TECHNICAL FIELD
The present disclosure relates to the technical field of faucets, in particular to a quick mounting and dismounting method for a faucet, and a quick-mounting faucet.
BACKGROUND
Due to the inconvenience in the existing mounting method of faucets, the existing mounting method of faucets is high in difficulty for mounting personnel to operate and labor intensity. In the general mounting method of faucets, the faucet is fixed by fastening with nuts under the table. In the method, the mounting personnel needs to lie down under the table and mount the faucet on the back. Because the water channel of the washbasin blocks the mounting hole, the mounting personnel may not reach out hands to tighten the nuts, so the mounting personnel has to use special tools to mount the faucet.
SUMMARY
The present disclosure aims to provide a quick mounting and dismounting method for a faucet, and a quick-mounting faucet, so that at least part of defects in the prior art may be solved.
In order to achieve the purpose, through the technical scheme provided by embodiments of the present disclosure, a quick mounting and dismounting method for a faucet includes the following steps:
- S1, preparing a faucet with movable claws, wherein the movable claws are rotatably arranged on the faucet;
- S2, forming a hole in a carrier, wherein the size of the hole is matched with the size of a tube shell of the faucet;
- S3, bundling up the movable claws, and enabling the bundled movable claws to pass through the carrier from the hole; and
- S4, after the movable claws pass through the hole, unfolding the movable claws to hook the periphery of the hole in the carrier so as to mount the tube shell on the carrier.
Further, before the movable claws pass through the hole, the movable claws are bundled up to cling to the faucet. After the movable claws are loosened, the movable claws rotate to initial positions. When the movable claws are in the initial positions, the movable claws may abut against the periphery of the hole.
Further, the movable claws are mounted on the faucet through torsional springs.
Further, the movable claws are mounted on a central tube on the faucet.
Further, threads are arranged on an outer wall of the central tube, the central tube is in threaded connection with the carrier, and the movable claws are placed on the outer wall of the central tube.
Further, the central tube, together with the movable claws, passes through the hole. After the movable claws pass through the hole, the central tube is rotated to drive the movable claws to get close to the carrier. After the movable claws abut against the carrier, the movable claws are unfolded to hook the periphery of the hole in the carrier so as to fixedly mount the tube shell on the carrier.
Further, when the faucet is dismounted from the carrier, first the movable claws are rotated to be bundled up, and then the bundled movable claws come out of the hole so as to dismount the tube shell from the carrier.
The embodiment of the present disclosure provides another technical scheme. A quick-mounting faucet includes a faucet body. The faucet body includes a tube shell and rotatably bundled movable claws. The movable claws are rotatably unfolded to hook the carrier so as to mount the tube shell on the carrier.
Further, the movable claws rotate through the torsional springs.
Further, the faucet body also includes a water inlet and outlet tube and a central tube, and the water inlet and outlet tube and the central tube are positioned by a limiting structure.
Compared with the prior art, the present disclosure has the following technical effects. Quick mounting of the faucet may be realized through the movable claws, and the mounting efficiency may be greatly improved compared with traditional methods.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a space diagram of a quick-mounting faucet provided by embodiments of the present disclosure.
FIG. 2 is a schematic diagram of FIG. 1 after a tube shell is omitted.
FIG. 3 is a schematic diagram of FIG. 2 after a seat shell is omitted.
FIG. 4 is a locally enlarged schematic diagram of FIG. 3.
FIG. 5 is a schematic diagram of a limiting structure of a quick-mounting faucet provided by embodiments of the present disclosure.
Reference signs in attached figures: 1, tube shell; 2, movable claw; 3, ferrule; 4, thread; 5, water inlet and outlet tube; 6, central tube; 7, limiting structure; 8, first sealing ring; 9, water regulating head; and 10, bottom shell.
DETAILED DESCRIPTION OF THE EMBODIMENTS
The following clearly and completely describes the technical scheme in the embodiments of the present disclosure with reference to the embodiments of the present disclosure. Apparently, the described embodiments are merely a part rather than all of the embodiments of the present disclosure. All other embodiments obtained by a person of ordinary skill in the art based on the embodiments of the present invention without creative efforts shall fall within the protection scope of the present invention.
