CN204699512U - Water purifier - Google Patents

Abstract

The disclosure is directed to water purifier, comprising: condition detection architecture, be arranged in the water route of described water purifier, described condition detection architecture can detect the flow condition of described water purifier; Controller, is connected to described condition detection architecture and water quantity regulating structure, when described flow condition changes, sends runoff investigation instruction to described water quantity regulating structure; Described water quantity regulating structure, be arranged in the condensed water output pipe of described water purifier, regulate the water yield of described condensed water output pipe according to described runoff investigation instruction, trend towards preset ratio with the ratio of the purification water yield and the concentrated water yield that maintain the output of described water purifier.By technical scheme of the present disclosure, the water yield can be exported to the condensed water of water purifier and carry out dynamic adjustments, to guarantee the constant rate purifying the water yield and the concentrated water yield, avoid because flow condition change causes the purification water yield and the concentrated water yield out of proportion, affect the experience of filter element performance in water purifier and user.

Description

Water purifier

Technical field

The disclosure relates to water purifier technical field, particularly relates to water purifier.

Background technology

Water purifier, or also known as water purifier, may be used for the floating thing in filtering water, heavy metal, germ etc., therefore can not only remove the peculiar smell that iron rust, bleaching powder etc. cause, water quality safety can also be guaranteed, even can directly drink.

Utility model content

The disclosure provides water purifier, to solve the deficiency in correlation technique.

According to the first aspect of disclosure embodiment, a kind of water purifier is provided, comprises:

Condition detection architecture, be arranged in the water route of described water purifier, described condition detection architecture can detect the flow condition of described water purifier;

Controller, is connected to described condition detection architecture and water quantity regulating structure, when described flow condition changes, sends runoff investigation instruction to described water quantity regulating structure;

Described water quantity regulating structure, be arranged in the condensed water output pipe of described water purifier, regulate the water yield of described condensed water output pipe according to described runoff investigation instruction, trend towards preset ratio with the ratio of the purification water yield and the concentrated water yield that maintain the output of described water purifier.

Optionally, described condition detection architecture comprises:

Temperature sensor, described temperature sensor detects the inflow temperature of described water purifier, using as described flow condition; Wherein, the runoff investigation instruction of described controller generation is interval relevant to the preset temperature residing for described inflow temperature;

Described water quantity regulating structure regulates the water yield of described condensed water output pipe according to the runoff investigation instruction received, and water yield and described preset temperature interval are proportionate.

Optionally, described temperature sensor is arranged in the intake line of not purifying waste water of described water purifier.

Optionally, the setting position of described temperature sensor is near the water inlet of described intake line of not purifying waste water.

Optionally, described condition detection architecture comprises:

Hydraulic pressure sensor, described hydraulic pressure sensor detects the intake pressure of described water purifier, using as described flow condition; Wherein, the runoff investigation instruction of described controller generation is interval relevant to the preset pressure residing for described intake pressure;

Described water quantity regulating structure regulates the water yield of described condensed water output pipe according to the runoff investigation instruction received, and water yield and described preset pressure interval are proportionate.

Optionally, comprise osmosis filtration structure in described water purifier and be arranged at the booster water pump of described osmosis filtration structure front end; Wherein, described hydraulic pressure sensor is arranged in the water route of described booster water pump front end.

Optionally, described condition detection architecture comprises:

Water quality sensor, described water quality sensor detects the influent quality of described water purifier, using as described flow condition; Wherein, the runoff investigation instruction of described controller generation is interval relevant to the preset quality residing for described influent quality;

Described water quantity regulating structure regulates the water yield of described condensed water output pipe according to the runoff investigation instruction received, and water yield and described preset quality interval are in inverse correlation.

Optionally, described influent quality comprise following one of at least: total dissolved solid, electrical conductivity, turbidity, oxygen demand, total organic carbon amount, residual chlorine amount, pH-value, hardness, intake pressure, inflow temperature, osmotic pressure, pollution index.

Optionally, described water quantity regulating structure comprises:

Multiple one valve, described multiple one valve serial or parallel connection is arranged in described condensed water output pipe, and each one valve is in complete opening, buttoned-up status or default aperture state respectively;

Wherein, when multiple one valve is arranged in series, the default aperture of any two one valves is all different; When multiple one valve is arranged in parallel, irrelevant between the default aperture of each one valve and the default aperture of other one valves.

