Disclosure of Invention
Aiming at the defects or shortcomings of the prior art, the invention provides the bubble water machine and the cleaning method thereof, the bubble water machine can convey hot water, normal-temperature water, cold water and bubble water to users by only arranging the booster pump in the whole machine, and the whole machine is more compact and convenient while the production cost of the bubble water machine is greatly reduced.
In order to achieve the above object, the present invention provides a bubbling water machine, which comprises a refrigerating device, a hot tank, and a water purifying device, a cold water tank and a bubbling water tank which are sequentially arranged along a water flow direction, wherein the refrigerating device is used for refrigerating the cold water tank;
the water purifier comprises a water tank, a cold water tank, a hot water tank, a normal-temperature water outlet pipeline and a water outlet pipeline, wherein the water outlet pipeline of the water purifier is connected with the cold water tank;
the cold water tank supplies water to the bubble water tank through a bubble tank water supply pipeline, and a cold water outlet pipeline is branched beside the bubble tank water supply pipeline;
the water purifier is characterized in that a booster pump is arranged on the upstream side of a water inlet of the water purifier or on the downstream side of the pure water outlet, and the booster pump is used for pumping pure water flow of the pure water outlet to the cold tank water supply pipeline, the hot tank water supply pipeline and the normal temperature water outlet pipeline.
Preferably, the booster pump is arranged at the upstream of the water purifying device, and the water flow rates of the cold tank water supply pipeline, the hot tank water supply pipeline and the normal-temperature water outlet pipeline are not less than 1.5L/min and not more than 2.5L/min.
Preferably, the upper reaches side of the water inlet of booster pump is equipped with parallelly connected first water intake pipe and second water intake pipe, first water intake pipe is connected with the water tank, the second water intake pipe is used for inserting municipal running water and is equipped with into water relief pressure valve, filter and external water solenoid valve along the rivers flow direction in proper order, the delivery port of booster pump with purifier's water inlet links to each other.
Preferably, the bubbling water machine comprises an air bottle for supplying air to the bubbling water tank, and an external air pipeline serving as a bypass pipeline is arranged on an air inlet pipeline connecting the air bottle and the bubbling water tank.
Preferably, the refrigerating device is used for refrigerating the bubble water tank; or the outer tank body of the bubble water tank is provided with a heat insulation layer.
Preferably, a four-way valve is connected to a pure water outlet of the water purifying device, and the four-way valve comprises an inlet end connected with the pure water outlet, a first outlet end connected with the cold tank water supply pipeline, a second outlet end connected with the hot tank water supply pipeline, and a third outlet end connected with the normal-temperature water outlet pipeline.
The invention also provides a cleaning method of the bubble water machine, which comprises a non-heat pipe cleaning step, wherein the non-heat pipe cleaning step comprises the following steps:
non-heat pipe soaking and washing: pumping the cleaning fluid mixed with the cleaning medium by the booster pump, filling the normal-temperature water outlet pipeline, the cold tank water supply pipeline, the bubble tank water supply pipeline, the cold water outlet pipeline, the cold water tank, the bubble water tank and the bubble water outlet pipeline connected with the bubble water tank, and standing;
a non-heat pipe flushing step: through the booster pump, use the clear water to wash normal atmospheric temperature outlet pipe way cold jar supply channel bubble jar supply channel cold water outlet pipe way bubble water outlet pipe way the cold water jar and the bubble water pitcher.
Preferably, in the non-heat pipe soaking step, when the booster pump is started, a first, a second and a third one of a normal temperature water outlet valve of the normal temperature water outlet pipeline, a cold water outlet valve of the cold water outlet pipeline and a bubble water outlet valve of the bubble water outlet pipeline are sequentially opened and closed, and when the third one is closed, the booster pump is synchronously closed and stands still; and/or the like and/or,
in the non-heat pipe flushing step, when the booster pump is started, a first, a second and a third of a normal-temperature water outlet valve of the normal-temperature water outlet pipeline, a cold-water outlet valve of the cold-water outlet pipeline and a bubble water outlet valve of the bubble water outlet pipeline are opened and closed in sequence in a circulating manner, and when the accumulated opening time of the normal-temperature water outlet valve, the cold-water outlet valve and the bubble water outlet valve reaches the non-heat pipe preset flushing time, the booster pump, the normal-temperature water outlet valve, the cold-water outlet valve and the bubble water outlet valve are closed simultaneously.
Preferably, after standing for a set time, repeating the non-heat pipe soaking and washing step.
Preferably, the cleaning method includes a heat pipe cleaning step, and the heat pipe cleaning step includes:
soaking and washing the heat pipe: pumping and filling the cleaning fluid mixed with the cleaning medium through the booster pump, filling the hot tank water supply pipeline, the hot tank and a hot tank water outlet pipeline connected with the hot tank, and standing;
a step of washing the heat pipe: through the booster pump, use the clear water to wash hot jar water supply pipeline, hot jar and hot jar outlet conduit.
Preferably, in the step of soaking and washing the heat pipe, the booster pump is started, and a hot tank water outlet valve arranged on the hot tank water supply pipeline or the hot tank water outlet pipeline is started at the same time, and when the opening time of the hot tank water outlet valve reaches the preset opening time of the heat pipe, the booster pump and the hot tank water outlet valve are synchronously closed; and/or the like and/or,
in the step of flushing the heat pipe, the booster pump is started, the hot tank water outlet valve arranged on the hot tank water supply pipeline or the hot tank water outlet pipeline is started at the same time, and when the accumulated opening time of the hot tank water outlet valve reaches the preset flushing time of the heat pipe, the booster pump and the hot tank water outlet valve are synchronously closed.