Embodiment I
Referring to FIG. 1 to FIG. 5, the embodiment of the present disclosure provides a quick mounting and dismounting method for a faucet. The quick mounting and dismounting method for a faucet includes the following steps: S1, preparing a faucet with movable claws 2, wherein the movable claws 2 are rotatably arranged on the faucet; S2, forming a hole in a carrier, wherein the size of the hole is matched with the size of a tube shell of the faucet; namely, the size dimension of the hole is slightly smaller than the outer dimension of the tube shell of the faucet, and meanwhile larger than the sum of the diameters of water tubes running through the tube shell of the faucet; all in all, the size of the hole is not larger than the size of the tube shell 1 of the faucet; S3, bundling up the movable claws 2, and enabling the bundled movable claws 2 to pass through the carrier from the hole; and S4, after the movable claws 2 pass through the hole, unfolding the movable claws 2 to hook the periphery of the hole in the carrier so as to mount the tube shell 1 on the carrier. In the embodiment, quick mounting of the faucet may be realized through the movable claws 2, and the mounting efficiency may be greatly improved compared with traditional methods. Specifically, the carrier may be a vegetable basin, a washbasin and the like, or other carriers that a faucet needs to be placed. A hole is formed in the carrier. The size of the hole needs to be matched with the size of the tube shell 1 of the faucet so as to ensure that the tube shell 1 of the faucet may not come out of the hole naturally. The movable claws 2 are movable claws 2. When the movable claws 2 are bundled up, the movable claws 2 may cling to the faucet, so the movable claws 2 may pass through the hole. After the movable claws 2 pass through the hole, the movable claws 2 are unfolded. At this time, the size of the unfolded movable claw 2 is larger than the size of the hole, so the carrier may be hooked, the faucet may not come out of the hole naturally, and the tube shell 1 may be mounted on the carrier. When the faucet needs to be dismounted, the movable claws 2 may be bundled up again, so the movable claws 2 may pass through the hole again smoothly, and the tube shell 1 is dismounted from the carrier.
Referring to FIG. 1 to FIG. 5, before the movable claws 2 pass through the hole, the movable claws 2 are bundled up to cling to the faucet. After the movable claws 2 are loosened, the movable claws 2 rotate to initial positions. When the movable claws are in the initial positions, the movable claws 2 may abut against the periphery of the hole. In the embodiment, the initial positions of the movable claws 2 are limited. When the tips of the movable claws 2 located at the initial positions exceed the overage range of the hole, the movable claws 2 may not come out of the hole. Preferably, the unfolded amplitude may be limited by defining the angles at which the movable claws 2 rotate. The movable claws 2 are mounted on the faucet with torsional springs. For example, the initial state is that the movable claws 2 are in a horizontal state. At this time, the tips of the movable claws 2 exceed the coverage range of the hole. When the faucet needs to be mounted, the movable claws 2 are forcefully pressed. At this time, the movable claws 2 are in a vertical state. At this time, the movable claws 2 may pass through the hole smoothly. After the movable claws 2 pass through the hole, the movable claws 2 are loosened, and the movable claws 2 are reset to the horizontal state under the action of the torsional springs, so that the movable claws may not come out of the hole, and quick mounting of the faucet is realized. Quick dismounting is in the same way similarly. The faucet may be quickly dismounted from the carrier by simply pressing the movable claws 2 again to make the movable claws 2 vertical. Preferably, there are a plurality of movable claws 2. For example, three movable claws 2 are rotatably mounted on a ferrule 3, and each movable claw 2 is mounted on the ferrule 3 by a torsional spring. With fingers, the movable claws 2 may be pressed without tools, and the faucet is very convenient to mount.
Referring to FIG. 1 to FIG. 5, the movable claws 2 are mounted on a central tube 6 on the faucet. In the embodiment, in order to make the faucet more compact, the movable claws 2 may be mounted on the central tube 6, so one part may be saved. Preferably, threads 4 are arranged on an outer wall of the central tube 6. The central tube 2 is fixedly placed on the outer wall of the central tube 6. Preferably, the movable claws 2 may be arranged on the ferrule 3, and then the ferrule 3 sleeves the outer wall. For example, the movable claws 2 are also in threaded connection with the outer wall. The design of the threads 4 may facilitate the central tube 6 to be in threaded connection with the carrier, so the position of the central tube 6 on the carrier may be adjusted through the threads. Specifically, when the central tube 6 rotates forward, the part of the central tube 6 on the upper side of the carrier gradually becomes longer and the part of the central tube 6 on the lower side of the carrier correspondingly becomes shorter by rotating the central tube 6. At this time, the central tube 6, together with the movable claws 2, may move upward to gradually get close to the carrier. On the contrary, when the central tube 6 rotates backward, the part on the lower side of the carrier gradually becomes longer, so the movable claws 2 may also become more and more distant from the carrier. In addition, if the movable claws 2 are designed to be in threaded connection with the central tube 6, the positions of the movable claws 2 on the central tube 6 may be adjusted, so the movement of the central tube 6 with the movable claws 2 may be regarded as coarse adjustment of the positions of the movable claws 2, and the position adjustment of the movable claws 2 on the central tube 6 may be regarded as fine adjustment to ensure that the movable claws 2 may fully abut against the carrier and achieve tighter and more stable assembling.