Optionally, described water quantity regulating structure comprises:

One valve, is arranged in described condensed water output pipe, and described first one valve switches to complete opening, the first aperture state or buttoned-up status according to described runoff investigation instruction;

Adjustment hole, is arranged in series in described condensed water output pipe with described one valve, and described adjustment hole has the 3rd aperture being less than described condensed water output pipe bore, and the 3rd aperture is greater than the first aperture; Or described adjustment hole and described one valve are arranged in parallel in described condensed water output pipe, described adjustment hole has the 3rd aperture being less than described condensed water output pipe bore, and the 3rd aperture and the first aperture have nothing to do.

Optionally, described water quantity regulating structure comprises:

Multistage valve, be arranged in described condensed water output pipe, described multistage valve switches to following any state according to described runoff investigation instruction: the preset hole footpath state of opening, buttoned-up status, arbitrary rank completely.

The technical scheme that embodiment of the present disclosure provides can comprise following beneficial effect:

From above-described embodiment, the disclosure, by condition detection architecture, accurately can detect the flow condition of water purifier; Simultaneously, by arranging water quantity regulating structure, can according to the situation of change of the flow condition in water purifier, dynamic adjustments is carried out to the water yield of condensed water, to guarantee the constant rate purifying the water yield and the concentrated water yield, avoid because flow condition change causes the purification water yield and the concentrated water yield out of proportion, affect the experience of filter element performance in water purifier and user.。

Should be understood that, it is only exemplary and explanatory that above general description and details hereinafter describe, and can not limit the disclosure.

Accompanying drawing explanation

Accompanying drawing to be herein merged in description and to form the part of this description, shows and meets embodiment of the present disclosure, and is used from description one and explains principle of the present disclosure.

Fig. 1 is the structural representation of a kind of water purifier according to the disclosure one exemplary embodiment.

Fig. 2 is the structural representation of the another kind of water purifier according to the disclosure one exemplary embodiment.

Fig. 3 is the structural representation of another water purifier according to the disclosure one exemplary embodiment.

Fig. 4 is the structural representation of another water purifier according to the disclosure one exemplary embodiment.

Fig. 5 is the structural representation of another water purifier according to the disclosure one exemplary embodiment.

Fig. 6 is the structural representation of another water purifier according to the disclosure one exemplary embodiment.

Detailed description of the invention

Here will be described exemplary embodiment in detail, its sample table shows in the accompanying drawings.When description below relates to accompanying drawing, unless otherwise indicated, the same numbers in different accompanying drawing represents same or analogous key element.Embodiment described in following exemplary embodiment does not represent all embodiments consistent with the disclosure.On the contrary, they only with as in appended claims describe in detail, the example of apparatus and method that aspects more of the present disclosure are consistent.

Fig. 1 is the structural representation of a kind of water purifier according to the disclosure one exemplary embodiment.For convenience of description, in following examples, suitable simplification is carried out to water purifier 1, but as shown in Figure 1, water purifier 1 can comprise multi-stage filter core, such as PP cotton filter core 11, preposition activated charcoal filter core 12, counter-infiltration filter core 13 and post active carbon filter core 14 etc., and the waterflow boosting that can pass through in booster pump 15 pairs of pipelines, to assist above-mentioned filter core to the filtration of not purifying waste water and purification; So, based on said structure, inputted do not purify waste water by the input port 16 of not purifying waste water being connected to the cotton filter core 11 of PP, then after multi-stage filter core filters, delivery outlet 17 exports, condensed water is exported by condensed water delivery outlet 18 for purifying waste water by purifying waste water of obtaining.Certainly, it will be understood by those skilled in the art that the structure of the water purifier 1 in correlation technique all can be applicable in technical scheme of the present disclosure, the disclosure does not limit this.