Preferably, after standing for a set time, the heat pipe soaking and washing step is repeated.
Preferably, the cleaning method further comprises a pressure relief step, wherein the pressure relief step comprises:
before the non-heat pipe cleaning step and the heat pipe cleaning step, simultaneously opening a normal-temperature water outlet valve of the normal-temperature water outlet pipeline, a cold-water outlet valve of the cold-water outlet pipeline and a bubble water outlet valve of the bubble water outlet pipeline, and when the opening time reaches preset pressure relief time, simultaneously closing the normal-temperature water outlet valve, the cold-water outlet valve and the bubble water outlet valve.
Preferably, after the pressure relief step and before the non-heat pipe cleaning step and the heat pipe cleaning step, a hollow pipe is used for replacing a filter element of the water purifying device.
Through the technical scheme, in the bubble water machine, the pure water outlet of the water purifying device is connected with the cold tank water supply pipeline, the hot tank water supply pipeline and the normal temperature water outlet pipeline which are arranged in parallel, the cold water tank supplies water to the bubble water tank through a bubble tank water supply pipeline, a cold water outlet pipeline is branched beside the bubble tank water supply pipeline, in addition, a booster pump is arranged on the upstream side of the water inlet of the water purifying device or the downstream side of the pure water outlet, wherein the booster pump is used for pumping the pure water flow at the pure water outlet to the cold tank water supply pipeline, the hot tank water supply pipeline and the normal temperature water outlet pipeline, so, just can carry hot water, normal atmospheric temperature water, cold water and bubble water in the bubble water machine to the user through a booster pump, not only can reduce the manufacturing cost of bubble water machine, but also can make the complete machine more small and exquisite pleasing to the eye to effectively promote user's use and experience.
Additional features and advantages of the invention will be set forth in the detailed description which follows.
Drawings
The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention. In the drawings:
fig. 1 and 2 are schematic structural views of a bubbling water machine according to a preferred embodiment of the present invention, wherein fig. 1 shows that a cup holder is restored and stored on a front panel, and fig. 2 shows that the cup holder is in an open state;
FIG. 3 is a schematic structural view of the front panel of FIG. 2, wherein the cup holder is in an open position;
FIG. 4 is an exploded view of a portion of the structure of FIG. 3;
FIG. 5 is a schematic view of the cup holder body and pivot bracket of FIG. 4;
FIG. 6 is a schematic structural view of the cover plate of FIG. 4;
FIG. 7 is a schematic view of the bottom structure of FIG. 5;
FIG. 8 is a schematic structural view of a dual canister assembly;
FIG. 9 is an exploded view of the structure of FIG. 8;
FIG. 10 is a schematic structural diagram of the cold water tank and the bubble water tank of FIG. 9 inserted into the cold tank cold guide and the bubble tank cold guide, wherein the coil evaporator is sequentially wound outside the cold tank cold guide and the bubble tank cold guide;
FIG. 11 is a schematic view of the structure of the insulating medium of FIG. 9;
FIG. 12A is a cross-sectional view of the cold water tank of FIG. 9;
fig. 12B is a schematic structural view of the bubbling water tank in fig. 9, in which the peripheral wall of the bubbling water tank is not shown;
FIGS. 13 and 14 are schematic structural views of the bubbling water machine of FIG. 2 with a portion of the casing removed, wherein FIG. 13 shows a right side view of the bubbling water machine, FIG. 14 shows a left side view of the bubbling water machine, and the hot tank is disposed in the hot tank shield;
FIG. 15 is a schematic view of a bracket of the bubbling water machine, in which the front bracket, the back bracket and the bottom bracket are integrally formed;
FIG. 16 is a schematic view of the gas cylinder of FIG. 14 pivotally connected to a divider plate;
FIG. 17 is a side view of FIG. 16;
FIG. 18 is an exploded view of the structure of FIG. 16;
FIG. 19 is a schematic pipeline flow diagram of the bubbling water machine in accordance with the preferred embodiment of the present invention;
FIG. 20 is a flow chart showing the steps of the cleaning method of the bubbling water machine in accordance with the first preferred embodiment of the present invention;
fig. 21 is a flowchart illustrating steps of a washing method of a bubbling water machine in accordance with a second preferred embodiment of the present invention.
Description of reference numerals:
200 cold water tank of 100 water purifier
300bubble water tank 400 hot tank
600 water tank of 500 booster pump
700gas cylinder 900 water receiving box
101filter element 201 cold tank cold guide part
301 double-tank positioning plate for bubble tankcold guide piece 302
303heat preservation medium 304 slow flow plate
801compressor 802 condenser
803coil type evaporator 804 fan heat dissipation assembly
1cup holder 2 casing
3water outlet nozzle 4 filter
7 double-tank assembly 8 hot tank shield
11 cup holdermain body 12 pivot support
13 cup basemagnetic attraction part 14 metal disc
22 casingmagnetic attraction piece 23 cup holder main body receiving groove
25 condenser heat-dissipatingvent 26 front panel
27cover plate 51 front support
52back support 53 bottom support
54division board 61 fixing seat
62 movable block
12A arch-shapedpiece 12B vertical locating piece
27A convex part
L1 Cold tank Water supply line L2 bubble tank Water supply line
L3 Cold Water Outlet line L4 bubble Water Outlet line
L5 Normal temperature Water outlet pipeline L6 Hot Water tank Water supply pipeline
L7 Hot tank Water outlet line L8 first Water inlet line
L10 air inlet pipeline of L9 second water inlet pipeline
L11 external air pipeline F1 four-way valve
F2 Cold Water Outlet valve F3 bubble Water Outlet valve
F4 Normal temperature outlet valve F5 Hot Water tank outlet valve
F6 external water electromagnetic valve F7 water inlet pressure reducing valve
F9 one-way valve for F8 gas cylinder pressure reducing valve
F10 bubble tank relief valve T1 cold tank temperature-sensing probe
T2 bubble tank temperature-sensing probe W1 bubble tank water level probe
Detailed Description
The following detailed description of embodiments of the invention refers to the accompanying drawings. It should be understood that the detailed description and specific examples, while indicating the present invention, are given by way of illustration and explanation only, not limitation.
