The present disclosure relates generally to a sprayer, and more particularly to a brushing sprayer.
Generally, a conventional sprayer for kitchen cleaning is usually only a nozzle connected to a faucet, which can only provide a single flushing function. Therefore, if a user needs other water outlet functions, the sprayer needs to be replaced by another sprayer, which causes inconvenience in use.
In addition, when cleaning relatively greasy tableware, the user usually needs to place the tableware under the sprayer, and washes the tableware with a tool such as a melon cloth or a brush at the same time. However, the sprayer cannot be adjusted according to the blind position of the tableware. Therefore, the user usually needs to rinse while brushing, which not only wastes time for washing the dishes, but also increases the waste of water.
At least for the above reasons, the conventional sprayer for rinsing still have room for improvements.
In view of the above, the primary objective of the present disclosure is to provide a brushing sprayer. The brushing sprayer provides multiple flushing functions, and includes a brushing head, so that the user could save time for washing the dishes, and could decrease the waste of water. Furthermore, the brushing sprayer is more convenient in use compared to conventional sprayers for kitchen cleaning.
The present disclosure provides a brushing sprayer. The brushing sprayer includes a pipe body, a diverter, a control assembly and a brushing head. The a pipe body increases an inlet end and an outlet opening, wherein the inlet end has an inlet opening, and the outlet end has a first outlet opening, a second outlet opening and a third outlet opening. The inlet opening, the first outlet opening, the second outlet opening and the third outlet opening communicate with each other. The diverter is positioned in the pipe body, and comprising a first flow way, a second flow way and a third flow way communicating with each other, wherein the first flow way, the second flow way and the third flow way communicate with the inlet opening, the first outlet opening, the second outlet opening and the third outlet opening. A control assembly passes through the pipe body, and is connected to the diverter. The control assembly is adapted to plug two selected from the group consisting of the first flow way, the second flow way and the third flow way, whereby a water flow could be regulated by the control assembly to outlet from the first flow way, the second flow way or the third flow way. A brushing head is positioned on the outlet end of the pipe body.
With the aforementioned design, the brushing sprayer provides multiple flushing functions, and includes a brushing head, so that the user could save time for washing the dishes, and could decrease the waste of water. Furthermore, the brushing sprayer is more convenient in use compared to conventional sprayers for kitchen cleaning.
The present disclosure will be best understood by referring to the following detailed description of some illustrative embodiments in conjunction with the accompanying drawings, in which
As illustrated in
The pipe body 10 includes an inlet end 101 and an outlet opening 102, wherein the inlet end 101 has an inlet opening 101a, and the outlet end 102 has a first outlet opening 102a, a second outlet opening 102b and a third outlet opening 102c. According to one embodiment of the present disclosure, the inlet opening 101a, the first outlet opening 102a, the second outlet opening 102b and the third outlet opening 102c communicate with each other.
The diverter 20 is positioned in the pipe body 10, and includes a first flow way 201, a second flow way 202 and a third flow way 203 communicating with each other. According to one embodiment of the present disclosure, the first flow way 201, the second flow way 202 and the third flow way 203 communicate with the inlet opening 101a, the first outlet opening 102a, the second outlet opening 102b and the third outlet opening 102c.
The control assembly 30 passes through the pipe body 10, and is connected to the diverter 20. According to one embodiment of the present disclosure, the control assembly 30 is adapted to plug two selected from the group consisting of the first flow way 201, the second flow way 202 and the third flow way 203, whereby a water flow F1, F2 or F3 could be regulated by the control assembly 30 to outlet from the first flow way 201, the second flow way 202 or the third flow way 203.
According to one embodiment of the present disclosure, the diverter 20 includes three parts 20A, 20B, 20C, wherein the three parts 20A, 20B, 20C could be composed to form the first flow way 201, the second flow way 202 or the third flow way 203, as shown in
The brushing head 40 is positioned on the outlet end 102 of the pipe body 10. The control assembly 30 includes a first plug 32 and a second plug 34, the first plug 32 is positioned corresponding to the first flow way 201, the second flow way 202 and the third flow way 203, and the second plug 34 is positioned corresponding to the second flow way 202 and the third flow way 203.
The diverter 20 includes a first diverting well 240 and a second diverting well 250 communicating with each other. According to one embodiment of the present disclosure, the first diverting well 240 has a first through hole 242 and a second through hole 244. The first diverting well 240 communicates with the second diverting well 250 through the second through hole 244. The first through hole 242 communicates with the first flow way 201, and the second through hole 244 communicates with the second flow way 202 and the third flow way 203.