As shown in Figure 1, on the basis of said structure, water purifier 1 can also comprise:

Condition detection architecture 2, be arranged in the water route of described water purifier 1, described condition detection architecture 2 can detect the flow condition of described water purifier 1;

Controller 3, is connected to described condition detection architecture 1 and water quantity regulating structure 4, when described flow condition changes, sends runoff investigation instruction to described water quantity regulating structure 4;

Described water quantity regulating structure 4, be arranged in the condensed water output pipe condensed water delivery port outlet of counter-infiltration filter core 13 lower left (namely in figure) of condensed water delivery outlet 18 and counter-infiltration filter core 13 (i.e. between) of described water purifier 1, regulate the water yield of described condensed water output pipe according to described runoff investigation instruction, trend towards preset ratio with the ratio of the purification water yield and the concentrated water yield that maintain the output of described water purifier 1.

In the present embodiment, preset ratio refers to predetermined purification ratio, and this purification ratio can guarantee that the strainability of the counter-infiltration filter core 13 in water purifier 1 keeps stable, and exports enough purifying waste water.

In the present embodiment, accurately can be detected the flow condition of water purifier 1 by condition detection architecture 2; And by arranging water quantity regulating structure 4, according to the situation of change of the flow condition in water purifier 1, dynamic adjustments can be carried out to the water yield of condensed water.Such as when the water yield of not purifying waste water increases, by increasing the water yield of condensed water output pipe, not purifying waste water by timely filtration treatment of increase can be guaranteed, and avoid the strainability causing counter-infiltration filter core 13 to produce fluctuation; Or, such as when the water quality of not purifying waste water reduces, by increasing the water yield of condensed water output pipe, can by not purifying waste water to RO (the Reverse Osmosis membrane of counter-infiltration filter core 13, reverse osmosis) film surface rinses, thus avoid the impurity increased to reduce the filter efficiency of RO film.Similarly, when the water yield recovery of not purifying waste water or quality recovery, the water yield of condensed water output pipe can be reduced by water quantity regulating structure 4, to return to original state.

Below in conjunction with accompanying drawing 2-6, the composition structure of declaration condition detection architecture 2 and water quantity regulating structure 4; Certainly, structure is herein only for citing, and the condition detection architecture 2 of other types form and water quantity regulating structure 4 obviously also can be applied in technical scheme of the present disclosure, and the disclosure does not limit this.

Embodiment one:

As an exemplary embodiment, as shown in Figure 2, condition detection architecture 2 can comprise: temperature sensor 21, and this temperature sensor 21 detects the inflow temperature of described water purifier 1, using as described flow condition; Wherein, the runoff investigation instruction of described controller 3 generation is interval relevant to the preset temperature residing for described inflow temperature.

In this embodiment, temperature sensor 21 can be arranged in any water route of water purifier 1; Wherein, when being positioned at intake line of not purifying waste water (pipeline between the water inlet of namely do not purify waste water input port 16 and the cotton filter core 11 of PP) of described water purifier 1, the water temperature of not purifying waste water of input can be measured more preparatively, and when temperature sensor 21 the closer to do not purify waste water input port 16 time, more can realize temperature measurement exactly, thus the setting position of temperature sensor 21 can be made near the water inlet (input port 16 of namely not purifying waste water) of described intake line of not purifying waste water, be such as set to temperature sensor 21 to be close to the inner side of input port 16 of not purifying waste water.

Interval by arranging multiple preset temperature, such as interval 1:T1 ~ T2, interval 2:T2 ~ T3, interval 3:T3 ~ T4 etc., and corresponding water yield is set for each preset temperature is interval, then controller 3 can preset temperature residing for the detected temperatures of temperature sensor 21 interval, and send corresponding runoff investigation instruction, to realize the regulable control to water quantity regulating structure 4 according to the water yield of correspondence.Wherein, assuming that T1 < T2 < T3 < T4, then the water yield of interval 1, interval 2, interval 3 correspondences increases successively, and namely water yield and preset temperature interval are proportionate.

In the embodiment shown in Figure 2, water quantity regulating structure 4 comprises:

First one valve 41, is arranged in described condensed water output pipe, and described first one valve 21 switches to complete opening, the first aperture state or buttoned-up status according to runoff investigation instruction;

Second one valve 42, be arranged in series in described condensed water output pipe with described first one valve 21, described second one valve 22 switches to complete opening, the second aperture state or buttoned-up status according to runoff investigation instruction, and the first aperture is different from the second aperture.