It should be noted that the embodiments and features of the embodiments may be combined with each other without conflict.
In the present invention, unless specified to the contrary, use of the terms of orientation such as "upper, lower, top, bottom" or the like are generally described with respect to the orientation shown in the drawings or the positional relationship of the components with respect to each other in the vertical, or gravitational direction.
The present invention will be described in detail below with reference to the embodiments with reference to the attached drawings.
The invention provides a bubbling water machine, referring to fig. 1 and fig. 19, the bubbling water machine comprises a refrigerating device, a hot tank 400, a water purifying device 100, a cold water tank 200 and a bubbling water tank 300 which are sequentially arranged along the flow direction of water, wherein the refrigerating device is used for refrigerating the cold water tank 200; the pure water outlet of the water purifier 100 is connected with a plurality of pure water outlet pipelines which are arranged in parallel, and the plurality of pure water outlet pipelines comprise a cold tank water supply pipeline L1 connected with the cold water tank 200, a hot tank water supply pipeline L6 connected with the hot tank 400 and a normal temperature water outlet pipeline L5; the cold water tank 200 supplies water to the bubble water tank 300 through a bubble tank water supply pipeline L2, and a cold water outlet pipeline L3 is branched beside the bubble tank water supply pipeline L2; the water purifier 100 is provided with a booster pump 500 on the upstream side of the water inlet or the downstream side of the pure water outlet, and the booster pump 500 is used for pumping the pure water flow from the pure water outlet to the cold tank water supply pipeline L1, the hot tank water supply pipeline L6 and the normal temperature water outlet pipeline L5.
In the technical scheme, thebooster pump 500 is arranged on the upstream side of the water inlet of thewater purifying device 100 or on the downstream side of the pure water outlet, so that the bubble water machine can convey hot water, normal-temperature water, cold water and bubble water to a user only through thebooster pump 500, and thus, a plurality of booster pumps 500 are not required to be arranged in the bubble water machine to convey fluid, namely, onebooster pump 500 is arranged in the bubble water machine, so that the number of the booster pumps 500 required to be arranged in the bubble water machine is small, the production cost of the whole machine can be greatly reduced, the occupied space of the whole machine can be effectively reduced, and the transportation cost and the storage cost of the bubble water machine are favorably reduced. In addition, the bubble water machine is small in size, the whole machine is small and attractive, and the use experience of a user is improved.
Specifically, referring to fig. 19, thebooster pump 500 is started, and the normal temperature water outlet pipeline L5 is connected, so that the bubbling water machine can supply normal temperature water to a user, and then thebooster pump 500 is stopped and the normal temperature water outlet pipeline L5 is cut off, so that the bubbling water machine stops outputting the normal temperature water; similarly, when the user needs to drink hot water from thehot tank 400, thebooster pump 500 is started, and the hot tank water supply pipeline L6 and the hot tank water outlet pipeline L7 connected with thehot tank 400 are simultaneously communicated, and when the user finishes taking the hot water, thebooster pump 500 is stopped, and the hot tank water supply pipeline L6 and the hot tank water outlet pipeline L7 are simultaneously cut off; thebooster pump 500 is started, and the cold water tank water supply line L1, the bubble tank water supply line L2 and the cold water outlet line L3 are simultaneously communicated, the bubbling water machine can supply cold water from thecold water tank 200 to a user, thebooster pump 500 is turned off, the cold water outlet line L3 is cut off, and the bubbling water machine stops supplying cold water to the user. In addition, air (such as carbon dioxide gas) is continuously supplied to thebubble water tank 300 through the air inlet line L10, the cold water in thecold water tank 200 is pressed into thebubble water tank 300 through thebooster pump 500, so that water and air are mixed in thebubble water tank 300 to form bubble water, and the tank pressure of thebubble water tank 300 is relatively high (up to 6MPa to 9MPa), so that the bubble water in thebubble water tank 300 can be pressed out through the bubble water outlet line L4 when the bubble water outlet line L4 connected to thebubble water tank 300 is connected, and the bubble water outlet line L4 is cut off when the user finishes taking the bubble water.
Preferably, thebooster pump 500 is disposed at the upstream of thewater purifying apparatus 100, and referring to fig. 19, in this way, the water flow rates of the cold tank water supply pipeline L1, the hot tank water supply pipeline L6 and the normal temperature water outlet pipeline L5 are not less than 1.5L/min and not more than 2.5L/min, that is, the water flow rates of the cold water, the hot water and the normal temperature water respectively output to the user through the cold water outlet pipeline L3, the hot tank water outlet pipeline L7 and the normal temperature water outlet pipeline L5 are all between 1.5L/min and 2.5L/min, so that by disposing thebooster pump 500 at the upstream of thewater purifying apparatus 100, the water outlet flow rate of the bubbling water machine is increased, the water receiving time of the user is favorably shortened, and the user has better use experience. Of course, thebooster pump 500 may be disposed at the downstream of thewater purifying device 100, and the operation pressure and resistance of thebooster pump 500 are small, which is beneficial to reducing the operation noise of thebooster pump 500 and improving the user experience.
