CN215161552U - Water outlet system and water outlet device - Google Patents

Abstract

The utility model relates to a water outlet system and a water outlet device with the same. Go out water system include: a first end of the second water channel is used for accessing pure water, and a second end of the second water channel is connected with a first water nozzle; the first end of the first water channel is used for being connected with pure water, one end of the third water channel is connected with a second water nozzle, and a heating module is arranged on the third water channel and used for heating the pure water.

Description

Water outlet system and water outlet device

Technical Field

The utility model relates to a water purification field especially relates to a water outlet system and a water outlet device who has this water outlet system.

Background

In order to improve the water outlet function of the faucet, a dual-function water outlet faucet is already available in the market, which can realize the water outlet of tap water, pure water and the like through one faucet. However, as the standard of living increases, people have more demands on the water outlet joint, so that the existing water faucet has room for further improvement.

SUMMERY OF THE UTILITY MODEL

Based on this, the utility model aims at providing a water outlet system and a water outlet device who has this water outlet system.

A water egress system, comprising: a first end of the second water channel is used for accessing pure water, and a second end of the second water channel is connected with a first water nozzle; the first end of the first water channel is used for being connected with pure water, one end of the third water channel is connected with a second water nozzle, and a heating module is arranged on the third water channel and used for heating the pure water.

Furthermore, a voltage stabilizing module and a power module are also arranged on the third water path; the pressure stabilizing module is arranged on the water inlet side of the heating module and is used for reducing the water pressure of the pure water; the power module is arranged between the pressure stabilizing module and the heating module and used for providing power for the pure water after the water pressure is reduced to move to the second water nozzle.

Furthermore, a first temperature detection module is further arranged on the third water path, the first temperature detection module is arranged on the water inlet side of the heating module, and the first temperature detection module is used for detecting the temperature of the pure water to be fed into the heating module.

Further, a second temperature detection module is further arranged on the third water path, the second temperature detection module is arranged on the water outlet side of the heating module, and the second temperature detection module is used for detecting the temperature of the pure water heated by the heating module.

Further, the pressure stabilizing module is a water storage tank or a zero pressure valve; the power module is an electric water pump.

Furthermore, a silicon controlled module is further arranged on the third water path, the silicon controlled module is arranged on the water inlet side of the heating module, and the silicon controlled module is attached to a pipeline on the water inlet side of the heating module.

Furthermore, a path switching valve is arranged on the second water channel, a water outlet of the path switching valve is connected with the first water nozzle, and a pure water inlet of the path switching valve is connected with the first end of the second water channel.

Further, the effluent system still includes: the first end in first water route is used for inserting the water purification, the second end in first water route with the water purification import of the valve of changing the way is connected.

Furthermore, the water outlet system also comprises a water purification component, the water purification component is provided with a raw water port, a purified water port and a waste water port, the first end of the first water channel is connected with the purified water port, the first end of the second water channel is connected with the purified water port, and the first end of the third water channel is connected with the purified water port; the water purification component comprises a front filter element, an RO membrane filter element and a rear filter element; the water inlet side of the preposed filter element is communicated with the raw water port, the purified water outlet side of the preposed filter element is communicated with the purified water inlet side of the RO membrane filter element, and the purified water outlet side of the preposed filter element is also communicated with the purified water port; the pure water outlet side of the RO membrane filter element is communicated with the pure water port, and the wastewater outlet side of the RO membrane filter element is communicated with the wastewater port; the pure water inlet side of the rear filter element is communicated with the pure water outlet side of the RO membrane filter element, and the pure water outlet side of the rear filter element is communicated with the pure water port.

Further, the water purification subassembly still includes second connecting line, the first end of second connecting line is connected the pure water play water side of rearmounted filter core with between the pure water mouth, the second end of second connecting line is connected leading filter core with between the RO membrane filter core be provided with third solenoid valve, check valve on the second connecting line.

Further, along the direction from the first end of the second connecting pipeline to the second end of the second connecting pipeline, the third electromagnetic valve and the one-way valve are sequentially arranged on the second connecting pipeline.

Further, the water purification subassembly still includes second connecting line, the first end of second connecting line is connected the pure water play water side of rearmounted filter core with between the pure water mouth, the second end of second connecting line is connected leading filter core with between the RO membrane filter core be provided with the relief valve on the second connecting line.