Referring to FIG. 1 to FIG. 5, after the threads 4 are designed, the movable claws 2 pass through the hole with the central tube 6. After the movable claws 2 pass through the hole, the central tube is rotated to drive the movable claws to get close to the carrier. After the movable claws abut against the carrier, the movable claws are unfolded to hook the periphery of the hole in the carrier so as to fixedly mount the tube shell on the carrier. In the embodiment, the positions of the movable claws 2 are adjusted, so that the gap between the movable claws 2 and the carrier is adjusted. The adjustment is convenient so that the movable claws 2 cling to the carrier. Before the faucet is mounted, the positions of the movable claws 2 may be adjusted to get far away from the tube shell 1 so as to ensure that interference with the carrier may not be generated when the central tube 6, together with the movable claws 2, passes through the hole. After the movable claws 2 completely pass through the hole to the bottom side of the carrier, the movable claws 2 may be adjusted to get close to the carrier through the threads 4 until the movable claws 2 jack up the carrier. At this time, the tube shell 1 may be firmly mounted on the surface side of the carrier.
Referring to FIG. 1 to FIG. 5, a water outlet tube may be placed on the central tube 6 for water outlet. Preferably, the central tube 6 and the water outlet tube may be integrally designed. That is, the tube may be used as the central tube 6 to drive the movable claws 2, and also may be used as the water outlet tube for water outlet, so that the structure of the product may be smaller, and the cost may also be saved.
Embodiment II
Referring to FIG. 1 to FIG. 5, the embodiment of the present disclosure provides a quick-mounting faucet. The quick-mounting faucet includes a faucet body. The faucet body includes a tube shell 1 and rotatably bundled movable claws 2. The movable claws 2 are rotatably unfolded to hook the carrier so as to mount the tube shell 1 on the carrier. In the embodiment, quick mounting of the faucet may be realized through the movable claws 2, and the mounting efficiency may be greatly improved compared with traditional methods.
Specifically, the carrier may be a vegetable basin, a washbasin and the like, or other carriers that a faucet needs to be placed. A hole is formed in the carrier. The size of the hole needs to be not larger than the size of the tube shell 1 of the faucet so as to ensure that the tube shell 1 of the faucet may not come out of the hole naturally. The movable claws 2 are movable claws 2. When the movable claws 2 are bundled up, the movable claws 2 may cling to the faucet, so the movable claws 2 may pass through the hole. After the movable claws 2 pass through the hole, the movable claws 2 are unfolded. At this time, the size of the unfolded movable claws 2 is larger than the size of the hole, so the carrier may be hooked, the faucet may not come out of the hole naturally, and the tube shell 1 may be mounted on the carrier. When the faucet needs to be dismounted, the movable claws 2 may be bundled up again, so the movable claws 2 may pass through the hole again smoothly, and the tube shell 1 is dismounted from the carrier.
Referring to FIG. 1 to FIG. 5, the movable claws 2 rotate through the torsional springs. The movable claws 2 are mounted on the faucet with the torsional springs. For example, the initial state is that the movable claws 2 is in a horizontal state. At this time, the tips of the movable claws 2 exceed the coverage range of the hole. When the faucet needs to be mounted, the movable claws 2 are forcefully pressed. At this time, the movable claws 2 are in a vertical state. At this time, the movable claws 2 may pass through the hole smoothly. After the movable claws 2 pass through the hole, the movable claws 2 are loosened, and the movable claws 2 are reset to the horizontal state under the action of the torsional springs, so that the movable claws may not come out of the hole, and quick mounting of the faucet is realized. Quick dismounting is in the same way similarly. The faucet may be quickly dismounted from the carrier by simply pressing the movable claws 2 again to make the movable claws 2 vertical. Preferably, there are a plurality of movable claws 2. For example, three movable claws 2 are rotatably mounted on a ferrule 3, and each movable claw 2 is mounted on the ferrule 3 by a torsional spring. With fingers, the movable claws 2 may be pressed without tools, and the faucet is very convenient to mount.
Of course, the three movable claws 2 may also be bundled and unfolded through the arc chamfering angles of the three movable claws 2, so that quick mounting and dismounting of the faucet are realized, and the convenience in mounting and dismounting is greatly provided.
Referring to FIG. 1 to FIG. 5, the faucet body also includes a water inlet and outlet tube 5 and a central tube 6, and the water inlet and outlet tube 5 and the central tube 6 are limited by a limiting structure 7. In the embodiment, the water inlet and outlet tube 5 and the central tube 6 are both flexible tubes relatively. In order to avoid the water inlet and outlet tube 5 and the central tube 6 from scattering in the mounting process to cause the inference of mounting or dismounting. The positions of the water inlet and outlet tube 5 and the central tube 6 are limited by the limiting structure 7, so that the dismounting efficiency may be improved. Preferably, the limiting structure 7 includes a ring body and a plurality of fixing areas arranged in the ring body, and the water inlet and outlet tube 5 and the central tube 6 are both located in the fixing areas. The fixing area is enclosed by a plurality of bumps matched with the ring body.
