of the guide body (200) may be provided in a portion of the outer surface of the second body portion (220). The first water passage guide (250) may be formed in a plate shape and may be spaced apart from the bottom member (230) of the guide body (200) by a preset height, and a first fluid port (251) in fluid communication with the first water passage hole (231) may be formed between the first water passage guide (250) and the bottom member (230) of the guide body (200).

Meanwhile, a second water passage guide (260) protruding toward the central axis of the guide body (200) may be provided in a portion of the inner surface of the second body portion (220). The second water passage guide (260) may be formed in a plate shape and may be spaced apart from the bottom member (230) of the guide body (200) by a preset height, and a second fluid port (261) in fluid communication with the second water passage hole (232) may be formed between the second water passage guide (260) and the bottom member (230) of the guide body (200).

According to one embodiment of the present invention, the first water passage hole (231) may be eccentrically arranged radially outward from the central axis of the guide body (200). In addition, since the fluid flowing through the first flow port (251) is introduced toward the radially outward side of the first flow space (200a) by the first water passage guide (250), a vortex flow may be induced within the first flow space (200a). Through this, the fluid and air are separated, so that the bubble content in the fluid is reduced during spray discharge, and the water splashing phenomenon may be alleviated.

A cover housing (500) through which the fluid is ultimately discharged can be fastened to the receiving housing (110) of the head body (100). An aerator (700) can be received at the center of the cover housing (500), and a spray plate (510) for spraying water can be arranged along the circumferential direction on the radially outer side of the cover housing (500). The fluid flowing through the first flow space (200a), the guide body (200), and the air trap (400) can pass through the spray plate (510) and be discharged in a spray manner, and the fluid flowing through the second flow space (200b) can pass through the aerator (700) and be discharged in a direct manner.

The air trap (400) may have at least one water passage opening (410) formed along the central axis of the air trap (400), and a mesh net (450) forming a water film may be arranged in each of the at least one water passage openings (410).

Preferably, the air trap (400) may be formed in a plate shape having a predetermined thickness and may be provided with a plurality of water passage openings (410) spaced apart along its circumference. In addition, a mesh net (450) forming a water film is arranged in each of the plurality of water passage openings (410), thereby preventing excessive mixing of air when the fluid flows and inducing uniform distribution of water.

In FIGS. 2 and 5 of the present invention, the flow control cover (300) and the air trap (400) are shown as circular, but this is merely exemplary and is not necessarily limited thereto, and the flow control cover (300) and the air trap (400) may be formed in a triangular, square, or other polygonal shape.

For example, when the air trap (400) is formed in a circular shape, the individual water openings (410) can be formed in an arc shape, and when the air trap (400) is formed in a triangular or square polygonal shape, the individual water openings (410) can be formed in a folded shape having a preset range of angles.

Specifically, the air trap (400) may include a first trap body (420) positioned inwardly with respect to its central axis, a second trap body (430) positioned outwardly with respect to its central axis, and a connecting member (440) formed to extend radially from the air trap (400) to connect the first trap body (420) and the second trap body (430). A plurality of water passage openings (410) are formed between the first trap body (420) and the second trap body (430), and may be spaced apart from each other by being partitioned by the connecting member (440). The first trap body (420) may be formed to extend along the inner edge of the air trap (400), and the second trap body (430) may be formed to extend along the outer edge of the air trap (400).

At least one supporting protrusion (320) may be provided on the surface of the flow control cover (300) to be inserted into at least one water passage opening (410), respectively. Preferably, a plurality of supporting protrusions (320) spaced apart from each other may be provided on the surface of the flow control cover (300) along the circumferential direction thereof. Each supporting protrusion (320) may include a first protrusion member (321) and a second protrusion member (322) spaced apart from each other. The first protrusion member (321) may be inserted so as to face one side of the water passage opening (410), and the second protrusion member (322) may be inserted so as to face the other side of the water passage opening (410).