Furthermore, along the water flow direction, a first electromagnetic valve and a booster pump are sequentially arranged between the water purification water outlet side of the preposed filter element and the water purification water inlet side of the RO membrane filter element.

Further, the water purification assembly further comprises a first connecting pipeline, the first end of the first connecting pipeline is connected between the water purification water outlet side of the front filter element and the water purification port, the second end of the first connecting pipeline is connected between the first electromagnetic valve and the booster pump, and the first connecting pipeline is provided with a second electromagnetic valve and a flow limiting valve.

Further, the second electromagnetic valve and the flow limiting valve are sequentially arranged on the first connecting pipeline along the direction from the first end to the second end of the first connecting pipeline.

Further, a second end of the second connecting pipeline is connected between the first electromagnetic valve and the booster pump.

Furthermore, a fourth electromagnetic valve is arranged between the wastewater outlet side of the RO membrane filter element and the wastewater outlet.

For a better understanding and an implementation, the present invention is described in detail below with reference to the accompanying drawings.

Drawings

FIG. 1 is a schematic structural diagram of a water outlet system according to an embodiment;

FIG. 2 is another schematic structural diagram of the water outlet system according to the embodiment;

FIG. 3 is a schematic structural diagram of a water outlet device according to an embodiment;

FIG. 4 is an internal schematic view of an upper water outlet module according to an embodiment;

FIG. 5 is an internal schematic view of a lower water outlet module according to an embodiment;

FIG. 6 is a schematic structural diagram of the upper water outlet base module according to the embodiment;

FIG. 7 is a bottom view of the upper water outlet base module according to the embodiment;

FIG. 8 is a schematic structural view of the lower outlet top seat module according to the embodiment;

FIG. 9 is a top view of the lower outlet header module according to an embodiment;

reference numerals:

1. a water outlet system; 11. a water purification assembly; 11a, a raw water port; 11b, a water purifying port; 11c, a pure water port; 11d, a waste water port; 111. a front filter element; 112. an RO membrane filter element; 113. a post-positioned filter element; 114. a first solenoid valve; 115. a booster pump; 116. a first connecting line; 1161. a second solenoid valve; 1162. a flow-limiting valve; 117. a second connecting line; 1171. a third electromagnetic valve; 1172. a one-way valve; 1173. a pressure relief valve; 118. a fourth solenoid valve; 12. a first waterway; 121. a path changing valve; 13. a second waterway; 14. a third waterway; 141. a heating module; 142. a voltage stabilization module; 143. a power module; 144. a first temperature detection module; 145. a second temperature detection module; 146. a silicon controlled module; 15. a first water nozzle; 16. a second water nozzle; 2. a water outlet device; 21. an upper water outlet module; 211. an upper water outlet shell; 212. a first conduit; 213. a second conduit; 214. an upper water outlet base module; 214a, a sixth interface; 214b, a seventh interface; 214c, an eighth interface; 214d, a first diversion trench; 214e, a second diversion trench; 2141. an external thread; 2142. a first spacer ring; 2143. a second divider ring; 2144. a third spacer ring; 22. a lower water outlet module; 221. a lower water outlet base; 221a, a first interface; 221b, a second interface; 221c, a third interface; 221d, a fourth interface; 221e, a fifth interface; 222. a lower water outlet shell; 223. a third pipeline; 224. a fourth conduit; 225. a fifth pipeline; 226. a lower water outlet top seat module; 226a, a ninth interface; 226b, tenth interface; 226c, eleventh interface; 226d, a third guiding gutter; 226e, a fourth guiding gutter; 2261. a threaded hole; 2262. a fourth spacer ring; 2263. a fifth divider ring; 2264. a sixth divider ring.