Referring to FIG. 1 to FIG. 5, the faucet body also includes a seat shell. The bottoms of the water inlet and outlet tube 5 and the central tube 6 are both fixed in the seat shell. Preferably, the central tube 6 and the water inlet and outlet tube 5 are fixed on the bottom shell 10 through screws.
Referring to FIG. 1 to FIG. 5, the movable claws 2 are mounted on a central tube 6 on the faucet. In the embodiment, in order to make the faucet more compact, the movable claws 2 may be mounted on the central tube 6, so one part may be saved. Preferably, threads 4 are arranged on an outer wall of the central tube 6. The central tube 2 is fixedly placed on the outer wall of the central tube 6. Preferably, the movable claws 2 may be arranged on the ferrule 3, and then the ferrule 3 sleeves the outer wall. For example, the movable claws 2 are also in threaded connection with the outer wall, or directly fixed on the outer wall in welding, cementing and other forms. The design of the threads 4 may facilitate the central tube 6 to be in threaded connection with the carrier, so the position of the central tube 6 on the carrier may be adjusted through the threads. Specifically, when the central tube 6 rotates forward, the part of the central tube 6 on the upper side of the carrier gradually becomes longer and the part of the central tube 6 on the lower side of the carrier correspondingly becomes shorter by rotating the central tube 6. At this time, the central tube 6, together with the movable claws 2, may move upward to gradually get close to the carrier. On the contrary, when the central tube 6 rotates backward, the part on the lower side of the carrier gradually becomes longer, so the movable claws 2 may also become more and more distant from the carrier. In addition, if the movable claws 2 are designed to be in threaded connection with the central tube 6, the positions of the movable claws 2 on the central tube 6 may be adjusted, so the movement of the central tube 6 together with the movable claws 2 may be regarded as coarse adjustment of the positions of the movable claws 2, and the position adjustment of the movable claws 2 on the central tube 6 may be regarded as fine adjustment to ensure that the movable claws 2 may fully abut against the carrier and achieve tighter and more stable assembling.
Referring to FIG. 1 to FIG. 5, after the threads 4 are designed, the movable claws 2 pass through the hole with the central tube 6. After the movable claws 2 pass through the hole, the central tube is rotated to drive the movable claws to get close to the carrier. After the movable claws abut against the carrier, the movable claws are unfolded to hook the periphery of the hole in the carrier so as to fixedly mount the tube shell on the carrier. In the embodiment, the positions of the movable claws 2 are adjusted, so that the gap between the movable claws 2 and the carrier is adjusted. The adjustment is convenient so that the movable claws 2 cling to the carrier. Before the faucet is mounted, the positions of the movable claws 2 may be adjusted to get far away from the tube shell 1 so as to ensure that interference with the carrier may not be generated when the central tube 6, together with the movable claws 2, passes through the hole. After the movable claws 2 completely pass through the hole to the bottom side of the carrier, the movable claws 2 may be adjusted to get close to the carrier through the threads 4 until the movable claws 2 jack up the carrier. At this time, the tube shell 1 may be firmly mounted on the surface side of the carrier.
Referring to FIG. 1 to FIG. 5, the water inlet and outlet tube 5 includes a water outlet tube and a plurality of water inlet tubes. The water outlet tube may be placed on the central tube 6 for water outlet. Preferably, the central tube 6 and the water outlet tube may be integrally designed. That is, the tube may be used as the central tube 6 to drive the movable claws 2, and also may be used as the water outlet tube for water outlet, so that the structure of the product may be smaller, and the cost may also be saved.
Referring to FIG. 1 to FIG. 5, the faucet body also includes a first sealing ring 8. The first sealing ring 8 is arranged between the tube shell 1 and the carrier. The faucet body also includes a second sealing ring. The second sealing ring is arranged between the tube shell 1 and the movable claws 2. When the movable claws 2 move upward, the second sealing ring may jack up the carrier, so that sealing is realized.
Referring to FIG. 1 to FIG. 5, an end of the central tube 6 is provided with a water regulating head 9. In the embodiment, the water regulating head 9 is designed, so that the water content and mode may be regulated.
Although the embodiments of the present disclosure have already been illustrated and described, various changes, modifications, replacements and transformations can be made by those skilled in the art under the condition of without departing from the principle and the spirit of the present disclosure, and thus the scope of the present disclosure should be restricted by claims and equivalents thereof.
Patent Application
20250092649