Preferably, the first protruding member (321) may be arranged radially inward relative to the central axis of the flow control cover (300), and the second protruding member (322) may be arranged radially outward relative to the central axis of the flow control cover (300). The first protruding member (321) may be arranged to face the radially inward surface within the corresponding water passage opening (410), and the second protruding member (322) may be arranged to face the radially outward surface within the corresponding water passage opening (410). Through this, the flow control cover (300) is stably supported by being in close contact with the air trap (400), and unnecessary vibration or displacement when the fluid flows can be prevented.

Specifically, the flow control cover (300) may further include a cover body (310) having a plate structure, a plurality of fixing support grooves (311) formed spaced apart along the circumferential direction on the cover body (310), a first turning guide part (330) formed extending in the circumferential direction on the radially outer side of the cover body (310), and a second turning guide part (340) formed extending in the circumferential direction on the radially inner side of the cover body (310).

The first protruding member (321) and the second protruding member (322) may be formed to protrude from the surface of the cover body (310) toward the air trap (400). The fixing support groove (311) may be formed to be recessed to a predetermined depth from the surface of the cover body (310) (the surface facing the air trap (400)).

The first turning guide section (330) and the second turning guide section (340) may each include at least one bending section, through which a multi-stage turning flow may be induced when the fluid flowing in the first flow space (200a) passes through the flow control cover (300). That is, the fluid changes direction at least twice while flowing along the first turning guide section (330) and the second turning guide section (340), thereby losing the straightness of the fluid and promoting the separation of air and fluid.

The first rotation guide member (330) may include a first-first guide member (331) extending horizontally radially outward on the same plane as the cover body (310), and a first-second guide member (332) extending perpendicularly along the central axis direction of the flow control cover (300) from the end of the first-first guide member (331). Both the first-first guide member (331) and the first-second guide member (332) may be formed along the circumferential direction of the cover body (310).

When the fluid flows into the flow control cover (300) from the first flow space (200a), it flows along the surface of the first-second guide member (332). The fluid, which had been flowing axially along the first-second guide member (332), changes direction again as it passes through the first-first guide member (331), and a second swirling flow may occur. At this time, since the first-first guide member (331) has a structure extending radially outward, it can induce the fluid to swirl at a certain angle when it flows in.

The second rotation guide member (340) may include a second-first guide member (341) extending perpendicularly along the central axis direction of the flow control cover (300) from the radially inner end of the cover body (310), and a second-second guide member (342) extending perpendicularly toward the radially inner side of the flow control cover (300) from the end of the second-first guide member (341). Both the second-first guide member (341) and the second-second guide member (342) may be formed along the circumferential direction of the cover body (310).

When the fluid flows from the first flow space (200a) to the flow control cover (300), it can flow while swirling along the surface of the second-second guide member (342). In this process, the flow direction of the fluid is naturally adjusted by the arrangement of the second-second guide member (342), the flow path of the fluid is lengthened, and the mixing of air can be suppressed.

The fluid flowing radially along the 2-2 guide member (342) changes direction again as it passes through the 2-1 guide member (342), and a second swirling flow may occur. At this time, since the 2-1 guide member (341) has a structure extending in the axial direction, the fluid can be guided to swirl at a certain angle when it flows in.

The end of the 2-2 induction member (342) can be positioned while maintaining a constant gap with the inner surface of the flow control cover (300), thereby allowing the fluid to flow while maintaining a constant flow rate and pressure.

As a result, the fluid loses its straightness by going through at least two or more swirling flows through the first swirl guide unit (330) and the second swirl guide unit (340), thereby minimizing the mixing of air within the fluid. In addition, the fluid is stably distributed within the flow control cover (300), and a constant flow rate and flow rate can be maintained during spraying, thereby preventing the phenomenon of water splashing.

The connecting member (440) of the air trap (400) described above can be inserted and supported in the anchoring support groove (311), and through this, the air trap (400) and the flow control cover (300) can be restricted from rotating by interfering with each other along the circumferential direction.