Detailed Description

A water outlet system 1, see fig. 1 or fig. 2, the water outlet system 1 includes a water purifying assembly 11, a first waterway 12, a second waterway 13, and a third waterway 14. Wherein, the water purification component 11 uses the pre-filter element 111 to obtain purified water, and uses the pre-filter element 111 to obtain pure water by reverse osmosis membrane filtration, and the water purification component 11 is provided with a purified water port 11b for outputting purified water and a pure water port 11c for outputting pure water. The first end of the first waterway 12 is connected with the water purifying port 11b of the water purifying assembly 11, the second end of the first waterway 12 is connected with the first water nozzle 15, the first waterway 12 is provided with the switch valve 121, and the switch valve 121 is arranged between the water purifying port 11b of the water purifying assembly 11 and the first water nozzle 15. A first end of the second water path 13 is connected to the pure water port 11c of the water purification assembly 11, a second end of the second water path 13 is connected to the switching valve 121 of the first water path 12, and the first water nozzle 15 is switched to output pure water or pure water through the switching valve 121. The first end of the third water path 14 is connected to the pure water port 11c of the water purification assembly 11, the second end of the third water path 14 is connected to the second water nozzle 16, the third water path 14 is provided with a heating module 141, the heating module 141 is arranged between the pure water port 11c of the water purification assembly 11 and the second water nozzle 16, the heating module 141 is used for heating pure water, and the heating module 141 may be an existing instant heating device such as a heating wire.

The water outlet system 1 adopts the above design, so that normal-temperature purified water, normal-temperature purified water and heated purified water can be output to meet different requirements of consumers, for example, when purified water or purified water is needed to clean an object, the first water nozzle 15 can be used for outputting normal-temperature purified water and normal-temperature purified water; when the normal-temperature pure water or the heated pure water is required to be drunk, the second water nozzle 16 may be used to output the normal-temperature pure water or the heated pure water. In addition, considering that the pipeline between the switching valve 121 and the first water nozzle 15 is polluted by the purified water, the second water nozzle 16 is adopted to output the directly drinkable purified water, and the pollution caused by the shared water channel of the purified water and the purified water is avoided.

Referring to fig. 1 or 2, a pressure stabilizing module 142 and a power module 143 may be further disposed on the third waterway 14. The pressure stabilizing module 142 is arranged between the pure water port 11c of the water purifying assembly 11 and the heating module 141, and the pressure stabilizing module 142 is used for reducing the water pressure of the pure water to zero water pressure or close to zero water pressure; specifically, the pressure stabilizing module 142 may be a water storage tank or a zero pressure valve, and in this embodiment, the pressure stabilizing module 142 employs a zero pressure valve, which can effectively prevent the pure water from secondary pollution in the water storage tank and reduce the volume of the whole machine. The power module 143 is arranged between the pressure stabilizing module 142 and the heating module 141, and the power module 143 is used for providing power for the pure water which is reduced to zero water pressure or is close to zero water pressure to move to the second water nozzle 16; specifically, the power module 143 uses an electric water pump, and the electric water pump is controlled in an electric control manner, and the electric water pump can transport pure water to the heating module 141 for heating according to a set water amount.

Referring to fig. 1 or 2, a first temperature detection module 144 may be further disposed on the third waterway 14. The first temperature detection module 144 is disposed on the water inlet side of the heating module 141, and the first temperature detection module 144 is configured to detect the temperature of pure water to be introduced into the heating module 141, so that the water outlet system 1 can control the power of the heating module 141 according to the temperature of the pure water before heating, thereby facilitating reduction of energy consumption. In the embodiment, the first temperature detecting module 144 is disposed between the power module 143 and the heating module 141, and the first temperature detecting module 144 may adopt an existing temperature sensor capable of detecting the temperature of water, which is not limited herein.

Referring to fig. 1 or 2, a second temperature detection module 145 may be further disposed on the third water path 14. The second temperature detecting module 145 is disposed on the water outlet side of the heating module 141, and the second temperature detecting module 145 is configured to detect the temperature of the pure water heated by the heating module 141, so that the water outlet system 1 can check whether the temperature of the heated pure water is required, and the power of the heating module 141 can be regulated according to the temperature of the heated pure water, which is helpful for further reducing energy consumption. In the embodiment, the second temperature detecting module 145 is disposed between the heating module 141 and the second water nozzle 16, and the second temperature detecting module 145 may be an existing temperature sensor capable of detecting the temperature of water, which is not limited herein.