The second diverting well 250 has a third through hole 252 and a fourth through hole 254. According to one embodiment of the present disclosure, the third through hole 252 communicates with the second flow way 202, and the fourth through hole 254 communicates with the third flow way 203.
According to one embodiment of the present disclosure, the first plug 32 correspondingly passes into the first diverting well 240 and the second plug 34 correspondingly passes into the second diverting well 250.
According to one embodiment of the present disclosure, when the control assembly 30 plugs the second flow way 202 and the third flow way 203, the water flow F1 outlets from the first flow way 201, as shown in
In detail, when the first plug 32 plugs the second through hole 244 of the first diverting well 240, the water flow F1 outlets from the first flow way 201 through the first through hole 242 of the first diverting well 240.
According to one embodiment of the present disclosure, when the control assembly 30 plugs the first flow way 201 and the third flow way 203, the water flow F2 outlets from the second flow way 202, as shown in
In detail, when the first plug 32 plugs the first through hole 242 of the first diverting well 240, and the second plug 34 plugs the fourth through hole 254 of the second diverting well 250, the water flow F2 outlets from the second flow way 202 through the third through hole 252 of the second diverting well 250.
According to one embodiment of the present disclosure, when the control assembly 30 plugs the first flow way 201 and the second flow way 202, the water flow F3 outlets from the third flow way 203, as shown in
In detail, the first plug 32 plugs the first through hole 242 of the first diverting well 240, and the second plug 34 plugs the third through hole 252 of the second diverting well 250, the water flow F3 outlets from the third flow way 203 through the fourth through hole 254 of the second diverting well 250.
According to one embodiment of the present disclosure, the control assembly 30 includes a linked structure 33. The linked structure 33 is connected to the first plug 32 and the second plug 34. According to one embodiment of the present disclosure, first plug 32 is connected to one end of the linked structure 33 while the second plug 34 is connected to the other one end of the linked structure 33. When the first plug 32 plugs the first through hole 244 of the first diverting well 240, the second plug 34 is driven by the first plug 32 to plug the fourth through hole 254 of the second diverting well 252.
When the first plug 32 plugs the first through hole 242 of the first diverting well 240, and the second pressed portion 354 of the pressed member 35 is pressed, the first pressed portion 352 pulls the second plug 34 to plug the fourth through hole 254 of the second diverting well 250, whereby the water flow F2 outlets from the second flow way 202.
Referring to
According to one embodiment of the present disclosure, the rotating assembly 44 includes a water power member 442. The water power member 442 is positioned on the first flow way 201. When the water flow F1 flows through the water power member 442 along the first flow way 201, the water flow F1 drives the water power member 442 to rotate, and drives the brushing portion 42 to rotate simultaneously.
According to one embodiment of the present disclosure, the rotating assembly 44 is a planetary gear decelerator 44. The water power member 442 is a sun gear 442 of the planetary gear decelerator 44, and the brushing portion 42 is connected to a driven gear 446 of the dual gear decelerator 44. According to one embodiment of the present disclosure, a planetary gear carrier 444 is positioned between the water power member 442 and the brushing portion 42. When the sun gear 442 rotates, the sun gear 442 transmits a rotation force to the ring wheel 446 through the planetary gear carrier 444, whereby to rotate the ring wheel 446, so as to drive the brushing portion 42 to rotate.
Referring to
According to one embodiment of the present disclosure, the rotating assembly 44 includes a water power member 442. The water power member 442 is positioned on the first flow way 201. When the water flow F1 flows through the water power member 442 along the first flow way 201, the water flow F1 drives the water power member 442 to rotate, and drives the brushing portion 42 to rotate simultaneously.
According to one embodiment of the present disclosure, the rotating assembly 44 is a dual gear decelerator 44. The water power member 442 is a fan gear 442 of the dual gear decelerator 44, and the brushing portion 42 is connected to a driven gear 446. According to one embodiment of the present disclosure, a dual gear assembly 444 is positioned between the water power member 442 and the brushing portion 42. When the fan gear 442 rotates, the fan gear 442 transmits a rotation force to the driven gear 446 through the dual gear assembly 444, whereby to rotate the driven gear 446, so as to drive the brushing portion 42 to rotate.
Referring to
In
In
It must be pointed out that the embodiments described above are only some preferred embodiments of the present disclosure. All equivalent structures which employ the concepts disclosed in this specification and the appended claims should fall within the scope of the present disclosure.