Specifically, the upper reaches side ofbooster pump 500's water inlet is equipped with parallelly connected first inlet channel L8 and second inlet channel L9, first inlet channel L8 is connected withwater tank 600, second inlet channel L9 is used for inserting municipal tap water and is equipped with into water relief pressure valve F7 along the rivers flow direction in proper order,filter 4 and external water solenoid valve F6,booster pump 500's delivery port links to each other withpurifier 100's water inlet, refer to fig. 19, thus, can satisfy user's multi-scene application demand, namely, the user accessible adds water in towardwater tank 600 in order to provide the water source, also can choose external municipal tap water for use as the water source for use, be favorable to promoting user's use and experience.
In addition, in order to supply air into the bubblingwater tank 300, referring to fig. 19, the bubbling water machine includes anair bottle 700 for supplying air into the bubblingwater tank 300. However, the specification of thegas cylinder 700 suitable for the domestic bubbling water machine is small, so that the replacement period of thegas cylinder 700 is short, and frequent replacement is not beneficial to convenient use of a user, therefore, an external gas pipeline L11 serving as a bypass pipeline is preferably arranged on a gas inlet pipeline L10 connecting thegas cylinder 700 and the bubblingwater tank 300, so that the user can supply gas to the external gas cylinder arranged outside the complete machine through the external gas pipeline L11, and the specification of the external gas cylinder can not be limited by the space of the complete machine, so that the user can purchase the external gas cylinder with a large specification by himself, the replacement frequency of thegas cylinder 700 can be greatly reduced, and the use and operation of the user are facilitated. Of course, the external air pipeline L11 serving as a bypass pipeline is arranged on the air inlet pipeline L10, so that the multi-scene application requirements of the user can be met, and the use experience of the user can be improved.
Preferably, the pure water outlet of thewater purifying device 100 is connected with a four-way valve F1, the four-way valve F1 includes an inlet end connected with the pure water outlet, a first outlet end connected with the cold tank water supply pipeline L1, a second outlet end connected with the hot tank water supply pipeline L6, and a third outlet end connected with the normal temperature water outlet pipeline L5, as shown in fig. 19, so that the number of pipe fittings required to be arranged on the pipeline can be reduced, which is beneficial to reducing the production cost of the whole machine. In addition, the number of the pipe fittings arranged on the pipeline is small, the water leakage risk of the whole machine can be reduced, the use experience of a user can be improved, and the assembly efficiency of the whole machine can be improved by reducing the assembly processes.
Specifically, since the temperature difference between the pure water from thewater purifying apparatus 100 and the water temperature (about 4 ℃) when the bubble water inlet feeling is optimal is large (about 25 ℃), it takes a long time for thecold water tank 200 to cool the normal temperature water if the refrigerating apparatus cools only thecold water tank 200, and the cold water in thecold water tank 200 is pushed into thebubble water tank 300 when the water temperature in thecold water tank 200 approaches the optimal mouth feeling water temperature of the bubble water, and thus, the refrigerating apparatus preferably cools thebubble water tank 300 to greatly shorten the time for the user to wait for the drinking of the bubble water. Thecold water tank 200 and thebubble water tank 300 may be independently cooled or may be simultaneously cooled. The refrigerating apparatus may cool only thecold water tank 200 and may maintain the low temperature state of the bubble water in thebubble water tank 300 by providing an insulating layer on the outer tank of thebubble water tank 300.
The invention provides a bubbling water machine, which comprises amachine shell 2, awater outlet nozzle 3 and acup seat 1, wherein thewater outlet nozzle 3 and thecup seat 1 are positioned on the front side of themachine shell 2, and thecup seat 1 is positioned right below thewater outlet nozzle 3 and can be reset and stored on afront panel 26 of themachine shell 2.
In the technical scheme, thecup seat 1 is positioned under thewater outlet nozzle 3, and thecup seat 1 can be reset and stored on thefront panel 26 of themachine shell 2, so that when a user uses a shorter cup body for containing liquid, the shorter cup body can be placed on thecup seat 1, and the height difference between thewater outlet nozzle 3 and the shorter cup body can be effectively shortened, therefore, when thewater outlet nozzle 3 flows out of the liquid, the liquid flowing into the shorter cup body can be effectively prevented from splashing out of the cup, and the use experience of the user can be greatly improved; when a user uses a higher cup body to contain liquid, thecup seat 1 can be reset and contained on thefront panel 26 of theshell 2, and then the higher cup body is placed below thewater outlet nozzle 3, so that the use and operation of the user are facilitated.
Preferably, referring to fig. 1 and 2, awater receiving box 900 located right below thewater outlet nozzle 3 is arranged at the bottom of the front side of thecasing 2, and thecup holder 1 is located above thewater receiving box 900, so that when the cup of a user is short, thecup holder 1 is placed on thecup holder 1 to receive water, and when the cup of the user is high, thecup holder 1 is reset to be stored, and then the cup is placed on thewater receiving box 900 to receive water. In addition,water receiver 900 is used for accepting the liquid that flows out fromfaucet 3 and does not fall into user's cup to prevent to pollute user's operation mesa, be favorable to improving user's use and experience.
Preferably, thecup holder 1 comprises a cup holdermain body 11 and a pivotingbracket 12, and the pivotingbracket 12 is pivotally connected to thefront panel 26, and referring to fig. 2 to 4, the connection mode of thecup holder 1 and thefront panel 26 is simple in structure and high in operation reliability. Of course, thecup holder 1 and thefront panel 26 may be connected in other suitable manners, such as providing a mounting seat on the back of thefront panel 26, and thecup holder 1 may be linearly inserted into the mounting seat from the front side of thefront panel 26 laterally inwards and can extend laterally outwards for holding a cup body, etc., which is not illustrated herein.