Wherein, each one valve (as the first one valve 41, second one valve 42 etc.) is except complete opening (making condensed water pass through completely), buttoned-up status (making condensed water cannot pass through completely), only comprise a kind of controllable bore diameter (this aperture is between buttoned-up status and complete opening), thus be called " one valve ", be merely able to the aperture set when dispatching from the factory according to water purifier 1, control the circulation of condensed water.

In the present embodiment, because the default aperture of any two one valves is all different, such as the default aperture of the first one valve 41 i.e. the first aperture is 0.5mm, default aperture i.e. second aperture of the second one valve 42 is 0.2mm, and the aperture of condensed water output pipe is 1mm, then for example: when the second one valve 42 is in the second aperture state, the water yield of whole condensed water output pipe will be limited to the state of " aperture is 0.2mm ", and when the second one valve 42 is in complete opening, when first one valve 41 is in the first aperture state, the water yield of whole condensed water output pipe will be limited to the state of " aperture is 0.5mm ", and when the first one valve 41 and the second one valve 242 are all in complete opening, the water yield of whole condensed water output pipe will be in maximum stream flow state, the i.e. state of " aperture is 1mm ".

Therefore, by the water quantity regulating structure 4 that one valve that multiple default aperture is different is in series, the multistage adjustment of condensed water water yield can be realized; As by the first one valve 41 and the second one valve 42, can realize: multiple ranks such as 0.2mm aperture, 0.5mm aperture and 1mm aperture, form the multistage flow-control to condensed water.

Certainly, be only described for the cascaded structure of two one valves herein; In fact, water quantity regulating structure 4 can comprise multiple one valve, multiple one valve is arranged in series in described condensed water output pipe, each one valve switches to complete opening, buttoned-up status or default aperture state according to runoff investigation instruction respectively, and the default aperture of any two one valves is all different; Connect analogously with two one valves, when multiple one valve meets above-mentioned condition, multistage flow-control can be realized, repeat no more herein.

Embodiment two:

As another exemplary embodiment, as shown in Figure 3, condition detection architecture 2 can comprise: hydraulic pressure sensor 22, and this hydraulic pressure sensor 22 detects the intake pressure of described water purifier 1, using as described flow condition; Wherein, the runoff investigation instruction of described controller 3 generation is interval relevant to the preset pressure residing for described intake pressure.

In this embodiment, when being provided with osmosis filtration structure (such as counter-infiltration filter core 13) in water purifier 1 and be positioned at the booster water pump 15 of this osmosis filtration structure front end, hydraulic pressure sensor 22 can be arranged in the water route of booster water pump 15 front end; Such as in figure 3, on the water route of hydraulic pressure sensor 22 between the cotton filter core 11 of PP and preposition activated charcoal filter core 12.

With preset temperature interval analogously, interval by arranging multiple preset pressure, such as interval 1:P1 ~ P2, interval 2:P2 ~ P3, interval 3:P3 ~ P4 etc., and corresponding water yield is set for each preset pressure is interval, then controller 3 can preset pressure residing for the detected pressures of hydraulic pressure sensor 22 interval, and send corresponding runoff investigation instruction, to realize the regulable control to water quantity regulating structure 4 according to the water yield of correspondence.Wherein, assuming that P1 < P2 < P3 < P4, then the water yield of interval 1, interval 2, interval 3 correspondences increases successively, and namely water yield and preset pressure interval are proportionate.

In the embodiment shown in fig. 3, water quantity regulating structure 4 comprises:

First one valve 41, is arranged in described condensed water output pipe, and described first one valve 41 switches to complete opening, the first aperture state or buttoned-up status according to runoff investigation instruction;

Second one valve 42, be arranged in parallel in described condensed water output pipe with described first one valve 41, described second one valve 42 switches to complete opening, the second aperture state or buttoned-up status according to runoff investigation instruction, irrelevant between the first aperture and the second aperture.