Referring to fig. 1 or 2, in order to reduce energy consumption, a thyristor module 146 may be further disposed on the third water path 14. The silicon controlled module 146 is arranged on the water inlet side of the heating module 141, and pure water flowing to the heating module 141 is used for absorbing heat on the silicon controlled module 146, so that the temperature of the silicon controlled module 146 is reduced on one hand, and the heat of the silicon controlled module 146 is recovered on the other hand. In the present embodiment, the thyristor module 146 is disposed between the power module 143 and the heating module 141, and the thyristor module 146 is located between the first temperature detection module 144 and the heating module 141.

Referring to fig. 1 or 2, a specific structure of the water purifying module 11 will be described in detail. The water purification unit 11 includes a raw water port 11a, the purified water port 11b, the purified water port 11c, and a waste water port 11 d. The water purification assembly 11 includes a pre-filter cartridge 111 and an RO membrane filter cartridge 112. Wherein, the water inlet side of the pre-filter element 111 is communicated with the raw water port 11a, the purified water outlet side of the pre-filter element 111 is communicated with the purified water inlet side of the RO membrane filter element 112, and the purified water outlet side of the pre-filter element 111 is also communicated with the purified water port 11 b. The pure water outlet side of the RO membrane cartridge 112 communicates with the pure water port 11c, and the waste water outlet side of the RO membrane cartridge 112 communicates with the waste water port 11 d. In order to improve the purity of the pure water, the water purification assembly 11 further comprises a post-filter element 113, the post-filter element 113 is arranged between the RO membrane filter element 112 and the pure water port 11c, a pure water inlet side of the post-filter element 113 is communicated with a pure water outlet side of the RO membrane filter element 112, the pure water outlet side of the post-filter element 113 is communicated with the pure water port 11c, and the pure water is filtered again by the post-filter element 113 and then is output from the pure water port 11 c.

Referring to fig. 1 or 2, the piping design between the pre-filter cartridge 111 and the RO membrane cartridge 112 is described in detail below. Specifically, a first electromagnetic valve 114 and a booster pump 115 are sequentially disposed between the purified water outlet side of the pre-filter 111 and the purified water inlet side of the RO membrane filter 112 along the water flow direction. The water purification assembly 11 further includes a first connection pipeline 116, a first end of the first connection pipeline 116 is connected between the purified water outlet side of the front filter element 111 and the purified water port 11b, a second end of the first connection pipeline 116 is connected between the first electromagnetic valve 114 and the booster pump 115, and the first connection pipeline 116 is provided with a second electromagnetic valve 1161 and a flow limiting valve 1162. The redundant purified water can flow to the booster pump 115 after passing through the second electromagnetic valve 1161 and the flow limiting valve 1162 in sequence, so that the stable operation of the water purifying assembly 11 is ensured.

Referring to fig. 1, the piping design between the post-filter cartridge 113 and the RO membrane cartridge 112 is described in detail below. Specifically, the water purification assembly 11 further includes a second connection pipeline 117, a first end of the second connection pipeline 117 is connected between the pure water outlet side of the rear filter element 113 and the pure water port 11c, a second end of the second connection pipeline 117 is connected between the first electromagnetic valve 114 and the booster pump 115, and the second connection pipeline 117 is provided with a third electromagnetic valve 1171 and a one-way valve 1172. The excess pure water which fails to enter the pressure stabilizing module 142 increases the pressure of the water circuit, and when the pressure exceeds the threshold value of the check valve 1172, the check valve 1172 acts to enable the excess pure water to flow to the booster pump 115 after passing through the third electromagnetic valve 1171 and the check valve 1172 in sequence, so that the stable operation of the water purifying assembly 11 is ensured. In order to realize the functions of the third solenoid valve 1171 and the check valve 1172, referring to fig. 2, a relief valve 1173 may be provided in the second connecting line 117, and when the pressure exceeds the threshold of the relief valve 1173, the excess pure water may flow to the booster pump 115 through the relief valve 1173.

Referring to fig. 1 or 2, the piping design between the RO membrane cartridge 112 and the waste port 11d is described in detail below. Specifically, a fourth solenoid valve 118 is provided between the waste water outlet side of the RO membrane cartridge 112 and the waste water port 11 d.