The inner circumference of the first body portion (210) of the above-described guide body (200) may be provided with a first mounting step (211) and a second mounting step (212), each of which is formed in a stepped manner. The second mounting step (212) may be arranged on the outer side in the discharge direction (i.e., on the opposite side of the bottom member (230)) of the first mounting step (211). The first mounting step (211) and the second mounting step (212) may be formed to extend along the inner circumferential direction of the first body portion (210), and the first mounting step (211) and the second mounting step (212) may be arranged to be spaced apart from each other along the axial direction of the guide body (200).

The first rotation guide part (330) of the above-described flow control cover (300), preferably the end of the first-second guide member (332), can be mounted on the first settling step (211). The second trap body (430) of the above-described air trap (400) can be mounted and fixed on the second settling step (212). The fluid flowing into the first flow space (200a) can be guided to the water passage opening (410) of the air trap (400) through the first rotation guide part (330) and the second trap body (430). In addition, the fluid flowing into the first flow space (200a) can be guided to the water passage opening (410) of the air trap (400) through the second rotation guide part (340) and the first trap body (420).

The fluid in the first flow space (200a) must be able to flow through the mesh net (450) provided in the water passage opening (410), and the fluid and air are separated by the water film formed on the surface of the mesh net (450), and the discharge of air bubbles contained in the fluid can be reduced. Through this, the splashing phenomenon of the sprayed fluid can be prevented.

The flow control cover (300) can be positioned so as to be movable a predetermined distance along the central axis direction within the guide body (200), and can be moved by the pressure of the fluid when the spray jet is supplied. More specifically, the flow control cover (300) is guided along the inner circumferential surface of the guide body (200), and can be configured so as to be movable in the axial direction of the guide body (200) according to a change in pressure when the fluid flows into the first flow space (200a).

The movement of the flow control cover (300) can play a role in controlling the flow of fluid within the guide body (200). When spray water is supplied, the flow control cover (300) moves toward the air trap (400) by the fluid pressure and can be pressurized to adhere closely to the air trap (400). Accordingly, the gap between the flow control cover (300) and the air trap (400) is minimized, and the fluid flows at a constant velocity and direction, so that a stable water film can be formed.

In this process, the flow control cover (300) can maintain uniform distribution of the fluid by controlling the flow rate and pressure during spraying, and can suppress mixing of air within the fluid. The water film formed by the flow control cover (300) being in close contact with the air trap (400) can prevent the inflow of external air and induce the fluid to be sprayed uniformly. This minimizes mixing of air, suppresses the formation of bubbles within the fluid, and maintains a constant size of water droplets during spraying.

As a result, the movement of the flow control cover (300) and the close contact with the air trap (400) can increase the stability of water film formation, prevent air mixing, and create an optimal spray jet environment, thereby minimizing water splashing. This can provide the user with a uniform and smooth spray jet function, and enhance convenience and efficiency in actual use environments.

A water faucet head (10) according to one embodiment of the present invention includes the above configuration, thereby suppressing air mixing and optimizing the flow characteristics of the fluid by using a flow control cover (300) and an air trap (400), thereby preventing water splashing when using the faucet and maximizing user convenience.

According to another embodiment of the present invention, a faucet (1) including a faucet head (10) according to one embodiment of the present invention described above can be provided.

Fig. 9 is a photograph showing a water splashing phenomenon when using a conventional water faucet head, and Fig. 10 is a photograph showing a water splashing prevention effect when using a water faucet head (10) according to one embodiment of the present disclosure.

As shown in Fig. 9, a faucet with a conventional head structure may cause water splashing when spraying water, which may cause inconveniences such as the user's clothes getting wet.

On the other hand, as disclosed in FIG. 10, a faucet to which a faucet head (10) according to one embodiment of the present invention is applied can greatly improve user convenience by reducing the phenomenon of water splashing even when spraying water.