Specifically, referring to fig. 1 to 5, thepivot bracket 12 includes an arch 12A extending upward from the cup holdermain body 11 and a vertical position-limitingmember 12B extending downward from a distal end of the arch 12A, thefront panel 26 is provided with a through hole for the arch 12A and the vertical position-limitingmember 12B to pass through, a bottom end of the vertical position-limitingmember 12B is disposed below the through hole and pivotally connected to a back surface of thefront panel 26, so that when thecup holder 1 is opened, the vertical position-limitingmember 12B is limited to abut against the back surface of thefront panel 26, so that the cup holdermain body 11 can be stably in a horizontally-tilted state; when thecup holder 1 is returned and stored, the cup holdermain body 11 is attached to the front surface of thefront panel 26.
Preferably, the bubbling water machine includes acover plate 27 having aprotrusion 27A, and referring to fig. 2, 4 and 6, when thecover plate 27 is mounted on the back surface of thefront panel 26, theprotrusion 27A is inserted into the upper portion of the through hole, so that when the user opens or resets thecup holder 1, the internal components in thehousing 2 can be prevented from being exposed from the through hole, and the whole machine is more beautiful. Specifically, when thecup holder 1 is assembled on thehousing 2, the arch 12A and thevertical stopper 12B are inserted into the housing from the front side of thefront panel 26 through the through hole, and then thevertical stopper 12B is disposed below the through hole and pivotally connected to the back side of thefront panel 26, so that when thecup holder 1 is opened and reset, the arch 12A reciprocates in the lower portion of the through hole, the upper portion of the through hole is not blocked, and the internal components in the internal cavity of the housing are exposed therefrom.
In order to make most of the short cups on the market placed on the cup holdermain body 11 with a good effect of preventing liquid from splashing out of the cup, the distance between the bottom end of thespout 3 and the cup holdermain body 11 when thecup holder 1 is opened should preferably be not less than 100mm and not more than 150 mm.
Preferably, referring to fig. 1, 3, 4 and 7, the cup holdermain body 11 is provided with a cup holdermagnetic attraction piece 13, and thefront panel 26 is correspondingly provided with a casemagnetic attraction piece 22, so as to set up, when a user needs to reset and store thecup holder 1, the user only needs to pivot the horizontally placed cup holdermain body 11 to be attached to thefront panel 26, and the cup holdermain body 11 is fixedly stored on thefront panel 26 by the attraction force of the cup holdermagnetic attraction piece 13 and the casemagnetic attraction piece 22, thereby facilitating the use and operation of the user. Of course, thecup holder body 11 can be attached to and received in thefront panel 26 by means of a snap, etc., and will not be described herein again.
In addition, the cupmain body 11 is discoid and the top dish face and the chassis face all are equipped with themetal disc 14 as decorating the usefulness, and the preceding cup main body that is equipped with the cupmain body 11 adaptation offront panel 26accomodates groove 23, refer to fig. 1, fig. 2 and fig. 4, like this, no matter when thecup 1 is opened, still when thecup 1 resets and accomodates, all can make the complete machine comparatively pleasing to the eye, be favorable to improving user's use and experience.
Preferably, referring to fig. 9, 10, 13 and 19, the bubbling water machine includes a refrigeration device, and awater purification device 100, acold water tank 200 and a bubblingwater tank 300 which are sequentially arranged along a water flow direction, the refrigeration device includes acompressor 801, acondenser 802 and acoil evaporator 803 which are sequentially arranged in a refrigerant loop, thecold water tank 200 and the bubblingwater tank 300 are respectively sleeved with a cold tankcold guide 201 and a bubbling tankcold guide 301, and thecoil evaporator 803 is sequentially wound on the outer peripheral walls of the cold tankcold guide 201 and the bubbling tankcold guide 301. It can be understood that since the pure water from thewater purifying apparatus 100 is normal temperature water and the temperature difference from the water temperature (about 4 ℃) when the bubble water inlet feeling is optimal is large, the refrigerating apparatus can refrigerate thebubble water tank 300 as well as thecold water tank 200 in order to greatly shorten the time for the user to wait for drinking the bubble water. Thecold water tank 200 and thebubble water tank 300 may be independently cooled or simultaneously cooled. In addition, the cold tankcold guide 201 and the bubble tankcold guide 301 are additionally arranged outside thecold water tank 200 and thebubble water tank 300, so that the situation of local supercooling of thecold water tank 200 and thebubble water tank 300 can be avoided, and the temperature of liquid in thecold water tank 200 and thebubble water tank 300 is uniform.
Further, the bubbling water machine comprises a double-tank positioning plate 302 provided with a positioning groove, and referring to fig. 9, the tops of thecold water tank 200 and the bubblingwater tank 300 are fittingly sleeved in the positioning groove. Specifically, thecoil evaporator 803 is sequentially wound on the cold tankcold guide piece 201 and the bubble tankcold guide piece 301, at this time, the cold tankcold guide piece 201 and the bubble tankcold guide piece 301 are connected through thecoil evaporator 803, then thecold water tank 200 and thebubble water tank 300 are respectively inserted into the cold tankcold guide piece 201 and the bubble tankcold guide piece 301, then the double-tank positioning plate 302 is sleeved on the tops of thecold water tank 200 and thebubble water tank 300, and finally the cold tankcold guide piece 201 and the bubble tankcold guide piece 301 are respectively fastened on thecold water tank 200 and thebubble water tank 300 by adopting a fixed connection mode such as screws or rivets, so that thecold water tank 200 and thebubble water tank 300 form a double-tank assembly 7 with a compact structure, the occupied space is small, and the whole machine can be more compact.