In the present embodiment, by the multiple one valve of parallel connection, then by each enable one or more one valve, the Concentrate flow of appropriate level can be formed.The such as default aperture of the first one valve 41 i.e. the first aperture is 0.5mm, default aperture i.e. second aperture of the second one valve 22 is 0.2mm, and the aperture of condensed water output pipe is 1mm, then for example: when the first one valve 41 be in buttoned-up status, the second one valve 42 be in the second aperture state time, the water yield of whole condensed water output pipe will be limited to the state of " aperture is 0.2mm "; When the second one valve 42 be in buttoned-up status, the first one valve 41 be in the first aperture state time, the water yield of whole condensed water output pipe will be limited to the state of " aperture is 0.5mm "; When the first one valve 41 be in the first aperture state, the second one valve 42 be in the second aperture state time, the water yield of whole condensed water output pipe will be limited to the state of " aperture is 0.7mm (0.2mm+0.5mm) "; When the first one valve 41 or the second one valve 42 are in complete opening, the water yield of whole condensed water output pipe is in maximum stream flow state, i.e. the state of " aperture is 1mm ".

Therefore, the water quantity regulating structure 4 consisted of the one valve parallel connection that multiple default aperture is different, can realize the multistage adjustment of condensed water water yield; As by the first one valve 41 and the second one valve 42, can realize: multiple ranks such as 0.2mm aperture, 0.5mm aperture, 0.7mm aperture and 1mm aperture, form the multistage flow-control to condensed water.

Certainly, be only described for the parallel-connection structure of two one valves herein; In fact, water quantity regulating structure 4 can comprise multiple one valve, the plurality of one valve is arranged in parallel in described condensed water output pipe, each one valve switches to complete opening, buttoned-up status or default aperture state according to runoff investigation instruction respectively, and irrelevant between the default aperture of each one valve and the default aperture of other one valves; In parallel analogously with two one valves, when multiple one valve meets above-mentioned condition, multistage flow-control can be realized, repeat no more herein.

Embodiment three:

As another exemplary embodiment, as shown in Figure 4, condition detection architecture 2 can comprise: water quality sensor 23, and this water quality sensor 23 detects the influent quality of described water purifier 1, using as described flow condition; Wherein, the runoff investigation instruction of described controller 3 generation is interval relevant to the preset quality residing for described influent quality.

In this embodiment, water quality sensor 23 can be arranged on any water route in water purifier 1, such as in the embodiment shown in fig. 4, water quality sensor 23 is positioned on output pipe of purifying waste water (pipeline between the delivery port of namely purify waste water delivery outlet 17 and post active carbon filter core 14).

Influent quality comprise following one of at least: total dissolved solid (TDS, Total DissolvedSolids), electrical conductivity, turbidity, oxygen demand, total organic carbon amount, residual chlorine amount, pH-value, hardness, intake pressure, inflow temperature, osmotic pressure, pollution index.So, for the Testing index of adopted influent quality, it is interval that the preset quality similar with above-mentioned temperature/hydraulic pressure can be set, for " TDS ", then can arrange such as: interval 1:TDS1 ~ TDS2, interval 2:TDS2 ~ TDS3, interval 3:TDS3 ~ TDS4 etc., and corresponding water yield is set for each preset quality is interval, then controller 3 can preset quality residing for the detection water quality of water quality sensor 23 interval, and send corresponding runoff investigation instruction, to realize the regulable control to water quantity regulating structure 4 according to the water yield of correspondence.Wherein, assuming that TDS1 < TDS2 < TDS3 < TDS4, namely interval 1, the interval water quality of 2, interval 3 reduce successively, then the water yield of interval 1, interval 2, interval 3 correspondences increases successively, and namely water yield and preset quality interval are in inverse correlation.

In the embodiment shown in fig. 4, water quantity regulating structure 4 comprises:

One valve 43, is arranged in described condensed water output pipe, and described one valve 43 switches to complete opening, the first aperture state or buttoned-up status according to runoff investigation instruction;

Adjustment hole 44, is arranged in series in described condensed water output pipe with described one valve 43, and described adjustment hole 24 has the 3rd aperture being less than described condensed water output pipe bore, and the 3rd aperture is different from the first aperture.

In the present embodiment, adjustment hole 44 can be arranged at the optional position of condensed water output pipe, the condensed water water outlet of such as water purifier 1.