In addition, according to the above water outlet system 1, the applicant designs a water purifier and a water outlet device 2, wherein relevant devices or water paths of the water outlet system 1 can be respectively integrated on the water purifier and the water outlet device 2 according to design requirements, without any limitation. However, in the present embodiment, the water purifying assembly 11 of the water outlet system 1 is integrated on the water purifier, and the first waterway 12, the second waterway 13, the third waterway 14, the first water nozzle 15, the second water nozzle 16 and the related devices disposed on the first waterway 12, the second waterway 13 or the third waterway 14 of the water outlet system 1 are integrated on the water outlet device 2.

Referring to fig. 3 to 5, the water outlet device 2 is composed of an upper water outlet module 21 and a lower water outlet module 22, wherein, the first waterway 12, the second waterway 13, the third waterway 14, the first water nozzle 15, the second water nozzle 16 and the related devices arranged on the first waterway 12, the second waterway 13 or the third waterway 14 of the water outlet system 1 can be integrated on the upper water outlet module 21 and the lower water outlet module 22 according to the design requirements, without any limitation, in the present embodiment, the first water nozzle 15, the second water nozzle 16, the switching valve 121, the heating module 141, the first temperature detecting module 144, and the second temperature detecting module 145 are integrated on the upper water outlet module 21, the pressure stabilizing module 142 and the power module 143 are integrated on the lower water outlet module 22, and specific structures of the upper water outlet module 21 and the lower water outlet module 22 provided in this embodiment will be described in detail below.

Referring to fig. 4, the upper water outlet module 21 includes an upper water outlet housing 211, a first pipe 212, and a second pipe 213. Wherein, the first water nozzle 15 is installed on the top of the upper water outlet housing 211. The second water nozzle 16 is installed at the upper end of the peripheral side of the upper water outlet housing 211, and the second water nozzle 16 is located below the first water nozzle 15. The switching valve 121, the heating module 141, the first temperature detection module 144, and the second temperature detection module 145 are all installed in the inner cavity of the upper water outlet housing 211, and along the direction from the top end of the upper water outlet housing 211 to the bottom end thereof, the second temperature detection module 145, the heating module 141, the first temperature detection module 144, and the switching valve 121 are sequentially disposed in the upper water outlet housing 211. The first pipeline 212 is arranged in the inner cavity of the upper water outlet housing 211, a first end of the first pipeline 212 is connected with the first water nozzle 15, and a second end of the first pipeline 212 is connected with the water outlet of the switching valve 121. The second pipeline 213 is arranged in the inner cavity of the upper water outlet housing 211, a first end of the second pipeline 213 is connected with the second water nozzle 16, the second pipeline 213 passes through the heating module 141, the second pipeline 213 is respectively contacted with the heating module 141, the first temperature detection module 144 and the second temperature detection module 145, the water passing through the second pipeline 213 is rapidly heated by the heating module 141, the water temperature of the water before entering the heating module 141 is detected by the first temperature detection module 144, and the water temperature of the water after entering the heating module 141 is detected by the second temperature detection module 145.

Referring to fig. 5, the lower water outlet module 22 includes a lower water outlet base 221, a lower water outlet housing 222, a third pipe 223, a fourth pipe 224, and a fifth pipe 225. The lower water outlet base 221 is provided with a first interface 221a, a second interface 221b, a third interface 221c, a fourth interface 221d and a fifth interface 221e, the first interface 221a is communicated with the second interface 221b, the third interface 221c is communicated with the fourth interface 221d, the third interface 221c is further communicated with the fifth interface 221e, the first interface 221a is used for being connected with a water purification port 11b of the water purification assembly 11, and the third interface 221c is used for being connected with a pure water port 11c of the water purification assembly 11. The lower outlet housing 222 is mounted on top of the lower outlet base 221. The pressure stabilizing module 142 and the power module 143 are installed in the inner cavity of the lower water outlet casing 222, and the power module 143 and the pressure stabilizing module 142 are sequentially arranged in the lower water outlet casing 222 along the direction from the top end to the bottom end of the lower water outlet casing 222; and, the water inlet of the voltage stabilizing module 142 is connected with the fifth interface 221e, and the water inlet of the power module 143 is connected with the water outlet of the voltage stabilizing module 142. The third, fourth and fifth pipes 223, 224, 225 are all mounted in the interior cavity of the lower outlet housing 222. A first end of the third pipe 223 is connected to the second port 221b, and a second end of the third pipe 223 is communicated with the clean water inlet of the change-over valve 121. A first end of the fourth pipe 224 is connected to the fourth port 221d, and a second end of the fourth pipe 224 is communicated with the pure water inlet of the change-over valve 121. A first end of the fifth pipe 225 is connected to the outlet of the power module 143, and a second end of the fifth pipe 225 is communicated with a second end of the second pipe 213.