Although the present disclosure has been described in detail above through representative examples, those skilled in the art will understand that various modifications can be made to the above-described embodiments without departing from the scope of the present disclosure. Therefore, the scope of the rights of the present disclosure should not be limited to the described embodiments, but should be determined not only by the utility model claims described below but also by equivalents of the utility model claims.

1: Susan
10: Susan Head
100: Head Body
110: Reception housing
111: Rotating guide
112: Support wall
120: Toggle switch
121: Transition protrusion
200: Guide body
200a: First fluid space
200b: Second fluid space
210: First body section
211: First anchorage step
212: Second anchorage step
220: Second body section
230: Bottom member
231: First Command Hall
232: Second Command Hall
241: First sealing member
242: Second sealing member
250: First Command Guide
251: First fluid
260: Second Command Guide
261: Second fluid channel
300: Flow control cover
310: Cover body
311: Anchoring support home
320: Support protrusion
321: First protruding member
322: Second protruding member
330: First turning guidance section
331: 1-1 Guide member
332: 1-2 Induction member
340: Second turning guidance section
341: 2-1 Guide member
342: 2-2 Induction member
400: Air Trap
410: Water opening
420: First Trap Body
430: Second Trap Body
440: Connecting member
450: Mesh
500: Cover Housing
510: Water sprinkler
610: Nozzle switching part
611: Rotating shaft
612: Viewable area
613: Rotating joint
620: Transition Ball
630: Spring member
700: Aerator
810: Spray plate packing
820: Water tank packing

Claims (6)

In a water faucet head equipped with a water splash prevention function,
Head body;
A guide body installed inside the head body, having a first flow space for spray jetting and a second flow space for direct jetting, and having a plurality of water passage holes provided to communicate with each of the first flow space and the second flow space;
A flow control cover arranged in the first flow space to slow down the linear motion in the fluid flow direction;
An air trap that is placed on the outside of the flow control cover in the first flow space and forms a water film to suppress air mixing.
Including,
The above flow control cover is arranged to be movable along the central axis direction within the above guide body,
A water head characterized in that when fluid flows in the first flow space, the flow control cover is pressed against the air trap to apply pressure.
delete In a water faucet head equipped with a water splash prevention function,
Head body;
A guide body installed inside the head body, having a first flow space for spray jetting and a second flow space for direct jetting, and having a plurality of water passage holes provided to communicate with each of the first flow space and the second flow space;
A flow control cover arranged in the first flow space to slow down the linear motion in the fluid flow direction;
An air trap that is placed on the outside of the flow control cover in the first flow space and forms a water film to suppress air mixing.
Including,
The above air trap has at least one water passage opening formed along the central axis of the air trap,
A mesh net forming a water curtain is arranged in each of the at least one water openings,
At least one supporting protrusion is provided on the surface of the above flow control cover to be inserted corresponding to each of the at least one water openings,
Each of the above at least one supporting protrusion includes a first protrusion member and a second protrusion member spaced apart from each other,
A water head characterized in that the first protruding member is inserted so as to face one side of the water outlet, and the second protruding member is inserted so as to face the other side of the water outlet.
In claim 3,
The at least one water outlet is composed of a plurality of water outlets spaced apart along the circumferential direction of the air trap,
The at least one support protrusion is composed of a plurality of support protrusions spaced apart along the circumferential direction of the flow control cover,
A water head characterized in that, on the surface of the flow control cover, the first protruding member of each of the supporting protrusions is arranged to face the inner surface of the corresponding water passage opening, and the second protruding member of each of the supporting protrusions is arranged to face the outer surface of the corresponding water passage opening.
delete In claim 1,
The above first fluid space is formed as a hollow double-wall structure having an inner wall and an outer wall,
Among the plurality of water passages, the first water passage hole communicating with the first flow space is eccentrically arranged radially outward from the central axis of the guide body,
A water head characterized in that when fluid is introduced into the first flow space through the first water hole, a vortex flow of the fluid is induced within the first flow space.