In the present embodiment, assuming that the first aperture of one valve 43 be 0.2mm, the 3rd aperture of adjustment hole 44 is 0.5mm, and the aperture of condensed water output pipe is 1mm, then the aperture due to adjustment hole 44 is non-adjustable, can think that the maximum diameter of hole of condensed water output pipe is restricted to the 3rd aperture.Correspondingly, when one valve 43 is in the first aperture state, the water yield of whole condensed water output pipe will be limited to the state of " aperture is 0.2mm "; When one valve 43 is in complete opening, the water yield of whole condensed water output pipe will be limited to the state of " aperture is 0.5mm ".

Therefore, by the water quantity regulating structure 2 that the different one valve in aperture 43 and adjustment hole 44 are in series, the multistage adjustment of condensed water water yield can be realized; Such as can realize: multiple ranks such as 0.2mm aperture, 0.5mm aperture, form the multistage flow-control to condensed water.

It should be noted that:

1, in embodiment of the present disclosure, only the multi-form of water quantity regulating structure 4 is illustrated, and do not limit the syntagmatic of " condition detection architecture 2 " and " water quantity regulating structure 4 ", namely " the condition detection architecture 2 " of arbitrary form and " water quantity regulating structure 4 " of arbitrary form all can carry out independent assortment, and are applied in technical scheme of the present disclosure.

2, water quantity regulating structure 4 can also exist a variety of multi-form, is described below to other several form.

As an illustrative embodiments, as shown in Figure 5, water quantity regulating structure 4 can comprise:

One valve 43, is arranged in described condensed water output pipe, and described one valve 43 switches to complete opening, the first aperture state or buttoned-up status according to runoff investigation instruction;

Adjustment hole 44, is arranged in parallel in described condensed water output pipe with described one valve 43, and described adjustment hole 44 has the 3rd aperture being less than described condensed water output pipe bore, and irrelevant between the 3rd aperture and the first aperture.

In the present embodiment, assuming that the first aperture of one valve 43 be 0.2mm, the 3rd aperture of adjustment hole 44 is 0.5mm, and the aperture of condensed water output pipe is 1mm, then for example: when one valve 43 is in buttoned-up status, the condensed water of whole condensed water output pipe is circulated by adjustment hole 44, and namely water yield will be limited to the state of " aperture is 0.5mm "; When one valve 43 is in the first aperture state, the water yield of whole condensed water output pipe will be limited to the state of " aperture is 0.7mm (0.2mm+0.5mm) "; When one valve 43 is in complete opening, the water yield of whole condensed water output pipe is in maximum stream flow state, i.e. the state of " aperture is 1mm ".

Therefore, by one valve 43 water quantity regulating structure 4 that form in parallel with adjustment hole 44, the multistage adjustment of condensed water water yield can be realized; As by one valve 43 and adjustment hole 44, can realize: multiple ranks such as 0.5mm aperture, 0.7mm aperture and 1mm aperture, form the multistage flow-control to condensed water.

As another illustrative embodiments, as shown in Figure 6, water quantity regulating structure 4 can comprise: multistage valve 45, and be arranged in described condensed water output pipe, described multistage valve 45 is in following any state: the preset hole footpath state of opening, buttoned-up status, arbitrary rank completely.

In the present embodiment, multistage valve 45 itself is configured with the preset hole footpath state of multiple rank, such as 0.2mm aperture, 0.5mm aperture, 0.7mm aperture etc., then except completely open or closed condition except, can also switch between each default aperture state as required, thus form the multistage flow-control to condensed water.

Those skilled in the art, at consideration description and after putting into practice disclosed herein disclosing, will easily expect other embodiment of the present disclosure.The application is intended to contain any modification of the present disclosure, purposes or adaptations, and these modification, purposes or adaptations are followed general principle of the present disclosure and comprised the undocumented common practise in the art of the disclosure or conventional techniques means.Description and embodiment are only regarded as exemplary, and true scope of the present disclosure and spirit are pointed out by claim below.

Should be understood that, the disclosure is not limited to precision architecture described above and illustrated in the accompanying drawings, and can carry out various amendment and change not departing from its scope.The scope of the present disclosure is only limited by appended claim.