Referring to fig. 4 and 5, in order to make the module integration of the water outlet apparatus 2 higher and facilitate the connection between the upper water outlet module 21 and the lower water outlet module 22, the upper water outlet module 21 further includes an upper water outlet base module 214, and the lower water outlet module 22 further includes a lower water outlet top base module 226, wherein the upper water outlet base module 214 is installed at the bottom of the upper water outlet housing 211, the lower water outlet top base module 226 is installed at the top of the lower water outlet housing 222, and the upper water outlet base module 214 is in threaded connection with the lower water outlet top base module 226, so that the upper water outlet module 21 can be directly assembled with the lower water outlet module 22 by means of threaded connection, thereby realizing the rapid assembly between the upper water outlet module 21 and the lower water outlet module 22. In the embodiment, the lower end of the upper outlet base module 214 is provided with external threads 2141, and the upper end of the lower outlet top base module 226 is provided with a threaded hole 2261 matched with the external threads 2141.

Referring to fig. 4, a sixth port 214a, a seventh port 214b, and an eighth port 214c are disposed at the top of the upper water outlet base module 214, wherein the sixth port 214a is communicated with the purified water inlet of the path changing valve 121, the seventh port 214b is communicated with the purified water inlet of the path changing valve 121, and the eighth port 214c is communicated with the second end of the second pipe 213.

Referring to fig. 5, a ninth port 226a, a tenth port 226b, and an eleventh port 226c are disposed at the bottom of the lower outlet top seat module 226, wherein the ninth port 226a is connected to the second end of the third pipe 223, the tenth port 226b is connected to the second end of the fourth pipe 224, and the eleventh port 226c is connected to the second end of the fifth pipe 225. The ninth port 226a, the tenth port 226b, and the eleventh port 226c of the lower outlet top seat module 226 are respectively communicated with the sixth port 214a, the seventh port 214b, and the eighth port 214c of the upper outlet base seat module 214.

Referring to fig. 6 and 7, under the premise that the upper outlet base module 214 and the lower outlet top base module 226 rotate relatively, in order to ensure that the ninth port 226a, the tenth port 226b and the eleventh port 226c of the lower outlet top seat module 226 are respectively communicated with the sixth port 214a, the seventh port 214b and the eighth port 214c of the upper outlet base seat module 214, the bottom of the upper water outlet base module 214 is sequentially provided with a first partition ring 2142, a second partition ring 2143, and a third partition ring 2144 from inside to outside, a first flow guide groove 214d is formed between the first partition ring 2142 and the second partition ring 2143, a second flow guide groove 214e is formed between the second partition ring 2143 and the third partition ring 2144, a sixth port 214a is communicated with the second flow guide groove 214e, a seventh port 214b is communicated with the first flow guide groove 214d, and an eighth port 214c is communicated with the inside of the first partition ring 2142. Furthermore, the center lines of the first partition ring 2142, the second partition ring 2143, and the third partition ring 2144 are located on the same straight line with the axis of the external thread 2141 of the upper water outlet base module.

Referring to fig. 8 and 9, correspondingly, a fourth separating ring 2262, a fifth separating ring 2263 and a sixth separating ring 2264 are sequentially arranged on the top of the lower water outlet top seat module 226 from inside to outside, a third diversion trench 226d is formed between the fourth separating ring 2262 and the fifth separating ring 2263, a fourth diversion trench 226e is formed between the fifth separating ring 2263 and the sixth separating ring 2264, a ninth interface 226a is communicated with the fourth diversion trench 226e, a tenth interface 226b is communicated with the third diversion trench 226d, and an eleventh interface 226c is communicated with the inside of the fourth separating ring 2262. Furthermore, the center lines of the fourth separating ring 2262, the fifth separating ring 2263 and the sixth separating ring 2264 are located on the same straight line with the axis of the threaded hole 2261 of the lower water outlet top seat module, the inside of the first separating ring 2142 corresponds to the inside of the fourth separating ring 2262, the first guide groove 214d corresponds to the third guide groove 226d, and the second guide groove 214e corresponds to the fourth guide groove 226 e.