Preferably, theheat preservation medium 303 is arranged outside thecold water tank 200 and thebubble water tank 300, and referring to fig. 8 and 9 to 11, that is, the cold guide member, thecoil evaporator 803 and theheat preservation medium 303 are arranged outside the tanks in sequence, so that the cold loss of thecoil evaporator 803 can be effectively reduced, and the energy efficiency of the refrigerating device and the whole machine can be improved.
Specifically, referring to fig. 8 to 11, theheat insulating medium 303 is preferably a foam heat insulating layer and includes a left foam heat insulating layer and a right foam heat insulating layer which are fastened to each other, the cold tankcold conducting piece 201 and the bubble tankcold conducting piece 301 coiled with the coiledpipe evaporator 803 are placed in any one of the left foam heat insulating layer and the right foam heat insulating layer, the double-tank positioning plate 302 is sleeved on the tops of the cold tankcold conducting piece 201 and the bubble tankcold conducting piece 301, the cold tankcold conducting piece 201 and the bubble tankcold conducting piece 301 are fastened to thecold water tank 200 and thebubble water tank 300 respectively by adopting a fixing connection manner such as screws or rivets, and finally, the remaining foam heat insulating layers are fastened to form the double-tank assembly 7 with a compact structure.
In addition, referring to fig. 12A,purifier 100 supplies water tocold water tank 200 through cold water tank water supply line L1, and cold water tank water supply line L1 is from last to stretching intocold water tank 200 and stretching into the end and be the U-shaped from the roof ofcold water tank 200, so, can effectively slow down the impact of the normal atmospheric temperature water that comes frompurifier 100 to the cold water incold water tank 200, be favorable to slowing down the scurrying of normal atmospheric temperature water and cold water. In addition, an exhaust hole which can be opened and closed is opened at the upper part of thecold water tank 200, and when liquid is introduced into thecold water tank 200 for the first time, the exhaust hole is opened to exhaust the air in thecold water tank 200.
It should be noted that, referring to fig. 12A, 12B and 19, since the temperature of the liquid in thebubble water tank 300 is generally lower at the lower water temperature than at the upper water temperature, the arrangement of the water inlet end of the bubble water outlet line L4 at the bottom of thebubble water tank 300 ensures not only a sufficient outlet water pressure but also a preferential output of the bubble water at a lower temperature. The same applies to the arrangement of the water inlet end of the bubble tank water supply line L2 at the bottom of thecold water tank 200. In addition, a cold water tank temperature sensing probe T1 for detecting the water temperature in thecold water tank 200 in real time is arranged; a bubble tank temperature sensing probe T2 for detecting the temperature of water in the tank in real time, a bubble tank water level probe W1 for detecting the water level in the tank in real time, and a bubble tank relief valve F10 for monitoring the air pressure in the tank in real time are provided in thebubble water tank 300, and the bubble tank water level probe W1 is used to ensure the stability of the air pressure in thebubble water tank 300.
Thecold water tank 200 and thebubble water tank 300 are respectively internally provided with the cold water tank temperature sensing probe T1 and the bubble water tank temperature sensing probe T2, so that icing caused by too low temperature of liquid in the tank can be prevented, thecold water tank 200, thebubble water tank 300 and corresponding pipelines (such as a bubble tank water supply pipeline L2, a bubble water outlet pipeline L4 and the like) are prevented from being burst, and the reliability of the whole machine operation is improved. In addition, when the water level in thebubble water tank 300 sensed by the bubble tank water level probe W1 is less than the preset lower water level threshold of the bubble tank, thebooster pump 500 is controlled to be started so that the cold water in thecold water tank 200 is pressed into thebubble water tank 300, and then the bubble water is prepared, so that the situation of insufficient bubble water when the user needs to drink the bubble water can be prevented.
Preferably, a nozzle is provided at the extending end of the water supply pipeline L2 of thebubble water tank 300, so that the liquid entering thebubble water tank 300 is in a spraying state, thus not disturbing the temperature field of the liquid in thebubble water tank 300, but also increasing the dissolution rate of carbon dioxide in the liquid, and thus the outputted bubble water has a better water temperature and a better drinking taste. Alternatively, instead of using a nozzle at the extended end of the bubble tank water supply line L2, abaffle plate 304 for receiving and slowly flowing water may be disposed in thebubble water tank 300, such that the liquid flowing into thebubble tank 300 from the bubble tank water supply line L2 drops onto thebaffle plate 304 and slowly flows into the water in thebubble water tank 300 through the edge of thebaffle plate 304.
Preferably, referring to fig. 13 and 15, the bubbling water machine includes afront bracket 51, aback bracket 52 and abottom bracket 53 which are integrally formed, so that compared with the case that thefront bracket 51, theback bracket 52 and thebottom bracket 53 are respectively formed and then assembled together, the integrally formed bracket has stronger supporting strength, and thefront bracket 51, theback bracket 52 and thebottom bracket 53 do not need to be assembled by extra labor, which is also beneficial to improving the assembly efficiency of the whole machine. Afront panel 26 is mounted on the front of thefront bracket 51. In addition, the upstream side ofwater purifier 100's water inlet or the downstream side of pure water delivery port are equipped withbooster pump 500, andbooster pump 500 andcompressor 801 all set up on the top surface ofbottom bracket 53, like this, still are favorable to the shock attenuation to promote user's use and experience.