Claims (11)

1. a water purifier, is characterized in that, comprising:

Condition detection architecture, be arranged in the water route of described water purifier, described condition detection architecture can detect the flow condition of described water purifier;

Controller, is connected to described condition detection architecture and water quantity regulating structure, when described flow condition changes, sends runoff investigation instruction to described water quantity regulating structure;

Described water quantity regulating structure, be arranged in the condensed water output pipe of described water purifier, regulate the water yield of described condensed water output pipe according to described runoff investigation instruction, trend towards preset ratio with the ratio of the purification water yield and the concentrated water yield that maintain the output of described water purifier.

2. water purifier according to claim 1, is characterized in that, described condition detection architecture comprises:

Temperature sensor, described temperature sensor detects the inflow temperature of described water purifier, using as described flow condition; Wherein, the runoff investigation instruction of described controller generation is interval relevant to the preset temperature residing for described inflow temperature;

Described water quantity regulating structure regulates the water yield of described condensed water output pipe according to the runoff investigation instruction received, and water yield and described preset temperature interval are proportionate.

3. water purifier according to claim 2, is characterized in that, described temperature sensor is arranged in the intake line of not purifying waste water of described water purifier.

4. water purifier according to claim 3, is characterized in that, the setting position of described temperature sensor is near the water inlet of described intake line of not purifying waste water.

5. water purifier according to claim 1, is characterized in that, described condition detection architecture comprises:

Hydraulic pressure sensor, described hydraulic pressure sensor detects the intake pressure of described water purifier, using as described flow condition; Wherein, the runoff investigation instruction of described controller generation is interval relevant to the preset pressure residing for described intake pressure;

Described water quantity regulating structure regulates the water yield of described condensed water output pipe according to the runoff investigation instruction received, and water yield and described preset pressure interval are proportionate.

6. water purifier according to claim 5, is characterized in that, comprises osmosis filtration structure and be arranged at the booster water pump of described osmosis filtration structure front end in described water purifier; Wherein, described hydraulic pressure sensor is arranged in the water route of described booster water pump front end.

7. water purifier according to claim 1, is characterized in that, described condition detection architecture comprises:

Water quality sensor, described water quality sensor detects the influent quality of described water purifier, using as described flow condition; Wherein, the runoff investigation instruction of described controller generation is interval relevant to the preset quality residing for described influent quality;

Described water quantity regulating structure regulates the water yield of described condensed water output pipe according to the runoff investigation instruction received, and water yield and described preset quality interval are in inverse correlation.

8. water purifier according to claim 7, it is characterized in that, described influent quality comprise following one of at least: total dissolved solid, electrical conductivity, turbidity, oxygen demand, total organic carbon amount, residual chlorine amount, pH-value, hardness, intake pressure, inflow temperature, osmotic pressure, pollution index.

9. water purifier according to claim 1, is characterized in that, described water quantity regulating structure comprises:

Multiple one valve, described multiple one valve serial or parallel connection is arranged in described condensed water output pipe, and each one valve is in complete opening, buttoned-up status or default aperture state respectively;

Wherein, when multiple one valve is arranged in series, the default aperture of any two one valves is all different; When multiple one valve is arranged in parallel, irrelevant between the default aperture of each one valve and the default aperture of other one valves.

10. water purifier according to claim 1, is characterized in that, described water quantity regulating structure comprises:

One valve, is arranged in described condensed water output pipe, and described one valve switches to complete opening, the first aperture state or buttoned-up status according to described runoff investigation instruction;

Adjustment hole, is arranged in series in described condensed water output pipe with described one valve, and described adjustment hole has the 3rd aperture being less than described condensed water output pipe bore, and the 3rd aperture is greater than the first aperture; Or described adjustment hole and described one valve are arranged in parallel in described condensed water output pipe, described adjustment hole has the 3rd aperture being less than described condensed water output pipe bore, and the 3rd aperture and the first aperture have nothing to do.

11. water purifiers according to claim 1, is characterized in that, described water quantity regulating structure comprises:

Multistage valve, be arranged in described condensed water output pipe, described multistage valve switches to following any state according to described runoff investigation instruction: the preset hole footpath state of opening, buttoned-up status, arbitrary rank completely.