Referring to fig. 6 to 9, after the upper and lower water outlet modules 21 and 22 are screwed together, the first partition ring 2142 is inserted into the interior of the fourth partition ring 2262, and the interior of the first partition ring 2142 is communicated with the interior of the fourth partition ring 2262; the second separating ring 2143 is inserted into the fifth separating ring 2263 and located between the fourth separating ring 2262 and the fifth separating ring 2263, and the first flow guiding groove 214d is communicated with the third flow guiding groove 226 d; the third separating ring 2144 is inserted into the sixth separating ring 2264 and located between the fifth separating ring 2263 and the sixth separating ring 2264, and the second guiding groove 214e is communicated with the fourth guiding groove 226 e. Moreover, the center lines of the first partition ring 2142, the second partition ring 2143, and the third partition ring 2144 are located on the same straight line as the axis line of the external thread 2141 of the upper water outlet base module, and the center lines of the fourth partition ring 2262, the fifth partition ring 2263, and the sixth partition ring 2264 are located on the same straight line as the axis line of the threaded hole 2261 of the lower water outlet top base module, so no matter how the upper water outlet base module 214 and the lower water outlet top base module 226 rotate, the interior of the first partition ring 2142 is still communicated with the interior of the fourth partition ring 2262, the first guide groove 214d is still communicated with the third guide groove 226d, and the second guide groove 214e is still communicated with the fourth guide groove 226 e. Further, a sealing ring is arranged between the outer wall of the first separating ring 2142 and the inner wall of the fourth separating ring 2262, a sealing ring is arranged between the outer wall of the second separating ring 2143 and the inner wall of the fifth separating ring 2263, and a sealing ring is arranged between the outer wall of the third separating ring 2144 and the inner wall of the sixth separating ring 2264, so that pure water and pure water can be effectively prevented from being mixed together. In addition, according to the above-mentioned matching relationship of the separation rings, it is also possible that the fourth separation ring 2262 is inserted into the interior of the first separation ring 2142, the fifth separation ring 2263 is inserted into the second separation ring 2143 and is located between the first separation ring 2142 and the second separation ring 2143, and the sixth separation ring 2264 is inserted into the third separation ring 2144 and is located between the second separation ring 2143 and the third separation ring 2144.

The above-mentioned embodiments only represent some embodiments of the present invention, and the description thereof is specific and detailed, but not to be construed as limiting the scope of the present invention. It should be noted that, for those skilled in the art, without departing from the spirit of the present invention, several variations and modifications can be made, which are within the scope of the present invention.

Claims (10)

1. A water outlet system (1), characterized in that the water outlet system (1) comprises:

a first end of the second water path (13) is used for connecting pure water, and a second end of the second water path (13) is connected with a first water nozzle (15);

the first end of the first water path (12) is used for being connected with pure water, one end of the third water path (14) is connected with a second water nozzle (16), a heating module (141) is arranged on the third water path (14), and the heating module (141) is used for heating the pure water.

2. The water outlet system (1) according to claim 1, characterized in that a pressure stabilizing module (142), a power module (143) are further provided on the third waterway (14); the pressure stabilizing module (142) is arranged on the water inlet side of the heating module (141), and the pressure stabilizing module (142) is used for reducing the water pressure of the pure water; the power module (143) is arranged between the pressure stabilizing module (142) and the heating module (141), and the power module (143) is used for providing power for the pure water with reduced water pressure to move to the second water nozzle (16).

3. A water outlet system (1) according to claim 2, characterized in that: a first temperature detection module (144) is further arranged on the third water path (14), the first temperature detection module (144) is arranged on the water inlet side of the heating module (141), and the first temperature detection module (144) is used for detecting the temperature of the pure water to enter the heating module (141).

4. A water outlet system (1) according to claim 2, characterized in that: a second temperature detection module (145) is further arranged on the third water path (14), the second temperature detection module (145) is arranged on the water outlet side of the heating module (141), and the second temperature detection module (145) is used for detecting the temperature of the pure water heated by the heating module (141).