Further, a vertically arrangedseparation plate 54 is arranged above thebooster pump 500 and thecompressor 801, the front end and the rear end of theseparation plate 54 are respectively and fixedly connected with thefront bracket 51 and theback bracket 52, referring to fig. 13 to 15, afilter element 101 of thewater purifying device 100 and anair cylinder 700 for supplying air to thebubble water tank 300 are arranged on one side of theseparation plate 54, and acold water tank 200 and abubble water tank 300 are arranged on the other side of theseparation plate 54, so that the inner cavity of the casing can be divided into three relatively independent spaces by additionally arranging theseparation plate 54, namely, thecompressor 801 and thebooster pump 500 below the separation plate, thefilter element 101 and theair cylinder 700 on one side of the separation plate, and thecold water tank 200 and thebubble water tank 300 on the other side of the separation plate, so that thefilter element 101 and theair cylinder 700 are arranged on the same side.
Preferably, referring to fig. 14, 16 to 18, the bubbling water machine includes a gas cylinder pressure reducing valve F8 pivotally mounted on thepartition plate 54, and a mouth of thegas cylinder 700 is inserted into an inlet valve port of the gas cylinder pressure reducing valve F8. Specifically, the bubbling water machine further comprises a fixedseat 61 fixedly mounted on thepartition plate 54 and amovable block 62 pivotally connected with the fixedseat 61, and the gas cylinder pressure reducing valve F8 is fixedly connected with themovable block 62. So configured, thegas cylinder 700 may pivot with the gas cylinder pressure reducing valve F8, thus facilitating replacement of thegas cylinder 700 by a user.
In addition, the condenser heat dissipation opening 25 is formed in theback support 52, referring to fig. 13 and 15, the fanheat dissipation assembly 804 and thecondenser 802 which are sequentially stacked on the condenser heat dissipation opening 25 are arranged in front of the back panel, so that heat dissipated by thecondenser 802 can be discharged out of the whole machine through the condenser heat dissipation opening 25 through the fanheat dissipation assembly 804, normal operation of thecondenser 802 is guaranteed, the service life of thecondenser 802 and even the service life of the whole machine are prolonged, and use experience of a user is improved.
The present invention further provides a cleaning method of the bubble water machine, referring to fig. 20 and 21, the cleaning method includes a non-heat pipe cleaning step, and the non-heat pipe cleaning step includes:
non-heat pipe soaking and washing: the cleaning fluid mixed with the cleaning medium is pumped and filled in the normal temperature water outlet line L5, the cold tank water supply line L1, the bubble tank water supply line L2, the cold water outlet line L3, thecold water tank 200, thebubble water tank 300, and the bubble water outlet line L4 connected to thebubble water tank 300 by thebooster pump 500, and is left standing;
a non-heat pipe flushing step: the normal temperature water outlet line L5, the cold tank water supply line L1, the bubble tank water supply line L2, the cold water outlet line L3, the bubble water outlet line L4, thecold water tank 200, and thebubble water tank 300 are flushed with clean water by thebooster pump 500.
Wherein, in order to make the cleaning fluid fully contact with the dirt in the pipeline and further dissolve or fall off the dirt, the standing time is not less than 2 minutes and not more than 4 minutes. In addition, after the pipeline is kept still for a set time, the non-heat pipe soaking and washing step is repeated, in the process, the cleaning fluid with dirt can be discharged, and meanwhile, the pipeline is filled with fresh cleaning fluid again, so that the soaking and washing pipeline soaking and descaling effect can be improved.
Preferably, in the non-heat pipe soaking and washing step, when thebooster pump 500 is started, the first, second and third ones of the normal temperature water outlet valve F4 of the normal temperature water outlet pipeline L5, the cold water outlet valve F2 of the cold water outlet pipeline L3 and the bubble water outlet valve F3 of the bubble water outlet pipeline L4 are sequentially opened and closed, and when the third one is closed, thebooster pump 500 is synchronously closed and stands still. Specifically, the sequence of opening and closing the normal-temperature water outlet valve F4, the cold-water outlet valve F2, and the bubble-water outlet valve F3 is not limited, that is, the normal-temperature water outlet valve F4 is opened and closed first, then the cold-water outlet valve F2 is opened and closed, and finally the bubble-water outlet valve F3 is opened and closed; or the bubble water outlet valve F3 can be opened and closed firstly, then the normal temperature outlet valve F4 is opened and closed, and finally the cold water outlet valve F2 is opened and closed. In order to fill the pipeline with the cleaning fluid, the opening time of each of the normal-temperature water outlet valve F4, the cold-water outlet valve F2 and the bubble water outlet valve F3 is not less than 40 seconds and not more than 80 seconds.
In addition, in the non-heat pipe flushing step, when thebooster pump 500 is started, the first, the second and the third of the normal temperature water outlet valve F4 of the normal temperature water outlet pipeline L5, the cold water outlet valve F2 of the cold water outlet pipeline L3 and the bubble water outlet valve F3 of the bubble water outlet pipeline L4 are cyclically opened and closed in sequence, and when the accumulated opening time of the normal temperature water outlet valve F4, the cold water outlet valve F2 and the bubble water outlet valve F3 reaches the non-heat pipe preset flushing time, thebooster pump 500, the normal temperature water outlet valve F4, the cold water outlet valve F2 and the bubble water outlet valve F3 are closed at the same time. Specifically, the sequential opening and closing sequence of the normal temperature outlet valve F4, the cold water outlet valve F2, and the bubble water outlet valve F3 is not limited, as long as the normal temperature outlet valve F4, the cold water outlet valve F2, and the bubble water outlet valve F3 are opened and closed once in one opening and closing cycle, for example, the sequence of opening and closing once may be the normal temperature outlet valve F4, the cold water outlet valve F2, and the bubble water outlet valve F3, or the sequence of opening and closing once may be the cold water outlet valve F2, the normal temperature outlet valve F4, the bubble water outlet valve F3, and the like. Wherein, the opening time of the normal temperature water outlet valve F4, the cold water outlet valve F2 and the bubble water outlet valve F3 is not less than 10 seconds and not more than 30 seconds. In addition, in order to achieve a better pipeline flushing effect, the non-heat pipe preset flushing time should be not less than 4 minutes and not more than 6 minutes.