5. A water outlet system (1) according to claim 2,

the pressure stabilizing module (142) is a water storage tank or a zero pressure valve; the power module (143) is an electric water pump;

a silicon controlled module (146) is further arranged on the third water path (14), the silicon controlled module (146) is arranged on the water inlet side of the heating module (141), and the silicon controlled module (146) is attached to a pipeline on the water inlet side of the heating module (141);

a path switching valve (121) is arranged on the second water path (13), a water outlet of the path switching valve (121) is connected with the first water nozzle (15), and a pure water inlet of the path switching valve (121) is connected with a first end of the second water path (13);

the water outlet system (1) further comprises:

the first end of the first waterway (12) is used for accessing purified water, and the second end of the first waterway (12) is connected with the purified water inlet of the route changing valve (121).

6. The water outlet system (1) according to claim 5, wherein:

the water outlet system (1) further comprises a water purifying assembly (11), wherein the water purifying assembly (11) is provided with a raw water port (11a), a purified water port (11b), a purified water port (11c) and a waste water port (11d), the first end of the first water channel (12) is connected with the purified water port (11b), the first end of the second water channel (13) is connected with the purified water port (11c), and the first end of the third water channel (14) is connected with the purified water port (11 c);

the water purification component (11) comprises a front filter element (111), an RO membrane filter element (112) and a rear filter element (113); the water inlet side of the preposed filter element (111) is communicated with the raw water port (11a), the water purification water outlet side of the preposed filter element (111) is communicated with the water purification water inlet side of the RO membrane filter element (112), and the water purification water outlet side of the preposed filter element (111) is also communicated with the water purification water port (11 b); the pure water outlet side of the RO membrane filter element (112) is communicated with the pure water port (11c), and the waste water outlet side of the RO membrane filter element (112) is communicated with the waste water port (11 d); the pure water inlet side of the rear filter element (113) is communicated with the pure water outlet side of the RO membrane filter element (112), and the pure water outlet side of the rear filter element (113) is communicated with the pure water port (11 c).

7. The water outlet system (1) according to claim 6, wherein:

the water purification assembly (11) further comprises a second connecting pipeline (117), a first end of the second connecting pipeline (117) is connected between the pure water outlet side of the rear filter element (113) and the pure water outlet (11c), a second end of the second connecting pipeline (117) is connected between the front filter element (111) and the RO membrane filter element (112), and a third electromagnetic valve (1171) and a one-way valve (1172) are arranged on the second connecting pipeline (117);

the third electromagnetic valve (1171) and the check valve (1172) are arranged on the second connecting pipeline (117) in sequence along the direction from the first end to the second end of the second connecting pipeline (117).

8. The water outlet system (1) according to claim 6, wherein: the water purification subassembly (11) still includes second connecting line (117), the first end of second connecting line (117) is connected the pure water play water side of rearmounted filter core (113) with between pure water mouth (11c), the second end of second connecting line (117) is connected leading filter core (111) with between RO membrane filter core (112) be provided with relief valve (1173) on second connecting line (117).

9. The outlet system (1) according to claim 7 or 8, wherein:

a first electromagnetic valve (114) and a booster pump (115) are sequentially arranged between the purified water outlet side of the preposed filter element (111) and the purified water inlet side of the RO membrane filter element (112) along the water flow direction;

the water purification assembly (11) further comprises a first connecting pipeline (116), a first end of the first connecting pipeline (116) is connected between the purified water outlet side of the preposed filter element (111) and the purified water port (11b), a second end of the first connecting pipeline (116) is connected between the first electromagnetic valve (114) and the booster pump (115), and a second electromagnetic valve (1161) and a flow limiting valve (1162) are arranged on the first connecting pipeline (116);

the second electromagnetic valve (1161) and the flow limiting valve (1162) are sequentially arranged on the first connecting pipeline (116) along the direction from the first end to the second end of the first connecting pipeline (116);

a second end of the second connecting pipeline (117) is connected between the first solenoid valve (114) and the booster pump (115);

a fourth electromagnetic valve (118) is arranged between the wastewater outlet side of the RO membrane filter element (112) and the wastewater outlet (11 d).

10. A water outlet device (2), characterized in that: comprising the outlet system (1) according to any of claims 1 to 9.

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