Preferably, referring to fig. 20 and 21, the cleaning method includes a heat pipe cleaning step including:
soaking and washing the heat pipe: the cleaning fluid mixed with the cleaning medium is pumped and filled in the hot tank water supply line L6, thehot tank 400, and the hot tank water outlet line L7 connected to thehot tank 400 by the pressurizingpump 500, and is left to stand;
a step of washing the heat pipe: the hot tank water supply line L6, thehot tank 400, and the hot tank water outlet line L7 are flushed with clean water by the pressurizingpump 500.
Wherein, in order to make the cleaning fluid fully contact with the dirt in the pipeline and further dissolve or fall off the dirt, the standing time is not less than 4 minutes and not more than 6 minutes. In addition, after the heat pipe is kept still for a set time, the soaking and washing steps of the heat pipe are repeated, in the process, the cleaning fluid with dirt can be discharged, and meanwhile, the pipeline is filled with fresh cleaning fluid again, so that the soaking and washing pipeline soaking and descaling effect can be improved.
Preferably, in the step of soaking and washing the heat pipe, thebooster pump 500 is started, and the hot pot water outlet valve F5 provided on the hot pot water supply line L6 or the hot pot water outlet line L7 is started at the same time, and when the opening time of the hot pot water outlet valve F5 reaches the preset opening time of the heat pipe, thebooster pump 500 and the hot pot water outlet valve F5 are synchronously closed. Wherein, in order to fill the pipeline with the cleaning fluid, the preset opening time of the heat pipe is not less than 20 seconds and not more than 80 seconds.
In addition, in the step of flushing the heat pipe, thebooster pump 500 is started, and the hot tank outlet valve F5 provided on the hot tank water supply line L6 or the hot tank outlet line L7 is started at the same time, and when the cumulative opening time of the hot tank outlet valve F5 reaches the preset flushing time of the heat pipe, thebooster pump 500 and the hot tank outlet valve F5 are synchronously closed. Wherein, in order to achieve better pipeline flushing effect, the preset flushing time of the heat pipe should be not less than 1 minute and not more than 3 minutes.
Specifically, since the cleaning method in the present invention uses the cleaning fluid to clean the pipeline, in order to avoid damaging thefilter element 101, thefilter element 101 should be removed from the pipeline before cleaning the pipeline, and the hollow tube is used to replace thefilter element 101 and installed in the pipeline, but thefilter element 101 is connected to the pipeline, so that the pipeline at the downstream of thefilter element 101 is in a pressure-bearing state, which makes it difficult for a user to remove thefilter element 101 from the pipeline, and is inconvenient for the user to use and operate, and therefore, the cleaning method preferably further includes a pressure relief step. In addition, the user may add cleaning fluid or clean water into the water tank for cleaning the bubble water machine, or may connect the cleaning fluid or clean water into the second water inlet line L9 for cleaning the bubble water machine.
Preferably, with reference to fig. 20 and 21, the pressure relief step comprises: before the non-heat pipe cleaning step and the heat pipe cleaning step, simultaneously opening a normal-temperature water outlet valve F4 of a normal-temperature water outlet pipeline L5, a cold-water outlet valve F2 of a cold-water outlet pipeline L3 and a bubble water outlet valve F3 of a bubble water outlet pipeline L4, and when the opening time reaches a preset pressure relief time, simultaneously closing the normal-temperature water outlet valve F4, the cold-water outlet valve F2 and the bubble water outlet valve F3. The preset pressure relief time is preferably not less than 4 seconds and not more than 10 seconds, so that the pressure in the pipeline can be well relieved.
It should be noted that, the cleaning method of the bubbling water machine in the present invention may be to perform the pressure relief step first, then replace thefilter element 101 with the hollow tube, then perform the non-heat pipe cleaning step, and finally perform the hot tank cleaning step, refer to fig. 20; or the pressure relief step can be performed first, then the hollow tube is used for replacing thefilter element 101, then the hot tank cleaning step is performed, and finally the non-heat pipe cleaning step is performed, referring to fig. 21; the pressure relief step can be performed first, then the hollow tube is used for replacing thefilter element 101, then the non-heat-tube soaking and washing step and the heat-tube soaking and washing step are performed, and finally the non-heat-tube washing step and the heat-tube washing step are performed, which are not shown in the description.
In particular, other configurations of the bubbling water machine according to the present invention are known to those skilled in the art, and are not described herein in detail in order to reduce redundancy.
The present invention is not limited to the above preferred embodiments, and any modifications, equivalent substitutions, improvements, etc. within the spirit and principle of the present invention should be included in the protection scope of the present invention.
It should be noted that the various technical features described in the above embodiments can be combined in any suitable manner without contradiction, and the invention is not described in any way for the possible combinations in order to avoid unnecessary repetition.
In addition, any combination of the various embodiments of the present invention is also possible, and the same should be considered as the disclosure of the present invention as long as it does not depart from the spirit of the present invention.